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Starter Activity: Answer the following question in your classwork
jotter 1. What type of fibres are the cell walls of plants
made of? 2. Name the small rings of DNA found in bacterial
cells. 3. Name the process by which yeast cells
reproduce. 4. What is the function of a) ribosomes? b) mitochondria?
Answers
1. Cellulose
2. Plasmids
3. Budding
4. a) protein synthesis
b) respiration
Key Area 2
Transport across cell membranes
The Cell Membrane
Learning Intention: • Describe the structure of the cell membrane Success Criteria: • Be able to describe the structure of the cell
membrane. • Explain the terms ‘selectively permeable’ and ‘fluid
mosaic’
The Function of the Cell Membrane
Twig Video Clip: The Cell Membrane
Whilst you are watching the video clip write down key words on a show me board.
• The cell membrane is known to contain protein and phospholipid molecules.
• These molecules are arranged in a fluid mosaic structure
Fluid Mosaic Model
Fluid Mosaic Model
The cell membrane consists of:
• phospholipid molecules that are constantly moving which makes the structure fluid.
• Patches of protein molecules which form a mosaic.
Phospholipid bilayer
• The water-soluble hydrophilic heads make up the two outer surfaces of the bilayer.
• One layer of heads forms the outside of the cell membrane and the other layer forms the inside of the cell membrane in contact with the cytoplasm.
Water insoluble hydrophobic tails point inwards to the centre of the bilayer since they are attracted to those in the opposite layer.
An effective boundary.
• This arrangement of phospholipids is fluid but also stable.
• It forms an effective boundary around the cell.
• It allows tiny molecules such as water to pass through it rapidly.
• Larger molecules such as glucose rely on the membrane’s protein molecules to enter or leave the cell.
Cell membrane proteins. These are found: • attached to surface of the membrane. • embedded within the membrane. • as channels (pores) which span the membrane.
Functions of Proteins
• Structural support
• Channels
• Carriers
• Enzymes
• Receptors
• Antigenic markers
The cell membrane is SELECTIVELY PERMEABLE, and controls which substances can enter and leave the cell.
Specificity
• Proteins have a unique shape and only allow certain molecules to pass through the membrane.
Mobile
The fluid nature of the membrane allows proteins to move about within the bilayer.
Homework task - Make a 3D cell membrane model
• Your task is to make a 3D model of the cell membrane.
• You can use any materials you can find at home, especially recycling materials.
• Your model should show the proteins and the phospholipids with their head and tail ends.
• The component parts should be labelled or there should be a key to identify them.
• Examples of materials you could use include paper, cardboard, plastic bottle lids, plasticene, playdoh, straws, cotton buds, cocktail sticks, buttons, ribbons, fabric, lolly sticks, dry pasta, lego, stickle bricks, k’nex.
• THE POSSIBILITIES ARE ENDLESS SO HAVE FUN!
Quick Questions
1. What does the word Hydrophobic mean?
2. What does Hydrophillic mean?
3. Which molecules in the membrane have hydrophillic heads and hydrophobic tails?
4. Give 3 functions of a protein in the cell membrane.
5. Why is the membrane described as ‘fluid’?
6. Name a molecule that can move freely through the cell membrane.
7. Name a molecule that has to pass through a protein channel to get through the cell membrane.
8. Explain why the membrane is ‘selectively permeable’
Visking tubing
• Visking tubing is a selectively permeable material that acts like a cell membrane.
• We can use it to demonstrate which molecules are able to pass through the membrane, and which are not.
• Your teacher will show you how to use the visking tubing in an experiment.
Visking tubing experiment
Water
Visking tubing bag
Starch and glucose solution
Test water for starch and glucose after 20 minutes
Visking tubing experiment
1. Soften a length of visking tubing under running water until you can open it up.
2. Tie a firm knot in one end. 3. Add equal volumes of starch and glucose solutions
using droppers. 4. Tie a firm knot in the other end. Cut off any excess
tubing to leave 1cm tails. 5. Wash the bag thoroughly under running water. 6. Place bag in a test tube, cover with water and leave
for 20 minutes. Remove the bag. 7. Transfer a drop of the water to a spotting tile and
test for starch using iodine. 8. Test the remaining water for glucose by adding
Benedicts solution and heating to 80°C for 5 minutes.
Visking tubing experiment Results:
Colour change observed
Result of test – positive or negative
Starch test (iodine)
Glucose test
(Benedicts)
Conclusion : The ______was able to pass through the visking tubing but the _______was not. This is because starch has ________ molecules but glucose has ________molecules.
Selectively Permeable Membranes
• Cell membranes allow small molecules like glucose, oxygen and water to pass through them freely.
• This is because the membrane has tiny holes in it called pores that make it permeable. Large molecules like starch are unable to pass through.
Selectively Permeable Membranes
• Pores in the membrane are small, so only small molecules such as glucose, water, oxygen and carbon dioxide can get through.
• Large molecules such as starch cannot pass through.
• Selectively permeable membranes allow certain molecules to pass through but not others.
nucleus
selectively permeable membrane
cytoplasm
The Cell Membrane
Learning Intention: • Describe the structure of
the cell membrane Success Criteria: • Be able to describe the
structure of the cell membrane.
• Explain the terms ‘selectively permeable’ and ‘fluid mosaic’
Starter
Starter
C
Diffusion
Learning Intention: • Understand the process of diffusion • Identify which molecules will pass across
membranes via diffusion. Success Criteria: • Explain the terms passive and active
transport • Define the term diffusion and give
examples of diffusion in cells
Passive transport
• passive transport is the movement of a substance across a cell membrane down a concentration gradient
• It does not require energy.
• The two types of passive transport are:
1. Diffusion
2. Osmosis
Diffusion
• Diffusion is the movement of molecules
in a liquid or gas from high to low
concentration until they are evenly spread
out.
• Diffusion moves down a concentration
gradient.
Diffusion clip
Diffusion in liquids
• Diffusion in liquids can be seen by adding dye to a beaker of water.
Add dye to one side only
Water
Do not shake or stir. Leave for 20 minutes.
Diffusion in liquids
Red dye in water
Red dye molecules and water molecules have moved until they are evenly spread – this is DIFFUSION.
Direction of diffusion
Diffusion always occurs from high concentration of a molecule to low concentration of that molecule.
Concentration Gradient
The difference in concentration of two solutions is called a concentration gradient.
In diffusion, molecules will always move down the concentration gradient from high concentration to low concentration.
Concentration Gradient
high ground
gradient (slope)
low ground
ball ball rolls down gradient
ball stops
•Like a ball on a slope, molecules diffuse down a concentration gradient from high to low.
Concentration Gradient
• A concentration gradient exists when there is
a difference in concentration from one area
to another.
• Molecules move down a concentration
gradient from high to lower concentration.
The molecules will stop moving when the two
concentrations are equal.
Cells and diffusion
• Many substances can enter or leave cells by diffusion.
• This happens across the cell membrane. • Animal cells take in glucose, oxygen and
amino acids by diffusion. • Carbon dioxide and waste materials
leave animal cells by diffusion.
Diffusion in an animal cell
Glucose
Oxygen
Carbon dioxide
Waste
Amino acids
Diffusion
Learning Intention: • Understand the process of diffusion • Identify which molecules will pass
across membranes via diffusion. Success Criteria: • Explain the terms passive and active
transport • Define the term diffusion and give
examples of diffusion in cells
Starter
Starter
Diffusion
Waste/carbon dioxide
Cell membrane
Transport across cell membranes: Osmosis
Learning Intention: Describe the term ‘Osmosis’ Success Criteria: • Define the term osmosis • Investigate the effect of osmosis on
cells.
Osmosis • Osmosis is the special diffusion of water from an area of high concentration to an area of low concentration through a selectively permeable membrane.
High water concentration
Low water concentration
Twig Video Clip - Osmosis
Osmosis in action
Visking tubing
• Visking tubing is a selectively permeable material that can be used to show the effect of osmosis on cells.
• The visking tubing behaves like a cell membrane, so we can use it to make model cells.
Osmosis experiment
A: Pure water B: Concentrated Sugar solution
Visking tubing bag
10% sugar solution
water
Boiling tube
1. Wash and dry bags when filled. 2. Weigh both bags. 3. Place in test tubes for 20 minutes then dry and reweigh.
TEACHER DEMONSTRATION
Osmosis Experiment: Results
A B
Mass of bag and contents at start (g)
Mass of bag and contents after 20 minutes (g)
Difference in mass (g)
Conclusion
• Bag A increased/decreased in mass. This was because water moved in/out by osmosis.
• Bag B increased/decreased in mass. This was because water moved in/out by osmosis.
• Water always moves from ________ water concentration to ______ water concentration.
Answer the following questions in sentences:
1. Why was the visking tubing bag dried in a paper towel before being weighed?
2. Why was visking tubing used in this experiment? What property does it have that makes it a good model cell?
3. What would happen to an onion cell placed in pure water?
4. What would happen to a cheek cell placed in 10% sucrose solution?
Predicting osmosis
Transport across cell membranes: Osmosis
Learning Intention: Describe the term ‘Osmosis’ Success Criteria: • Define the term osmosis • Investigate the effect of
osmosis on cells.
Starter
Starter
C
Osmosis Experiment
Learning Intention:
Investigate the cell membrane and the movement of molecules across it
Success Criteria:
• Understand the term osmosis Understand the effect of osmosis on plant cells
Investigation
Aim: To investigate osmosis in potato cells
Effect of water & concentrated sugar solution on potato cylinders
Diagram
Method 1. Label 2 test tubes A and B.
2. Collect 2 pieces of potato which have been cut with a cork borer.
3. Wash them and roll them on a paper towel to dry them.
4. Weigh one piece, note its mass in the table on your worksheet.
5. Put it in test tube A with water.
6.Note the mass of the other piece and put it in test tube B with concentrated sugar solution.
7.Leave for about 24 hours.
Method
• Remove potato cylinders and pat dry with a paper towel.
• Weigh and measure cylinder A (water) and record on worksheet.
• Weigh and measure cylinder B (sucrose) and record on worksheet.
• Record Softness: + = hard
++ = normal
+++ = very soft
Results
Mass of potato (g)
Change in mass
Length of potato (mm)
Change in length
Softness (+ ++ +++)
Before After (g) % Before After (mm) % Before After
Potato in water (A)
Potato in sugar solution (B)
Calculate % change in mass & length CHANGE IN MASS = mass after expt – original mass
% CHANGE IN MASS = Change in mass x 100
original mass
CHANGE IN LENGTH = length after expt – original length
% CHANGE IN LENGTH = Change in length x 100
original length
What happened to your potato cylinders? Comment on the mass, length and softness of both before and after. Why do you think this happened? Use your knowledge of osmosis to explain your results. Was water moving into or out of the potato cells? Why?
Conclusion
Osmosis Experiment
Learning Intention:
Investigate the cell membrane and the movement of molecules across it
Success Criteria:
• Understand the term osmosis Understand the effect of osmosis on plant cells
Predict the results
• Look at the following examples.
• Which side has the higher water concentration?
• Which way will the water molecules move?
50%
sucrose
10%
sucrose
LWC HWC water
100%
water
10%
sucrose
HWC LWC water
25%
salt
30%
salt
HWC LWC water
10%
sucrose
0.5%
sucrose
LWC HWC water
10%
salt
2%
salt
LWC HWC water
1.0M
NaCl
0.5M
NaCl
LWC HWC water
2.0M
HCl
1.0M
HCl
LWC HWC water
6%
NaOH
10%
NaOH
HWC LWC water
100%
water
100%
water
HWC HWC water
1%
salt
10%
sucrose
HWC LWC water
The effect of osmosis on plant and animal cells
Learning Intention:
Investigate the cell membrane and the movement of molecules across it
Success Criteria:
• Understand the term osmosis Understand the effect of osmosis on plant cells
Which direction?
The direction of the movement of water molecules into or out of a cell depends on the water concentration of the liquid the cell is in compared with the water concentration of the cell contents.
What happens in living cells?
Osmosis and plant cells
Plant Cells
Vacuole
Cell wall membrane
Concentrated salt/sugar solution
Dilute sugar/salt solution
Pure Water
Shrinks as high water concentration inside cell- water lost by osmosis Plasmolysis (cell is Plasmoysed)
Cell Swells-high water concentration outside the cell. Water enters the cell by osmosis Full turgor- cells is turgid
No change
Osmosis and animal cells
Watch cells in water
ANIMAL CELLS Shrinks as high
water concentration
inside cell- water lost
by osmosis
Remains the same
as the movement of
water is equal
across the
membrane
Bursts as high water
concentration
outside the cell.
Water enters the cell
by osmosis
Placed in pure
water
Placed in 0.85% salt
solution (weak salt
solution
Placed in strong salt
solution
Task
• Complete the worksheet
The effect of osmosis on plant and animal cells
Learning Intention:
Investigate the cell membrane and the movement of molecules across it
Success Criteria:
• Understand the term osmosis Understand the effect of osmosis on plant cells
Starter
Starter
A
Starter
Starter
Turgid
Active Transport
Learning Intention: Describe the process of active transport Success Criteria: • Understand the term active transport
and its effect on cells • Understand the idea of concentration
gradient
Passive transport
• Diffusion and osmosis are examples of passive transport.
• This always involves movement of molecules down a concentration gradient.
• Passive transport does not need any energy input.
Active transport • Some molecules and ions are moved across the
membrane by active transport. • This involves movement of molecules and ions
against a concentration gradient. • Active transport does need energy input. • Membrane proteins are involved in this
process.
Transport across cell membranes (Glow)
Active transport
The sodium potassium pump
Sodium pumped out
Potassium pumped in
OUTSIDE THE CELL
INSIDE THE CELL
CELL MEMBRANE
•This is an example of active transport which occurs in nerve cells. •Sodium ions are pumped out of cells against the concentration gradient. •Potassium ions are pumped into cells against the concentration gradient.
Membrane proteins
Active transport in cells
• When a cell is alive, the membrane can use active transport to make sure that suitable molecules are allowed to build up in the cell, and unsuitable or harmful molecules are kept out of the cell.
Practical application of this idea
• You will probably have had antibiotics at some time for an infection.
• Many antibiotics work by destroying the membranes of live bacteria in your body.
• The damaged membranes allow vital nutrients to escape and poisonous substances to enter and kill the bacterial cells.
Task
• Complete the card sort to compare the 3 processes.
Quiz
1. What is osmosis?
A. a cafe on Grassyards road
B. a water hole in the desert
C. a ‘special case’ of the diffusion of water
D. how cells get energy
2. Which solution has the highest water concentration?
A. 20% sucrose
B. 5% sucrose
C. 40% sucrose
D. 2% sucrose
3. Which solution has the highest water concentration?
A. 5M NaOH
B. 0.1M NaOH
C. 2M NaOH
D. 3M NaOH
4. Which solution has the lowest water concentration?
A. pure water
B. 50% salt solution
C. 10% sugar solution
D. 6% acid solution
5. In which direction will the water flow?
A. left to right
B. right to left
C. stay the same
D. upwards
1.0M
NaCl
0.5M
NaCl
6. Osmosis only occurs if a membrane is.......
A. selectively permeable
B. blue
C. in a cell
D. waterproof
7. Osmosis and diffusion occur if there is a.......
A. cell wall
B. concentration span
C. concentration gradient
D. group of cells
8. Water will enter a cell by osmosis if....
A. the temperature is high
B. the water concentration inside the cell is lower than outside the cell
C. the water concentration inside the cell is higher than outside the cell
D. the cell is alive
9. Water will leave a cell by osmosis if....
A. the temperature is high
B. the water concentration inside the cell is lower than outside the cell
C. the water concentration inside the cell is higher than outside the cell
D. the cell is alive
10. What happens when red blood cells are placed in water?
A. they burst
B. they become plasmolysed
C. they become turgid
D. they lose water
11. What happens when plant cells are placed in water?
A. they burst
B. they become plasmolysed
C. they become turgid
D. they lose water
12. Which of these is an example of active transport?
A. plant cells taking in water by osmosis
B. salt molecules diffusing through a semi-permeable membrane
C. red blood cells bursting in water
D. sodium ions moving out of cells against the concentration gradient
Active Transport
Learning Intention: Describe the process of
active transport Success Criteria: • Understand the term active
transport and its effect on cells
• Understand the idea of concentration gradient
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