Membranes

Question 1

What are the functions of cell membranes ?

Answer 1

• Compartmentalisation
• Providing a selectively permeable barrier
• Transporting solutes
• Communication and intracellular interactions
• Scaffold for biochemical pathways and activities
• Scaffold for attachments to cytoskeleton and adjacent cells

Question 2

Summarise the importance of compartmentalisation

Answer 2

• separates organelles from the cytoplasm so each organelle is doing its own function simultaneously
• increases the efficiency of subcellular processes by confined spaces in cells
• it allows the creation of specific microenvironments

Question 3

Summarise the importance of the membrane providing a selectively permeable barrier

Answer 3

• it prevent unrestricted exchange of molecules
• allows communication between compartments

Question 4

Summarise the importance of membranes transporting solutes

Answer 4

Helps organelles to communicate with each other and the external environment

Question 5

Compare and contrast methods of transporting solutes

Answer 5

1) simple diffusion -
- passive
- no specialised proteins required
- goes down a concentration gradient
2) facilitated diffusion -
- passive
- carrier proteins needed
- goes down a concentration gradient
3) osmosis
- passive
- specific to water
- goes down a concentration gradient
4) active transport
- active (requires energy from ATP)
- goes against a concentration gradient
- requires specialised channel and carrier proteins

Question 6

Summarise the importance of communication and intracellular interactions

Answer 6

External stimuli is transmitted into cells via specific receptors in the plasma membrane and so cells need to carry out specific responses
Stimuli includes nutrients, ions, hormones, viruses and toxins
Responses include endocytosis, intracellular signalling cascades , mitosis and changes in gene expression

Question 7

Summarise the importance of membranes acting as a scaffold for biochemical pathways and activities

Answer 7

• Membranes are sites of chemical reactions where enzymes involved are embedded in membrane structure
• Membranes provide scaffolding within which components can be ordered for effective interaction
• Membranes bring enzymes and substrates closer to each other to increase their collisions
• Membranes are sites of energy transduction (chemical gradients are transformed into electrical gradients)

Question 8

Summarise the importance for membranes acting as a scaffold for attachments to the cytoskeleton and adjacent cells

Answer 8

• the membrane supports the cytoskeleton by providing attachment sites
• the cytoskeleton interacts with the extracellular matrix via transmembrane molecules providing cell shape and strength

Question 9

Summarise the general properties of membranes

Answer 9

• it is a sheet like bilayer composed of polar amphipathic lipids
• it is 6-10 nm thick
• all bilayers have a cytosolic face (faces the cytoplasm) and exoplasmic face (faces the external environment)

Question 10

How is the phospholipid bilayer held together ?

Answer 10

It is held together by cooperative non-covalent interactions -
• hydrophobic interactions - these ensure the hydrocarbon tails are isolated from aqueous surroundings
• van der waals forces - attraction between hydrocarbon tails favours close packing
• electrostatic and hydrogen bonding - interactions between polar heads and water molecules keeps the bilayers together
• bilayers 1 - close in on themselves to form compartments
• bilayers 2 - invagination (endocytosis) and evagination (exocytosis)

Question 11

Summarise the fluid - mosaic model

Answer 11

• proposed by Singer and Nicholson in 1972
• it describes how the phospholipids, cholesterol molecules, proteins and carbohydrates are distributed across membranes
• mosaic : the membrane is fluid which makes it impossible for it to form an impenetrable barrier
• lipids can diffuse laterally, rotate and flip flop
• proteins can only diffuse laterally and rotate but never flip flop

Question 12

Summarise membrane composition

Answer 12

Membrane composition varies with cell type and it defines a cell’s function.
The bilayer components are distributed unequally between the 2 surfaces to create asymmetry.

• lipids and sterols form the permeable barrier
• proteins carry out majority of the functions
• polysaccharides linked to lipids make glycolipids and polysaccharides linked to proteins make glycoproteins used for signalling

Question 13

Describe the structure and function of a nerve cell membrane

Answer 13

Structure : lipid 76% - protein 18% - carbohydrate 3%
Function : it insulates axons of peripheral nerves and has a high stability and so a low metabolic activity

Question 14

Describe the structure and function of a red blood cell membrane

Answer 14

Structure : lipid 43% - protein 49% - carbohydrate 8%
Function : stable and metabolically active so it can transfer oxygen to tissues and remove carbon dioxide

Question 15

Describe the structure and function of a mitochondrial inner membrane

Answer 15

Structure : lipid 24% - protein 76% - carbohydrate - 0%
Function : high metabolic activity for the electron transport chain in aerobic respiration

Question 16

What are the general rules for chemical diversity of membranes ?

Answer 16

• higher percentage of lipids = more stable
• greater amounts of protein (enzymes) = high metabolic activity
• polysaccharides are absent from internal membranes
• cholesterols reduce the permeability of the membrane and increase compressibility

Question 17

Describe the mobility of lipids in the bilayer

Answer 17

Lipids can undergo rapid lateral diffusion and transverse diffusion
- transverse diffusion is the movement of the phospholipid from one face of the bilayer to the other face
- lateral diffusion gives the membrane fluidity

Question 18

What is the role of the enzymes scramblase and flippase in the mobility of lipids ?

Answer 18

Scramblase enzymes ensure both monolayers remain equally populated
Flippase enzymes move the phospholipids from one face to the other face for asymmetry

Question 19

Why are there different proportions of lipids on either face of the membrane ?

Answer 19

The asymmetrical disposition of the lipids helps to give symmetry

Question 20

What happens if there is no cholesterol present in the cell membrane ?

Answer 20

• The phospholipids could separate from each other leaving gaps in the membrane allowing the passage of unwanted substances
• The phospholipids could get closer together and prevent the passage of important substances
• Could result in diseases such as Alzheimer’s

Question 21

Summarise the distribution of glycolipids

Answer 21

• only found on the exoplasmic leaflet
• unable to show transverse diffusion
• asymmetrically distributed
• protect the cell from mechanical and chemical damage

Question 22

How are membrane proteins classified ?

Answer 22

They are grouped into 3 classes in regards to their relationship with the phospholipid bilayer

Question 23

What are the 3 classes of membrane proteins ?

Answer 23

• intrinsic or integral
• extrinsic or peripheral
• lipid anchored

Question 24

Describe the structure and function of integral membrane proteins

Answer 24

• penetrate hydrophobic core of the bilayer
• single pass or multi pass transmembrane proteins
• totally embedded in the membrane
• function as receptors, channels, transporters and electron transfer agents
• they are amphipathic - have hydrophobic and hydrophilic parts

Question 25

Describe the structure and function of alpha helix transmembrane proteins

Answer 25

• forms alpha helix structure
• lots of hydrogen bonding
• composed mainly of hydrophobic amino acids
• multiple alpha helices can associate to form a channel

Question 26

What are some of the general rules for transmembrane proteins ?

Answer 26

• have a secondary structure (alpha helix or beta pleated sheet)
• the part of the protein that interacts with the hydrophobic core of the membrane is coated with non polar amino acids
• 30 to 90% of the integral membrane proteins are laterally mobile and the rest are anchored to the underlying cytoskeleton
• proteins never flip flop

Question 27

Describe the structure and function of extrinsic proteins

Answer 27

• held to the membrane surface by non covalent ionic and hydrogen bonds
• interact with integral proteins but not the core
• function as enzymes, signal transducers and fibrillar skeleton which anchors integral proteins

Question 28

Describe the structure of a red blood cell membrane

Answer 28

Interactions between the plasma membrane and cytoskeleton maintains the red blood cells biconcave shape
- there are a plethora of protein types

Question 29

Describe the structure and function of glycophorin

Answer 29

• integral protein
• stabilised by non covalent interactions between amino acid side chains
• 60% of total mass made up by 16 oligosaccharide chains

Question 30

Describe the structure and function of spectrin

Answer 30

• extrinsic protein
• there are 2 heterodimers (alpha and beta)
• the 2 heterodimers associate to form a tetramer
• tetramers are joined at both ends to short actin filaments to form junctional complexes
• spectrin forms a mesh underlying the entire membrane

Question 31

Describe the structure and function of actin

Answer 31

• extrinsic protein
• globular protein - around 13 monomers associate to form filaments
• binds ends of spectrin tetramers at the junctional complex

Question 32

Describe the structure and function of an anion channel protein

Answer 32

• homodimer integral multi pass transmembrane protein
• enables the passage of bicarbonate and chloride ions

Question 33

Describe the structure and function of ankyrin

Answer 33

• extrinsic protein
• binds spectrin tetramer and anion channel protein
• forms a cross link between the spectrin mesh and integral anion channel proteins
• it anchors the membrane to the cytoskelton

Question 34

What is hereditary elliptocytosis ?

Answer 34

• red blood cells become elongated and elliptical
• elliptical red bloods are removed prematurely by the spleen which causes anaemia
• caused by mutations in spectrin