Cellular Biology - Plasma Membrane Structure PDF

Summary

This document discusses the structure and function of the plasma membrane in cells. It explains concepts such as lipid bilayer, protein confinement, and membrane fluidity. The document also describes various methods for studying membrane properties.

Full Transcript

Aggregates, tethering, tight junctions
**Protein Confinement**: 7. Membrane Protein Organization
Cell cortex and spectrin network (e.g., in red
blood cells)

Artificial membrane models for studies **Liposomes**: Separation of dif environments

SDS, Triton used to study integral membrane Adhesion & fixation
proteins, they can be isolated
from the lipid bilayer by solubilization using
**Detergents**: 6. Membrane Tools & Methodologies Force transmission to cytoskeleton
detergents
1. Plasma Membrane Overview **Functions**: Exchange & transport
Measures protein/lipid mobility
**FRAP (Fluorescence Recovery After
Photobleaching)**: Signal reception and transmission
Fusion protein technique with GFP
Cellular recognition (cells identify and interact
with each other or with molecules)
Chain length of hydrocarbon tails

Degree of saturation (unsaturated = more fluid) Amphipathic (hydrophobic (polar) and
Composed of 2 fatty acids attached to a polar Closed structure to avoid the exposure of
**Fluidity affecting Factors**: 5. Membrane Dynamics hydrophilic (non polar) regions in the same
head hydrophobic hydrocarbon tail to water
Cholesterol content molecule), bilayer formation
**Phospholipids** (Main components of cell
membrane )
Temperature effects Cellular Biology - Types: Phosphatidylethanolamine,
Phosphatidylcholine, phosphatidylserine (in the
Plasma Membrane inner layer), Sphingomyelin

Outer leaflet: Phosphatidylcholine,
Sphingomyelin, Glycolipids
Structure Stabilizes membranes by intercalating between
phospholipids (OH= hydroxyl)
**Lipids (40%)** **Cholesterol**
Inner leaflet: Phosphatidylethanolamine, Prevents excessive fluidity
**Leaflet (couche) Composition**:
Phosphatidylserine
Found on the Surface
Cholesterol in both leaflets of All Eukaryotic Plasma Membranes
**Glycolipids**
Converting extracellular signals into 4. Membrane Asymmetry
Responsible for cell signaling & recognition
intracellular
ones, specifically through negatively charged
Types: Transmembrane (1 to 5), Lipid-linked (1, 7,
phospholipids in the cytosolic face of the
8), Peripheral proteins (9 and 10)
plasma membrane **Functional Importance**:
2. Membrane Composition Functions: Enzymes, transporters, receptors,
distinguish Cell death (apoptosis) **Membrane proteins**:
adhesion proteins

**Proteins (52%)** Amphipathic nature, alpha-helices, or beta-
Membrane as a dynamic and heterogeneous barrels
structure (different phospholipids,
proteins, and complex sugars) **Protein diffusion**: Lateral diffusion (FRAP method)
**Fluid Mosaic Model**
fluid because the phospholipids and Protects cells, aids in recognition (e.g., blood
proteins can move within the plane of the group antigens)
membrane
**Carbohydrates (8%)** **Glycocalyx**:
3. Membrane Structure short chains of sugars (oligosaccharides) linked
spontaneous bilayer formation to
them - glycoproteins. Others have longer
Movement types: lateral diffusion, rotation, polysaccharide chains - proteoglycans
2D fluidity **Lipid Bilayer**
flexion, rare flip-flop

Trilamellar structure