Membrane Chapter 7 - PowerPoint PPT Presentation

1 / 59
About This Presentation
Title:

Membrane Chapter 7

Description:

Membrane Chapter 7 – PowerPoint PPT presentation

Number of Views:88
Avg rating:3.0/5.0
Slides: 60
Provided by: PatB190
Category:

less

Transcript and Presenter's Notes

Title: Membrane Chapter 7


1
MembraneChapter 7
2
Cell membrane
3
(No Transcript)
4
Cell Membrane
  • Plasma membrane
  • Selective permeability
  • Surrounds all living cells
  • 2 molecules thick.

5
G\Chapter_07\A_PowerPoint_Lectures\07_Lecture_Pre
sentation\07_11MembraneSelectivity_A.html
6
Plasma Membrane
  • Interacts with environment
  • Exchanges information
  • Manages the movement in and out of the cell

7
Fluid mosaic model
  • Revised in 1972 by Singer Nicolson
  • Globular proteins imbedded in the membrane
  • Not surrounding the lipid layer
  • Proteins float in the membrane like boats in a
    pond.

8
Plasma membrane
  • Lipid membrane (phospholipids)
  • Protein passageways
  • Allow water-soluble substances to pass

9
Membrane Structure
  • 1. Phospholipid layer
  • 2. Cholesterol
  • 3. Transmembrane proteins
  • 4. Interior protein network
  • 5. Cell surface markers

10
Membrane structure
11
Triglycerides
  • Water insoluble
  • Non-polar

12
Phospholipid
  • Glycerol (3 carbon alcohol)
  • 2 fatty acids
  • Phosphate attached to 3rd carbon

13
(No Transcript)
14
(No Transcript)
15
Phospholipid bilayer
  • Orients polar head toward water molecules
  • Non-polar tail away from water.
  • Non-polar barrier to water soluble molecules

16
Phospholipid bilayer
  • Hydrophobic interactions hold membrane together
  • Phospholipids unanchored proteins move freely
    within the membrane

17
(No Transcript)
18
Cholesterol
  • Cholesterol between lipids
  • Increases or decreases fluidity
  • Depends on temperature.

19
Cholesterol
20
Structures of membrane proteins
  • 1. Peripheral proteins
  • Attached to the surface membrane
  • 2. Integral proteins
  • Extend through the membrane
  • Transmembrane proteins
  • Partway

21
Structures of membrane proteins
  • Non-polar section of protein
  • Contact with the non-polar interior (hydrophobic)
  • Polar section of the protein
  • Extends out of membrane

22
Transmembrane proteins
  • 1. Single-pass anchors
  • 2. Multiple-pass channels and carriers
  • 3. Pores
  • Aquaporins

23
(No Transcript)
24
(No Transcript)
25
(No Transcript)
26
Functions of membrane proteins
  • 1. Transport
  • Allow specific substances to enter or leave
  • 2. Enzymes
  • Carry out reactions on interior surface
  • 3. Cell surface receptors
  • Sensitive to chemical messages

27
Functions of membrane proteins
  • 4. Cell surface identity markers
  • Cell recognition between cells
  • Glycoproteins
  • 5. Cell adhesion proteins
  • Proteins stick to each other
  • Temporary or more permanently
  • 6. Attachments to the cytoskeleton

28
Membrane Proteins
29
Membrane structure
30
Membrane formation
  • Proteins lipids made in ER
  • Processed in Gogi apparatus
  • Vesicles
  • Fuse with membrane
  • Correct orientation

31
Movement across the membrane
  • 1. Passive transport
  • 2. Bulk transport
  • 3. Active transport

32
Passive transport
  • Diffusion
  • High concentration to areas of lower
    concentration
  • Concentrations are the same in all regions

33
Passive transport
  • Two conditions determine the direction of the
    flow of ions
  • 1. Relative concentration of the ion on each side
    of the membrane
  • 2. The voltage across the membrane

34
Diffusion
35
  • D\Chapter_07\A_PowerPoint_Lectures\07_Lecture_Pre
    sentation\07_11Diffusion_A.html

36
Osmosis
  • Net movement of water across a membrane
  • Moves towards an area of higher solute
    concentration
  • Or lower water concentration
  • Passive transport of water

37
Osmosis
  • Osmoregulation
  • Control of water balance

38
Osmosis
  • Hyperosmostic
  • Solution with higher concentration of solute
  • Has less water
  • Hypoosmostic
  • Solution with the lower concentration of solute
  • Has more water
  • Isosmostic
  • Solutions have equal concentration of solutes

39
Solutions
  • Solute
  • Substance being dissolved
  • Common solutes in the cell or cells cytoplasm?
  • Solvent
  • Substance doing the dissolving
  • What is the most common solvent in the cell?

40
Solutions
  • Hypertonic
  • Solution with higher concentration of solute
  • Hypotonic
  • Solution with lower concentration of solute
  • Isotonic
  • Solutions with equal solute concentrations

41
(No Transcript)
42
(No Transcript)
43
Facilitated diffusion
  • Carriers transport
  • Ions, aa or sugars across the membrane
  • Specific for type of solute
  • Moves from high concentration to low
  • The carrier facilitates the process

44
(No Transcript)
45
Examples
  • RBC diffusion of the bicarbonate ion
  • RBC diffusion of glucose

46
Facilitated diffusion
  • 1. It is specific
  • 2. It is passive
  • 3. It saturate
  • Carriers are saturated
  • Transport rate cannot increase
  • Despite the concentration gradient

47
Bulk transport
  • Endocytosis
  • Membrane envelops food particles
  • 1. Phagocytosis
  • 2. Pinocytosis
  • 3. Receptor-mediated endocytosis

48
Bulk transport
  • Phagocytosis
  • The cell engulfs particles
  • Pinocytosis
  • The cell engulfs liquid
  • Receptor-mediated
  • Transported molecules bind specific receptors in
    the plasma membrane

49
Phagocytosis
50
Pinocytosis
51
Receptor-mediated
52
Exocytosis
  • The reverse of endocytosis
  • Discharge of materials from the cell
  • Secretion of many hormones, neurotransmitters,
    digestive enzymes and other substances

53
Active transport
  • Movement of substances against or up the
    concentration gradient
  • Low concentration to high
  • Requires energy.
  • Requires the use of ATP.
  • Cell takes up substances into cytoplasm that are
    already hypertonic to the extracellular fluid.

54
Sodium-potassium pump
  • Protein transports Na and K ions across the
    membrane.
  • Every cycle transports 3 Na ions out
  • Exchange for 2 K ions into the cell
  • Against concentration gradients.

55
(No Transcript)
56
  • D\Chapter_07\A_PowerPoint_Lectures\07_Lecture_Pre
    sentation\07_16ActiveTransport_A.html

57
Coupled transport
  • Molecule moves up its concentration gradient
  • Uses the drive from another substance moving down
    its concentration gradient.
  • Na ions and glucose

58
Fig. 7-19


H
ATP
H


Proton pump
H
H


H
H


Diffusion of H
H
Sucrose-H cotransporter
H


Sucrose


Sucrose
59
(No Transcript)
Write a Comment
User Comments (0)
About PowerShow.com