Masaryk University Faculty of Medicine Physiology Exam Review of Physiology st 1 edition By: REBAND AHMED REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam Part A 1. Structure and function of cell membranes Structure Lipid bilayer The cell membrane consists primarily of a thin layer of amphipathic phospholipids which are arranged so that the hydrophobic "tail" regions are shielded from the surrounding polar fluid, causing the more hydrophilic "head" regions to associate with the cytosolic and extracellular faces of the resulting bilayer. This forms a continuous, spherical lipid bilayer. The arrangement of hydrophilic heads and hydrophobic tails of the lipid bilayer prevent polar solutes (e.g. amino acids, nucleic acids, carbohydrates, proteins, and ions) from diffusing across the membrane, but generally allows for the passive diffusion of hydrophobic molecules. Integral membrane proteins The cell membrane contains many integral membrane proteins. These structures, which can be visualized by electron microscopy or fluorescence microscopy, can be found on the inside of the membrane, the outside, or membrane spanning. These may include integrins, cadherins, desmosomes, clathrin-coated pits, caveolaes, and different structures involved in cell adhesion. Function The cell membrane surrounds the protoplasm of a cell and, in animal cells, physically separates the intracellular components from the extracellular space, thereby serving a function similar to that of skin. In fungi, some bacteria, and plants, an additional cell wall forms the outermost boundary; however, the cell wall plays mostly a mechanical support role rather than a role as a selective boundary. The cell membrane also plays a role in anchoring the cytoskeleton to provide shape to the cell, and in attaching to the extracellular matrix and other cells to help group cells together to form tissues. The barrier is differentially permeable and able to regulate what enters and exits the cell, thus facilitating the transport of materials needed for survival. The movement of substances across the membrane can be either passive, occurring without the input of cellular energy, or active, requiring the cell to expend energy in moving it. The membrane also maintains the cell potential. Specific proteins embedded in the cell membrane can act as molecular signals that allow cells to communicate with each other. Protein receptors are found ubiquitously and function to receive signals from both the environment and other cells REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam 2. Structure and functions of cell organelles Chromosomes - Usually in the form of chromatin - Contains genetic information - Composed of DNA - Set number per species (i.e. 23 pairs for human) Nuclear membrane - Surrounds nucleus - Composed of two layers - Numerous openings for nuclear traffic Nucleolus - Spherical shape - Visible when cell is not dividing - Contains RNA for protein manufacture Centrioles - Paired cylindrical organelles near nucleus - Composed of nine tubes, each with three tubules - Involved in cellular division - Lie at right angles to each other Chloroplasts - A plastid usually found in plant cells - Contain green chlorophyll where photosynthesis takes place Cytoskeleton - Composed of microtubules - Supports cell and provides shape - Aids movement of materials in and out of cells REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam Endoplasmic reticulum - Tubular network fused to nuclear membrane - Goes through cytoplasm onto cell membrane - Stores, separates, and serves as cell's transport system - Smooth type: lacks ribosomes - Rough type (pictured): ribosomes embedded in surface Golgi apparatus - Protein 'packaging plant' - A membrane structure found near nucleus - Composed of numerous layers forming a sac Lysosome - Digestive 'plant' for proteins, lipids, and carbohydrates - Transports undigested material to cell membrane for removal - Vary in shape depending on process being carried out - Cell breaks down if lysosome explodes Mitochondria - Second largest organelle with unique genetic structure - Double-layered outer membrane with inner folds called cristae - Energy-producing chemical reactions take place on cristae - Controls level of water and other materials in cell - Recycles and decomposes proteins, fats, and carbohydrates, and forms urea Ribosomes - Each cell contains thousands - Miniature 'protein factories' - Composes 25% of cell's mass - Stationary type: embedded in rough endoplasmic reticulum - Mobile type: injects proteins directly into cytoplasm Vacuoles - Membrane-bound sacs for storage, digestion, and waste removal - Contains water solution - Contractile vacuoles for water removal (in unicellular organisms) Cell wall - Most commonly found in plant cells - Controls turgity - Extracellular structure surrounding plasma membrane - Primary cell wall: extremely elastic - Secondary cell wall: forms around primary cell wall after growth is complete Plasma membrane - Outer membrane of cell that controls cellular traffic - Contains proteins (left, gray) that span through the membrane and allow passage of materials - Proteins are surrounded by a phospholipid bi-layer. REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam 3. Passive transport across membranes. Cotransport. Passive transport means moving biochemicals and atomic or molecular substances across the cell membrane. Unlike active transport, this process does not involve chemical energy. The four main kinds of passive transport are diffusion, facilitated diffusion, filtration and osmosis. I. Diffusion is a process by which there is a net flow of matter from a region of high concentration to one of low concentration. It is driven by a conc. gradient. It can be measured using the following equation: J = -PA (C – C ) 1 2 2 where: J = flux (flow) [mmol/sec], P = permeability (cm/sec), A = area (cm ), C = conc. 1 1 (mmol/L), C2 = conc.2 (mmol/L) II. Facilitated diffusion is the spontaneous passage of molecules or ions across a biological membrane passing through specific transmembrane transport proteins. It occurs down an electrochemical gradient (“downhill”), similar to simple diffusion. Glucose transport in muscle an adipose cells is “downhill”, is carrier-mediated, and is inhibited by sugars as galactose; therefore, it is categorized as facilitated diffusion. III. Filtration is a mechanical or physical operation which is used for the separation of solids from fluids (liquids or gases) by interposing a medium through which only the fluid can pass. Oversize solids in the fluid are retained, but the separation is not complete; solids will be contaminated with some fluid and filtrate will contain fine particles (depending on the pore size and filter thickness). IV. Osmosis is the diffusion of water molecules across a selectively permeable membrane. The net movement of water molecules through a partially permeable membrane from a solution of high water potential to an area of low water potential. Co-transport Also known as coupled transport, refers to the simultaneous or sequential passive transfer of molecules or ions across biological membranes in a fixed ratio. Cotransporters can be classified as symporters and antiporters depending on whether the substances move in the same or opposite directions. REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam 4. Compartmentalization of body fluids The total body fluid is distributed mainly between two compartments: the extracellular fluid and the intracellular fluid. The extracellular fluid is divided into the interstitial fluid and the blood plasma. There is another small compartment of fluid that is referred to as transcellular fluid. This . compartment includes fluid in the synovial, peritoneal, pericardial, and intraocular spaces, as well as the cerebrospinal fluid; it is usually considered to be a specialized type of extracellular fluid, although in some cases, its composition may differ markedly from that of the plasma or interstitial fluid. All the transcellular fluids together constitute about 1 to 2 liters. In the average 70-kilogram adult human, the total body water is about 60 per cent of the body weight, or about 42 liters. This percentage can change, depending on age, gender, and degree of obesity. As a person grows older, the percentage of total body weight that is fluid gradually decreases. This is due in part to the fact that aging is usually associated with an increased percentage of the body weight being fat, which decreases the percentage of water in the body. Because women normally have more body fat than men, they contain slightly less water than men in proportion to their body weight. Intracellular Fluid Compartment About 28 of the 42 liters of fluid in the body are inside the 75 trillion cells and are collectively called the intracellular fluid. Thus, the intracellular fluid constitutes about 40 per cent of the total body weight in an “average” person. Extracellular Fluid Compartment All the fluids outside the cells are collectively called the extracellular fluid. Together these fluids account for about 20 per cent of the body weight, or about 14 liters in a normal 70- kilogram adult. The two largest compartments of the extracellular fluid are the interstitial fluid, which makes up more than three fourths of the extracellular fluid, and the plasma, which makes up almost one fourth of the extracellular fluid, or about 3 liters. The plasma is the noncellular part of the blood; it exchanges substances continuously with the interstitial fluid through the pores of the capillary membranes. These pores are highly permeable to almost all solutes in the extracellular fluid except the proteins. Therefore, the extracellular fluids are constantly mixing, so that the plasma and interstitial fluids have about the same composition except for proteins, which have a higher concentration in the plasma. Measurement The volume of a fluid compartment in the body can be measured by placing an indicator substance in the compartment, allowing it to disperse evenly throughout the compartment’s fluid, and then analyzing the extent to which the substance becomes diluted. REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam 5. Differences between intra- and extracellular fluids Ionic Composition of Plasma and Interstitial Fluid Is Similar Because the plasma and interstitial fluid are separated only by highly permeable capillary membranes, their ionic composition is similar. The most important difference between these two compartments is the higher concentration of protein in the plasma; because the capillaries have a low permeability to the plasma proteins, only small amounts of proteins are leaked into the interstitial spaces in most tissues. Because of the Donnan effect, the concentration of positively charged ions (cations) is slightly greater (about 2 per cent) in the plasma than in the interstitial fluid. Important Constituents of the Intracellular Fluid The intracellular fluid is separated from the extracellular fluid by a cell membrane that is highly permeable to water but not to most of the electrolytes in the body. In contrast to the extracellular fluid, the intracellular fluid contains only small quantities of sodium and chloride ions and almost no calcium ions. Instead, it contains large amounts of potassium and phosphate ions plus moderate quantities of magnesium and sulfate ions, all of which have low concentrations in the extracellular fluid. Also, cells contain large amounts of protein, almost four times as much as in the plasma. REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam 6. Production and resorption of interstitial fluid (Starling forces) Interstitial fluid is a solution that bathes and surrounds the cells of multicellular animals. It is the main component of the extracellular fluid, which also includes plasma and transcellular fluid. The interstitial fluid is found in the interstitial spaces, also known as the tissue spaces. On average, a person has about 11 litres (2.4 imperial gallons) of . interstitial fluid, providing the cells of the body with nutrients and a means of waste removal. Formation of interstitial fluid Hydrostatic pressure is generated by the systolic force of the heart. It pushes water out of the capillaries (Starling forces). The water potential is created due to the ability of small solutes to pass through the walls of capillaries. This buildup of solutes induces osmosis. The water passes from a high concentration (of water) outside of the vessels to a low concentration inside of the vessels, in an attempt to reach an equilibrium. The osmotic pressure drives water back into the vessels. Because the blood in the capillaries is constantly flowing, equilibrium is always reached. The balance between the two forces differs at different points on the capillaries. At the arterial end of a vessel, the hydrostatic pressure is greater than the osmotic pressure, so the net movement favors water and other solutes being passed into the tissue fluid. At the venous end, the osmotic pressure is greater, so the net movement favors substances being passed back into the capillary. This difference is created by the direction of the flow of blood and the imbalance in solutes created by the net movement of water favoring the interstitial fluid. Removal of interstitial fluid To prevent a build-up of interstitial fluid surrounding the cells in the tissue, the lymphatic system plays a part in the transport of interstitial fluid. Interstitial can pass into the surrounding lymph vessels, and eventually ends up rejoining the blood. Sometimes the removal of tissue fluid does not function correctly, and there is a build-up. This causes swelling, and can often be seen around the feet and ankles, for example Elephantiasis. The position of swelling is due to the effects of gravity. REBAND AHMED Spring Semester 2010 Masaryk University Faculty of Medicine Physiology Exam 7. Ion channels Ion channels are integral proteins that span the membrane and, when open, permit the passage of certain ions. 1. Ion channels are selective; they permit the passage of some ions, but not others. Selectively is based on the size of the channel and the distribution of charges that line it. 2. Ions channels may be opened or closed. When the channel is open, the ion(s) for which it is selective can flow through it. When the channel is closed, ions cannot flow through them. 3. The conductance of a channel depends on the probability that the channel is open. The higher the probability that a channel is open, the higher the conductance, or permeability. Opening and closing of channels are controlled by gates. a. Voltage-gated channels are open or closed by changes in membrane potential. The activation gate of the Na+ channel in nerve is opened by depolarization; when open, the nerve membrane is permeable to Na+ (e.g., during the upstroke of the nerve action potential). The inactivation gate of the Na+ channel in nerve is closed by depolarization; when closed, the nerve membrane is impermeable to Na+ (e.g., during the repolarization phase of the nerve action potential). b. Ligand-gated channels are opened or closed by hormones, second messengers, or neurotransmitters. For example, the nicotinic receptor for acetylcholine (ACh) at the motor end plate is an ion channel that opens when Ach binds to it. When open, it is permeable to Na+ and K+, causing the motor end plate to depolarize. REBAND AHMED Spring Semester 2010
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