Incompatibility behavior of a symbiotic plasmid pMH7653Rb in Mesorhizobium huakuii 7653R.

Mesorhizobium huakuii strain 7653R harbored two indigenous plasmids named pMH7653Ra and pMH7653Rb. The larger plasmid pMH7653Rb (symbiotic plasmid) was transferred to M. huakuii HN308SR harboring three plasmids: pMHHN308a, pMHHN308b and pMHHN308c, and HN3015SR harboring three plasmids: pMHHN3015a, pMHHN3015b and pMHHN3015c by tri-parent mating. Two stable indigenous plasmids, pMHHN308b and pMHHN308c of HN308SR, were co-eliminated due to the introduction of pMH7653Rb, and the transconjugant was named HN308SRN14. The results implied that pMH7653Rb and pMHHN308b, pMHHN308c were incompatible and might have been ascribed to the same incompatible group. The plasmid profiles of transconjugant HN3015SRN14 showed that the second largest plasmid pMHHN3015b of HN3015SR was cured due to the introduction of pMH7653Rb. The results also implied that pMH7653Rb and pMHHN3015b were incompatible. Results from plant nodulation tests showed that pMH7653Rb could only maintain the nodulation ability in transconjugant HN308SRN14 and its nodule number was more than that of wild strain HN308SR, but could not replace the nitrogen fixation effect of pMHHN308b and pMHHN308c. The plasmid cured mutant HN308SRN14D harboring only pMHHN308a formed null nodules that demonstrated pMHHN308a was relevant to nodulation ability. HN3015SRN14 harboring pMH7653Rb, pMHHN3015a and pMHHN3015c formed null nodules while HN3015SRN14D containing pMHHN3015a and pMHHN3015c lost the nodulation ability. The plasmid replication repC-like gene sequences were detected by a polymerase chain reaction from 7653R, HN308, HN3015, HN308SRN14 and HN3015SRN14. The repC gene sequence similarities of the strains tested attained 99%.

Effects of the purL gene expression level on the competitive nodulation ability of Sinorhizobium fredii.

Purine pathway in Rhizobium is important during the nodulation processes. The purL gene in Sinorhizobium fredii (S. fredii) has been identified to be required for the whole establishment of a nitrogen-fixing nodule. To get a better understanding of the purL gene's impacts on Rhizobium-plant interaction, the competitive nodulation abilities of S. fredii containing different purL expression plasmids were studied. Several kinds of coinoculations were performed, including using different bacterial concentration ratios, with or without the supplementation of purine source in the plant nutrient solution, and the delayed coinoculation tests. The results indicated that the competitive nodule occupancy of S. fredii was affected significantly by the purL expression level during the early nodulation periods. The mutant strain containing no purL expression could not elicit competitive nodules both in the presence and absence of purine source. A positive linear correlation within certain limits was observed between strain's competitive nodule occupancy and purL gene expression level. All these results suggested that the purL gene played a role in the competitive nodulation of S. fredii.

BacA is indispensable for successful Mesorhizobium-Astragalus symbiosis.

A homologue of Sinorhizobium meliloti bacA was isolated from Mesorhizobium huakuii 7653R, which is capable of fixing atmospheric nitrogen in symbiotic association with leguminous Astragalus sinicus (Chinese milk vetch). Inactivation of the bacA gene abolished the ability of M. huakuii 7653R to establish a successful symbiosis with its host plant. Simultaneously, compared with wild-type M. huakuii 7653R, the bacA mutant was more sensitive to cell envelope-disrupting agents (acidic solution, ethanol, SDS, and crystal violet). Mass spectrometry analysis revealed that the very-long-chain fatty acid (27-OHC-28:0 and 29-OHC-30:0) contents of lipid A was reduced in the M. huakuii 7653R bacA mutant. Taken together, our data suggest that the cell envelope was altered in the M. huakuii 7653R bacA mutant, which might deteriorate bacterial adaption to acute environmental changes encountered in host cells and ultimately result in the failure of Mesorhizobium-legume symbiosis.

Genetic diversity of root-nodulating bacteria isolated from pea (Pisum sativum) in subtropical regions of China.

Diversity of 42 isolates from effective nodules of Pisum sativum in different geographical regions of China were studied using 16S rRNA gene RFLP patterns, 16S rRNA sequencing, 16S-23S rRNA intergenic spacer (IGS) region RFLP patterns and G-C rich random amplified polymorphic DNA (RAPD). The isolates were distributed in two groups on the basis of their 16S rRNA gene RFLP patterns. The 16S rRNA gene sequences of strains from 16S rRNA gene RFLP patterns group I were very closely related (identities higher than 99.5%) to Rhizobium leguminosarum USDA 2370. Group II consisting of WzP3 and WzP15 was closely related to Rhizobium etli CFN42. The analysis of the 16S-23S IGS RFLP patterns divided the isolates into 18 genotypes and four groups. Group I was clustered with R. leguminosarum USDA2370. Group II consisted of YcP2, YcP3 and CqP7. The strains of group III were distributed abroad. Group IV consisted of WzP3, WzP15 and R. etli CFN42. RAPD divided the isolates into nine clusters in which group IV only consisted of YcP2 and the strains of group V and IX were from Wenzhou and Xiantao, respectively. This assay demonstrated the geographical effect on genetic diversity of pea rhizobia.

A nodule-specific plant cysteine proteinase, AsNODF32, is involved in nodule senescence and nitrogen fixation activity of the green manure legume Astragalus sinicus.

Asnodf32, encoding a nodule-specific cysteine proteinase in Astragalus sinicus, is probably involved in nodule senescence. To obtain direct evidence of its role in nodule senescence, Agrobacterium rhizogenes-mediated RNA interference was applied to A. sinicus hairy roots. Real-time qRT-PCR was used to estimate the efficiency of suppression. The senescent phenotype of transgenic nodules was examined with paraffin-embedded slides, TUNEL (TdT-mediated dUTP nick-end labeling) assay, and transmission electron microscopy, and the bacteroid nitrogen fixation activity was also measured. It was found that silencing of Asnodf32 delayed root nodule and bacteroid senescence. The period of bacteroid active nitrogen fixation was significantly extended. Interestingly, nodules enlarged in length were also observed on Asnodf32-silenced hairy roots. The results reported here indicate that Asnodf32 plays an important role in the regulation of root nodule senescence.

The function of three indigenous plasmids in Mesorhizobium huakuii 2020 and its symbiotic interaction with Sym pJB5JI of Rhizobium leguminosarum.

A Mesorhizobium huakuii strain 2020, isolated from a rice-growing field in southern China, contains three indigenous plasmids named p2020a, p2020b and p2020c, respectively. The plasmids were deleted via Tn5-sacB insertion, and two cured derivatives were obtained. Interestingly, the mutant 2020D29 curing of p2020c could significantly enhance the capacity of symbiotic nitrogen fixation. But the mutant 2020D8 curing of p2020b lost the ability to nodulate Astragalus sinicus. Furthermore, the third plasmid p2020a could be hardly eliminated, suggesting that some house-keeping genes necessary for strain growth located on this plasmid. Then the Sym plasmid pJB5JI of R. leguminosarum bv. viciae was transferred into 2020 and its cured derivatives. The pot plant test showed that the ability of competition and symbiotic nitrogen fixation of transconjugant 2020-137 (pJB5JI) was increased evidently in contrast to 2020. pJB5JI could not restore the ability of 2020D8 to nodulate Astragalus sinicus. 2020D8-8 (pJB5JI) could form ineffective nodules on peas, which implied that the symbiotic plasmid pJB5JI could express its function at the chromosomal background of Mesorhizobium huakuii 2020. The plasmid stability was checked in transconjugants under free-living and during symbiosis. The results indicated that pJB5JI failed to be detected in some nodule isolates. That Km resistance gene could be amplified from all transconjugants and nodule isolates suggested that pJB5JI was fully or partially integrated into the chromosome of recipients.

Cloning and identification of lpsH, a novel gene playing a fundamental role in symbiotic nitrogen fixation of Mesorhizobium huakuii.

Mesorhizobium huakuii 7653R forms a symbiotic relationship with Astragalus sinicus to produce nitrogen-fixing root nodules under nitrogen-limiting conditions. By screening its transposon-inserted mutant library, a mutation in the lpsH gene was found to form pseudonodules on A. sinicus. Its effect was further confirmed by double-crossover mutant HK242. DNA sequence analysis revealed that the lpsH gene encodes a deduced protein of 397 amino acids with a predicted molecular mass of 43.6 kD. LpsH contains a putative signal peptide, 11 transmembrane helices, and an O-antigen polymerase domain, which locates on the periplasmic membrane and is necessary to lipopolysaccharide synthesis. Plant studies showed that the lpsH gene mutant formed ineffective nodules, and this symbiotic phenotype was linked to abnormal nodule development.

The symbiosis phenotype and expression patterns of five nodule-specific genes of Astragalus sinicus under ammonium and salt stress conditions.

In previous works, we isolated 14 nodule-specific or nodule-enhanced genes from Astragalus sinicus by suppressive subtractive hybridization. In this study, we have further identified the expression patterns of five nodule-specific genes of A. sinicus under salt and ammonium stress. Transcription levels of genes tested were quantified by quantitative fluorescence real-time RT-PCR. Results showed that: (1) About 80 mM NaCl and all stress treatments containing (NH(4))(2)SO(4) significantly inhibited nitrogen-fixing capacity of inoculated plants. About 40 mM NaCl showed relative lighter inhibition. (2) Compare with positive control at normal conditions, the expressions of all genes were significantly reduced by all ammonium stress. (3) Under salt stress without exogenous nitrogen, transcription levels of AsIIA255 and AsE246 were significantly increased after treatment for 3 days. But expressions of AsG2411, AsIIC2512, and AsB2510 were suppressed by 80 mM NaCl and not significantly affected by 40 mM NaCl. (4) Under salt stress with exogenous nitrogen, expressions of AsG2411, AsIIC2512, AsB2510, and AsIIA255 were significantly suppressed. While, the transcription level of AsE246 under 80 mM NaCl containing 1 mM (NH(4))(2)SO(4) was still higher than that of positive control. The correlation of the expression profiles of three cysteine cluster protein (CCP) genes (AsG2411, AsIIC2512, AsIIA255) and one lipid transfer protein (LTP) gene (AsE246) with the nitrogen-fixing capacities of nodules in each treatments may explain the molecular mechanisms of their supposed functions in symbiosis and nitrogen-fixing process. Our results also implied that AsIIA255 and AsE246 might play a role in the response of A. sinicus to salt stress to facilitate the nitrogen-fixation process.

A novel nodule-enhanced gene encoding a putative universal stress protein from Astragalus sinicus.

A nodule-enhanced gene, AsD243, was identified from infected roots of Astragalus sinicus using suppressive subtractive hybridization (SSH). It encodes a 20-kD protein related to the bacterial universal stress protein family (Usp). Sequence analysis showed that AsD243 is highly similar to the bacterial MJ0577-type of ATP-binding Usp proteins, which have been proposed to function as a molecular switch. Expression analyses revealed that AsD243 was transcribed in all plant organs, and progressively during all stages of nodulation. Its transcripts increased significantly at 7 days after inoculation, which is 2 days later than the onset of leghemoglobin expression in A. sinicus nodules. AsD243 was expressed more strongly in mature roots than in young roots regardless of inoculation status. We suggest that the AsD243 may have other functions in plant processes besides nodulation.

Thirteen nodule-specific or nodule-enhanced genes encoding products homologous to cysteine cluster proteins or plant lipid transfer proteins are identified in Astragalus sinicus L. by suppressive subtractive hybridization.

Thirteen nodule-specific or nodule-enhanced genes have been revealed by suppressive subtractive hybridization (SSH) with two mRNA populations of infected and uninfected control roots of Astragalus sinicus. Eleven of them encode small polypeptides showing homology to cysteine cluster proteins (CCPs) that contain a putative signal peptide and conserved cysteine residues. Among these CCP-like genes, AsG257 codes for a homologue of the defensin 2 family and AsD255 contains a scorpion toxin-like domain at the C-terminus. Sequence analysis of a genomic AsD255 fragment which was isolated revealed that one intron separates the first exon encoding the signal peptide from the second exon encoding the cysteine cluster domain of this nodulin. Another two genes, AsE246 and AsIB259, encode two different products similar to lipid transfer proteins (LTPs). Virtual northern blot and reverse transcription-polymerase chain reaction (RT-PCR) analysis indicated that the other genes except AsIB259 and AsC2411 were expressed exclusively in inoculated roots and that their expression was 2-4 d later than that of the leghaemoglobin (Lb) gene during nodule development. Transcription of AsIB259 was also detected in uninfected control roots but with a significant decline in expression and a temporal expression similar to Lb. AsC2411 had a basal expression in control roots identified by RT-PCR. Sequence alignment showed that the putative proteins AsE246 and AsIB259 show lower homology with LTPs from legumes than with those from other plants.

[Genetic diversity and phylogeny of soybean bradyrhizobia isolated from south and north region of China].

Studies on genetic diversity and phylogeny of soybean bradyrhizobia isolated from south and north region of China were investigated through 16S rRNA gene PCR RFLP, 16S rRNA gene sequencing and 16S-23S rRNA IGS PCR RFLP assays. Results of 16S rRNA gene PCR RFLP and 16S rRNA gene sequencing analysis reveal that strains tested are ascribed into Bradyrhizobium japonicum and B. elkanii species. B. japonicum is the dominant species and accounts for 91% of strains tested, but B. elkanii just up to 9%, which shows poor genetic diversity. Results of 16S-23S rRNA IGS PCR RFLP assays reveal that strains belonged to B. japonicum can be divided into Group I and Group HIIat the 69 similarity. Group I consists of strains from northern China, and Group 1I consists of strains from southern China, which demonstrates geographical effect on genetic diversity of bradyrhzobia. Results of 16S-23S rRNA IGS PCR RFLP further reflects that strains of Group I and Group II are phylogenetically different with type or representative strains USDA6, USDA110 and USDA122 of B. japonicum.

Symbiotic abilities of Sinorhizobium fredii with modified expression of purL.

Previous reports showed that a transposon-induced PurL- mutant of Sinorhizobium fredii induced pseudonodules on Glycine max and the addition of 5-aminoimidazole-4-carboxamide-riboside or adenine to the plant could not restore the mutant to establish effective symbiosis. To gain a better understanding of the impact of the purL gene on symbiosis formation, we measured the effect of modified expression of this gene on the symbiotic abilities of S. fredii on soybean (G. max). A 1.98-kb in-frame deletion mutant in the purL gene of S. fredii was constructed. Transcriptional modification of the purL gene was conducted using several promoters such as those of lac, nifH, nifQ, and fixN. It was found that reduced expression of purL gene or suitable symbiotic expression of purL (such as with the promoter nifH or nifQ) can efficiently establish symbiosis of S. fredii on G. max without the exogenous supplementation of any adenine or purine precursor; at least a minimal level of expression of purL is essential for effective symbiosis with soybean.

[Studies on genetic diversity and phylogeny of slow-growing rhizobia isolated from Vigna radiata at main ecotypes of China].

Studies on genetic diversity and phylogeny of slow-growing rhizobia isolated from Vigna radiata at main ecotypes of China were conducted by using 16S rRNA gene PCR-RFLP, 16S rRNA gene sequencing and 16S-23S rRNA IGS PCR-RFLP assays. Results of 16S rRNA gene PCR RFLP analysis reveal that all the strains tested are clustered into three groups at the similarity of 76%. Group I contains 13 slow-growing rhizobia tested including LYG1; Group II consists of 21 strains tested and the type strains of B. japonicum and B. liaoningense, and 10 tested strains isolated from Guangdong, Guangxi and the type strain of B. elkanii compose Group III . The results of 16S-23S rRNA IGS PCR-RFLP show that strains tested could be divided into A and B groups, which could be correspondently subdivided into A I , A II , AIII , BI and B II subgroups at the similarity of 85% . Compared with 16S rRNA PCR-RFLP, IGS RFLP assay show higher resolution, strains and reference strains tested can be divided into 21 IGS RFLP patterns. The strains isolated from Xinjiang, Guangdong and Guangxi regions show obvious geographical effect on genetic diversity.

Apparent incompatibility of plasmid pSfrYC4b of Sinorhizobium fredii with two different plasmids in another strain.

Sinorhizobium fredii YC4B is a spontaneous mutant derivative of strain YC4 that is unable to nodulate soybeans. The second-largest plasmid of strain YC4B, termed pSfrYC4b (810 kb), was transferred to S. fredii HN01SR, a strain which contains three large indigenous plasmids (pSfrHN01a, pSfrHN01b and pSfrHN01c). Surprisingly, two stable indigenous plasmids (pSfrHN01a and pSfrHN01b) of strain HN01SR were cured simultaneously by the introduction of pSfrYC4b. Furthermore, a novel, unstable plasmid (pHY4) became visible in agarose gels. The electrophoretic mobility of plasmid pHY4 was slower than that shown by the cured plasmids, indicating that the molecular weight of the former is higher than that of plasmids pSfrYC4b and pSfrHN01b. Replication gene repC-like sequences were detected by polymerase chain reaction (PCR) on pSfrHN01a and pSfrYC4b, but not on pSfrHN01b. Sau3AI and PstI restriction patterns of the PCR-amplified repC-like sequences from HN01SR and YC4B were very similar.

Effect of nisin on the growth of Staphylococcus aureus determined by a microcalorimetric method.

A novel microcalorimetric technique based on the bacterial heat output was applied to evaluate the biological effect of nisin on the growth of Staphylococcus aureus. The thermogenic curves of S. aureus in the presence of nisin were studied by an LKB-2277 Thermal Activity Monitor. The thermokinetic parameters, such as the growth rate constant (k), the generation times (G), the inhibitory ratio (I), and the half inhibitory concentration (IC50), for the growth of S. aureus at different nisin concentrations were determined. The relationship between the growth rate constant (k) and the concentration of nisin (c) is nearly linear, which can be modeled by the formula k = 0.03794 - 4.005 x 10(-4) x c, with a correlation coefficient of -0.9971. Based on this model, we obtained the critical inhibitory concentration of nisin on the growth of S. aureus at 94.73 IU/mL. We proposed that this microcalorimetric method could be a useful tool in monitoring the biological effect of nisin on microorganisms, and providing valuable information on the study of microorganism metabolisms.

[Effects of bkdAB interruption on avermectin biosynthesis].

In this study, Streptomyces avermitilis Bjbm0006 which produces four avermectin B components was used as an original test strain. A replacement plasmid containing a gene cluster bkdAB (branched-chain alpha-keto acid dehydrogenase gene) involved in the biosynthesis of avermectin B in S. avermitilis Bjbm0006 was constructed by means of PCR technique and then named as pHJ5821 (pHZ1358::bkdAB&erm). A recombinant strain Bjbm5821 was obtained after the gene cluster was interrupted by double crossover. This strain was tested in laboratory conditions and analysed by PCR using the total DNA as template. The HPLC analysis showed that the strain Bjbm5821 synthesized the same 'a' components Bla and B2a as the original strain did. However, It lost the ability for the production of 'b'components for example B1b and B2b. A novel compound was detected in fermentation products. The results of present study suggests that the production of gene cluster bkdAB may play a main role similar to alpha-ketoisovaleric acid dehydrogenase in the pathway of avermectin synthesis.

[Root colonization and nodulation of Sinorhizobium fredii HN01DL in Glycine max rhizosphere].

Rhizobox-soil microcosms studies on the colonization, dispersal and nodulation of Sinorhizobium fredii HN01DL marked with luxAB gene in Glycine max rhizosphere showed that the colonization dynamics and the density of HN01DL in non-sterilized rhizobox-soil microcosms were different from those in sterilized rhizobox-soil microcosms. The colonization density of the former reached the maximum (8.65 log cfu.g-1 root) 12 days after the coated seeds planted, and that of the latter decreased rapidly at the early stage and achieved the maximum (6.88 log cfu.g-1 root) 15 days afterwards. Furthermore, the colonization density of HN01DL reached the maximum (7.05 log cfu.g-1 root) in section A (0-4 cm) of root system 5 days after seeds planted, decreased slowly and kept a relative stable level until 19 days, and began to rise up again 33 days afterwards. The strain could also disperse to the place of 16 cm from seed to root tip by 46 days after seed planted. HN01DL maintained a constantly higher colonization density level in section A of root system, formed the largest number of luminescent nodules (total 16.3, dominantly located in main root of section A), and had the highest luminescent percentage (68.8%). The luminescent nodule percentage decreased gradually along section A to E of root system, and no luminescent nodule was detected in section E of root system.

[Effect of Sinorhizobium fredii YC4 symbiotic plasmid amplification on nod factors and symbiotic N-fixation].

Sinorhizobium fredii YC4 can form nitrogen-fixing nodules on soybean (Glycine max) and wild soybean (G. soja). It can produce unique lipochitooligosaccharide nod factors (LCOs), in comparison with the other four strains of S. fredii. The constitution of LCOs produced by YC4 contained more hydrophobic substitutions detected by Thin-layer chromatography (TLC) of 14C-labeled nod factors. A spontaneous mutant termed YSC3 amplified in the symbiotic plasmid was isolated from YC4, which can produce more amount of LCOs than its parental strain at 28 degrees C, and showed a difference in the construction of LCOs. Nodulation test indicated that YSC3 only formed ineffective nodules on soybean G. soja.

[A study of the effects on the symbiotic nitrogen fixation of Sinorhizobium fredii with the introduction of dctABD and nifA genes].

A recombinant plasmid pHN307 containing C4-dicarboxylic acid transport genes (dctABD) from Sinorhizobium meliloti, nifA genes from Klebsiella pneumoniae and reporter genes luxAB from pDB30 was constructed by using pTR102 as the vector. The pHN307 was then introduced into the S. fredii HN01, YC4 and GR3 by tri-parental mating, and the stability of pHN307 in the transconjugants under free-living and symbiotic condition was also investigated. The results of plant pot experiment indicated that the introduction of pHN307 in the transconjugants could significantly increase the nodule fresh weight, shoot dry weight (biomass) and total nitrogen content of the symbiotic plants with soybean variety of Heilong 33. When the transconjugants were in symbiotic with soybean variety of Chuanzao No. 1, HN01 (pHN307) could significantly increase its root nodule number and fresh weight; GR3 (pHN307) could significantly increase its root nodule number, nodule fresh weight, shoot dry weight and total nitrogen content, but YC4(pHN307) demonstrated negative effect under the same condition. The results of this study suggested that the introduction of dctABD and nifA could improve the symbiotic nitrogen fixation efficiency and nodulation ability of the rhizobia tested, respectively, and its effect was relevant to the characteristics of recipient rhizobia and soybean variety.

[Genetic diversity and phylogeny of rhizobia isolated from peanut (Arachis hypogaea)].

Forty three rhizobium strains isolated from peanut (Arachis hypogaea) and 15 reference strains from other genus and species were analyzed by the method of 16S rRNA RFLP, 16S rRNA sequencing and 16S-23S IGS PCR RFLP. The results of the 16S rRNA RFLP shown that 43 strains tested were all ascribed to the genus of Bradyrhizobium phylogenetically. Strains tested were adjacent to the B. japonicum and far from B. elkanii 16S rRNA genotype. The genotypes generated by the 4 restriction endonucleases, Mbo I, Dde I, Hae III and Msp I, were same as the representatives of B. japonicum. The dendrogram generated by 16S rRNA sequence and Neighbor-joining method shown that peanut rhizobia clustered into the subcluster represented by B. japonicum and B. liaoningense, were more close to B. liaoningense genetically, and the sequence difference between them was less than 1%. High sequence similarity was also determined between B. liaoningense and B. japonicum. JZ1, representative strain of peanut rhizobia were systematically far from the B. elkanii, and the sequence divergence about 2%. The results from IGS RFLP analysis indicated that although they were phylogenetically close to B. japonicum and B. elkanii, peanut rhizobia forming an independent group at the similarity of 71% could be further divided into four subgroups, A, B, C and D. Subgroup A consisted of strains from different region, subgroup B was composed of strains from Wuchang, Qianjiang and Jingzhou, subgroup C was mainly composed of strains from Jingzhou and starins of subgroup D mainly from Neijiang. Reference strains from B. japonicum and B. elkanii were independently clustered into the subgroup E at the similarity of 71%. The geographical factor effect on genetic diversity of rhizobia was found.