产甘油假丝酵母与酿酒酵母胞浆3-磷酸甘油脱氢酶基因的功能比较

胞浆3-磷酸甘油脱氢酶(GPD)是酿酒酵母细胞甘油合成过程中的关键限速酶．尽管高产甘油菌株产甘油假丝酵母基因组中编码该酶的基因CgGPD已经被克隆出来,但是具体的功能,特别是与酿酒酵母GPD1和GPD2基因的功能比较值得进一步研究．以酿酒酵母渗透压敏感型的gpd1/gpd2和gpd1突变株为宿主,分别导入CgGPD、GPD1和GPD2基因,比较分析了CgGPD、GPD1和GPD2基因在高渗透压胁迫条件下和厌氧环境中的表达调控,及其对细胞甘油合成能力的影响．研究发现,GPD1基因受到渗透压诱导表达,GPD2基因在细胞厌氧条件下起着氧化还原平衡调节作用,而CgGPD基因不仅能够在渗透压胁迫条件下通过过量快速合成甘油调节渗透压平衡,而且能够在厌氧培养环境中互补GPD2基因的缺失,使gpd1/gpd2缺失突变株能够正常生长,同时提高了突变株的甘油合成能力．结果表明,CgGPD基因在gpd1/gpd2缺失突变株中既具有GPD1基因的功能,又能发挥GPD2基因的功能．     

Effect of alternative NAD<Superscript>+</Superscript>-regenerating pathways on the formation of primary and secondary aroma compounds in a <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> glycerol-defective mutant

Saccharomyces cerevisiae maintains a redox balance under fermentative growth conditions by re-oxidizing NADH formed during glycolysis through ethanol formation. Excess NADH stimulates the synthesis of mainly glycerol, but also of other compounds. Here, we investigated the production of primary and secondary metabolites in S. cerevisiae strains where the glycerol production pathway was inactivated through deletion of the two glycerol-3-phosphate dehydrogenases genes (GPD1/GPD2) and replaced with alternative NAD⁺-generating pathways. While these modifications decreased fermentative ability compared to the wild-type strain, all improved growth and/or fermentative ability of the gpd1Δgpd2Δ strain in self-generated anaerobic high sugar medium. The partial NAD⁺ regeneration ability of the mutants resulted in significant amounts of alternative products, but at lower yields than glycerol. Compared to the wild-type strain, pyruvate production increased in most genetically manipulated strains, whereas acetate and succinate production decreased in all strains. Malate production was similar in all strains. Isobutanol production increased substantially in all genetically manipulated strains compared to the wild-type strain, whereas only mutant strains expressing the sorbitol producing SOR1 and srlD genes showed increases in isoamyl alcohol and 2-phenyl alcohol. A marked reduction in ethyl acetate concentration was observed in the genetically manipulated strains, while isobutyric acid increased. The synthesis of some primary and secondary metabolites appears more readily influenced by the NAD⁺/NADH availability. The data provide an initial assessment of the impact of redox balance on the production of primary and secondary metabolites which play an essential role in the flavour and aroma character of beverages.     

Over-expressing <Emphasis Type="Italic">GLT1</Emphasis> in a <Emphasis Type="Italic">gpd2</Emphasis>Δ mutant of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> to improve ethanol production

We constructed two recombinant strains of Saccharomyces cerevisiae in which the GPD2 gene was deleted using a one-step gene replacement method to minimize formation of glycerol and improve ethanol production. In addition, we also over-expressed the GLT1 gene by a two-step gene replacement method to overcome the redox-imbalancing problem in the genetically modified strains. The result of anaerobic batch fermentations showed that the rate of growth and glucose consumption of the KAM-5 (MATα ura3 gpd2Δ::RPT) strain were slower than the original strain, and the KAM-13 (MATα ura3 gpd2Δ::RPT P _PGK -GLT1) strain, however, was indistinguishable compared to the original strain using the same criteria, as analyzed. On the other hand, when compared to the original strain, there were 32 and 38% reduction in glycerol formation for KAM-5 and KAM-13, respectively. Ethanol production increased by 8.6% for KAM-5 and 13.4% for KAM-13. Dramatic reduction in acetate and pyruvic acid was also observed in both mutants compared to the original strains. Although gene GPD2 is responsible for the glycerol synthesis, the mutant KAM-13, in which glycerol formation was substantially reduced, was able to cope and maintain osmoregulation and redox balance and have increased ethanol production under anaerobic fermentations. The result verified the proposed concept of increasing ethanol production in S. cerevisiae by genetic engineering of glycerol synthesis and over-expressing the GLT1 gene along with reconstituted nicotinamide adenine dinucleotide metabolism.     

Elimination of glycerol and replacement with alternative products in ethanol fermentation by <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Glycerol is a major by-product of ethanol fermentation by Saccharomyces cerevisiae and typically 2–3% of the sugar fermented is converted to glycerol. Replacing the NAD⁺-regenerating glycerol pathway in S. cerevisiae with alternative NADH reoxidation pathways may be useful to produce metabolites of biotechnological relevance. Under fermentative conditions yeast reoxidizes excess NADH through glycerol production which involves NADH-dependent glycerol-3-phosphate dehydrogenases (Gpd1p and Gpd2p). Deletion of these two genes limits fermentative activity under anaerobic conditions due to accumulation of NADH. We investigated the possibility of converting this excess NADH to NAD⁺ by transforming a double mutant (gpd1∆gpd2∆) with alternative oxidoreductase genes that might restore the redox balance and produce either sorbitol or propane-1,2-diol. All of the modifications improved fermentative ability and/or growth of the double mutant strain in a self-generated anaerobic high sugar medium. However, these strain properties were not restored to the level of the parental wild-type strain. The results indicate an apparent partial NAD⁺ regeneration ability and formation of significant amounts of the commodity chemicals like sorbitol or propane-1,2-diol. The ethanol yields were maintained between 46 and 48% of the sugar mixture. Other factors apart from the maintenance of the redox balance appeared to influence the growth and production of the alternative products by the genetically manipulated strains.     

Interruption of glycerol pathway in industrial alcoholic yeasts to improve the ethanol production

The two homologous genes GPD1 and GPD2, encoding two isoenzymes of NAD⁺-dependent glycerol-3-phosphate dehydrogenase in industrial yeast Saccharomyces cerevisiae CICIMY0086, had been deleted. The obtained two kinds of mutants gpd1Δ and gpd2Δ were studied under alcoholic fermentation conditions. gpd1Δ mutants exhibited a 4.29% (relative to the amount of substrate consumed) decrease in glycerol production and 6.83% (relative to the amount of substrate consumed) increased ethanol yield while gpd2Δ mutants exhibited a 7.95% (relative to the amount of substrate consumed) decrease in glycerol production and 7.41% (relative to the amount of substrate consumed) increased ethanol yield compared with the parental strain. The growth rate of the two mutants were slightly lower than that of the wild type under the exponential phase whereas ANG1 (gpd1Δ) and the decrease in glycerol production was not accompanied by any decline in the protein content of the strain ANG1 (gpd1Δ) but a slight decrease in the strain ANG2 (gpd2Δ). Meanwhile, dramatic decrease of acetate acid formation was observed in strain ANG1 (gpd1Δ) and ANG2 (gpd2Δ) compared to the parental strain. Therefore, it is possible to improve the ethanol yield by interruption of glycerol pathway in industrial alcoholic yeast.     

Gpd1 and Gpd2 fine-tuning for sustainable reduction of glycerol formation in Saccharomyces cerevisiae

Gpd1 and Gpd2 are the two isoforms of glycerol 3-phosphate dehydrogenase (GPDH), which is the rate-controlling enzyme of glycerol formation in Saccharomyces cerevisiae. The two isoenzymes play crucial roles in osmoregulation and redox balancing. Past approaches to increase ethanol yield at the cost of reduced glycerol yield have most often been based on deletion of either one or two isogenes (GPD1 and GPD2). While single deletions of GPD1 or GPD2 reduced glycerol formation only slightly, the gpd1Δ gpd2Δ double deletion strain produced zero glycerol but showed an osmosensitive phenotype and abolished anaerobic growth. Our current approach has sought to generate "intermediate" phenotypes by reducing both isoenzyme activities without abolishing them. To this end, the GPD1 promoter was replaced in a gpd2Δ background by two lower-strength TEF1 promoter mutants. In the same manner, the activity of the GPD2 promoter was reduced in a gpd1Δ background. The resulting strains were crossed to obtain different combinations of residual GPD1 and GPD2 expression levels. Among our engineered strains we identified four candidates showing improved ethanol yields compared to the wild type. In contrast to a gpd1Δ gpd2Δ double-deletion strain, these strains were able to completely ferment the sugars under quasi-anaerobic conditions in both minimal medium and during simultaneous saccharification and fermentation (SSF) of liquefied wheat mash (wheat liquefact). This result implies that our strains can tolerate the ethanol concentration at the end of the wheat liquefact SSF (up to 90 g liter(-1)). Moreover, a few of these strains showed no significant reduction in osmotic stress tolerance compared to the wild type.     

Osmoregulation of fission yeast: cloning of two distinct genes encoding glycerol-3-phosphate dehydrogenase, one of which is responsible for osmotolerance for growth

Many types of microorganisms, including both prokaryotes and eukaryotes, have developed mechanisms to adapt to severe osmotic stress. In this study, we isolated multicopy suppressor genes for a Schizosaccharomyces pombe mutant, which exhibited the clear phenotype of being osmosensitive for growth (Osm^s) on agar plates containing high concentrations of either non-ionic or ionic osmotic solutes. Two genes were thus identified, and each was suggested to encode an NADH-dependent glycerol-3-phosphate dehydrogenase (GPD), which is required for glycerol synthesis. The nucleotide sequences, determined for these genes (named gpd1 ⁺ and gpd2 ⁺, respectively), revealed that S. pombe has two distinct GPD isozymes. They are only 60% identical to each other in their amino acid sequences. One such isozyme, GPD1, was shown to be directly involved in osmoregulation, based on the following observations. (i) Expression of gpd1 ⁺ was regulated at the mRNA level in response to osmotic upshift, (ii) It was demonstrated that wild-type cells markedly accumulated internal glycerol under high-osmolarity growth conditions. (iii) Δ gpd1 mutants, however, failed to do so even in a high-osmolarity medium, and thus exhibited an Osm^s phenotype. On the other hand, the gpd2 ⁺ gene was constitutively expressed at a particular low level, regardless of the osmolarity of the medium.     

Cloning and characterization of a NAD+-dependent glycerol-3-phosphate dehydrogenase gene from Candida glycerinogenes, an industrial glycerol producer

The osmotolerant yeast Candida glycerinogenes produces glycerol as a major metabolite on an industrial scale, but the underlying molecular mechanisms are poorly understood. We cloned and characterized a 4900-bp genomic fragment containing the CgGPD gene encoding a glycerol-3-phosphate dehydrogenase homologous to GPD genes in other yeasts using degenerate primers in conjunction with inverse PCR. Sequence analysis revealed a 1167-bp open reading frame encoding a putative peptide of 388 deduced amino acids with a molecular mass of 42 695 Da. The CgGPD gene consisted of an N-terminal NAD⁺-binding domain and a central catalytic domain, whereas seven stress response elements were found in the upstream region. Functional analysis revealed that Saccharomyces cerevisiae gpd1 Δ and gpd1 Δ/ gpd2 Δ osmosensitive mutants transformed with CgGPD were restored to the wild-type phenotype when cultured in high osmolarity media, suggesting that it is a functional GPD protein. Transformants also accumulated glycerol intracellularly and GPD-specific activity increased significantly when stressed with NaCl, whereas the S. cerevisiae mutants transformed with the empty plasmid showed only slight increases. The full-length CgGPD gene sequence including upstream and downstream regions has been deposited in GenBank under accession no. EU186536 .     

Physiological response to anaerobicity of glycerol-3-phosphate dehydrogenase mutants of Saccharomyces cerevisiae.

Mutants of Saccharomyces cerevisiae, in which one or both of the genes encoding the two isoforms of NAD-dependent glycerol-3-phosphate dehydrogenase had been deleted, were studied in aerobic batch cultures and in aerobic-anaerobic step change experiments. The respirofermentative growth rates under aerobic conditions with semisynthetic medium (20 g of glucose per liter) of two single mutants, gpd1 delta and gpd2 delta, and the parental strain (mu = 0.5 h-1) were almost identical, whereas the growth rate of a double mutant, gpd1 delta gpd2 delta, was approximately half that of the parental strain. Upon a step change from aerobic to anaerobic conditions in the exponential growth phase, the specific carbon dioxide evolution rates (CER) of the wild-type strain and the gpd1 delta strain were almost unchanged. The gpd2 delta mutant showed an immediate, large (> 50%) decrease in CER upon a change to anaerobic conditions. However, after about 45 min the CER increased again, although not to the same level as under aerobic conditions. The gpd1 delta gpd2 delta mutant showed a drastic fermentation rate decrease upon a transition to anaerobic conditions. However, the CER values increased to and even exceeded the aerobic levels after the addition of acetoin. High-pressure liquid chromatographic analyses demonstrated that the added acetoin served as an acceptor of reducing equivalents by being reduced to butanediol. The results clearly show the necessity of glycerol formation as a redox sink for S. cerevisiae under anaerobic conditions.     

Improving ethanol productivity by modification of glycolytic redox factor generation in glycerol-3-phosphate dehydrogenase mutants of an industrial ethanol yeast

The GPD2 gene, encoding NAD⁺-dependent glycerol-3-phosphate dehydrogenase in an industrial ethanol-producing strain of Saccharomyces cerevisiae, was deleted. And then, either the non-phosphorylating NADP⁺-dependent glyceraldehyde-3-phosphate dehydrogenase (GAPN) from Bacillus cereus, or the NADP⁺-dependent glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from Kluyveromyces lactis, was expressed in the obtained mutant AG2 deletion of GPD2, respectively. The resultant recombinant strain AG2A (gpd2Δ P _PGK -gapN) exhibited a 48.70 ± 0.34% (relative to the amount of substrate consumed) decrease in glycerol production and a 7.60 ± 0.12% (relative to the amount of substrate consumed) increase in ethanol yield, while recombinant AG2B (gpd2Δ P _PGK -GAPDH) exhibited a 52.90 ± 0.45% (relative to the amount of substrate consumed) decrease in glycerol production and a 7.34 ± 0.15% (relative to the amount of substrate consumed) increase in ethanol yield compared with the wild-type strain. More importantly, the maximum specific growth rates (μ _max) of the recombinant AG2A and AG2B were higher than that of the mutant gpd2Δ and were indistinguishable compared with the wild-type strain in anaerobic batch fermentations. The results indicated that the redox imbalance of the mutant could be partially solved by expressing the heterologous genes.     

产甘油假丝酵母胞浆3-磷酸甘油脱氢酶基因（CgGPD）功能分析

【目的】从高产甘油生产菌株产甘油假丝酵母（Candida glycerinogenes）基因组中克隆了NAD+依赖3-磷酸甘油脱氢酶编码基因（CgGPD）,但是该基因及其上游调控序列具体的功能还是未知的。本文研究了CgGPD基因及其上游调控序列的功能。【方法】本文以酿酒酵母（Saccharomyces cerevisiae）及其渗透压敏感型突变株为宿主,构建3种不同的酵母表达载体导入酵母细胞,研究了不同酵母转化子在渗透压胁迫条件下CgGPD基因表达对细胞的耐高渗透压胁迫应答及其细胞的甘油合成能力的影响。【结果】实验结果表明无论是以来源于S. cerevisiae 的TPI启动子还是来源于CgGPD基因的启动子,过量表达CgGPD基因的转化子均能够显著加速葡萄糖消耗速度和提高甘油合成能力,在gpd1/gpd2突变株中表达CgGPD基因能够消除细胞对外界高渗透压的敏感性,同时转化子胞内甘油大量积累。【结论】CgGPD基因在野生型酵母S. cerevisiae W303-1A表达显著提高细胞的甘油合成能力,在gpd/1gpd2突变株中能够互补GPD1基因的功能,CgGPD基因表达受渗透压诱导 调控。     

Anaerobic growth and improved fermentation of Pichia stipitis bearing a URA1 gene from Saccharomyces cerevisiae

Respiratory and fermentative pathways co-exist to support growth and product formation in Pichia stipitis. This yeast grows rapidly without ethanol production under fully aerobic conditions, and it ferments glucose or xylose under oxygen-limited conditions, but it stops growing within one generation under anaerobic conditions. Expression of Saccharomyces cerevisiaeURA1 (ScURA1) in P. stipitis enabled rapid anaerobic growth in minimal defined medium containing glucose when essential lipids were present. ScURA1 encodes a dihydroorotate dehydrogenase that uses fumarate as an alternative electron acceptor to confer anaerobic growth. Initial P. stipitis transformants grew and produced 32 g/l ethanol from 78 g/l glucose. Cells produced even more ethanol faster following two anaerobic serial subcultures. Control strains without ScURA1 were incapable of growing anaerobically and showed only limited fermentation. P. stipitis cells bearing ScURA1 were viable in anaerobic xylose medium for long periods, and supplemental glucose allowed cell growth, but xylose alone could not support anaerobic growth even after serial anaerobic subculture on glucose. These data imply that P. stipitis can grow anaerobically using metabolic energy generated through fermentation but that it exhibits fundamental differences in cofactor selection and electron transport with glucose and xylose metabolism. This is the first report of genetic engineering to enable anaerobic growth of a eukaryote. Received: 6 January 1998 / Received revision: 9 April 1998 / Accepted: 19 April 1998     

Physiological and genetic characterisation of osmosensitive mutants of Saccharomyes cerevisiae

The screening of 20,000 Saccharomyces cerevisiae random mutants to identify genes involved in the osmotic stress response yielded 14 mutants whose growth was poor in the presence of elevated concentrations of NaCl and glucose. Most of the mutant strains were more sensitive to NaCl than to glucose at the equivalent water activity (a_w) and were classified as salt-sensitive rather than osmosensitive. These mutants fell into 11 genetic complementation groups and were designated osr1–osr11 (osmotic stress response). All mutations were recessive and showed a clear 2⁺ : 2^– segregation of the salt-stress phenotype upon tetrad analysis when crossed to a wild-type strain. The complementation groups osr1, osr5 and osr11 were allelic to the genes PBS2, GPD1 and KAR3, respectively. Whereas intracellular and extracellular levels of glycerol increased in the wild-type strains when exposed to NaCl, all mutants demonstrated some increase in extracellular glycerol production upon salt stress, but a number of the mutants showed little or no increase in intracellular glycerol concentrations. The mutants had levels of glycerol-3-phosphate dehydrogenase, an enzyme induced by osmotic stress, either lower than or similar to those of the parent wild-type strain in the absence of osmotic stress. In the presence of NaCl, the increase in glycerol-3-phosphate dehydrogenase activity in the mutants did not match that of the parent wild-type strain. None of the mutants had defective ATPases or were sensitive to heat stress. It is evident from this study and from others that a wide spectrum of genes is involved in the osmotic stress response in S. cerevisiae. Received: 5 January 1998 / Accepted: 24 March 1998     

Overexpressing <Emphasis Type="Italic">GLT1</Emphasis> in <Emphasis Type="Italic">gpd1</Emphasis>Δ mutant to improve the production of ethanol of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

To improve ethanol production in Saccharomyces cerevisiae, two yeast strains were constructed. In the mutant, KAM-4, the GPD1 gene, which encodes a glycerol 3-phosphate dehydrogenase of S. cerevisiae to synthesize glycerol, was deleted. The mutant KAM-12 had the GLT1 gene (encodes glutamate synthase) placed under the PGK1 promoter while harboring the GPD1 deletion. Notably, overexpression of GLT1 by the PGK1 promoter along with GPD1 deletion resulted in a 10.8% higher ethanol production and a 25.0% lower glycerol formation compared to the wild type in anaerobic fermentations. The growth rate of KAM-4 was slightly lower than that of the wild type under the exponential phase whereas KAM-12 and the wild type were indistinguishable in the biomass concentration at the end of growth period. Meanwhile, dramatic reduction of formation of acetate and pyruvic acid was observed in all the mutants compared to the wild type.     

Screening of high-yielding biocontrol bacterium Bs<Emphasis Type="Italic">-</Emphasis>916 mutant by ion implantation

Bacillus subtilis 916 was an effective biocontrol agent in control rice sheath blight caused by Rhizoctonia solani. To further improve its antagonistic ability, low-energy ion implantation was applied in Bs-916. We studied the effects of different doses of N⁺ implantation. The optimum dose of ion implantation for the Bs-916 was from 15 × 2.6 × 10¹⁴ N⁺/cm² to 25 × 2.6 × 10¹⁴ N⁺/cm². The mutant strain designated as Bs-H74 was obtained, which showed higher inhibition activity in the screening plate. Its inhibition zone against the indicator organism increased by 30.7% compared to the parental strain. The control effect of rice sheath blight was improved by 14.6% over that of Bs-916. Thin-layer chromatography and high-performance liquid chromatography analysis indicated that lipopeptides produced by Bs-916 and the mutant strains belonged to the surfactin family. Bs-H74 produced approximately 3.0-fold surfactin compared to that of Bs-916. To determine the role of surfactin in biocontrol by Bs-916, we tested another mutant strain, Bs-M49, which produced lower levels of surfactin significantly, and found that Bs-M49 had no obvious effects against R. solani. These results suggested that the surfactin produced by Bs-916 plays an important role in the suppression of sheath blight. These observations also showed that the Bs-H74 mutant strain is a better biocontrol agent than the parental strain.     

Deficiency in frataxin homologue YFH1 in the yeast Pichia guilliermondii leads to missregulation of iron acquisition and riboflavin biosynthesis and affects sulfate assimilation

Pichia guilliermondii is a representative of yeast species that overproduce riboflavin (vitamin B₂) in response to iron deprivation. P. guilliermondii YFH1 gene coding for frataxin homologue, eukaryotic mitochondrial protein involved in iron trafficking and storage, was identified and deleted. Constructed P. guilliermondii Δyfh1 mutant grew very poorly in a sucrose-containing synthetic medium supplemented with sulfate or sulfite as a sole sulfur source. Addition of sodium sulfide, glutathione, cysteine, methionine, N-acetyl-l-cysteine partially restored growth rate of the mutant suggesting that it is impaired in sulfate assimilation. Cellular iron content in Δyfh1 mutant was ~3–3.5 times higher as compared to the parental strain. It produced 50–70 times more riboflavin in iron sufficient synthetic media relative to the parental wild-type strain. Biomass yield of the mutant in the synthetic glutathione containing medium supplemented with glycerol as a sole carbon source was 1.4- and 2.6-fold increased as compared to sucrose and succinate containing media, respectively. Oxygen uptake of the Δyfh1 mutant on sucrose, glycerol or succinate, when compared to the parental strain, was decreased 5.5-, 1.7- and 1.5-fold, respectively. Substitution of sucrose or glycerol in the synthetic iron sufficient medium with succinate completely abolished riboflavin overproduction by the mutants. Deletion of the YFH1 gene caused hypersensitivity to hydrogen peroxide and exogenously added riboflavin and led to alterations in superoxide dismutase activities. Thus, deletion of the gene coding for yeast frataxin homologue has pleiotropic effect on metabolism in P. guilliermondii.     

Quantitative evaluation of yeast's requirement for glycerol formation in very high ethanol performance fed-batch process

Background

Glycerol is the major by-product accounting for up to 5% of the carbon in Saccharomyces cerevisiae ethanolic fermentation. Decreasing glycerol formation may redirect part of the carbon toward ethanol production. However, abolishment of glycerol formation strongly affects yeast's robustness towards different types of stress occurring in an industrial process. In order to assess whether glycerol production can be reduced to a certain extent without jeopardising growth and stress tolerance, the yeast's capacity to synthesize glycerol was adjusted by fine-tuning the activity of the rate-controlling enzyme glycerol 3-phosphate dehydrogenase (GPDH). Two engineered strains whose specific GPDH activity was significantly reduced by two different degrees were comprehensively characterized in a previously developed Very High Ethanol Performance (VHEP) fed-batch process.

Results

The prototrophic strain CEN.PK113-7D was chosen for decreasing glycerol formation capacity. The fine-tuned reduction of specific GPDH activity was achieved by replacing the native GPD1 promoter in the yeast genome by previously generated well-characterized TEF promoter mutant versions in a gpd2 Δ background. Two TEF promoter mutant versions were selected for this study, resulting in a residual GPDH activity of 55 and 6%, respectively. The corresponding strains were referred to here as TEFmut7 and TEFmut2. The genetic modifications were accompanied to a strong reduction in glycerol yield on glucose; the level of reduction compared to the wild-type was 61% in TEFmut7 and 88% in TEFmut2. The overall ethanol production yield on glucose was improved from 0.43 g g^-1 in the wild type to 0.44 g g^-1 measured in TEFmut7 and 0.45 g g^-1 in TEFmut2. Although maximal growth rate in the engineered strains was reduced by 20 and 30%, for TEFmut7 and TEFmut2 respectively, strains' ethanol stress robustness was hardly affected; i.e. values for final ethanol concentration (117 ± 4 g L^-1), growth-inhibiting ethanol concentration (87 ± 3 g L^-1) and volumetric ethanol productivity (2.1 ± 0.15 g l^-1 h^-1) measured in wild-type remained virtually unchanged in the engineered strains.

Conclusions

This work demonstrates the power of fine-tuned pathway engineering, particularly when a compromise has to be found between high product yield on one hand and acceptable growth, productivity and stress resistance on the other hand. Under the conditions used in this study (VHEP fed-batch), the two strains with "fine-tuned" GPD1 expression in a gpd2 Δ background showed slightly better ethanol yield improvement than previously achieved with the single deletion strains gpd1 Δ or gpd2 Δ. Although glycerol reduction is known to be even higher in a gpd1 Δ gpd2 Δ double deletion strain, our strains could much better cope with process stress as reflected by better growth and viability.     

The Saccharomyces cerevisiae protein YJR043C (Pol32) interacts with the catalytic subunit of DNA polymerase α and is required for cell cycle progression in G2?/?M

We have analysed the YJR043c gene of Saccharomyces cerevisiae, previously identified by systematic sequencing. The deletion mutant (yjr043cΔ) shows slow growth at low temperature (15° C), while at 30° C and 37° C the growth rate of mutant cells is only moderately affected. At permissive and nonpermissive temperatures, mutant cells were larger and showed a high proportion of large-budded cells with a single duplicated nucleus at or beyond the bud neck and a short spindle. This phenotype was even more striking at low temperature, the mutant cells becoming dumbbell shaped. All these phenotypes suggest a role for YJR043C in cell cycle progression in G2/M phase. In two-hybrid assays, the YJR043c gene product specifically interacted with Poll, the catalytic subunit of DNA polymerase α. The pol1-1 /yjr043cΔ double mutant showed a more severe growth defect than the pol1-1 single mutant at permissive temperature. Centromeric plasmid loss rate elevated in yjr043cΔ. Analysis of the sequence upstream of the YJR043c ORF revealed the presence of an MluI motif (ACGCGT), a sequence associated with many genes involved in DNA replication in budding yeast. The cell cycle phenotype of the yjr043cΔ mutant, the evidence for genetic interaction with Pol1, the presence of an MluI motif upstream and the elevated rate of CEN plasmid loss in mutants all support a function for YJR043C in DNA replication. Received: 22 July 1998 / Accepted: 22 September 1998     

Efficient induction of formate hydrogen lyase of aerobically grown <Emphasis Type="Italic">Escherichia coli</Emphasis> in a three-step biohydrogen production process

A three-step biohydrogen production process characterized by efficient anaerobic induction of the formate hydrogen lyase (FHL) of aerobically grown Escherichia coli was established. Using E. coli strain SR13 (fhlA ⁺⁺, ΔhycA) at a cell density of 8.2 g/l medium in this process, a specific hydrogen productivity (28.0 ± 5.0 mmol h⁻¹ g⁻¹ dry cell) of one order of magnitude lower than we previously reported was realized after 8 h of anaerobic incubation. The reduced productivity was attributed partly to the inhibitory effects of accumulated metabolites on FHL induction. To avoid this inhibition, strain SR14 (SR13 ΔldhA ΔfrdBC) was constructed and used to the effect that specific hydrogen productivity increased 1.3-fold to 37.4 ± 6.9 mmol h⁻¹ g⁻¹. Furthermore, a maximum hydrogen production rate of 144.2 mmol h⁻¹ g⁻¹ was realized when a metabolite excretion system that achieved a dilution rate of 2.0 h⁻¹ was implemented. These results demonstrate that by avoiding anaerobic cultivation altogether, more economical harvesting of hydrogen-producing cells for use in our biohydrogen process was made possible.