Lactate dehydrogenase has no control on lactate production but has a strong negative control on formate production in <i>Lactococcus lactis</i>

Andersen, Heidi Winterberg; Pedersen, Martin Bastian; Hammer, Karin; Jensen, Peter Ruhdal

doi:10.1046/j.0014-2956.2001.02599.x

Cited by 61 publications

(55 citation statements)

References 36 publications

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“…The inferior characteristics observed for the Ldh enzyme present in this strain are reflected in the observation that the lactateproducing capacity in this strain never exceeded approximately 85% of the total carbon flux, which is significantly lower than that observed in wild-type cells (Ͼ95%) (20,43). Previously, it has been shown that the las operon-encoded Ldh enzyme has a low degree of control over lactate formation rates in L. lactis (1), which is in agreement with the metabolic predictions generated by the kinetic model of the lactococcal pyruvate metabolism (23). However, replacement of the las operon-encoded Ldh enzyme with LdhB in that same model confirms the metabolic values reported here (data not shown; reference 23; jjj .biochem.sun.ac.za/wcfs.html).…”

Section: Discussionmentioning

confidence: 99%

IS 981 -Mediated Adaptive Evolution Recovers Lactate Production by ldhB Transcription Activation in a Lactate Dehydrogenase-Deficient Strain of Lactococcus lactis

et al. 2003

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Lactococcus lactis NZ9010 in which the las operon-encoded ldh gene was replaced with an erythromycin resistance gene cassette displayed a stable phenotype when grown under aerobic conditions, and its main end products of fermentation under these conditions were acetate and acetoin. However, under anaerobic conditions, the growth of these cells was strongly retarded while the main end products of fermentation were acetate and ethanol. Upon prolonged subculturing of this strain under anaerobic conditions, both the growth rate and the ability to produce lactate were recovered after a variable number of generations. This recovery was shown to be due to the transcriptional activation of a silent ldhB gene coding for an Ldh protein (LdhB) with kinetic parameters different from those of the native las operon-encoded Ldh protein. Nevertheless, cells producing LdhB produced mainly lactate as the end product of fermentation. The mechanism underlying the ldhB gene activation was primarily studied in a single-colony isolate of the recovered culture, designated L. lactis NZ9015. Integration of IS981 in the upstream region of ldhB was responsible for transcription activation of the ldhB gene by generating an IS981-derived ؊35 promoter region at the correct spacing with a natively present ؊10 region. Subsequently, analysis of 10 independently isolated lactate-producing derivatives of L. lactis NZ9010 confirmed that the ldhB gene is transcribed in all of them. Moreover, characterization of the upstream region of the ldhB gene in these derivatives indicated that site-specific and directional IS981 insertion represents the predominant mechanism of the observed recovery of the ability to produce lactate.Homolactic fermentation by lactic acid bacteria involves the classical Embden-Meyerhoff-Parnas pathway leading to pyruvate, which is converted to lactic acid by lactate dehydrogenase. This enzyme and the gene that encodes it have been studied in many lactic acid bacteria, including Lactococcus lactis (11, 34), Streptococcus thermophilus (19), and various lactobacilli (2,15,47,51). L. lactis is the best-studied representative of this group, and the complete and partial genomes of several strains have been determined (4, 29). The gene encoding L. lactis Ldh was identified and characterized by Llanos and coworkers in 1992 (33, 34). The ldh gene is the last gene of the so-called lactic acid synthesis or las operon, which also encodes the glycolytic enzymes phosphofructokinase and pyruvate kinase. Transcription of the las operon was shown to yield a polycistronic transcript encompassing all three genes. But under some conditions, transcripts representing only two genes (pfk and pyk or pyk and ldh) or even a single gene (ldh) of the operon were also detected, which probably resulted from RNA processing upstream of the pyk and ldh genes (38). It has been shown that the las operon is subject to CcpAmediated carbon catabolite transcriptional activation, and a CcpA target site (cre sequence) was found within the las promoter region (38). The...

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Section: Discussionmentioning

confidence: 99%

IS 981 -Mediated Adaptive Evolution Recovers Lactate Production by ldhB Transcription Activation in a Lactate Dehydrogenase-Deficient Strain of Lactococcus lactis

et al. 2003

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“…Quantification of glucose, pyruvate, lactate, formate, acetoin, acetate, and ethanol by HPLC was performed as described previously (1).…”

Section: Methodsmentioning

confidence: 99%

“…Andersen and colleagues used modulation of gene expression to show that lactate dehydrogenase has no control on the glycolytic flux in L. lactis MG1363 (1). Phosphofructokinase (PFK), on the other hand, appeared to be present in a very low excess, and even a small reduction of PFK activity resulted in an almost proportional decrease in the glycolytic flux (2).…”

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Glyceraldehyde-3-Phosphate Dehydrogenase Has No Control over Glycolytic Flux in Lactococcus lactis MG1363

2003

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Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) has previously been suggested to have almost absolute control over the glycolytic flux in Lactococcus lactis (B. Poolman, B. Bosman, J. Kiers, and W. N. Konings, J. Bacteriol. 169:5887-5890, 1987). Those studies were based on inhibitor titrations with iodoacetate, which specifically inhibits GAPDH, and the data suggested that it should be possible to increase the glycolytic flux by overproducing GAPDH activity. To test this hypothesis, we constructed a series of mutants with GAPDH activities from 14 to 210% of that of the reference strain MG1363. We found that the glycolytic flux was unchanged in the mutants overproducing GAPDH. Also, a decrease in the GAPDH activity had very little effect on the growth rate and the glycolytic flux until 25% activity was reached. Below this activity level, the glycolytic flux decreased proportionally with decreasing GAPDH activity. These data show that GAPDH activity has no control over the glycolytic flux (flux control coefficient ‫؍‬ 0.0) at the wild-type enzyme level and that the enzyme is present in excess capacity by a factor of 3 to 4. The early experiments by Poolman and coworkers were performed with cells resuspended in buffer, i.e., nongrowing cells, and we therefore analyzed the control by GAPDH under similar conditions. We found that the glycolytic flux in resting cells was even more insensitive to changes in the GAPDH activity; in this case GAPDH was also present in a large excess and had no control over the glycolytic flux.Lactic acid bacteria (LAB) are used extensively for the fermentation of food products, where the resulting acidification preserves the food and contributes to the texture and organoleptic quality. The major fermentation product of LAB is lactic acid, but depending on the actual LAB species and the conditions for growth, other products can be formed, which may contribute to the flavor of the fermented products. The regulation of by-products formed by LAB sugar metabolism has been studied extensively, mainly with Lactococcus lactis as the model organism. The work has focused on identification of key metabolites and mechanisms involved in regulating the switch between fermentation modes (7,8,12,13,14,15,18,28,30,39,40).Much less work has been performed with respect to investigating the control of the glycolytic flux in L. lactis. Andersen and colleagues used modulation of gene expression to show that lactate dehydrogenase has no control on the glycolytic flux in L. lactis MG1363 (1). Phosphofructokinase (PFK), on the other hand, appeared to be present in a very low excess, and even a small reduction of PFK activity resulted in an almost proportional decrease in the glycolytic flux (2). However, recent studies showed that PFK has no control over the glycolytic flux either (25; B. J. Koebmann et al., unpublished data). Poolman and coworkers used inhibition with iodoacetate to investigate the control by glyceraldehyde-3-phosphate dehydrogenase (GAPDH) in nongrowing cells of L. lactis subsp. cremoris strai...

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“…The activities of PYK and LDH have previously been shown to affect pyruvate metabolism in L. lactis (1,7), and differences in fermentation patterns between glucose and maltose could thus be due to differences in the specific activities of these enzymes on maltose. The specific activities of the three las enzymes in wild-type strain MG1363 grown on maltose and on glucose were therefore measured and found to be almost identical (data not shown).…”

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“…One study focusing on the las operon, coding for phosphofructokinase (PFK), pyruvate kinase (PYK), and LDH (9), revealed that LDH has a strong negative effect on the mixed acid flux; the flux control coefficient was less than Ϫ1, meaning that a 10% reduction in LDH leads to a Ͼ10% increase in the mixed acid flux (1). Another study revealed that PYK exhibits strong positive control of formate and acetate production (flux control coefficient for PYK on the formate and acetate flux were both close to 1) (7).…”

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The las Enzymes Control Pyruvate Metabolism in Lactococcus lactis during Growth on Maltose

et al. 2007

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The fermentation pattern of Lactococcus lactis with altered activities of the las enzymes was examined on maltose. The wild type converted 65% of the maltose to mixed acids. An increase in phosphofructokinase or lactate dehydrogenase expression shifted the fermentation towards homolactic fermentation, and with a high level of expression of the las operon the fermentation was homolactic.In Lactococcus lactis sugars can be metabolized either by homolactic fermentation, producing lactate, or by mixed acid fermentation, producing formate, acetate, and ethanol. The former mode of fermentation is favored during growth on readily metabolizable sugars, such as glucose and lactose, whereas growth on slowly fermentable sugars, such as maltose (11) and galactose (17), usually results in mixed acid fermentation.The mechanisms regulating this shift in metabolism are still unclear. It has been observed that under sugar starvation conditions the level of fructose-1,6-bisphosphate (FBP) is lowered (16), and since FBP is an allosteric activator of lactate dehydrogenase (LDH) (19), this could explain a shift in fermentation pattern (4, 16) (Fig. 1). The level of the triose phosphates dihydroxyacetone phosphate and glyceraldehyde-3-phosphate in L. lactis is also lowered during growth on slowly fermentable sugars (17). Since the triose phosphates are allosteric inhibitors of pyruvate formate lyase (PFL) (14), this may also be part of the explanation of the shift in fermentation mode (Fig. 1). Other investigators have suggested that the NADH/NAD ϩ ratio regulates the shift in metabolism. A correlation was found between this ratio and the glycolytic flux; a high ratio gave a high flux and vice versa (5). These investigators also determined that glyceraldehyde-3-phosphate dehydrogenase was activated and LDH was deactivated at low ratios, whereas the opposite was the case at high ratios. This type of regulation could, in combination with the above-mentioned effect of the triose phosphates, explain the shift in pyruvate metabolism. A more recent study indicated that both the level of FBP and the NADH/NAD ϩ ratio may be important, but with large variations between strains (18).In recent years the glucose metabolism in L. lactis has been studied extensively with respect to the glycolytic rate and product formation. One study focusing on the las operon, coding for phosphofructokinase (PFK), pyruvate kinase (PYK), and LDH (9), revealed that LDH has a strong negative effect on the mixed acid flux; the flux control coefficient was less than Ϫ1, meaning that a 10% reduction in LDH leads to a Ͼ10% increase in the mixed acid flux (1). Another study revealed that PYK exhibits strong positive control of formate and acetate production (flux control coefficient for PYK on the formate and acetate flux were both close to 1) (7). The positive control by PYK and the negative control by LDH almost cancelled out, resulting in very little effect of modulation of the entire operon on the fermentation pattern. In this paper we describe a control analysis of ...

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Lactate dehydrogenase has no control on lactate production but has a strong negative control on formate production in Lactococcus lactis

Cited by 61 publications

References 36 publications

IS 981 -Mediated Adaptive Evolution Recovers Lactate Production by ldhB Transcription Activation in a Lactate Dehydrogenase-Deficient Strain of Lactococcus lactis

IS 981 -Mediated Adaptive Evolution Recovers Lactate Production by ldhB Transcription Activation in a Lactate Dehydrogenase-Deficient Strain of Lactococcus lactis

Glyceraldehyde-3-Phosphate Dehydrogenase Has No Control over Glycolytic Flux in Lactococcus lactis MG1363

The las Enzymes Control Pyruvate Metabolism in Lactococcus lactis during Growth on Maltose

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