Molecular modeling of substrate selectivity of Candida antarctica lipase B and Candida rugosa lipase towards c9, t11- and t10, c12-conjugated linoleic acid

Molecular modeling was used to clarify the mechanism of the selectivity of Candida antarctica lipase B and Candida rugosa lipase towards cis9, trans11 (c9, t11-) and trans10, cis12 (t10, c12-) conjugated linoleic acid. Hydrogen bonds network, substrate conformation, binding affinity and water molecules in the binding site were analyzed. Substrate conformation and binding affinity were not correlated with the experimental results of the substrate selectivity. On the contrary, better enzyme preference towards a substrate was correlated with two stronger hydrogen bonds (His-NH-O_a and His-NH-Ser-O_γ) and less water molecules between the substrate the binding pocket. Possible explanation of these was discussed.     

分别利用产甘油假丝酵母抗逆转录因子CgSTB5和CgSEF1对酿酒酵母菌株糠醛耐受改造

【背景】纤维素是生物转化解决能源问题的主要原料之一,其水解物中存在严重影响抑制菌株生长的糠醛,需脱毒才可应用于发酵,提高菌株耐受性是解决纤维素水解液实际生产应用的关键。【目的】酿酒酵母(Saccharomyces cerevisiae)是主要的纤维素水解液发酵工业菌株,但糠醛耐受性较低,通过分子改造获得具有高糠醛耐受性的菌株。【方法】利用新获得的产甘油假丝酵母(Candidaglycerinogenes)的相关抗逆转录因子CgSTB5、CgSEF1和CgCAS5,通过分子技术进行S.cerevisiae改造,考察其对酿酒酵母糠醛耐受性的影响,并尝试应用于未脱毒纤维素乙醇发酵。【结果】单个表达CgSTB5和CgSEF1的酿酒酵母,通过菌株点板实验表明菌株的糠醛耐受性提高25%以上,并且摇瓶发酵结果显示糠醛降解性能明显提高,生长延滞期明显缩短,S.cerevisiae W303/p414-CgSTB5的未脱毒纤维素乙醇发酵生产效率提高12.5%左右。【结论】转录因子CgSTB5和CgSEF1均能对提高酿酒酵母糠醛耐受性起到重要作用,并且有助于提高酿酒酵母菌株未脱毒纤维素乙醇发酵性能。     

URA3基因影响青蒿酸酿酒酵母工程菌中试发酵产量

CRISPR/Cas9基因编辑技术已经被广泛应用于工程酿酒酵母的基因插入、基因替换和基因敲除,通过使用选择标记进行基因编辑具有简单高效的特点。前期利用CRISPR/Cas9系统敲除青蒿酸生产菌株酿酒酵母(Saccharomyces cerevisiae) 1211半乳糖代谢负调控基因GAL80,获得菌株S. cerevisiae 1211-2,在不添加半乳糖诱导的情况下,青蒿酸摇瓶发酵产量达到了740 mg/L。但在50 L中试发酵实验中,S. cerevisiae 1211-2很难利用对青蒿酸积累起到决定性作用的碳源-乙醇,青蒿酸的产量仅为亲本菌株S.cerevisiae 1211的20%–25%。我们推测因遗传操作所需的筛选标记URA3突变,影响了其生长及青蒿酸产量。随后我们使用重组质粒pML104-KanMx4-u连同90 bp供体DNA成功恢复了URA3基因,获得了工程菌株S. cerevisiae 1211-3。S. cerevisiae 1211-3能够在葡萄糖和乙醇分批补料的发酵罐中正常生长,其青蒿酸产量超过20g/L,与亲本菌株产量相当。研究不但获得了不加半乳糖诱导的青...     

The Saccharomyces cerevisiae genes ( CMP1 and CMP2 ) encoding calmodulin-binding proteins homologous to the catalytic subunit of mammalian protein phosphatase 2B

Summary Saccharomyces cerevisiae genomic clones that encode calmodulin-binding proteins were isolated by screening a λgt11 expression library using¹²⁵I-labeled calmodulin as probe. Among the cloned yeast genes, we found two closely related genes (CMP1 andCMP2) that encode proteins homologous to the catalytic subunit of phosphoprotein phosphatase. The presumed CMP1 protein (62999 Da) and CMP2 protein (68496 Da) contain a 23 amino acid sequence very similar to those identified as calmodulin-binding sites in many calmodulin-regulated proteins. The yeast genes encode proteins especially homologous to the catalytic subunit of mammalian phosphoprotein phosphatase type 213 (calcineurin). The products of theCMP1 andCMP2 genes were identified by immunoblot analysis of cell extracts as proteins of 62000 and 64000 Da, respectively. Gene disruption experiments demonstrated that elimination of either or both of these genes had no effect on cell viability, indicating that these genes are not essential for normal cell growth.     

An optimized protocol for the production of interdelta markers in Saccharomyces cerevisiae by using capillary electrophoresis

The amplification of genomic sequence blocks flanked by delta elements of retrotransposon origin has proved to be a very convenient method for molecular characterization of Saccharomyces cerevisiae strains. Fluorescent automated capillary electrophoresis (CE) was used to detect interdelta marker (IDM) patterns in S. cerevisiae, using the ABI Prism 3130 Genetic Analyzer. Main experimental parameters were studied and the optimal conditions for IDM amplification and samples run on the CE apparatus were determined. Fingerprints from fluorescent-labelled IDM produced using CE with the same sample analyzed by agarose electrophoresis (AE) were compared. The CE analysis was able to distinguish 43 different IDM profiles among 45 S. cerevisiae isolates with a discriminating capacity of 99.8%, whereas the AE analysis of the same samples allowed the identification of 27 different patterns (discriminatory power equal to 96%). Detection of fluorescent IDM was fast and reliable, and it facilitated data comparison. For the first time in our knowledge, the fluorescent CE proved to be well suited for IDM fingerprinting. Moreover, it could be routinely applied for the molecular differentiation of S. cerevisiae strains.     

Inactivation of SSM4, a new Saccharomyces cerevisiae gene, suppresses mRNA instability due to rna14 mutations

Decay rates of mRNAs depend on many elements and among these, the role of the poly(A) tail is now well established. In the yeast Saccharomyces cerevisiae, thermosensitive mutations in two genes, RNA14 and RNA15, result in mRNAs having shorter poly(A) tails and reduced half-life. To identify other components interacting in the same process, we have used a genetic approach to isolate mutations that suppress the thermosensitivity of an rna14 mutant strain. Mutations in a single locus, named SSM4, not only suppress the cell growth phenotype but also the mRNA instability and extend the short mRNA poly(A) tails. The frequency of appearance and the recessive nature of these mutations suggested that the suppressor effect was probably due to a loss of function. We failed to clone the SSM4 gene directly by complementation, owing to its absence from gene banks; it later emerged that the gene is toxic to Escherichia coli, but we have nevertheless been able to clone the SSM4 sequence by Ty element transposition tagging. Disruption of the SSM4 gene does not affect cell viability and suppresses the rna14 mutant phenotypes. The protein encoded by the SSM4 gene has a calculated molecular mass of 151 kDa and does not contain any known motif or show homology with known proteins. The toxicity of the SSM4 gene in E. coli suggests that a direct biochemical activity is associated with the corresponding protein.     

运用CRISPR/Cas9技术构建表达10rolGLP-1的降糖酵母

为研发一种用于治疗2型糖尿病的新型生物药物,本研究运用实验室前期构建的10rolglp-1基因和CRISPR/Cas9基因组编辑技术创建了重组酿酒酵母(Saccharomyces cerevisiae)工程菌株。构建了向导RNA(guide RNA,gRNA)表达载体pyES2-gRNA、供体载体pNK1-L-PGK-10rolGLP-1-R和Cas9表达载体pGADT7-Cas9,将这些表达载体共转化酿酒酵母INVSc1菌株,通过同源重组途径敲入PGK-10rolGLP-1表达单元,最终得到具有降血糖功能、高表达10rolGLP-1的酿酒酵母。通过SDS-PAGE和蛋白质印迹,筛选出2种稳定表达10rolGLP-1的酿酒酵母重组菌株。降血糖实验结果表明,重组降血糖酿酒酵母对糖尿病小鼠模型具有显著的降血糖作用,其血糖下降平缓,可避免引起低血糖风险。体重变化和多尿等其他症状也明显改善,表明本研究构建的口服降血糖酿酒酵母有望成为一种简单有效、经济实用的糖尿病生物药物。     

Mutations in the Saccharomyces cerevisiae vacuolar fusion proteins Ccz1, Mon1 and Ypt7 cause defects in cell cycle progression in a num1Δ background

The proteins Ccz1 and Mon1 are known to function together with the Rab-GTPase Ypt7 in membrane fusion reactions at the yeast vacuole. In a genome-wide analysis they have also been found to interact genetically with the nuclear-migration protein Num1. In this study we analyze these synthetic effects and we show that the mutants ccz1Δ num1Δ, mon1Δ num1Δ and ypt7Δ num1Δ exhibit severe defects in cell cycle progression. A large fraction of the mutant cells enter a new cell division cycle without having completed mitotic exit, leading to the accumulation of multinuclear, anuclear and multibudded cells. The double deletion strains display also increased sensitivity to calcium ions. The cell-cycle defects are only weakly observed if deletions of other vacuolar protein sorting genes are combined with num1Δ or if other nuclear-migration genes are deleted together with CCZ1, whereas the calcium sensitivity is characteristic for a large subset of the tested double mutants. Further, the cell-cycle defects of the ccz1Δ num1Δ strain can be partially rescued by overproduction of either the calcium pump Pmc1 or the nuclear-migration factors Kar9 and Bim1. Together, these results indicate that deregulation of the cell cycle in these mutants results from two separate mechanisms, one of which is related to calcium homeostasis.     

Recombinant Candida rugosa LIP2 expression in Pichia pastoris under the control of the AOX1 promoter

The LIP2 isoenzyme gene from Candida rugosa has been completely synthesised and functionally expressed under the AOX1 promoter control in Pichia pastoris. The on-line monitoring and control of methanol, the key inducer carbon source in fed-batch cultures, has enhanced the yield product/biomass 7.8-fold and the productivity 12.8-fold compared to the best batch cultivation with the Pichia system and, 10-fold compared to the fed-batch cultivation process using the native C. rugosa strain.Nevertheless, the high ionic strength of culture broth favoured aggregation of Lip2, leading to total loss of lipolytic activity. After cultivation, a diaultrafiltration process was implemented to diminish ionic strength, allowing for the recovery of lipolytic activity in the diaultrafiltrate. The developed bioprocess resulted into a reproducible product in terms of quality and productivity.     

在钙离子敏感性方面与RCH1遗传互作的酿酒酵母基因的筛选

酿酒酵母ScRCH1是白念珠菌CaRCH1的同功基因,作为人体溶质转运蛋白SLC10A7的同源蛋白,两者都是细胞质膜上钙离子内流的抑制因子。为了研究酿酒酵母RCH1与基因组中其他基因之间的遗传互作,利用合成遗传阵列(Synthetic Genetic Array,SGA)方法构建了RCH1分别与其他非必需基因之间的双基因缺失株文库。钙离子表型筛选表明RCH1与17个基因之间存在遗传互作,其中4个基因BUD9、THR1、RAS2和CPR7在钙离子敏感性方面的功能以前没有报道过。这些结果为深入研究Rch1对钙离子稳态的调控提供了参考。     

定向进化Rho1提高酿酒酵母的乙醇耐受性和超高浓度乙醇发酵性能

燃料乙醇发酵过程中酿酒酵母细胞活性被高浓度乙醇严重抑制而导致发酵提前终止，生产强度严重降低，因此构建同时具有高耐受性、高发酵性能的菌株一直是发酵工业追求的目标。选取酿酒酵母细胞形态调节关键基因小GTP酶家族成员Rho1,构建易错PCR产物文库，以酿酒酵母S288c为出发菌株采取“富集-自然生长-复筛”的筛选策略，成功筛选得到两株乙醇胁迫耐受性与发酵性能均提高的突变株M2和M5。测序发现突变株过表达的Rho1序列出现了3～5个氨基酸的突变和大片段的缺失突变。以300 g/L起始葡萄糖进行乙醇发酵，72 h时，M2和M5的乙醇滴度比对照菌株分别提高了19.4%和22.3%,超高浓度乙醇发酵能力显著提高。本研究为利用蛋白定向进化方法改良酵母菌复杂表型提供了新的作用靶点。     

Rapid intracellular alkalinization of Saccharomyces cerevisiae MATa cells in response to α-factor requires the CDC25 gene product

The α-factor mating pheromone induces a transient intracellular alkalinizatin of MATa cells within minutes after exposure to the pheromone, and is the earliest biochemical event that can be identified subsequent to the exposure. Dissipation of the pheromone induced pH gradient, using 2,4-dinotrophenol or sodium orthovanadate, does not inhibit the biological response of the yeast to the pheromone such as mating and ‘schmoo’ formation. These findings suggest that the pheromone mediated pH change per se is not a part of the transmembrane signalling but rather the consequence of a biochemical reaction triggered by the α-pheromone interaction with its receptor and may have a permissive effect on the pheromonal response. The cdc25^ts mutation causes MATa cells to become nonresponsive to α-factor subsequent to a shift to the restrictive temperature, suggesting that the CDC25 gene product participates in the pheromone response pathway.     

Xylose isomerase from polycentric fungus Orpinomyces: gene sequencing, cloning, and expression in Saccharomyces cerevisiae for bioconversion of xylose to ethanol

The cDNA sequence of the gene for xylose isomerase from the rumen fungus Orpinomyces was elucidated by rapid amplification of cDNA ends. The 1,314-nucleotide gene was cloned and expressed constitutively in Saccharomyces cerevisiae. The deduced polypeptide sequence encoded a protein of 437 amino acids which showed the highest similarity to the family II xylose isomerases. Further, characterization revealed that the recombinant enzyme was a homodimer with a subunit of molecular mass 49 kDa. Cell extract of the recombinant strain exhibited high specific xylose isomerase activity. The pH optimum of the enzyme was 7.5, while the low temperature optimum at 37°C was the property that differed significantly from the majority of the reported thermophilic xylose isomerases. In addition to the xylose isomerase gene, the overexpression of the S. cerevisiae endogenous xylulokinase gene and the Pichia stipitis SUT1 gene for sugar transporter in the recombinant yeast facilitated the efficient production of ethanol from xylose.     

Efficient synthesis of enantiomeric ethyl lactate by <Emphasis Type="Italic">Candida antarctica</Emphasis> lipase B (CALB)-displaying yeasts

The whole-cell biocatalyst displaying Candida antarctica lipase B (CALB) on the yeast cell surface with α-agglutinin as the anchor protein was easy to handle and possessed high stability. The lyophilized CALB-displaying yeasts showed their original hydrolytic activity and were applied to an ester synthesis using ethanol and l-lactic acid as substrates. In water-saturated heptane, CALB-displaying yeasts catalyzed ethyl lactate synthesis. The synthesis efficiency increased depending on temperature and reached approximately 74% at 50°C. The amount of l-ethyl lactate increased gradually. l-Ethyl lactate synthesis stopped at 200 h and restarted after adding of l-lactic acid at 253 h. It indicated that CALB-displaying yeasts retained their synthetic activity under such reaction conditions. In addition, CALB-displaying yeasts were able to recognize l-lactic acid and d-lactic acid as substrates. l-Ethyl lactate was prepared from l-lactic acid and d-ethyl lactate was prepared from d-lactic acid using the same CALB-displaying whole-cell biocatalyst. These findings suggest that CALB-displaying yeasts can supply the enantiomeric lactic esters for preparation of useful and improved biopolymers of lactic acid.     

Phenotypic analysis of the ccp1Δ and ccp1Δ-ccp1 mutant strains of Saccharomyces cerevisiae indicates that cytochrome c peroxidase functions in oxidative-stress signaling

Yeast cytochrome c peroxidase (CCP) efficiently catalyzes the reduction of H₂O₂ to H₂O by ferrocytochrome c in vitro. The physiological function of CCP, a heme peroxidase that is targeted to the mitochondrial intermembrane space of Saccharomyces cerevisiae, is not known. CCP1-null-mutant cells in the W303-1B genetic background (ccp1Δ) grew as well as wild-type cells with glucose, ethanol, glycerol or lactate as carbon sources but with a shorter initial doubling time. Monitoring growth over 10 days demonstrated that CCP1 does not enhance mitochondrial function in unstressed cells. No role for CCP1 was apparent in cells exposed to heat stress under aerobic or anaerobic conditions. However, the detoxification function of CCP protected respiring mitochondria when cells were challenged with H₂O₂. Transformation of ccp1Δ with ccp1^W191F, which encodes the CCP^W191F mutant enzyme lacking CCP activity, significantly increased the sensitivity to H₂O₂ of exponential-phase fermenting cells. In contrast, stationary-phase (7-day) ccp1Δ-ccp1^W191F exhibited wild-type tolerance to H₂O₂, which exceeded that of ccp1Δ. Challenge with H₂O₂ caused increased CCP, superoxide dismutase and catalase antioxidant enzyme activities (but not glutathione reductase activity) in exponentially growing cells and decreased antioxidant activities in stationary-phase cells. Although unstressed stationary-phase ccp1Δ exhibited the highest catalase and glutathione reductase activities, a greater loss of these antioxidant activities was observed on H₂O₂ exposure in ccp1Δ than in ccp1Δ-ccp1^W191F and wild-type cells. The phenotypic differences reported here between the ccp1Δ and ccp1Δ-ccp1^W191F strains lacking CCP activity provide strong evidence that CCP has separate antioxidant and signaling functions in yeast.     

Optimized methodology for extraction of (1 → 3)(1 → 6)-β-d-glucan from Saccharomyces cerevisiae and in vitro evaluation of the cytotoxicity and genotoxicity of the corresponding carboxymethyl derivative

The cell wall of Saccharomyces cerevisiae is an important source of β-d-glucan, a glucose homopolymer with immunostimulant properties. The standard methodologies described for its extraction involve acid and alkaline washings, which degrade part of its glucose chains and reduce the final yield. In the present study, an optimized methodology for extraction of β-d-glucan from S. cerevisiae cells, involving sonication and enzyme treatment, with a yield of 11.08 ± 0.19%, was developed. The high-purity (1 → 3)(1 → 6)-β-d-glucan was derivatized to carboxymethyl-glucan (CM-G). In vitro tests with CM-G in Chinese hamster epithelial cells (CHO-k1) did not reveal any cytotoxic or genotoxic effects or influences of this molecule on cell viability. The method described here is a convenient alternative for the extraction of (1 → 3)(1 → 6)-β-d-glucan under mild conditions without the generation of wastes that could be potentially harmful to the environment.