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Prepare a 10’ talk for Friday March 3 on plant defense responses or
describe interactions between plants& pathogens, pests or symbionts
Plant defense responses
Some possible pathogens
• Hypersensitive response
• Agrobacterium tumefaciens
• Systemic acquired
• Agrobacterium rhizogenes
resistance
• Pseudomonas syringeae
• Innate immunity
• Pseudomonas aeruginosa
• Phytoalexin synthesis
• Viroids
• Defensins and other
• DNA viruses
proteins
• RNA viruses
• Oxidative burst
• Fungi
Some possible pests
• Oomycetes
• Nematodes
Some possible symbionts
• Rootworms
• N-fixing bacteria
• Aphids
• N-fixing cyanobacteria
• Thrips
• Endomycorrhizae
• Gypsy moths
• Ectomycorrhizae
• hemlock woolly adelgid
Photosynthesis
2 sets of rxns in separate
parts of chloroplast
Light-independent (dark) reactions
Overall Reaction:
3 CO2 + 3 RuBP + 9 ATP + 6 NADPH =
3 RuBP + 9 ADP + 9 Pi + 6 NADP+ + 1 Glyceraldehyde 3-P
Light-independent (dark) reactions
1) fixing CO2
2) reversing glycolysis
3) regenerating RuBP
fixing CO2
1) RuBP binds CO2
fixing CO2
1) CO2 is bound to RuBP
2) rapidly splits into two 3-Phosphoglycerate
• therefore called C3 photosynthesis
•detected by immediately killing cells fed 14CO2
fixing CO2
1) CO2 is bound to RuBP
2) rapidly splits into two 3-Phosphoglycerate
3) catalyzed by Rubisco (ribulose 1,5 bisphosphate
carboxylase/oxygenase)
the most important & abundant protein on earth
•Lousy Km
•Rotten Vmax!
•Makes lots of mistakes!
Reversing glycolysis
converts 3-Phosphoglycerate to G3P
consumes 1 ATP & 1 NADPH
Reversing glycolysis
G3P has 2 possible fates
1) 1 in 6 becomes (CH2O)n
Reversing glycolysis
G3P has 2 possible fates
1) 1 in 6 becomes (CH2O)n
2) 5 in 6 regenerate RuBP
Reversing glycolysis
1 in 6 G3P becomes (CH2O)n
either becomes starch in chloroplast (to store in cell)
Reversing glycolysis
1 in 6 G3P becomes (CH2O)n
either becomes starch in chloroplast (to store in cell)
or is converted to
DHAP & exported
to cytoplasm to
make sucrose
Reversing glycolysis
1 in 6 G3P becomes (CH2O)n
either becomes starch in chloroplast (to store in cell)
or is converted to
DHAP & exported
to cytoplasm to
make sucrose
Pi/triosePO4
antiporter only
trades DHAP for Pi
Reversing glycolysis
1 in 6 G3P becomes (CH2O)n
either becomes starch in chloroplast (to store in cell)
or is converted to
DHAP & exported
to cytoplasm to
make sucrose
Pi/triosePO4
antiporter only
trades DHAP for Pi
mechanism to
regulate PS
Regenerating RuBP
G3P has 2 possible fates
5 in 6 regenerate RuBP
necessary to keep cycle going
Regenerating RuBP
Basic problem: converting a 3C to a 5C compound
feed in five 3C sugars, recover three 5C sugars
Regenerating RuBP
Basic problem: converting a 3C to a 5C compound
must assemble
intermediates that
can be broken into
5 C sugars after
adding 3C subunit
Regenerating RuBP
making intermediates that can be broken into 5 C sugars
after adding
3C subunits
3C + 3C + 3C = 5C + 4C
Regenerating RuBP
making intermediates that can be broken into 5 C sugars
after adding
3C subunits
3C + 3C + 3C = 5C + 4C
4C + 3C = 7C
Regenerating RuBP
making intermediates that can be broken into 5 C sugars
after adding
3C subunits
3C + 3C + 3C = 5C + 4C
4C + 3C = 7C
7C + 3C = 5C + 5C
Regenerating RuBP
making intermediates that can be broken into 5 C sugars
after adding
3C subunits
3C + 3C + 3C = 5C + 4C
4C + 3C = 7C
7C + 3C = 5C + 5C
Uses 1 ATP/RuBP
Light-independent (dark) reactions
build up pools of intermediates , occasionally remove one
very complicated book-keeping
Light-independent (dark) reactions
build up pools of intermediates , occasionally remove one
very complicated book-keeping
Use 12 NADPH and 18 ATP to make one 6C sugar
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase: Rubisco must be carbamylated &
bind Mg2+ to be active!
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase :
uses ATP to activate rubisco
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
• Rubisco must be carbamylated & bind Mg2+ to be active!
• RuBP binds & inactivates uncarbamylated rubisco
• Rubisco activase removes this RuBP
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
• Rubisco must be carbamylated & bind Mg2+ to be active!
• RuBP binds & inactivates uncarbamylated rubisco
• Rubisco activase removes this RuBP
• In the dark many species phosphorylate
carboxyarabinotol to form carboxyarabinitol 1phosphate which binds the rubisco active site
Regulating the Calvin Cycle
Rubisco activase removes this RuBP
• In the dark many species phosphorylate
carboxyarabinotol to form carboxyarabinitol 1phosphate which binds the rubisco active site
• Rubisco activase also removes CA1P in the light
• CA1P phosphatase then removes the PO4
Regulating the Calvin Cycle
Availability of CO2
Demand is set by mesophyll, stomata control supply
Ci is usually much lower than Ca
A vs Ci plots tattle on the Calvin cycle
Regulating the Calvin Cycle
A vs Ci plots tattle on the Calvin cycle
• In linear phase rubisco is limiting
• When curves RuBP or Pi regeneration is limiting
Regulating the Calvin Cycle
Currently Rubisco usually limits C3 plants
Will increase plant growth until hit new limiting factor
Regulating the Calvin Cycle
Currently Rubisco usually limits C3 plants
Will increase plant growth until hit new limiting factor
Free-Air CO2 Enrichment Experiments show initial gains,
but taper off w/in a few years
Now are limited by nutrients or water
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase
2) Light-induced changes in stroma
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase
2) Light-induced changes in stroma
a) pH: rubisco is most active at pH > 8
(in dark pH is ~7.2)
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase
2) Light-induced changes in stroma
a) pH: rubisco is most active at pH > 8
b) [Mg2+]: in light [Mg2+] in stroma is ~ 10x greater
than in dark
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase
2) Light-induced changes in stroma
a) pH: rubisco is most active at pH > 8
b) [Mg2+]: in light [Mg2+] in stroma is ~ 10x greater
than in dark
Mg2+ moves from thylakoid lumen to stroma to
maintain charge neutrality
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase
2) Light-induced changes in stroma
a) pH: rubisco is most active at pH > 8
b) [Mg2+]: in light [Mg2+] in stroma is ~ 10x greater
than in dark
c) CO2 is an allosteric activator of rubisco that only
binds at high pH and high [Mg2+]
also: stomates open in the light
Regulating the Calvin Cycle
Rubisco is main rate-limiting step
indirectly regulated by light 2 ways
1) Rubisco activase
2) Light-induced changes in stroma
Several other Calvin cycle enzymes (e.g.Fructose-1,6bisphosphatase) are also activated by high pH & [Mg2+]
Regulating the Calvin Cycle
Several Calvin cycle enzymes (e.g.Fructose-1,6bisphosphatase) are also regulated by thioredoxin
contain disulfide bonds which get oxidized in the dark
Regulating the Calvin Cycle
Several Calvin cycle enzymes (e.g.Fructose-1,6bisphosphatase) are also regulated by thioredoxin
contain disulfide bonds which get oxidized in the dark
in light, ferredoxin reduces thioredoxin, thioredoxin
reduces these disulfide bonds to activate the enzyme
SH SH
light
2Fdox
PSI
+
PSII
2e-
2Fdred
reduced
thioredoxin
S-S
oxidized
thioredoxin
S-S
oxidized
enzyme
(inactive)
SH SH
reduced
enzyme
(active)
Regulating the Calvin Cycle
Several Calvin cycle enzymes (e.g.Fructose-1,6bisphosphatase) are also regulated by thioredoxin
contain disulfide bonds which get oxidized in the dark
in light, ferredoxin reduces thioredoxin, thioredoxin
reduces these disulfide bonds to activate the enzyme
How light reactions talk to the Calvin cycle
SH SH
light
2Fdox
PSI
+
PSII
2e-
2Fdred
reduced
thioredoxin
S-S
oxidized
thioredoxin
S-S
oxidized
enzyme
(inactive)
SH SH
reduced
enzyme
(active)
PHOTORESPIRATION
Rubisco can use O2 as substrate instead of CO2
RuBP + O2 <=> 3-phosphoglycerate + phosphoglycolate
PHOTORESPIRATION
Rubisco can use O2 as substrate instead of CO2
RuBP + O2 <=> 3-phosphoglycerate + Phosphoglycolate
Releases CO2 without making ATP or NADH
PHOTORESPIRATION
Releases CO2 without making ATP or NADH
Called photorespiration : undoes photosynthesis
PHOTORESPIRATION
Rubisco can use O2 as substrate instead of CO2
RuBP + O2 <=> 3-phosphoglycerate + Phosphoglycolate
C3 plants can lose 25%-50% of their fixed carbon
PHOTORESPIRATION
Rubisco can use O2 as substrate instead of CO2
RuBP + O2 <=> 3-phosphoglycerate + Phosphoglycolate
C3 plants can lose 25%-50% of their fixed carbon
Both rxns occur at same active site
PHOTORESPIRATION
C3 plants can lose 25%-50% of their fixed carbon
phosphoglycolate is converted to glycolate : poison!
Detoxifying Glycolate
1) glycolate is shuttled to peroxisomes
Detoxifying Glycolate
1) glycolate is shuttled to peroxisomes
2) peroxisomes convert it to glycine
produce H2O2
Detoxifying Glycolate
1) glycolate is shuttled to peroxisomes
2) peroxisomes convert it to glycine
3) glycine is sent to mitochondria
Detoxifying Glycolate
1) glycolate is shuttled to peroxisomes
2) peroxisomes convert it to glycine
3) glycine is sent to mitochondria
4) mitochondria convert 2 glycine to 1
serine + 1 CO2
Why photorespiration loses CO2
Detoxifying Glycolate
1) glycolate is shuttled to peroxisomes
2) peroxisomes convert it to glycine
3) glycine is sent to mitochondria
4) mitochondria convert 2 glycine to 1
serine + 1 CO2
5) serine is returned to peroxisome
Detoxifying Glycolate
1) glycolate is shuttled to peroxisomes
2) peroxisomes convert it to glycine
3) glycine is sent to mitochondria
4) mitochondria convert 2 glycine to 1
serine + 1 CO2
5) serine is returned to peroxisome
6) peroxisome converts it to glycerate &
returns it to chloroplast
Detoxifying Glycolate
Why peroxisomes are next to cp and mito in C3 plants
Mitochondrion
C4 and CAM photosynthesis
Rubisco can use O2 as substrate instead of CO2
[CO2] is 1/600 [O2] _-> usually discriminate well
C4 and CAM photosynthesis
Rubisco can use O2 as substrate instead of CO2
[CO2] is 1/600 [O2]
Photorespiration increases with temperature
C4 and CAM photosynthesis
Rubisco can use O2 as substrate instead of CO2
[CO2] is 1/600 [O2]
Photorespiration increases with temperature
Solution: increase [CO2] at rubisco
C4 and CAM photosynthesis
Solution: increase [CO2] at rubisco
C4 & CAM = adaptations that reduce PR & water loss
C4 and CAM photosynthesis
Adaptations that reduce PR & water loss
Both fix CO2 with a different enzyme
C4 and CAM photosynthesis
Adaptations that reduce PR & water loss
Both fix CO2 with a different enzyme
later release CO2 to be fixed by rubisco
use energy to increase [CO2] at rubisco
C4 and CAM photosynthesis
Adaptations that reduce PR & water loss
Both fix CO2 with a different enzyme
later release CO2 to be fixed by rubisco
use energy to increase [CO2] at rubisco
C4 isolates rubisco spatially (e.g. corn)
C4 and CAM photosynthesis
Adaptations that reduce PR & water loss
Both fix CO2 with a different enzyme
later release CO2 to be fixed by rubisco
use energy to increase [CO2] at rubisco
C4 isolates rubisco spatially (e.g. corn)
CAM isolates rubisco temporally (e.g. cacti)