Photosynthesis 5.6

Question 1

What is photophosphorylation? LD

Answer 1

Photophosphorylation id the generation of ATP using light energy from DP and Pi. It can be cyclic or non cyclic

Question 2

What are the two stages of photosynthesis?

Answer 2

Photosynthesis is the light dependant stage and then the light independent

Question 3

What are the 2 products of non cyclic photophosphorylation? LD

Answer 3

Non cyclic produces ATP and reduced NADP

Question 4

What is photolysis? LD

Answer 4

Photolysis is the splitting of water using light energy.

H2O —– 1/2 O2 + 2H+ +2e-

Question 5

What causes ATP synthase to turn? LD

Answer 5

ATP synthase turns as hydrogen ions diffuse through it

Question 6

What does the turning of ATP synthase do? LD

Answer 6

When ATP synthase turns it causes ADP and Pi to combine and create ATP

Question 7

What do the electron carriers have in? LD

Answer 7

The electron carriers contain iron 3+

Question 8

What happens to the electron carriers as electron pass in and out? LD

Answer 8

The electron carriers contain iron 3+. When electrons enter them they are reduced into iron 2+ and then when the electrons leave again they are oxidised back to iron 3+

Question 9

What is the energy released by movement of electrons used for? LD

Answer 9

Electrons passing through the electron carriers realises energy and this is used to pump hydrogen across the thylakoid membrane into the thylakoid lumen

Question 10

What does hydrogen ions getting pumped into the thylakoid lumen do? LD

Answer 10

When hydrogen ions are pumped into the thylakoid lumen it builds up a hydrogen ion gradient. Eventually as they accumulate they diffuse through ATP synthase

Question 11

What happens when electrons pass down electron carriers? LD

Answer 11

When electrons are passed down electron carriers they release energy

Question 12

What is ferredoxin? LD

Answer 12

Ferredoxin is a protein-iron-sulphur complex that accepts electrons and passes them to NADP in the stroma

Question 13

How do electrons get to the NADP in the stroma? LD

Answer 13

Electron get to NADP in the stroma by ferredoxin

Question 14

What order are the photosystems in? LD

Answer 14

First is photosystem 2 and then photosystem 1

Question 15

Briefly outline non cyclic photophosphorylation LD

Answer 15

Non cyclic photophosphorylation:

1. Light energy excites 2 e- in PS2
2. Electrons get passed down electron carriers which releases energy (reduces and oxidises). Electrons are replaced by those from photolysis
3. energy released pumps H+ ions into thylakoid lumen , building up a proton gradient
4. electron reaches ps1 and gets excited by light energy
5. electrons pass to ferredoxin and then to the NADP in stroma
6. H+ diffuse through ATP synthase, turning it forming ATP from ADP and Pi
7. NADP reduced by 2 electron sand 2 hydrogen ions by NADP reductase

Question 16

How is NADP reduced? LD

Answer 16

NADP is reduced by adding 2 electrons and 2 hydrogen ions. NADP reductase catalyses this

Question 17

How are electrons in either photosystem 1 or 2 excited? LD

Answer 17

Electrons in photosystem 1 or 2 are excited by light energy

Question 18

What is the Z scheme? LD

Answer 18

The z scheme is a sketch of the pathways of enzyme and component of photophosphorylation against a Y axis measuring the energy of electrons at every stage

Question 19

What is cyclic photophosphorylation? LD

Answer 19

Cyclic photophosphorylation is where electrons are excited at photosystem 1 then back to the electron carrier chain. It only makes ATP and only uses photosystem 1

Question 20

What are the differences between non cyclic and cyclic phosphorylation? LD

Answer 20

cyclic photophosphorylation:

• only uses photosystem 1, non uses both
• ATP is the only product, non also makes reduced NADP
• no photolysis

Question 21

What cells is cyclic photophosphorylation used by? LD

Answer 21

Guard cells only have photosystem 1 so only make ATP. They use this ATP to actively move potassium ions into the guard cells, reducing their water potential. So water then ,moves in by osmosis causing the cells to swell until they push apart and therefore open the stoma

Question 22

What is the brief passage of electrons in the light dependent stage?

Answer 22

Photosystem 2
Electron carrier system
photosystem 1
ferredoxin
NADP reductase

Question 23

At what stage of photosynthesis does cyclic and non cyclic photophosphorylation occur?

Answer 23

These occur at the light dependent stage

Question 24

Where in photophosphorylation does energy get released and how is it used? LD

Answer 24

Energy I released from movement of electrons along the electron carrier chain. It is used to pump hydrogen ions into the thylakoid lumen, building a gradient until they diffuse into the stroma via ATP synthase to generate ATP production

Question 25

Where does the reduction of NADP occur? LD

Answer 25

Reduction of NADP occurs in the stroma

Question 26

Where does the 2 electrons and 2 hydrogen ions come from in the reduction of NADP? LD

Answer 26

The 2 electron come from the ferredoxin

The 2 hydrogen ions come from photolysis of water

Question 27

Where does the light independent stage happen?

Answer 27

The light independent stage occurs in the stroma of chloroplasts

Question 28

What happens in the light independent stage?

Answer 28

In the light independent stage carbon dioxide gets converted to organic compounds in the calvin cycle

Question 29

How does CO2 enter the stroma? LI

Answer 29

CO2 comes through the stoma and then diffuse into the spongy mesophyll cells then into a palisade cell where it enters the stroma of the chloroplasts

Question 30

What does TP stand for? LI

Answer 30

TP= triose phosphate

Question 31

What does GP stand for? LI

Answer 31

GP = glycerate 3 phosphate

Question 32

What does RuBP stand for? LI

Answer 32

RuBP = ribulose bisphosphate

Question 33

What is the CO2 concentration like in the stroma? Why is this important? LI

Answer 33

In the stroma CO2 concentration is kept low as it gets fixed in the celvin cycle. This means there is a bug concentration gradient outside and inside the stroma meaning CO2 keeps diffusing in enabling the calvin cycle to continue

Question 34

What time conditions does the light independent stage happen in?

Answer 34

The light independent stage only happens in daylight

Question 35

Why would the light independent stage cease without day light?

Answer 35

Despite being light independent it would cease without day light because it needs ATP which is made in the light dependent stage

Question 36

How many turns does the calvin cycle need to do? Why? LI

Answer 36

The calvin cycle needs to turn 6 times in order to make the 2 TP needed to make glucose and the 10 needed to go back into RuBP production

Question 37

Overall how many TP are needed to be produced? LI

Answer 37

12 TP are needed as 10 go to RuBP and 2 into the production of glucose

Question 38

How many carbons are in:

• TP
• GP
• RuBP
• CO2
• intermediate product

Answer 38

TP = 3C
GP = 3C
RuBP = 5C
CO2 = 1C
intermediate product  = 6C

Question 39

What are the uses of TP? LI

Answer 39

uses of TP:

• glucose —- starch and cellulose
• amino acids
• glycerol
• fatty acids

Question 40

Outline the calvin cycle LI?

Answer 40

Calvin Cycle:

1. CO2 combines with RuBP catalysed by RuBisCO
2. 6C intermediate compound forms because the RuBP is carboxylated and immediately breaks down
3. 2 GP (3C) are formed
4. 2 ATP broken down to ADP and Pi +2 reduced NADP becomes 2 NADP
5. GP reduced (by the hydrogen from reduced NADP) into 2 TP (3C)
6. some TP go into synthesising organic compounds
7. Regeneration of RuBP by some TP requires phosphates so ATP is used breaking it down to ADP and Pi

Question 41

Why does reduced NADP get turned back to NADP? LI

Answer 41

When reduced NADP gets turned back to NADP it loses hydrogen ions and these hydrogen ions are needed to turn GP into TP as it needs to be reduced

Question 42

How many points does ATP get broken down in the Calvin cycle? LI

Answer 42

ATP is broken down into ADP and Pi :

• Turning GP into TP
• Turning TP to RuBP to give the reaction phosphates

Question 43

In plants what is the glucose turned into from TP? LI

Answer 43

Glucose is used for starch and cellulose production

Question 44

Why does the light independent stage only occur in day light?

Answer 44

In daylight:

• ATP and reduced NADP made in light
• light dependent stage raises the stroma pH as H+ get pumped out of it, this pH is the optimum for RuBisCO
• concentration of Mg2+ increases in stroma and these act as co factors for RuBisCO, activating it by attaching to its active site
• ferredoxin gets reduced in the light dependent stage and this ferredoxin activates enzymes in Calvin cycle

Question 45

What happens to magnesium ions in daylight? LI

Answer 45

magnesium ion concentration increases in the stroma in daylight and these act as cofactors to activate RubisCO by attaching to it active site.

Question 46

Why is it important in light independent stage that stroma pH increases?

Answer 46

In the light dependent stage hydrogen ions are pumped out of stroma. This raises pH to 8 which is the optimum temperature for RubisCO, it works best in these conditions

Question 47

What is ferredoxins role in the light independent stage?

Answer 47

Ferredoxin activates enzymes in the calvin cycle.

Question 48

How many ATP (at separate points) and reduced NADP are used in one turn of the calvin cycle?

Answer 48

• 2 ATP broken down into 2 ADP and Pi
• 2 reduced NADP into 2 NADP
• 1 ATP into 1 ADP and Pi

Question 49

What is the general equation for photosynthesis?

Answer 49

Photosynthesis =

6CO2 + 6H2O+ ENERGY —–C6H1206 + 6O2

Question 50

What is photosynthesis?

Answer 50

Photosynthesis is a physiological process that converts light energy from sunlight to chemical energy

Question 51

What can organisms use this chemical energy from photosynthesis for?

Answer 51

Chemical energy is used by organisms to synthesise large molecules which form the building blocks of organic cells

Question 52

What is autotrophic nutrition?

Answer 52

Autotrophic nutrition is where organisms make their own nutrients

Question 53

What is a photon?

Answer 53

A photon is a particle of energy

Question 54

What are organisms called when they can photosynthesise?

Answer 54

Organisms that can photosynthesise are called photoautotrophs (because they use light as an energy source or autotrophic nutrition). Also known as producers

Question 55

Is carbon fixation endothermic or exothermic?

Answer 55

Carbon fixation is endothermic as it requires energy

Question 56

What are heterotrophs?

Answer 56

Heterotrophs obtain energy by digesting complex organic molecules of food to smaller molecules that they can use as respiratory substrates

Question 57

Is respiration endothermic or exothermic?

Answer 57

Respiration is exothermic as it releases chemical energy

Question 58

How do photosynthesis and respiration interrelate?

Answer 58

The products of one are the raw materials for the other. Aerobic respiration removes oxygen from the atmosphere and photosynthesis adds oxygen to the atmosphere

Question 59

What is the general equation for respiration?

Answer 59

Respiration=

C6H12O6 + 6O2 —– 6H2O + 6CO2 + ENERGY

Question 60

Difference in when respiration and photosynthesis occur?

Answer 60

Plants respire all the time but only photosynthesise during day light

Question 61

What is the compensation point?

Answer 61

Compensation point is where photosynthesis and respiration occur at the same rate so that there is no net loss or net gain of carbohydrate

Question 62

What is the compensation period?

Answer 62

Compensation period is the time a plant takes to reach the compensation point

Question 63

What is the difference between compensation point and period in sun versus shade plants?

Answer 63

Shade plants reach their compensation point sooner so have a shorter compensation period because they utilise light at a lower intensity
Sun plants take longer to reach compensation point as they require a higher light intensity take longer before able to photosynthesise well

Question 64

Does photosynthetic bacteria have chloroplasts?

Answer 64

Photosynthetic bacteria do not have chloroplasts

Question 65

Discuss the membrane of chloroplasts?

Answer 65

Chloroplasts have an envelope made up of two membranes; an inner and an outer. Between these two there is an intermembrane space. The outer membrane is highly permeable. They have a third membrane called the thylakoid membrane which is folded inside

Question 66

What are the two distinct regions within the chloroplast s?

Answer 66

In chloroplasts there is:

• The stroma (fluid filled matrix)
• grana consisting of stacks of thylakoids

Question 67

How are thylakoids from different grana connected?

Answer 67

A thylakoid of one grana may be connected to a thylakoid of a different grana by intergranal lamellae.

Question 68

What is the single for grana?

Answer 68

Grana is plural for granum

Question 69

How is the thylakoid membrane folded?

Answer 69

The thylakoid membrane is folded into flattened disc like sacs called thylakoids

Question 70

What is a stack of thylakoids called?

Answer 70

A stack of thylakoids is a granum

Question 71

What is the inside of a thylakoid referred to?

Answer 71

The inside of a thylakoid is called the thylakoid lumen or thylakoid space

Question 72

Why is it good that the grana are surrounded by stroma ?

Answer 72

Grana are surrounded by stroma so the products of the light dependent stage can easily pass into the stroma for the light independent stage

Question 73

Why is there a huge surface area in chloroplasts/by chloroplasts?

Answer 73

There are many grana in every chloroplast and many chloroplasts in each photosynthetic cell making a huge surface area for:

• distribution of photosystems that contain photosynthetic pigments
• electron carriers and ATP synthase enzymes needed to convert light energy into ATP

Question 74

What is in the stroma?

Answer 74

The stroma contains

• enzymes for LI stage
• starch grains
• oil droplets
• small ribosomes
• DNA

Question 75

What does the loop of DNA in the stroma of chloroplasts do?

Answer 75

This loop of DNA codes for some of the proteins needed for photosynthesis. These are assembled at chloroplast ribosomes

Question 76

What are photosystems?

Answer 76

Photosystems are funnel shaped structures embedded in the thylakoid membrane held by proteins. they contain photosynthetic pigments. They have a primary reaction centre consisting of p680 or p700 chlorophyll

Question 77

What are photosynthetic pigments?

Answer 77

Photosynthetic pigments absorb light of a particular wavelength and reflects another colour which is what we see.

Question 78

What are the two types of chlorophyll a and where are they found?

Answer 78

Chlorophyll A

• p700 found in photosystem 1
• p680 found din photosystem 2

Question 79

What colour do they absorb and reflect?

• chlorophyll a
• chlorophyll b

Answer 79

Chlorophyll a absorbs red and some blue and reflect blue green
Chlorophyll b absorbs 400-500nm and 640nm and it reflects yellow green

Question 80

What are 2 accessory pigments?

Answer 80

Accessory pigments:

• carotenoids reflect orange and yellow and absorb 400-500nm
• Xanthrophylls reflect yellow and absorb 375nm-550nm

Question 81

discuss the term limiting factor?

Answer 81

Limiting factors are present tin the least favourable amounts.
The rate of a metabolic process that depends on a number of factors, is limited by he factor present in the least favourable level

Question 82

What happens when you increase/decrease light intensity on rate of photosynthesis?

Answer 82

Increasing light intensity = faster rate of photosynthesis

Decreasing light intensity = slower rate of photosynthesis

Question 83

Why does light affect rate of photosynthesis?

Answer 83

Light affects the rate of photosynthesis because the first stage of photosynthesis is dependent on light and therefore the second stage is also then affected because it needs products made in the first stage to continue

Question 84

How does light intensity affect stoma and what does this do?

Answer 84

Light causes stoma to open so CO2 can diffuse in and transpiration can occur leading ti the uptake of water

Question 85

What are the effects of having no/dim light on the calvin cycle?

Answer 85

Dim light on calvin cycle
No ATP or reduced NADP will be made in the light dependent stage so:
-no TP made as no ATP or reduced NADP
-accumulation of GP as not becoming TP
-No RuBP as no ATP

Question 86

What are the effects of having bright light on the calvin cycle?

Answer 86

Bright light on the Calvin cycle
This means ATP and reduced NADP are being made in the light dependent stage so:
-high RuBP as there is ATP
-high TP as there is ATP and reduced NADP
-low GP as it gets made into TP

Question 87

What is CO2 role in the calvin cycle?

Answer 87

In the calvin cycle CO2 gets fixed

Question 88

What happens if CO2 concentrations fall below 0.01%?

Answer 88

If CO2 levels fall below 0.01% then RuBP cannot accept in and become GP so

• RuBP accumulates
• GP drops as no CO2
• TP drops as no GP

Question 89

What happens if the temperature is 30 degrees or lower?

Answer 89

At 30 degrees or lower, assuming light intensity, water and carbon dioxide are sufficient then photosynthesis increases as temperature increases

Question 90

What happens of the temperature raises above 30 degrees?

Answer 90

When the temperature is above 30 degrees growth rates reduce due to photo respiration.
Photo respiration is where oxygen competes with carbon dioxide to enter RuBisCOs active site, and it favours the oxygen.
-initial accumulation of RuBP then gradually declines
-Decrease in GP and TP

Question 91

What happens when temperature is above 45 degrees?

Answer 91

When the temperature is above 45 degrees enzymes denature so rate of photosynthesis slows down

Question 92

What are 3 reasons why water is important other than it being a reactant?

Answer 92

Waters importance:

• cooling effect on the plant
• maintains turgidity
• turgid guard cells keep stoma open for gaseous exchange

Question 93

What are 3 effects when the plant does not have enough water? Including rate of photosynthesis

Answer 93

Not enough water:

• plasmolysis, flaccid tissues and wilting
• roots start to produce absicisic acid which causes stomata to close therefore reducing gaseous exchange
• Rate of photosynthesis reduces

Question 94

What are two ways would could measure the rate of photosynthesis?

Answer 94

You can measure the rate of photosynthesis by:

• CO2 uptake
• O2 production

Question 95

What are the limitations of measuring rate of photosynthesis with O2 production?

Answer 95

O2 production:

• Some of the oxygen will be used in respiration so the a mount you measure will be an underestimate
• Some nitrogen gas may be in what you collect

Question 96

What equipment do you use to measure the oxygen production from the plant?

Answer 96

To measure oxygen production you use a photosynthometer (audus microburette)

Question 97

What is a photosynthometer also known as?

Answer 97

A photosynthomenter is also known as an audus microburette

Question 98

How do you set up the experiment for measuring oxygen production?

Answer 98

• thermometer
• elodea plant in pond water/sodium hydrogen carbonate solution
• water bath
• capillary tube with funneled end
• syringe attached to tubing to moVVe bubble
• scale/ruler to measure bubble

Question 99

What happens in the experiment for oxygen production?

Answer 99

1. bubbles of gas collect at the funnel and goes up capillary tube
2. experimenter manipulates bubble, moving it with a syringe
3. measure the length of the bubble
4. work out the volume of gas ( length x pi r squared)

Question 100

What are 4 things you have to do for an experiment?

Answer 100

• control variables like co2 concentrations, light
• write a plan
• write a prediction
• work out IV and DV