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Pathogens • Agrobacterium tumefaciens: Greg • Agrobacterium rhizogenes • Pseudomonas syringeae • Pseudomonas aeruginosa: Mike • Viroids: Bryant • DNA viruses • RNA viruses: Rob • Fungi : Connor • oomycetes • Nematodes: Chris Symbionts • N-fixers • Endomycorrhizae • Ectomycorrhizae Nutrient transport in roots Move from soil to endodermis in apoplast Move from endodermis to xylem in symplast Nutrient transport in roots Transported into xylem by H+ antiporters, channels,pumps Transport to shoot Nutrients move up plant in xylem sap Nutrient transport in leaves Xylem sap moves through apoplast Leaf cells take up what they want Nutrient assimilation Assimilating N and S is very expensive! • Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd) Nutrient assimilation Assimilating N and S is very expensive! • Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd) • Assimilating NH4+ into amino acids also costs ATP + e- Nutrient assimilation Assimilating N and S is very expensive! • Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd) • Assimilating NH4+ into amino acids also costs ATP + e• Nitrogen fixation costs 16 ATP + 8 e- Nutrient assimilation Assimilating N and S is very expensive! • Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd) • Assimilating NH4+ into amino acids also costs ATP + e• Nitrogen fixation costs 16 ATP + 8 e• SO42- reduction to S2- costs 8 e- + 2ATP Nutrient assimilation Assimilating N and S is very expensive! • Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd) • Assimilating NH4+ into amino acids also costs ATP + e• Nitrogen fixation costs 16 ATP + 8 e• SO42- reduction to S2- costs 8 e- + 2ATP • S2- assimilation into Cysteine costs 2 more e• Most explosives are based on N or S! Nutrient assimilation Most explosives are based on N or S! Most nutrient assimilation occurs in source leaves! N cycle Must convert N2 to a form that can be assimilated • N2 -> NO3- occurs in atmosphere: lightning (8%) & Photochemistry (2%) of annual total fixed • Remaining 90% comes from biological fixation to NH4+ N cycle Soil bacteria denitrify NO3- & NH4+ back to N2 • Plants must act fast! • Take up NO3- & NH4+ but generally prefer NO3• Main form available due to bacteria N assimilation by non-N fixers Nitrate reductase in cytoplasm reduces NO3- to NO2NO3- + NADPH = NO2- + NADP+ large enzyme with FAD & Mo cofactors NO2- is imported to plastids & reduced to NH4+ by nitrite reductase N assimilation by non-N fixers NO2- is imported to plastids & reduced to NH4+ by nitrite reductase NO2- + 6 Fdred + 8 H+ = NH4+ + 6 Fdox + 2 H2O N assimilation by non-N fixers NO2- is imported to plastids & reduced to NH4+ by nitrite reductase NO2- + 6 Fdred + 8 H+ = NH4+ + 6 Fdox + 2 H2O Regulated at NO3- reductase; always << NO2- reductase NO2- is toxic! N assimilation by non-N fixers Regulated at NO3- reductase; always << NO2- reductase NO2- is toxic! NR induced by light & nitrate N assimilation by non-N fixers Regulated at NO3- reductase; always << NO2- reductase NO2- is toxic! NR induced by light & nitrate Regulated by kinase in dark, dephosphorylation in day NH4 assimilation GS -> GOGAT 1. Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi GS -> GOGAT 1. Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi 2. Glutamine + a-ketoglutarate + NADH/2 Fdred <=> 2 Glutamate + NAD+/ 2 Fdox GS -> GOGAT 1. Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi 2. Glutamine + a-ketoglutarate + NADH/2 Fdred <=> 2 Glutamate + NAD+/ 2 Fdox 3. Fd GOGAT lives in source cp GS -> GOGAT Fd GOGAT lives in source cp • NADH GOGAT lives in sinks GS -> GOGAT 1. Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi 2. Glutamine + a-ketoglutarate + NADH/2 Fdred <=> 2 Glutamate + NAD+/ 2 Fdox 3. Use glutamate to make other a.a. by transamination GS -> GOGAT 3. Use glutamate to make other a.a. by transamination Glutamate, aspartate & alanine can be converted to the other a.a. S assimilation SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid! S assimilation S is used in cysteine & methionine S assimilation S is used in cysteine & methionine Also used in CoA, S-adenosylmethionine S assimilation S is used in cysteine & methionine Also used in CoA, S-adenosylmethionine Also used in sulphoquinovosyl-diacylglycerol S assimilation S is used in cysteine & methionine Also used in CoA, S-adenosylmethionine Also used in sulphoquinovosyl-diacylglycerol And in many storage compounds: eg allicin (garlic) S assimilation SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid! Some bacteria use SO42- as e- acceptor -> H2S S assimilation SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid! Some bacteria use SO42- as e- acceptor -> H2S Some photosynthetic bacteria use reduced S as e- donor! S assimilation SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid! Some bacteria use SO42- as e- acceptor -> H2S Some photosynthetic bacteria use reduced S as e- donor! Now that acid rain has declined in N. Europe Brassica & wheat need S in many places S assimilation SO4 2- is taken up by roots & transported to leaves in xylem Most is reduced in cp S assimilation SO4 2- is taken up by roots & transported to leaves in xylem Most is reduced in cp 1. add SO4 2- to ATP -> APS S assimilation 1. add SO4 2- to ATP -> APS 2. Transfer S to Glutathione -> S-sulfoglutathione S assimilation 1. add SO4 2- to ATP -> APS 2. Transfer S to Glutathione -> S-sulfoglutathione 3. S-sulfoglutathione + GSH -> SO32- + GSSG 1. 2. 3. 4. S assimilation add SO4 2- to ATP -> APS Transfer S to Glutathione -> S-sulfoglutathione S-sulfoglutathione + GSH -> SO32- + GSSG Sulfite + 6 Fd -> Sulfide 1. 2. 3. 4. 5. • S assimilation add SO4 2- to ATP -> APS Transfer S to Glutathione -> S-sulfoglutathione S-sulfoglutathione + GSH -> SO32- + GSSG Sulfite + 6 Fd -> Sulfide Sulfide + O-acetylserine -> cysteine + acetate O-acetylserine was made from serine + acetyl-CoA S assimilation Most cysteine is converted to glutathione or methionine S assimilation Most cysteine is converted to glutathione or methionine Glutathione is main form exported S assimilation Most cysteine is converted to glutathione or methionine Glutathione is main form exported Also used to make many other S-compounds S assimilation Most cysteine is converted to glutathione or methionine Glutathione is main form exported Also used to make many other S-compounds Methionine also has many uses besides protein synthesis S assimilation Most cysteine is converted to glutathione or methionine 1. Cys + homoserine -> cystathione S assimilation Most cysteine is converted to glutathione or methionine 1. Cys + homoserine -> cystathione 2. Cystathione -> homocysteine + Pyruvate + NH4+ S assimilation Most cysteine is converted to glutathione or methionine 1. Cys + homoserine -> cystathione 2. Cystathione -> homocysteine + Pyruvate + NH4+ 3. Homocysteine + CH2=THF -> Met + THF 4. 80% of met is converted to S-adenosylmethionine & used for biosyntheses S assimilation Most cysteine is converted to glutathione or methionine Glutathione is made enzymatically! 1. Glutamate + Cysteine -> g-glutamyl cysteine S assimilation Glutathione (GluCysGly) is made enzymatically! 1. Glutamate + Cysteine -> g-glutamyl cysteine 2. g-glutamyl cysteine + glycine -> glutathionine S assimilation Glutathione (GluCysGly) is made enzymatically! 1. Glutamate + Cysteine -> g-glutamyl cysteine 2. g-glutamyl cysteine + glycine -> glutathionine Glutathione is precursor for many chemicals, eg phytochelatins S assimilation Glutathione (GluCysGly) is made enzymatically! 1. Glutamate + Cysteine -> g-glutamyl cysteine 2. g-glutamyl cysteine + glycine -> glutathionine Glutathione is precursor for many chemicals, eg phytochelatins SAM & glutathione are also precursors for many cell wall components Plant Growth Size & shape depends on cell # & cell size Plant Growth Size & shape depends on cell # & cell size Decide when,where and which way to divide Plant Growth Size & shape depends on cell # & cell size Decide which way to divide & which way to elongate • Periclinal = perpendicular to surface Plant Growth Size & shape depends on cell # & cell size Decide which way to divide & which way to elongate • Periclinal = perpendicular to surface: get longer Plant Growth Size & shape depends on cell # & cell size Decide which way to divide & which way to elongate • Periclinal = perpendicular to surface: get longer • Anticlinal = parallel to surface Plant Growth Size & shape depends on cell # & cell size Decide which way to divide & which way to elongate • Periclinal = perpendicular to surface: get longer • Anticlinal = parallel to surface: add more layers Plant Growth Decide which way to divide & which way to elongate • Periclinal = perpendicular to surface: get longer • Anticlinal = parallel to surface: add more layers Now must decide which way to elongate Plant Growth Decide which way to divide & which way to elongate • Periclinal = perpendicular to surface: get longer • Anticlinal = parallel to surface: add more layers Now must decide which way to elongate: which walls to stretch Plant Cell Walls and Growth Carbohydrate barrier surrounding cell • Protects & gives cell shape Plant Cell Walls and Growth Carbohydrate barrier surrounding cell • Protects & gives cell shape • 1˚ wall made first • mainly cellulose • Can stretch! Plant Cell Walls and Growth Carbohydrate barrier surrounding cell • Protects & gives cell shape • 1˚ wall made first • mainly cellulose • Can stretch! • 2˚ wall made after growth stops • Lignins make it tough Plant Cell Walls and Growth • 1˚ wall made first • mainly cellulose • Can stretch! Control elongation by controlling orientation of cell wall fibers as wall is made Plant Cell Walls and Growth • 1˚ wall made first • mainly cellulose • Can stretch! Control elongation by controlling orientation of cell wall fibers as wall is made • 1˚ walls = 25% cellulose, 25% hemicellulose, 35% pectin, 5% protein (but highly variable) Plant Cell Walls and Growth 1˚ walls = 25% cellulose, 25% hemicellulose, 35% pectin, 5% protein (but highly variable) Cellulose: ordered chains made of glucose linked b 1-4 Plant Cell Walls and Growth 1˚ walls = 25% cellulose, 25% hemicellulose, 35% pectin, 5% protein (but highly variable) Cellulose: ordered chains made of glucose linked b 1-4 • Cross-link with neighbors to form strong, stable fibers Plant Cell Walls and Growth Cellulose: ordered chains made of glucose linked b 1-4 • Cross-link with neighbors to form strong, stable fibers • Made by enzyme embedded in the plasma membrane Plant Cell Walls and Growth Cellulose: ordered chains made of glucose linked b 1-4 • Cross-link with neighbors to form strong, stable fibers • Made by enzyme embedded in the plasma membrane • Guided by cytoskeleton Plant Cell Walls and Growth Cellulose: ordered chains made of glucose linked b 1-4 • Cross-link with neighbors to form strong, stable fibers • Made by enzyme embedded in the plasma membrane • Guided by cytoskeleton • Cells with poisoned µtubules are misshapen Plant Cell Walls and Growth Cellulose: ordered chains made of glucose linked b 1-4 • Cross-link with neighbors to form strong, stable fibers • Made by enzyme embedded in the plasma membrane • Guided by cytoskeleton • Cells with poisoned µtubules are misshapen • Other wall chemicals are made in Golgi & secreted Plant Cell Walls and Growth Cellulose: ordered chains made of glucose linked b 1-4 • Cross-link with neighbors to form strong, stable fibers • Made by enzyme embedded in the plasma membrane • Guided by cytoskeleton • Cells with poisoned µtubules are misshapen • Other wall chemicals are made in Golgi & secreted • Only cellulose pattern is tightly controlled Plant Cell Walls and Growth Cellulose pattern is tightly controlled • 6 CES enzymes form a “rosette”: each makes 6 chains -> 36/fiber Plant Cell Walls and Growth Cellulose pattern is tightly controlled • 6 CES enzymes form a “rosette”: each makes 6 chains -> 36/fiber • Rosettes are guided by microtubules Plant Cell Walls and Growth Cellulose pattern is tightly controlled • 6 CES enzymes form a “rosette”: each makes 6 chains • Rosettes are guided by microtubules • Deposition pattern determines direction of elongation Plant Cell Walls and Growth Cellulose pattern is tightly controlled • Deposition pattern determines direction of elongation • New fibers are perpendicular to growth direction, yet fibers form a mesh Plant Cell Walls and Growth New fibers are perpendicular to growth direction, yet fibers form a mesh Multinet hypothesis: fibers reorient as cell elongates Old fibers are anchored so gradually shift as cell grows Plant Cell Walls and Growth New fibers are perpendicular to growth direction, yet fibers form a mesh Multinet hypothesis: fibers reorient as cell elongates Old fibers are anchored so gradually shift as cell grows Result = mesh
