Cellular Form and Function Concepts of cellular structure Cell surface Membrane transport Cytoplasm Modern Cell Theory All living organisms are composed of cells. the simplest structural and functional unit of life. cells are alive An organism s structure and functions are due to the activities of its cells. Cells come only from preexisting cells i.e., all life traces its ancestry to the same original cells Cells of all species have many fundamental similarities in chemical composition and metabolic mechanisms. 3-1 3-2 Cell Shapes, Size, Cell Surface Area, and Volume Generalized Cell Structures 20 m Growth 20 m 10 m 10 m Large cell Diameter = 20 mm Surface area = 20 mm 20 mm 6 = 2,400 mm 2 Volume = 20 mm 20 mm 20 mm = 8,000 mm 3 Three principle parts of a cell 1. Plasma membrane = cell membrane 2. Cytoplasm = everything between the membrane and the nucleus - cytosol = intracellular fluid - organelles = structures with specific functions 3. Nucleus = genetic material of cell Small cell Diameter = 10 mm Surface area = 10 mm 10 mm 6 = 600 mm 2 Volume = 10 mm 10 mm 10 mm = 1,000 mm 3 Effect of cell growth: Diameter (D) increased by a factor of 2 Surface area increased by a factor of 4 (= D 2 ) Volume increased by a factor of 8 (= D 3 ) 3-3 2.-4 Plasma Membrane Extracellular fluid Peripheral protein Glycolipid Glycoprotein Carbohydrate chains Extracellular face of membrane Phospholipid bilayer Peripheral protein Transmembrane protein Channel Intracellular fluid Cholesterol Proteins of cytoskeleton Intracellular face of membrane Figure 3.6b Not all cells contain all of these organelles. 3-6 2.-5 (b) 1
Membrane Protein Functions Cell Surface - Second Messenger System A messenger binds to a receptor 1 Chemical messenger Breakdown products Ions CAM of another cell First messenger Receptor Adenylate cyclase G G P i 2 Receptor releases ATP P i G protein, G protein 3 binds to an enzyme, adenylate cyclase - converts ATP to cyclic AMP (camp), the camp second messenger. (second messenger) Inactive kinase 4 camp activates a cytoplasmic enzyme called a kinase. (a) Receptor (b) Enzyme (c) Ion Channel (d) Gated ion channel (e) Cell-identity marker (f) Cell-adhesion A receptor that An enzyme that A channel protein A gated channel A glycoprotein molecule (CAM) binds to chemical breaks down that is constantly that opens and acting as a cell- A cell-adhesion messengers such a chemical open and allows closes to allow identity marker molecule (CAM) as hormones sent messenger and ions to pass ions through distinguishing the that binds one by other cells terminates its into and out of only at certain body s own cells cell to another effect the cell times from foreign cells Inactive enzymes Activated kinase P i 5 Kinases add phosphate groups (P i) to other enzymes. This activates some enzymes or deactivates others, leading to varied metabolic effects in the cell. Figure 3.8 3-7 Activated enzymes Various metabolic effects 3-8 Cell Surface Glycoproteins and Glycolipids unique in everyone Functions protection - cell adhesion immunity to infection - fertilization defense against cancer transplant compatibility Cell surface - Cilia Cilia respiratory tract, uterine tubes, ventricles of the brain, efferent ductules of testes Flagella Cilia and flagella composed of Microfilaments. Mucus Saline layer Epithelial cells 1 2 3 4 5 6 7 3-9 (a) Power stroke Recovery stroke (b) Figure 3.12a Figure 3.12b 3-10 The Selective Permeable Membrane!! Permeable to some molecules but not all Filtration (coffee filter) Diffusion and Osmosis transmembrane proteins act as specific channels for some particles Protein carriers How things get in the cell Diffusion- - Dye placed in water Molecules move from a high concentration to region of lower conc. Equilibrium reached in the far right cylinder Vesicles can transport in and out 2.-11 2.-12 2
Diffusion Rates Please note that due to differing operating systems, some animations will not appear until the presentation is viewed in Presentation Mode (Slide Show view). You may see blank slides in the Normal or Slide Sorter views. All animations will appear after viewing in Presentation Mode and playing each animation. Most animations will require the latest version of the Flash Player, which is available at http://get.adobe.com/flashplayer. Factors affecting diffusion rate through a membrane temperature molecular weight - larger molecules move slower steepness of concentrated gradient membrane surface area membrane permeability - 3-14 Osmosis Movement of water through a selectively permeable membrane from an area of high water conc. to area of lower water conc. Osmosis: The movement of water across a semi-permeable membrane membrane Water moves through the phospholipid bilayer Transmembrane proteins can function as water channels (Aquaporins) 2.-15 2.-16 Attraction of water to solute particles forms hydration spheres Aquaporins - channel proteins specialized for passage of water Please note that due to differing operating systems, some animations will not appear until the presentation is viewed in Presentation Mode (Slide Show view). You may see blank slides in the Normal or Slide Sorter views. All animations will appear after viewing in Presentation Mode and playing each animation. Most animations will require the latest version of the Flash Player, which is available at http://get.adobe.com/flashplayer. 2.-17 3
Osmotic Pressure Osmotic Pressure: amount of pressure required to stop osmosis (amt of hydrostatic pressure) Hydrostatic pressure: physical pressure generated by a liquid Osmotic pressure Hydrostatic pressure (b) 30 minutes later Figure 3.15b 3-19 Osmolarity One osmole - 1 mole of dissolved particles 1M NaCl (1 mole Na + ions + 1 mole Cl - ions) thus 1M NaCl = 2 osm/l Osmolarity number of osmoles of solute per liter of solution (i.e., number of solutes/l solution) Osmolality number of osmoles of solute per kilogram of water (i.e., number of solutes/kg of H20) Physiological solutions are expressed in milliosmoles per liter (mosm/l) blood plasma = 300 mosm/l osmolality similar to osmolarity at concentration of body fluids 3-20 Tonicity Tonicity - ability of a solution to affect fluid volume and pressure in a cell depends on concentration and permeability of solute Hypotonic solution has a lower concentration of solutes than intracellular fluid (ICF) high water concentration Cells lyse Hypertonic solution has a higher concentration of solutes low water concentration Cells crenate Isotonic solution concentrations in cell and ICF equal no changes in cell volume or shape 3-21 Effects of Tonicity on RBCs (a) Hypotonic (b) Isotonic (c) Hypertonic 3-22 1. Simple diffusion 2. Diffusion through a channel 3. Carrier Mediated Transport uses a transporter protein. Membrane Carriers (proteins) Uniport carries one solute at a time Symport (Cotransport) carries > 2 osolutes simultaneously in same direction Antiport (Countertransport) carries >2 or more solutes in opposite directions e.g., sodium-potassium pump carriers employ two methods of transport facilitated diffusion active transport 2.-23 3-24 4
Diffusion Through Membrane Channels Filtration and osmosis Facilitated Transport: Glucose example Glucose binds to transport protein Transport protein changes shape Glucose moves down the concentration gradient Each membrane channel specific for ions (e.g., K+, Na+, or Ca+2) Channels may be open or gated 2.-25 2.-26 Transport Across the Plasma Membrane - So far - Movement of stuff against its concentration gradient Requires energy from ATP Enables movement into cell against a concentration gradient Active Transport 2.-27 2.-28 Transport Vesicles (another way of getting things in and out) Vesicles are round sacs of membrane that surround stuff (Requires ATP) Endocytosis = vesicles bringing something into cell Exocytosis = vesicles release something from cell Endocytosis: 1)receptor-mediated endocytosis 2)Phagocytosis 3)Pinocytosis droplets of extracellular fluid 2. Cytoplasm = everything between membrane and nucleus 1. cytosol = intracellular fluid 2. organelles = special structures with specific functions 2.-29 2.-30 5
1. Cytosol = Intracellular fluid 2. Cell Organelles 55% of cell volume 75-90% water organic molecules (carbs, lipids, sugars, proteins, enzymes), ATP, waste products, and ions Dissolved (solutes) Site of many important chemical reactions 2.-31 Some organelles lack membranes others are surrounded by one or two phospho-lipid bilayer membranes 2.-32 Network of protein filaments throughout the cytosol Functions: support and shape organization of cell contents cell & organelle movement Cytoskeleton The Cytoskeletonal Filaments 1. Microfilaments 2. Intermediate filaments 3. Microtubules 2.-33 Fig 2.6 2.-34 Centrosome 1. Centrioles 2. Pericentriolar material Found near nucleus Important site during mitosis Microtrubule formation! Ribosomes Protein Makers Sites where protein is made!!!!!!!!!!!!!! Tiny packages of ribosomal RNA (rrna) synthesize proteins (plasma membrane & for export) 1. Free ribosomes are loose in cytosol synthesize proteins used inside the cell 2. On Surface of Endoplasmic Reticulum (mitochondria, synthesize mitochondrial proteins) 2.-35 2.-36 6
Endoplasmic Reticulum Network of membranes forming flattened sacs (Cisterns) 2 types: Rough ER continuous with nuclear envelope & covered with ribosomes synthesizes, processes & packages proteins for export Smooth ER -- no attached ribosomes synthesizes phospholipids, steroids and fats detoxifies harmful substances (alcohol) 2.-37 2.-38 Golgi Complex Packaging by Golgi Complex Flattened curved membranous sacs (cisterns) Modify, sort, packages proteins produced by rough ER 2.-39 2.-40 Lysosomes Membranous vesicles formed in Golgi Complex digestive enzymes Functions digest foreign substances autophagy recycle own organelles Peroxisomes & Proteasomes Membranous vesicles small contain enzymes Peroxisomes: oxidize toxic chemicals Proteosomes: break down proteins (metabolic breakdown) - 2.-41 2.-42 7
Mitochondria Double membrane bound organelle Function generation of ATP!!!!!!! (Adenosine triphosphate) Cellular respiration Can self-replicate Nucleus Nucleolus Function: Directs all cell activities Double membrane (aka: nuclear envelope) Contains our genetic stuff: chromosomes (DNA) Nucleolus: where ribosomes are produced 2.-43 2.-44 8