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The Plasma Membrane and Membrane Potential. Chapter 3. Objectives. Know the composition of the plasma membrane Understand the functions of the plasma membrane Explain how the various forms of membrane transport work Know the functions of the sodium-potassium pumps - PowerPoint PPT Presentation
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The Plasma Membrane and Membrane Potential
Chapter 3
Objectives• Know the composition of the plasma membrane
• Understand the functions of the plasma membrane
• Explain how the various forms of membrane transport work
• Know the functions of the sodium-potassium pumps
• Know what a membrane potential is and how it is established
The Plasma Membrane
• Surrounds all living cells
• Composed of a phospholipid bilayer– Polar hydrophilic heads on the outside, nonpolar
hydrophobic tails on the inside– Trilaminar appearance
Phospholipid Bilayer
Composition of Plasma Membrane
• Trilaminar structure
• Composition includes– Phospholipids– Proteins– Cholesterol– Carbohydrates
• Fluid mosaic model– Proteins and cholesterol embedded
Bilayer Function
• Provides structure and fluidity to the membrane
• Prevents hydrophilic substances from crossing the membrane
Membrane Protein Function
• Transmembrane (integral) proteins– Channels• Leak or gated
– Carrier (transport)• Selectively transport substances across membrane
– Docking-marker acceptors or receptors– Membrane-bound enzymes– Cell adhesion molecules (CAMs)• Caherins• Integrins
Membrane Carbohydrate Function• Function as “self” markers
• Allow cells to identify themselves as belonging to you
• Allows cells to identify cells of the same type
• Used during tissue formation to ensure that the same type of cells are being used– Also ensure that tissues do not overlap
Cell Adhesion• Plasma membrane involved in cell adhesion
– Three ways: CAMs, ECM, and specialized junctions
• Extra cellular matrix– The “glue” that holds the cells together– Network of fibrous proteins embedded in gel-like fluid
• Collagen, elastin, fibronectin– Secreted by fibroblasts– Cellular regulation and protection
• Specilaized junctions– Desmosomes– Tight junctions– Gap junctions
vivo.colostate.edu
Cell Adhesions
• Tight junctions • Gap junctions
bio.davidson.edu
academic.brooklyn.cuny.edu
Membrane Transport
• Selective permeability– Plasma membrane controls what enter and exits
the cell
– Determined by two properties• Size• Solubility in lipids
– Can be unassisted or assisted
Diffusion• Diffusion (simple diffusion)
– Net movement from an area of higher concentration to an area of lower concentration
– Does not require energy, passive process
• Fick’s law of diffusion– Effects of factors that influence the rate of diffusion
• Magnitude of concentration gradient• Surface area of membrane• Lipid solubility of substance• Molecular weight• Distance across membrane
Osmosis• Osmosis
– Diffusion of water across a selectively permeable membrane• Osmotic pressure , osmolarity (milliosmoles/L) 300 mOsm normal in body fluids• Hydrostatic pressure
– Aquaporins – protein channels that allow water the diffuse in and out of cell
– Tonicity refers to the effect the solution will have on cell volume• Hypertonic
– Water out of cell, cell shrinks
• Hypotonic– Water into cell, cell swells
• Isotonic– Water movement is at equilibrium, cell retains its normal shape
Osmosis
Effects of Tonicity
lrn.org
Assisted Membrane Transport
• Two types– Carrier mediated • Transport of small hydrophilic molecules• Require a conformational change of as transport
protein• Depends on: specificity, saturation (Tm), competition
– Vesicular transport• Transport of large molecules or many molecules at a
time• Formation of vesicles needed
Facilitated Diffusion and Active Transport
• Facilitated diffusion– Similar to simple diffusion, but requires a carrier– Glucose and amino acids
• Active transport– Moves substances against their concentration
gradient• Requires energy• Primary and secondary active transport
Sodium Potassium Pump
Secondary Active Transport
• Depends on primary active transport
• Symports– SGLT
• Antiports
Bulk Passage
• Endocytosis– Phagocytosis– Pinocytosis– Receptor-mediated
• Exocytosis
Membrane Potential• Separation of opposite
charges across the plasma membrane– Occur in thin areas
adjacent to the membrane
• Electrical potential measured in mV
• Na+, K+, A- responsible for maintaining resting membrane potential faculty.irsc.edu
Membrane Potential• K+ more concentrated in the ICF
– If K+ diffuses out, the ICF becomes more negative– K+ attracted by negative charge, moves into cell– Equilibrium is reach, membrane potential will equal -90mV
• Na+ more concentrated in the ECF– Diffuses into the cell– Inside becomes more positive– Equilibrium potential of Na equals 60mv
• Must consider both at the same time– Resting membrane potential typically -70mV– K+ has more influence because membrane more permeable to it