积累L-苹果酸的米根霉突变株酶活性初探

对富马酸产生菌株—米根霉ME-F10进行诱变育种的过程中, 得到一株性能稳定的高效积累L-苹果酸的突变株ME-M15。该菌株发酵96 h平均L-苹果酸产量达16.3 g/L, 较出发菌株L-苹果酸积累量平均提高3倍, 而富马酸和乙醇的积累量大幅下降。对突变株代谢途径关键酶活研究表明, 突变株富马酸酶胞质途径同功酶和乙醇脱氢酶活力较之出发菌株酶活力明显减弱, 而丙酮酸羧化酶活力无明显差别。     

D-核糖生产菌的选育

将枯草芽胞杆菌通过紫外线诱变得到了莽草酸缺陷突变株,在２８株突变株中有１０株积累Ｄ－核糖。这些菌株均属戊糖磷酸途径的非氧化支路缺失突变株。对这些菌株的产核糖能力进行了验证、培养基中芳香族氨基酸的浓度影响Ｄ－核糖的积累     

MAPK级联途径调控植物细胞胞质分裂

胞质分裂(cytokinesis)是细胞分裂的最后关键一步,产生2个含有完整的遗传物质和胞质细胞器的子细胞．植物胞质分裂包括细胞板的形成,这一过程是在成膜体的牵引下由一些植物特有的步骤完成的．促分裂原活化蛋白激酶(MAPK)级联途径在真核生物中是高度保守的,由MAPKs,MAPKKs,MAPKKKs组成,通过MAPKKK→ MAPKK → MAPK的逐级磷酸化传递细胞信号．近来的研究表明, NACK-MAPKKK→MAPKK→MAPK→MAP65构成的信号途径调控植物细胞的胞质分裂．本文就这一信号途径,总结了植物胞质分裂机制的研究进展,并对其中的问题进行了讨论与展望．     

苏云金芽胞杆菌spoIIID基因缺失突变株的特点

摘要：【目的】构建苏云金芽胞杆菌spoIIID基因缺失突变株,并研究其与出发菌株的表型及性质差异。【方法】采用基因同源重组技术敲除了苏云金芽胞杆菌HD-73菌株中的spoIIID基因,构建了spoIIID缺失突变株,测定生长曲线,并通过扫描电子显微镜观察,芽胞计数分析及SDS-PAGE 蛋白电泳比较突变株与出发菌株的差异。构建遗传互补菌株,观察菌株性状的回复情况。【结果】通过温敏载体同源重组敲除技术获得了苏云金芽胞杆菌HD-73菌株spoIIID基因缺失突变株,生长曲线测定表明,突变株较出发菌株在平稳期后期生长较缓和;扫描电子显微镜观察和芽胞计数分析显示,突变株基本丧失了形成芽胞的能力,但依然形成晶体。SDS-PAGE结果显示,在 SSM培养基中,突变株对伴胞晶体蛋白的形成量影响并不显著;在营养较富集的Luria-Bertani培养基中,突变株中伴胞晶体蛋白的形成量较野生型和互补株明显降低。利用载体pHT315携带spoIIID操纵子互补突变株,互补株恢复了产生晶体和芽胞的能力。【结论】本研究证明spoIIID基因是苏云金芽胞杆菌芽胞形成所必需,同时与晶体蛋白的表达相关。     

Pseudomonas plecoglossicida NyZ12基因无痕敲除方法的建立

旨在建立一种适合环己胺降解菌NyZ12基因无痕敲除的可靠方法。通过overlapping PCR技术将目的基因上下游同源臂融合并克隆到自杀载体pEX18km上,将重组质粒转化到大肠杆菌S17pir中,再通过接合转移到假单胞菌NyZ12菌株内,经pEX18km质粒上sacB基因的反向筛选得到突变株并通过PCR方法和测序鉴定。结果显示,成功构建了假单胞菌NyZ12菌株orf4637的基因突变株(NyZ12Δ4637)。通过自杀载体同源重组可以成功获得敲除的无痕突变株,且突变株基因组上没有任何抗性筛选标记残留,为环己胺降解菌NyZ12基因功能研究提供了可靠的基因敲除技术。     

青枯雷尔氏菌胞外多糖合成缺失突变株构建及其生物学特性

【目的】由青枯雷尔氏菌(Ralstonia solanacearum)引起的植物青枯病是一种毁灭性土传病害。胞外多糖(extracellular polysaccharides,EPS)是青枯雷尔氏菌关键的致病因子之一。通过构建胞外多糖缺失突变株,研究胞外多糖在青枯病致病中的作用。【方法】从青枯雷尔氏菌FJAT-91的基因组中克隆出胞外多糖合成结构基因epsD同源臂,克隆至自杀性质粒p K18mobsacB,再将庆大霉素抗性基因(Gm)插入同源臂中间,获得重组质粒p K18-epsD。将重组质粒转化至青枯雷尔氏菌FJAT-91感受态细胞中,通过同源重组敲除epsD基因,获得EPS合成缺失的突变株FJAT-91Δeps 。研究突变株与野生菌株在菌落形态、胞外多糖合成、运动能力、定殖能力的差异性。【结果】突变菌株FJAT-91ΔepsD与出发菌株FJAT-91相比:胞外多糖产量显著减少,生长较慢;泳动能力(swimming motility)和群集运动能力(swarming motility)显著降低;在番茄苗根部和茎部的定殖能力显著降低;弱化指数(AI)为0.905,鉴定为无致病力菌株。【结论】胞外多糖在青枯雷尔氏菌的致病中起着关键的作用,本课题研究成果为开发植物疫苗提供了优良的材料与研究基础。     

铜绿假单胞菌M18 rsmY突变株的构建及其对PCA和Plt的区别性调控

【目的】在假单胞菌中,小RNA(sRNA)参与初级和次级代谢产物、多种毒素因子以及菌群传感系统的调控,通过在植物根际促生铜绿假单胞菌M18中研究RsmY对吩嗪-1-羧酸(PCA)和藤黄绿菌素(Plt)两种抗生素的调控作用,深入了解假单胞菌中次级代谢的途径并为构建高产抗生素工程菌株提供了一定的理论基础。【方法】运用同源重组技术,构建了铜绿假单胞菌M18株的rsmY突变菌株M18RY,通过基因过表达、lacZ报告基因融合分析实验,进一步验证了RsmY对抗生素合成基因的调控作用。【结果】比较野生型M18和突变株M18RY中PCA和Plt在同一培养条件下的生物合成量,突变菌株M18RY中PCA的产量显著增加,为野生型菌株的5倍左右,而Plt的产量降为野生型的1/8。LacZ报告基因融合分析进一步证明了RsmY对PCA的负调控作用主要是通过phz2基因簇来实现的。【结论】结果表明,rsmY基因区别性调控PCA和Plt的生物合成。     

铜绿假单胞菌PAO1 ku基因缺失菌株的构建及其对生物被膜耐药性的影响

【背景】铜绿假单胞菌是常见的条件致病菌,易形成生物被膜,具有基因突变率高、耐药性强的特点。非同源末端连接是DNA双链断裂的主要修复途径之一,修复过程会导致DNA突变产生。【目的】研究非同源末端连接对生物被膜中的铜绿假单胞菌基因突变率和耐药性的影响。【方法】通过基因无痕敲除的方法构建PAO1菌株的ku基因缺失突变株Δku并构建其回补株。对比研究突变株和野生菌株生物被膜形成能力、生物被膜状态下各菌的基因突变率以及对抗生素的耐受性。通过荧光定量PCR检测生物被膜中PAO1菌株ku基因的表达水平。【结果】各突变株生物被膜形成能力无显著差异;与野生菌株相比,突变株Δku在生物被膜中的基因突变率以及对环丙沙星和庆大霉素的最低抑菌浓度(minimum inhibitory concentration,MIC)下降。荧光定量PCR结果表明,ku基因在生物被膜形成早期转录水平有明显上调。【结论】非同源末端连接修复途径对生物被膜中的铜绿假单胞菌基因突变率以及耐药性的提高有一定的作用。本研究将为后续进一步阐释铜绿假单胞菌耐药产生机制提供一定的理论依据。     

铜绿假单胞菌parC基因突变与耐氟喹诺酮的关系

研究了成都地区临床分离的铜绿假单胞菌拓扑异构酶ⅣparC基因突变与耐氟喹诺酮类药物的关系。测定临床分离的55株铜绿假单胞菌的MIC值,从中筛选出1株敏感菌和8株耐药菌,以标准敏感菌株ATCC27853作为质控菌株。用PCR反应扩增parC基因的喹诺酮耐药决定区(QRDR),扩增产物片段长度为396bp,同时对上述10株菌的PCR产物进行测序分析。临床分离敏感菌和标准菌株ATCC27853的parC基因序列与国外报道的序列相同,而R25,R42,R43,R44等4株耐药菌株在87位(TCGCG→TTG)均有突变,该单位点突变引起氨基酸由Ser→Leu的改变,此外,新发现在所有耐药菌株115位有一静止突变(GCT→GCG),该突变未引起氨基酸的改变。拓扑异构酶ⅣparC基因突变是铜绿假单胞菌对氟喹诺酮类药物产生耐药性的机制之一,以87位的突变最为常见。     

植物胞质分裂发生机制

胞质分裂(cytohnesis)是指在同一细胞中在新形成的两个子核之间形成新的间隔,将母细胞一分为二的过程。胞质分裂存在于任何一种生命形式中,从单细胞的细菌到多细胞的真核生物都能进行胞质分裂。近些年由于细胞学方法的改进和研究材料增多等因素,使得对植物胞质分裂发生机制的研究取得了很大的进展。现对植物中不同类型的胞质分裂在细胞学、分子生物学方面的研究进展作一综述。     

SEPH, a Cdc7p orthologue from Aspergillus nidulans, functions upstream of actin ring formation during cytokinesis

In the filamentous fungus, Aspergillus nidulans, multiple rounds of nuclear division occur before cytokinesis, allowing an unambiguous identification of genes required specifically for cytokinesis. As in animal cells, both an intact microtubule cytoskeleton and progression through mitosis are required for actin ring formation and contraction. The sepH gene from A. nidulans was discovered in a screen for temperature-sensitive cytokinesis mutants. Sequence analysis showed that SEPH is 42% identical to the serine-threonine kinase Cdc7p from fission yeast. Signalling through the Septation Initiation Network (SIN), which includes Cdc7p and the GTPase Spg1p, is emerging as a primary regulatory pathway used by fission yeast to control cytokinesis. A similar group of proteins comprise the Mitotic Exit Network (MEN) in budding yeast. This is the first direct evidence for the existence of a functional SIN-MEN pathway outside budding and fission yeast. In addition to SEPH, potential homologues were also identified in other fungi and plants but not in animal cells. Deletion of sepH resulted in a viable strain that failed to septate at any temperature. Interestingly, quantitative analysis of the actin cytoskeleton revealed that sepH is required for construction of the actin ring. Therefore, SEPH is distinct from its counterpart in fission yeast, in which SIN components operate downstream of actin ring formation and are necessary for ring contraction and later events of septation. We conclude that A. nidulans has components of a SIN-MEN pathway, one of which, SEPH, is required for early events during cytokinesis.     

Characterization of ypa1 and ypa2, the Schizosaccharomyces pombe orthologs of the peptidyl proyl isomerases that activate PP2A, reveals a role for Ypa2p in the regulation of cytokinesis

The Schizosaccharomyces pombe septation initiation network (SIN) regulates cytokinesis. Cdc7p is the first kinase in the core SIN; we have screened genetically for SIN regulators by isolating cold-sensitive suppressors of cdc7-24. Our screen yielded a mutant in SPAC1782.05, one of the two fission yeast orthologs of mammalian phosphotyrosyl phosphatase activator. We have characterized this gene and its ortholog SPAC4F10.04, which we have named ypa2 and ypa1, respectively. We find that Ypa2p is the major form of protein phosphatase type 2A activator in S. pombe. A double ypa1-Δ ypa2-Δ null mutant is inviable, indicating that the two gene products have at least one essential overlapping function. Individually, the ypa1 and ypa2 genes are essential for survival only at low temperatures. The ypa2-Δ mutant divides at a reduced cell size and displays aberrant cell morphology and cytokinesis. Genetic analysis implicates Ypa2p as an inhibitor of the septation initiation network. We also isolated a cold-sensitive allele of ppa2, the major protein phosphatase type 2A catalytic subunit, implicating this enzyme as a regulator of the septation initiation network.     

Regulation of cytokinesis by spindle-pole bodies

In the fission yeast Schizosaccharomyces pombe, cytokinesis is thought to be controlled by the daughter spindle-pole body (SPB) through a regulatory pathway named the septation initiation network (SIN). Here, we demonstrate that laser ablation of both, but not a single SPB, results in failure of cytokinesis. Ablation of only the daughter SPB often leads to activation of the SIN on the mother SPB and successful cytokinesis. Thus, either SPB can drive cytokinesis.     

Dma1 ubiquitinates the SIN scaffold, Sid4, to impede the mitotic localization of Plo1 kinase

Proper cell division requires strict coordination between mitotic exit and cytokinesis. In the event of a mitotic error, cytokinesis must be inhibited to ensure equal partitioning of genetic material. In the fission yeast, Schizosaccharomyces pombe, the checkpoint protein and E3 ubiquitin ligase, Dma1, delays cytokinesis by inhibiting the septation initiation network (SIN) when chromosomes are not attached to the mitotic spindle. To elucidate the mechanism by which Dma1 inhibits the SIN, we screened all SIN components as potential Dma1 substrates and found that the SIN scaffold protein, Sid4, is ubiquitinated in vivo in a Dma1-dependent manner. To investigate the role of Sid4 ubiquitination in checkpoint function, a ubiquitination deficient sid4 allele was generated and our data indicate that Sid4 ubiquitination by Dma1 is required to prevent cytokinesis during a mitotic checkpoint arrest. Furthermore, Sid4 ubiquitination delays recruitment of the Polo-like kinase and SIN activator, Plo1, to spindle pole bodies (SPBs), while at the same time prolonging residence of the SIN inhibitor, Byr4, providing a mechanistic link between Dma1 activity and cytokinesis inhibition.     

Timely Septation Requires SNAD-dependent Spindle Pole Body Localization of the Septation Initiation Network Components in the Filamentous Fungus Aspergillus nidulans

In the filamentous fungus Aspergillus nidulans, cytokinesis/septation is triggered by the septation initiation network (SIN), which first appears at the spindle pole body (SPB) during mitosis. The coiled-coil protein SNAD is associated with the SPB and is required for timely septation and conidiation. We have determined that SNAD acted as a scaffold protein that is required for the localization of the SIN proteins of SIDB and MOBA to the SPB. Another scaffold protein SEPK, whose localization at the SPB was dependent on SNAD, was also required for SIDB and MOBA localization to the SPB. In the absence of either SEPK or SNAD, SIDB/MOBA successfully localized to the septation site, indicating that their earlier localization at SPB was not essential for their later appearance at the division site. Unlike their functional counterparts in fission yeast, SEPK and SNAD were not required for vegetative growth but only for timely septation. Furthermore, down-regulation of negative regulators of the SIN suppressed the septation and conidiation phenotypes due to the loss of SNAD. Therefore, we conclude that SPB localization of SIN components is not essential for septation per se, but critical for septation to take place in a timely manner in A. nidulans.     

Dma1 prevents mitotic exit and cytokinesis by inhibiting the septation initiation network (SIN)

In the fission yeast Schizosaccharomyces pombe, the septation initiation network (SIN) triggers cytokinesis after mitosis. We investigated the relationship between Dma1p, a spindle checkpoint protein and cytokinesis inhibitor, and the SIN. Deletion of dma1 inactivates the spindle checkpoint and allows precocious SIN activation, while overexpressing Dma1p reduces SIN signaling. Dma1p seems to function by inhibiting the SIN activator, Plo1p kinase, since dma1 overexpression and deletion phenotypes suggest that Dma1p antagonizes Plo1p localization. Furthermore, failure to maintain high cyclin-dependent kinase (CDK) activity during spindle checkpoint activation in dma1 deletion cells requires Plo1p. Dma1p itself localizes to spindle pole bodies through interaction with Sid4p. Our observations suggest that Dma1p functions to prevent mitotic exit and cytokinesis during spindle checkpoint arrest by inhibiting SIN signaling.     

Etd1p is a novel protein that links the SIN cascade with cytokinesis

In animal cells, cytokinesis occurs by constriction of an actomyosin ring. In fission yeast cells, ring constriction is triggered by the septum initiation network (SIN), an SPB-associated GTPase-regulated kinase cascade that coordinates exit from mitosis with cytokinesis. We have identified a novel protein, Etd1p, required to trigger actomyosin ring constriction in fission yeasts. This protein is localised at the cell tips during interphase. In mitosis, it relocates to the medial cortex region and, coincident with cytokinesis, it assembles into the actomyosin ring by association to Cdc15p. Relocation of Etd1p from the plasma membrane to the medial ring is triggered by SIN signalling and, reciprocally, relocation of the Sid2p-Mob1p kinase complex from the SPB to the division site, a late step in the execution of the SIN, requires Etd1p. These results suggest that Etd1p coordinates the mitotic activation of SIN with the initiation of actomyosin ring constriction. Etd1p peaks during cytokinesis and is degraded by the ubiquitin-dependent 26S-proteasome pathway at the end of septation, providing a mechanism to couple inactivation of SIN to completion of cytokinesis.     

SIN and the art of splitting the fission yeast cell

The septation initiation network (SIN) triggers the onset of cytokinesis in the fission yeast Schizosaccharomyces pombe by promoting contraction of the medially placed F-actin ring. SIN signaling is regulated by the polo-like kinase plo1p and by cdc2p, the initiator of mitosis, and its activation is co-ordinated with other events in mitosis to ensure that cytokinesis does not begin until chromosomes have been separated. Though the SIN controls the contractile ring, the signal originates from the poles of the mitotic spindle. Recent studies suggest that the spindle pole body may act as a dynamic assembly site for active SIN signaling complexes. In the budding yeast Saccharomyces cerevisiae the counterpart of the SIN, called the MEN, mediates both mitotic exit and cytokinesis, in part through regulating activation of the phosphoprotein phosphatase Cdc14p. Flp1p, the S. pombe ortholog of Cdc14p, is not essential for mitotic exit, but may contribute to an orderly mitosis-G1 transition by regulating the destruction of the mitotic inducer cdc25p.