Download Membranes

Membranes
Membrane Models
Fig 6-1
Membrane Lipids
• Phosphoglycerides
• AKA:
Phospholipids
Fig 6-2
Phosphoglycerides
• Variety of alcohol
head groups
Fig 6-2
Phosphoglycerides
• Variety of fatty acid
tail groups
Common Fatty Acids
Name
C #
Double Bonds (position)
Myristate
14
0
Palmitate
16
0
Palmitoleate
16
1 (9)
Stearate
18
0
Oleate
18
1 (9)
Linoleate
18
2 (9, 12)
Linolenate
18
3 (9, 12, 15)
Arachidonate
20
4 (5, 8, 11, 14 )
Sphingolipids
• Sphingosine in place of glycerol & 1 fatty
acid
Glycolipids
• Sphingolipids – glycosphingolipids are
predominate glycolipid
• Glycosylphosphatidylinositol – GPI
– Sugar chain on inositol moiety of
phosphatidylinositol
– Used frequently as an anchor for peripheral
membrane proteins
Sterol Lipids
• Cholesterol
– Major animal
membrane sterol lipid
– Major contributor to
fluidity of membranes
– Precursor for steroid
hormone and bile salt
biosynthesis
Physical Properties of Biological
Membranes
• Lipid Compositions
PS = phosphotidylserine, PC= phosotidylcholine, SM = sphingomyelin,
GS = glycosphingosine, PE = phosphotidylethanolamine
Physical Properties of Biological
Membranes
• Computer generated atomic models predicting
molecular arrangements in phospholipid bilayers
Membrane Proteins
• Integral proteins
– Transmembrane
domains
• 25 aa -helix
• -barrel
• H-bonding of all amino
& carbonyl groups
• Hydrophobic residues
– G, A, L, I, V
– Hydropathy
calculations predict
TM domains from
protein sequence
Membrane Proteins
• Peripheral proteins
– Acylation
• Farnesylation
• Myristoylation
–
–
–
–
GPI anchor
Electrostatic interaction
Partial insertion
Association with integral
protein
Transport Complexes
Control of Membrane Permeability
• Selective permeability of membranes
• Control of solute movement across membranes
– Pumps
• "active transport"
• Require energy source to achieve movement
– Carriers
• "passive transport"
• Movement of particles down concentration gradients result in
conformational changes that can allow transport against
gradient
– Channels
• "selective passive transport"
• Opening and closing is regulated
Types of Membrane Pumps
Energy Source
Pump
Bacteriorhodopsin
Substance Distribution
H+
Halobacteria
Halorhodopsin
Cl-
Photoredox
H+
Photosynthetic
organisms
Redox potential
Electron transport
chain NADH oxidase
H+
Mitochondria,
bacteria
Decarboxlyation
Ion-transporting
decarboxlyases
Na+
Bacteria
Pyrophosphate
H+-pyrophosphatase
H+
Plant vacuoles, fungi,
bacteria
ATP
Transport ATPases
Light
various
ions
Universal
ATP-Driven Pumps
Pump
Distribution
Substrate
1 Function
F0F1
Mitochondria,
chloroplasts, bacteria,
plasma membranes
H+
ATP synthesis
V0V1
eukaryotic
endomembranes
H+
ATP-driven H+
pumping
Na/K-ATPase
plasma membrane
3 Na+ for 2 K+
Na/K gradient
generation
H/K – ATPase
stomach & kidney cell
plasma membranes
1 H+ for 1 K+
gastric & renal H
secretion
H-ATPase
plasma membrane in
yeast, plants & protozoa
1 H+
proton gradient
CFTR
respiratory & pancreatic
epithelial cell plasma
membranes
ATP, Cl-
Cl- secretion
Classes of Carriers
F and V family ATPases
Carrier Kinetics
Channel
Proteins
Channel Complexes
Chemiosmotic Cycles