Chapter 5- Cell Membrane And Factors

Question 1

What is the role of plasma membranes at the surface of cells?

Answer 1

1) they are a barrier between the cell and its environment, controlling which substances enter and leave the cell. They’re partially permeable so allow some molecules to pass through but not others.

2) they allow recognition by other cells eg the cells of the immune system

3) They allow cell communication (sometimes called cell signalling)

Question 2

What is the role of membranes within cells?

Answer 2

1) the membranes around organelles divide the cell into different compartments, so act as a barrier between the organelle and cytoplasm. This makes functions more efficient eg enzymes needed for respiration are kept inside the mitochondria.

2) they can form vesicles to transport substances between different areas of the cell,

3) they control which substances enter and leave the organelle eg RNA leaves the nucleus via the nuclear membrane.

4) membranes within orgsnelles act as barriers between the membrane contents and the rest of the organelle, eg thylakoid membranes in chloroplasts.

5) membranes within cells can be the site of chemical reactions eg the inner membrane of mitochondria contain enzymes for respiration.

Question 3

What model shows the structure of the plasma membrane?

Answer 3

The fluid mosaic model

Question 4

What is the fluid mosaic model?

Answer 4

1) phospholipid molecules form a continuous bilayer
2) the bilayer is “fluid” because phospholipids are constantly moving
3) cholesterol molecules are present, and proteins are scattered throughout
4)some proteins have polysaccharide chain attached called glycoproteins
5) some lipids have polysaccharide chain attached called Glycolipids

Question 5

What is the role of phospholipids in cell membranes?

Answer 5

1) the head is hydrophilic and tail is hydrophobic, so the molecules arrange themselves into a bilayer. The heads face put towards the water.

2) the centre of the bilayer is hydrophobic so the membrane doesn’t allow water soluble substances like ions through it, however lipid soluble substances like vitamins can dissolve through.

Question 6

What is the role of cholesterol in plasma membranes?

Answer 6

1) cholesterol is a lipid present in all cell membranes except for bacterial cell membranes. They fit between the phospholipids. They bond to the hydrophobic tails of the phospholipids, causing them to pack more closely together. This makes the membrane less fluid and more rigid.

2) at lower temperatures, cholesterol prevents phospholipids from packing too close together and so increases membrane fluidity.

Question 7

What is the role of proteins in plasma membranes?

Answer 7

1) some proteins form channels to allow small or charged particles through

2) other proteins (carrier proteins) transport molecules and ions across the membrane by active transport or facilitated diffusion.

3) proteins also act as receptors for molecules eg hormones in cell signalling. When a molecule binds to the protein, a chemical reaction is triggered inside the cell.

Question 8

What is the role of Glycolipids/proteins in plasma membranes?

Answer 8

1) Glycolipid and glycoproteins stabilise the membrane by forming hydrogen bonds with surrounding water molecule.

2) they’re also sites where drugs, hormones and antibodies bind

3) they act at receptors for cell signalling

4) they’re also antigens , cell surface molecules are involved in the immune response.

Question 9

How does cell signalling allow cells to communicate?

Answer 9

1) one cell releases a messenger molecule eg a hormone

2) this molecule travels eg in the blood to another cell

3) this messenger molecule is detected by the cell because it binds to a receptor on its cell membrane

Question 10

How are cell membrane receptors involved in cell signalling?

Answer 10

1) proteins in the cell membrane act as receptors for messenger molecules. These are called membrane bound receptors.

2) receptor proteins have specific shapes, only messenger molecules with a complementary shape can bind to them.

3) different cells have different types of receptors, they respond to different messenger molecules

4) a cell that responds to a particular messenger molecule is called a target cell

Question 11

Example of how drugs bind to cell membrane receptors?

Answer 11

Antihistamines

Cell damage caused the release of histamine. Histamine bonds to receptors on the surface of other cells and causes inflammation. Antihistamines work by blocking histamine receptors on cell surfaces. This prevents histamine from binding to the cell and stops inflammation.

Question 12

How can the permeability of the cell membrane be investigated?

Answer 12

1) cut five equal sized pieces of beetroot and rinse them to remove any pigment released during cutting

2) place the five pieces in five different east tubes, each with 5cm3 of water

3) place each test tube in a water Bath at different temperatures eg 10, 20, 30, 40 degrees Celsius for the same length of time.

4) remove the pieces of beetroot from the tubes leaving just the coloured liquid.

5) now use a colorimeter. The higher the permeability, the more pigment is released so the higher the Absorbance of the liquid.

Question 13

How does temperature affect membrane permeability?

Answer 13

1) temperatures below 0, mean the phospholipids don’t have much energy so can’t move very much. They’re packed closely gehegter wnd membrane is rigid. Channel and carrier proteins deform, increasing permeability. Ice crystals may form and pierce the membrane making it highly permeable when it thaws.

2) temperatures between 0 and 45, mean the phospholipids can move around and aren’t packed at tightly so the membrane is partially permeable. As temperature increases, phospholipids move more because they have more energy so permeability increases.

3) temperatures above 45, means the phospholipid bilayer starts to melt and the membrane become more permeable. Water inside the cell expands, putting pressure on the membrane. Channel and carrier proteins deform so can’t control what enters and leaves the cell, so permeability increases.

Question 14

How does changing the solvent affect membrane permeability?

Answer 14

1) surrounding cells in a Solvent eg ethanol increases permeability of the membrane. This is beacsye solvents dissolve the lipids in a cell membrane so the membrane loses its structure.

2) some solvents increase cell permeability more than others, eg ethanol increases cell permeability more than methanol.

You can investigate the effects of different solvents by doing the beetroot experiment. Increasing concentration of the solvent also increases membrane permeability.

Question 15

What is diffusion?

Answer 15

Diffusion is the net movement of particles from an area of higher concentration to an area of lower concentration, down the concentration gradient. it is a passive process.

Question 16

What molecules can diffuse through cell membrane via simple diffusion?

Answer 16

1) small non-polar molecules such as oxygen as carbon dioxide are able to diffuse easily through spaces between phospholipids.

2) water is also small enough to fit between phospholipids so can didfduse across plasma membranes even thing it’s polar. Diffusion of water molecules is osmosis.

Question 17

What factors affect the rate of diffusion?

Answer 17

1) concentration gradient
2) thicken of the exchange surface
3) the surface area
4) the temperature

Question 18

How does concentration gradient affect rate of diffusion?

Answer 18

The higher the concentration, the faster the rate of diffusion

Question 19

How does thickness of the exchange surface affect rate of diffusion?

Answer 19

The thinner the exchange surface (the shorter the distance the particles have to travel), the faster the rate of diffusion.

Question 20

How does surface area affect rate of diffusion?

Answer 20

The larger the surface area, the faster the rate of diffusion

Question 21

How does temperature affect rate of diffusion?

Answer 21

The warmer it is, the faster the rate of diffusion because the particles have more kinetic energy so they move faster.

Question 22

How can you investigate diffusion in cellls?

Answer 22

1) make up some agar jelly with phenolphthalein and dilute sodium hydroxide. This will make jelly pink .

2) then fill a beaker with some dilute hydrochloric acid. Use a scalpel to cut a few cubes from the jelly and place them in the acid.

3) if you leave cubes for a while, they’ll eventually turn colourless as acid diffuses into agar jelly, and neutralises the sodium hydroxide.

Question 23

How can you change the agar jelly experiment according to the factor being investigated?

Answer 23

Surface area - cut agar jelly into different sized cubes and work out surface area to volume ratio. Record the time taken for each cube to go colourless.

Concentration gradient - use different concentrations of hydrochloric acid. Put equal sized jelly cubes in each test tube and time which cubes go colourless first.

Temperature - place the tee tubes with the same concentration of hydrochloric acid into water baths if varying temperatures. Use equal sized agar jelly cubes and time how long it takes to become colourless.

Question 24

What is facilitated diffusion?

Answer 24

1) so,e larger molecules, ions and polar molecules don’t diffuse directly into the membrane and need to diffuse through carrier and channel proteins.

2) particles move down a concentration gradient so it’s a passive process

Question 25

What are carrier proteins?

Answer 25

They move large molecules into and out of the cell.

1) first, a large molecule attaches to a carrier protein in the membrane

2) then the protein changes shape

3) this releases the molecule on the opposite side of the membrane

Question 26

What are channel proteins?

Answer 26

Channel proteins form pores in the membrane for charged particles to diffuse through.

Question 27

What is active transport in cell membranes?

Answer 27

Active transport uses atp to move molecules and ions across plasma membranes, against a concentration gradient. This involves carrier proteins.

Question 28

How do cells take in substances by endocytosis?

Answer 28

1) some molecules are too large to by taken into the cell by carrier proteins eg proteins and lipids.

2) a deal surrounds a substance with a section of its plasma membrane.

3) the membrane then pinches off to form a vesicle inside the cell containing the ingested substance. This process requires energy

Question 29

Example of endocytosis in the body?

Answer 29

White blood cells use endocytosis to take in things like microorganisms and dead cells so they can destroy them.

Question 30

How can cells secrete substances by exocytosis ?

Answer 30

1) some substances produced by the cell eg digestive enzymes need to be released from the cell.

2) vesicles containing these substances pinch off from the sacs in the Golgi apparatus and move towards the plasma membrane.

3) the vesicles fuse with the plasma membrane and release their contents outside the cell. This process used ATP

4) some substances like membrane proteins are inserted straight into the plasma membrane instead.

Question 31

What is osmosis?

Answer 31

The diffusion of water molecules across a partially permeable membrane down a water potential gradient. Pure water has the highest water potential.

Question 32

How are animals cells affected by water potential

Answer 32

Hypotonic solution (water potential is greater in solution than cell) - water moves into cell causing the burst (lysis)

Isotonic (same water potential) - the cell stays the same

Hypertonic (water potential greater inside cell than outside) - movement of water out of the cell causing cell to shrink (crenation).

Question 33

How does water potential affect plant cells?

Answer 33

Hypotonic solution (water potential outside greater than inside cell) - water moves in and vacuole swells. Cell becomes turgid.

Isotonic solution (same water potential) - cell stays the same

Hypertonic solution (water potential inside cell greater than outside) -water leaves the cell and cell becomes flaccid. Cytoplasm and membrane pull away from cell wall. This is called plasmolysis.