Photosynthesis

Question 1

what’s light energy converted to and what is it used for?

Answer 1

chemical energy which is used to synthesise large organic molecules from inorganic ones like H2O, CO2 (autotrophic nutrition)

Question 2

what are organisms that photosynthesise called?

Answer 2

photoautotrophs

Question 3

equation for photosynthesis

Answer 3

6 CO2 + 6 H2O + energy from photons —-> C6H12O6 + 6 O2

Question 4

what’s a photon?

Answer 4

a particle of light containing energy

Question 5

What’s the main product of photosynthesis?

Answer 5

• monosaccharide sugar which is converted to disaccharides for transport then starch for storage

Question 6

photosynthesis is an example of…

Answer 6

carbon fixation

Question 7

do plants respire?

Answer 7

YES

Question 8

what are non-photosynthetic organisms called?

Answer 8

• heterotrophs
• they obtain energy from digesting organic molecules of food into smaller ones that can be used as respiratory substrates

Question 9

what type of reaction is respiration ( endothermic/exothermic)?

Answer 9

exothermic

Question 10

respiration equation

Answer 10

C6H12O6 + 6 O2 —> 6H2O + 6CO2 + energy

Question 11

how do photosynthesis and respiration interrelate?

Answer 11

• important in recycling CO2 + O2 in atmosphere
• products of photosynthesis are the raw materials for aerobic respiration
• aerobic respiration removes O2 from the atmosphere + adds CO2. Photosynthesis does the opposite

Question 12

define compensation point

Answer 12

when photosynthesis and respiration proceed at the same rate so there’s no net gain or loss of carbohydrate

Question 13

do plants respire all the time?

Answer 13

YES

Question 14

do plants photosynthesise all the time?

Answer 14

NO
- only during daylight
- light intensity must be sufficient to allow photosynthesis at a rate that replenishes carbohydrate stores used up by respiration

Question 15

define compensation period?

Answer 15

time a plant takes to reach its compensation point

Question 16

how will the compensation period of shade plants differ from that of sun plants?

Answer 16

shorter compensation period than sun plants which need higher light intensity to achieve their optimum rate of photosynthesis

Question 17

what’s the granum (pl. grana)?

Answer 17

inner part of chloroplasts made of stacks of thylakoid membranes where light- dependent stage happens

Question 18

define photosynthetic pigment?

Answer 18

pigment that absorbs specific wavelengths of light and traps energy associated with the light whilst reflecting other wavelengths of light (what we see)

Question 19

define photosystem?

Answer 19

funnel shaped system of photosynthetic pigments in thylakoids

Question 20

define stroma

Answer 20

fluid filled matrix

Question 21

define thylakoid

Answer 21

flattened membrane bound sac, contains photosynthetic pigments + photosystems

Question 22

permeability of outer membrane

Answer 22

highly permeable

Question 23

what are the structures found between grana?

Answer 23

intergranal lamellae

Question 24

what are the 3 different internal compartments and the membranes that create them?

Answer 24

• outer, inner, thylakoid membranes
• intermembrane space, stroma, thylakoid space

Question 25

permeability of thylakoid membrane

Answer 25

less permeable than outer membrane

Question 26

why are there many grana and chloroplasts?

Answer 26

to provide large SA for:
- photosystems containing photosynthetic pigments that trap sunlight energy
- electron carriers and ATP synthase enzymes needed to convert light to ATP

Question 27

features of the stroma

Answer 27

• enzymes that catalyse reactions in light dependent stage
• starch grains, oil droplets, small ribosomes and DNA
• loop of DNA has genes that code for some proteins needed for photosynthesis to occur which are assembled at chloroplast ribosomes

Question 28

what are the 2 types of chlorophyll a?

Answer 28

• P680 in photosystem II, peak of absorption is light of wavelength 680nm
• P700 in photosystem I, peak 700nm
• both appear blue-green and absorb red light

Question 29

what colour does chlorophyll b appear?

Answer 29

yellow green

Question 30

name some accessory pigments

Answer 30

• carotenoids
• xanthophyll

Question 31

define hydrolysis

Answer 31

the splitting of a molecule of a molecule using water

Question 32

define dehydration

Answer 32

the removal of H from a molecule

Question 33

define metabolic pathway

Answer 33

a series of small reactions controlled by enzymes (respiration + photosynthesis)

Question 34

define phosphorylation

Answer 34

adding phosphate to a molecule (ADP is phosphorylated to ATP)

Question 35

define photolysis

Answer 35

the splitting of a molecule using light energy

Question 36

define decarboxylation

Answer 36

removal of CO2 from a molecule

Question 37

define photophosphorylation

Answer 37

adding phosphate to a molecule using light

Question 38

define NADP

Answer 38

a coenzyme + electron + H carrier

Question 39

define electron carriers

Answer 39

molecules that accept e- then donate those e- to another carrier. Form an electron transport system. e.g Ferredoxin, NAD (respiration), NADP(photosynthesis)

Question 40

what are the main stages in the light dependent stage?

Answer 40

1. light harvesting at the photosystems
2. photolysis of water
3. photophosphorylation
4. the formation of NADPH
   O2 produced

Question 41

what’s the role of water in the light dependent stage?

Answer 41

• source of H+ used in aerobic respiration
• donates e- to chlorophyll to replace those lost when light strikes
• source of O2 (by-product)
• keeps cells turgid

Question 42

photolysis equation

Answer 42

2 H2O —> 4H+ + 4e- + O2

Question 43

photosystem(s) involved in non cyclic photophosphorylation

Answer 43

PS II AND PS I

Question 44

photosystem(s) involved in cyclic photophosphorylation

Answer 44

PS I only

Question 45

products of non cyclic photophosphorylation

Answer 45

• ATP
• O2
• NADPH

Question 46

products of cyclic photophosphorylation

Answer 46

• ATP in smaller quantities

Question 47

cyclic and non cyclic photophosphorylation involve….

Answer 47

electron carriers

Question 48

stages in non- cyclic photophosphorylation

Answer 48

1. photon strikes PS II (P680), its energy is channelled to the primary pigment reaction centre
2. light energy excites a pair of e- inside chlorophyll molecule
3. energised pair e- escape from chlorophyll and are captured by e- carriers ( proteins containing Fe cores)
4. these e- replaced by e- from photolysis
5. Fe3+ ion reduced when e- accepted to Fe2+. It then donates the e- becoming reoxidised, to the next carrier in chain
6. during redox reactions, some energy associated with the e- is released and use to pump H+ into thylakoid space from the stroma
7. eventually, e- captured by another chlorophyll in PS I. These e- replace those lost from PS I due to excitation by light energy
8. Ferredoxin (protein-Fe-S complex) accepts the e- from PS I and passes them to NADP in the stroma
9. as H+ accumulate in thylakoid space, electrochemical gradient forms
10. H+ diffuses down conc gradient through channels in membrane associated with ATP synthase enzymes and, as they do so, flow of protons causes ADP and Pi to re-join ( phosphorylation
11. as H+ pass through channel, they’re accepted along with e- by NADP which becomes reduced, catalysed by NADP reductase
    - light energy converted to ATP (chemical energy)

Question 49

what products end up in the stroma after photophosphorylation for the lis?

Answer 49

• ATP
• NADPH

Question 50

Define rate

Answer 50

quantity taken up or produced per unit time

Question 51

How can rate of photosynthesis be measured and limitations?

Answer 51

• by measuring the volume of O2 produced per minute by aquatic plant
• limitations:
  some O2 used in respiration
  dissolved N2 gas collected

Question 52

what’s cyclic and non-cyclic photophosphorylationcalled ?

Answer 52

The Z scheme

Question 53

stages in cyclic phosphorylation

Answer 53

1. light strikes PS I, pair of e- in chlorophyll at the reaction centre gain energy + become excited
2. e- escape and passed on to an e- carrier system and then back to PS I
3. During passage of e- along system, small amount of ATP is generated

Question 54

what are some differences between cyclic and non-cyclic photophosphorylation?

Answer 54

• no photolysis
• no H+ or O2 produced
• no NADPH generated
• less ATP made

Question 55

why do guard cells only have PS I?

Answer 55

• ATP for active transport of K+ into cells, lowering water potential so that water moves in by osmosis.
• guard cells swell and stomata open

Question 56

what’s the Calvin cycle?

Answer 56

metabolic pathway of the light-independent stage of photosynthesis, occurring (in eukaryotic cells) in the stroma of chloroplasts where CO2 is fixed, with the products of lds to make organic compounds

Question 57

What occurs when there’s no light?

Answer 57

• lis ceases as there’s no ATP and H to reduce carbon and synthesise large complex organic molecules

Question 58

what’s the role of CO2?

Answer 58

• source of C for all organic molecules found in all carbon based life forms on Earth
• organic molecules used as structures (cellulose cell wall, enzymes, antigens) or as energy stores (starch + glycogen)

Question 59

why is carbon fixation in stroma important for diffusion?

Answer 59

• maintains a conc gradient
• (air) stomata –> spongy mesophyll –> palisade layer

Question 60

stages of Calvin cycle

Answer 60

1. CO2 combines with ribulose bisphosphate RuBP ( 5 C, CO2 acceptor), catalysed by RuBisCO
2. RuBP accepts the carboxyl (COO-) group, becomes carboxylated forming an unstable 6C intermediate compound that immediately breaks down
3. product is 2 GP (glycerate-3-phosphate) (3C), CO2 has been fixed
4. GP is reduced, using H+ from NADPH to triose phosphate (TP). Energy from ATP is also used at the rate of 2 ATP for every CO2 molecule fixed during stage 3
5. in 10 of every 12 TP molecules (3C), the atoms are rearranged to 6 RuBP (5C) which requires phosphate groups.
   - the remaining 2 of the 12 TP are the product

Question 61

why do plants contain little RuBP?

Answer 61

its converted to GP which is continually being regenerated

Question 62

how many turns of the Calvin cycle are needed to make 2TP (to make one glucose molecule)

Answer 62

6

Question 63

Outline the main processes in the Calvin cycle

Answer 63

1. Carbon fixation (RuBP combining with CO2 to form GP)
2. Reduction (of GP to TP)
3. Regeneration ( TP to RuBP)

Question 64

why is RuBisCo only activated during daylight?

Answer 64

• H+ pumped from stroma into thylakoid space in lds raises pH to 8 which is optimum for RuBisCO
• extra ATP in stroma also activate it
• in daylight Mg2+ ions in stroma increase which are cofactors
• Ferredoxin that’s reduced by e- from PS I activates enzymes used in Calvin cycle

Question 65

what are the uses of TP

Answer 65

• synthesis of aa, fatty acids, glycerol
• some glucose converted to sucrose, starch, cellulose
• the rest us recycled to regenerate RuBP. 5TP (3C) form 3 RuBP (5C)

Question 66

What’s water stress?

Answer 66

condition a plant faces when water supply becomes limited

Question 67

What’s a limiting factor?

Answer 67

the factor that will limit the rate when its at lower levels

Question 68

examples of limiting factors

Answer 68

• CO2 conc
• H20
• light intensity
• availability of chlorophyll, e- carries, relevant enzymes
• Temperature
• turgidity of cells

Question 69

How does light intensity affect rate of ps?

Answer 69

• light provides energy for lds to produce ATP + NADPH
• causes stomata to open for gaseous exchange which causes transpiration (increase H2O uptake)
• at constant favourable temp + CO2 conc, light intensity is the limiting factor but as it increases rate of ps increases until another factor becomes the limiting factor

Question 70

How does temperature intensity affect rate of ps?

Answer 70

• enzyme catalysed reactions sensitive to temp
• 25-30C, rate of ps increases as temp increases ( if other factors are at sufficient levels)
• above 30C, growth rates reduce due to photorespiration: O2 competes with CO2 for RuBisCO’s active site
• above 45C, enzymes denature so conc of GP + TP reduce and RuBP not regenerated

Question 71

What happens to levels of RuBP, TP, GP if there’s little or no light?

Answer 71

1. GP can’t be reduced to TP (GP increases)
2. TP levels fall + GP accumulates
3. if TP levels fall, RuBP can’t be regenerated

Question 72

What happens to levels of RuBP, TP, GP if there’s little or no CO2?

Answer 72

• RuBP can’t accept CO2 (to form GP) and accumulates
• GP can’t be made
• so TP can’t be made

Question 73

what happens when a plant is under stress?

Answer 73

• water lost via transpiration not replaced
• cells become plasmolysed
• roots produce abscisic acid which is translocated to leaves + closes stomata
• tissue becomes flaccid + leaves wilt
  -rate of ps decreases

Question 74

How to set up and use a photosynthometer ( Audus microburette)

Answer 74

• set up so its airtight + no bubbles in capillary tubing
• gas collected at flared end of capillary tube over a known time period
• gas bubble can be moved into the part of the tube against the scale and its length is measured
• if radius of tube bore is known :
  volume of gas collected = length of bubble x (pi)r2