Nutrient loading alters the performance of key nutrient exchange mutualisms

Nutrient exchange mutualisms between phototrophs and heterotrophs, such as plants and mycorrhizal fungi or symbiotic algae and corals, underpin the functioning of many ecosystems. These relationships structure communities, promote biodiversity and help maintain food security. Nutrient loading may destabilise these mutualisms by altering the costs and benefits each partner incurs from interacting. Using meta‐analyses, we show a near ubiquitous decoupling in mutualism performance across terrestrial and marine environments in which phototrophs benefit from enrichment at the expense of their heterotrophic partners. Importantly, heterotroph identity, their dependence on phototroph‐derived C and the type of nutrient enrichment (e.g. nitrogen vs. phosphorus) mediated the responses of different mutualisms to enrichment. Nutrient‐driven changes in mutualism performance may alter community organisation and ecosystem processes and increase costs of food production. Consequently, the decoupling of nutrient exchange mutualisms via alterations of the world's nitrogen and phosphorus cycles may represent an emerging threat of global change.     

A new perfusion system for the measurement and characterization of potential rates of soil nitrification

The effect of two isoflavonoids, coumestrol and daidzein which are present in aseptically grown roots and root exudates of soybean, was tested on some rhizospheric microorganisms. It was found that coumestrol promotes the growth ofR. japonicum USDA 138 (about 30%) andR. leguminosarum (about 15%) whereas it inhibits the growth ofAgrobacterium tumefaciens (about 50%) andPseudomonas sp. (about 20%). The following microorganisms were unaffected by this molecule:R. japonicum W505,Agrobacterium radiobacter, Micrococcus luteus andCryptococcus laurentii. It was found that daidzein promotesR. japonicum USDA 138 growth (about 20%) and inhibitsPseudomonas sp. growth (about 20%); other microorganisms were unaffected. In addition, coumestrol favoured the formation of ‘coccoids’ cells byRhizobium japonicum USDA 138 which could be the infective state of this strain. It seems that this compound is able to help nodulation of soybean by aRhizobium strain. This result supports the work of Peterset al. (1986) and Redmondet al. (1986) who show that flavones present in plant exudates induces expression of nodulation genes in Rhizobium.     

Iron uptake and metabolism in the rhizobia/legume symbioses

Iron-containing proteins figure prominently in the nitrogen-fixing symbioses between bacteria of the genera Azorhizovium, Bradyrhizobium and Rhizobium and their respective plant hosts. Although iron is abundant in the soil, the acquisition of iron is problematic due to its low solubility at biological pH under aerobic conditions. The study of iron acquisition as it pertains to these economically important symbioses is directed at answering three questions: 1) how do rhizobial cells acquire iron as free-living microorganisms where they must compete for this nutrient with other soil inhabitants 2) how do the plant hosts acquire enough iron for the symbiosis and 3) how do rhizobia acquire iron as symbionts? Production and/or utilization of ferric-specific ligands (siderophores) has now been documented in the laboratory for a number of rhizobial species, but there is limited information on whether production and/or untilization occurs either in the soil or in planta. Studies with rhizobial mutants which can no longer produce and/or utilize siderophores should address whether siderophores contribute to functional symbioses. In addition, the ability to produce and/or utilize siderophores may affect the outcome of both interstrain and interspecific competition in the rhizosphere and in bulk soil. Some progress has been made at documenting the effects of iron deficiency on nodule development. Studies are also underway to determine whether, in addition to its central structural role, iron may also play a regulatory role in the symbioses. This review is an attempt to give an overview of the field, and hopefully will stimulate further research on the iron nutrition of these symbioses which account for such a significant proportion of the world's biologically fixed nitrogen.     

Horizontal gene transfer and recombination shape mesorhizobial populations in the gene center of the host plants Astragalus luteolus and Astragalus ernestii in Sichuan, China

Thirty-three rhizobial strains isolated from the root nodules of Astragalus luteolus and Astragalus ernestii growing on the west plateau at two different altitudes in Sichuan province, China, were characterized by amplified rDNA restriction analysis (ARDRA), amplified fragment length polymorphism (AFLP), and by sequencing of rrs, glnA, glnII and nifH . The ARDRA analysis revealed considerable genomic diversity. In AFLP analysis, 20 of 33 Astragalus rhizobia formed three distinct clades, with others dispersed into different groups with the reference strains. Phylogenetic analysis of the rrs gene of six representative strains showed that the isolates were members of the genus Mesorhizobium . Three of the isolates formed a sister clade to Mesorhizobium loti and Mesorhizobium ciceri , whereas the other three formed a sister clade to a clade harboring the species Mesorhizobium huakuii, Mesorhizobium plurifarum, Mesorhizobium septentrionale and Mesorhizobium amorphae , indicating the existence of two new species. Phylogenetic analysis of glnA and glnII confirmed the rrs phylogenies for four strains, but the trees were incongruent. The nifH sequences of the strains formed a monophyletic clade and were typical of those of mesorhizobia forming symbioses with inverted repeat lacking clade legume species. The incongruent phylogenies of the genes studied suggest that horizontal gene transfer and recombination shape mesorhizobial populations in the gene center of the host plants.     

Novel putative Mesorhizobium and Ensifer genomospecies together with a novel symbiovar psoraleae nodulate legumes of agronomic interest grown in Tunisia

Forty rhizobial strains were isolated from Lotus creticus, L. pusillus and Bituminaria bituminosa endemic to Tunisia, and they belonged to the Mesorhizobium and Ensifer genera based on 16S rDNA sequence phylogeny. According to the concatenated recA and glnII sequence-based phylogeny, four Bituminaria isolates Pb5, Pb12, Pb8 and Pb17 formed a monophyletic group with Mesorhizobium chacoense ICMP14587^T, whereas four other strains Pb1, Pb6, Pb13 and Pb15 formed two separate lineages within the Ensifer genus. Among the L. pusillus strains, Lpus9 and Lpus10 showed a 96% identical nucleotide with Ensifer meliloti CCBAU83493^T; whereas six other strains could belong to previously undescribed Mesorhizobium and Ensifer species. For L. creticus strains, Lcus37, Lcus39 and Lcus44 showed 98% sequence identity with Ensifer aridi JNVU TP6, and Lcus42 shared a 96% identical nucleotide with Ensifer meliloti CCBAU83493^T; whereas another four strains were divergent from all the described Ensifer and Mesorhizobium species. The analysis of the nodC gene-based phylogeny identified four symbiovar groups; Mesorhizobium sp. sv. anthyllidis (Lpus3 and Lpus11 from L. pusillus, Lcus43 from L. creticus), Ensifer medicae sv. meliloti (four strains from L. creticus and two strains from L. pusillus), E. meliloti sv. meliloti (four from L. creticus, four from L. pusillus and four from B. bituminosa). In addition, four B. bituminosa strains (Pb5, Pb8, Pb12, and Pb17) displayed a distinctive nodC sequence distant from those of other symbiovars described to date. According to their symbiotic gene sequences and host range, the B. bituminosa symbionts (Pb5, Pb8, Pb12 and Pb17) would represent a new symbiovar of M. chacoense for which sv. psoraleae is proposed.     

Intrinsic antibiotic resistance and streptomycin uptake in cowpea rhizobia

Abstract Uptake of [³H]dihydrostreptomycin in sensitive and resistant strains of cowpea rhizobia was examined to explain one of the possible mechanisms of intrinsic antibiotic resistance. The rate of accumulation of labelled streptomycin in resistant strains was drastically reduced when compared to that of sensitive strains. Our results indicated that high levels of intrinsic antibiotic resistance was due to decreased permeability causing failure to accumulate the drug.     

我国主要生态区域绿豆慢生根瘤菌的遗传多样性和系统发育研究

利用16SrRNAPCR-RFLP、16SrRNA序列分析以及16S-23SrRNAIGS(IntergeneticSpacer)PCR-RFLP技术对分离自中国主要生态区域的44株慢生型绿豆根瘤菌和5株参比菌株进行了遗传多样性和系统发育研究。16SrRNAPCR-RFLP分析表明:在76%的相似水平上,所有供试菌株可分为三大类群:群I由LYG1等13株慢生根瘤菌组成,该群在系统发育上与B.japonicum和B.liaoningense的参比菌株存在一定的差异;群Ⅱ由XJ1等21株供试菌株、B.japonicum和B.liaoningense的代表菌株组成;群Ⅲ由10株来自广东和广西的菌株和B.elkanii的代表菌株组成。16S-23SrRNAIGSPCR-RFLP分析将供试菌株分为A、B两大群。群A由34株供试菌株、B.japonicum和B.liaoningense的代表菌株组成。在85%的相似性水平上,可再分为AⅠ、AⅡ和AⅢ3个亚群。群B由10株分离自广西和广东的菌株和B.elkanii的代表菌株组成。在85%的相似性水平上,可再分为BI和BⅡ两亚群,表现出一定的多样性。与16SrRNAPCR-RFLP相比,16S-23SrRNAIGSPCR-RFLP具有更高的解析度,供试菌株表现出更加丰富的遗传多样性。分离自中国新疆、广东和广西等地的菌株在分群上具有较为明显的地域特征。     

Denitrification ability of rhizobial strains isolated from Lotus sp.

Ten rhizobial strains isolated from Lotus sp. have been characterized by their ability to denitrify. Out of the 10 strains, the five slow-growing isolates grew well under oxygen-limiting conditions with nitrate as a sole nitrogen source, and accumulated nitrous oxide in the growth medium when acetylene was used to inhibit nitrous oxide reductase activity. All five strains contained DNA homologous to the Bradyrhizobium japonicum nirK, norBDQ and nosZ genes. In contrast, fast-growing lotus rhizobia were incapable of growing under nitrate-respiring conditions, and did not accumulate nitrous oxide in the growth medium. DNA from each of the five fast-growing strains showed a hybridization band with the B. japonicum nirK gene but not with norBDQ and nosZ genes. Partial 16S rDNA gene sequencing revealed that fast-growing strains could be identified as Mesorhizobium loti species and the slow-growers as Bradyrhizobium sp.     

斜茎黄芪根瘤菌结瘤基因nodA PCR扩增及PCR-RFLP分析

对采自我国北方地区的16株斜茎黄芪根瘤菌代表菌株的共同结瘤基因nodA进行了PCR扩增及PCR-RFLP分析研究。来自Mesorhizobium和Rhizobium系统发育分支的代表菌株都得到了nodA PCR扩增产物;而来自Agrobacterium系统发育分支的代表菌株都没有得到nodA PCR扩增产物。进一步的nodAPCR-RFLP分析结果表明斜茎黄芪根瘤菌具有很大的nodA基因遗传多样性,具有4种不同的16S rDNAPCR-RFLP遗传图谱类型的12株斜茎黄芪根瘤菌具有8种不同的nodA PCR-RFLP遗传图谱类型。但是斜茎黄芪根瘤菌nodA基因遗传多样性随种群而变化,来自M.septentrionale的具有相同的16S rDNA PCR-RFLP遗传图谱类型的4个代表菌株具有4种不同的nodA PCR-RFLP遗传图谱类型;而来自M.tempera-tum的具有相同的16S rDNA PCR-RFLP遗传图谱类型3个代表菌株则具有相同的nodA PCR-RFLP遗传图谱类型。此外,来自不同种的具有不同16S rDNA PCR-RFLP遗传图谱类型的菌株却具有相同的nodA PCR-RFLP遗传图谱类型,说明nodA基因可能在根瘤菌的不同种间发生了水平转移。