A general method for site-directed mutagenesis in prokaryotes

The genetic analysis of genes from prokaryotic species for which experimental genetic systems have not yet been developed is often limited by the difficulty of producing mutations in those genes. We report here a general technique applicable to Gram-negative prokaryotes for site-directed mutagenesis of cloned DNA fragments which we have applied to the study of the symbiotic nitrogen fixation genes of Rhizobium meliloti. In particular, we mutagenized cloned R. meliloti restriction fragments in Escherichia coli with transposon Tn5 and then replaced the wild-type parental DNA sequences with the mutant DNA sequences in the R. meliloti genome. Using this method we show that an R. meliloti DNA restriction fragment, cloned previously on the basis of homology to Klebsiella pneumoniae nif genes, contains gene(s) essential for symbiotic nitrogen fixation. In addition, we use this method to construct a physical genetic map of a subset of the R. meliloti nif genes.     

豆科植物-根瘤菌共生固氮的分子机理

与豆科植物－根瘤菌共生固氮有关的基因涉及根瘤菌基因和宿主基因，根瘤菌基因有结瘤基因（nodD,nodAB-CIJ和hsn基因），根瘤菌细胞表面结构基因（exs,lps和ndv基因）和固氮基因（nif和fix基因）；宿主基因主要是结瘤素基因（ENOD和NOD基因）。根瘤菌结瘤基因表达后诱导产生结瘤因子。在根瘤发育过程中，这些基因在根瘤菌与植物之间进行着信息交换，并且具有不同的表达水平。结瘤因子和植物激素对它们进行着调节。     

Activation of extra copies of genes coding for nitrogenase in Rhodopseudomonas capsulata

Biological nitrogen fixation requires the nitrogenase enzyme complex, ATP, and a strong reductant. Klebsiella pneumoniae contains 15 linked nitrogen fixation (nif) genes, three of which, nifH, nifD and nifK have been sufficiently conserved in evolution that cloned K. pneumoniae nifHDK DNA will hybridize to DNA sequences from every nitrogen-fixing bacterium examined to date, including the purple, non-sulphur bacterium Rhodopseudomonas capsulata, in which one complete nifHDK operon has been mapped. Using cloned K. pneumoniae nifHDK DNA we report here that R. capsulata contains multiple copies of the genes for nitrogenase components. Two regions containing sequences homologous to all three nif structural genes have been identified, and mutations in one region produced a Nif- phenotype. Nif+ pseudorevertants were derived from these mutants, some of which retained the original mutation suggesting that some of the extra nif gene sequences can be functionally activated.     

Regulation of nitrogen metabolism genes by nifA gene product in Klebsiella pneumoniae

The Klebsiella pneumoniae nifA gene product, which is known to activate expression of the nitrogen fixation (nif) structural genes, is shown here also to be able to substitute for the product of the gene glnG (ntrC) in the regulation of other nitrogen metabolism genes. An evolutionary relationship between the nifA and glnG genes is suggested.     

Sinorhizobium meliloti nifA gene exerts a pleiotropic effect on nodulation through the enhanced plant defense response

Sinorhizobium meliloti nifA gene is required for the expression of a bunch of nif and fix genes. Here, we report its pleiotropic effects on the nodule formation. Compared with wild type strain, nifA mutant sig- nificantly reduced nodule suppression rate in split-root system. The plants inoculated with mutant strain produced lower amount of daidzein and less necrotic cells on their roots. In addition, the defense genes failed to be evoked by nifA mutant at the early nodulation stage. These findings indicated that host defense response was one of the mechanisms mediated by nifA gene to regulate nodule formation during symbiosis. Even though nifA mutant could increase the number of nodules in host plant, it synthesized lower Nod factors than wild type. This suggested that nifA gene mediated multiple and diverse instances in nodulation formation.     

Extra-copy nifA enhances the nodulation efficiency of Sinorhizobium fredii

Previous investigations have shown that nifA gene is involved in nodulation and symbiotic nitrogen fixation regulation of Rhizobium. We study the role of nifA on nodulation of leguminous plants. We found that Sinorhizobium fredii harboring multi-copy plasmid carrying the constitutively expressed Klebsiella pneumoniae nifA exhibited an increase of noduiation activity and nodulation competitiveness on soybean plants. The Nod-factor secreted by the rhizobia cells containing the multi-copied nifA was assayed,and preliminary results showed that S. fredii containing the multi-copy plasmid carrying nifA produced higher strength of Nod-factor than the rhizobia containing the same plasmid carrying the vector did.     

Characterization of root-nodulating bacteria on Retama raetam in arid Tunisian soils

The aim of this study is to investigate the diversity of Retama raetam root-nodule bacteria isolated from arid regions of Tunisia. Twelve isolates, chosen as representative for different 16S rRNA gene patterns, were characterized by 16S rRNA gene sequencing and phenotypic analysis. Isolates were assigned to Sinorhizobium, Rhizobium and Agrobacterium. Symbiotic properties of Sinorhizobium and Rhizobium isolates showed a large diversity in their capacity to infect their host plant and fix atmospheric nitrogen. Strain RK 22 identified as Rhizobium was the most effective isolate.     

Rearrangement of nitrogen fixation genes during heterocyst differentiation in the cyanobacterium Anabaena

Nitrogen fixation by the cyanobacterium Anabaena is carried out in heterocysts, specialized, non-dividing cells which differentiate under conditions of ammonia or nitrate deprivation. In Anabaena, heterocyst differentiation is accompanied by rearrangement of some nitrogen fixation genes. A site-specific recombination between an 11 base-pair direct repeat sequence flanking the nifK and nifD genes removes 11 kilobases of intervening DNA, resulting in juxtaposition of the two genes and an alteration of the nifD protein-coding sequence.     

ATP sulphurylase activity of the nodP and nodQ gene products of Rhizobium meliloti

The symbiotic bacterium Rhizobium meliloti stimulates alfalfa (Medicago sativa L.) roots to undergo morphogenesis and form nitrogen-fixing nodules. It has been proposed that the bacterial genes nodABC, common to all Rhizobium, are required for synthesis of an oligosaccharide factor, which is converted to a sulphated form (NodRm-1) by the products of the R. meliloti-specific genes nodH and nodQ1-5; NodRm-1 elicits host-specific plant responses. Previously we have shown that the nodP gene is homologous to a segment of the Escherichia coli genome; when we cloned this E. coli fragment we found that it mapped near 59 minutes, corresponding to the cysDNC locus. The genes cysD and cysN encode proteins that catalyse the synthesis of adenosine 5'-phosphosulphate, the first step in the activation of inorganic sulphate. Here we demonstrate that nodP and nodQ correspond to cysD and cysN, and that their proteins have ATP sulphurylase activity both in vivo and in vitro. We propose that nodP and nodQ synthesize an activated sulphate that is an intermediate in the formation of the alfalfa-specific sulphated nodRm-1 factor.     

Different recombination site specificity of two developmentally regulated genome rearrangements

In the absence of a combined nitrogen source, such as ammonia, approximately every tenth vegetative cell along filaments of the cyanobacterium Anabaena develops into a heterocyst, a terminally differentiated cell that is morphologically and biochemically specialized for nitrogen fixation. At least two specific DNA rearrangements involving the nitrogen-fixation (nif) genes occur during heterocyst differentiation, one within the nifD gene and the other near the nifS gene. The two rearrangements have several properties in common. Both occur quantitatively in all heterocyst genomes, both occur at approximately the same developmental time, late in the process of heterocyst differentiation, and both result from site-specific recombination between short repeated DNA sequences. We report here the nucleotide sequences found at the site of recombination near the nifS gene. These sequences differ from those found previously for the nifD rearrangement, suggesting that the two rearrangements are catalysed by different enzymes and may be regulated independently. We also show that the nifS gene is transcribed only from rearranged genomes.     

Exogenous cAMP upregulates the expression of glnII and glnK-amtB genes in Sinorhizobium meliloti 1021

Sinorhizobium meliloti is a soil-borne bacterium that can lead a symbiosis life with leguminous host plants. Successful symbiont establishment requires specific recognition and progressive differentiation of both bac- teria and host cells. Once inside the plant cells of root nodules, the bacteria differentiate into non-dividing cells called bacteroids. Bacteroids obtain carbon source from the plant and, in return, they provide the plant with ammonium, and/or amino acid, as fixed nitrogen. Sign…     

Transcriptome analysis of Sinorhizobium meliloti nodule bacteria in nifA mutant background

Sinorhizobium meliloti is one genus of gram-nega- tive soil bacteria that can fix atmospheric nitrogen in root nodules of its symbiotic leguminous host plants[1]. Specific recognition and progressive differentiation ofboth bacteria and host cells are requ…     

Symbiotic host-specificity of Rhizobium meliloti is determined by a sulphated and acylated glucosamine oligosaccharide signal

Rhizobia are symbiotic bacteria that elicit the formation on leguminous plants of specialized organs, root nodules, in which they fix nitrogen. In various Rhizobium species, such as R. leguminosarum and R. meliloti, common and host-specific nodulation (nod) genes have been identified which determine infection and nodulation of specific hosts. Common nodABC genes as well as host-specific nodH and nodQ genes were shown recently, using bioassays, to be involved in the production of extracellular Nod signals. Using R. meliloti strains overproducing symbiotic Nod factors, we have purified the major alfalfa-specific signal, NodRm-1, by gel permeation, ion exchange and C18 reverse-phase high performance liquid chromatography. From mass spectrometry, nuclear magnetic resonance, (35)S-labelling and chemical modification studies, NodRm-1 was shown to be a sulphated beta-1,4-tetrasaccharide of D-glucosamine (Mr 1,102) in which three amino groups were acetylated and one was acylated with a C16 bis-unsaturated fatty acid. This purified Nod signal specifically elicited root hair deformation on the homologous host when added in nanomolar concentration.     

The enoyl-ACP reductase gene, <Emphasis Type="Italic">fabI1</Emphasis>, of <Emphasis Type="Italic">Sinorhizobium meliloti</Emphasis> is involved in salt tolerance,swarming mobility and nodulation efficiency

Our previous work showed that an enoyl-ACP reductase gene fabI1 of Sinorhizobium meliloti was down-regulated in the nifA mutant nodule bacteria. To gain a better understanding of fabI1 gene, a single site insertion mutant was constructed in this study. The fabI1 mutant was retarded in cell growth, and its ability to grow on media with high concentration of NaCl was reduced. In addition, the mutant was completely defective in swarming phenotype. During symbiosis, the fabI1 mutant had delayed nodule formation...     

大豆和花生根瘤菌氢酶的研究

根瘤菌在共生固氮过程中因放H2所消耗的能量约占固所氮总能量的40%-6%。吸氢酶则能回收和利用固氮过程所放的H2,养活能量损失,从而提高共生固氮效率。在厌氧条件下,加入防止酶蛋白聚合的试剂,利用DEAE-纤维素和Sephacry S-200柱层析,从自养性大豆根瘤菌和花生根瘤菌类菌体中分离并提纯膜结合态氢酶。纯化的两种氢酶表现相近的分子特征：均含有大（60kD,65kD)、小（30kD,35kD)两个亚基,均为NiFe-氢酶,并且有较高的吸H2活性。大豆根瘤菌氢酶的纯酶组分不含Cyt b599。花生根瘤菌L8-3菌株能进行化能自养生长,诱导出高吸H2活性。根瘤菌的吸H2能明显提高固氮活性。从具有高吸H2活性的花生根瘤菌中分离并克隆吸氢基因,采用PCR和探针杂交技术,获得含有吸氢基因的质粒pZ-55。利用多种限制性内切酶构建了质粒pZ-55的物理图谱。通过三亲本杂交,将含吸氢基因的重组质粒转移到不吸H2的花生和毛豆根瘤菌中,所获得的结合株在自生和共生条件下均表达吸H2活性。以结合株接种大田花生,获得的共生根瘤的吸H2活性比接种受体株提高4倍,花生叶片和种子的含N量、产量分别提高1.7%、8.9%和9.6%。