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4 1 NOITCES CHAPTER 1 Basic structure and function of cells Epithelial cells rarely operate independently of each other and com- CELL STRUCTURE monly form aggregates by adhesion, often assisted by specialized inter- cellular junctions. They may also communicate with each other either GENERAL CHARACTERISTICS OF CELLS by generating and detecting molecular signals that diffuse across inter- cellular spaces, or more rapidly by generating interactions between The shapes of mammalian cells vary widely depending on their interac- membrane-bound signalling molecules. Cohesive groups of cells con- tions with each other, their extracellular environment and internal stitute tissues, and more complex assemblies of tissues form functional structures. Their surfaces are often highly folded when absorptive or systems or organs. transport functions take place across their boundaries. Cell size is Most cells are between 5 and 50 µm in diameter: e.g. resting lym- limited by rates of diffusion, either that of material entering or leaving phocytes are 6 µm across, red blood cells 7.5 µm and columnar epithe-
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cells, or that of diffusion within them. Movement of macromolecules lial cells 20 µm tall and 10 µm wide (all measurements are approximate). can be much accelerated and also directed by processes of active trans- Some cells are much larger than this: e.g. megakaryocytes of the bone port across the plasma membrane and by transport mechanisms within marrow and osteoclasts of the remodelling bone are more than 200 µm the cell. According to the location of absorptive or transport functions, in diameter. Neurones and skeletal muscle cells have relatively extended apical microvilli (Fig. 1.1) or basolateral infoldings create a large shapes, some of the former being over 1 m in length. surface area for transport or diffusion. Motility is a characteristic of most cells, in the form of movements of cytoplasm or specific organelles from one part of the cell to another. CELLULAR ORGANIZATION It also includes: the extension of parts of the cell surface such as pseu- dopodia, lamellipodia, filopodia and microvilli; locomotion of entire Each cell is contained within its limiting plasma membrane, which
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cells, as in the amoeboid migration of tissue macrophages; the beating encloses the cytoplasm. All cells, except mature red blood cells, also of flagella or cilia to move the cell (e.g. in spermatozoa) or fluids overly- contain a nucleus that is surrounded by a nuclear membrane or enve- ing it (e.g. in respiratory epithelium); cell division; and muscle contrac- lope (see Fig. 1.1; Fig. 1.2). The nucleus includes: the genome of the tion. Cell movements are also involved in the uptake of materials from cell contained within the chromosomes; the nucleolus; and other sub- their environment (endocytosis, phagocytosis) and the passage of large nuclear structures. The cytoplasm contains cytomembranes and several molecular complexes out of cells (exocytosis, secretion). membrane-bound structures, called organelles, which form separate Surface projections (cilia, microvilli) Surface invagination Actin filaments Vesicle Mitochondrion Cell junctions Plasma membrane Desmosome Peroxisomes Cytosol Nuclear pore Intermediate
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filaments Nuclear envelope Smooth endoplasmic Nucleus reticulum Nucleolus Ribosome Rough endoplasmic reticulum Microtubules Golgi apparatus Centriole pair Lysosomes Cell surface folds Fig . 1 .1 The main structural components and internal organization of a generalized cell .
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Cell structure 5 1 RETPaHC CC MMVV AAPPMM AAJJCC Receptor Transmembrane protein pore complex of proteins Carbohydrate residues External (extracellular) surface MM MM CCyy LLPPMM Internal (intracellular) surface NN Lipid bilayer appearance in electron microscope Intrinsic membrane protein Extrinsic Transmembrane protein protein Transport Non-polar tail or diffusion of phospholipid channel Cytoskeletal Polar end of element EENN phospholipid Fig . 1 .3 The molecular organization of the plasma membrane, according to the fluid mosaic model of membrane structure . Intrinsic or integral membrane proteins include diffusion or transport channel complexes, receptor proteins and adhesion molecules . These may span the thickness of the membrane (transmembrane proteins) and can have both extracellular and cytoplasmic domains . Transmembrane proteins have hydrophobic zones, which cross the phospholipid bilayer and allow the Fig . 1 .2 The structural organization and some principal organelles of a
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protein to ‘float’ in the plane of the membrane . Some proteins are typical cell . This example is a ciliated columnar epithelial cell from human restricted in their freedom of movement where their cytoplasmic domains nasal mucosa . The central cell, which occupies most of the field of are tethered to the cytoskeleton . view, is closely apposed to its neighbours along their lateral plasma membranes . Within the apical junctional complex, these membranes form a tightly sealed zone (tight junction) that isolates underlying tissues from, charides and polysaccharides are bound either to proteins (glycopro- in this instance, the nasal cavity . Abbreviations: AJC, apical junctional teins) or to lipids (glycolipids), and project mainly into the extracellular complex; APM, apical plasma membrane; C, cilia; Cy, cytoplasm; EN, domain (Fig. 1.3). euchromatic nucleus; LPM, lateral plasma membrane; M, mitochondria; In the electron microscope, membranes fixed and contrasted by MV, microvilli; N, nucleolus . (Courtesy of Dr Bart Wagner, Histopathology
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heavy metals such as osmium tetroxide appear in section as two densely Department, Sheffield Teaching Hospitals, UK .) stained layers separated by an electron-translucent zone – the classic unit membrane. The total thickness of each layer is about 7.5 nm. The and distinct compartments within the cytoplasm. Cytomembranes overall thickness of the plasma membrane is typically 15 nm. Freeze- include the rough and smooth endoplasmic reticulum and Golgi appa- fracture cleavage planes usually pass along the hydrophobic portion of ratus, as well as vesicles derived from them. Organelles include lyso- the bilayer, where the hydrophobic tails of phospholipids meet, and somes, peroxisomes and mitochondria. The nucleus and mitochondria split the bilayer into two leaflets. Each cleaved leaflet has a surface and are enclosed by a double-membrane system; lysosomes and peroxi- a face. The surface of each leaflet faces either the extracellular surface somes have a single bounding membrane. There are also non- (ES) or the intracellular or protoplasmic (cytoplasmic) surface (PS). The
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membranous structures, called inclusions, which lie free in the cytosolic extracellular face (EF) and protoplasmic face (PF) of each leaflet are compartment. They include lipid droplets, glycogen aggregates and pig- artificially produced during membrane splitting. This technique has ments (e.g. lipofuscin). In addition, ribosomes and several filamentous also demonstrated intramembranous particles embedded in the lipid protein networks, known collectively as the cytoskeleton, are found in bilayer; in most cases, these represent large transmembrane protein the cytosol. The cytoskeleton determines general cell shape and sup- molecules or complexes of proteins. Intramembranous particles are ports specialized extensions of the cell surface (microvilli, cilia, flag- distributed asymmetrically between the two half-layers, usually adher- ella). It is involved in the assembly of specific structures (e.g. centrioles) ing more to one half of the bilayer than to the other. In plasma mem- and controls cargo transport in the cytoplasm. The cytosol contains branes, the intracellular leaflet carries most particles, seen on its face
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many soluble proteins, ions and metabolites. (the PF). Where they have been identified, clusters of particles usually represent channels for the transmembrane passage of ions or molecules Plasma membrane between adjacent cells (gap junctions). Biophysical measurements show the lipid bilayer to be highly fluid, Cells are enclosed by a distinct plasma membrane, which shares fea- allowing diffusion in the plane of the membrane. Thus proteins are able tures with the cytomembrane system that compartmentalizes the cyto- to move freely in such planes unless anchored from within the cell. plasm and surrounds the nucleus. All membranes are composed of Membranes in general, and the plasma membrane in particular, form lipids (mainly phospholipids, cholesterol and glycolipids) and pro- boundaries selectively limiting diffusion and creating physiologically teins, in approximately equal ratios. Plasma membrane lipids form a distinct compartments. Lipid bilayers are impermeable to hydrophilic lipid bilayer, a layer two molecules thick. The hydrophobic ends of each solutes and ions, and so membranes actively control the passage of ions
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lipid molecule face the interior of the membrane and the hydrophilic and small organic molecules such as nutrients, through the activity of ends face outwards. Most proteins are embedded within, or float in, the membrane transport proteins. However, lipid-soluble substances can lipid bilayer as a fluid mosaic. Some proteins, because of extensive pass directly through the membrane so that, for example, steroid hor- hydrophobic regions of their polypeptide chains, span the entire width mones enter the cytoplasm freely. Their receptor proteins are either of the membrane (transmembrane proteins), whereas others are only cytosolic or nuclear, rather than being located on the cell surface. superficially attached to the bilayer by lipid groups. Both are integral Plasma membranes are able to generate electrochemical gradients (intrinsic) membrane proteins, as distinct from peripheral (extrinsic) and potential differences by selective ion transport, and actively take up membrane proteins, which are membrane-bound only through their or export small molecules by energy-dependent processes. They also association with other proteins. Carbohydrates in the form of oligosac- provide surfaces for the attachment of enzymes, sites for the receptors
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Basic structure and function of cells 5.e1 1 RETPaHC Combinations of biochemical, biophysical and biological tech- niques have revealed that lipids are not homogenously distributed in membranes, but that some are organized into microdomains in the bilayer, called ‘detergent-resistant membranes’ or lipid ‘rafts’, rich in sphingomyelin and cholesterol. The ability of select subsets of proteins to partition into different lipid microdomains has profound effects on their function, e.g. in T-cell receptor and cell–cell signalling. The highly organized environment of the domains provides a signalling, trafficking and membrane fusion environment.
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BaSIC STRuCTuRE aNd fuNCTION Of CEllS 6 1 NOITCES of external signals, including hormones and other ligands, and sites for abundant proteins; SER is abundant in steroid-producing cells and the recognition and attachment of other cells. Internally, plasma mem- muscle cells. A variant of the endoplasmic reticulum in muscle cells is branes can act as points of attachment for intracellular structures, in the sarcoplasmic reticulum, involved in calcium storage and release for particular those concerned with cell motility and other cytoskeletal muscle contraction. For further reading on the endoplasmic reticulum, functions. Cell membranes are synthesized by the rough endoplasmic see Bravo et al (2013). reticulum in conjunction with the Golgi apparatus. Smooth endoplasmic reticulum Cell coat (glycocalyx) The smooth endoplasmic reticulum (see Fig. 1.4) is associated with The external surface of a plasma membrane differs structurally from carbohydrate metabolism and many other metabolic processes, includ- internal membranes in that it possesses an external, fuzzy, carbohydrate- ing detoxification and synthesis of lipids, cholesterol and steroids. The
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rich coat, the glycocalyx. The cell coat forms an integral part of the membranes of the smooth endoplasmic reticulum serve as surfaces for plasma membrane, projecting as a diffusely filamentous layer 2–20 nm the attachment of many enzyme systems, e.g. the enzyme cytochrome or more from the lipoprotein surface. The cell coat is composed of the P450, which is involved in important detoxification mechanisms and carbohydrate portions of glycoproteins and glycolipids embedded in is thus accessible to its substrates, which are generally lipophilic. The the plasma membrane (see Fig. 1.3). membranes also cooperate with the rough endoplasmic reticulum The precise composition of the glycocalyx varies with cell type; many and the Golgi apparatus to synthesize new membranes; the protein, tissue- and cell type-specific antigens are located in the coat, including carbohydrate and lipid components are added in different structural the major histocompatibility complex of the immune system and, in compartments. The smooth endoplasmic reticulum in hepatocytes con-
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the case of erythrocytes, blood group antigens. Therefore, the glycocalyx tains the enzyme glucose-6-phosphatase, which converts glucose-6- plays a significant role in organ transplant compatibility. The glycocalyx phosphate to glucose, a step in gluconeogenesis. found on apical microvilli of enterocytes, the cells forming the lining epithelium of the intestine, consists of enzymes involved in the diges- Rough endoplasmic reticulum tive process. Intestinal microvilli are cylindrical projections (1–2 µm The rough endoplasmic reticulum is a site of protein synthesis; its long and about 0.1 µm in diameter) forming a closely packed layer cytosolic surface is studded with ribosomes (Fig. 1.5E). Ribosomes only called the brush border that increases the absorptive function of bind to the endoplasmic reticulum when proteins targeted for secretion enterocytes. begin to be synthesized. Most proteins pass through its membranes and accumulate within its cisternae, although some integral membrane pro- Cytoplasm teins, e.g. plasma membrane receptors, are inserted into the rough
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endoplasmic reticulum membrane, where they remain. After passage Compartments and functional organization from the rough endoplasmic reticulum, proteins remain in membrane- bound cytoplasmic organelles such as lysosomes, become incorporated The cytoplasm consists of the cytosol, a gel-like material enclosed by into new plasma membrane, or are secreted by the cell. Some carbohy- the cell or plasma membrane. The cytosol is made up of colloidal pro- drates are also synthesized by enzymes within the cavities of the rough teins such as enzymes, carbohydrates and small protein molecules, endoplasmic reticulum and may be attached to newly formed protein together with ribosomes and ribonucleic acids. The cytoplasm contains (glycosylation). Vesicles are budded off from the rough endoplasmic two cytomembrane systems, the endoplasmic reticulum and Golgi reticulum for transport to the Golgi as part of the protein-targeting apparatus, as well as membrane-bound organelles (lysosomes, peroxi- mechanism of the cell. somes and mitochondria), membrane-free inclusions (lipid droplets,
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glycogen and pigments) and the cytoskeleton. The nuclear contents, Ribosomes, polyribosomes the nucleoplasm, are separated from the cytoplasm by the nuclear and protein synthesis envelope. Ribosomes are macromolecular machines that catalyse the synthesis of Endoplasmic reticulum proteins from amino acids; synthesis and assembly into subunits takes The endoplasmic reticulum is a system of interconnecting membrane- place in the nucleolus and includes the association of ribosomal RNA lined channels within the cytoplasm (Fig. 1.4). These channels take (rRNA) with ribosomal proteins translocated from their site of synthesis various forms, including cisternae (flattened sacs), tubules and vesicles. in the cytoplasm. The individual subunits are then transported into the The membranes divide the cytoplasm into two major compartments. cytoplasm, where they remain separate from each other when not The intramembranous compartment, or cisternal space, is where secre- actively synthesizing proteins. Ribosomes are granules approximately tory products are stored or transported to the Golgi complex and cell 25 nm in diameter, composed of rRNA molecules and proteins assem-
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exterior. The cisternal space is continuous with the perinuclear space. bled into two unequal subunits. The subunits can be separated by their Structurally, the channel system can be divided into rough or granu- sedimentation coefficients (S) in an ultracentrifuge into larger 60S and lar endoplasmic reticulum (RER), which has ribosomes attached to its smaller 40S components. These are associated with 73 different pro- outer, cytosolic surface, and smooth or agranular endoplasmic reticu- teins (40 in the large subunit and 33 in the small), which have structural lum (SER), which lacks ribosomes. The functions of the endoplasmic and enzymatic functions. Three small, highly convoluted rRNA strands reticulum vary greatly and include: the synthesis, folding and transport (28S, 5.8S and 5S) make up the large subunit, and one strand (18S) is of proteins; synthesis and transport of phospholipids and steroids; and in the small subunit.
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storage of calcium within the cisternal space and regulated release into A typical cell contains millions of ribosomes. They may form groups the cytoplasm. In general, RER is well developed in cells that produce (polyribosomes or polysomes) attached to messenger RNA (mRNA), which they translate during protein synthesis for use outside the system of membrane compartments, e.g. enzymes of the cytosol and cytoskel- etal proteins. Some of the cytosolic products include proteins that can be inserted directly into (or through) membranes of selected organelles, such as mitochondria and peroxisomes. Ribosomes may be attached to the membranes of the rough endoplasmic reticulum (see Fig. 1.5E). In a mature polyribosome, all the attachment sites of the mRNA are occupied as ribosomes move along it, synthesizing protein according to its nucleotide sequence. Consequently, the number and spacing of ribosomes in a polyribosome indicate the length of the mRNA mole- cule and hence the size of the protein being made. The two subunits have separate roles in protein synthesis. The 40S subunit is the site of
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attachment and translation of mRNA. The 60S subunit is responsible for the release of the new protein and, where appropriate, attachment to the endoplasmic reticulum via an intermediate docking protein that directs the newly synthesized protein through the membrane into the cisternal space. Golgi apparatus (Golgi complex) Fig . 1 .4 Smooth endoplasmic reticulum with associated vesicles . The The Golgi apparatus is a distinct cytomembrane system located near the dense particles are glycogen granules . (Courtesy of Rose Watson, Cancer nucleus and the centrosome. It is particularly prominent in secretory Research UK .) cells and can be visualized when stained with silver or other metallic
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Basic structure and function of cells 6.e1 1 RETPaHC The glycocalyx plays a significant role in maintenance of the integrity of tissues and in a wide range of dynamic cellular processes, e.g. serving as a vascular permeability barrier and transducing fluid shear stress to the endothelial cell cytoskeleton (Weinbaum et al 2007). Disruption of the glycocalyx on the endothelial surface of large blood vessels precedes inflammation, a conditioning factor of atheromatosis (e.g. deposits of cholesterol in the vascular wall leading to partial or complete obstruc- tion of the vascular lumen). Protein synthesis on ribosomes may be suppressed by a class of RNA molecules known as small interfering RNA (siRNA) or silencing RNA. These molecules are typically 20–25 nucleotides in length and bind (as a complex with proteins) to specific mRNA molecules via their comple- mentary sequence. This triggers the enzymatic destruction of the mRNA or prevents the movement of ribosomes along it. Synthesis of the encoded protein is thus prevented. Their normal function may have antiviral or other protective effects; there is also potential for developing
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artificial siRNAs as a therapeutic tool for silencing disease-related genes.
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Cell structure 7 1 RETPaHC A B N GG V GG M C Phagocytic pathway Secretory pathway Membrane recycling Receptor-mediated endocytosis Clathrin-coated pit Early endosome Late endosome Lysosomal fusion Secondary lysosome Residual body Vesicle shuttling between cisternae trans-Golgi network Golgi cisternae cis-Golgi network Rough endoplasmic reticulum D E G R Fig . 1 .5 The Golgi apparatus and functionally related organelles . A, Golgi apparatus (G) adjacent to the nucleus (N) (V, vesicle) . B, A large residual body (tertiary lysosome) in a cardiac muscle cell (M, mitochondrion) . C, The functional relationships between the Golgi apparatus and associated cellular structures . D, A three-dimensional reconstruction of the Golgi apparatus in a pancreatic β cell showing stacks of Golgi cisternae from the cis-face (pink)
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and cis-medial cisternae (red, green) to the trans-Golgi network (blue, yellow, orange–red); immature proinsulin granules (condensing vesicles) are shown in pale blue and mature (crystalline) insulin granules in dark blue . The flat colour areas represent cut faces of cisternae and vesicles . E, Rough endoplasmic reticulum (R), associated with the Golgi apparatus (G) . (D, Courtesy of Dr Brad Marsh, Institute for Molecular Bioscience, University of Queensland, Brisbane . A,B,E From human tissue, courtesy of Dr Bart Wagner, Histopathology Department, Sheffield Teaching Hospitals, UK .)
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BaSIC STRuCTuRE aNd fuNCTION Of CEllS 8 1 NOITCES salts. Traffic between the endoplasmic reticulum and the Golgi appara- Endocytic (internalization) pathway tus is bidirectional and takes place via carrier vesicles derived from the The endocytic pathway begins at the plasma membrane and ends in donor site that bud, tether and fuse with the target site. lysosomes involved in the degradation of the endocytic cargo through Golgins are long coiled-coil proteins attached to the cytoplasmic the enzymatic activity of lysosomal hydrolases. Endocytic cargo is surface of cisternal membranes, forming a fibrillar matrix surrounding internalized from the plasma membrane to early endosomes and the Golgi apparatus to stabilize it; they have a role in vesicle trafficking then to late endosomes. Late endosomes transport their cargo to lyso- (for further reading on golgins, see Munro 2011). The Golgi apparatus somes, where the cargo material is degraded following fusion and has several functions: it links anterograde and retrograde protein and
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mixing of contents of endosomes and lysosomes. Early endosomes lipid flow in the secretory pathway; it is the site where protein and lipid derive from endocytic vesicles (clathrin-coated vesicles and caveolae). glycosylation occurs; and it provides membrane platforms to which Once internalized, endocytic vesicles shed their coat of adaptin and signalling and sorting proteins bind. clathrin, and fuse to form an early endosome, where the receptor Ultrastructurally, the Golgi apparatus (Fig. 1.5A) displays a contin- molecules release their bound ligands. Membrane and receptors from uous ribbon-like structure consisting of a stack of several flattened the early endosomes can be recycled to the cell surface as exocytic membranous cisternae, together with clusters of vesicles surrounding vesicles. its surfaces. Cisternae differ in enzymatic content and activity. Small Clathrin-dependent endocytosis occurs at specialized patches of transport vesicles from the rough endoplasmic reticulum are received plasma membrane called coated pits; this mechanism is also used to
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at one face of the Golgi stack, the convex cis-face (entry or forming internalize ligands bound to surface receptor molecules and is also surface). Here, they deliver their contents to the first cisterna in the termed receptor-mediated endocytosis. Caveolae (little caves) are struc- series by membrane fusion. From the edges of this cisterna, the protein turally distinct pinocytotic vesicles most widely used by endothelial and is transported to the next cisterna by vesicular budding and then smooth muscle cells, when they are involved in transcytosis, signal fusion, and this process is repeated across medial cisternae until the transduction and possibly other functions. In addition to late endo- final cisterna at the concave trans-face (exit or condensing surface) is somes, lysosomes can also fuse with phagosomes, autophagosomes reached. Here, larger vesicles are formed for delivery to other parts of and plasma membrane patches for membrane repair. Lysosomal hydro- the cell. lases process or degrade exogenous materials (phagocytosis or hetero-
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The cis-Golgi and trans-Golgi membranous networks form an inte- phagy) as well as endogenous material (autophagy). Phagocytosis gral part of the Golgi apparatus. The cis-Golgi network is a region of consists of the cellular uptake of invading pathogens, apoptotic cells complex membranous channels interposed between the rough endo- and other foreign material by specialized cells. Lysosomes are numerous plasmic reticulum and the Golgi cis-face, which receives and transmits in actively phagocytic cells, e.g. macrophages and neutrophil granulo- vesicles in both directions. Its function is to select appropriate proteins cytes, in which lysosomes are responsible for destroying phagocytosed synthesized on the rough endoplasmic reticulum for delivery by vesicles particles, e.g. bacteria. In these cells, the phagosome, a vesicle poten- to the Golgi stack, while inappropriate proteins are shuttled back to the tially containing a pathogenic microorganism, may fuse with several rough endoplasmic reticulum. lysosomes.
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The trans-Golgi network, at the other side of the Golgi stack, is also Autophagy involves the degradation and recycling within an a region of interconnected membrane channels engaged in protein autophagosome of cytoplasmic components that are no longer needed, sorting. Here, modified proteins processed in the Golgi cisternae are including organelles. The assembly of the autophagosome involves packaged selectively into vesicles and dispatched to different parts of several proteins, including autophagy-related (Atg) proteins, as well as the cell. The packaging depends on the detection, by the trans-Golgi Hsc70 chaperone, that translocate the substrate into the lysosome (Boya network, of particular amino-acid signal sequences, leading to their et al 2013). Autophagosomes sequester cytoplasmic components and enclosure in membranes of appropriate composition that will further then fuse with lysosomes without the participation of a late endosome. modify their contents, e.g. by extracting water to concentrate them The 26S proteasome (see below) is also involved in cellular degradation
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(vesicles entering the exocytosis pathway) or by pumping in protons to but autophagy refers specifically to a lysosomal degradation–recycling acidify their contents (lysosomes destined for the intracellular sorting pathway. Autophagosomes are seen in response to starvation and cell pathway). growth. Within the Golgi stack proper, proteins undergo a series of sequen- Late endosomes receive lysosomal enzymes from primary lysosomes tial chemical modifications by Golgi resident enzymes synthesized derived from the Golgi apparatus after late endosome–lysosome mem- in the rough endoplasmic reticulum. These include: glycosylation brane tethering and fusion followed by diffusion of lysosomal contents (changes in glycosyl groups, e.g. removal of mannose, addition of into the endosomal lumen. The pH inside the fused hybrid organelle, N-acetylglucosamine and sialic acid); sulphation (addition of sulphate now a secondary lysosome, is low (about 5.0) and this activates lyso- groups to glycosaminoglycans); and phosphorylation (addition of
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somal acid hydrolases to degrade the endosomal contents. The products phosphate groups). Some modifications serve as signals to direct pro- of hydrolysis either are passed through the membrane into the cytosol, teins and lipids to their final destination within cells, including lyso- or may be retained in the secondary lysosome. Secondary lysosomes somes and plasma membrane. Lipids formed in the endoplasmic may grow considerably in size by vesicle fusion to form multivesicular reticulum are also routed for incorporation into vesicles. bodies, and the enzyme concentration may increase greatly to form large lysosomes (Fig. 1.5B). Exocytic (secretory) pathway Secreted proteins, lipids, glycoproteins, small molecules such as amines Lysosomes and other cellular products destined for export from the cell are trans- ported to the plasma membrane in small vesicles released from the Lysosomes are membrane-bound organelles 80–800 nm in diameter, trans-face of the Golgi apparatus. This pathway either is constitutive, in often with complex inclusions of material undergoing hydrolysis (sec-
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which transport and secretion occur more or less continuously, as with ondary lysosomes). Two classes of proteins participate in lysosomal immunoglobulins produced by plasma cells, or it is regulated by exter- function: soluble acid hydrolases and integral lysosomal membrane nal signals, as in the control of salivary secretion by autonomic neural proteins. Each of the 50 known acid hydrolases (including proteases, stimulation. In regulated secretion, the secretory product is stored tem- lipases, carbohydrases, esterases and nucleases) degrades a specific sub- porarily in membrane-bound secretory granules or vesicles. Exocytosis strate. There are about 25 lysosomal membrane proteins participating is achieved by fusion of the secretory vesicular membrane with the in the acidification of the lysosomal lumen, protein import from the plasma membrane and release of the vesicle contents into the extracel- cytosol, membrane fusion and transport of degradation products to the lular domain. In polarized cells, e.g. most epithelia, exocytosis occurs cytoplasm. Material that has been hydrolysed within secondary lyso-
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at the apical plasma membrane. Glandular epithelial cells secrete into somes may be completely degraded to soluble products, e.g. amino a duct lumen, as in the pancreas, or on to a free surface, such as the acids, which are recycled through metabolic pathways. However, degra- lining of the stomach. In hepatocytes, bile is secreted across a very small dation is usually incomplete and some debris remains. A debris-laden area of plasma membrane forming the wall of the bile canaliculus. This vesicle is called a residual body or tertiary lysosome (see Fig. 1.5B), and region is defined as the apical plasma membrane and is the site of may be passed to the cell surface, where it is ejected by exocytosis; exocrine secretion, whereas secretion of hepatocyte plasma proteins alternatively, it may persist inside the cell as an inert residual body. into the blood stream is targeted to the basolateral surfaces facing the Considerable numbers of residual bodies can accumulate in long-lived sinusoids. Packaging of different secretory products into appropriate cells, often fusing to form larger dense vacuoles with complex lamellar
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vesicles takes place in the trans-Golgi network. Delivery of secretory inclusions. As their contents are often darkly pigmented, this may vesicles to their correct plasma membrane domains is achieved by change the colour of the tissue; e.g. in neurones, the end-product of sorting sequences in the cytoplasmic tails of vesicular membrane lysosomal digestion, lipofuscin (neuromelanin or senility pigment), proteins. gives ageing brains a brownish-yellow colouration. Lysosomal enzymes
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Basic structure and function of cells 8.e1 1 RETPaHC Carrier vesicles in transit from the endoplasmic reticulum to the Golgi apparatus (anterograde transport) are coated by coat protein complex II (COPII), whereas COPI-containing vesicles function in the retrograde transport route from the Golgi apparatus (reviewed in Spang (2013)). The membranes contain specific signal proteins that may allocate them to microtubule-based transport pathways and allow them to dock with appropriate targets elsewhere in the cell, e.g. the plasma mem- brane in the case of secretory vesicles. Vesicle formation and budding at the trans-Golgi network involves the addition of clathrin on their external surface, to form coated pits. Specialized cells of the immune system, called antigen-presenting cells, degrade protein molecules, called antigens, transported by the endocytic pathway for lysosomal breakdown, and expose their frag- ments to the cell exterior to elicit an immune response mediated ini- tially by helper T cells.
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Cell structure 9 1 RETPaHC may also be secreted – often as part of a process to alter the extracellular A matrix, as in osteoclast-mediated erosion during bone resorption. For further reading on lysosome biogenesis, see Saftig and Klumperman (2009). lysosomal dysfunction Lysosomal storage diseases (LSDs) are a consequence of lysosomal dysfunction. Approximately 60 different types of LSD have been identi- fied on the basis of the type of material accumulated in cells (such as mucopolysaccharides, sphingolipids, glycoproteins, glycogen and lipo- fuscins). LSDs are characterized by severe neurodegeneration, mental decline, and cognitive and behavioural abnormalities. Autophagy impairment caused by defective lysosome–autophagosome coupling triggers a pathogenic cascade by the accumulation of substrates that contribute to neurodegenerative disorders including Parkinson’s dis- ease, Alzheimer’s disease, Huntington’s disease and several tau-opathies. Many lysosomal storage diseases are known, e.g. Tay–Sachs disease
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(GM2 gangliosidosis), in which a faulty β-hexosaminidase A leads to the accumulation of the glycosphingolipid GM2 ganglioside in neu- rones, causing death during childhood. In Danon disease, a vacuolar skeletal myopathy and cardiomyopathy with neurodegeneration in hemizygous males, lysosomes fail to fuse with autophagosomes because of a mutation of the lysosomal membrane protein LAMP-2 (lysosomal B associated membrane protein-2). 26S proteasome Outer membrane A protein can be degraded by different mechanisms, depending on the cell type and different pathological conditions. Furthermore, the same substrate can engage different proteolytic pathways (Park and Inner membrane Cuervo 2013). Three major protein degradation mechanisms operate in eukaryotic cells to dispose of non-functional cellular proteins: Cristae (folds) the autophagosome–lysosomal pathway (see above); the apoptotic procaspase–caspase pathway (see below); and the ubiquitinated Elementary particles protein–26S proteasome pathway. The 26S proteasome is a multicata-
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lytic protease found in the cytosol and the nucleus that degrades intra- cellular proteins conjugated to a polyubiquitin chain by an enzymatic cascade. The 26S proteasome consists of several subunits arranged into two 19S polar caps, where protein recognition and adenosine 5′- triphosphate (ATP)-dependent target processing occur, flanking a 20S central barrel-shaped structure with an inner proteolytic chamber (Tomko and Hochstrasser 2013). The 26S proteasome participates in the removal of misfolded or abnormally assembled proteins, the deg- radation of cyclins involved in the control of the cell cycle, the process- ing and degradation of transcription regulators, cellular-mediated Fig . 1 .6 A, Mitochondria in human cardiac muscle . The folded cristae immune responses, and cell cycle arrest and apoptosis. (arrows) project into the matrix from the inner mitochondrial membrane . B, The location of the elementary particles that couple oxidation and Peroxisomes phosphorylation reactions . (A, Courtesy of Dr Bart Wagner,
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Peroxisomes are small (0.2–1 µm in diameter) membrane-bound Histopathology Department, Sheffield Teaching Hospitals, UK .) organelles present in most mammalian cells. They contain more than 50 enzymes responsible for multiple catabolic and synthetic biochemi- cal pathways, in particular the β-oxidation of very-long-chain fatty Mitochondria acids (>C22) and the metabolism of hydrogen peroxide (hence the In the electron microscope, mitochondria usually appear as round or name peroxisome). Peroxisomes derive from the endoplasmic reticu- elliptical bodies 0.5–2.0 µm long (Fig. 1.6), consisting of an outer lum through the transfer of proteins from the endoplasmic reticulum mitochondrial membrane; an inner mitochrondrial membrane, sepa- to peroxisomes by vesicles that bud from specialized sites of the endo- rated from the outer membrane by an intermembrane space; cristae, plasmic reticulum and by a lipid non-vesicular pathway. All matrix infoldings of the inner membrane that harbour ATP synthase to gener-
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proteins and some peroxisomal membrane proteins are synthesized by ate ATP; and the mitochondrial matrix, a space enclosed by the inner cytosolic ribosomes and contain a peroxisome targeting signal that membrane and numerous cristae. The permeability of the two mito- enables them to be imported by proteins called peroxins (Braverman chondrial membranes differs considerably: the outer membrane is et al 2013, Theodoulou et al 2013). Mature peroxisomes divide by freely permeable to many substances because of the presence of large small daughter peroxisomes pinching off from a large parental non-specific channels formed by proteins (porins), whereas the inner peroxisome. membrane is permeable to only a narrow range of molecules. The pres- Peroxisomes often contain crystalline inclusions composed mainly ence of cardiolipin, a phospholipid, in the inner membrane may con- of high concentrations of the enzyme urate oxidase. Oxidases use tribute to this relative impermeability. molecular oxygen to oxidize specific organic substrates (such as L-amino Mitochondria are the principal source of chemical energy in most
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acids, D-amino acids, urate, xanthine and very-long-chain fatty acids) cells. Mitochondria are the site of the citric acid (Krebs’) cycle and the and produce hydrogen peroxide that is detoxified (degraded) by per- electron transport (cytochrome) pathway by which complex organic oxisomal catalase. Peroxisomes are particularly numerous in hepato- molecules are finally oxidized to carbon dioxide and water. This process cytes. Peroxisomes are important in the oxidative detoxification of provides the energy to drive the production of ATP from adenosine various substances taken into or produced within cells, including diphosphate (ADP) and inorganic phosphate (oxidative phosphoryla- ethanol. Peroxin mutation is a characteristic feature of Zellweger syn- tion). The various enzymes of the citric acid cycle are located in the drome (craniofacial dysmorphism and malformations of brain, liver, mitochondrial matrix, whereas those of the cytochrome system and eye and kidney; cerebrohepatorenal syndrome). Neonatal leukodystro- oxidative phosphorylation are localized chiefly in the inner mitochon-
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phy is an X-linked peroxisomal disease affecting mostly males, caused drial membrane. by deficiency in β-oxidation of very-long-chain fatty acids. The build-up The intermembrane space houses cytochrome c, a molecule involved of very-long-chain fatty acids in the nervous system and suprarenal in activation of apoptosis. glands determines progressive deterioration of brain function and The number of mitochondria in a particular cell reflects its general suprarenal insufficiency (Addison’s disease). For further reading, see energy requirements; e.g. in hepatocytes there may be as many as 2000, Braverman et al (2013). whereas in resting lymphocytes there are usually very few. Mature
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Basic structure and function of cells 9.e1 1 RETPaHC The transcription factor EB (TFEB) is responsible for regulating lyso- somal biogenesis and function, lysosome-to-nucleus signalling and lipid catabolism (for further reading, see Settembre et al (2013)). If any of the actions of lysosomal hydrolases, of the lysosome acidification mechanism or of lysosomal membrane proteins fails, the degradation and recycling of extracellular substrates delivered to lysosomes by the late endosome and the degradation and recycling of intracellular sub- strates by autophagy lead to progressive lysosomal dysfunction in several tissues and organs. Experimentally, TFEB activation can reduce the accumulation of the pathogenic protein in a cellular model of Huntington’s disease (a neurodegenerative genetic disorder that affects muscle coordination) and improves the Parkinson’s disease phenotype in a murine model. Cristae are abundant in mitochondria seen in cardiac muscle cells and in steroid-producing cells (in the suprarenal cortex, corpus luteum and Leydig cells). The protein steroidogenic acute regulatory protein (StAR) regulates the synthesis of steroids by transporting
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cholesterol across the outer mitochondrial membrane. A mutation in the gene encoding StAR causes defective suprarenal and gonadal steroidogenesis.
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BaSIC STRuCTuRE aNd fuNCTION Of CEllS 10 1 NOITCES erythrocytes lack mitochondria altogether. Cells with few mitochondria ent and its electronic charge, and the potential difference across the generally rely largely on glycolysis for their energy supplies. These membrane. These factors combine to produce an electrochemical gradi- include some very active cells, e.g. fast twitch skeletal muscle fibres, ent, which governs ion flux. Channel proteins are utilized most effec- which are able to work rapidly but for only a limited duration. Mito- tively by the excitable plasma membranes of nerve cells, where the chondria appear in the light microscope as long, thin structures in the resting membrane potential can change transiently from about −80 mV cytoplasm of most cells, particularly those with a high metabolic rate, (negative inside the cell) to +40 mV (positive inside the cell) when e.g. secretory cells in exocrine glands. In living cells, mitochondria stimulated by a neurotransmitter (as a result of the opening and sub-
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constantly change shape and intracellular position; they multiply by sequent closure of channels selectively permeable to sodium and growth and fission, and may undergo fusion. potassium). The mitochondrial matrix is an aqueous environment. It contains a Carrier proteins bind their specific solutes, such as amino acids, and variety of enzymes, and strands of mitochondrial DNA with the capacity transport them across the membrane through a series of conforma- for transcription and translation of a unique set of mitochondrial genes tional changes. This latter process is slower than ion transport through (mitochondrial mRNAs and transfer RNAs, mitochondrial ribosomes membrane channels. Transport by carrier proteins can occur either pas- with rRNAs). The DNA forms a closed loop, about 5 µm across; several sively by simple diffusion, or actively against the electrochemical gradi- identical copies are present in each mitochondrion. The ratio between ent of the solute. Active transport must therefore be coupled to a source its bases differs from that of nuclear DNA, and the RNA sequences also of energy, such as ATP generation, or energy released by the coordinate
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differ in the precise genetic code used in protein synthesis. At least 13 movement of an ion down its electrochemical gradient. Linked trans- respiratory chain enzymes of the matrix and inner membrane are port can be in the same direction as the solute, in which case the carrier encoded by the small number of genes along the mitochondrial DNA. protein is described as a symporter, or in the opposite direction, when The great majority of mitochondrial proteins are encoded by nuclear the carrier acts as an antiporter. genes and made in the cytosol, then inserted through special channels in the mitochondrial membranes to reach their destinations. Their Translocation of proteins across membrane lipids are synthesized in the endoplasmic reticulum. intracellular membranes It has been shown that mitochondria are of maternal origin because Proteins are generally synthesized on ribosomes in the cytosol or on the mitochondria of spermatozoa are not generally incorporated the rough endoplasmic reticulum. A few are made on mitochondrial into the ovum at fertilization. Thus mitochondria (and mitochondrial ribosomes. Once synthesized, many proteins remain in the cytosol,
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genetic variations and mutations) are passed only through the where they carry out their functions. Others, such as integral membrane female line. proteins or proteins for secretion, are translocated across intracellular Mitochondria are distributed within a cell according to regional membranes for post-translational modification and targeting to their energy requirements, e.g. near the bases of cilia in ciliated epithelia, in destinations. This is achieved by the signal sequence, an addressing the basal domain of the cells of proximal convoluted tubules in the system contained within the protein sequence of amino acids, which is renal cortex (where considerable active transport occurs) and around recognized by receptors or translocators in the appropriate membrane. the proximal segment, called middle piece, of the flagellum in sperma- Proteins are thus sorted by their signal sequence (or set of sequences tozoa. They may be involved with tissue-specific metabolic reactions, that become spatially grouped as a signal patch when the protein folds e.g. various urea-forming enzymes are found in liver cell mitochondria. into its tertiary configuration), so that they are recognized by and enter
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Moreover, a number of genetic diseases of mitochondria affect particu- the correct intracellular membrane compartment. lar tissues exclusively, e.g. mitochondrial myopathies (skeletal muscle) and mitochondrial neuropathies (nervous tissue). For further informa- Cell signalling tion on mitochondrial genetics and disorders, see Chinnery and Hudson (2013). Cellular systems in the body communicate with each other to coordi- Cytosolic inclusions nate and integrate their functions. This occurs through a variety of The aqueous cytosol surrounds the membranous organelles described processes known collectively as cell signalling, in which a signalling above. It also contains various non-membranous inclusions, including molecule produced by one cell is detected by another, almost always by free ribosomes, components of the cytoskeleton, and other inclusions, means of a specific receptor protein molecule. The recipient cell trans- such as storage granules (e.g. glycogen), pigments (such as lipofuscin duces the signal, which it most often detects at the plasma membrane, granules, remnants of the lipid oxidative mechanism seen in the supra- into intracellular chemical messages that change cell behaviour.
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renal cortex) and lipid droplets. The signal may act over a long distance, e.g. endocrine signalling through the release of hormones into the blood stream, or neuronal lipid droplets synaptic signalling via electrical impulse transmission along axons Lipid droplets are spherical bodies of various sizes found within many and subsequent release of chemical transmitters of the signal at syn- cells, but are especially prominent in the adipocytes (fat cells) of apses or neuromuscular junctions. A specialized variation of endocrine adipose connective tissue. They do not belong to the Golgi-related vacu- signalling (neurocrine or neuroendocrine signalling) occurs when neu- olar system of the cell. They are not membrane-bound, but are droplets rones or paraneurones (e.g. chromaffin cells of the suprarenal medulla) of lipid suspended in the cytosol and surrounded by perilipin proteins, secrete a hormone into interstitial fluid and the blood stream. which regulate lipid storage and lipolysis. See Smith and Ordovás Alternatively, signalling may occur at short range through a paracrine
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(2012) for further reading on obesity and perilipins. In cells specialized mechanism, in which cells of one type release molecules into the inter- for lipid storage, the vacuoles reach 80 µm or more in diameter. They stitial fluid of the local environment, to be detected by nearby cells of function as stores of chemical energy, thermal insulators and mechani- a different type that express the specific receptor protein. Neurocrine cal shock absorbers in adipocytes. In many cells, they may represent cell signalling uses chemical messengers found also in the central end-products of other metabolic pathways, e.g. in steroid-synthesizing nervous system, which may act in a paracrine manner via interstitial cells, where they are a prominent feature of the cytoplasm. They may fluid or reach more distant target tissues via the blood stream. Cells also be secreted, as in the alveolar epithelium of the lactating breast. may generate and respond to the same signal. This is autocrine signal- ling, a phenomenon that reinforces the coordinated activities of a group Transport across cell membranes of like cells, which respond together to a high concentration of a local
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Lipid bilayers are increasingly impermeable to molecules as they signalling molecule. The most extreme form of short-distance signalling increase in size or hydrophobicity. Transport mechanisms are therefore is contact-dependent (juxtacrine) signalling, where one cell responds to required to carry essential polar molecules, including ions, nutrients, transmembrane proteins of an adjacent cell that bind to surface recep- nucleotides and metabolites of various kinds, across the plasma mem- tors in the responding cell membrane. Contact-dependent signalling brane and into or out of membrane-bound intracellular compartments. also includes cellular responses to integrins on the cell surface binding Transport is facilitated by a variety of membrane transport proteins, to elements of the extracellular matrix. Juxtacrine signalling is impor- each with specificity for a particular class of molecule, e.g. sugars. Trans- tant during development and in immune responses. These different port proteins fall mainly into two major classes: channel proteins and types of intercellular signalling mechanism are illustrated in Figure 1.7. carrier proteins. For further reading on cell signalling pathways, see Kierszenbaum and Channel proteins form aqueous pores in the membrane, which open Tres (2012).
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and close under the regulation of intracellular signals, e.g. G-proteins, Signalling molecules and their receptors to allow the flux of solutes (usually inorganic ions) of specific size and charge. Transport through ion channels is always passive, and ion flow The majority of signalling molecules (ligands) are hydrophilic and so through an open channel depends only on the ion concentration gradi- cannot cross the plasma membrane of a recipient cell to effect changes
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4 1 NOITCES CHAPTER 1 Basic structure and function of cells Epithelial cells rarely operate independently of each other and com- CELL STRUCTURE monly form aggregates by adhesion, often assisted by specialized inter- cellular junctions. They may also communicate with each other either GENERAL CHARACTERISTICS OF CELLS by generating and detecting molecular signals that diffuse across inter- cellular spaces, or more rapidly by generating interactions between The shapes of mammalian cells vary widely depending on their interac- membrane-bound signalling molecules. Cohesive groups of cells con- tions with each other, their extracellular environment and internal stitute tissues, and more complex assemblies of tissues form functional structures. Their surfaces are often highly folded when absorptive or systems or organs. transport functions take place across their boundaries. Cell size is Most cells are between 5 and 50 µm in diameter: e.g. resting lym- limited by rates of diffusion, either that of material entering or leaving phocytes are 6 µm across, red blood cells 7.5 µm and columnar epithe-
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cells, or that of diffusion within them. Movement of macromolecules lial cells 20 µm tall and 10 µm wide (all measurements are approximate). can be much accelerated and also directed by processes of active trans- Some cells are much larger than this: e.g. megakaryocytes of the bone port across the plasma membrane and by transport mechanisms within marrow and osteoclasts of the remodelling bone are more than 200 µm the cell. According to the location of absorptive or transport functions, in diameter. Neurones and skeletal muscle cells have relatively extended apical microvilli (Fig. 1.1) or basolateral infoldings create a large shapes, some of the former being over 1 m in length. surface area for transport or diffusion. Motility is a characteristic of most cells, in the form of movements of cytoplasm or specific organelles from one part of the cell to another. CELLULAR ORGANIZATION It also includes: the extension of parts of the cell surface such as pseu- dopodia, lamellipodia, filopodia and microvilli; locomotion of entire Each cell is contained within its limiting plasma membrane, which
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cells, as in the amoeboid migration of tissue macrophages; the beating encloses the cytoplasm. All cells, except mature red blood cells, also of flagella or cilia to move the cell (e.g. in spermatozoa) or fluids overly- contain a nucleus that is surrounded by a nuclear membrane or enve- ing it (e.g. in respiratory epithelium); cell division; and muscle contrac- lope (see Fig. 1.1; Fig. 1.2). The nucleus includes: the genome of the tion. Cell movements are also involved in the uptake of materials from cell contained within the chromosomes; the nucleolus; and other sub- their environment (endocytosis, phagocytosis) and the passage of large nuclear structures. The cytoplasm contains cytomembranes and several molecular complexes out of cells (exocytosis, secretion). membrane-bound structures, called organelles, which form separate Surface projections (cilia, microvilli) Surface invagination Actin filaments Vesicle Mitochondrion Cell junctions Plasma membrane Desmosome Peroxisomes Cytosol Nuclear pore Intermediate
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filaments Nuclear envelope Smooth endoplasmic Nucleus reticulum Nucleolus Ribosome Rough endoplasmic reticulum Microtubules Golgi apparatus Centriole pair Lysosomes Cell surface folds Fig . 1 .1 The main structural components and internal organization of a generalized cell .
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Cell structure 5 1 RETPaHC CC MMVV AAPPMM AAJJCC Receptor Transmembrane protein pore complex of proteins Carbohydrate residues External (extracellular) surface MM MM CCyy LLPPMM Internal (intracellular) surface NN Lipid bilayer appearance in electron microscope Intrinsic membrane protein Extrinsic Transmembrane protein protein Transport Non-polar tail or diffusion of phospholipid channel Cytoskeletal Polar end of element EENN phospholipid Fig . 1 .3 The molecular organization of the plasma membrane, according to the fluid mosaic model of membrane structure . Intrinsic or integral membrane proteins include diffusion or transport channel complexes, receptor proteins and adhesion molecules . These may span the thickness of the membrane (transmembrane proteins) and can have both extracellular and cytoplasmic domains . Transmembrane proteins have hydrophobic zones, which cross the phospholipid bilayer and allow the Fig . 1 .2 The structural organization and some principal organelles of a
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protein to ‘float’ in the plane of the membrane . Some proteins are typical cell . This example is a ciliated columnar epithelial cell from human restricted in their freedom of movement where their cytoplasmic domains nasal mucosa . The central cell, which occupies most of the field of are tethered to the cytoskeleton . view, is closely apposed to its neighbours along their lateral plasma membranes . Within the apical junctional complex, these membranes form a tightly sealed zone (tight junction) that isolates underlying tissues from, charides and polysaccharides are bound either to proteins (glycopro- in this instance, the nasal cavity . Abbreviations: AJC, apical junctional teins) or to lipids (glycolipids), and project mainly into the extracellular complex; APM, apical plasma membrane; C, cilia; Cy, cytoplasm; EN, domain (Fig. 1.3). euchromatic nucleus; LPM, lateral plasma membrane; M, mitochondria; In the electron microscope, membranes fixed and contrasted by MV, microvilli; N, nucleolus . (Courtesy of Dr Bart Wagner, Histopathology
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heavy metals such as osmium tetroxide appear in section as two densely Department, Sheffield Teaching Hospitals, UK .) stained layers separated by an electron-translucent zone – the classic unit membrane. The total thickness of each layer is about 7.5 nm. The and distinct compartments within the cytoplasm. Cytomembranes overall thickness of the plasma membrane is typically 15 nm. Freeze- include the rough and smooth endoplasmic reticulum and Golgi appa- fracture cleavage planes usually pass along the hydrophobic portion of ratus, as well as vesicles derived from them. Organelles include lyso- the bilayer, where the hydrophobic tails of phospholipids meet, and somes, peroxisomes and mitochondria. The nucleus and mitochondria split the bilayer into two leaflets. Each cleaved leaflet has a surface and are enclosed by a double-membrane system; lysosomes and peroxi- a face. The surface of each leaflet faces either the extracellular surface somes have a single bounding membrane. There are also non- (ES) or the intracellular or protoplasmic (cytoplasmic) surface (PS). The
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membranous structures, called inclusions, which lie free in the cytosolic extracellular face (EF) and protoplasmic face (PF) of each leaflet are compartment. They include lipid droplets, glycogen aggregates and pig- artificially produced during membrane splitting. This technique has ments (e.g. lipofuscin). In addition, ribosomes and several filamentous also demonstrated intramembranous particles embedded in the lipid protein networks, known collectively as the cytoskeleton, are found in bilayer; in most cases, these represent large transmembrane protein the cytosol. The cytoskeleton determines general cell shape and sup- molecules or complexes of proteins. Intramembranous particles are ports specialized extensions of the cell surface (microvilli, cilia, flag- distributed asymmetrically between the two half-layers, usually adher- ella). It is involved in the assembly of specific structures (e.g. centrioles) ing more to one half of the bilayer than to the other. In plasma mem- and controls cargo transport in the cytoplasm. The cytosol contains branes, the intracellular leaflet carries most particles, seen on its face
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many soluble proteins, ions and metabolites. (the PF). Where they have been identified, clusters of particles usually represent channels for the transmembrane passage of ions or molecules Plasma membrane between adjacent cells (gap junctions). Biophysical measurements show the lipid bilayer to be highly fluid, Cells are enclosed by a distinct plasma membrane, which shares fea- allowing diffusion in the plane of the membrane. Thus proteins are able tures with the cytomembrane system that compartmentalizes the cyto- to move freely in such planes unless anchored from within the cell. plasm and surrounds the nucleus. All membranes are composed of Membranes in general, and the plasma membrane in particular, form lipids (mainly phospholipids, cholesterol and glycolipids) and pro- boundaries selectively limiting diffusion and creating physiologically teins, in approximately equal ratios. Plasma membrane lipids form a distinct compartments. Lipid bilayers are impermeable to hydrophilic lipid bilayer, a layer two molecules thick. The hydrophobic ends of each solutes and ions, and so membranes actively control the passage of ions
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lipid molecule face the interior of the membrane and the hydrophilic and small organic molecules such as nutrients, through the activity of ends face outwards. Most proteins are embedded within, or float in, the membrane transport proteins. However, lipid-soluble substances can lipid bilayer as a fluid mosaic. Some proteins, because of extensive pass directly through the membrane so that, for example, steroid hor- hydrophobic regions of their polypeptide chains, span the entire width mones enter the cytoplasm freely. Their receptor proteins are either of the membrane (transmembrane proteins), whereas others are only cytosolic or nuclear, rather than being located on the cell surface. superficially attached to the bilayer by lipid groups. Both are integral Plasma membranes are able to generate electrochemical gradients (intrinsic) membrane proteins, as distinct from peripheral (extrinsic) and potential differences by selective ion transport, and actively take up membrane proteins, which are membrane-bound only through their or export small molecules by energy-dependent processes. They also association with other proteins. Carbohydrates in the form of oligosac- provide surfaces for the attachment of enzymes, sites for the receptors
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Basic structure and function of cells 5.e1 1 RETPaHC Combinations of biochemical, biophysical and biological tech- niques have revealed that lipids are not homogenously distributed in membranes, but that some are organized into microdomains in the bilayer, called ‘detergent-resistant membranes’ or lipid ‘rafts’, rich in sphingomyelin and cholesterol. The ability of select subsets of proteins to partition into different lipid microdomains has profound effects on their function, e.g. in T-cell receptor and cell–cell signalling. The highly organized environment of the domains provides a signalling, trafficking and membrane fusion environment.
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BaSIC STRuCTuRE aNd fuNCTION Of CEllS 6 1 NOITCES of external signals, including hormones and other ligands, and sites for abundant proteins; SER is abundant in steroid-producing cells and the recognition and attachment of other cells. Internally, plasma mem- muscle cells. A variant of the endoplasmic reticulum in muscle cells is branes can act as points of attachment for intracellular structures, in the sarcoplasmic reticulum, involved in calcium storage and release for particular those concerned with cell motility and other cytoskeletal muscle contraction. For further reading on the endoplasmic reticulum, functions. Cell membranes are synthesized by the rough endoplasmic see Bravo et al (2013). reticulum in conjunction with the Golgi apparatus. Smooth endoplasmic reticulum Cell coat (glycocalyx) The smooth endoplasmic reticulum (see Fig. 1.4) is associated with The external surface of a plasma membrane differs structurally from carbohydrate metabolism and many other metabolic processes, includ- internal membranes in that it possesses an external, fuzzy, carbohydrate- ing detoxification and synthesis of lipids, cholesterol and steroids. The
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rich coat, the glycocalyx. The cell coat forms an integral part of the membranes of the smooth endoplasmic reticulum serve as surfaces for plasma membrane, projecting as a diffusely filamentous layer 2–20 nm the attachment of many enzyme systems, e.g. the enzyme cytochrome or more from the lipoprotein surface. The cell coat is composed of the P450, which is involved in important detoxification mechanisms and carbohydrate portions of glycoproteins and glycolipids embedded in is thus accessible to its substrates, which are generally lipophilic. The the plasma membrane (see Fig. 1.3). membranes also cooperate with the rough endoplasmic reticulum The precise composition of the glycocalyx varies with cell type; many and the Golgi apparatus to synthesize new membranes; the protein, tissue- and cell type-specific antigens are located in the coat, including carbohydrate and lipid components are added in different structural the major histocompatibility complex of the immune system and, in compartments. The smooth endoplasmic reticulum in hepatocytes con-
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the case of erythrocytes, blood group antigens. Therefore, the glycocalyx tains the enzyme glucose-6-phosphatase, which converts glucose-6- plays a significant role in organ transplant compatibility. The glycocalyx phosphate to glucose, a step in gluconeogenesis. found on apical microvilli of enterocytes, the cells forming the lining epithelium of the intestine, consists of enzymes involved in the diges- Rough endoplasmic reticulum tive process. Intestinal microvilli are cylindrical projections (1–2 µm The rough endoplasmic reticulum is a site of protein synthesis; its long and about 0.1 µm in diameter) forming a closely packed layer cytosolic surface is studded with ribosomes (Fig. 1.5E). Ribosomes only called the brush border that increases the absorptive function of bind to the endoplasmic reticulum when proteins targeted for secretion enterocytes. begin to be synthesized. Most proteins pass through its membranes and accumulate within its cisternae, although some integral membrane pro- Cytoplasm teins, e.g. plasma membrane receptors, are inserted into the rough
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endoplasmic reticulum membrane, where they remain. After passage Compartments and functional organization from the rough endoplasmic reticulum, proteins remain in membrane- bound cytoplasmic organelles such as lysosomes, become incorporated The cytoplasm consists of the cytosol, a gel-like material enclosed by into new plasma membrane, or are secreted by the cell. Some carbohy- the cell or plasma membrane. The cytosol is made up of colloidal pro- drates are also synthesized by enzymes within the cavities of the rough teins such as enzymes, carbohydrates and small protein molecules, endoplasmic reticulum and may be attached to newly formed protein together with ribosomes and ribonucleic acids. The cytoplasm contains (glycosylation). Vesicles are budded off from the rough endoplasmic two cytomembrane systems, the endoplasmic reticulum and Golgi reticulum for transport to the Golgi as part of the protein-targeting apparatus, as well as membrane-bound organelles (lysosomes, peroxi- mechanism of the cell. somes and mitochondria), membrane-free inclusions (lipid droplets,
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glycogen and pigments) and the cytoskeleton. The nuclear contents, Ribosomes, polyribosomes the nucleoplasm, are separated from the cytoplasm by the nuclear and protein synthesis envelope. Ribosomes are macromolecular machines that catalyse the synthesis of Endoplasmic reticulum proteins from amino acids; synthesis and assembly into subunits takes The endoplasmic reticulum is a system of interconnecting membrane- place in the nucleolus and includes the association of ribosomal RNA lined channels within the cytoplasm (Fig. 1.4). These channels take (rRNA) with ribosomal proteins translocated from their site of synthesis various forms, including cisternae (flattened sacs), tubules and vesicles. in the cytoplasm. The individual subunits are then transported into the The membranes divide the cytoplasm into two major compartments. cytoplasm, where they remain separate from each other when not The intramembranous compartment, or cisternal space, is where secre- actively synthesizing proteins. Ribosomes are granules approximately tory products are stored or transported to the Golgi complex and cell 25 nm in diameter, composed of rRNA molecules and proteins assem-
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exterior. The cisternal space is continuous with the perinuclear space. bled into two unequal subunits. The subunits can be separated by their Structurally, the channel system can be divided into rough or granu- sedimentation coefficients (S) in an ultracentrifuge into larger 60S and lar endoplasmic reticulum (RER), which has ribosomes attached to its smaller 40S components. These are associated with 73 different pro- outer, cytosolic surface, and smooth or agranular endoplasmic reticu- teins (40 in the large subunit and 33 in the small), which have structural lum (SER), which lacks ribosomes. The functions of the endoplasmic and enzymatic functions. Three small, highly convoluted rRNA strands reticulum vary greatly and include: the synthesis, folding and transport (28S, 5.8S and 5S) make up the large subunit, and one strand (18S) is of proteins; synthesis and transport of phospholipids and steroids; and in the small subunit.
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storage of calcium within the cisternal space and regulated release into A typical cell contains millions of ribosomes. They may form groups the cytoplasm. In general, RER is well developed in cells that produce (polyribosomes or polysomes) attached to messenger RNA (mRNA), which they translate during protein synthesis for use outside the system of membrane compartments, e.g. enzymes of the cytosol and cytoskel- etal proteins. Some of the cytosolic products include proteins that can be inserted directly into (or through) membranes of selected organelles, such as mitochondria and peroxisomes. Ribosomes may be attached to the membranes of the rough endoplasmic reticulum (see Fig. 1.5E). In a mature polyribosome, all the attachment sites of the mRNA are occupied as ribosomes move along it, synthesizing protein according to its nucleotide sequence. Consequently, the number and spacing of ribosomes in a polyribosome indicate the length of the mRNA mole- cule and hence the size of the protein being made. The two subunits have separate roles in protein synthesis. The 40S subunit is the site of
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attachment and translation of mRNA. The 60S subunit is responsible for the release of the new protein and, where appropriate, attachment to the endoplasmic reticulum via an intermediate docking protein that directs the newly synthesized protein through the membrane into the cisternal space. Golgi apparatus (Golgi complex) Fig . 1 .4 Smooth endoplasmic reticulum with associated vesicles . The The Golgi apparatus is a distinct cytomembrane system located near the dense particles are glycogen granules . (Courtesy of Rose Watson, Cancer nucleus and the centrosome. It is particularly prominent in secretory Research UK .) cells and can be visualized when stained with silver or other metallic
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Basic structure and function of cells 6.e1 1 RETPaHC The glycocalyx plays a significant role in maintenance of the integrity of tissues and in a wide range of dynamic cellular processes, e.g. serving as a vascular permeability barrier and transducing fluid shear stress to the endothelial cell cytoskeleton (Weinbaum et al 2007). Disruption of the glycocalyx on the endothelial surface of large blood vessels precedes inflammation, a conditioning factor of atheromatosis (e.g. deposits of cholesterol in the vascular wall leading to partial or complete obstruc- tion of the vascular lumen). Protein synthesis on ribosomes may be suppressed by a class of RNA molecules known as small interfering RNA (siRNA) or silencing RNA. These molecules are typically 20–25 nucleotides in length and bind (as a complex with proteins) to specific mRNA molecules via their comple- mentary sequence. This triggers the enzymatic destruction of the mRNA or prevents the movement of ribosomes along it. Synthesis of the encoded protein is thus prevented. Their normal function may have antiviral or other protective effects; there is also potential for developing
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artificial siRNAs as a therapeutic tool for silencing disease-related genes.
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Cell structure 7 1 RETPaHC A B N GG V GG M C Phagocytic pathway Secretory pathway Membrane recycling Receptor-mediated endocytosis Clathrin-coated pit Early endosome Late endosome Lysosomal fusion Secondary lysosome Residual body Vesicle shuttling between cisternae trans-Golgi network Golgi cisternae cis-Golgi network Rough endoplasmic reticulum D E G R Fig . 1 .5 The Golgi apparatus and functionally related organelles . A, Golgi apparatus (G) adjacent to the nucleus (N) (V, vesicle) . B, A large residual body (tertiary lysosome) in a cardiac muscle cell (M, mitochondrion) . C, The functional relationships between the Golgi apparatus and associated cellular structures . D, A three-dimensional reconstruction of the Golgi apparatus in a pancreatic β cell showing stacks of Golgi cisternae from the cis-face (pink)
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and cis-medial cisternae (red, green) to the trans-Golgi network (blue, yellow, orange–red); immature proinsulin granules (condensing vesicles) are shown in pale blue and mature (crystalline) insulin granules in dark blue . The flat colour areas represent cut faces of cisternae and vesicles . E, Rough endoplasmic reticulum (R), associated with the Golgi apparatus (G) . (D, Courtesy of Dr Brad Marsh, Institute for Molecular Bioscience, University of Queensland, Brisbane . A,B,E From human tissue, courtesy of Dr Bart Wagner, Histopathology Department, Sheffield Teaching Hospitals, UK .)
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BaSIC STRuCTuRE aNd fuNCTION Of CEllS 8 1 NOITCES salts. Traffic between the endoplasmic reticulum and the Golgi appara- Endocytic (internalization) pathway tus is bidirectional and takes place via carrier vesicles derived from the The endocytic pathway begins at the plasma membrane and ends in donor site that bud, tether and fuse with the target site. lysosomes involved in the degradation of the endocytic cargo through Golgins are long coiled-coil proteins attached to the cytoplasmic the enzymatic activity of lysosomal hydrolases. Endocytic cargo is surface of cisternal membranes, forming a fibrillar matrix surrounding internalized from the plasma membrane to early endosomes and the Golgi apparatus to stabilize it; they have a role in vesicle trafficking then to late endosomes. Late endosomes transport their cargo to lyso- (for further reading on golgins, see Munro 2011). The Golgi apparatus somes, where the cargo material is degraded following fusion and has several functions: it links anterograde and retrograde protein and
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mixing of contents of endosomes and lysosomes. Early endosomes lipid flow in the secretory pathway; it is the site where protein and lipid derive from endocytic vesicles (clathrin-coated vesicles and caveolae). glycosylation occurs; and it provides membrane platforms to which Once internalized, endocytic vesicles shed their coat of adaptin and signalling and sorting proteins bind. clathrin, and fuse to form an early endosome, where the receptor Ultrastructurally, the Golgi apparatus (Fig. 1.5A) displays a contin- molecules release their bound ligands. Membrane and receptors from uous ribbon-like structure consisting of a stack of several flattened the early endosomes can be recycled to the cell surface as exocytic membranous cisternae, together with clusters of vesicles surrounding vesicles. its surfaces. Cisternae differ in enzymatic content and activity. Small Clathrin-dependent endocytosis occurs at specialized patches of transport vesicles from the rough endoplasmic reticulum are received plasma membrane called coated pits; this mechanism is also used to
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at one face of the Golgi stack, the convex cis-face (entry or forming internalize ligands bound to surface receptor molecules and is also surface). Here, they deliver their contents to the first cisterna in the termed receptor-mediated endocytosis. Caveolae (little caves) are struc- series by membrane fusion. From the edges of this cisterna, the protein turally distinct pinocytotic vesicles most widely used by endothelial and is transported to the next cisterna by vesicular budding and then smooth muscle cells, when they are involved in transcytosis, signal fusion, and this process is repeated across medial cisternae until the transduction and possibly other functions. In addition to late endo- final cisterna at the concave trans-face (exit or condensing surface) is somes, lysosomes can also fuse with phagosomes, autophagosomes reached. Here, larger vesicles are formed for delivery to other parts of and plasma membrane patches for membrane repair. Lysosomal hydro- the cell. lases process or degrade exogenous materials (phagocytosis or hetero-
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The cis-Golgi and trans-Golgi membranous networks form an inte- phagy) as well as endogenous material (autophagy). Phagocytosis gral part of the Golgi apparatus. The cis-Golgi network is a region of consists of the cellular uptake of invading pathogens, apoptotic cells complex membranous channels interposed between the rough endo- and other foreign material by specialized cells. Lysosomes are numerous plasmic reticulum and the Golgi cis-face, which receives and transmits in actively phagocytic cells, e.g. macrophages and neutrophil granulo- vesicles in both directions. Its function is to select appropriate proteins cytes, in which lysosomes are responsible for destroying phagocytosed synthesized on the rough endoplasmic reticulum for delivery by vesicles particles, e.g. bacteria. In these cells, the phagosome, a vesicle poten- to the Golgi stack, while inappropriate proteins are shuttled back to the tially containing a pathogenic microorganism, may fuse with several rough endoplasmic reticulum. lysosomes.
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The trans-Golgi network, at the other side of the Golgi stack, is also Autophagy involves the degradation and recycling within an a region of interconnected membrane channels engaged in protein autophagosome of cytoplasmic components that are no longer needed, sorting. Here, modified proteins processed in the Golgi cisternae are including organelles. The assembly of the autophagosome involves packaged selectively into vesicles and dispatched to different parts of several proteins, including autophagy-related (Atg) proteins, as well as the cell. The packaging depends on the detection, by the trans-Golgi Hsc70 chaperone, that translocate the substrate into the lysosome (Boya network, of particular amino-acid signal sequences, leading to their et al 2013). Autophagosomes sequester cytoplasmic components and enclosure in membranes of appropriate composition that will further then fuse with lysosomes without the participation of a late endosome. modify their contents, e.g. by extracting water to concentrate them The 26S proteasome (see below) is also involved in cellular degradation
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(vesicles entering the exocytosis pathway) or by pumping in protons to but autophagy refers specifically to a lysosomal degradation–recycling acidify their contents (lysosomes destined for the intracellular sorting pathway. Autophagosomes are seen in response to starvation and cell pathway). growth. Within the Golgi stack proper, proteins undergo a series of sequen- Late endosomes receive lysosomal enzymes from primary lysosomes tial chemical modifications by Golgi resident enzymes synthesized derived from the Golgi apparatus after late endosome–lysosome mem- in the rough endoplasmic reticulum. These include: glycosylation brane tethering and fusion followed by diffusion of lysosomal contents (changes in glycosyl groups, e.g. removal of mannose, addition of into the endosomal lumen. The pH inside the fused hybrid organelle, N-acetylglucosamine and sialic acid); sulphation (addition of sulphate now a secondary lysosome, is low (about 5.0) and this activates lyso- groups to glycosaminoglycans); and phosphorylation (addition of
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somal acid hydrolases to degrade the endosomal contents. The products phosphate groups). Some modifications serve as signals to direct pro- of hydrolysis either are passed through the membrane into the cytosol, teins and lipids to their final destination within cells, including lyso- or may be retained in the secondary lysosome. Secondary lysosomes somes and plasma membrane. Lipids formed in the endoplasmic may grow considerably in size by vesicle fusion to form multivesicular reticulum are also routed for incorporation into vesicles. bodies, and the enzyme concentration may increase greatly to form large lysosomes (Fig. 1.5B). Exocytic (secretory) pathway Secreted proteins, lipids, glycoproteins, small molecules such as amines Lysosomes and other cellular products destined for export from the cell are trans- ported to the plasma membrane in small vesicles released from the Lysosomes are membrane-bound organelles 80–800 nm in diameter, trans-face of the Golgi apparatus. This pathway either is constitutive, in often with complex inclusions of material undergoing hydrolysis (sec-
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which transport and secretion occur more or less continuously, as with ondary lysosomes). Two classes of proteins participate in lysosomal immunoglobulins produced by plasma cells, or it is regulated by exter- function: soluble acid hydrolases and integral lysosomal membrane nal signals, as in the control of salivary secretion by autonomic neural proteins. Each of the 50 known acid hydrolases (including proteases, stimulation. In regulated secretion, the secretory product is stored tem- lipases, carbohydrases, esterases and nucleases) degrades a specific sub- porarily in membrane-bound secretory granules or vesicles. Exocytosis strate. There are about 25 lysosomal membrane proteins participating is achieved by fusion of the secretory vesicular membrane with the in the acidification of the lysosomal lumen, protein import from the plasma membrane and release of the vesicle contents into the extracel- cytosol, membrane fusion and transport of degradation products to the lular domain. In polarized cells, e.g. most epithelia, exocytosis occurs cytoplasm. Material that has been hydrolysed within secondary lyso-
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at the apical plasma membrane. Glandular epithelial cells secrete into somes may be completely degraded to soluble products, e.g. amino a duct lumen, as in the pancreas, or on to a free surface, such as the acids, which are recycled through metabolic pathways. However, degra- lining of the stomach. In hepatocytes, bile is secreted across a very small dation is usually incomplete and some debris remains. A debris-laden area of plasma membrane forming the wall of the bile canaliculus. This vesicle is called a residual body or tertiary lysosome (see Fig. 1.5B), and region is defined as the apical plasma membrane and is the site of may be passed to the cell surface, where it is ejected by exocytosis; exocrine secretion, whereas secretion of hepatocyte plasma proteins alternatively, it may persist inside the cell as an inert residual body. into the blood stream is targeted to the basolateral surfaces facing the Considerable numbers of residual bodies can accumulate in long-lived sinusoids. Packaging of different secretory products into appropriate cells, often fusing to form larger dense vacuoles with complex lamellar
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vesicles takes place in the trans-Golgi network. Delivery of secretory inclusions. As their contents are often darkly pigmented, this may vesicles to their correct plasma membrane domains is achieved by change the colour of the tissue; e.g. in neurones, the end-product of sorting sequences in the cytoplasmic tails of vesicular membrane lysosomal digestion, lipofuscin (neuromelanin or senility pigment), proteins. gives ageing brains a brownish-yellow colouration. Lysosomal enzymes
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Basic structure and function of cells 8.e1 1 RETPaHC Carrier vesicles in transit from the endoplasmic reticulum to the Golgi apparatus (anterograde transport) are coated by coat protein complex II (COPII), whereas COPI-containing vesicles function in the retrograde transport route from the Golgi apparatus (reviewed in Spang (2013)). The membranes contain specific signal proteins that may allocate them to microtubule-based transport pathways and allow them to dock with appropriate targets elsewhere in the cell, e.g. the plasma mem- brane in the case of secretory vesicles. Vesicle formation and budding at the trans-Golgi network involves the addition of clathrin on their external surface, to form coated pits. Specialized cells of the immune system, called antigen-presenting cells, degrade protein molecules, called antigens, transported by the endocytic pathway for lysosomal breakdown, and expose their frag- ments to the cell exterior to elicit an immune response mediated ini- tially by helper T cells.
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Cell structure 9 1 RETPaHC may also be secreted – often as part of a process to alter the extracellular A matrix, as in osteoclast-mediated erosion during bone resorption. For further reading on lysosome biogenesis, see Saftig and Klumperman (2009). lysosomal dysfunction Lysosomal storage diseases (LSDs) are a consequence of lysosomal dysfunction. Approximately 60 different types of LSD have been identi- fied on the basis of the type of material accumulated in cells (such as mucopolysaccharides, sphingolipids, glycoproteins, glycogen and lipo- fuscins). LSDs are characterized by severe neurodegeneration, mental decline, and cognitive and behavioural abnormalities. Autophagy impairment caused by defective lysosome–autophagosome coupling triggers a pathogenic cascade by the accumulation of substrates that contribute to neurodegenerative disorders including Parkinson’s dis- ease, Alzheimer’s disease, Huntington’s disease and several tau-opathies. Many lysosomal storage diseases are known, e.g. Tay–Sachs disease
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(GM2 gangliosidosis), in which a faulty β-hexosaminidase A leads to the accumulation of the glycosphingolipid GM2 ganglioside in neu- rones, causing death during childhood. In Danon disease, a vacuolar skeletal myopathy and cardiomyopathy with neurodegeneration in hemizygous males, lysosomes fail to fuse with autophagosomes because of a mutation of the lysosomal membrane protein LAMP-2 (lysosomal B associated membrane protein-2). 26S proteasome Outer membrane A protein can be degraded by different mechanisms, depending on the cell type and different pathological conditions. Furthermore, the same substrate can engage different proteolytic pathways (Park and Inner membrane Cuervo 2013). Three major protein degradation mechanisms operate in eukaryotic cells to dispose of non-functional cellular proteins: Cristae (folds) the autophagosome–lysosomal pathway (see above); the apoptotic procaspase–caspase pathway (see below); and the ubiquitinated Elementary particles protein–26S proteasome pathway. The 26S proteasome is a multicata-
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lytic protease found in the cytosol and the nucleus that degrades intra- cellular proteins conjugated to a polyubiquitin chain by an enzymatic cascade. The 26S proteasome consists of several subunits arranged into two 19S polar caps, where protein recognition and adenosine 5′- triphosphate (ATP)-dependent target processing occur, flanking a 20S central barrel-shaped structure with an inner proteolytic chamber (Tomko and Hochstrasser 2013). The 26S proteasome participates in the removal of misfolded or abnormally assembled proteins, the deg- radation of cyclins involved in the control of the cell cycle, the process- ing and degradation of transcription regulators, cellular-mediated Fig . 1 .6 A, Mitochondria in human cardiac muscle . The folded cristae immune responses, and cell cycle arrest and apoptosis. (arrows) project into the matrix from the inner mitochondrial membrane . B, The location of the elementary particles that couple oxidation and Peroxisomes phosphorylation reactions . (A, Courtesy of Dr Bart Wagner,
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Peroxisomes are small (0.2–1 µm in diameter) membrane-bound Histopathology Department, Sheffield Teaching Hospitals, UK .) organelles present in most mammalian cells. They contain more than 50 enzymes responsible for multiple catabolic and synthetic biochemi- cal pathways, in particular the β-oxidation of very-long-chain fatty Mitochondria acids (>C22) and the metabolism of hydrogen peroxide (hence the In the electron microscope, mitochondria usually appear as round or name peroxisome). Peroxisomes derive from the endoplasmic reticu- elliptical bodies 0.5–2.0 µm long (Fig. 1.6), consisting of an outer lum through the transfer of proteins from the endoplasmic reticulum mitochondrial membrane; an inner mitochrondrial membrane, sepa- to peroxisomes by vesicles that bud from specialized sites of the endo- rated from the outer membrane by an intermembrane space; cristae, plasmic reticulum and by a lipid non-vesicular pathway. All matrix infoldings of the inner membrane that harbour ATP synthase to gener-
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proteins and some peroxisomal membrane proteins are synthesized by ate ATP; and the mitochondrial matrix, a space enclosed by the inner cytosolic ribosomes and contain a peroxisome targeting signal that membrane and numerous cristae. The permeability of the two mito- enables them to be imported by proteins called peroxins (Braverman chondrial membranes differs considerably: the outer membrane is et al 2013, Theodoulou et al 2013). Mature peroxisomes divide by freely permeable to many substances because of the presence of large small daughter peroxisomes pinching off from a large parental non-specific channels formed by proteins (porins), whereas the inner peroxisome. membrane is permeable to only a narrow range of molecules. The pres- Peroxisomes often contain crystalline inclusions composed mainly ence of cardiolipin, a phospholipid, in the inner membrane may con- of high concentrations of the enzyme urate oxidase. Oxidases use tribute to this relative impermeability. molecular oxygen to oxidize specific organic substrates (such as L-amino Mitochondria are the principal source of chemical energy in most
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acids, D-amino acids, urate, xanthine and very-long-chain fatty acids) cells. Mitochondria are the site of the citric acid (Krebs’) cycle and the and produce hydrogen peroxide that is detoxified (degraded) by per- electron transport (cytochrome) pathway by which complex organic oxisomal catalase. Peroxisomes are particularly numerous in hepato- molecules are finally oxidized to carbon dioxide and water. This process cytes. Peroxisomes are important in the oxidative detoxification of provides the energy to drive the production of ATP from adenosine various substances taken into or produced within cells, including diphosphate (ADP) and inorganic phosphate (oxidative phosphoryla- ethanol. Peroxin mutation is a characteristic feature of Zellweger syn- tion). The various enzymes of the citric acid cycle are located in the drome (craniofacial dysmorphism and malformations of brain, liver, mitochondrial matrix, whereas those of the cytochrome system and eye and kidney; cerebrohepatorenal syndrome). Neonatal leukodystro- oxidative phosphorylation are localized chiefly in the inner mitochon-
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phy is an X-linked peroxisomal disease affecting mostly males, caused drial membrane. by deficiency in β-oxidation of very-long-chain fatty acids. The build-up The intermembrane space houses cytochrome c, a molecule involved of very-long-chain fatty acids in the nervous system and suprarenal in activation of apoptosis. glands determines progressive deterioration of brain function and The number of mitochondria in a particular cell reflects its general suprarenal insufficiency (Addison’s disease). For further reading, see energy requirements; e.g. in hepatocytes there may be as many as 2000, Braverman et al (2013). whereas in resting lymphocytes there are usually very few. Mature
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Basic structure and function of cells 9.e1 1 RETPaHC The transcription factor EB (TFEB) is responsible for regulating lyso- somal biogenesis and function, lysosome-to-nucleus signalling and lipid catabolism (for further reading, see Settembre et al (2013)). If any of the actions of lysosomal hydrolases, of the lysosome acidification mechanism or of lysosomal membrane proteins fails, the degradation and recycling of extracellular substrates delivered to lysosomes by the late endosome and the degradation and recycling of intracellular sub- strates by autophagy lead to progressive lysosomal dysfunction in several tissues and organs. Experimentally, TFEB activation can reduce the accumulation of the pathogenic protein in a cellular model of Huntington’s disease (a neurodegenerative genetic disorder that affects muscle coordination) and improves the Parkinson’s disease phenotype in a murine model. Cristae are abundant in mitochondria seen in cardiac muscle cells and in steroid-producing cells (in the suprarenal cortex, corpus luteum and Leydig cells). The protein steroidogenic acute regulatory protein (StAR) regulates the synthesis of steroids by transporting
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cholesterol across the outer mitochondrial membrane. A mutation in the gene encoding StAR causes defective suprarenal and gonadal steroidogenesis.
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BaSIC STRuCTuRE aNd fuNCTION Of CEllS 10 1 NOITCES erythrocytes lack mitochondria altogether. Cells with few mitochondria ent and its electronic charge, and the potential difference across the generally rely largely on glycolysis for their energy supplies. These membrane. These factors combine to produce an electrochemical gradi- include some very active cells, e.g. fast twitch skeletal muscle fibres, ent, which governs ion flux. Channel proteins are utilized most effec- which are able to work rapidly but for only a limited duration. Mito- tively by the excitable plasma membranes of nerve cells, where the chondria appear in the light microscope as long, thin structures in the resting membrane potential can change transiently from about −80 mV cytoplasm of most cells, particularly those with a high metabolic rate, (negative inside the cell) to +40 mV (positive inside the cell) when e.g. secretory cells in exocrine glands. In living cells, mitochondria stimulated by a neurotransmitter (as a result of the opening and sub-
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constantly change shape and intracellular position; they multiply by sequent closure of channels selectively permeable to sodium and growth and fission, and may undergo fusion. potassium). The mitochondrial matrix is an aqueous environment. It contains a Carrier proteins bind their specific solutes, such as amino acids, and variety of enzymes, and strands of mitochondrial DNA with the capacity transport them across the membrane through a series of conforma- for transcription and translation of a unique set of mitochondrial genes tional changes. This latter process is slower than ion transport through (mitochondrial mRNAs and transfer RNAs, mitochondrial ribosomes membrane channels. Transport by carrier proteins can occur either pas- with rRNAs). The DNA forms a closed loop, about 5 µm across; several sively by simple diffusion, or actively against the electrochemical gradi- identical copies are present in each mitochondrion. The ratio between ent of the solute. Active transport must therefore be coupled to a source its bases differs from that of nuclear DNA, and the RNA sequences also of energy, such as ATP generation, or energy released by the coordinate
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differ in the precise genetic code used in protein synthesis. At least 13 movement of an ion down its electrochemical gradient. Linked trans- respiratory chain enzymes of the matrix and inner membrane are port can be in the same direction as the solute, in which case the carrier encoded by the small number of genes along the mitochondrial DNA. protein is described as a symporter, or in the opposite direction, when The great majority of mitochondrial proteins are encoded by nuclear the carrier acts as an antiporter. genes and made in the cytosol, then inserted through special channels in the mitochondrial membranes to reach their destinations. Their Translocation of proteins across membrane lipids are synthesized in the endoplasmic reticulum. intracellular membranes It has been shown that mitochondria are of maternal origin because Proteins are generally synthesized on ribosomes in the cytosol or on the mitochondria of spermatozoa are not generally incorporated the rough endoplasmic reticulum. A few are made on mitochondrial into the ovum at fertilization. Thus mitochondria (and mitochondrial ribosomes. Once synthesized, many proteins remain in the cytosol,
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genetic variations and mutations) are passed only through the where they carry out their functions. Others, such as integral membrane female line. proteins or proteins for secretion, are translocated across intracellular Mitochondria are distributed within a cell according to regional membranes for post-translational modification and targeting to their energy requirements, e.g. near the bases of cilia in ciliated epithelia, in destinations. This is achieved by the signal sequence, an addressing the basal domain of the cells of proximal convoluted tubules in the system contained within the protein sequence of amino acids, which is renal cortex (where considerable active transport occurs) and around recognized by receptors or translocators in the appropriate membrane. the proximal segment, called middle piece, of the flagellum in sperma- Proteins are thus sorted by their signal sequence (or set of sequences tozoa. They may be involved with tissue-specific metabolic reactions, that become spatially grouped as a signal patch when the protein folds e.g. various urea-forming enzymes are found in liver cell mitochondria. into its tertiary configuration), so that they are recognized by and enter
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Moreover, a number of genetic diseases of mitochondria affect particu- the correct intracellular membrane compartment. lar tissues exclusively, e.g. mitochondrial myopathies (skeletal muscle) and mitochondrial neuropathies (nervous tissue). For further informa- Cell signalling tion on mitochondrial genetics and disorders, see Chinnery and Hudson (2013). Cellular systems in the body communicate with each other to coordi- Cytosolic inclusions nate and integrate their functions. This occurs through a variety of The aqueous cytosol surrounds the membranous organelles described processes known collectively as cell signalling, in which a signalling above. It also contains various non-membranous inclusions, including molecule produced by one cell is detected by another, almost always by free ribosomes, components of the cytoskeleton, and other inclusions, means of a specific receptor protein molecule. The recipient cell trans- such as storage granules (e.g. glycogen), pigments (such as lipofuscin duces the signal, which it most often detects at the plasma membrane, granules, remnants of the lipid oxidative mechanism seen in the supra- into intracellular chemical messages that change cell behaviour.
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