Alternatives to lactic acid: Possible advantages

Fields, Jeremy H. A.

doi:10.1002/jez.1402280306

Cited by 61 publications

(32 citation statements)

References 69 publications

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“…A number of alternative pathways to lactate and ethanol fermentation have been discovered in animals with high resistance to anoxia. These animals accumulate combinations of a number of end products including Ala, octopine, alanopine, acetate, propionate, 2-methyl-b~-tyrate, and succinate (Fields, 1983). The advantages of these alternative strategies for anaerobic fermentation are based on an increased ATP production per mo1 of substrate fermented, the production of NAD+ to provide a net sink for reductant, and the maintenance of the cellular pH.…”

Section: 1989)mentioning

confidence: 99%

Long-Term Anaerobic Metabolism in Root Tissue (Metabolic Products of Pyruvate Metabolism)

1993

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Vanlerberghe et al. (1990) have recently shown that the green alga Selenastrum minutum accumulates succinate under anaerobic conditions. They demonstrate that the OAA required for reduction to succinate is initially provided by transferring the amino group of aspartate to pymvate to provide a 2-fold increase in ATP yield per hexose as com- One of the difficulties with most of the studies on anaerobic metabolism in plants is that they are restricted to short time intervals, usually a maximum of 12 to 24 h Ranson, 1967% 1967b;Hoffman et al., 1986;Vanlerberghe et al., 1990;Roberts et al., 1992). However, since barley (Hordeum vulgare L.) and maize can usually survive 3 to 5 d of anaerobic stress (Harberd and Edwards, 1982;Lemke-Keyes and Sachs, 1989), it may be the long-term adaptations to anaerobic stress that are more important in determining sensitivity to flooding.In this study, we looked at the long-tem effects of anaeroshort-term effects. We show that although a number of metabolic products, lactate, Ala, malate, and succinate, accumulate during short-term anaerobiosis, they do not continue to increase during long-term anaerobiosis. We also examined the effect on the accumulation of metabolites of reducing both the leve1 of available nitrogen and the accumulation of ethanol by using an ADH-mutant. Finally, we 'Ooked at 'Ome Of the enzYmes involved in and wccinate production to determine whether anY Of these enzYmes are induced der anaerobic COnditions. 1988, 1989).Under hypoxic or anaerobic conditions, there are changes in the levels of glycolytic intermediates in roots and an increased glycolytic flux (the Pasteur effect) (Faiz-ur-Rahman occur so that the cell can meet its requirements for ATP despite the much lower efficiency of ATp production by fermentation. The increase in glycolytic flux &ring hypoxia is accompanied by the accumulation of a number of glycolytic end products including ethanoI, lactate, AIa, and various organic acids and amino acids (Effer and R~~~~~, 196713;Gfeller and Gibbs, 1984;Roberts et al., 1984;Hoffman et al., 1986;Roberts et al., 1992). A number of alternative pathways to lactate and ethanol fermentation have been discovered in animals with high resistance to anoxia. These animals accumulate combinations of a number of end products including Ala, octopine, alanopine, acetate, propionate, 2-methyl-b~-tyrate, and succinate (Fields, 1983). The advantages of these alternative strategies for anaerobic fermentation are based on an increased ATP production per mo1 of substrate fermented, the production of NAD+ to provide a net sink for reductant, and the maintenance of the cellular pH. Davies, 1980

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Section: 1989)mentioning

confidence: 99%

Long-Term Anaerobic Metabolism in Root Tissue (Metabolic Products of Pyruvate Metabolism)

1993

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“…TDH occurs in only a few animal groups, but is the predominant pyruvate reductase enzyme in haliotids, and highlights the importance of anaerobiosis in the adductor muscle (Gäde 1988). Although functionally analogous, TDH is often co-expressed with LDH (Livingstone 1991), but appears to maintain lower cytosolic redox potential during extended anaerobic episodes (Fields 1983), and accounts for 90-95% of the glycolytic redox maintenance in the adductor muscle of H. iris (Wells & Baldwin 1995;Wells et al 1998).…”

Section: Introductionmentioning

confidence: 99%

Thermal constraints on glycolytic metabolism in the New Zealand abalone,Haliotis iris:the role of tauropine dehydrogenase

Hickey

Wells²

2003

New Zealand Journal of Marine and Freshwater Research

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Black-foot abalone, Haliotis iris, were sampled from two populations in warm northern waters, and from two in colder southern waters. Abalone muscle is characterised by high activity of the glycolytic pyruvate reductase enzyme, tauropine dehydrogenase (TDH). Adductor muscle TDH was profiled for thermostability and activity to test the hypothesis that the enzyme may show adaptation in titre or kinetic characteristics reflecting thermal habitat. Temperature dependency of the apparent Michaelis-Menten constant of TDH for pyruvate ( app Km pyr ) suggested eurythermal enzyme behaviour below 20°C, and compromised function at the higher temperatures of northern populations occurring in the summer months. Thermostability profiles and enzyme activities suggest TDH expression does not differ significantly among populations (P > 0.05), indicating that this locus shows no compensation for temperature. The optimal temperature for efficient TDH function, estimated from V max ./ app Km pyr , is close to 20°C. The possible thermal constraints on glycolytic metabolism in H. iris are discussed.

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“…This is supported, in part, by the operation of a partial reductive TCA cycle from OAA to succinate (24). This pathway results in accumulation of succinate as a fermentative end-product contributing to redox balance and energy metabolism under anoxia (5,25).…”

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Anaerobic Metabolism in the N-Limited Green Alga Selenastrum minutum

Vanlerberghe

Turpin²

1990

Plant Physiol.

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The green alga Selenastrum minutum (Naeg.) Collins is able to assimilate NH4+ in the dark under anaerobic conditions (GC Vanlerberghe, AK Horsey, HG Weger, DH Turpin [1989] Plant Physiol 91: 1551-1557. In the present study, analysis of metabolites following addition of NH4+ to cells acclimated to anaerobic conditions has shown the following. There was a transient decline in adenylate energy charge from 0.6 to 0.4 followed by a recovery back to -0.6. This was accompanied by a rapid increase in pyruvate/phosphoenolpyruvate and fructose-1,6-bisphosphate/ fructose-6-phosphate ratios indicating activation of pyruvate kinase and 6-phosphofructokinase, respectively. There was also an increase in fructose-2,6-bisphosphate, which, since this alga lacks pyrophosphate dependent 6-phosphofructokinase can be inferred to inhibit gluconeogenic fructose-1,6-bisphosphatase.These changes resulted in an increase in the rate of anaerobic starch breakdown. Anaerobic NH4+ assimilation also resulted in a two-fold increase in the rate of production of the major fermentative end-products in this alga, D-lactate and ethanol. There was no change in the rate of accumulation of the fermentative endproduct succinate but malate accumulated under anoxia during NH4+ assimilation. A rapid increase in Gin and decline in Glu indicates that primary NH4+ assimilation under anoxia was via glutamine synthetase-glutamate synthase. Almost all N assimilated under these conditions was sequestered in alanine. These results allow us to propose a model for the regulation of carbon metabolism during anaerobic NH4+ assimilation.

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Alternatives to lactic acid: Possible advantages

Cited by 61 publications

References 69 publications

Long-Term Anaerobic Metabolism in Root Tissue (Metabolic Products of Pyruvate Metabolism)

Long-Term Anaerobic Metabolism in Root Tissue (Metabolic Products of Pyruvate Metabolism)

Thermal constraints on glycolytic metabolism in the New Zealand abalone,Haliotis iris:the role of tauropine dehydrogenase

Anaerobic Metabolism in the N-Limited Green Alga Selenastrum minutum

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