Molecular polymorphism of β-fructosidase SUC genes in the Saccharomyces yeasts

The molecular polymorphism of SUC genes that encode β-fructosidase has been investigated in the yeast genus Saccharomyces. We have determined the nucleotide sequences of subtelomeric SUC3, SUC5, SUC7, SUC8, SUC9, and SUC10 genes of S. cerevisiae and the SUCa gene of S. arboricola. Comparisons of the nucleotide sequences of all known SUC genes revealed the predominance of C → T transitions in the third codon position, which were silent. The amino acid sequences of β-fructosidases studied have identity of 88–100%. SUCa (S. arboricola) and SUCb (S. bayanus) proteins, which had amino acid identity with other SUC proteins of less than 92%, were the most divergent. It was determined that accumulation of the polymeric SUC genes takes place in industrial populations of S. cerevisiae, while the other Saccharomyces species (S. arboricola, S. bayanus, S. cariocanus, S. kudriavzevii, S. mikatae, and S. paradoxus) each harbor only one SUC gene. Subtelomeric repeats of β-fructosidase SUC genes could appear in the genome of S. cerevisiae under the effect of selection in the course of their domestication.     

Comparative genetics of yeasts: A novel β-fructosidase gene <Emphasis Type="Italic">SUC8</Emphasis> in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Molecular and genetic analyses revealed that the distillers race XII, which is an ancestor of Saccharomyces cerevisiae Peterhof and Gatchina genetic lines, has three polymeric β-fructosidase genes: SUC2, SUC5, and SUC8. The latter gene located on the X chromosome was identitied in this work for the first time. The presence of the single SUC2 gene in yeasts used in the international project on sequencing of the S. cerevisiae genome is discussed.     

Expression of exoinulinase genes in Saccharomyces cerevisiae to improve ethanol production from inulin sources

To improve inulin utilization and ethanol fermentation, exoinulinase genes from the yeast Kluyveromyces marxianus and the recently identified yeast, Candida kutaonensis, were expressed in Saccharomyces cerevisiae. S. cerevisiae harboring the exoinulinase gene from C. kutaonensis gave higher ethanol yield and productivity from both inulin (0.38 vs. 0.34 g/g and 1.35 vs. 1.22 g l^?1 h^?1) and Jerusalem artichoke tuber flour (0.47 vs. 0.46 g/g and 1.62 vs. 1.54 g l^?1 h^?1) compared with the strain expressing the exoinulinase gene from K. marxianus. Thus, the exoinulinase gene from C. kutaonensis is advantageous for engineering S. cerevisiae to improve ethanol fermentation from inulin sources.     

Genealogy of Principal Strains of the Yeast Genetic Stock Center

We have constructed a genealogy of strain S288C, from which many of the mutant and segregant strains currently used in studies on the genetics and molecular biology of Saccharomyces cerevisiae have been derived. We have determined that its six progenitor strains were EM93, EM126, NRRL YB-210 and the three baking strains Yeast Foam, FLD and LK. We have estimated that approximately 88% of the gene pool of S288C is contributed by strain EM93. The principal ancestral genotypes were those of segregant strains EM93-1C and EM93-3B, initially distributed by C. C. Lindegren to several laboratories. We have analyzed an isolate of a lyophilized culture of strain EM93 and determined its genotype as MATa/MATα SUC2/SUC2 GAL2/gal2 MAL/MAL mel/mel CUP1/cup1 FLO1/flo1. Strain EM93 is therefore the probable origin of genes SUC2, gal2, CUP1 and flo1 of S288C. We give details of the current availability of several of the progenitor strains and propose that this genealogy should be of assistance in elucidating the origins of several types of genetic and molecular heterogeneities in Saccharomyces.     

Optimized invertase expression and secretion cassette for improving Yarrowia lipolytica growth on sucrose for industrial applications

Yarrowia lipolytica requires the expression of a heterologous invertase to grow on a sucrose-based substrate. This work reports the construction of an optimized invertase expression cassette composed of Saccharomyces cerevisiae Suc2p secretion signal sequence followed by the SUC2 sequence and under the control of the strong Y. lipolytica pTEF promoter. This new construction allows a fast and optimal cleavage of sucrose into glucose and fructose and allows cells to reach the maximum growth rate. Contrary to pre-existing constructions, the expression of SUC2 is not sensitive to medium composition in this context. The strain JMY2593, expressing this new cassette with an optimized secretion signal sequence and a strong promoter, produces 4,519 U/l of extracellular invertase in bioreactor experiments compared to 597 U/l in a strain expressing the former invertase construction. The expression of this cassette strongly improved production of invertase and is suitable for simultaneously high production level of citric acid from sucrose-based media.     

Polygenic control for fermentation of β-fructosides in the yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>: New genes <Emphasis Type="Italic">SUC9</Emphasis> and <Emphasis Type="Italic">SUC10</Emphasis>

Using molecular karyotyping and genetic hybridization analysis, two new polymeric β-fructosidase genes, SUC9 and SUC10, were identified in the yeast Saccharomyces cerevisiae, which are located on chromosome XIV and on the chromosome XVI/XIII doublet, respectively. The genes are responsible for fermentation of sucrose and raffinose. The SUC gene genotypes of strains VKM Y-1831 and DBVPG 1340 are SUC2 SUC9 and suc2 ⁰ SUC10, respectively. suc2 ⁰ is a silent sequence. The scientific and applied significance of SUC genes is discussed.     

SUC1 and SUC2: two sucrose transporters from Arabidopsis thaliana; expression and characterization in baker's yeast and identification of the histidine-tagged protein

An important, most likely essential step for the long distance transport of sucrose in higher plants is the energy-dependent, uncoupler-sensitive loading into phloem cells via a sucrose-H⁺ symporter. This paper describes functional expression in Saccharomyces cerevisiae of two cDNAs encoding energy-dependent sucrose transporters from the plasma membrane of Arabidopsis thaliana, SUC1 and SUC2. Yeast cells transformed with vectors allowing expression of either SUC1 or SUC2 under the control of the promoter of the yeast plasma membrane ATPase gene (PMA1) transport sucrose, and to a lesser extent also maltose, across their plasma membranes in an energy-dependent manner. The K_M-values for sucrose transport are 0.50 mM and 0.77 mM, respectively, and transport by both proteins is strongly inhibited by uncouplers such as carbonyl cyanide m-chlorophenylhydrazone (CCCP) and dinitrophenol (DNP), or SH-group inhibitors. The V_MAX but not the K_M-values of sucrose transport depend on the energy status of transgenic yeast cells. The two proteins exhibit different patterns of pH dependence with SUC1 being much more active at neutral and slightly acidic pH values than SUC2. The proteins share 78% identical amino acids, their apparent molecular weights are 54.9 kDa and 54.5 kDA, respectively, and both proteins contain 12 putative transmembrane helices. A modified SUC1-His6 cDNA encoding a histidine tag at the SUC1 C-terminus was also expressed in S. cerevisiae. The tagged protein is fully active and is shown to migrate at an apparent molecular weight of 45 kDa on 10% SDS—polyacrylamide gels.     

Comparative genetics of yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>. Chromosomal translocations carrying the <Emphasis Type="Italic">SUC2</Emphasis> marker

Three different translocations involving chromosome IX have been detected in natural Saccharomyces cerevisiae strains using pulsed-field gel electrophoresis with intact chromosomal DNA and their hybridization with the SUC2 probe. Hybrids of these strains with genetic lines having normal molecular karyotype were shown to have back dislocation of at least marker SUC2 due to crossingover. The significance of the detected translocations is discussed.     

Effects of signal sequences and folding accessory proteins on extracellular expression of carboxypeptidase Y in recombinant Saccharomyces cerevisiae

Carboxypeptidase Y (CPY) is a yeast vacuolar protease with useful applications including C-terminal sequencing of peptides and terminal modification of target proteins. To overexpress CPY with the pro-sequence (proCPY) encoded by the Saccharomyces cerevisiae PRC1 gene in recombinant S. cerevisiae, the proCPY gene was combined with the gene coding for a signal sequence of S. cerevisiae mating factor α (MFα), invertase (SUC2), or Kluyveromyces marxianus inulinase (INU1). Among the three constructs, the MFα signal sequence gave the best specific activity of extracellular CPY. To enhance the CPY expression level, folding accessory proteins of Kar2p, Pdi1p and Ero1p located in the S. cerevisiae endoplasmic reticulum were expressed individually and combinatorially. A single expression of Kar2p led to a 28 % enhancement in extracellular CPY activity, relative to the control strain of S. cerevisiae CEN.PK2-1D/p426Gal1-MFαCPY. Coexpression of Kar2p, Pdi1p and Ero1p gave a synergistic effect on CPY expression, of which activity was 1.7 times higher than that of the control strain. This work showed that engineering of signal sequences and protein-folding proteins would be helpful to overexpress yeast proteins of interest.     

A silent gene allelicto yeast invertase structural gene SUC2 can be activated by mutation to direct the formation of a new type of invertase

Strains fromSaccharomyces cerevisiae unable to produce invertase (suc0) may revert to invertase formation by ultraviolet treatment or spontaneously at a lower rate, as a consequence of activation of a silent gene allelic to the SUC2 locus. However, the new internal protein is physically different from the internal invertase expressed by the SUC2 gene according to electrophoresis analysis.     

Considerazioni su Gelsi Ingialliti per Fame

Jerusalem artichoke (Helianthus tuberosus L.), an important crop, containing over 50% inulin in its tubers on a dry weight basis is an agricultural and industrial crop with a great potential for production of ethanol and industrial products. Inulin is a good substrate for bioethanol production. Saccharomyces cerevisiae 6525 can produce high concentrations of ethanol, but it cannot synthesize inulinase. In this study, a new integration vector carrying inuA1 gene encoding exoinulinase was constructed and transformed into 18SrDNA site of industrial strain S. cerevisiae 6525. The obtained transformant, BR8, produced 1.1 U mL^? 1 inulinase activity within 72 h and the dry cell weight reached 12.3 g L^? 1 within 48 h. In a small-scale fermentation, BR8 produced 9.5% (v/v) ethanol, with a productivity rate of 0.385 g ethanol per gram inulin, while wild-type S. cerevisiae 6525 produced only 3.3% (v/v) ethanol in the same conditions. In a 5-L fermentation, BR8 produced 14.0% (v/v) ethanol in fermentation medium containing inulin and 1% (w/v) (NH4)₂SO₄. The engineered S. cerevisiae 6525 carrying inuA1 converted pure nonhydrolyzed inulin directly into high concentrations of ethanol.     

不同信号肽对酿酒酵母蔗糖转化酶Suc2分泌表达水平的影响

目前，绝大多数酿酒酵母（Saccharomyces cerevisiae）菌株利用菊糖生产乙醇的能力有限，而蔗糖转化酶Suc2是酿酒酵母水解菊糖的关键酶，其分泌水平直接影响酿酒酵母转化菊糖为乙醇的性能。为提高酿酒酵母中蔗糖转化酶Suc2的分泌表达水平，利用生物信息学的分析方法选择出11种不同的分泌信号肽，包括酿酒酵母内源性、其他菌株来源以及已报道序列优化改造的信号肽，将它们融合至Suc2并构建了相应的酿酒酵母BY4741重组菌。其中，酿酒酵母内源分泌信号肽AGA2能使蔗糖转化酶Suc2更有效的分泌，含有信号肽AGA2的重组菌BY-AG的蔗糖酶酶活和菊糖酶酶活相对于含有天然信号肽的原始菌BY-S分别提高42%和26%，其利用菊糖产乙醇能力较原始菌提高了32%，乙醇产量达到78.11 g/L。在使用毕赤酵母（Pichia pastoris）分泌信号肽MSB2时，蔗糖转化酶Suc2的分泌水平也有提高，含有信号肽MSB2的重组菌BY-MS较原始菌BY-S的蔗糖酶酶活和菊糖酶酶活分别提高了80%和74%，同时，利用菊糖产乙醇能力也提高了56%，产量达到86.31 g/L。最后，对重组菌BY-MS摇瓶发酵过程中的生物量、蔗糖酶酶活、残糖总量和乙醇产量进行了监测，结果表明，重组菌BY-MS的发酵性能较原始菌BY-S有显著提高。本研究为提高蔗糖转化酶Suc2的分泌水平、构建高效菊糖基乙醇生产菌株提供参考。     

Sandwich hybridisation assay for quantitative detection of yeast RNAs in crude cell lysates

Background  

A rapid microtiter plate based sandwich hybridization assay was developed for detection and quantification of single RNA species using magnetic beads. Following solution hybridization target RNA molecules were collected by biotin-streptavidin affinity binding and detected by fluorescence signal generated by alkaline phosphatase. The 18S rRNA and SUC2 mRNA of Saccharomyces cerevisiae were used as model RNA target molecules.     

Regulation of Substrate Uptake in Nocardia erythropolis

The regulation of uptake of glucose (GLU), glycerol (GLY), mannitol (MTL), and succinate (SUC) has been examined in Nocardia erythropolis 305. The apparent K_m values of the uptake activities of cells subcultured in a medium with the corresponding substrate as the sole carbon source were 205, 48, 8.7, and 36 μM for GLU, GLY, MTL, and SUC, respectively. GLU and GLY uptake activities were constitutive, although there was evidence for an additional inducible component in GLY uptake. Moreover, MTL and SUC uptake activities were inducible. MTL uptake activity was markedly induced by cultivation in MTL medium and partially induced by growth in GLU medium, whereas SUC uptake was induced only by cultivation in SUC medium. SUC added to MTL medium partially repressed the formation of, or inhibited the activity of, MTL uptake. When not induced, uptake of MTL and SUC was proportional to the substrate concentration. The induced uptake of MTL and SUC and the constitutive uptake of GLU were energy dependent and carrier mediated. Uptake of GLY, constitutively or when induced, was also carrier mediated.