Principles of Cell Membrane Function (Lectures 1 & 2)
Proteosome
degradation of intracellular proteins
Transmembrane Proteins
examples: ion channels/pres, carriers, active pumps move H20 Soluble substances, large polar molecules & ions alpha-helixes line up to facilitate movement of ions across membrane
Lysosome
intracellular degradation Contain powerful hydrolytic (digestive) enzymes Synthesized in the golgi complex as coated vesicles Debris can be brought into lysosome via endocytosis or if cell is damaged the lysosome releases its granular contents and digests the cell
Ligand Binding Receptors (Integral Membrane Proteins)
ligands bind to the extracellular domain ---> cause a conformational change ---> physiological response ex: GPCR ---> adregenic, muscarinc, angiotensin, vasopressin ex: second messengers (cAMP, IP3)
Membrane Permeability Depends on?
lipid:acqueous partition coefficient
Cytoskeleton Components
microtubules, microfilaments, intermediate filaments, microtrabecular lattice
Phospholipids in Inner Leaflet
phosphatidylserine, phosphatidylethanolamine phosphatidylinositol involved in signal transduction (PIP2) know chart organelle concentrations
Phospholipases
phospholipids are substrates for phospholipases Phospholipase C is effector for Gq/GPCR (cleaves PIP2 to IP3 and DAG activating PKC) PLA2 cleaves arachidonic acid in plasma membrane to prostaglandins + leukotrienes PI3 Kinase converts PIP2 to PIP3 PIP2 = Phosphatidylinositol 4,5 Biphosphate IP3 = Phosphatidylserine
Microfilaments
smallest element, made up of actin Function: 1. Important in contractile systems (muscles) 2. Cells moving away from each other during mitosis (cell division) 3. Responsible for ameboid movement (pseudopodia) 4. Stiffen microvilli structure (important in brush border)
Cholesterol
steroid ring binds to fatty acid chains and partially immobilizes them provides rigidity to plasma membrane hypercholesteremia's disrupt the ability of plasma membrane (phospholipids) to interact normally
Secretory Pathway
synthesis and processing of membrane and secreted proteins occurs in the RER RER > transport vesicles > cis-golgi > trans-golgi > secretory vesicles > plasma membrane Membrane proteins go through a sorting process and gather in the trans-golgi so carrier vesicles can insert them into their bilayers
Functions of Integral Membrane Proteins
1. Ligand-binding receptors 2. Ion Channels/Pores 3. Adhesion Molecules 4. Carrier Proteins 5. Active Pumps
Extracellular Ca2+ Concentration
1.1-1.4 (ionized) mmol/L
Intracellular Na+ Concentration
10-15 mEq/L
Intracellular Ca2+
10^-7 (super small) ionized mmol/L
Intracellular K+ Concentration
120-150 mEq/L
Extracellular Na Concentration
135-147 mEq/L
Sphingolipids
2nd major class of membrane lipids derived from sphingosine instead of glycerol interact with bilayer to prevent lipid molecules from diffusing away from membrane ex: spingomyelin & galactocerebrosides
Extracellular K+ Concentration
3.5-5 mEq/L
Extracellular Cl- Concentration
95-105 mEq/L
Vesicular Transport is regulated by:
Binding to small G-proteins (GTP/GDP binding proteins) that regulate assembly and delivery of contents SNARE proteins = 1. vesicular (vSNAREs) on vesicular membranes interact with 2. target (tSNAREs) on plasma membranes > exocytosis (neurotransmitters) Vesicles contain structural proteins or lipids in their membranes to direct specific membrane compartments (cell membranes)
Microtrabecular Lattice
Consists of a network of thin filaments running through the cytoplasm, anchoring to the PM suspend other cytoskeletal components (such as free ribosomes) may be involved in coordinating complex rxns in cytosol
Types of Secretion
Constitutive Secretion = occurs immediately after synthesis (leukocytes, hepatocytes, keratinocytes, fibroblasts) Regulated Secretion = substances stored in vesicles, exocytosis occurs in response to signals (neurons, endocrine cells, exocrine cells, and leukocytes)
Peroxisome
Detoxification of substances
Microtubule Stability
Dynamic instability is needed for normal function Provides tracks for movement of organelles Stability depends on rate of polymerization (addition of tubulin subunits) to rate of GTP hydrolysis to GDP by Beta subunit GTP cap stabilizes microtubule > if lost it becomes unstable and will depolymerize
Dyneins & Kinesins
Dyneins and Kinesins Use energy from ATP hydrolysis to move chromosomes, vesicles, and other organelles along microtubules Unidirectional, move cargo in one way Dyneins move things RETROGRADE (towards - end) Kinesins move things ANTEROGRADE (+ end)
Integral Membrane Proteins
Embedded in plasma membrane Attached by covalent bonds Types: Transmembrane - span lipid bilayer ECF/ICF multiple times - contain amphipathic alpha helices miscible with hydrophobic bilayer Embedded Lipid-anchored (bound to lipid by covalent bond)
Phospholipid Structure
Fatty Acids (FA tails) are nonpolar & hydrophobic Heads are Polar & Hydrophilic = amphiphatic, miscible in H20 or lipids forms a bilayer, that allows heads to dissolve in water and tails to repel water
Adhesion Molecules
Form physical contacts with the extracellular matrix that surround the cell for cell interactions examples: Cell- Matrix: integrins: allow communication between cell & its surrounding tissue Cell-Cell: - Cadherins: Ca2+ dependent (glycoprotein) - N-CAMs: Ca2+ independent, function in immune cell movement loss of cell adhesion molecules is observed in metastatic tumors
Smooth ER
Lack ribosomes (smooth appearance) Abundant in cells involved in lipid metabolism and synthesis (steroid hormones) SER in liver is a system known as the microsomal enzyme oxidizing system (MEOS) or cytochrome P450 Sarcoplasmic reticulum in muscles cells control levels of Ca2+ available to muscle for cell contraction
Microtubules
Largest cytoskeletal element, made of tubulin Function: 1. for cell structure and shape, especially neurons 2. transport secretory vesicles, especially neurons 3. Intracellular protein trafficking 4. sperm movement 5. cell division, during mitosis Both cilia and flagella are composed largely of microtubules, outgrowths of a basal body in the cell
Composition of Plasma Membrane
Lipids & Proteins are major constituents Lipids create hydrophobicity to prevent diffusion of many endogenous substances
Lipids of the Plasma Membrane
Lipids found primarily in glycerol based phospholipids glycerol is esterfied to fatty acids & phosphate = phosphodiester other lipids: glycolipid & cholesterol
Microtubule Structure
Long hollow, cyclindrical structure has protofilaments tubulin is a heterodimer = alpha and beta subunits Minus (-) End = closest to centrosome, bordered by alpha subunit Plus (+) End = extends from centrosome = beta subunit Alpha & Beta Subunits bind GTP and tubulin (faster on + side because only beta has GTPase Activity) examples: dynesin/kinesin
Tay-Sachs
Lysosomal storage disease Accumulation of gangliosides in neurons Causes seizure, blindness, degeneration of motor and mental performance
Actin
Most abundant protein F-Actin: filamentous, intact, attaches to cytoskeleton & proteins, (tips of microvilli) G-Actin: globular Interact with integrin receptors and form focal adhesion complexes for cell traction
Ion Channels/Pores (Integral Membrane Proteins)
Non-Gated - leaky channels are always open & ready for passive flow of ions down an electrochemical gradient Gated - regulated by various stimuli (chemical, voltage, mechanical) - gating determines when ions can move/whether It is open or closed
Peripheral Membrane Proteins
Not embedded in cell membrane, loosely attached via electrostatic interactions located on either side (just one side) Hydrophillic removed by salt solutions that disrupt ionic/hydrogen bonds example: Ankyrin "anchors" cytoskeleton in RBCS
Phospholipids in Outer Leaflet
Phosphatidylcholine, Sphingomyelin know chart organelle concentrations
Fluid-Mosaic Model of Membranes
Phospholipids & proteins "float" within the membrane & can diffuse "freely" over the membrane surface Free movement may be impeded by cytoskeletal structures in the cytoplasm Membranes are dynamic structures Membrane fluidity and permeability is influenced by cholesterol and degree of saturation of FA more double bounds (especially cis) = more fluid
Vesicular Transport
Products destined to remain inside the cell are in coated vesicles covered with clathrin (protein) > forms a lattice around the vesicle and associated proteins that later serve as recognition signals (receptor mediated endocytosis via clathrin coated pits) = Integral Proteins Products destined to leave the cell are in secretory vesicles > much larger than the coated vesicles and found in protein hormone producing cells > fuse with the plasma membrane and release contents via exocytosis
Chemical Nature of Phospholipids
Results in formation of a hydrophobic barrier to compartmentalize molecules to functionally distinct locations in the cell allows for creation of ion concentration gradients ex: proton H gradient for ETC, Na/K gradient needed for cell functions
Endoplasmic Reticulum
Rough ER (RER) = covered with ribosomes, site of protein synthesis 3 pathways for the insertion of membrane proteins depending on the organelle = mitochondrial, peroxisome, and plasma membrane/all other organelles mRNA has localization signal that determines if a secretory, membrane or cytosolic protein will be synthesized Secretory and membrane proteins are synthesized in the rough ER (RER) whereas cytosolic proteins are synthesized by free ribosomes in the cytosol All cells have RER (greater the secretory function the more abundant)
Cytosol
Semi-fluid (gelatinous) substance Contains cytoplasmic organelles Contains many enzymes that function in intermediary metabolism (sugars, fats, amino acids) Many "free" ribosomes to produce cytosolic proteins Cytosol also have inclusion bodies which fluctuates depending on the cell (glycogen storage vessels)
Intermediate Filaments
Stable (not reversibly assembled and disassembled) Neurofilaments are found in nerve cells and help stabilize projections from cell body Stabilize actin-myosin interaction in skeletal muscle Skin strength due partly to interlocking intermediate filaments (cells would rupture/blister without them) Proteins that make-up IF's are cell specific and used as cellular markers (vimentin is found in fibroblasts, cytokeratin in epithelial cells),
Golgi Apparatus
Stacked flattened membranous sacs (number of stacks is dependent on cell type)
Voltage Gated Ion Channels Characteristics
Voltage sensors = S4 Ion selective pore = between S5 & S6 Example = Na+ channels open/close (depolarize/hyperpolarize) alpha-subunits have 6 transmemebrane domains
Voltage Gated Ion Channels Examples
activated Na+ channels open and close as the membrane is depolarized or hyperpolarized transmembrane protein has voltage sensors and a selectivity filter example: Nicotinic Receptors when Na" channels open in response to ACh binding to alpha-subunits, Na+ moves down a concentration gradient
Cell/Plasma Membrane
cell envelope, separates cell from external environment serves as a barrier fluid within the cell is ICF, fluid outside is ECF (separates these compartments)
Glycocalyx (Peripheral Membrane Proteins)
consists of negatively charged glycosaminoglycans, giving the plasma membrane a fuzzy like coating Function: 1. repel negatively charged substances 2. attach to other cells 3. cell-cell recognition 4. play a major role in renal corpuscle (protein) where It is found on the lining of the capillary endothelium, negative charge repels large negatively charged macromolecules from leaking through the glomeruli
