Nodulation of Pole Bean (Phaseolus vulgaris L.) by Rhizobium Species of Two Cross-Inoculation Groups

Physiology and morphology of pole bean (Phaseolus vulgaris L. cv Kentucky Wonder) root nodules induced by two Rhizobium species of different cross-inoculation groups have been compared. Root nodules induced by Rhizobium sp. 127E15, which is a strain of the cowpea group Rhizobium, were pinkish, had irregular shapes, and were only partially effective. Their peak acetylene reduction activity was 4.36 μmol of C₂H₄ formed per g of fresh nodules per h at 30 days after inoculation. The effective nodules induced by Rhizobium phaseoli 127K14, which is a strain of the bean group Rhizobium, were dark red, spherical, and showed peak acetylene reduction activity of 15.95 μmol of C₂H₄ formed per g of fresh nodules per h at 15 days after inoculation. The partial effectiveness of 127E15-induced nodules was associated with fewer infected cells, a delay in the increase of bacteroid population within the host cells, abundance of cytoplasmic vesicles in the host cells, more bacteroids within a membrane envelope (peribacteroid membrane), and the inability of bacteroids to completely fill up the host cytoplasmic space. The 127K14-induced nodules were fully mature, with host cells filled with bacteroids by 12 days after inoculation. In contrast, the 127E15-induced nodules did not reach a similar developmental stage even 30 days after inoculation.     

Quantitative Study of Nodulation Competitiveness in Rhizobium Strains

We compared the nodulation competitiveness of three strains of Rhizobium leguminosarum by counting the number of nodules formed on faba bean plants after the application at sowing time of different concentrations of the strains to soils already containing Rhizobium strains of the same species. A relationship of type y = axⁿ was found to exist between the ratio of the nodules formed by the applied inoculum strain to the nodules formed by the soil strains and the ratio of Rhizobium cells in the inoculum to the cells in the soil. This relationship was also confirmed in another competition experiment in which two R. meliloti strains of identical competitiveness were mixed in various proportions. The relationship can also be applied to the majority of results reported in the literature. Should it prove to be more widely applicable, it could be used to estimate the relative competitiveness of Rhizobium strains and thus predict the performance of an inoculum in a given soil.     

A Specific Endogenous Reference for Genetically Modified Common Bean (Phaseolus vulgaris L.) DNA Quantification by Real-Time PCR Targeting Lectin Gene

The Embrapa 5.1 genetically modified (GM) common bean was approved for commercialization in Brazil. Methods for the quantification of this new genetically modified organism (GMO) are necessary. The development of a suitable endogenous reference is essential for GMO quantification by real-time PCR. Based on this, a new taxon-specific endogenous reference quantification assay was developed for Phaseolus vulgaris L. Three genes encoding common bean proteins (phaseolin, arcelin, and lectin) were selected as candidates for endogenous reference. Primers targeting these candidate genes were designed and the detection was evaluated using the SYBR Green chemistry. The assay targeting lectin gene showed higher specificity than the remaining assays, and a hydrolysis probe was then designed. This assay showed high specificity for 50 common bean samples from two gene pools, Andean and Mesoamerican. For GM common bean varieties, the results were similar to those obtained for non-GM isogenic varieties with PCR efficiency values ranging from 92 to 101 %. Moreover, this assay presented a limit of detection of ten haploid genome copies. The primers and probe developed in this work are suitable to detect and quantify either GM or non-GM common bean.     

Analysis of the Proteome of Common Bean (Phaseolus vulgaris L.) Roots after Inoculation with Rhizobium etli

Proteomics techniques were used to identify the underlying mechanism of the early stage of symbiosis between the common bean (Phaseolus vulgaris L.) and bacteria. Proteins from roots of common beans inoculated with bacteria were separated using two-dimensional polyacrylamide gel electrophoresis and identified using mass spectrometry. From 483 protein spots, 29 plant and 3 bacterial proteins involved in the early stage of symbiosis were identified. Of the 29 plant proteins, the expression of 19 was upregulated and the expression of 10 was downregulated. Upregulated proteins included those involved in protein destination/storage, energy production, and protein synthesis; whereas the downregulated proteins included those involved in metabolism. Many upregulated proteins involved in protein destination/storage were chaperonins and proteasome subunits. These results suggest that defense mechanisms associated with induction of chaperonins and protein degradation regulated by proteasomes occur during the early stage of symbiosis between the common bean and bacteria.     

Continuous Cultivation of Glucose-Limited Bean Cells (Phaseolus vulgaris L.) in a Modified Bacterial Fermentor

A commercially available bacterial fermentor was modified toallow the continuous cultivation of glucose-limited bean cells(Phaseolus vulgaris L.) at a defined pH. A steady state wasreached using a dilution rate of 0?004 h^–1 and was maintainedfor 4 months; during this period the dry weight and packed cellvolume of the culture remained constant; the yield for glucosewas 0?34 (dry wt./dry wt) and for carbon 0?27 (g atom/g atom).Glucose-limited cells had lower C/N ratios both for cytoplasmand cell walls than cells in the exponential phase of growthin batch cultures.     

Pathogenicity of Pratylenchus penetrans to Navy Bean (Phaseolus vulgaris L.)

The pathogenicity of Pratylenchus penetrans (root-lesion nematode) to Phaseolus vulgaris (navy bean) was evaluated in greenhouse experiments. Shoot and root fresh weight of cv. Sanilac plants were increased 4 and 21%, respectively, by an initial population density (Pi) of 25 P. penetrans per 100 cm³ soil. Leaf area and shoot fresh and dry weights were decreased by a Pi of 50 or more P. penetrans per 100 cm³ soil. A significant positive linear relationship existed between initial soil population densities of P. penetrans and final soil and root population densities of this nematode. Three dry bean cultivars, Sanilac, Seafarer, and Tuscola, were susceptible to P. penetrans, and yields were reduced by 43-76% when plants were exposed to a Pi of 150 P. penetrans per 100 cm³ soil. P. penetrans also reproduced on bean cultivars Saginaw, Gratiot, and Kentwood, but did not decrease bean yields, suggesting that these cultivars were tolerant to this nematode.     

Thigmotropism in Organs of the Bean Plant (Phaseolus vulgaris L.)

When each vegetative aerial organ of the young bean plant isunilaterally mechanically perturbed by gentle rubbing, it exhibitspositive thigmotropism. The internodes undergo only moderatethigmotropism, but leaves and petioles bend much more, especiallywhen they are rubbed on their abaxial surfaces. When the abaxialsurface of one petiole is rubbed, it bends down, but the oppositepetiole bends upward at the stem-petiole pulvinus. These observationsare interpreted in terms of the vining habit of bean plants. Bean, Phaseolus vulgaris, thigmotropism, mechanical perturbation     

On Vessel Member Differentiation in the Bean (Phaseolus vulgaris L.)

Certain ultrastructural features of vessel member differentiationwere examined in the primary xylem of petiole of bean (Phaseolusvulgaris L.). The cells used had helical secondary wall thickeningsand simple perforation plates. The primary cell wall increasesin thickness before the helices of secondary wall develop. Ina common wall between two vessel members of different ages,theprimary thickening occurs first in the older cell so thatfor a time the middle lamella is located closer to the youngercell rather than medianly. Apparently the helix is depositedafter the primary wall of a given cell reaches maximum thickness.The perforation of the end wall is preceded by primary thickeningof the part of the wall that is later removed. The marginalregion remains relatively thin and becomes covered with a rimof secondary wall. Vesicles with fibrous content appear nearthe surface within the end wall shortly before the perforationoccurs. A highly vacuolated protoplast with a much enlargednucleus and numerous organdIes is present during cell wall differentiation.After that process is completed, the protoplast disintegratesand the primary wall bearing the helix is hydrolysed where itis exposed to the cell lumen and, under certain conditions,also under the secondary wall.     

Semienclosed Tube Cultures of Bean Plants (Phaseolus vulgaris L.) for Enumeration of Rhizobium phaseoli by the Most-Probable-Number Technique

The semienclosed tube culture technique of Gibson was modified to permit growth of common bean (Phaseolus vulgaris L.) roots in humid air, enabling enumeration of the homologous (nodule forming) symbiont, Rhizobium phaseoli, by the most-probable-number plant infection method. A bean genotype with improved nodulation characteristics was used as the plant host. This method of enumeration was accurate when tubes were scored 3 weeks after inoculation with several R. phaseoli strains diluted from aqueous suspensions, peat-based inoculants, or soil. A comparison of population sizes obtained by most-probable-number tube cultures and plate counts indicated that 1 to 3 viable cells of R. phaseoli were a sufficient inoculant to induce nodule formation.     

Genome Sequence of Rhizobium grahamii CCGE502, a Broad-Host-Range Symbiont with Low Nodulation Competitiveness in Phaseolus vulgaris

Here we present the genome sequence of Rhizobium grahamii CCGE502. R. grahamii groups with other newly described broad-host-range species, which are not very efficient Phaseolus vulgaris symbionts, with a wide geographic distribution and which constitutes a novel Rhizobium clade.     

普通菜豆种质资源表型鉴定及多样性分析

对646份普通菜豆核心种质在贵州毕节进行了表型鉴定,结果表明,普通菜豆具有丰富的形态性状多样性。总变异数为367,平均遗传丰富度为8.34,变异范围2~31;遗传多样性指数为0.63,变异范围为0.02~0.91。通过多变量的主成分分析,前3个主成分的贡献率较大,分别为17.73%、15.35%和11.33%。依据表型鉴定数据信息,将供试种质聚类并划分为4组。Ⅰ组的遗传多样性较高,主要为直立有限的大粒资源,大多资源属于安第斯基因库;Ⅱ组的遗传多样性最低,为直立无限生长习性的小粒资源,属于中美基因库;Ⅲ组的遗传多样性最高,主要以蔓生无限为主,包括小部分直立无限和匍匐无限的资源;Ⅳ组的遗传多样性较低,为蔓生无限生长习性、株高最高、分枝数最少的资源。筛选到大粒、多荚、长荚、宽荚等具有特异性状的种质资源35份。     

Subcellular Localization of Zinc and Calcium in Bean (Phaseolus vulgaris L.) Tissues

Two bean (Phaseolus vulgaris L.) cultivars differing in growth responses to zinc were examined for differences in uptake and subcellular localization of ⁶⁵Zn during a 15-day growth period. The zinc-sensitive cultivar Sanilac showed initially a much higher rate of absorption, which declined after 24 hours. The zinc-tolerant cultivar Saginaw showed a slow but steady rate of absorption for 10 days. In roots as well as in stem callus tissues of both cultivars, three-fourths of the absorbed ⁶⁵Zn was localized in the “cytoplasmic” supernatant fractions (containing ribosomes and vacuolar sap). Very little (less than 7%) ⁶⁵Zn was localized in the cell wall fraction. There was a much greater proportion of the absorbed ⁶⁵Zn localized in root mitochondria and nuclei of the zinc-sensitive Sanilac than in the zinc-tolerant Saginaw. Stem callus tissues, however, did not show such cultivar differences in zinc accumulation at the sub-cellular level.     

Nodulation and Nitrogen Fixation Efficacy of Rhizobium fredii with Phaseolus vulgaris Genotypes

Phaseolus plant introduction (PI) genotypes (consisting of 684 P. vulgaris, 26 P. acutifolius, 39 P. lunatus, and 5 P. coccineus accessions) were evaluated for their ability to form effective symbioses with strains of six slow-growing (Bradyrhizobium) and four fast-growing (Rhizobium fredii) soybean rhizobia. Of the 684 P. vulgaris genotypes examined, three PIs were found to form effective nitrogen-fixing symbioses with the R. fredii strains. While none of the Bradyrhizobium strains nodulated any of the genotypes tested, some produced large numbers of undifferentiated root proliferations (hypertrophies). A symbiotic plasmid-cured R. fredii strain failed to nodulate the P. vulgaris PIs and cultivars, suggesting that P. vulgaris host range genes are Sym plasmid borne in the fast-growing soybean rhizobia.     

Biocontrol of Fusarium Root Rot in the Common Bean (Phaseolus vulgaris L.) by using Symbiotic Glomus mosseae and Rhizobium leguminosarum

Abstract The interaction between VA mycorrhiza Glomus mosseae (Gm), root rodulating symbiont Rhizobium leguminosarum (Rl), and root rot pathogen Fusarium solani (Fs) on the common bean (Phaseolus vulgaris) in relation to plant growth, nutrient uptake, disease severity, rhizosphere microbial biomass, and nutrient availability was investigated. Mycorrhizal plants yielded significantly greater plant biomass and mobilized more N and P uptake as compared to nonmycorrhizal plants or those infected with Fs. However, the mycorrhizal root colonizing ability, in presence of Fs, was reduced by 27%, whereas Rl enhanced it by 37%. The inoculation of Gm, besides decreasing propagule number of Fs in the rhizosphere, decreased pathogenic root rot by 34 to 77%. However, in the presence of Rl, Gm-inoculated plants were more tolerant of the fungal root pathogen. The Gm + Rl inoculated plants not only had maximum plant biomass and root nodulation, but also exhibited higher microbial biomass, alkaline phosphatase activity, and available phosphorus in their rhizosphere. Rl, alone or in association with Gm, caused the maximum increase in mineral nitrogen (NH₄ ⁺ and NO₃ ⁻) content in soil. These results indicate that Gm has a vital role in inhibiting the root pathogen from invasion, more so in the presence of R. leguminosarum. Received: 26 February 1996; Revised: 12 July 1996     

Cell-Wall Proteins Induced by Water Deficit in Bean (Phaseolus vulgaris L.) Seedlings

In the last few years, much attention has been given to the role of proteins that accumulate during water deficit. In this work, we analyzed the electrophoretic patterns of basic protein extracts, enriched for a number of cell-wall proteins, from bean (Phaseolus vulgaris L.) seedlings and 21-d-old plants subjected to water deficit. Three major basic proteins accumulated in bean seedlings exposed to low water potentials, with apparent molecular masses of 36, 33, and 22 kD, which we refer to as p36, p33, and p22, respectively. Leaves and roots of 21-d-old plants grown under low-water-availability conditions accumulated only p36 and p33 proteins. In 21-d-old plants subjected to a fast rate of water loss, both p33 and p36 accumulated to approximately the same levels, whereas if the plants were subjected to a gradual loss of water, p33 accumulated to higher levels. Both p36 and p33 were glycosylated and were found in the cell-wall fraction. In contrast, p22 was not glycosylated and was found in the soluble fraction. The accumulation of these proteins was also induced by abscisic acid (0.1-1.0 mM) treatment but not by wounding or by jasmonate treatment.     

Effect of Glyphosate on Intact Bean Plants (Phaseolus vulgaris L.) and Isolated Cells

Whole bean (var. “Eastern Butterwax”) plants and isolated cells were used to investigate possible mechanisms of action of glyphosate [N-(phosphonomethyl)glycine]. Results showed that glyphosate was quickly absorbed by the whole plant but not by individual cells and that it caused a rapid reduction in leaf dry matter accumulation, leaf expansion, leaf angle, and stomatal aperture without affecting the water status of the plant. Glyphosate also caused a rapid reduction in cellular uptake of ⁸⁶Rb and ³²P which preceded its detrimental effects on photosynthesis, RNA and protein synthesis, and respiration of isolated cells. This reduction in ion absorption was not due to a loss of membrane integrity, decrease in energy supply or chelation of ions. It was concluded that glyphosate was directly inhibiting the ion absorption process of bean leaf cells.     

Affinity Chromatography of the Major Seed Protein of the Bean (Phaseolus vulgaris L.)

The major globulin of the French bean (Phaseolus vulgaris L.) undergoes a reversible pH-dependent polymerization. At pH values above 6.5, the monomeric form of the protein predominates; and at pH values below 6.5, the protein occurs as a polymer, probably a tetramer. At extremes of pH, the protein dissociates further into peptides. The reversible pH-dependent interaction between globulin subunits is used in this report as the basis for an affinity chromatography procedure for isolation of the globulin. The major globulin from several genetic variants can be obtained in gram quantities and does not indicate the presence of any impurities on discontinuous sodium dodecyl sulfate gel electrophoresis.     

Endogenous Regulation of Photosynthetic Rate in Primary Leaves of Bean (Phaseolus vulgaris L.)

The rate of photosynthesis and/or dry matter production wasstudied in fully-expanded primary leaves of bean (Phaseolusvulgaris cv. Bulgarian) plants which had been subjected to varioussurgical and hormonal treatments. Between 30 and 40 per centof the assimilates produced by the primary leaves, over a 4-dayperiod starting with expansion of the first trifoliate leaf,were diverted to the growing shoot above the insertion of theprimary leaves. In detopped plants (i.e. lacking all leaves,stem and buds above insertion of primary leaves), both the rateof net photosynthesis (NP) of the primary leaves 4 days afterdetopping, and the mean net assimilation rate (NAR) over thisinterval, did not differ significantly from those of intactplants. The assimilate normally diverted to the top in intactplants was distributed between the remaining organs of the detoppedplant. When translocation of assimilates from the primary leaveswas stopped by girdling their petioles, both NAR and NP wereas in untreated control plants after a 2-day period. The assimilatesproduced during that period accumulated in the mesophyll chlorenchymain the form of starch granules. Intact plants supplied withGA₃, or IAA, through the primary leaves as well as detoppedplants supplied with IAA through the stump, differed from untreatedcontrol plants in the pattern of distribution of the assimilatesproduced: IAA favoured dry-matter accumulation in the roots,while GA₃ favoured the tops. Nevertheless, neither NP, nor NARdiffered significantly from the corresponding controls.