Fermentative Metabolism of <i>Chlamydomonas reinhardii</i>

Gibbs, Martin; Gfeller, Rene P.; Chen, Changguo

doi:10.1104/pp.82.1.160

Cited by 92 publications

(74 citation statements)

References 23 publications

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“…Whereas P700 ϩ reduction is accelerated in the WT, it is markedly slower in sta6, showing that, when respiration is blocked by myxothiazol and ATP is depleted in the cells, sta6 cells are no longer capable of assimilating acetate, confirming that acetate assimilation is ATP-dependent (2, 3). Likewise, acetate cannot be assimilated under dark anaerobic conditions (28), suggesting that the ATP produced by glycolysis and fermentation is not enough to assimilate acetate. It explains why the burst of reducing power we observe after myxothiazol addition in the WT in acetate is only transient and correlates with the rate measured in stt7-9 dum11 in the same conditions.…”

Section: Lipid Breakdown (H Inmentioning

confidence: 99%

Interaction between Starch Breakdown, Acetate Assimilation, and Photosynthetic Cyclic Electron Flow in Chlamydomonas reinhardtii

Johnson

Alric

2012

Journal of Biological Chemistry

116

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Background: Most green microalgae grow photoautotrophically and heterotrophically. Results: The origin of chloroplast reductants in the dark is starch and/or acetate. Conclusion: It is possible to distinguish between these two carbon reserves and measure the reducing flux of carbohydrate catabolism using spectroscopic methods. Significance: The glycolytic flux in the chloroplast of green algae is faster than in plants.

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Section: Lipid Breakdown (H Inmentioning

confidence: 99%

Interaction between Starch Breakdown, Acetate Assimilation, and Photosynthetic Cyclic Electron Flow in Chlamydomonas reinhardtii

Johnson

Alric

2012

Journal of Biological Chemistry

116

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“…In alga1 cells fed with acetate, the glyoxysome, a single membrane-bound organelle, is involved in using acetyl-COA for gluconeogenesis through the glyoxylate cycle (Beevers, 1969;Monroy and Schwartzbach, 1984;Gibbs et al, 1986;Steinbiss and Zetsche, 1986;Rikin and Schwartzbach, 1989). The presence of acetate inhibits the expression of photosynthetic genes under light but activates the expression of glyoxysome enzymes for the metabolism of acetate (Monroy and Schwartzbach, 1984;Gibbs et al, 1986;Steinbiss and Zetsche, 1986;Kindle, 1987;Rikin and Schwartzbach, 1989). These observations suggest that in algae acetate is a more favorable exogenous carbon source than CO, , probably because the utilization of CO, involves the expression of more complex photosynthetic pathways.…”

Section: Acetate Repression 1s Evolutionarily Conserved In the Plant mentioning

confidence: 99%

Metabolic repression of transcription in higher plants.

1990

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Using freshly isolated maize mesophyll protoplasts and a transient expression method, I showed that the transcriptional activity of seven maize photosynthetic gene promoters is specifically and coordinately repressed by the photosynthetic end products sucrose and glucose and by the exogenous carbon source acetate. Analysis of deleted, mutated, and hybrid promoters showed that sugars and acetate inhibit the activity of distinct positive upstream regulatory elements without a common consensus. The metabolic repression of photosynthetic genes overrides other forms of regulation, e.g., light, tissue type, and developmental stage. Repression by sugars and repression by acetate are mediated by different mechanisms. The identification of conditions that avoid sugar repression overcomes a major obstacle to the study of photosynthetic gene regulation in higher plants.

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“…In the first step of acetate dissimilation, the acetate is converted to acetyl-CoA, a reaction that involves a pyrophosphoryl split of ATP, which is coupled to the acetylation of CoA by free acetate (13 It has to be emphasized that the increased ATP/NAD(P)H demand in the photoheterotrophic cells brings about not only changes in the antenna size and energy distribution (state transition), but it governs the photosystem stoichiometry as well. This is reflected in an increased number of PSI reaction centers ( Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Another possible interpretation of acetate effect on H2 photoevolution has to be considered also. During acetate metabolism, both C reinhardtii and C stellata consume ATP and produce NAD(P)H (13,31). The increased level of NAD(P)H may serve as the necessary electron donor system to PSI and in turn, via Fd, may accelerate the activation of hydrogenase in a reductive process (13,24).…”

Section: Resultsmentioning

confidence: 99%

“…During acetate metabolism, both C reinhardtii and C stellata consume ATP and produce NAD(P)H (13,31). The increased level of NAD(P)H may serve as the necessary electron donor system to PSI and in turn, via Fd, may accelerate the activation of hydrogenase in a reductive process (13,24). Other factors that may also result in differences in the activation of hydrogenase enzyme in the photoheterotrophic and autotrophic algae may be associated with the different 02-evolving activities of PSII or with differences in the reductive deoxygenation of the latent hydrogenase enzyme as well as in differences in protein synthesis of hydrogenase and its activators (12).…”

Section: Resultsmentioning

confidence: 99%

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Hydrogen Photoevolution Indicates an Increase in the Antenna Size of Photosystem I in Chlamydobotrys stellata during Transition from Autotrophic to Photoheterotrophic Nutrition

Boichenko¹,

Wießner²,

Klimov³

et al. 1992

Plant Physiol.

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The changes in the light-harvesting antenna size of photosystem I were investigated in the green alga Chiamydobotrys stellata during transition from autotrophic to photoheterotrophic nutrition by measuring the light-saturation behavior of hydrogen evolution following single turnover flashes. It was found that during autotrophic-to-photoheterotrophic transition the antenna size of photosystem I increased from 180 to 250 chlorophyll. The chlorophyll (a + b)/P700 ratio decreased from 800 to 550. The electron transport of photosystem I measured from reduced 2,6-dichlorophenolindophenol to methylviologen was accelerated 1.4 times. In the 77K fluorescence spectra, the photosystem II fluorescence yield was considerably lowered relative to the photosystem I fluorescence yield. It is suggested that the increased light-harvesting capacity and redistribution of absorbed excitation energy in favor of photosystem I is a response of photoheterotrophic algae to meet the ATP demand for acetate metabolism by efficient photosystenr. I cyclic electron transport when the noncyclic photophosphorylation is inhibited by CO2 deficiency.In the green alga Chlamydobotrys stellata, the ultrastructure and photosynthetic activities of chloroplast membranes depend on the nutritional conditions. Autotrophically grown cells evolve oxygen and utilize CO2 as a carbon source, like other unicellular green algae (25). Under heterotrophic culture conditions when CO2 is replaced by acetate, 02 evolution is abolished and only PSI activity is necessary for acetate metabolism (26,27). In the photoheterophic cells, the membrane structure of the chloroplasts is almost grana free (28) and the amount of

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Fermentative Metabolism of Chlamydomonas reinhardii

Cited by 92 publications

References 23 publications

Interaction between Starch Breakdown, Acetate Assimilation, and Photosynthetic Cyclic Electron Flow in Chlamydomonas reinhardtii

Interaction between Starch Breakdown, Acetate Assimilation, and Photosynthetic Cyclic Electron Flow in Chlamydomonas reinhardtii

Metabolic repression of transcription in higher plants.

Hydrogen Photoevolution Indicates an Increase in the Antenna Size of Photosystem I in Chlamydobotrys stellata during Transition from Autotrophic to Photoheterotrophic Nutrition

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