The effectiveness of some Indonesian strains of Rhizobium on four tropical legumes

Nodules were collected from 14 legume species from the Indonesian Islands of South Sulawesi, Java and Sumatra. Their rhizobia were isolated and growth characteristics, nodulation ability and nitrogen fixing effectiveness were assessed against recommended commercially available Australian strains. The test legumes wereMacroptilium atropurpureum Urb. cv. Siratro,Vigna unguiculata (L.) Walp. cv Eureka,Centrosema pubescens Benth cv. Belalto andDesmodium heterocarpon (L) DC. A significant portion of the native rhizobial isolates were of the fast growing type. Dry matter and total nitrogen production forM. atropurpureum andV. unguiculata was highest when inoculated with native strains while the commerical strains produced superior dry matter production forC. pubescens andD. heterocarpon. However the total nitrogen production of native and commercial strains was not significantly different for the latter two legumes. The study indicated that a potential exists for developing inocula from local Rhizobium strains.     

The effectiveness and competitiveness of some Indonesian Rhizobium strains on tropical legumes grown in four soil types of Java

Several Indonesian and some imported Rhizobium strains were assessed for their effectiveness in nodulating four legume species in four soil types of Java. Naturally occurring Rhizobia formed effective symbioses onVigna unguiculata, Macroptilium atropurpureum andDesmodium heterocarpon in all four soils and the applied strains, with some exceptions, did not infect a majority of nodules of these legumes.Centrosema pubescens was more specific in its Rhizobia requirements and applied strains formed effective symbioses in two clay soils, but not in two sandy loam soils.     

Correlation between NaCl Sensitivity of Rhizobium Bacteria and Ineffective Nodulation of Leguminous Plants

A sodium chloride (NaCl)-sensitive mutant of Rhizobium fredii USDA191, which contained a single copy of Tn5-Mob transposed into chromosomal DNA, was obtained by Tn5-Mob random insertion. The growth rate of this mutant was lower than that of the wild type in the presence of 0.2 M NaCl and it seemed to lack the inductive ATP production in response to the addition of NaCl. This mutant induced the formation of small and whitish nodules on lateral roots of soybeans, which were negative for acetylene reduction activity, indicating that the nodules were ineffective for nitrogen fixation. The mutant also reduced the weight of above-ground portions and roots to 64 and 55%, respectively, compared with the weight of the plants inoculated with the wild-type cells. These results suggest that NaCl sensitivity of Rhizobium bacteria is one of the important factors for nodule formation and nitrogen fixation.     

A high-affinity iron transport system of Rhizobium meliloti may be required for efficient nitrogen fixation in planta

We have analyzed the ability of single site insertion mutants of Rhizobium meliloti 1021 defective in various components of a high-affinity iron transport system to produce nodules, fix nitogen and promote plant growth. Our results indicate that a high-affinity iron transport system may significantly increase the ability of the differentiated form of the bacterium to fix nitrogen and induce an increase in plant growth.Abbreviations EDDA ethylenediamine-N,N-bis(2-hydroxyphenylacetic acid) - CAS chrome azurol S     

Phylogenetic relationships among actinorhizal plants. The impact of molecular systematics and implications for the evolution of actinorhizal symbioses

A review of recent molecular systematic studies of actinorhizal plants and their Frankia endosymbionts is presented. For comparative purposes, a discussion of recent studies pertaining to the evolution of nodulation in the legume-rhizobium system is included. Molecular systematic studies have revealed that actinorhizal plants are more closely related than current taxonomic schemes imply. Broad-based analyses of the chloroplast gene rbcL indicate that all symbiotic root-nodulating higher plants belong to a single large clade. More focused molecular analyses of both legume and actinorhizal hosts within this large clade indicate that symbioses have probably arisen more than once. By comparing host phylogenies and recently published bacterial phylogenies, we consider the coevolution of bacterial symbionts with their actinorhizal hosts.     

紫云英根瘤菌胞外多糖缺失变种及其结瘤性状的变化

根据紫云英根瘤菌在寄主豆科植物紫云英上的结瘤能力,经转座子Tn5诱变获得的18株Exo~-变种可分为4种结瘤类群(A-D):A类变种诱导植物产生小的瘤状突起,不具固氮能力;B类变种形成无效根瘤;C类变种产生固氮效率降低的根瘤;D类变种丧失了结瘤能力。电镜分析显示:无效瘤和瘤状突起中不存在类菌体区,根瘤细胞均为不含细菌的空细胞,侵染线不能穿透到根瘤细胞中。说明紫云英根瘤菌胞外多糖很可能参与有效根瘤的形成。     

The soybean (Glycine max) nodulation‐suppressive CLE peptide,GmRIC1, functions interspecifically in common white bean (Phaseolus vulgaris), but not in a supernodulating line mutated in the receptor PvNARK

Legume plants regulate the number of nitrogen‐fixing root nodules they form via a process called the Autoregulation of Nodulation (AON). Despite being one of the most economically important and abundantly consumed legumes, little is known about the AON pathway of common bean (Phaseolus vulgaris). We used comparative‐ and functional‐genomic approaches to identify central components in the AON pathway of common bean. This includes identifying PvNARK, which encodes a LRR receptor kinase that acts to regulate root nodule numbers. A novel, truncated version of the gene was identified directly upstream of PvNARK, similar to Medicago truncatula, but not seen in Lotus japonicus or soybean. Two mutant alleles of PvNARK were identified that cause a classic shoot‐controlled and nitrate‐tolerant supernodulation phenotype. Homeologous over‐expression of the nodulation‐suppressive CLE peptide‐encoding soybean gene, GmRIC1, abolished nodulation in wild‐type bean, but had no discernible effect on PvNARK‐mutant plants. This demonstrates that soybean GmRIC1 can function interspecifically in bean, acting in a PvNARK‐dependent manner. Identification of bean PvRIC1, PvRIC2 and PvNIC1, orthologues of the soybean nodulation‐suppressive CLE peptides, revealed a high degree of conservation, particularly in the CLE domain. Overall, our work identified four new components of bean nodulation control and a truncated copy of PvNARK, discovered the mutation responsible for two supernodulating bean mutants and demonstrated that soybean GmRIC1 can function in the AON pathway of bean.     

Novel root nodule bacteria belonging to the genus Caulobacter

Aims: Aim of this study is to determine the genetic variation of rhizobia associated with horse gram [Macrotyloma uniflorum (Lam.) Verdc.] plants grown in different regions of Andhra Pradesh, India. Methods and Results: Four representative isolates having most representative characters from the previous characterization were selected for 16S rRNA sequence. The sequences were submitted to the NCBI GenBank and Ribosomal Database Project (RDP). The isolates HGR‐4, 6 and 13 showed more than 99% homology between them and they were grouped with Rhizobium reference strains where as the isolate HGR‐25 showed 87·1, 87·4 and 87·2% homology with the isolates HGR‐4, 6 and 13, respectively, and were grouped with reference strains for Caulobacter. The nodulation ability of these isolates on horse gram was confirmed by inoculation tests. Conclusions: The isolate HGR‐25 was identified as Caulobacter isolated from the plants growing in soil samples collected from Khareemnagar district, Andhra Pradesh, India. Inoculation tests revealed that Caulobacter formed nodules on horse gram. It was also confirmed by RDP. Significance and Impact of the Study: This is the first report that a legume was nodulated by a member of the genus Caulobacter, which belongs to the family Caulobacteriaceae in the order Caulobacterales of Alphaproteobacteria.     

Nodulation of specific legumes is controlled by several distinct loci in Rhizobium trifolii

Summary Three distinct loci (designated regions III, IV and V) were identified in the 14 kb Nod region of Rhizobium trifolii strain ANU843 and were found to determine the host range characteristics of this strain. Deletion of region III or region V only from the 14 kb Nod region affected clover nodulation capacity. The introduction to R. Leguminosarum of DNA fragments on multicopy vectors carrying regions III, IV and V (but not smaller fragments) extended the host range of R. leguminosarum so that infection threads and nodules occurred on white clover plants. The same DNA fragments were introduced to the Sym plasmid-cured strain (ANU845) carrying the R. meliloti recombinant nodulation plasmid pRmSL26. Plasmid pRmSL26 alone does not confer root hair curling or nodulation on clover plants. However, the introduction to ANU845 (pRmSL26) of a 1.4 kb fragment carrying R. trifolii region IV only, resulted in the phenotypic activation of marked root hair curling ability to this strain on clovers but no infection events or nodules resulted. Only the transfer of regions III, IV and V to strain ANU845 (pRmSL26) conferred normal nodulation and host range ability of the original wild type R. trifolii strain. These results indicate that the host range genes determine the outcome of early plant-bacterial interactions primarily at the stage of root hair curling and infection.     

Polymer-entrapped rhizobium as an inoculant for legumes

Summary Field and cylinder experiments conducted in France and in Senegal showed that polyacrylamide, previously proposed as an entrapping gel for preparing Rhizobium inoculants, could be replaced by alginate (AER inoculant) or a mixture of xanthan and carob gum (XER inoculant). Semi-dried or dried AER and XER were used successfully provided that their storage time was less than 90 days. In soil inoculation trails, no marked differences were observed among semi-dried XER, dried AER, and dried XER. A number of seed inoculation experiments indicated that dried XER significantly outranked AER. Seeds preinoculated by up to 48 days with XER yielded plants which were comparable in nodulation and growth parameters to those derived from plant receiving peat inoculation at the time of planting.     

Improved legume-rhizobium symbiosis by inoculating preceding cereal crop with rhizobium

Summary In cereal-legume crop rotation system, better Rhizobium symbiosis was obtained by double inoculation,i.e., when the preceeding cereal crop of maize was also inoculated with the same Rhizobium strain, used to inoculate the following legume crop of green gram or groundnut.     

Nodulation studies on legumes exotic to Australia: Hedysarum coronarium

Abstract Symbiotic experiments in glasshouse, controlled environment cabinet, and field were conducted with four lines of sulla ( Hedysarum coronarium ) and 15 strains of Rhizobium spp. This plant is highly Rhizobium -specific and appropriate strains are most unlikely to occur naturally in Australia. Under several sets of experimental conditions, H. coronarium nodulated abundantly and effectively with homologous rhizobia introduced from Spain and Italy. The optimum temperature for nitrogen fixation was relatively low (approx. 21°C) but significant interactions between line of host, strain of rhizobia, and growth temperature were frequent. The rhizobia were persistent in soil.     

Split‐root systems applied to the study of the legume‐rhizobial symbiosis: What have we learned?

Split‐root system (SRS) approaches allow the differential treatment of separate and independent root systems, while sharing a common aerial part. As such, SRS is a useful tool for the discrimination of systemic (shoot origin) versus local (root/nodule origin) regulation mechanisms. This type of approach is particularly useful when studying the complex regulatory mechanisms governing the symbiosis established between legumes and Rhizobium bacteria. The current work provides an overview of the main insights gained from the application of SRS approaches to understand how nodule number (nodulation autoregulation) and nitrogen fixation are controlled both under non‐stressful conditions and in response to a variety of stresses. Nodule number appears to be mainly controlled at the systemic level through a signal which is produced by nodule/root tissue, translocated to the shoot, and transmitted back to the root system, involving shoot Leu‐rich repeat receptor‐like kinases. In contrast, both local and systemic mechanisms have been shown to operate for the regulation of nitrogenase activity in nodules. Under drought and heavy metal stress, the regulation is mostly local, whereas the application of exogenous nitrogen seems to exert a regulation of nitrogen fixation both at the local and systemic levels.     

紫云英根瘤菌的exo与nod基因在宿主结瘤过程中的协同作用

紫云英根瘤菌菌株107经转座子Tn5诱变的胞外多糖合成缺陷型变种(Exo~-),在共生性状方面的改变有四种类型。我们选用了仅在宿主根部形成瘤状突起(Calli)的A类(NA-01,NA-02)、形成无效瘤(Nod~ ,Fix~-)的B类(NA-12)及不结瘤的(Nod~-)D类(NA-14)中的四个突变株分别与消除了共生质粒的Exo~ Nod~-变种(热处理变种及ANU-1116)混合接种紫云英幼苗,观察到与D类变种配合的接种组仍不能结瘤,而与A,B两类变种配合的接种组均诱导宿主产生形态正常的无效根瘤,并且该无效瘤全部被Nod~-变种侵占。说明一个表型仍为Exo~ ,但失去共生质粒的Nod~-变种,可在一个含有该质粒的Exo~-变种的帮助下进入根瘤。这提示共生质粒上的结瘤基因(nod)仅与侵染过程的早期有关,瘤的发育尚需根瘤菌的其他基因,其中包括exo基因的参与。 此外,共生质粒缺失的三个异种根瘤菌突变株分别与紫云英根瘤菌Exo~-变种混合接种时,也都在紫云英根部诱导出无效瘤,并且从瘤中能分离到这三个异种菌。表明在最初的识别作用发生后,植物对共生菌的专一性要求有所降低。     

Nodulation and growth ofLeucaena leucocephala (Lam.) de Wit as affected by inoculation and N fertilizer

Leonard jar, pot and field experiments examined the effects of inoculation and the influence of nitrogen fertilizer on nodulation, nitrogen fixation and growth ofLeucaena leucocephala (Lam.) de Wit at IITA, Ibadan, Nigeria. Leucaena responded to both inoculation and/or nitrogen application. Shoot growth and total N and P of inoculated plants were comparable to those of the highest N treatment, and the values were about 55% greater than those of uninoculated ones. Field data indicated that toal N yields of inoculated leucaena were increased by 50% with 40 or 80 kg ha^–1 of N fertilizer. However, N fertilizer depressed N fixation by 56% as was expected from nodule mass data. N-fixation was delayed for about 8 weeks in the plots without N. Application of small amounts of N starter (20 ppm) proved to be beneficial to satisfy the plant need during the early stage of leucaena growth. The rhizobial strains IRc 1045 and IRc 1050 were effective, competitive and survived well in the field one year after their establishment.     

Nodulation competitiveness in the Rhizobium-legume symbiosis

Successful nodulation of legumes by rhizobia is a complex process that, in the open field, depends on many different environmental factors. Generally, legume productivity in an agricultural field may be improved by inoculation with selected highly effective N₂-fixing root nodule bacteria. However, field legume inoculation with Rhizobium and Bradyrhizobium spp. has often been unsuccessful because of the presence in the soil of native strains that compete with the introduced strain in nodule formation on the host plants. This ability to dominate nodulation is termed competitiveness and is critical for the successful use of inoculants.The author is with the Departmentode Microbiologia del Suelo y Sistemas Simbioticos, Estation Experimental del Zaidin, Consejo Superior de Investigaciones Cientificas, C/Professor Albareda 1, 18008 Granada, Spain     

Regulation of legume nodulation by acidic growth conditions

Legumes represent some of the most important crop species worldwide. They are able to form novel root organs known as nodules, within which biological nitrogen fixation is facilitated through a symbiotic interaction with soil-dwelling bacteria called rhizobia. This provides legumes with a distinct advantage over other plant species, as nitrogen is a key factor for growth and development. Nodule formation is tightly regulated by the plant and can be inhibited by a number of external factors, such as soil pH. This is of significant agricultural and economic importance as much of global legume crops are grown on low pH soils. Despite this, the precise mechanism by which low pH conditions inhibits nodule development remains poorly characterized.     

Promiscuity of Hosting Nitrogen Fixation in Rice: An Overview from the Legume Perspective

ABSTRACT:?

The subject area of this review provides extraordinary challenges and opportunities. The challenges relate to the fact that the integration of various fields such as microbiology, biochemistry, plant physiology, eukaryotic as well as bacterial genetics, and applied plant sciences are required to assess the disposition of rice, an alien host, for establishing such a unique phenomenon as biological nitrogen fixation. The opportunities signify that, if successful, the breakthrough will have a significant impact on the global economy and will help improve the environment. This review highlights the literature related to the area of legume-rhizobia interactions, particularly those aspects whose understanding is of particular interest in the perspective of rice. This review also discusses the progress achieved so far in this area of rice research and the possibility of built-in nitrogen fixation in rice in the future. However, it is to be borne in mind that such research does not ensure any success at this point. It provides a unique opportunity to broaden our knowledge and understanding about many aspects of plant growth regulation in general.