Phylogenetic analysis of Ukrainian BYMV isolates from soybeans and beans

Two isolates of Bean yellow mosaic virus originating from soybean (Glycine max L.) and bean (Phaseolus vulgaris L.) plants that are distributed in Ukraine were examined according to their molecular characteristics. PCR amplification products were sequenced and compared with the corresponding sequences of different BYMV isolates obtained from GeneBank. The dates obtained in phylogenetic analysis showed 98% sequence identities of isolates under study, and, in accordance with the species demarcation criteria and identification guidelines for potyviruses, it was suggested that the Ukrainian isolates are one strain of BYMV. The sequence showed a high degree of sequence identities with other BYMV isolates/strains and shared maximum identity with BYMV strains reported from Russia, Australia, and Argentina. The sequence data have been submitted to NCBI, accession numbers KT923790.1 for soybean isolate and KT923791.1 for bean isolate of BYMV.     

Genome-wide analysis of the PHB gene family in <Emphasis Type="Italic">Glycine max</Emphasis> (L.) Merr.

Prohibitins (PHBs) have one SPFH domain in common and present in species ranging from prokaryotes to eukaryotes. Although a number of researches on PHBs were performed in different plant species, a systematic analysis of the PHB family in soybean is still remains uncharacterized. In the present study, 24 putative PHB genes have been first systemically identified in soybean. According to phylogenetic analysis, these GmPHBs could be classified into four groups. Gene structures and motif patterns showed high levels of conservation within the phylogenetic subgroups. Several members of this family have undergone purifying selection based on Ka/Ks analysis on duplicated PHB genes in soybean. We performed microsynteny analysis across four legume species based on the comparisons among the specific regions contained in PHB genes. As a result, numerous microsyntenic gene pairs among soybean, Medicago, Lotus and Phaseolus were identified. Most soybean PHB genes exhibited different expression levels in various tissues and developmental stages through expression analysis using publicly available RNA-seq datasets. The 11 GmPHB genes from III_B subgroup were examined by qPCR for their expression in two soybean cultivar after infection by Phytophthora sojae. Besides three GmPHB genes previous reported by us, here other four genes also were rapidly induced by P. sojae infection in the resistant genotype, while induction was very weak in the susceptible genotype. The comprehensive overview of the PHB gene family in soybean genome will provide useful information for further functional analysis of the PHB gene family in soybean.     

Nymph and Adult Biology of <Emphasis Type="Italic">Euschistus cornutus</Emphasis> Dallas: a Potential Soybean Pest in the Neotropics

Laboratory studies with Euschistus cornutus Dallas indicated that nymphs complete development when feeding on green bean, Phaseolus vulgaris L. pod, on soybean, Glycine max (L.) Merrill pod, and on raw shelled peanut, Arachis hypogaea L., but not on fruit (berry) of privet, Ligustrum lucidum Ait. Total mortality was lower on green bean pod (45%), and higher on soybean pod and peanut raw (75 and 80%, respectively). Nymph developmental time was significantly longer for females feeding on green bean pod (37.4 days) than on soybean pod (27 days); a single data was observed on peanut raw (32 days). Males showed no significant differences in total nymph developmental time among foods (31.3 to 33.0 days). At adult emergency, fresh body weight of females (52.2 to 68.5 mg) and males (61.9 to 71.3 mg) did not show statistical differences among foods tested nor between genders. Survivorship of E. cornutus adult after 50 days was greater on peanut raw than on green bean or soybean pod; on privet berry, the majority of males and females (>80%) were dead after 20 days. The reproductive performance data was, in general, greater on peanut raw than on green bean or soybean pod; on privet fruit, no female laid eggs. Fresh body weight gain occurred on all foods, except on privet berry, on which adults lost weight over time. Records of specimens from insect collections in Brazil indicated that E. cornutus occurs in the Southeast and South regions (19° to 31° S latitude). The most common host plant is soybean, suggesting a potential pest status of this stink bug on this crop in the future.     

Biochemical evidence bearing on the domestication of<Emphasis Type="Italic">Phaseolus</Emphasis> (Fabaceae) beans

The genusPhaseolus (Fabaceae) consists of some 50 species, all of which are distributed in the Americas. Four of these contain cultigens.P. vulgaris (common bean),P. lunatus (lima bean),P. acutifolius (tepary bean),P. coccineus subsp.coccineus (runner bean); andP. coccineus subsp.polyanthus (no English vernacular name). Biochemical markers—phaseolin seed storage protein and isozymes—have provided new evidence on the organization of the first three species. Domestication has possibly caused a strong reduction in genetic diversity inP. vulgaris andP. acutifolius. BothP. vulgaris andP. lunatus cultivars result from at least two independent domestications, in Mesoamerica and in the Andes. These two species consist of two gene pools, each of which includes wild ancestors and their respective cultivated descendants. Our findings suggest the need for additional emphasis on genetic conservation of wild ancestors and their use in breeding programs and for a comparison of inter-gene pool vs. intra-gene pool crosses in breeding programs.     

Polyphasic characterization of rhizobia microsymbionts of common bean [<Emphasis Type="Italic">Phaseolus vulgaris</Emphasis> (L.)] isolated in Mato Grosso do Sul,a hotspot of Brazilian biodiversity

Common bean [Phaseolus vulgaris (Linnaeus)] is the key source of protein, carbohydrates and micronutrients for over 300 million people in the tropics. Like many legumes, P. vulgaris can fix atmospheric nitrogen in symbiosis with rhizobia, alleviating the need for the expensive and polluting N-fertilizers. The crop is known to nodulate with a wide range of rhizobia and, although Brazil is not a center of genetic origin/domestication of P. vulgaris, a variety of rhizobial species have been found as symbionts of the legume. Mato Grosso do Sul (MS) is one of the largest common bean producer states in Brazil, with reports of high yields and abundant natural nodulation. The objective of this study was to evaluate the diversity of 73 indigenous rhizobia isolated from common bean grown in 22 municipalities of MS. Great morphophysiological and genetic diversity was found, as indicated by the six and 35 clusters formed, considering the similarity level of 75 and 70%, respectively, for the phenotypic and rep-PCR dendrograms. Eleven representative isolates were selected for detailed genetic characterization using 16S rRNA and three protein-coding housekeeping genes, glnII, gyrB and recA. We identified species originated from the centers of origin/domestication of the legume, R. etli and R. phaseoli, species probably indigenous of Brazil, R. leucaenae and others of the Rhizobium/Agrobacterium clade, in addition to putative new species. The results highlight the great rhizobial diversity of the region.     

Characterisation of structural genes involved in phytic acid biosynthesis in common bean (<Emphasis Type="Italic">Phaseolus vulgaris</Emphasis> L.)

Phytate (myo-inositol hexakisphosphate), the major form of phosphorous storage in plant seeds, is an inositol phosphate compound poorly digested by humans and monogastric animals. A major goal for grain crop improvement is the reduction of its content in the seed to improve micronutrient bioavailability and phosphorus utilisation by humans and non-ruminant animals, respectively. We are interested in lowering phytic acid in common bean seed and to this goal we have undertaken a two-strategy approach: the isolation of mutants from an EMS mutagenised population (Campion et al. 2009) and the identification of genes coding for candidate enzymes involved in inositol phosphate metabolism for future targeted mutant isolation and/or study. In this paper we report data referred to the second approach and concerning the isolation and genomic organisation of Phaseolus vulgaris genes coding for myo-inositol 1-phosphate synthase (PvMIPSs and PvMIPSv), inositol monophosphatase (PvIMP), myo-inositol kinase (PvMIK), inositol 1,4,5-tris-phosphate kinase (PvIPK2), inositol 1,3,4-triphosphate 5/6-kinase (PvITPKα and PvITPKβ) and inositol 1,3,4,5,6 pentakisphosphate 2-kinase (PvIPK1). All these genes have been mapped on the common bean reference genetic map of McClean (NDSU) 2007 using a virtual mapping strategy. Bean markers, presumably associated to each gene of the phytic acid pathway, have also been identified. In addition, we provide a picture of the expression, during seed development, of the genes involved in phytic acid synthesis, including those such as MIK, IMP and IPK2, for which this information was lacking.     

Protein characters and relationship betweenPhaseolus vulgaris ssp.Aborigineus Burk. and related taxons of the genusPhaseolus

Both quantitative and qualitative immunochemical methods were used for studying the mutual relationships of several spocies and the subspecies of the genusPhaseolus: Ph. vulgaris L. ssp.vulgaris, Ph. vulgaris L. ssp.aborigineus Burk.,Ph. coccineus L.,Ph. acutifolius A. Gray,Ph. lunatus L. (American endemites) andPh. aureus L. (a typical Asian bean). Protein characters of cotyledons (i.e., ?storage” proteins) of the above species were compared with the aid of antisera prepared against seed (cotyledon) proteins ofPh. vulgaris L. ssp.vulgaris, cv. Veltruská Saxa, using

1. (a)
   the whole complex of cotyledon protein,     
   
   

Overexpression of <Emphasis Type="Italic">AtGRDP2</Emphasis> gene in common bean hairy roots generates vigorous plants with enhanced salt tolerance

Proteins with glycine-rich repeats have been identified in plants, mammalians, fungi, and bacteria. Plant glycine-rich proteins have been associated to stress response. Previously, we reported that the Arabidopsis thaliana AtGRDP2 gene, which encodes a protein with a glycine-rich domain, plays a role in growth and development of A. thaliana and Lactuca sativa. In this study, we generated composite Phaseolus vulgaris plants that overexpress the AtGRDP2 gene in hairy roots generated by Agrobacterium rhizogenes. We observed that hairy roots harboring the AtGRDP2 gene developed more abundant and faster-growing roots than control hairy roots generated with the wild type A. rhizogenes. In addition, composite common bean plants overexpressing the AtGRDP2 gene in roots were more tolerant to salt stress showing increments in their fresh and dry weight. Our data further support the role of plant GRDP genes in development and stress response.     

Characterization and genetics of multiple soybean aphid biotype resistance in five soybean plant introductions

Key message

Five soybean plant introductions expressed antibiosis resistance to multiple soybean aphid biotypes. Two introductions had resistance genes located in the Rag1, Rag2, and Rag3 regions; one introduction had resistance genes located in the Rag1, Rag2, and rag4 regions; one introduction had resistance genes located in the Rag1 and Rag2 regions; and one introduction had a resistance gene located in the Rag2 region.

Abstract

Soybean aphid (Aphis glycines Matsumura) is the most important soybean [Glycine max (L.) Merr.] insect pest in the USA. The objectives of this study were to characterize the resistance expressed in five plant introductions (PIs) to four soybean aphid biotypes, determine the mode of resistance inheritance, and identify markers associated with genes controlling resistance in these accessions. Five soybean PIs, from an initial set of 3000 PIs, were tested for resistance against soybean aphid biotypes 1, 2, 3, and 4 in choice and no-choice tests. Of these five PIs, PI 587663, PI 587677, and PI 587685 expressed antibiosis against all four biotypes, while PI 587972 and PI 594592 expressed antibiosis against biotypes 1, 2, and 3. F₂ populations derived from PI 587663 and PI 587972 were evaluated for resistance against soybean aphid biotype 1, and populations derived from PIs 587677, 587685, and 594592 were tested against biotype 3. In addition, F_2:3 plants were tested against biotypes 2 and 3. Genomic DNA from F₂ plants was screened with markers linked to Rag1, Rag2, Rag3, and rag4 soybean aphid-resistance genes. Results showed that PI 587663 and PI 594592 each had three genes with variable gene action located in the Rag1, Rag2, and Rag3 regions. PI 587677 had three genes with variable gene action located in the Rag1, Rag2 and rag4 regions. PI 587685 had one dominant gene located in the Rag1 region and an additive gene in the Rag2 region. PI 587972 had one dominant gene located in the Rag2 region controlling antixenosis- or antibiosis-type resistance to soybean aphid biotypes 1, 2, or 3. PIs 587663, 587677, and 587685 also showed antibiosis-type resistance against biotype 4. Information on multi-biotype aphid resistance and resistance gene markers will be useful for improving soybean aphid resistance in commercial soybean cultivars.

     

Attachment ability of the southern green stink bug, <Emphasis Type="Italic">Nezara viridula</Emphasis> (L.), on plant surfaces

Traction forces of male and female southern green stink bugs Nezara viridula (L.) were measured on adaxial leaves of green beans (Phaseolus vulgaris L. cv. ‘Nagauzura’), peas (Pisum sativum L. cv. ‘Hakuryu’), rice (Oryza sativa L. cv. ‘Mac hin sung’), and soybean (Glycine max [L.] Merr. cv. ‘Enrei’), as well as on glass as a control surface. Bugs attached well on three-dimensionally structured surfaces covered with anti-adhesive epicuticular wax crystals. Strongest pulls were generated on adaxial green bean leaves, corresponding to safety factors (traction force/body weight) of 11.1 and 11.6 in males and females, respectively. These values were slightly lower on soybean (males: 7.4, females: 8.0) and rice leaves (males: 8.9, females: 10.6). Trichomes and papillae are assumed to promote pentatomid bug’s attachment. On tabular, wax-covered pea leaves, safety factors decreased significantly to 1.7 and 1.6, in males and females, respectively. Differently, on non-structured glass, safety factors resembled those on rice and soybean leaves (males: 9.6, females: 8.0). No statistical differences in traction force and safety factor between sexes were detected on any substrate. Surface wettability did not significantly affect the results. Both robust claws and tough adhesive pads enable the N. viridula bugs to grasp and adhere to a wide range of various plant substrates, including such ones covered with anti-adhesive wax crystals. However, tabular, pruinose pea leaves were detected to prevent the foothold of the southern green stink bugs, although pea is known as one of their common host plants.