Distinction of strains of bean common mosaic virus and blackeye cowpea mosaic virus using antibodies to N- and C- or N-terminal peptide domains of coat proteins

Earlier attempts to discriminate serologically strains NL1, NL3 and NY15 of bean common mosaic virus (BCMV) and strain W of blackeye cowpea mosaic virus (B1CMV) had been unsuccessful. Antibodies directed towards N- and C-, or N-terminal peptide regions of the coat proteins of the above strains enabled the distinction between B1CMV-W, BCMV-NY15 and BCMV-NL3 in electroblot immunoassay and in ELISA. The distinction was better with antibodies directed towards N-termini than with those to N- and C-termini. Strain NL1 of BCMV cross-reacted with both B1CMV-W and BCMV-NY15, but not with BCMV-NL3. Taxonomic implications of these findings are discussed.     

Incidence and severity of bean common mosaic disease and resistance of popular bean cultivars to the disease in western Kenya

The common bean (Phaseolus vulgaris) is a high protein crop and the main legume in the cropping system of western Kenya. Despite its importance, common bean yields are low (<1.0 t/ha) and declining. Bean common mosaic virus (BCMV) and bean common mosaic necrosis virus (BCMNV) are the most common and most destructive viruses and can cause a yield loss as high as 100%. In Kenya, a limited number of cultivars and exotic genotypes with resistance to BCMV and BCMNV strains have been reported. This study sought to determine the distribution and screen popular cultivars for resistance to the viruses. In October 2016 and May 2017, two diagnostic surveys for bean common mosaic disease (BCMD) were conducted in seven counties of western Kenya namely Bungoma, Busia, Homa Bay, Nandi, Vihiga, Kakamega and Siaya. Leaf samples showing virus-like symptoms were collected and analysed by ELISA. Sixteen popularly grown bean cultivars together with cowpea (Vigna unguiculata), soybean (Glycine max), green grams (Vigna radiata) and groundnut (Arachis hypogaea) were planted in a greenhouse in a completely randomized block design with three replicates. The plants were inoculated with BCMNV isolate at 3-leaf stage. Data were taken weekly for 3 weeks on type of symptoms expressed and number of plants infected. In total, 270 bean farms were visited. Symptoms of mosaic, downward curling, local lesions, stunting or a combination of these were observed during both surveys. Mean virus incidence was higher in the short rain season (50.2%) than in the long rain season (35.6%). The mean BCMD severity on a scale of 0–3 was highest (2.3) in Kakamega County and lowest (0.5) in Siaya. On variety resistance tests to BCMNV isolate, 10 bean cultivars were susceptible, four tolerant and two resistant. BCMNV is widely distributed across counties probably because of use of uncertified seeds by farmers and inoculum pressure from seed and aphid vector. For improved yields of common bean, farmers should be advised to plant certified seeds for all legumes in the cropping system.     

Immunocapture RT-PCR detection of Bean common mosaic virus and strain blackeye cowpea mosaic in common bean and black gram in India

The strains of Bean common mosaic virus (BCMV) and blackeye cowpea mosaic (BICM), genus Potyvirus, were detected from 25 common bean and 14 black gram seeds among 142 seed samples collected from different legume-growing regions of India. The samples were subjected to a growing-on test, an indicator plant test, an electron microscopic observations, an enzyme linked immunosorbent assay and an immunocapture RT-PCR. The incidence of the two tested viruses in common bean and black gram seed samples was 1–6% and 0.5–3.5%, respectively in growing-on test evaluations. Electron microscopic observations revealed filamentous virion particles from the leaves of plants showing characteristic virus disease symptoms in growing-on and host inoculation tests. The identity of the strains was confirmed by immunocapture RT-PCR, with a final amplification product of approximately 700 bp for BCMV and BCMV–BICM. The complete identity of the two viruses was further confirmed by nucleotide sequencing of the partial coat protein and 3′-UTR regions. The sequences of the four BCMV and BCMV–BICM isolates each consisted of 583–622 and 550–577 nucleotides. The present report confirms the widespread nature of these two serious potyviruses in the two most important legume crops in India.     

Serological and molecular characterisations of the Egyptian isolate of Bean common mosaic virus

Bean common mosaic virus (BCMV) was isolated from the naturally infected bean plants collected from the Kafr El-Sheikh and El-Gharbia Governorates. BCMV induced sever mosaic, vein banding, malformation, leaf curling and stunting on bean plants cv. Giza 6. The isolated virus was propagated in bean plants cv. Giza 6. The identification of BCMV was carried out serologically by an indirect enzyme-linked immunosorbent assay using BCMV antiserum. Positive reaction indicated that the virus under study was related serologically to Potyvirus. The molecular biology techniques were used to identify and characterise the coat protein gene of BCMV. Oligonucleotide primers were designed for BCMV according to the published nucleotide sequences of BCMV and were successfully amplified with a DNA fragment (300 bp) from BCMV CP gene by RT-PCR. The total RNA was extracted from bean leaves and was reverse-transcribed and amplified using the oligonucleotide primer. The amplified product was analysed by gel electrophoresis. Also, Southern and dot blot hybridisations were used to establish the authenticity and specificity to the RT-PCR-amplified products of BCMV. The nucleotide sequences of the Egyptian isolate of BCMV/CP showed similarity with an isolate (BCMV-NY 15) which belongs to Puerto Rico.     

The I gene of bean: a dosage-dependent allele conferring extreme resistance, hypersensitive resistance, or spreading vascular necrosis in response to the potyvirus Bean common mosaic virus

The resistance to the potyvirus Bean common mosaic virus (BCMV) conferred by the I allele in cultivars of Phaseolus vulgaris has been characterized as dominant, and it has been associated with both immunity and a systemic vascular necrosis in infected bean plants under field, as well as controlled, conditions. In our attempts to understand more fully the nature of the interaction between bean with the I resistance allele and the pathogen BCMV, we carefully varied both I allele dosage and temperature and observed the resulting, varying resistance responses. We report here that the I allele in the bean cultivars we studied is not dominant, but rather incompletely dominant, and that the system can be manipulated to show in plants a continuum of response to BCMV that ranges from immunity or extreme resistance, to hypersensitive resistance, to systemic phloem necrosis (and subsequent plant death). We propose that the particular phenotypic outcome in bean results from a quantitative interaction between viral pathogen and plant host that can be altered to favor one or the other by manipulating I allele dosage, temperature, viral pathogen, or plant cultivar.     

BCMV-ukr: isolate of bean common mosaic virus revealed in Ukraine

SUMMARY

Bean common mosaic virus (BCMV) is distributed worldwide and causes a serious disease in bean reducing growth and crops yield. The aim of this study was to investigate the occurrence of BCMV and Bean common mosaic necrotic virus (BCMNV) in Ukraine, to characterise host range and reactions of indicator plants to mechanical inoculation with the isolate and to differentiate it by using Drijfhout’s differentials. Leaf samples were positive for BCMV infection in RT-PCR assay employing specific primers with amplification of a 340-bp product. Based on a biological test on bean differentials, the isolate was assigned to pathogroup VII despite the fact that strain differed markedly from the standard strains in symptoms producing on differential groups IV and V. Partial sequence data of the coat protein region show 100% identity with BCMV 125 sequences tested. To our knowledge, this is the first attempt to characterise the BCMV circulating in Ukraine.     

Bean common mosaic virus and cucumber mosaic virus naturally infecting Aristolochia spp. plants in Brazil

In April 2022, Aristolochia plants with symptoms of mosaic were observed in a garden at Jardim Botânico Plantarum, Nova Odessa, São Paulo State, Brazil. Potyviridae-like particles were observed by transmission electron microscopy in leaf extracts. Total RNA extracted from symptomatic plants used in RT-PCR with universal and BCMV-specific primers detected the potyvirus bean common mosaic virus (BCMV). The cucumovirus cucumber mosaic virus (CMV) was identified only in Aristolochia littoralis plants that tested negative by RT-PCR for BCMV. Phylogenetic analysis grouped samples of Aristolochia in a different clade among samples of Phaseolus vulgaris. Phylogenetic analysis indicated that the CMV isolate from Aristolochia belongs to the CMV group IA. BCMV was mechanically transmitted to healthy plants of A. fimbriata, Chenopodium quinoa, P. vulgaris cv. Jalo and Macroptilium lathyroides. CMV was mechanically transmitted to plants of A. fimbriata and C. quinoa. The BCMV and CMV were aphid transmitted only by Aphis gossypii to Aristolochia plants. This is the first report of BCMV and CMV infecting Aristolochia plants in Brazil.     

Glycine mosaic virus: a comovirus from Australian native Glycine species

Two strains of a virus designated Glycine mosaic virus (GMV) were found in Glycine clandestina and G. tabacina, legumes indigenous to Australia and the western Pacific region. When transmitted by sap inoculation, GMV infected mostly leguminous species, and caused mosaic and mottling symptoms. The virus was not found naturally in soybean G. max, but it infected all of the 21 cultivars tested. GMV has isometric particles of c. 28 nm diameter, and produces three components with sedimentation coefficients of 60 S (top), 103 S (middle), and 130 S (bottom). Both middle and bottom components are required for infectivity. The virions contain two major proteins with molecular weights of c. 21 500 and 42 000. GMV produces large aggregates of particles in the cytoplasm of the mesophyll cells of pea Pisum sativum, and also induces amorphous membrane-bound bodies and cytoplasmic vesicles. The type strain (from New South Wales) reacts with antisera to Echtes Ackerbohnenmosaik, broad bean stain, and a Californian isolate of squash mosaic virus. The GW strain (from Queensland) reacts with all of the latter antisera, as well as with antisera to cowpea mosaic virus (Sb and Ark strains), bean pod mottle, and red clover mottle viruses, and is serologically related to, but not identical with, the type strain. These properties clearly establish GMV as a new member of the comovirus group.     

A New Virulent Isolate of Clover Yellow Vein Virus on Phaseolus vulgaris in Bulgaria

Potyviruses are a common threat for snap bean production in Bulgaria. During virus surveys of bean plots in the south central region, we identified an isolate of Clover yellow vein virus (ClYVV), designated ClYVV 11B, by indirect ELISA and RT‐PCR causing severe mosaic symptoms and systemic necrosis. Indirect and direct ELISA using ClYVV antisera differentiated the ClYVV isolate from Bean yellow mosaic virus (BYMV), but serological analysis could not distinguish the Bulgarian isolate ClYVV 11B from an Italian ClYVV isolate used as a reference (ClYVV 505/7). RT‐PCR analyses with specific primers revealed that both isolates were ClYVV. Sequence analysis of an 800 bp fragment corresponding to the coat protein coding region showed 94% identity at the nucleotide level between the two isolates. Phylogenetic analyses of aligned nucleotide sequences available in the database confirmed the existence of two groups of isolates, but ClYVV 11B and ClYVV505/7 belonged to the same group. We compared the virulence of both isolates on a set of differential cultivars and 19 bean breeding lines resistant to Bean common mosaic virus (BCMV) and Bean common mosaic necrosis virus (BCMNV): Bulgarian isolate ClYVV 11B was able to infect systemically all tested bean differential cultivars and breeding lines including those with genotypes Ibc3 and Ibc2²; Italian isolate ClYVV 505/7 was not able to infect systemically some differentials with genotypes bc‐ubc1, bc‐ubc2², bc‐ubc2bc3, Ibc1², Ibc2², Ibc3. The role of bc3 gene as a source of resistance to potyviruses is discussed.     

Increased multiple virus resistance in transgenic soybean overexpressing the double-strand RNA-specific ribonuclease gene PAC1

Viruses constitute a major constraint to soybean production worldwide and are responsible for significant yield losses every year. Although varying degrees of resistance to specific viral strains has been identified in some soybean genetic sources, the high rate of mutation in viral genomes and mixed infections of different viruses or strains under field conditions usually hinder the effective control of viral diseases. In the present study, we generated transgenic soybean lines constitutively expressing the double-strand RNA specific ribonuclease gene PAC1 from Schizosaccharomyces pombe to evaluate their resistance responses to multiple soybean-infecting virus strains and isolates. Resistance evaluation over three consecutive years showed that the transgenic lines displayed significantly lower levels of disease severity in field conditions when challenged with soybean mosaic virus (SMV) SC3, a prevalent SMV strain in soybean-growing regions of China, compared to the non-transformed (NT) plants. After inoculation with four additional SMV strains (SC7, SC15, SC18, and SMV-R), and three isolates of bean common mosaic virus (BCMV), watermelon mosaic virus (WMV), and bean pod mottle virus (BPMV), the transgenic plants exhibited less severe symptoms and enhanced resistance to virus infections relative to NT plants. Consistent with these results, the accumulation of each virus isolate was significantly inhibited in transgenic plants as confirmed by quantitative real-time PCR and double antibody sandwich enzyme-linked immunosorbent assays. Collectively, our results showed that overexpression of PAC1 can increase multiple virus resistance in transgenic soybean, and thus provide an efficient control strategy against RNA viruses such as SMV, BCMV, WMV, and BPMV.

     

East African strains of cowpea aphid-borne mosaic virus

Cowpea aphid-borne mosaic virus (CAMV) was isolated for the first time in East Africa where three distinct strains, type, veinbanding and mild, were differentiated by host range and serology. The three strains infected 17/38, 18/37 and 10/35 legume species, and 11/21, 7/21 and 3/19 non-legume species, respectively. The viruses were propagated in cowpea and assayed in Chenopodium amaranticolor. Isolates of all three strains had similar in vitro properties: dilution end point between 10^-3 and 10^-4; thermal inactivation point between 56 and 58 °C; longevity in vitro between 2 and 3 days. Infectivity of sap from frozen leaves was high after 4 wk but much less after 7 wk; infectivity was largely precipitated by 50% acetone but inactivated by 50% ethanol. High yields of virus were consistently obtained from cowpea by extracting systemically infected leaves in 0.5 m sodium citrate containing 1% mercaptoethanol (pH 8.1), and clarifying with 8.5 ml n-butanol/100 ml sap. Virus preparations contained numerous unaggregated and aggregated virus particles c. 750 nm long and contained components with sedimentation coefficients (s°_{20, w}) of 150S and 175S (presumably unaggregated and aggregated particles, respectively). CAMV is serologically distantly related to bean common mosaic virus, but not to bean yellow mosaic or eight other morphologically similar viruses. It is a typical but distinct member of the potato virus Y group.     

Characterization of Peanut Stripe Virus Isolates from Soybean in Taiwan

Potyvirus isolates were obtained in Taiwan from soybean showing crinkle, mottle, mosaic or blistering. They were identified as peanut stripe virus (PStV) on the basis of host range, serology, molecular weight of the capsid proteins and morphology of cytoplasmic cylindrical inclusions. PStV was found to be closely related serologically to adzuki bean mosaic virus (AzMV), blackeye cowpea mosaic virus (BICMV), and the bean common mosaic virus (BCMV) strain NY 15. A clear differentiation of PStV from these related viruses was possible on the basis of the cylindrical inclusion morphology. Only the peanut isolate of PStV from the USA and the three soybean isolates of PStV from Taiwan produced pinwheels, scrolls and curved laminated aggregates whereas the other serologically related viruses produced scrolls only. Whilst the peanut isolate of PStV infected all nine peanut cvs tested, the soybean isolate PN of PStV infected two peanut cvs only. AzMV, BICMV and two strains of soybean mosaic virus did not infect any of the peanut cultivars tested. On the other hand, nineteen and three of the 27 soybean cvs were susceptible to the soybean isolate PN and the peanut isolate of PStV, respectively. The capsid proteins of the peanut and the three soybean isolates of PStV and of AzMV appeared to be proteolytically undegraded and to have nearly identical molecular weights of 35 kD. Based upon results of virus surveys in soybean plantings in Taiwan, the incidence of soybean isolates of PStV in soybean is similar to that of soybean mosaic virus, suggesting that these PStV strains might be economically significant to soybean production m Taiwan.     

The Use of a Simple Electron Microscope Serology Procedure to Observe Relationships of Seven Potyviruses

The relationships between bean yellow mosaic (BYMV), bean common mosaic (BCMV), clover yellow vein (CYVV), lettuce mosaic (LMV), potato virus Y (PVY), turnip mosaic (TuMV) and celery mosaic (CeMV) viruses were studied in homologous and heterologous reactions, using simple and relatively rapid electron microscope serology decoration tests. The degree of relationship between these viruses was assessed by the intensity of antibody coating when the viruses were decorated by heterologous antibodies. A close relationship was observed between BYMV and CYVV, and between BYMV and LMV but not between CYVV and LMV. CeMV was quite closely related to BYMV and CYVV. Antibodies to BCMV and BYMV intensely decorated different strains of their own virus, but decoration was negligible in cross reactions.     

Occurrence of latent virus infection in visually-rated cowpea (Vigna unguiculata L. Walp) seedlings

Abstract

The presence of latent infections was studied in five cowpeas varieties. Seeds of the varieties were planted and the seedlings inoculated with antigens from Cucumber mosaic virus (CMV) genus Cucumovirus, Bean common mosaic virus (BCMV) genus Potyvirus (Blackeye cowpea mosaic virus strain), Southern bean mosaic virus (SBMV) genus Sobemovirus and Cowpea mottle virus (CPMoV) genus Carmovirus seven days after planting. Seedlings expressing symptoms were rouged at two weeks after inoculation, while asymptomatic ones were subjected to serological indexing to detect the presence/absence of latent infection. Protein A-sandwich enzyme-linked immunosorbent assay (PAS ELISA) was employed for the serological detection of CMV, SBMV and CPMoV, while antigen-coated plate (ACP) ELISA was used to detect BCMV in the asymptomatic plants. Cowpea seedlings without virus symptoms but with positive serological reactions were considered as being latently infected. All of the inoculated TVu 1272 and SuVita-2 plants showed symptoms consistent with CMV and CPMoV infections, respectively. The rate of CMV latent infection was high in TVu 1179 (14.5%), low in SuVita-2 (1.3%) but not recorded in TVu 1272.     

Interference Between Two Strains of Bean Common Mosaic Virus is Accompanied by Suppression of Symptoms Without Affecting Replication of the Challenging Virus

An unusual type of interference between two strains of bean common mosaic virus, viz. NY15 and NL3, infecting bean plants, was investigatred. Wdhen a primary leaf was inoculated with NY15 as inducer and 1–8 days later, the opposite leaf with NL3 as challenger, the plant did not develop symptoms characteristic of NL3, i.e. systemic necrosis in the top, stem and wilting and withering of the youngest trifoloclate leaves. A7-h interval between the inoculations with inducer and challenger already sufficed to reduce the number of plants showing NL3 symptoms. Surprisingly, the amount of NL3 in the challenge-inoculated leaf was always than that in the singly infected control, Furthermore, NY15 could not be detected in the opposite leaf until 8 days post-inoculation and appered enen later in that leaf when challenge-inoculated. Histological studies showed that NL3 appered later in the xylem of bothe the petiole and stem between primary leaves and first trifoliolate leaf, as compared with the singly inoculated control.
The results suggest that suppression of Nl3 symptoms by Ny15 is not caused by impeding its multiplication, but by delaying the transport of NL3 to the xylem of petiole and stem.     

A mosaic disease of cowpea (Vigna sinensis Endl.)

A mosaic disease of cowpea ( Vigna sinensis Endl.), prevalent in the bean-growing regions of China, is described.
The characteristic symptoms of the disease are conspicuous mosaic patterns, deformation and distortion of leaves and stunting of the plant.
The cowpea mosaic virus is transmitted by Aphis rumicis L., Macrosiphum pisi Kalt. and Aphis gossypii Glov. It is also transmitted by artificial juice inoculation. The virus is seed-bome. It withstands ageing m vitro for 3 days at 220 C. Its inactivation temperature is approximately 62° C. its tolerance to dilution is about 1: 3000.
Cowpea mosaic virus infects lima bean and Adzuki bean in addition to cowpea.
The relation of this virus to cowpea mosaic virus described by McLean and asparagus-bean mosaic virus described by Snyder is discussed.     

Patterns of accumulation of Bean common mosaic virus in Phaseolus vulgaris genotypes nearly isogenic for the I locus

The I locus of Phaseolus vulgaris is genetically and phenotypically well described, conferring incompletely dominant, temperature‐dependent resistance against viruses currently assigned to at least four Potyvirus species. Despite the fact that the resistance allele at this locus, the I gene, has been incorporated into nearly all bean germplasm worldwide, little is known regarding its resistance mechanism. In the present study, P. vulgaris lines nearly isogenic for I were challenged with Bean common mosaic virus (BCMV; genus Potyvirus) in order to investigate at the cellular level the temperature‐dependent resistance reaction. Immunolocalisation and confocal laser scanning microscopy were employed to visualise the virus and to identify patterns of BCMV accumulation in resistant, susceptible and heterozygous genotypes. Virus was detected in all three genotypes regardless of temperature, supporting previous findings that BCMV accumulates in protoplasts containing the I allele. Genotype‐specific and temperature‐specific patterns of virus accumulation suggested a resistance mechanism that depends on host recognition of viral replication and/or local movement.     

Resistance to cucumber mosaic virus in potato

Reactions to two subgroup I isolates (Fny-CMV and Pf-CMV) and two subgroup II isolates (A9-CMV and LS-CMV) of cucumber mosaic virus (CMV) were studied in three non tuber-bearing wild potato species (Solanum spp.) of the series Etuberosa, and in two tuber-bearing interspecific potato hybrids and four potato cultivars using graft-inoculation. Three classes of phenotypic reactions (susceptible, hypersensitive, extreme resistance) were observed in the tuber-bearing genotypes. Susceptible genotypes developed mosaic or severe mosaic with leaf malformation and had high CMV titres. Hypersensitive genotypes developed either top necrosis or vein necrosis and/or necrotic spots on apical leaves, and had low CMV titres. Extremely resistant genotypes had no symptoms and no CMV was detected. The hybrid 87HW13.7 (S. tuberosum×S. multidissectum) developed top necrosis specific to infection with Fny-CMV. The hybrid ‘A6’ (S. demissum×S. tuberosum cv. Aquila) was hypersensitive to all CMV isolates tested. Extreme resistance was not functional against all CMV isolates. Neither hypersensitivity nor extreme resistance were related to the CMV subgroup.     

Occurrence of plantago mottle virus in pea, Pisum sativum, in New York State

Plantago mottle virus (RMV), a member of the tymovirus group, was identified as the causal agent of a disease of pea (Pisum sativum) in New York State. The pea virus isolates were identical in host range and serology to the type strain from Plantago major. In susceptible pea genotypes symptoms were strongly influenced by ambient temperature; high temperature (35^°C) reduced infectivity and suppressed symptoms, whereas low temperature (15 and 25^°C) prolonged the incubation period but favoured the development of conspicuous leaf veinal chlorosis, mottle and necrosis. Resistance to P1MV was found in seventeen of twenty-five domestic pea cultivars and in two of twelve foreign introductions. Many of the P1MV-resistant lines were resistant also to bean yellow mosaic virus. The use of resistant cultivars and the apparent limited conditions for efficient transmission of this virus have minimized its importance to pea crops in New York State.     

Strobilurins Seed Treatment Enhances Resistance of Common Bean Against Bean common mosaic virus

Commercial formulations of strobilurins (azoxystrobin, kresoxim‐methyl, trifloxystrobin and pyraclostrobin) were evaluated for their efficacy against Bean common mosaic virus (BCMV) in screenhouse and field conditions. Highest seed germination and seedling vigour were recorded with 20 μg/ml pyraclostrobin seed treatment in comparison with the control. In screenhouse studies, 76% protection against BCMV was recorded with pyraclostrobin seed treatment at 10 μg/ml. Under field conditions with natural BCMV inoculum, pyraclostrobin seed treatment resulted in 65% protection against BCMV. The protection offered by strobilurins against BCMV was evaluated by ELISA, with lowest immunoreactive values recorded in common bean seedlings raised from seeds treated with pyraclostrobin and kresoxim‐methyl. Strobilurins in addition to exerting a direct positive physiological effect on common bean plants also protect bean plants against BCMV infection in screen house and field conditions. Thus, it is proposed that these reduced‐risk pesticides are potential inducers against BCMV and growth enhancers and could be a beneficial component of integrated disease management of common bean.