酵母中葡萄糖阻遏作用机制研究进展

大多数微生物通过一种复杂的机制来感知和传递环境中的葡萄糖变化并对其做出适当的反应。酵母细胞中，葡萄糖主要通过Snf1/Mig1信号通路来阻遏三羧酸循环、糖异生、乙醛酸循环和替代碳源代谢等相关基因的转录表达。木糖、半乳糖、蔗糖、乙醇和有机酸等替代碳源只有当环境中的葡萄糖消耗殆尽后才能重启代谢编程，进行替代碳源的利用。而葡萄糖去抑制对于提高现代微生物工业生产效率、解决环境与能源问题具有重要意义。本文综述了Snf1/Mig1信号通路阻遏机制以及相关转录因子的活性位点，具体介绍了多种替代碳源的应用以及其受葡萄糖阻遏的具体机制，总结提出了根据不同背景缓解或解除碳代谢阻遏的策略，以期为酵母菌现代化生产应用范围的扩大和效率的提高提供新思路。     

酿酒酵母Snf1/AMPK蛋白激酶通过调节细胞壁合成相关基因的表达影响细胞壁完整性

【目的】初步探讨酿酒酵母(Saccharomyces cerevisiae)中Snf1/AMPK蛋白激酶影响细胞壁完整性的机制。【方法】通过同源重组交换的方法,构建酿酒酵母Snf1/AMPK蛋白激酶催化亚基的敲除菌株snf1Δ,并通过基因回补对敲除菌株表型进行验证。在含有刚果红(Congo red)和荧光增白剂(Calcofluor white)的平板上检测snf1Δ菌株细胞壁的完整性,通过q RT-PCR的方法检测snf1Δ菌株中已知的细胞壁合成相关基因的表达情况。【结果】SNF1基因敲除影响细胞壁的完整性,并影响酿酒酵母对热激应答的反应。进一步研究发现,SNF1突变菌株中β-1,3-葡聚糖合成相关基因与β-1,6-葡聚糖合成相关基因的表达量均明显降低。【结论】结果显示酿酒酵母Snf1蛋白激酶影响细胞壁的完整性,此影响发生在转录水平上,即通过调节细胞壁合成相关基因的转录来实现,揭示了Snf1蛋白的一个新角色。     

MIG1基因和葡萄糖对扣囊复膜孢酵母细胞形态变化的影响及机理探究

【目的】研究MIG1基因和葡萄糖对扣囊复膜孢酵母细胞形态变化的影响及其机理探究。【方法】扣囊复膜孢酵母在不同浓度葡萄糖的YPD培养基中培养,敲除MIG1基因菌株在常规YPD培养基中培养,研究细胞内葡聚糖酶和几丁质酶活性以及细胞壁β-葡聚糖和几丁质含量与细胞形态变化之间的关系。【结果】培养基中葡萄糖浓度越低,扣囊复膜孢酵母菌丝体越少,单细胞酵母越多,且葡聚糖酶和几丁质酶活性越高,β-葡聚糖和几丁质含量越低;葡萄糖浓度对敲除MIG1基因菌株没有显著影响,葡聚糖酶和几丁质酶活性始终保持在较高水平,β-葡聚糖和几丁质含量也较低,菌体多以单细胞酵母形式存在。【结论】MIG1基因和葡萄糖通过葡萄糖阻遏作用调节葡聚糖酶和几丁质酶活性,进而影响细胞壁的葡聚糖和几丁质含量,最终影响扣囊复膜孢酵母细胞的形态变化。     

毕赤酵母碳源阻遏因子编码基因PpMIG1和PpMIG2的克隆与序列分析

通过MIG基因的同源性设计简并引物,采用PCR方法从毕赤酵母(Pichia pastoris)中成功克隆了两个MIG同源基因的核心片段,同时利用Genome Walking的方法获得了基因的全长及其侧翼序列,并分别命名为PpMIG1和PpMIG2.序列分析显示,PpMIG1基因全长1 335 bp,编码444个氨基酸;PpMIG2基因全长1 365 bp,编码454个氨基酸.这个两个基因所编码的蛋白质均与酿酒酵母碳源阻遏因子ScMig1同源,在氨基末端具有两个典型的C2H2锌指结构域,该结构域能够与受葡萄糖阻遏的许多基因的启动子相结合.PpMig阻遏因子的获得为毕赤酵母碳源阻遏机制的研究奠定了基础.     

纳豆激酶产生菌——纳豆菌对木糖和葡萄糖的利用

在纳豆激酶 (Nattokinase,简称NK)发酵条件研究中 ,我们发现木糖是较葡萄糖更佳的产酶碳源。进一步的试验证明 ,NK的发酵菌种———Bacillussubtilisvar.natto在混合碳源中没有二次生长现象 ,对木糖和葡萄糖的吸收是同时的 ,且互不干扰 ,葡萄糖对木糖的吸收利用没有分解代谢阻遏。     

CIT2基因对突变酿酒酵母木糖利用影响的研究

木糖利用困难是秸秆燃料乙醇产业化的制约因素,改造酿酒酵母使其能够代谢木糖生成乙醇是当前研究的热点之一。为了研究CIT2基因对遗传改良酿酒酵母C5D-P-M菌株中葡萄糖与木糖共发酵过程中木糖利用的影响,设计引物并应用重叠PCR技术获得敲除CIT2基因的敲除组件,通过同源重组的方法将C5D-P-M中的CIT2基因敲除得到突变菌株C5D-P-M-CIT2Δ。通过对出发菌株和突变菌株的生长速率、葡萄糖利用率、木糖利用率及乙醇产量进行研究,结果表明突变菌株C5D-P-M-CIT2Δ的上述指标比出发菌株C5D-P-M均有一定程度的提高。因此推测,酿酒酵母中CIT2基因是影响木糖利用的因素之一,CIT2基因的敲除可提高酿酒酵母的木糖利用率。     

gTME构建共发酵木糖和葡萄糖的重组酿酒酵母

利用全转录工程（gTME）方法将全局转录因子spt15随机突变并克隆表达, 构建突变库。将突变基因连接到表达载体 pYX212上, 醋酸锂法转化入不利用木糖的酿酒酵母YPH499中, 经特定的培养基初筛获得高效利用木糖并共发酵木糖和葡萄糖的酿酒酵母重组菌株。对获得的重组菌株进行了初步研究, 该菌株能够很好的利用木糖并共发酵木糖和葡萄糖。在30oC, 200 r/min, 发酵96 h时, 50 g/L木糖和葡萄糖的利用率为94.0%和98.9%, 乙醇产率为32.4%和31.6%, 原始菌株乙醇产率为44.3%; 当木糖和葡萄糖以质量比1:1混合发酵时, 木糖和葡萄糖利用率分别为91.7%和85.9%, 乙醇产率为26%。木糖醇的含量极低。     

gTME构建共发酵木糖和葡萄糖的重组酿酒酵母

利用全转录工程（gTME）方法将全局转录因子spt15随机突变并克隆表达, 构建突变库。将突变基因连接到表达载体 pYX212上, 醋酸锂法转化入不利用木糖的酿酒酵母YPH499中, 经特定的培养基初筛获得高效利用木糖并共发酵木糖和葡萄糖的酿酒酵母重组菌株。对获得的重组菌株进行了初步研究, 该菌株能够很好的利用木糖并共发酵木糖和葡萄糖。在30oC, 200 r/min, 发酵96 h时, 50 g/L木糖和葡萄糖的利用率为94.0%和98.9%, 乙醇产率为32.4%和31.6%, 原始菌株乙醇产率为44.3%; 当木糖和葡萄糖以质量比1:1混合发酵时, 木糖和葡萄糖利用率分别为91.7%和85.9%, 乙醇产率为26%。木糖醇的含量极低。     

spt15突变基因对酿酒酵母木糖利用的影响

利用基因工程手段得到重组菌YPH499-3中的spt15有效突变基因,通过表达载体pYX212转化入酿酒酵母原始菌株YPH499中,重新获得酿酒酵母重组菌株。对其性状进行研究,结果表明该菌株能有效利用木糖并共发酵木糖和葡萄糖。在30oC、200r/min,发酵72h时,50g/L木糖的利用率为82.0%,乙醇产率为28.4%;当木糖和葡萄糖以质量比1:1混合发酵时,木糖和葡萄糖的利用率分别为80.4%和100%,乙醇产率为31.4%;同时发现木糖醇的含量极低。从而验证了有效突变基因spt15-10对酿酒酵母共发酵木糖和葡萄糖产酒精的影响。     

在酿酒酵母中共表达XYLA和XKS1基因后利用木糖的初步研究

为了使酿酒酵母较好地利用木糖产生乙醇,将来自Thermus thermophilus的木糖异构酶基因XYLA和酿酒酵母自身的木酮糖激酶基因XKS1,构建到酵母表达载体pESC-LEU中,导入酿酒酵母YPH499中,同时成功表达了两种酶基因。该菌以木糖为唯一碳源进行限氧发酵,木糖的利用率为9.64%,为宿主菌的4.17倍,产生2.22 mmol.L-1的乙醇。同时初步探讨了两种酶基因的表达量对酿酒酵母发酵木糖生成乙醇的影响。木糖异构酶对木糖的利用起关键性的作用,木酮糖激酶的过量表达不利于乙醇生成。     

Novel approach to engineer strains for simultaneous sugar utilization

Use of lignocellulosic biomass as a second generation feedstock in the biofuels industry is a pressing challenge. Among other difficulties in using lignocellulosic biomass, one major challenge is the optimal utilization of both 6-carbon (glucose) and 5-carbon (xylose) sugars by industrial microorganisms. Most industrial microorganisms preferentially utilize glucose over xylose owing to the regulatory phenomenon of carbon catabolite repression (CCR). Microorganisms that can co-utilize glucose and xylose are of considerable interest to the biofuels industry due to their ability to simplify the fermentation processes. However, elimination of CCR in microorganisms is challenging due to the multiple coordinating mechanisms involved. We report a novel algorithm, SIMUP, which finds metabolic engineering strategies to force co-utilization of two sugars, without targeting the regulatory pathways of CCR. Mutants of Escherichia coli based on SIMUP algorithm showed predicted growth phenotypes and co-utilized glucose and xylose; however, consumed the sugars slower than the wild-type. Some solutions identified by the algorithm were based on stoichiometric imbalance and were not obvious from the metabolic network topology. Furthermore, sequencing studies on the genes involved in CCR showed that the mechanism for co-utilization of the sugars could be different from previously known mechanisms.     

Glucose represses the lactose-galactose regulon in Kluyveromyces lactis through a SNF1 and MIG1- dependent pathway that modulates galactokinase (GAL1) gene expression.

Expression of the lactose-galactose regulon in Kluyveromyces lactis is induced by lactose or galactose and repressed by glucose. Some components of the induction and glucose repression pathways have been identified but many remain unknown. We examined the role of the SNF1 (KlSNF1) and MIG1 (KlMIG1) genes in the induction and repression pathways. Our data show that full induction of the regulon requires SNF1; partial induction occurs in a Klsnf1 -deleted strain, indicating that a KlSNF1 -independent pathway(s) also regulates induction. MIG1 is required for full glucose repression of the regulon, but there must be a KlMIG1 -independent repression pathway also. The KlMig1 protein appears to act downstream of the KlSnf1 protein in the glucose repression pathway. Most importantly, the KlSnf1-KIMig repression pathway operates by modulating KlGAL1 expression. Regulating KlGAL1 expression in this manner enables the cell to switch the regulon off in the presence of glucose. Overall, our data show that, while the Snf1 and Mig1 proteins play similar roles in regulating the galactose regulon in Saccharomyces cerevisiae and K.lactis , the way in which these proteins are integrated into the regulatory circuits are unique to each regulon, as is the degree to which each regulon is controlled by the two proteins.     

The Snf1 kinase of the filamentous fungus Hypocrea jecorina phosphorylates regulation-relevant serine residues in the yeast carbon catabolite repressor Mig1 but not in the filamentous fungal counterpart Cre1

In Saccharomyces cerevisiae, the SNF1 gene product phosphorylates the carbon catabolite repressor protein Mig1 under conditions when glucose is limiting, thereby relieving the fungus from catabolite repression. We have investigated whether the corresponding counterpart of filamentous fungi-the Cre1 protein-is also phosphorylated by Snf1. To this end, snf1, an ortholog of SNF1, was isolated from the ascomycete Hypocrea jecorina. The gene encodes a protein with high similarity to Snf1 kinases from other eukaryotes in its N-terminal catalytic domain, but little similarity in the C-terminal half of the protein, albeit some short aa-areas were detected, however, which are conserved in filamentous fungi and in yeast. Expression of snf1 is independent of the carbon source. An overexpressed catalytic domain of H. jecorina Snf1 readily phosphorylated yeast Mig1, but not a Mig1 mutant form, in which all four identified Snf1 phosphorylation sites (Phi XRXXSXXX Phi) had been mutated. The enzyme did neither phosphorylate H. jecorina Cre1 nor histone H3, another substrate of Snf1 kinase in yeast. H. jecorina Snf1 also phosphorylated peptides comprising the strict Snf1 consensus, but notably did not phosphorylate peptides containing the regulatory serine residue in Cre1 (=Ser(241) in H. jecorina Cre1 and Ser(266) in Sclerotinia sclerotiorum CRE1). The use of cell-free extracts of H. jecorina as protein source for Snf1 showed phosphorylation of an unknown 36 kDa protein, which was present only in extracts from glucose-grown mycelia. We conclude that the Snf1 kinase from H. jecorina is not involved in the phosphorylation of Cre1.     

Evidence for catabolite inhibition in regulation of pentose utilization and transport in the ruminal bacterium Selenomonas ruminantium.

Pentose sugars can be an important energy source for ruminal bacteria, but there has been relatively little study regarding the regulation of pentose utilization and transport by these organisms. Selenomonas ruminantium, a prevalent ruminal bacterium, actively metabolizes xylose and arabinose. When strain D was incubated with a combination of glucose and xylose or arabinose, the hexose was preferentially utilized over pentoses, and similar preferences were observed for sucrose and maltose. However, there was simultaneous utilization of cellobiose and pentoses. Continuous-culture studies indicated that at a low dilution rate (0.10 h-1) the organism was able to co-utilize glucose and xylose. This co-utilization was associated with growth rate-dependent decreases in glucose phosphotransferase activity, and it appeared that inhibition of pentose utilization was due to catabolite inhibition by the glucose phosphotransferase transport system. Xylose transport activity in strain D required induction, while arabinose permease synthesis did not require inducer but was subject to repression by glucose. Since an electrical potential or a chemical gradient of protons drove xylose and arabinose uptake, pentose-proton symport systems apparently contributed to transport.     

Depression of Saccharomyces cerevisiae invasive growth on non-glucose carbon sources requires the Snf1 kinase

Haploid Saccharomyces cerevisiae cells growing on media lacking glucose but containing high concentrations of carbon sources such as fructose, galactose, raffinose, and ethanol exhibit enhanced agar invasion. These carbon sources also promote diploid filamentous growth in response to nitrogen starvation. The enhanced invasive and filamentous growth phenotypes are suppressed by the addition of glucose to the media and require the Snf1 kinase. Mutations in the PGI1 and GND1 genes encoding carbon source utilization enzymes confer enhanced invasive growth that is unaffected by glucose but requires active Snf1. Carbon source does not modulate FLO11 flocculin expression, but enhanced polarized bud site selection is necessary for invasion on certain carbon sources. Interestingly, deletion of SNF1 blocks invasion without affecting bud site selection. Snf1 is also required for formation of spokes and hubs in multicellular mats. To examine glucose repression of invasive growth more broadly, we performed genome-wide microarray expression analysis in wild-type cells growing on glucose and galactose, and snf1 Delta cells on galactose. SNF1 probably mediates glucose repression of multiple genes potentially involved in invasive and filamentous growth. FLO11-independent cell-cell attachment, cell wall integrity, and/or polarized growth are affected by carbon source metabolism. In addition, derepression of cell cycle genes and signalling via the cAMP-PKA pathway appears to depend upon SNF1 activity during growth on galactose.