1 / 57

Membranes: Keeping things where they belong

Membranes: Keeping things where they belong. Separate functional and anatomic fluid compartments in the body. Regulate the transport of materials between compartments. Connections between plasma membranes. Extracellular matrix: primarily secreted by fibroblasts.

shaquana-young
Télécharger la présentation

Membranes: Keeping things where they belong

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Membranes: Keeping things where they belong • Separate functional and anatomic fluid compartments in the body. • Regulate the transport of materials between compartments

  2. Connections between plasma membranes • Extracellular matrix: primarily secreted by fibroblasts. • Collagen: forms cable-like fibers that provide tensile strength; especially important in skin and blood vessels. *Scurvy: in vitamin C deficiency these fibers are not properly formed. • Elastin: rubber-like protein where elasticity (ability to return to pre-stress orientation) is important; especially important in arteries and lungs. • Fibronectin: promotes cell-cell adhesion and can hold cells in position.

  3. Adjacent intestinal epithelial cells

  4. Tight Junctions Intracellular Extracellular Transmembrane Proteins

  5. Tight junctions: zona occludens Impermeable (usually) connectio ns between cells. Cell membranes are attached to each other by strands of junctional proteins. Extracellular matrix Connections between plasma membranes

  6. Extracellular Intracellular keratin filaments Intracellular Spot Desmosome Thickened “plaque” area Intercellular filaments (commonly glycoproteins)

  7. Connections between plasma membranes • Spot desmosomes: macula adherens (~20 nm) • anchor cells together with some space to accommodate movement/stretching. • Cytoplasmic plaque • Intracellular intermediate filaments through cells connecting various plaques • Intercellular glycoprotiens connect the cells • Extracellular matrix • Tight junctions: zona occludens

  8. Extracellular Intracellular Passage of ions And small molecules 1.5 nm Large molecules blocked Gap Junctions Connexons

  9. Connections between plasma membranes • Gap Junctions: no fancy latin name; 2-4 nm • Communication between cells through connexons • Permit passage of small ions and particles between cell's cytoplasm • Extracellular matrix • Tight junctions: Tight junctions: zona occludens • Spot desmosomes: macula adherens

  10. Membrane Transport • Passive: movement of material without the expenditure of energy. • Simple Diffusion • particles in random motion display net movement relative to two conditions • Chemical gradient: material moves "down" it's concentration gradient.

  11. * Osmosis:the movement of water "down" it's concentration gradient. *Osmotic pressure:a "negative" effective pressure that acts to "pull" water Membrane Transport • Passive: movement of material without the expenditure of energy. • Simple Diffusion • particles in random motion display net movement relative to two conditions • Chemical gradient: material moves "down" it's concentration gradient.

  12. Semi-permeable

  13. X mmHg X mmHg

  14. Passive: movement of material without the expenditure of energy. Simple Diffusion particles in random motion display net movement relative to two driving force conditions Chemical gradient: material moves "down" it's concentration gradient. Ionic charge: electrical attaction/repulsion Other factors influencing volume-rate diffusion Permeability of the membrane to the substance Lipid-soluble-passes through Water-soluble - generally require selective channels or pores Molecular weight of the substance Surface area Distance (thickness of the membrane) Facilitated (carrier-mediated) diffusion - the diffusion of the material occurs via specialized protein "carriers" Membrane Transport

  15. Passive: movement of material without the expenditure of energy. Simple diffusion Facilitated (carrier-mediated) diffusion - the diffusion of the material occurs via specialized protein "carriers" particles in random motion display net movement relative to their electrochemical gradient Display unique characteristics Specificity: only one molecule (or class of molecules) transported Saturation: The rate of transport of molecules is limited to the number of carriers. There are only so many lifeboats on the Titanic Competition: When the carrier can transport multiple forms of a molecule (or drugs that closely resemble the molecule), the multiple forms compete for the limited number of carriers. If a ferry has 100 seats, and 70 are occupied by women, ony 30 men are getting across. Membrane Transport

  16. Passive: movement of material without the expenditure of energy. Simple diffusion Facilitated (carrier-mediated) diffusion Active Transport: requiring the expenditure of energy Primary: Energy used directly in transport of the molecule(s) Membrane Transport

  17. Passive: movement of material without the expenditure of energy. Simple diffusion Facilitated (carrier-mediated) diffusion Active Transport: requiring the expenditure of energy Primary: Energy used directly in transport of the molecule(s) Typical series of events ATP is used to phosphorylate the carrier carrier becomes exposed to the side with low concentration of the molecule to be transported Increased affinity for the transported molecule Binding of the molecule usually causes conformational (structrural) change Molecule is exposed to high concentration side Carrier is dephosphorylated Affinity for the molecule decreases, and the molecule is released Simple design: one molecule (or class), one direction Complex designs: multiple molecules; mutiple directions Membrane Transport

  18. Passive: movement of material without the expenditure of energy. Simple diffusion Facilitated (carrier-mediated) diffusion Active Transport: requiring the expenditure of energy Primary: Energy used directly in transport of the molecule(s) Typical series of events ATP is used to phosphorylate the carrier carrier becomes exposed to the side with low concentration of the molecule to be transported Increased affinity for the transported molecule Binding of the molecule usually causes conformational (structrural) change Molecule is exposed to high concentration side Carrier is dephosphorylated Affinity for the molecule decreases, and the molecule is released Simple design: one molecule (or class), one direction Complex designs: multiple molecules; mutiple directions Counter-transport: multiple molecules, opposite direction (3Na+/2K+) Co-transport: multiple molecules, same direction (not common) Secondary:Potential energy of another molecule used (commonly Na+) Membrane Transport

  19. Passive: movement of material without the expenditure of energy. Simple diffusion Facilitated (carrier-mediated) diffusion Active Transport: requiring the expenditure of energy Primary: Energy used directly in transport of the molecule(s) Secondary: Potential energy of another molecule used (commonly Na+) Counter-transport: multiple molecules, opposite direction (Na+/H+) Co-transport: multiple molecules, same direction (Na+/Glucose) Vesicular Clathrin "coated pit" pathway Endocytosis Exocytosis Potocytosis- the caveolae pathway Specialized caveolin-rich "pit" in membranes with cholesterol-stabilized constituents Sometimes maintains "tether" connection to the membrane Involved in many receptor-mediated communication processes Membrane Transport

  20. Membrane Potential

  21. An electrical potential caused by unbalanced distribution (in/out) of cations and anions. All cells Can primarily be attriubuted to Na/K exchange pump: pumps more cations out than anions in. Differences in permeability to Na and K: cell is much more permeable to K than to Na; the concentration gradient (K our) is balanced by the attraction of anions inside. Membrane impermeable anionic proteins Membrane Potential

  22. An electrical potential caused by unbalanced distribution (in/out) of cations and anions. All cells Can primarily be attriubuted to Na/K exchange pump: pumps more cations out than anions in. Differences in permeability to Na and K: cell is much more permeable to K than to Na; the concentration gradient (K our) is balanced by the attraction of anions inside. Membrane impermeable anionic proteins Uses of the membrane potential: Communication via electrical transmission - primarily nerve and muscle Secondary energy source for transport Membrane Potential

  23. Cellular Communicaton

  24. Autocrine Endocrine

  25. Neural

  26. Gated Channels- receptor activation "opens" channels for ions to move Electrical potential transmission Ions controlling secretion (eg: Ca) Second-messenger systems G-protein coupled Communications Ligand-receptor mediation

  27. GTP E1 E2 γ β α GDP

  28. γ γ β β GTP E1 E2 α α GDP

More Related