水稻含有B-box锌指结构域的OsBBX25蛋白参与植物对非生物胁迫的响应

锌指蛋白在调控植物生长发育和应对逆境过程中发挥着重要作用.为进一步研究锌指类蛋白参与植物非生物胁迫响应的分子机制,对水稻(Oryza sativa)中一个编码含有B-box锌指结构域蛋白的OsBBX25基因进行了功能分析.OsBBX25受盐、干旱和ABA诱导表达.异源表达OsBBX25的转基因拟南芥(Arabidopsis thaliana)与野生型相比对盐和干旱的耐受性增强,且盐胁迫条件下转基因植物中KIN1、RD29A和COR15的表达上调,干旱胁迫下KIN1、RD29A和RD22的表达上调.外源施加ABA时,转基因植物的萌发率与野生型之间没有明显差异.OsBBX25可能作为转录调控的辅助因子调节胁迫应答相关基因的表达,进而参与植物对非生物胁迫的响应.     

水稻NAM基因家族的全基因组鉴定及表达分析（英文）

植物特异性转录因子NAM家族从属于NAC转录因子超家族,在植株生长发育、生理代谢以及应对各种胁迫反应中均发挥重要作用。该研究采用生物信息学方法鉴定水稻基因组中的NAM基因,分析其时空表达模式、亚细胞定位以及蛋白相互作用,并采用实时定量qRT-PCR方法分析不同外源激素(如SA、ABA和MeJA)以及非生物胁迫(包括干旱、盐和冷)处理下各NAM基因的表达特征,为进一步探索NAM基因在非生物胁迫中的功能和应激机制以及激素调控途径奠定基础。结果显示:(1)从水稻基因组中共鉴定出48个NAM基因,进化分析将其分为5个亚家族;NAM基因在水稻基因组中存在9对片段复制事件。(2)组织表达分析显示,NAM基因在水稻不同组织及发育时期表现特异性表达,特别是叶鞘、茎和节的生长过程中高表达,且大多数是核定位,并存在多种蛋白互作。(3)实时定量qRT-PCR表达分析显示,10个NAM基因在不同组织中均特异表达;大部分NAM基因在盐和干旱胁迫下表达上调,而在冷胁迫下表达降低;SA、ABA和MeJA处理均可显著改变各NAM基因的表达水平。研究表明,NAM基因在水稻生长发育、激素应答和非生物胁迫响应中具有重要作用。     

水曲柳FmWRKY44基因克隆及表达分析

克隆水曲柳FmWRKY44基因,探究其在非生物胁迫和激素胁迫中的作用。利用水曲柳干旱转录组序列设计特异引物,克隆FmWRKY44基因的完整ORF序列,并对该序列及其编码产物进行生物信息学分析,采用qRT-PCR技术分析FmWRKY44表达模式。克隆了一个水曲柳WKRY基因,编码区长1383bp,编码460氨基酸。对其编码蛋白分析发现其为稳定亲水蛋白,亚细胞定位预测主要在细胞核,进行保守域及同源性分析分析,属于WRKYⅠ类家族,命名为FmWRKY44。qRT-PCR分析发现,FmWRKY44在种子中高度表达,并不同程度响应低温、高温、盐和干旱4种非生物胁迫。同时发现FmWRKY44与NAA、ABA、GA3、JA植物激素响应,水曲柳FmWRKY44基因积极响应低温、高温胁迫。     

蒺藜苜蓿MtbHLH25基因克隆、亚细胞定位及表达分析

【目的】bHLH转录因子数量众多,能够广泛参与植物的生长发育和逆境胁迫等过程。本试验以蒺藜苜蓿R108为材料,初步探讨MtbHLH25基因的功能。【方法】通过PCR扩增技术从蒺藜苜蓿中克隆MtbHLH25基因和启动子,构建酵母表达载体并用LiAc转化法转移到Y2H Gold酵母菌株中进行酵母自激活检测,构建亚细胞定位载体并通过冻融法转入农杆菌EHA105,菌液注射到烟草下表皮细胞后利用SP8激光共聚焦显微镜观察,通过实时荧光定量PCR技术研究MtbHLH25基因的时空表达水平。【结果】（1）从蒺藜苜蓿中成功克隆出MtbHLH25基因和启动子,该基因总长882 bp,共编码293个氨基酸。启动子序列分析发现其包含了ABA、MeJA、GA和SA等响应元件。（2）进化树结果表明MtbHLH25蛋白与蚕豆和长柔毛野豌豆中bHLH蛋白高度同源。（3）亚细胞定位结果显示MtbHLH25蛋白定位于细胞核。（4）酵母自激活检测结果显示MtbHLH25蛋白具有自激活活性。（5）表达分析结果显示,MtbHLH25在蒺藜苜蓿根、茎、叶、花和果实中均有表达,其中在根中表达水平最高;外源SA、MeJA、ABA、GA以及盐胁迫使MtbHLH25基因表达量都呈下降趋势,推测SA、MeJA、ABA、GA以及盐胁迫对MtbHLH25基因的表达起到负调控作用。干旱胁迫能够显著诱导MtbHLH25基因表达量的上升,说明该转录因子可能在干旱胁迫中起到正调控作用。【结论】MtbHLH25基因可能对盐胁迫敏感,在干旱胁迫中可能发挥正调控作用。此外,MtbHLH25蛋白具有自激活活性,对下游启动子调控的报告基因可能具有激活作用。     

激素处理及非生物胁迫下枳PtPPF-1基因的表达特性

PtPPF-1是从枳叶片中分离出的与豌豆中的PPF-1具有很高同源性的基因。PPF-1基因能通过控制叶绿体发育而延缓叶片衰老,同时PPF-1能被外源GA3诱导,是与植物营养生长密切相关的基因。本研究以实生苗枳[Poncirus trifoliata(L.)Raf.]为材料,采用半定量RT-PCR对不同激素处理及非生物胁迫(低温、干旱、盐)下枳叶中PtPPF-1的表达情况进行了分析,以期明确PtPPF-1的功能。结果表明,GA3I、AA、ABA促进了PtPPF-1的表达,KT对PtPPF-1的表达有抑制作用;低温、干旱、盐胁迫能诱导PtPPF-1的表达。推测GA3、IAA、ABA信号通路可能与KT信号通路作用于PtPPF-1的表达存在不同的机制。     

热激转录因子在植物抗非生物胁迫中的功能研究进展

植物在遭受环境胁迫时会产生一系列应激反应,而热激转录因子可通过介导热激蛋白或其他热诱导基因的转录和表达,来参与调控植物抵抗逆境胁迫过程和其他生命活动。主要介绍了植物热激转录因子的基本蛋白结构域,阐述了3类热激转录因子在抗极端温度（高温、低温）胁迫、干旱胁迫、高盐胁迫、活性氧胁迫中的功能与作用机制,并探讨和展望了植物热激转录因子在植物育种和提高植物抗逆性的研究中的发展与应用前景,以期为深入研究热激转录因子在调控植物抵抗逆境胁迫中的生物学功能与机制提供理论参考。     

赤霉素调节植物对非生物逆境的耐性

赤霉素（GAs）是一类重要的植物激素,调控植物生长发育的诸多方面．最近的研究表明,GA也参与对生物与非生物胁迫的响应,然而GA参与非生物胁迫响应的遗传学证据及其机制有待于进一步研究．本实验室前期研究证明,水稻EullfELONGATEDUPPERMOSTINTERNODE）通过一个新的生化途径降解体内的活性赤霉素分子,并参与调控水稻对病原菌的基础抗病性．本研究发现,euil突变体对盐胁迫能力降低,而超表达EUll基因的水稻和拟南芥耐盐性显著提高．进一步研究发现,积累高含量赤霉素的水稻euil突变体对脱落酸（ABA）的敏感性下降,而赤霉素缺失的EUll超表达转基因水稻和拟南芥均改变了对于ABA的敏感性．EUll基因的转录受逆境诱导,其功能缺失与超表达调控了逆境标志基因的表达．综上推测,GA可能是通过影响ABA的信号途径从而改变了植物对非生物胁迫的响应．     

青杄转录因子PwNAC30及其启动子序列的克隆与表达分析

该研究以青杄(Picea wilsonii)为实验材料,通过PCR从青杄的cDNA文库中克隆得到一个NAC转录因子,命名为PwNAC30。生物信息学分析显示,PwNAC30开放阅读框1 179bp,共编码392个氨基酸,在其N端存在保守的NAM(no apical meristem)结构域,可分为A～E等5个亚结构域。多序列对比和系统进化树分析显示,PwNAC30蛋白与同为云杉属的北美云杉(Picea sitchensis)聚为一类。启动子克隆分析显示,PwNAC30基因启动子上存在脱落酸(ABA)、赤霉素(GA)、茉莉酸甲酯(MeJA)、TC-rich repeats等激素和逆境响应元件,在GA、ABA、MeJA、低温、干旱、盐的处理下,其启动子活性均明显增强。荧光定量PCR分析表明,PwNAC30在球果中的表达量最高,而在花粉和种子中的表达量最低。PwNAC30对于盐、干旱、低温、ABA、MeJA、GA处理均有响应,尤其对盐、干旱、MeJA的响应最为显著。亚细胞定位结果显示,PwNAC30蛋白定位于细胞核与细胞质,主要定位于细胞核中。酵母单杂及双杂结果表明,PwNAC30蛋白的全长和N端没有转录激活活性,而C端有转录激活活性,且PwNAC30自身能形成同源二聚体。研究表明,青杄PwNAC30基因可以作为一个转录因子发挥作用,其转录激活活性在C端,且自身能够形成同源二聚体结构;PwNAC30基因广泛参与了ABA、GA、MeJA等激素的信号通路,并对盐、干旱、低温处理有响应。     

水稻NAM基因家族的全基因组鉴定及表达分析

植物特异性转录因子NAM家族从属于NAC转录因子超家族,在植株生长发育、生理代谢以及应对各种胁迫反应中均发挥重要作用。该研究采用生物信息学方法鉴定水稻基因组中的NAM基因,分析其时空表达模式、亚细胞定位以及蛋白相互作用,并采用实时定量qRT PCR方法分析不同外源激素(如SA、ABA和MeJA)以及非生物胁迫(包括干旱、盐和冷)处理下各NAM基因的表达特征,为进一步探索NAM基因在非生物胁迫中的功能和应激机制以及激素调控途径奠定基础。结果显示：(1)从水稻基因组中共鉴定出48个NAM基因,进化分析将其分为5个亚家族;NAM基因在水稻基因组中存在9对片段复制事件。(2)组织表达分析显示,NAM基因在水稻不同组织及发育时期表现特异性表达,特别是叶鞘、茎和节的生长过程中高表达,且大多数是核定位,并存在多种蛋白互作。(3)实时定量qRT PCR表达分析显示,10个NAM基因在不同组织中均特异表达;大部分NAM基因在盐和干旱胁迫下表达上调,而在冷胁迫下表达降低;SA、ABA和MeJA处理均可显著改变各NAM基因的表达水平。研究表明,NAM基因在水稻生长发育、激素应答和非生物胁迫响应中具有重要作用。     

大肠杆菌突变株QQS101发酵生产琥珀酸初步研究

琥珀酸是一种具有重要应用价值的生物基平台化合物。对大肠杆菌focA-pflB ldhA突变株QQS101在严格厌氧条件下生长和葡萄糖代谢能力进行了考察,比较分析了葡萄糖与大肠杆菌混合酸发酵产物的单位碳的还原程度,认为非严格厌氧条件有利于QQS101发酵葡萄糖积累琥珀酸,进一步对有氧生长碳源进行了对比试验的结果表明,以木糖支持有氧生长,QQS101摇瓶发酵39 h消耗葡萄糖37.6 g/L,琥珀酸的产量达到31.01 g/L,摩尔产率为1.258 mol Succinate/mol Glucose。发酵过程中,丙氨酸的添加能够提高琥珀酸的摩尔产率。     

碳源对重组大肠杆菌两阶段发酵产丁二酸的影响

研究了在好氧培养基中分别添加不同碳源对两阶段发酵菌体生长、酶活及代谢产物分布的影响,结果表明添加4mmol/L葡萄糖和12,54,80mmol/L乙酸钠均可以提高好氧阶段的菌体密度和相关酶活。将不同条件下培养的菌体转接厌氧发酵后,厌氧阶段的酶活和代谢产物分布也发生改变。进一步对酶活及代谢产物分析表明：Escherichia coli NZN111(sfcA)厌氧发酵过程中,磷酸烯醇式丙酮酸羧化激酶(PCK)是产丁二酸的关键酶,丙酮酸激酶(PYK)主要和副产物丙酮酸的积累有关,异柠檬酸裂解酶(ICL)对丁二酸产量也有一定影响。好氧培养基中添加80mmol/L乙酸钠,厌氧发酵结束时丁二酸的质量收率可达89.0%,相比对照提高了16.6%。     

Fed-batch culture of a metabolically engineered Escherichia coli strain designed for high-level succinate production and yield under aerobic conditions

An aerobic succinate production system developed by Lin et al. (Metab Eng, in press) is capable of achieving the maximum theoretical succinate yield of 1.0 mol/mol glucose for aerobic conditions. It also exhibits high succinate productivity. This succinate production system is a mutant E. coli strain with five pathways inactivated: DeltasdhAB, Delta(ackA-pta), DeltapoxB, DeltaiclR, and DeltaptsG. The mutant strain also overexpresses Sorghum vulgare pepc. This mutant strain is designated HL27659k(pKK313). Fed-batch reactor experiments were performed for the strain HL27659k(pKK313) under aerobic conditions to determine and demonstrate its capacity for high-level succinate production. Results showed that it could produce 58.3 g/l of succinate in 59 h under complete aerobic conditions. Throughout the entire fermentation the average succinate yield was 0.94+/-0.07 mol/mol glucose, the average productivity was 1.08+/-0.06 g/l-h, and the average specific productivity was 89.77+/-3.40 mg/g-h. Strain HL27659k (pKK313) is, thus, capable of large-scale succinate production under aerobic conditions. The results also showed that the aerobic succinate production system using the designed strain HL27659k(pKK313) is more practical than conventional anaerobic succinate production systems. It has remarkable potential for industrial-scale succinate production and process optimization.     

产琥珀酸重组大肠杆菌的发酵性能研究

研究了重组大肠杆菌JM001(△ppc)/pTrc99a-pck发酵产琥珀酸的性能,结果表明厌氧条件下其耗糖能力和产酸能力分别为对照菌株JM001的4.2倍和15.3倍。进一步优化发酵条件表明：采用接入菌泥的发酵方式比按照10%接种量转接厌氧发酵的效果要好,琥珀酸的对葡萄糖的质量收率提高了约10%,且副产物乙酸的量进一步降低。初始葡萄糖浓度高于60g/L时会对菌株的生长和产酸产生抑制,且浓度越高,抑制作用越明显。7L发酵罐放大实验中,整个厌氧发酵阶段葡萄糖的消耗速率为0.42g/(L.h),琥珀酸对葡萄糖的质量收率为67.75%,琥珀酸的生产强度为0.28g/(L.h)。     

Metabolic engineering of aerobic succinate production systems in Escherichia coli to improve process productivity and achieve the maximum theoretical succinate yield

The potential to produce succinate aerobically in Escherichia coli would offer great advantages over anaerobic fermentation in terms of faster biomass generation, carbon throughput, and product formation. Genetic manipulations were performed on two aerobic succinate production systems to increase their succinate yield and productivity. One of the aerobic succinate production systems developed earlier (Biotechnol, Bioeng., 2004, accepted) was constructed with five mutations (DeltasdhAB, Deltaicd, DeltaiclR, DeltapoxB, and Delta(ackA-pta)), which created a highly active glyoxylate cycle. In this study, a second production system was constructed with four of the five above mutations (DeltasdhAB, DeltaiclR, DeltapoxB, and Delta(ackA-pta)). This system has two routes in the aerobic central metabolism for succinate production. One is the glyoxylate cycle and the other is the oxidative branch of the TCA cycle. Inactivation of ptsG and overexpression of a mutant Sorghum pepc in these two production systems showed that the maximum theoretical succinate yield of 1.0 mol/mol glucose consumed could be achieved. Furthermore, the two-route production system with ptsG inactivation and pepc overexpression demonstrated substantially higher succinate productivity than the previous system, a level unsurpassed for aerobic succinate production. This optimized system showed remarkable potential for large-scale aerobic succinate production and process optimization.     

Genetic reconstruction of the aerobic central metabolism in Escherichia coli for the absolute aerobic production of succinate

Most reported efforts to enhance production of the industrially valuable specialty chemical succinate have been done under anaerobic conditions, where E. coli undergoes mixed-acid fermentation. These efforts have often been hampered by the limitations of NADH availability, poor cell growth, and slow production. An aerobic succinate production system was strategically designed that allows E. coli to produce and accumulate succinate efficiently and substantially as a product under absolute aerobic conditions. Mutations in the tricarboxylic acid cycle (sdhAB, icd, iclR) and acetate pathways (poxB, ackA-pta) of E. coli were created to construct the glyoxylate cycle for aerobic succinate production. Experiments in flask studies showed that 14.28 mM of succinate could be produced aerobically with a yield of 0.344 mole/mole using 55 mM glucose. In aerobic batch reactor studies, succinate production rate was faster, reaching 0.5 mole/mole in 24 h with a concentration of 22.12 mM; further cultivation showed that succinate production reached 43 mM with a yield of 0.7. There was also substantial pyruvate and TCA cycle C(6) intermediate accumulation in the mutant. The results suggest that more metabolic engineering improvements can be made to this system to make aerobic succinate production more efficient. Nevertheless, this aerobic succinate production system provides the first platform for enhancing succinate production aerobically in E. coli based on the creation of a new aerobic central metabolic network.     

过量表达苹果酸脱氢酶对大肠杆菌NZN111产丁二酸的影响

大肠杆菌NZN111是敲除了乳酸脱氢酶的编码基因 (ldhA) 和丙酮酸-甲酸裂解酶的编码基因 (pflB) 的工程菌,厌氧条件下由于辅酶NAD(H) 的不平衡导致其丧失了代谢葡萄糖的能力。构建了苹果酸脱氢酶的重组菌大肠杆菌NZN111/pTrc99a-mdh,在厌氧摇瓶发酵过程中通过0.3 mmol/L的IPTG诱导后重组菌的苹果酸脱氢酶 (Malate dehydrogenase,MDH) 酶活较出发菌株提高了14.8倍,NADH/NAD+的比例从0.64下降到0.26,同时NAD+和NADH浓度分别     

DctA- and Dcu-independent transport of succinate in Escherichia coli: contribution of diffusion and of alternative carriers

Quintuple mutants of Escherichia coli deficient in the C(4)-dicarboxylate carriers of aerobic and anaerobic metabolism (DctA, DcuA, DcuB, DcuC, and the DcuC homolog DcuD, or the citrate/succinate antiporter CitT) showed only poor growth on succinate (or other C(4)-dicarboxylates) under oxic conditions. At acidic pH (pH 6) the mutants regained aerobic growth on succinate, but not on fumarate. Succinate uptake by the mutants could not be saturated at physiological succinate concentrations (< or =5 mM), in contrast to the wild-type, which had a K(m) for succinate of 50 microM and a V(max) of 35 U/g dry weight at pH 6. At high substrate concentrations, the mutants showed transport activities (32 U/g dry weight) comparable to that of the wild-type. In the wild-type using DctA as the carrier, succinate uptake had a pH optimum of 6, whereas succinate uptake in the mutants was maximal at pH 5. In the mutants succinate uptake was inhibited competitively by monocarboxylic acids. Diffusion of succinate or fumarate across phospholipid membranes (liposomes) was orders of magnitude slower than the transport in the wild-type or the mutants. The data suggest that mutants deficient in DctA, DcuA, DcuB, DcuC, DcuD (or CitT) contain a carrier, possibly a monocarboxylate carrier, which is able to transport succinate, but not fumarate, at acidic pH, when succinate is present as a monoanion. Succinate uptake by this carrier was inhibited by addition of an uncoupler. Growth by fumarate respiration (requiring fumarate/succinate antiport) was also lost in the quintuple mutants, and growth was not restored at pH 6. In contrast, the efflux of succinate produced during glucose fermentation was not affected in the mutants, demonstrating that, for succinate efflux, a carrier different from, or in addition to, the known Dcu and CitT carriers is used.     

Succinate synthesis and excretion by Penicillium simplicissimum under aerobic and anaerobic conditions

Succinate is an interesting chemical for industries producing food and pharmaceutical products, surfactants, detergents and biodegradable plastics. Succinate is produced mainly by a mixed-acid fermentation process using anaerobically growing bacteria. However, succinate excretion is also widespread among fungi. In this article we report results on the intracellular concentration and the excretion of succinate by Penicillium simplicissimum under aerobic and anaerobic conditions. The intracellular concentration of succinate increased slightly with the specific growth rate and strongly if the respiratory chain was inhibited by sodium azide or anaerobic conditions (N(2)). A strong increase of succinate excretion was observed if the respiratory chain was inhibited. It is suggested that succinate synthesis under functional (sodium azide) or environmental (N(2)) anaerobic conditions occurs via the reductive part of the tricarboxylic acid cycle. Succinate is then excreted because the oxidative part of the tricarboxylic acid cycle is inactive. A possible role of succinate synthesis in the regeneration of NAD ('fumarate respiration') is discussed.     

过量表达异柠檬酸裂解酶对ldh-1谷氨酸棒状杆菌产丁二酸的影响

谷氨酸棒状杆菌SA001是缺失了乳酸脱氢酶基因 (ldhA) 的菌株。为了增加厌氧条件下经异柠檬酸到丁二酸的代谢通量,以提高丁二酸的产量。将来自大肠杆菌Escherichia coli K12的异柠檬酸裂解酶基因导入谷氨酸棒状杆菌SA001 (SA001/pXMJ19-aceA) 中。该菌经0.8 mmol/L的IPTG有氧诱导12 h后,转入厌氧发酵16 h,丁二酸的产量为10.38 g/L,丁二酸的生产强度为0.83 g/(L·h)。与出发菌株比较,异柠檬酸裂解酶的酶活提高了5.8倍,丁二酸的产量提高了48%。结果表明过量表达异柠檬酸裂解酶可以增加由乙醛酸途径流向丁二酸的代谢流。