细菌双杂交系统的应用和改进

细菌双杂交系统是新近建立的一种研究蛋白质间相互作用的方法。应用细菌双杂交系统可以研究环境因子对固氮调节蛋白NifL和NifA相互作用的影响。但实验结果中发现有假阳性的干扰。对照组大肠杆菌DHP1（cya^-）菌株,只含有产生T18－NifL或T25-NifL一种融合蛋白的质粒,也可导致菌株β－半乳糖苷酶活性的上升或生长在MacConkey/麦芽糖平板上菌落呈浅红色的假阳性结果。改用薄层层析法检测菌体抽出液中特异性的钙调蛋白依赖型腺苷酸环化酶活性,结果显示这一改进可排除细菌双杂交系统中可能出现的假阳性。     

Control of autogenous activation of Herbaspirillum seropedicae nifA promoter by the IHF protein

Analysis of the expression of the Herbaspirillum seropedicae nifA promoter in Escherichia coli and Herbaspirillum seropedicae, showed that nifA expression is primarily dependent on NtrC but also required NifA for maximal expression under nitrogen-fixing conditions. Deletion of the IHF (integration host factor)-binding site produced a promoter with two-fold higher activity than the native promoter in the H. seropedicae wild-type strain but not in a nifA strain, indicating that IHF controls NifA auto-activation. IHF is apparently required to prevent overexpression of the NifA protein via auto-activation under nitrogen-fixing conditions in H. seropedicae.     

肺炎克氏杆菌nifA基因在巴西固氮螺菌固氮基因表达的铵调节中的作用

固氯螺菌(Azospirillum)是一类仅在限铵和微好氧条件下固氮的微生物,它可与许多禾本科作物联合共生⑴,具有较大的应用潜力。铵作为固氮作用的调节信号,在固氮螺菌的实际应用中是首要的限制因素。在固氯螺菌中,铵不但具有与肺炎克氏杆菌(Klebsiella pneumoniae)相似的阻遏固氮酶合成的作用,而且还对已合成的固氮酶进行活性调节⑵。研究表明,其固氮酶翻译后活性调节的机制类似于深红红螺菌(Rhodospirillum rubrum)⑶,即在有铵条件下其固氮酶铁蛋白的一个亚基被共价修饰而丧失活性,这一过程是可逆的。由于铵在固氮螺菌中双水平地调节固氮作用,使得在野生菌株中研究其固氮基因表达水平上的调节较为困难。Zhang等⑷利用区域定位诱变技术获得了巴西固氮螺菌Sp7（A．Brasilense Sp7)的draT-突变株,在该突变株中铵不再影响固氮酶的活性,这为其固氮基因表达调节的研究提供了一个良好的材料。本文将组成型表达的肺炎克氏杆菌nifA基围引入该突变株中,通过分析讨论铵对巴西固氮螺菌固氮基固表达的调节作用方式。     

肺炎克氏杆菌NifA对巴西固氮螺菌nifH启动子的转录激活作用

用PR方法克隆了巴西固氮螺菌Yu62 nifH的启动子片段,DNA序列分析表明菌株Yu62与标准菌株sp7之间的DNA序列差异很小。利用启动子探针质粒载体pcBl82,构建了3个不同的nifH：：lacz转录融合质粒,在大肠杆菌中分别测定肺炎克氏杆菌NifA对它们的转录激活作用。结果表明巴西固氮螺菌nifH启动子的转录是依赖于NifA的,缺失了上游激活序列的启动子不能被NifA激活转录,肺炎克氏杆菌NifA对其自身nifH及巴西固氮螺菌nifH启动子的转录激活作用并无很大差异。     

Regulation of nitrogen fixation in Azospirillum brasilense Sp7: Involvement of nifA, glnA and glnB gene products

The expression of nifA-, niH- and nifB-lacZ fusions was examined in different mutants of Azospirillum brasilense. Mutations in nifA, glnA and glnB severely impaired the expression of nifH- and nifB-lacZ fusions. By contrast, a nifA-lacZ fusion was not affected in a nifA or a glnB background and was only partially impaired in glnA mutants. It is proposed that in A. brasilense, the PII protein and glutamine synthetase are involved in a post-translational modification of NifA.     

Characterization of the ntrBC genes of Azospirillam brasilense Sp7: Their involvement in the regulation of nitrogenase synthesis and activity

A 7.1 kb EcoRI fragment from Azospirillum brasilense, that hybridized with a probe carrying the ntrBC genes from Bradyrhizobium japonicum, was cloned. The nucleotide sequence of a 3.8 kb subfragment was established. This led to the identification of two open reading frames, encoding polypeptides of 401 and 481 amino acids, that were similar to NtrB and NtrC, respectively. A broad host range plasmid containing the putative Azospirillum ntrC gene was shown to restore nitrogen fixation under free-living conditions to a ntrC-Tn5 mutant of Azorhizobium caulinodans. Several Tn5 insertion mutants were isolated in the ntrBC coding region in A. brasilense. These mutants were prototrophic and Nif⁺. However, their nitrogenase activity was slightly lower than in the wild type and they were unable to grow on nitrate as sole nitrogen source. Under microaerobiosis and in the absence of ammonia, a nifA-lacZ fusion was expressed in the mutants at about 60% of the level in the wild type. In the presence of ammonia, the fusion was similarly expressed (60% of the maximum) both in the wild type and mutants. Addition of ammonia to a nitrogen-fixing culture of ntrBC mutants did not abolish nitrogenase activity, in contrast with the wild type. It thus appears that in Azospirillum the ntrBC genes are not essential for nitrogen fixation, although NtrC controls nifA expression to some extent. They are, however, required for the switch-off of nitrogenase activity.