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Plant Respiration Releases 50% of fixed CO 2 Provides energy for all sinks, source leaves at night & helps source during day!. Plant Respiration Similar, but more complex than in animals Making precursors, recycling products, releasing energy are also important. Plant Respiration
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Plant Respiration Releases 50% of fixed CO2 Provides energy for all sinks, source leaves at night & helps source during day!
Plant Respiration Similar, but more complex than in animals Making precursors, recycling products, releasing energy are also important
Plant Respiration Glycolysis in cytosol Pyruvate oxidation in mito Krebs cycle in mito Electron transport & chemiosmosis in mito
Plant Respiration • Glycolysis in cytosol • 1 glucose -> 2 pyruvate • Yields 2 NADH & 2 ATP per glucose Unique features in plants • May start with DHAP from cp instead of glucose
Unique features in plants • May start with DHAP from cp instead of glucose • May yield malate cf pyr • PEP ->OAA by PEPC, then reduced to malate
Plant Respiration • May yield malate cf pyr • PEP ->OAA by PEPC, then reduced to malate • Get more ATP/NADH in mito
Unique features in plants • May yield malate cf pyr • PEP ->OAA by PEPC, then reduced to malate • Get more ATP/NADH in mito • Replaces substrates
Plant Respiration • Glycolysis in cytosol • 1 glucose -> 2 pyruvate • Yields 2 NADH & 2 ATP per glucose Anaerobic plants ferment pyr to regenerate NAD+ Form EtOH
Plant Respiration • Glycolysis in cytosol • 1 glucose -> 2 pyruvate • Yields 2 NADH & 2 ATP per glucose Anaerobic plants ferment pyr to regenerate NAD+ Form EtOH Less toxic than lactate because diffuses away
Plant Respiration • Krebs cycle • Similar, but more complex Key role is making intermediates & recycling products
Plant Respiration • Krebs cycle • Similar, but more complex Key role is making intermediates & recycling products Many ways to feed in other substrates to burn
Plant Respiration • Krebs cycle • Similar, but more complex Key role is making intermediates & recycling products Many ways to feed in other substrates to burn or replace intermediates used for biosynthesis
Plant Respiration Many ways to feed in other substrates to burn or replace intermediates used for biosynthesis Needed to keep cycle going
Plant Respiration Many ways to feed in other substrates to burn or replace intermediates used for biosynthesis Needed to keep cycle going
Plant Respiration Many ways to feed in other substrates to burn or replace intermediates used for biosynthesis Needed to keep cycle going Malic enzyme is key: lets cell burn malate or citrate from other sources
Plant Respiration Many ways to feed in other substrates to burn or replace intermediates used for biosynthesis Needed to keep cycle going Malic enzyme is key: lets cell burn malate or citrate from other sources PEPCarboxylase lets cell replace Krebs intermediates used for synthesis
Plant Respiration Pentose phosphate shunt in cytosol orcp • 6 glucose-6P + 12NADP++ 7 H2O -> 5 glucose-6P + 6 CO2 + 12 NADPH +12 H+ : makes NADPH & intermediates
Plant Respiration Pentose phosphate shunt in cytosol orcp makes NADPH & intermediates Uses many Calvin Cycle enzymes
Plant Respiration Pentose phosphate shunt in cytosol orcp makes NADPH & intermediates Uses many Calvin Cycle enzymes Makes nucleotide & phenolic precursors
Plant Respiration Uses many Calvin Cycle enzymes Makes nucleotide & phenolic precursors Gets Calvin cycle started at dawn
ATP generation 2 stages 1) e- transport 2) chemiosmotic ATP synthesis
Three steps transport H+ across membrane 1) NADH dehydrogenase pumps 4 H+/ 2 e- 2) Cyt bc1 pumps 4 H+/ 2 e- 3) Cyt c oxidase pumps 2 H+/ 2 e- and adds 2 H+ to O to form H2O
e- transport • Plants have additional enzymes! • NADH dehydrogenase in matrix that transfers e- from NADH to UQ w/o pumping H+
Additional e- transport enzymes! • NADH dehydrogenase in matrix that transfers e- from NADH to UQ w/o pumping H+ Insensitive to rotenone
Additional e- transport enzymes! • NADH dehydrogenase in matrix that transfers e- from NADH to UQ w/o pumping H+ Insensitive to rotenone • Helps burn off excess NADH from making precursors
Additional e- transport enzymes! • NADH dehydrogenase in matrix that transfers e- from NADH to UQ w/o pumping H+ Insensitive to rotenone • Helps burn off excess NADH from making precursors • Much lower affinity for NADH than complex I
Additional e- transport enzymes! • NADH dehydrogenase in matrix that transfers e- from NADH to UQ w/o pumping H+ Insensitive to rotenone • Helps burn off excess NADH from making precursors • Energy is released as heat • NADH dehydrogenase in intermembrane space that transfers e- from NADH to UQ w/o pumping H+
Additional e- transport enzymes! • NADH dehydrogenase in intermembrane space that transfers e- from NADH to UQ w/o pumping H+ Insensitive to rotenone • "imports" e- from cytoplasmic NADH • Much lower affinity for NADH than complex I • Energy is released as heat
Additional e- transport enzymes! • NADPH dehydrogenase in intermembrane space that transfers e- from NADPH to UQ w/o pumping H+ Insensitive to rotenone • "imports" e- from cytoplasmic NADPH
Additional e- transport enzymes! • Alternative oxidase on matrix side of IM transfers e- from UQ to O2 w/o pumping H+ • Insensitive to Cyanide, Azide • or CO • Sensitive to SHAM • (salicylhydroxamic acid)
Additional e- transport enzymes! • Alternative oxidase on matrix side of IM transfers e- from UQ to O2 w/o pumping H+ • Insensitive to Cyanide, Azide or CO • Sensitive to SHAM (salicylhydroxamic acid,) • Also found in fungi, trypanosomes & Plasmodium
Additional e- transport enzymes! • Alternative oxidase on matrix side of IM transfers e- from UQ to O2 w/o pumping H+ • Also found in fungi, trypanosomes & Plasmodium • Energy lost as heat: • can raise Voodoo lilies • 25˚ C
Additional e- transport enzymes! • Alternative oxidase on matrix side of IM transfers e- from UQ to O2 w/o pumping H+ • Plants also have an uncoupler protein: lets H+ in w/o doing work!
Additional e- transport enzymes! Why so many ways to reduce ATP synthesis efficiency? Additional e- transport enzymes! Why so many ways to reduce ATP synthesis efficiency?
Additional e- transport enzymes! • Why so many ways to reduce ATP synthesis efficiency? • Regenerate NAD+ needed for precursor synthesis • Generate heat • Burn off excess energy captured by photosynthesis • Prevalence says they're doing something important! • Additional e- transport enzymes! • Why so many ways to reduce ATP synthesis efficiency? • Regenerate NAD+ needed for precursor synthesis • Generate heat • Burn off excess energy captured by photosynthesis • Prevalence says they're doing something important!
Regulating Respiration Regulated by demand for ATP, NADPH and substrates
Glycolysis is allosterically regulated at 3 irreversible steps Hexokinase is allosterically inhibited by its product: G-6P Allosteric site has lower affinity than active site
Glycolysis is allosterically regulated at 3 irreversible steps Hexokinase is allosterically inhibited by its product: G-6P Pyr kinase is allosterically inhibited by ATP & citrate
Regulating Glycolysis • Main regulatory step is Phosphofructokinase • Rate-limiting step • Committed step
Regulating Glycolysis • Main regulatory step is • Phosphofructokinase • Inhibited by Citrate, PEP & ATP • Stimulated by • ADP
Regulating Pyruvate DH • Mainly by a kinase • Inhibited when Pi added
Regulating Pyruvate DH • Mainly by a kinase • Inhibited when Pi added • NADH, Acetyl CoA, ATP • NH4+ inhibit PDH & • activate kinase
Regulating Pyruvate DH • Mainly by a kinase • Inhibited when Pi added • NADH, Acetyl CoA, ATP • NH4+ inhibit PDH & • activate kinase • Activated when no Pi • ADP, pyruvate inhibit • kinase
REGULATING THE KREBS CYCLE Krebs cycle is allosterically regulated at 4 enzymes citrate synthase Isocitrate dehydrogenase 3) a-ketoglutarate dehydrogenase 4) Malate dehydrogenase
REGULATING THE KREBS CYCLE Krebs cycle is allosterically regulated at 4 enzymes citrate synthase Isocitrate dehydrogenase 3) a-ketoglutarate dehydrogenase 4) Malate dehydrogenase All are inhibited by NADH & products
Environmental factors • Temperature • Rate ~ doubles for each 10˚ C increase up to ~ 40˚ • At higher T start to denature
Environmental factors • Temperature • Rate ~ doubles for each 10˚ C increase up to ~ 40˚ • At higher T start to denature 2) pO2 • Respiration declines if pO2 <5%
Environmental factors • Temperature • Rate ~ doubles for each 10˚ C increase up to ~ 40˚ • At higher T start to denature 2) pO2 • Respiration declines if pO2 <5% • Problem for flooded roots
Environmental factors • Temperature • Rate ~ doubles for each 10˚ C increase up to ~ 40˚ • At higher T start to denature 2) pO2 • Respiration declines if pO2 <5% • Problem for flooded roots • pCO2 • Inhibits respiration at 3%
Environmental factors • Temperature • Rate ~ doubles for each 10˚ C increase up to ~ 40˚ • At higher T start to denature 2) pO2 • Respiration declines if pO2 <5% • Problem for flooded roots • pCO2 • Inhibits respiration at 3% • No obvious effects at 700 ppm, yet biomass reduced