Coexpression of pyruvate decarboxylase and alcohol dehydrogenase genes in Lactobacillus brevis

Lactobacillus brevis ATCC367 was engineered to express pyruvate decarboxylase (PDC) and alcohol dehydrogenase (ADH) genes in order to increase ethanol fermentation from biomass-derived residues. First, a Gram-positive Sarcina ventriculi PDC gene (Svpdc) was introduced into L. brevis ATCC 367 to obtain L. brevis bbc03. The SvPDC was detected by immunoblot using an SvPDC oligo peptide antiserum, but no increased ethanol was detected in L. brevis bbc03. Then, an ADH gene from L. brevis (Bradh) was cloned behind the Svpdc gene that generated a pdc/adh-coupled ethanol cassette pBBC04. The pBBC04 restored anaerobic growth and conferred ethanol production of Escheirichia coli NZN111 (a fermentative defective strain incapable of growing anaerobically). Approximately 58 kDa (SvPDC) and 28 kDa (BrADH) recombinant proteins were observed in L. brevis bbc04. These results indicated that the Gram-positive ethanol production genes can be expressed in L. brevis using a Gram-positive promoter and pTRKH2 shuttle vector. This work provides evidence that expressing Gram-positive ethanol genes in pentose utilizing L. brevis will further aid manipulation of this microbe toward biomass to ethanol production.     

Influence of expression of the pet operon on intracellular metabolic fluxes of Escherichia coli

Fermentation patterns of Escherichia coli HB101 carrying plasmids expressing cloned genes of Zymomonas mobilis pyruvate decarboxylase (PDC) and alcohol dehydrogenase li (ADH) were determined in glucose-limited complex medium in pH-controlled anaerobic batch cultivations. Time profiles of glucose, dry cell weight, succinate, formate, acetate, and ethanol were determined, as were the activities of ADH and PDC. Fluxes through the central carbon pathways were calculated for each construct utilizing exponential phase data on extracellular components and assuming quasi-steady state for intermediate metabolites. Overall biomass yields were greatest for cells expressing both PDC and ADH activities. Yields of carbon catabolite end products were similar for all PDC-expressing strains and different from those for other strains. Relative to its glucose uptake rate, the strain with greatest PDC and ADH activities produces formate and acetate more slowly and ethanol more rapidly than other strains. Strong influences of plasmid presence and metabolic coupling complicate detailed interpretations of the data.     

Evaluation of the importance of lactate for the activation of ethanolic fermentation in lettuce roots in anoxia

According to the Davies–Roberts hypothesis, plants primarily respond to oxygen limitation by a burst of lactate production and the resulting pH drop in the cytoplasm activates ethanolic fermentation. To evaluate this system in lettuce ( Lactuca sativa L.), seedlings were subjected to anoxia and in vitro activities of alcohol dehydrogenase (ADH, EC 1.1.1.1), pyruvate decarboxylase (PDC, EC 4.1.1.1) and lactate dehydrogenase (LDH, EC 1.1.1.27) and concentrations of ethanol, acetaldehyde and lactate were determined in roots of the seedlings. The in vitro activities of ADH and PDC in the roots increase in anoxia, whereas no significant increase was measured in LDH activity. At 6 h, the ADH and PDC activities in the roots kept in anoxia were 2.8- and 2.9-fold greater than those in air, respectively. Ethanol and acetaldehyde in the roots accumulated rapidly in anoxia and increased 8- and 4-fold compared with those in air by 6 h, respectively. However, lactate concentration did not increase and an initial burst of lactate production was not found. Thus, ethanol and acetaldehyde production occurred without an increase in lactate synthesis. Treatments with antimycin A and salicylhydroxamic acid, which are respiratory inhibitors, to the lettuce seedlings in the presence of oxygen increased the concentrations of ethanol and acetaldehyde but not of lactate. These results suggest that ethanolic fermentation may be activated without preceding activation of lactate fermentation and may be not regulated by oxygen concentration directly.     

Alcohol Dehydrogenase and Pyruvate Decarboxylase Activity in Leaves and Roots of Eastern Cottonwood (Populus deltoides Bartr.) and Soybean (Glycine max L.)

Pyruvate decarboxylase (PDC, EC 4.1.1.1) and alcohol dehydrogenase (ADH, EC 1.1.1.1) are responsible for the anaerobic production of acetaldehyde and ethanol in higher plants. In developing soybean embryos, ADH activity increased upon imbibition and then declined exponentially with development, and was undetectable in leaves by 30 days after imbibition. PDC was not detectable in soybean leaves. In contrast, ADH activity remained high in developing cottonwood seedlings, with no decline in activity during development. ADH activity in the first fully expanded leaf of cottonwood was 230 micromoles NADH oxidized per minute per gram dry weight, and increased with leaf age. Maximal PDC activity of cottonwood leaves was 10 micromoles NADH oxidized per minute per gram dry weight. ADH activity in cottonwood roots was induced by anaerobic stress, increasing from 58 to 205 micromoles NADH oxidized per minute per gram dry weight in intact plants in 48 hours, and from 38 to 246 micromoles NADH oxidized per minute per gram dry weight in detached roots in 48 hours. Leaf ADH activity increased by 10 to 20% on exposure to anaerobic conditions. Crude leaf enzyme extracts with high ADH activity reduced little or no NADH when other aldehydes, such as trans-2-hexenal, were provided as substrate. ADH and PDC are constitutive enzyme in cottonwood leaves, but their metabolic role is not known.     

Enhanced low oxygen survival in Arabidopsis through increased metabolic flux in the fermentative pathway

We manipulated the enzyme activity levels of the alcohol fermentation pathway, pyruvate decarboxylase (PDC), and alcohol dehydrogenase (ADH) in Arabidopsis using sense and antisense overexpression of the corresponding genes (PDC1, PDC2, and ADH1). Transgenic plants were analyzed for levels of fermentation and evaluated for changes in hypoxic survival. Overexpression of either Arabidopsis PDC1 or PDC2 resulted in improved plant survival. In contrast, overexpression of Arabidopsis ADH1 had no effect on flooding survival. These results support the role of PDC as the control step in ethanol fermentation. Although ADH1 null mutants had decreased hypoxic survival, attempts to reduce the level of PDC activity enough to see an effect on plant survival met with limited success. The combination of flooding survival data and metabolite analysis allows identification of critical metabolic flux points. This information can be used to design transgenic strategies to improve hypoxic tolerance in plants.     

Detection and biochemical characterisation of fast and slow ethanol-producing yeasts

Summary By screening seven distillers' yeast strains, two strains ofSaccharomyces cerevisiae were identified as being either slow or fast ethanol producers. The levels of four key enzymes, invertase, pyruvate decarboxylase (PDC), alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ADD) in these strains during batch-fermentative production of ethanol were determined. In both strains, the levels of these enzymes varied during the fermentation. The fast-fermenting strain had higher levels of PDC and ADH, and lower levels of ADD, as compared to the slow-fermenting strain, at all stages of fermentation.

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Resumen Al hacer un muestreo siete levaduras de cerveza se han identificado dos cepas deSaccharomyces cerevisiae, caracterizandolas como productoras lenta y rápida de etanol. Para ambas cepas se determinaron, en el periodo de crecimiento exponencial los niveles de cuatro enzimas clave: invertasa, piruvato decarboxilasa (PDC), alcohol deshidrogenas (ADH) y aldehido deshidrogenasa (ADD). Los niveles de estos enzimas variaron durante la fermentación en las dos cepas. Los niveles de PDC y de ADH fueron más bajos y el nivel de ADD más bajo en la cepa fermentadora rápida comparada con la cepa fermentadora lenta.

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Résumé Par criblage de sept levures de distillerie, nous avons identifié deux souches deSaccharomyces cerevisiae produisant de l'éthanol, l'une rapidement et l'autre lentement. Les niveaux des quatre enzymes-clés, invertase, pyruvique décarboxylase (PDC), alcool déshydrogénase (ADH) et aldéhyde déshydrogénase (ADD) ont été déterminés chez ces souches pendant la production fermentative d'éthanol en batch. Chez les deux souches, les niveaux enzymatiques varient au cours de la fermentation. A tous les stades de celle-ci, la souche rapide présente un niveau élevé de PDC et ADH, et un niveau d'ADD inférieur à celui de la souche lente.

     

淹水对两种甜樱桃砧木根系无氧呼吸酶及发酵产物的影响

以美早/东北山樱桃、美早/马哈利为试材,研究了淹水过程中两种甜樱桃砧木生长根、褐色木质根中无氧呼吸酶——丙酮酸脱羧酶(PDC)、乙醇脱氢酶(ADH)和乳酸脱氢酶(LDH)活性及褐色木质根的发酵产物——乙醛、乙醇和乳酸含量变化,结果表明:两类根系PDC、LDH活性均呈先升后降趋势,ADH活性变化在生长根中亦先升后降,而在褐色木质根中为上升趋势,三种酶活性变化幅度表现为生长根大于褐色木质根;美早/东北山樱桃两类根系中ADH和LDH活性增加幅度大于美早/马哈利,PDC则相反;两种砧木褐色木质根乙醛、乙醇含量呈升高趋势,乳酸含量先升后降;最终美早/东北山樱桃褐色木质根中乙醛含量低于美早/马哈利,乙醇含量则相反,而乳酸含量前者较早达峰值且高于后者峰值。     

Effect of low temperature on ethanolic fermentation in rice seedlings

Rice seedlings (Oryza sativa L.) were incubated at 5-30 degrees C for 48 h and the effect of temperature on ethanolic fermentation in the seedlings was investigated in terms of low-temperature adaptation. Activities of alcohol dehydrogenase (ADH, EC 1.1.1.1) and pyruvate decarboxylase (PDC, EC 4.1.1.1) in roots and shoots of the seedlings were low at temperatures of 20-30 degrees C, whereas temperatures of 5, 7.5 and 10 degrees C significantly increased ADH and PDC activities in the roots and shoots. Temperatures of 5-10 degrees C also increased ethanol concentrations in the roots and shoots. The ethanol concentrations in the roots and shoots at 7.5 degrees C were 16- and 12-times greater than those in the roots and shoots at 25 degrees C, respectively. These results indicate that low temperatures (5-10 degrees C) induced ethanolic fermentation in the roots and shoots of the seedlings. Ethanol is known to prevent lipid degradation in plant membrane, and increased membrane-lipid fluidization. In addition, an ADH inhibitor, 4-methylpyrazole, decreased low-temperature tolerance in roots and shoots of rice seedlings and this reduction in the tolerance was recovered by exogenous applied ethanol. Therefore, production of ethanol by ethanolic fermentation may lead to low-temperature adaptation in rice plants by altering the physical properties of membrane lipids.     

Aerobic fermentation in tobacco pollen

We characterized the genes coding for the two dedicated enzymes of ethanolic fermentation, alcohol dehydrogenase (ADH) and pyruvate decarboxylase (PDC), and show that they are functional in pollen. Two PDC-encoding genes were isolated, which displayed reciprocal regulation: PDC1 was anaerobically induced in leaves, whereas PDC2 mRNA was absent in leaves, but constitutively present in pollen. A flux through the ethanolic fermentation pathway could be measured in pollen under all tested environmental and developmental conditions. Surprisingly, the major factor influencing the rate of ethanol production was not oxygen availability, but the composition of the incubation medium. Under optimal conditions for pollen tube growth, approximately two-thirds of the carbon consumed was fermented, and ethanol accumulated into the surrounding medium to a concentration exceeding 100 mM.     

Pyruvate decarboxylase provides growing pollen tubes with a competitive advantage in petunia

Rapid pollen tube growth places unique demands on energy production and biosynthetic capacity. The aim of this work is to understand how primary metabolism meets the demands of such rapid growth. Aerobically grown pollen produce ethanol in large quantities. The ethanolic fermentation pathway consists of two committed enzymes: pyruvate decarboxylase (PDC) and alcohol dehydrogenase (ADH). Because adh mutations do not affect male gametophyte function, the obvious question is why pollen synthesize an abundant enzyme if they could do just as well without. Using transposon tagging in Petunia hybrida, we isolated a null mutant in pollen-specific Pdc2. Growth of the mutant pollen tubes through the style is reduced, and the mutant allele shows reduced transmission through the male, when in competition with wild-type pollen. We propose that not ADH but rather PDC is the critical enzyme in a novel, pollen-specific pathway. This pathway serves to bypass pyruvate dehydrogenase enzymes and thereby maintain biosynthetic capacity and energy production under the unique conditions prevailing during pollen-pistil interaction.     

The catalytic direction of pyrophosphate:fructose 6-phosphate 1-phosphotransferase in rice coleoptiles in anoxia

The catalytic direction of pyrophosphate:fructose-6-phosphate 1-phosphotransferase (PFP; EC 2.7.1.90) in coleoptiles of rice ( Oryza sativa L.) seedlings subjected to anoxia stress is discussed. The stress greatly induced ethanol synthesis and increased activities of alcohol dehydrogenase (ADH; EC 1.1.1.1) and pyruvate decarboxylase (PDC; EC 4.1.1.1) in the coleoptiles, whereas the elevated PDC activity was much lower than the elevated ADH activity, suggesting that PDC may be one of the limiting factors for ethanolic fermentation in rice coleoptiles. Anoxic stress decreased concentrations of fructose 6-phosphate (Fru-6-P) and glucose 6-phosphate, and increased concentration of fructose 1,6-bisphosphate (Fru-1,6-bisP) in the coleoptiles. PFP activity in rice coleoptiles was low in an aerobic condition and increased during the stress, whereas no significant increase was found in ATP:fructose-6-phosphate 1-phosphotransferase (PFK; EC 2.7.1.11) activity in stressed coleoptiles. Fructose 2,6-bisphosphate concentration in rice coleoptiles was increased by the stress and pyrophosphate concentration was above the K_m for the forward direction of PFP and was sufficient to inhibit the reverse direction of PFP. Under stress conditions the potential of carbon flux from Fru-6-P toward ethanol through PFK may be much lower than the potential of carbon flux from pyruvate toward ethanol through PDC. These results suggest that PFP may play an important role in maintaining active glycolysis and ethanolic fermentation in rice coleoptiles in anoxia.     

Effect of hypoxic acclimation on anoxia tolerance in Vitis roots: response of metabolic activity and K+ fluxes

The effect of a hypoxic pre-treatment (HPT) on improving tolerance to prolonged anoxia conditions in two contrasting Vitis species (V. riparia, anoxia tolerant; V. rupestris, anoxia sensitive) was evaluated. The energy economy of root cells was studied by measuring heat production, the activity of pyruvate decarboxylase (PDC) and alcohol dehdrogenase (ADH), ethanol and ATP production, and K(+) fluxes. The results showed that HPT is an effective tool in order to maintain a sustainable metabolic performance in both the species under anoxia conditions, especially in sensitive species such as V. rupestris. Our results showed that the improved tolerance was mainly driven by: (i) an enhanced activity of key enzymes in alcohol fermentation (ADC and PDC); (ii) the capability to maintain a higher level of respiration, evidenced by a lesser decrease in heat development and ATP production; and (iii) the maintenance of a better ion homeostasis (highlighted by measurement of K(+) fluxes) and K(+) channel functionality.     

A high affinity pyruvate decarboxylase is present in cottonwood leaf veins and petioles: A second source of leaf acetaldehyde emission?

Considerable evidence indicates that acetaldehyde is released from the leaves of a variety of plants. The conventional explanation for this is that ethanol formed in the roots is transported to the leaves where it is converted to acetaldehyde by the alcohol dehydrogenase (ADH) found in the leaves. It is possible that acetaldehyde could also be formed in leaves by action of pyruvate decarboxylase (PDC), an enzyme with an uncertain metabolic role, which has been detected, but not characterized, in cottonwood leaves. We have found that leaf PDC is present in leaf veins and petioles, as well as in non-vein tissues. Veins and petioles contained measurable pyruvate concentrations in the range of 2 mM. The leaf vein form of the enzyme was purified approximately 143-fold, and, at the optimum pH of 5.6, the K_m value for pyruvate was 42 μM. This K_m is lower than the typical millimolar range seen for PDCs from other sources. The purified leaf PDC also decarboxylates 2-ketobutyric acid (K_m = 2.2 mM). We conclude that there are several possible sources of acetaldehyde production in cottonwood leaves: the well-characterized root-derived ethanol oxidation by ADH in leaves, and the decarboxylation of pyruvate by PDC in leaf veins, petioles, and other leaf tissues. Significantly, the leaf vein form of PDC with its high affinity for pyruvate, could function to shunt pyruvate carbon to the pyruvate dehydrogenase by-pass and thus protect the metabolically active vascular bundle cells from the effects of oxygen deprivation.     

Pyruvate metabolism in rice coleoptiles under anaerobiosis

Relative importance of ethanolic, lactate and alanine fermentation pathways was estimated in coleoptiles of rice seedlings (Oryza sativa L.) subjected to anoxic stress. The in vitro activities of alcohol dehydrogenase (ADH, EC 1.1.1.1), pyruvate decarboxylase (PDC, EC 4.1.1.1) and alanine aminotransferase (AlaAT, EC 2.6.1.2) in the coleoptiles increased in anoxia, whereas no significant increase was measured in lactate dehydrogenase (LDH, EC 1.1.1.27) activity. At 48 h, the ADH, PDC and AlaAT activities in anoxic coleoptiles were 62-, 15- and 7.6-fold greater, respectively, than those in the presence of oxygen. Ethanol and alanine in the coleoptiles accumulated rapidly under anoxia, increasing by 48 h, 57- and 5.6-fold compared with those in the presence of oxygen, respectively. However, lactate concentration did not increase and no initial burst of lactate production was detected. The relative ratio of carbon flux from pyruvate to ethanol, lactate and alanine in anoxic coleoptiles was estimated to be 92, 1 and 7% of the total carbon flux, respectively. These results suggest that the potential carbon flux from pyruvate to ethanol may be much greater than the potential flux from pyruvate to lactate and alanine in rice coleoptiles during anoxia.     

Ethanolic fermentation and anoxia tolerance in four rice cultivars

The relationship between coleoptile elongation and ethanolic fermentation was investigated in rice (Oryza sativa L.) coleoptiles of four cultivars subjected to a 48-h anoxic stress. The coleoptile elongation of all cultivars was suppressed by anoxic stress; however, the elongation of cvs Yukihikari and Nipponbare was much greater than that of cvs Leulikelash and Asahimochi. The stress did not significantly increase lactate dehydrogenase (LDH) activity or lactate concentration, but increased alcohol dehydrogenase (ADH) and pyruvate decarboxylase (PDC) activities, as well as ethanol concentration in the coleoptiles of all cultivars. The elevated ADH and PDC activities and ethanol concentration in cvs Yukihikari and Nipponbare were much greater than those of cvs Leulikelash and Asahimochi, suggesting that ethanolic fermentation is likely more active in cvs Yukihikari and Nipponbare than in cvs Leulikelash and Asahimochi. ATP concentration in cvs Yukihikari and Nipponbare in anoxia was also greater than that in cvs Leulikelash and Asahimochi in anoxia. The ethanol concentration in the coleoptiles was correlated with anoxia tolerance with respect to the ATP concentration and coleoptile elongation. These results suggest that the ability to increase ethanolic fermentation may be one of the determinants in anoxia tolerance of rice coleoptiles.     

低氧胁迫下24-表油菜素内酯对黄瓜幼苗根系生长及其无氧呼吸同工酶表达的影响

采用营养液水培,研究了低氧胁迫下24-表油菜素内酯(EBR)对黄瓜幼苗根系生长及其无氧呼吸同工酶表达的影响.结果表明:低氧胁迫增强了黄瓜幼苗根系丙酮酸脱羧酶(PDC)、乙醇脱氢酶(ADH)、乳酸脱氢酶(LDH)同工酶的表达,低氧胁迫下施用外源EBR的第3天PDC、ADH同工酶的表达量分别提高了18.8％、28.8％,而第6、第9天PDC、ADH、LDH同工酶的表达减弱,比单纯低氧处理分别降低19.5％、25.6％、53.4％及26.4％、26.0％、28.4％;低氧胁迫至第9天,黄瓜幼苗根系的生长受到了显著抑制(P＜0.05),而低氧胁迫下施用EBR,黄瓜幼苗根系的生长受抑制程度减轻,其根系总长、干重、根尖数较单纯低氧处理显著增加(P＜0.05),低氧抑制了黄瓜幼苗根系的生长,低氧胁迫下营养液添加EBR可调节黄瓜根系无氧呼吸同工酶的表达,缓解低氧胁迫对黄瓜幼苗根系的伤害.