适合龟裂链霉菌~(13)C代谢通量分析合成培养基的优化及应用

为开发一种适合龟裂链霉菌13C代谢通量分析的合成培养基,以龟裂链霉菌模式菌株M4018为研究对象,比较其在各种有机氮源和无机氮源的生长和土霉素合成特性。首次筛选到以硝酸钾为主要氮源的合成培养基,通过响应面分析法进一步优化,将土霉素合成能力由75.2 mg/L提高到145.6 mg/L。并应用到100%的1-13C葡萄糖标记实验,首次从同位素标记代谢流分析上证实了龟裂链霉菌中不存在2-酮-3-脱氧-6-磷酸葡糖酸裂解途径(Entner-Doudoroff pathway,ED),为龟裂链霉菌13C代谢通量分析提供了重要基础。     

基于前体供给途径遗传改造提高褐黄孢链霉菌纳他霉素的产量

纳他霉素(natamycin)是一种高效、广谱、安全的抗真菌剂,广泛应用于食品防腐与医药领域。纳他霉素可由多种链霉菌发酵产生。它是以乙酰辅酶A、丙二酰辅酶A及甲基丙二酰辅酶A为前体经Ⅰ型聚酮合酶(polyketide synthase,PKS)催化合成的多烯大环内酯类化合物。本研究以纳他霉素产生菌——褐黄孢链霉菌为研究材料,分别对不同前体分子供给途径中的关键酶进行过表达,并确定影响纳他霉素产量的关键前体供给途径。研究结果发现：通过过表达乙酰辅酶A合成酶(acetyl-CoA synthase,ACS)加强乙酰辅酶A合成途径,以及通过过表达甲基丙二酰辅酶A变位酶(methylmalonyl-CoA mutase,MCM)加强甲基丙二酰辅酶A合成途径,重组菌株纳他霉素产量分别比野生型菌株提高了44.19%和20.51%。共过表达ACS和MCM,重组菌株纳他霉素产量获得进一步提升(达1123.34mg/L),比野生型菌株提高了66.29%。上述发现为通过前体代谢工程的策略构建纳他霉素工业高产菌株提供了参考,也为其他聚酮类天然产物高产工程菌株的构建提供了借鉴。     

龟裂链霉菌zwf2基因阻断提高土霉素生物合成

葡萄糖-6-磷酸脱氢酶(G6PDH)是链霉菌磷酸戊糖途径中第一个酶("看家"酶),也是形成NADPH的关键酶,由zwf1和zwf2基因编码.以温敏型质粒pKC1139为基础构建了用于阻断龟裂链霉菌zwf2的重组质粒pKC1139-zwf2',通过大肠杆菌GM2929去甲基化pKC1139-zwf2'后电转至原始龟裂链霉菌M4018感受态细胞,筛选得到转化子.转化子进一步通过PCR鉴定和点杂交印迹分析鉴定,证明是zwf2基因阻断的阳性突变子命名为M4018-△zwf2.以原始菌株为对照,突变子摇瓶发酵结果表明:突变子的葡萄糖-6-磷酸脱氢酶酶活是原始菌的50%左右,但土霉素生物合成水平则提高了27%;在细胞生长方面,二者均在第4d进入生长稳定期而开始大量合成土霉素,发酵结束时细胞菌体浓度基本相同,但突变子的单位菌丝体土霉素生物合成能力则提高了31%.因此,zwf2的阻断有利于土霉素的生物合成,而对细胞生长没有明显影响.     

异源重构白色链霉菌土霉素生产菌株

【目的】土霉素(oxytetracycline,OTC)属于第一代四环素类抗生素,对革兰氏阳性菌和阴性菌具有很好的抑菌效果,目前主要应用于畜牧业、水产养殖业和作为原料药生产二代、三代四环类抗生素。因此,在生产上具有提高产量、降低成本的迫切需求。为了解决工业菌株改造中面临着遗传操作比较困难、周期长的问题,我们通过异源重构白色链霉菌(Streptomyces albus) Del14并作为底盘生产菌株,进而评估该菌株OTC生物制造细胞工厂的潜力。【方法】通过理性工程重构,获得一系列衍生菌株Del14:Oxy、Del14:Oxy1K、Del14:Oxy1KΔotrR、Del14B:Oxy1KΔotrR。对上述菌株进行摇瓶发酵以及HPLC检测发酵产物;通过RT-qPCR检测OTC生物合成基因簇(otc cluster)相关结构基因的转录水平。【结果】S. albus Del14生长快、不结球,对OTC具有一定的耐受性。通过操纵簇内调控因子OtcR和OtrR,最终使重组菌株Del14B:Oxy1KΔotrR OTC产量在第6天达到了1.1 g/L,与原始生产菌株龟裂链霉菌(S. rimosus) M4018在第8天产量相当。【结论】本研究首次在S. albus Del14中异源表达了土霉素生物合成基因簇,初步证实了一个很有潜力的OTC生物制造底盘,为这一OTC生产菌株的进一步优化改造奠定了基础。     

刺糖多孢菌中铵载体蛋白基因amtS的克隆及功能研究

目的:铵离子是细胞内合成各种核酸、氨基酸和辅助因子等含氮化合物的重要原料之一。微生物细胞膜上的铵载体蛋白介导了铵离子的转运。通过异源表达刺糖多孢菌中铵载体蛋白基因,研究其对链霉菌产孢能力和次级代谢产物产量的影响。方法:从刺糖多孢菌S04-41菌株中克隆铵载体蛋白基因amt S,通过接合转移导入天蓝色链霉菌M145和变铅青链霉菌TK24中,分析比较amt S基因的异源表达对其产孢能力和次级代谢产物产量的影响。结果:天蓝色链霉菌重组菌株M145/p MF-amt S和变铅青链霉菌重组菌株TK24/p MF-amt S中放线紫红素的产量分别提高了2.85倍和30.02倍。结论:刺糖多孢菌中的铵载体蛋白能够提高链霉菌中次生代谢产物的产量,为进一步研究该基因的功能与对刺糖多孢菌中多杀菌素合成的作用奠定了重要基础。     

挖掘与调控乙酸胁迫响应基因提高重组酿酒酵母合成番茄红素水平

【背景】乙酰辅酶A是酿酒酵母异源合成番茄红素的重要中间产物,胞质中乙酰辅酶A主要来自乙酰辅酶A合成酶催化乙酸合成。【目的】通过外源添加乙酸盐结合调控乙酸胁迫应答基因增加胞内乙酰辅酶A含量,改善细胞生长,促进番茄红素合成。【方法】在合成番茄红素的重组酵母菌中过表达乙酰辅酶A合成酶编码基因(acs2),在发酵过程中添加10g/L乙酸盐,结合转录组学分析挖掘乙酸胁迫响应基因,进行单一和组合调控。【结果】添加乙酸盐后,重组菌Y02中番茄红素含量增加了19.14%,但细胞生长受到抑制,转录组学结果表明adk2、fap7、hem13、elo3、pdc5、set5、pmt5、hst4、clb2和swe1表达水平增加,因此构建了单基因和双基因过表达菌株,其中Y02-set5-hst4菌在添加乙酸盐后细胞生长得到了显著改善,同时胞内乙酰辅酶A浓度提高了78.21%,番茄红素含量和产量达到12.62 mg/g-DCW和108.67 mg/L,与对照菌Y02相比分别提高了42.76%和67.13%。同时该菌中甲羟戊酸途径中关键基因erg12、erg20和hmg1的表达量与对照菌相比分别上调了1.70、1.4...     

植物中的乙酰辅酶A羧化酶(AACase)

介绍乙酰辅酶A羧化酶（ACCase）的结构与功能．表达和调控、编码基因克隆及其基因工程的研究进展。     

地中海拟无枝菌酸菌U32中生物素羧基载体蛋白结构基因的克隆、表达及转录

乙酰辅酶A羧化酶(Acetyl CoA Carboxylase EC 6.4.1.2, ACC)催化依赖于ATP的乙酰辅酶A羧化形成丙二酸单酰辅酶A,该反应是脂肪酸生物合成途径中的第一步,也是受到调控的关键一步。根据结核分枝杆菌(M. tuberculosis)和天蓝色链霉菌(S. coelicolor)中ACC-α亚基的氨基酸保守序列和地中海拟无枝菌酸菌U32对氨基酸密码子的使用偏好,设计简并引物以U32基因组DNA为模板扩增出一条约250bp的片段,并以此片段作探针成功地从U32基因组cosmid文库中克隆到相应的ACC-α亚基的编码基因accA。该基因对应的ORF长1797bp,编码一个598个氨基酸的蛋白,推算出的分子量是63,714Da;基因G+C mol%含量为70.1%,符合U32基因结构特征,距起始密码子GTG上游6个碱基处有链霉菌典型的RBS序列AGGAGG,并有生物素羧化酶特征的ATP结合区。利用pET28(b)系统构建表达载体,在E. coli BL21(DE3)中实现了accA的诱导表达,产物大部分以可溶形式存在,并通过Western Blot证明该蛋白上确有共价结合的生物素。Northern Blot分析了各种氮源对accA基因转录水平的不同影响。     

酿酒酵母产苹果酸的还原TCA路径构建及发酵调控

苹果酸广泛应用于食品、化工行业。文中通过在酿酒酵母内敲除丙酮酸脱羧酶PDC1,并通过构建胞质内还原TCA的路径,即超表达丙酮酸羧化酶和苹果酸脱氢酶,成功地实现了苹果酸的生产。在野生型菌株中基本检测不到苹果酸的生成,而在工程菌株,苹果酸发酵浓度达到了45 mmol /L,同时副产物乙醇的产量也降低了18%。进一步通过发酵调控提高第二信使Ca2+的浓度使苹果酸的产量提高了7 %,在此基础上提高丙酮酸羧化酶的辅酶生物素浓度,使苹果酸的产量达到52.5 mmol /L,较原始菌株提高了16%。     

亮氨酰氨肽酶基因的阻断对刺糖多孢菌生长及次级代谢产物合成的影响

【目的】构建亮氨酰氨肽酶基因(pep A)被阻断的刺糖多孢菌工程菌株,并鉴定该基因对刺糖多孢菌菌丝形态、生物量、菌体全蛋白表达水平及产多杀菌素能力的影响,探究该基因调控多杀菌素合成的可能机制。【方法】利用PCR扩增刺糖多孢菌中的pep A基因同源片段,经酶切连接技术构建敲除载体p OJ260-pep A;通过接合转移和单交换同源重组将该载体整合至刺糖多孢菌染色体中,获得工程菌株S.sp-△pep A;利用培养特征、形态学、高效液相色谱、SDS-PAGE等方法对菌株进行研究分析。【结果】工程菌株S.sp-△pep A菌丝片段化程度加剧,生长态势被延缓且生物量降低,但有效促进了多杀菌素的生物合成。阻断亮氨酰胺肽酶基因的表达使刺糖多孢菌菌体全蛋白表达情况发生明显改变,找到表达水平显著上调的差异蛋白核糖体蛋白亚基和醛基脱氢酶,核糖体蛋白亚基通过影响蛋白质代谢对菌体生长产生影响;醛基脱氢酶则可与乙醇脱氢酶、乙酰辅酶A的合成酶相互作用影响辅酶A合成,而辅酶A是合成多杀菌素的重要底物。【结论】在刺糖多孢菌合成多杀菌素的次级代谢过程中,pep A基因作为负调控因子发挥作用。     

Improvement of oxytetracycline production mediated via cooperation of resistance genes in Streptomyces rimosus

Increasing the self-resistance levels of Streptomyces is an effective strategy to improve the production of antibiotics.To increase the oxytetracycline(OTC) production in Streptomyces rimosus,we investigated the cooperative effect of three co-overexpressing OTC resistance genes:one gene encodes a ribosomal protection protein(otrA) and the other two express efflux proteins(otrB and otrC).Results indicated that combinational overexpression of otrA,otrB,and otrC(MKABC) exerted a synergetic effect.OTC production increased by 179%in the recombinant strain compared with that of the wild-type strain M4018.The resistance level to OTC was increased by approximately two-fold relative to the parental strain,thereby indicating that applying the cooperative effect of self-resistance genes is useful to improve OTC production.Furthermore,the previously identified cluster-situated activator OtcR was overexpressed in MKABC in constructing the recombinant strain MKRABC;such strain can produce OTC of approximately7.49 g L~((-1)),which represents an increase of 19%in comparison with that of the OtcR-overexpressing strain alone.Our work showed that the cooperative overexpression of self-resistance genes is a promising strategy to enhance the antibiotics production in Streptomyces.     

Molecular cloning and functional characterization of an ATP-binding cassette transporter OtrC from Streptomyces rimosus

ABSTRACT: BACKGROUND: The otrC gene of Streptomyces rimosus was previously annotated as an oxytetracycline (OTC) resistance protein. However, the amino acid sequence analysis of OtrC shows that it is a putative ATP-binding cassette (ABC) transporter with multidrug resistance function. To our knowledge, none of the ABC transporters in S. rimosus have yet been characterized. In this study, we aimed to characterize the multidrug exporter function of OtrC and evaluate its relevancy to OTC production. RESULTS: In order to investigate OtrC's function, otrC is cloned and expressed in E. coli The exporter function of OtrC was identified by ATPase activity determination and ethidium bromide efflux assays. Also, the susceptibilities of OtrC-overexpressing cells to several structurally unrelated drugs were compared with those of OtrC-non-expressing cells by minimal inhibitory concentration (MIC) assays, indicating that OtrC functions as a drug exporter with a broad range of drug specificities. The OTC production was enhanced by 1.6-fold in M4018 (P = 0.000877) and 1.4-fold in SR16 (P = 0.00973) duplication mutants, while it decreased to 80% in disruption mutants (P = 0.0182 and 0.0124 in M4018 and SR16, respectively). CONCLUSIONS: The results suggest that OtrC is an ABC transporter with multidrug resistance function, and plays an important role in self-protection by drug efflux mechanisms. This is the first report of such a protein in S. rimosus, and otrC could be a valuable target for genetic manipulation to improve the production of industrial antibiotics.     

Actinomyces rimosus resistance to oxytetracycline

High frequency of spontaneous and UV-and acridine dye-induced variants susceptible to oxytetracycline (OTC) and deprived of the capacity for synthesizing this antibiotic was observed in strain LST-118 of Actinomyces rimosus. The cells of strain LST-118 of Act. rimosus contained extrachromosomal DNA not found in its OTC susceptible variant BS87, which provides evidence in favour of participation of the extrachromosomal genetic elements in control of OTC resistance of the cells of Act. rimosus, LST-118. The OTC resistance in strain LST-118 is of inducable character. The resistance level is increasing from the beginning of the antibiotic synthesis and initially the subinhibitory concentrations of OTC in the medium were the inductors triggering cellular mechanisms ensuring resistance of the cell to the increasing concentrations of OTC in the medium. The capacity for absorption of OTC in Act rimosus is 2--3 times lower than that in E. coli. The experiments with labeled tetracycline showed that the cells of the actinomycete absorbed OTC when it was present in the medium. The absorption of the main amount of the antibiotic was registered during the first 5 minutes. The difference in absorption of OTC by the cells of the antibiotic resistant and sensitive strains was insignificant.     

The variation of antioxidant defense system of Streptomyces sp. M4018 with respect to carbon sources

The effect of glycerol, glucose, and starch as carbon sources on the antioxidant defense system such as superoxide dismutase (SOD) and catalase (CAT) activities, pyruvate levels, and membrane lipid peroxidation (LPO) levels of Streptomyces sp. M4018, after isolation from the rhizosphere samples of Colutea arborescens and identification as a strain of S. hiroshimensis based on phenotypic and genotypic characteristics, were investigated. As an antioxidant defense enzyme, SOD activities increased up to 20 g/L of glycerol and 15 g/L of starch, while they showed negative correlation with glucose concentration. CAT activity variations of glycerol- and glucose-supplemented mediums showed significant positive correlations with the trend of SOD activities. However, CAT activity, in contrast to SOD, in Streptomyces sp. M4018 tended to decrease as the starch concentration increased. The production of pyruvate increased with respect to glycerol and starch up to 15 g/L, while it was positively correlated with glucose concentration. The highest pyruvate production was seen at 20 g/L glucose. Membrane LPO levels were negatively correlated with the activities of SOD and CAT enzymes, and the minimum LPO level was determined at 5 g/L of glucose, where SOD and CAT activities reached their maximum levels. Nevertheless, the higher SOD and CAT activities in a wider range of incubation period compared to the beginning by resulting in insignificant increases in membrane LPO levels showed the unusual antioxidant response capacities of the in Streptomyces sp. M4018 against the potentially deleterious effects of reactive oxygen species (ROS) for glycerol, glucose, and starch as carbon sources.     

Pathway engineering of Escherichia coli for α-ketoglutaric acid production

α-Ketoglutaric acid (α-KG) is a multifunctional dicarboxylic acid in the tricarboxylic acid (TCA) cycle, but microbial engineering for α-KG production is not economically efficient, due to the intrinsic inefficiency of its biosynthetic pathway. In this study, pathway engineering was used to improve pathway efficiency for α-KG production in Escherichia coli. First, the TCA cycle was rewired for α-KG production starting from pyruvate, and the engineered strain E. coli W3110Δ4-PCAI produced 15.66 g/L α-KG. Then, the rewired TCA cycle was optimized by designing various strengths of pyruvate carboxylase and isocitrate dehydrogenase expression cassettes, resulting in a large increase in α-KG production (24.66 g/L). Furthermore, acetyl coenzyme A (acetyl-CoA) availability was improved by overexpressing acetyl-CoA synthetase, leading to α-KG production up to 28.54 g/L. Finally, the engineered strain E. coli W3110Δ4-P_(H)CAI_(H)A was able to produce 32.20 g/L α-KG in a 5-L fed-batch bioreactor. This strategy described here paves the way to the development of an efficient pathway for microbial production of α-KG.     

Streptomyces rimosus M4018 中氧化应激转录抑制因子Rex的克隆表达及与rex 操纵子的体外结合活性

【目的】为了研究龟裂链霉菌Streptomyces rimosus M4018中的rex基因对自身rex operator(ROP)的调控机制。【方法】根据天蓝色链霉菌Streptomyces coelicolor A3(2)中rex基因的同源序列设计引物进行PCR,从S.rimosus M4018中获得其rex基因(Sr-rex)。同时,通过染色体步移的方法,获得其上游的ROP序列。采用体外凝胶迁移的方法,分析了Sr-Rex对ROP的调控作用。【结果】获取的Sr-rex基因核苷酸序列长度为846 bp,预测的编码氨基酸序列与S.coelicolor A3(2)中Rex的同源性为84%,获得GenBank登录号:GQ849479。圆二色光谱显示Sr-Rex的结构以α螺旋和β折叠为主,与软件预测相符。凝胶迁移实验表明,Sr-Rex能与S.rimosus M4108中扩增到的ROP片段特异性结合。同时,以Rex:ROP的最小结合序列为基础,设计了一条22 bp的单链DNA片段,和Sr-Rex的最大结合摩尔浓度比约为5:1。高浓度的NADH抑制两者的结合活性,而NAD+对结合没有影响。【结论】在S.rimosus M4108中,Rex是通过响应胞内NAD(H)水平的方式来调控ROP的表达的。     

Precursor formation and biosynthesis of the macrolide antibiotic a 6599 (turimycin) by streptomyces hygroscopicus JA 6599]

The possible role of some metabolic systems producing acetyl-CoA, and methylmalonyl-CoA as initial precursors in the biosynthesis of the macrolide antibiotic A 6599 by Streptomyces hygroscopicus JA 6599 was studied. The activities of pyruvate decarboxylase exceeded in two higher producing strains about twofold those found in the mycelium of a lower producing one suggesting that in this organism an enhanced production of acetyl-CoA should be one of the prerequisites necessary for an improved antibiotic biosynthesis. No clear interrelationship was established, however, between the biosynthesis of the secondary metabolite A 6599 on the one hand and the acetate and propionate kinase content on the other hand. In S. hygroscopicus JA 6599 the carboxylation of acetyl-CoA or propionyl-CoA seems to be the major pathway giving malonyl-CoA or methylmalonyl-CoA, respectively. Thus, the activities of acetyl-CoA and propionyl-CoA carboxylases corresponded with both the levels of antibiotic production in several strains and with variations observed in the specific antibiotic production rate during the cultivation. Some other pathways synthesizing these precursors, e.g. via oxaloacetate, are assumed to be negligible since even in the mycelium of the lower producing strain increased activities of phosphoenolpyruvate carboxylase were present.