Incidence of pea seedborne mosaic virus pathotypes in the US National Pisum germplasm collection

One hundred and eighty-nine isolates of pea seedborne mosaic virus (PSbMV) were obtained from seedlings of 435 pea (Pisum sativum) germplasm introductions originally acquired from India, Turkey, Latin America and Europe. Fifty-eight per cent of the isolates were identified as belonging to pathotype P-1, 22% to pathotype P-4, and 7% to the mild form of the lentil pathotype L-1. Some isolates could not be classified into any known pathotype and need further study. No isolate appeared to present a threat to peas beyond that already known to exist with previously described forms of the virus.     

Mutations in pea seedborne mosaic virus genome-linked protein VPg after pathotype-specific virulence in Pisum sativum

Pisum sativum plant introduction (PI) line 269818 is resistant to potyvirus pea seedborne mosaic virus (PSbMV) isolates, categorized as pathotype P1, and is susceptible to pathotype P4 isolates. This difference in infectivity is determined by the viral genome-linked protein (VPg) cistron. Mutational analysis of VPg of PSbMV isolates DPD1 and NY representing pathotypes P1 and P4 revealed that codon changes affecting amino acids 105 to 117 in the central region of VPg influenced virulence on PI 269818. In contrast, infectivity on pea cultivar Dark Skinned Perfection, which is susceptible to both pathotypes, was not affected by the mutations. Mutants overcoming resistance in PI 269818 were analyzed for changes in the VPg coding region upon passage through PI 269818 and Dark Skinned Perfection. Adaptive changes were observed only upon passage through PI 269818 and only at codons from amino acid 105 to 117. Expression of DPD1 VPg in PI 269818 did not affect infection by NY, which suggests that VPg from DPD1 is not an elicitor of a general resistance response. The results are compatible with the hypothesis that viral amplification depends upon the interaction between VPg and a host factor.     

Structure-based mutational analysis of eIF4E in relation to sbm1 resistance to pea seed-borne mosaic virus in pea

Background

Pea encodes eukaryotic translation initiation factor eIF4E (eIF4E^S), which supports the multiplication of Pea seed-borne mosaic virus (PSbMV). In common with hosts for other potyviruses, some pea lines contain a recessive allele (sbm1) encoding a mutant eIF4E (eIF4E^R) that fails to interact functionally with the PSbMV avirulence protein, VPg, giving genetic resistance to infection.

Methodology/Principal Findings

To study structure-function relationships between pea eIF4E and PSbMV VPg, we obtained an X-ray structure for eIF4E^S bound to m⁷GTP. The crystallographic asymmetric unit contained eight independent copies of the protein, providing insights into the structurally conserved and flexible regions of eIF4E. To assess indirectly the importance of key residues in binding to VPg and/or m⁷GTP, an extensive range of point mutants in eIF4E was tested for their ability to complement PSbMV multiplication in resistant pea tissues and for complementation of protein translation, and hence growth, in an eIF4E-defective yeast strain conditionally dependent upon ectopic expression of eIF4E. The mutants also dissected individual contributions from polymorphisms present in eIF4E^R and compared the impact of individual residues altered in orthologous resistance alleles from other crop species. The data showed that essential resistance determinants in eIF4E differed for different viruses although the critical region involved (possibly in VPg-binding) was conserved and partially overlapped with the m⁷GTP-binding region. This overlap resulted in coupled inhibition of virus multiplication and translation in the majority of cases, although the existence of a few mutants that uncoupled the two processes supported the view that the specific role of eIF4E in potyvirus infection may not be restricted to translation.

Conclusions/Significance

The work describes the most extensive structural analysis of eIF4E in relation to potyvirus resistance. In addition to defining functional domains within the eIF4E structure, we identified eIF4E alleles with the potential to convey novel virus resistance phenotypes.     

Marker assisted pea breeding: <Emphasis Type="Italic">eIF4E</Emphasis> allele specific markers to <Emphasis Type="Italic">pea seed-borne mosaic virus</Emphasis> (PSbMV) resistance

Traditional plant breeding relies upon crosses and subsequent selection of genotypes to meet desirable traits. The incorporation of marker-assisted selection into breeding strategies would result in a reduction in the number of offspring to be propagated, selected and tested. In the case of pea (Pisum sativum L.), the testing of resistance to viral pathogens such as pea seed-borne mosaic virus (PSbMV) is included in the breeding process. Resistance to the common strains of PSbMV is conferred by a single recessive gene (eIF4E), localized on LG VI (sbm-1 locus). We have analyzed for variation in the eIF4E genomic sequences from 43 pea varieties and breeding lines, reported as donors of resistance. This enabled a comprehensive investigation of the eIF4E gene structure and mutations responsible for PSbMV resistance were identified. Subsequently, PCR-based and gene-specific single nucleotide polymorphism and co-dominant amplicon length polymorphism markers were developed. All together 60 accessions were analyzed using sequence data and/or allele specific DNA markers. Developed allele specific markers were reproducibly amplified across a broad spectra of pea varieties and breeding lines. These were found to be 100% accurate in detecting the presence of the respective alleles when compared to symptomology and ELISA, testing (74% reliable). Hence, these molecular markers will substantially speed-up PSbMV diagnosis and resistance breeding processes in pea.     

Improvements in the detection of pea seed-borne mosaic virus by ELISA

The detection by ELISA of pea seed-borne mosaic virus (PSbMV) in pea leaves and seeds was improved by the addition of cellulase or Triton X-100 to the extraction fluid, probably because the additives aided the release of virus particles from host materials. With leaf extracts the additives were most effective at 0.1%. In initial tests cellulase was used with macerozyme, but the latter enzyme was then shown to decrease the effectiveness of cellulase. Triton X-100 was as effective as cellulase and the absorbance values obtained in ELISA of infected leaf extracts, diluted to 1/10 in extraction fluid containing the additive, were about six times greater than those of infected extracts diluted in normal extraction fluid. Five named isolates of PSbMV, in addition to the homologous isolate, were readily detected in infected leaves extracted in fluid containing Triton X-100. In tests on seeds and seedlings of seven infected seed lots of pea cv. Waverex, using Triton X-100 in the extraction fluid, PSbMV was detected in five times as many seeds as seedlings, probably mainly because in many infected seeds the virus was in the testa and not in the embryo. About 9% of infected seedlings were without recognisable symptoms 4 wk after emergence.     

Loss of genetic diversity in pea germplasm by the elimination of individuals infected by pea seedborne mosaic virus

Significant reduction of genetic diversity was observed in seed coat colour and electrosphoretic isozyme genotypes when infected plants were eliminated in genetically heterogeneous pea populations. Some accessions where genetic homogeneity was expected were apparently mixtures. Detection of latent infections by pea seedborne mosaic virus by the ELISA method was more effective on single-plant samples than on bulked samples of four to five plants, and from older plants rather than young seedlings. The implication of these findings in relation to a virus eradication programme in plant germplasm collections are discussed.     

An eclipse of pea seed-borne mosaic virus in vegetative tissue of pea following repeated transmission through the seed

Four isolates of pea seed-borne mosaic virus (PSbMV) representing pathotypes P1 (isolates US and Q) and P4 (isolates S4 and S6), and groups III (US and Q) and V (S4 and S6) have been used in a study of the survival and partitioning of PSbMV under conditions of continuous seed transmission in the commercial pea cultivar Dundale. Assays suitable for detecting virus in small tissue samples were developed, and included dot-immunobinding assay with antisera to both PSbMV and cytoplasmic inclusion body (CIB) protein, and dot hybridisation assay (DHA) with cDNA transcribed from virus RNA. Under the conditions of our experiments, seed transmission occurred at rates exceeding 90% for all virus isolates. Virus was detectable by serology and symptoms in inoculated plants, and in all vegetative tissue of second generation plants raised from seed of the inoculated plants. However, in the third, fourth and fifth sequential generations raised from seed, all plants were symptomless. Neither virus nor CIB were detectable in leaf, stem or roots by serology, but both were readily detectable in some floral parts, and in immature and mature seed. Mature seed contained virus and CIB antigen in the testa, cotyledon and embryo. Inoculum prepared from whole seeds was infectious. The testa was shown not to be involved in transmission between generations, thus implicating the embryo alone in vertical transmission. Virus antigen could not be detected in the emerging cotyledons of germinating seed and all true leaves by serology, but the leaves contained PSbMV RNA detectable by DHA. These results show that PSbMV infection can be transferred through the vegetative phase at a subliminal level, and reaches relatively high concentrations in floral parts and seeds. Thus PSbMV may be maintained at a high level of infection in seed in the absence of any apparent symptoms in the plant, and without a requirement for horizontal transmission between plants by vectors. Such a mechanism may explain the high levels of infection commonly reported in pea breeding lines.     

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.     

Contrasting patterns in the spread of two seed-borne viruses in pea embryos

The temporal and spatial patterns of pea seed-borne mosaic potyvirus (PSbMV) and pea early browning tobra-virus (PEBV) accumulation in pea embryos were analyzed using in-situ hybridization and immunohistochemistry. For PSbMV, which infects embryos after fertilization, the distribution changed as the embryo developed and some tissues remained free of virus infection. In contrast, embryos were uniformly infected with PEBV from the earliest stages of embryo development, and PEBV was detected in the egg cell and pollen grains, indicative of gametic transmission into the embryo. These observations suggest that gametically transmitted viruses may be appropriate as potential vectors for the ectopic and uniform expression of novel genes in embryonic tissues. Functional complementarity in the two processes of embryo invasion was tested following co-inoculation with PSbMV and PEBV. Instead of complementation, interference in PSbMV seed transmission by PEBV was observed; PEBV seed transmission remained unaffected by PSbMV.     

Additional sources of resistance to groundnut rosette disease in groundnut germplasm and breeding lines

Groundnut rosette, a virus disease of groundnut (Arachis hypogaea) transmitted by the aphid, Aphis craccivora Koch, reduces yield in susceptible cultivars by 30–100%. Additional sources were sought in germplasm accessions involving 2301 lines from different sources and from 252 advanced breeding lines derived from crosses involving earlier identified sources of resistance to rosette. The lines were evaluated in field screening trials using an infector row technique during 1996 and 1997 growing seasons. Among the germplasm lines, 65 accessions showed high levels of resistance while 134 breeding lines were resistant. All rosette disease resistant lines were susceptible to groundnut rosette assistor virus. This work identified germplasm and breeding lines that will contribute to an integrated management of groundnut rosette disease. These new sources also provide an opportunity to eliminate yield losses due to the rosette disease.     

Identification of resistance source in wheat germplasm against spot blotch disease caused by Bipolaris sorokiniana

Four hundred and twenty-two spring wheat germplasm (Triticum aestivum L.) lines belonging to Indian, CIMMYT and Chinese wheat programme were evaluated for their tolerance against natural epiphytotic conditions of spot blotch caused by Bipolaris sorokiniana at the hot spot location, Pusa, Bihar, India. Of the 422 entries screened, none of the genotype showed immunity to the disease, whereas 52 were resistant, 180 moderately susceptible, 171 susceptible and 19 highly susceptible. Indian germplasm lines tended to be more susceptible than lines originated from CIMMYT and China. Chirya 3, Chirya 7 and Mayoor from CIMMYT showed high degree of resistance to the disease both under field and polyhouse conditions. On the basis of the disease severity under field conditions, 20 promising resistant genotypes and 10 highly susceptible lines were isolated for further testing under artificial epiphytotic conditions in polyhouse for genetic analysis and their potential for spot blotch resistance breeding.     

Barley yellow mosaic virus is overcoming RYM4 resistance in Belgium

Barley yellow mosaic virus (BaYMV) is the causal agent of a soil-borne systemic mosaic disease on barley. It has been reported in Belgium since the 1980s. The control of this disease is managed almost exclusively through the use of resistant varieties. The resistance of most commercial barley cultivars grown in Europe is conferred mainly by a single recessive gene, rym4. This monogenic resistance provides immunity against BaYMV pathotype 1 and has been mapped on barley chromosome 3HL and shown to be caused by mutations in the translation initiation factor eIF4E. Another pathotype, BaYMV pathotype 2, which appeared in the late 1980s (in Belgium, in the early 1990s), is able to overcome the rym4-controlled resistance. Until recently, this pathotype remained confined to specific locations. During a systematic survey in 2003, mosaic symptoms were observed only on susceptible barley cultivars collected in Belgian fields. BaYMV was detected by ELISA and RT-PCR on the susceptible cultivars and only by RT-PCR on the resistant cultivars. In 2004, mosaic symptoms were observed on susceptible and resistant cultivars. BaYMV was detected by ELISA and RT-PCR on both cultivars. In addition to developing RT-PCR methods for detecting and identifying BaYMV and Barley mild mosaic virus (BaMMV), an RT-PCR targeting the VPg/NIa viral protein part of the genome, known to discriminate the two BaYMV pathotypes, was set up to accurately identify the pathotype(s) now present in Belgium. The sequences from the generated amplicons revealed the single nucleotide substitution resulting in an amino acid change from lysine to asparagine specific to BaYMV pathotype 2. The possible reasons for the change in the BaYMV pathotype situation in Belgium, such as climatic change or a progressive build-up of soil inoculum potential, will be discussed, as well as the use of eIF4E-based resistance.     

The same allele of translation initiation factor 4E mediates resistance against two Potyvirus spp. in Pisum sativum

Pathogenicity of two sequenced isolates of Bean yellow mosaic virus (BYMV) was established on genotypes of Pisum sativum L. reported to carry resistance genes to BYMV and other potyviruses. Resistance to the white lupin strain of BYMV (BYMV-W) is inherited as a recessive gene named wlv that maps to linkage group VI together with other Potyvirus resistances. One of these, sbm1, confers resistance to strains of Pea seedborne mosaic virus and previously has been identified as a mutant allele of the eukaryotic translation initiation factor 4E gene (eIF4E). Sequence comparison of eIF4E from BYMV-W-susceptible and -resistant P. sativum genotypes revealed a polymorphism correlating with the resistance profile. Expression of eIF4E from susceptible plants in resistant plants facilitated BYMV-W infection in inoculated leaves. When cDNA of BYMV-W was agroinoculated, resistance mediated by the wlv gene frequently was overcome, and virus from these plants had a codon change causing an Arg to His change at position 116 of the predicted viral genome-linked protein (VPg). Accordingly, plants carrying the wlv resistance gene were infected upon inoculation with BYMV-W derived from cDNA with a His codon at position 116 of the VPg coding region. These results suggested that VPg determined pathogenicity on plants carrying the wlv resistance gene and that wlv corresponded to the sbm1 allele of eIF4E.     

种子脱水改变豌豆种传花叶病毒在子叶细胞中的稳定性与分布方式

作为种传病原物,豌豆种传花叶病毒（ＰＳｂＭＶ） 必须能承受种胚的干燥脱水过程方能在胚细胞中存活并种传。为了研究ＰＳｂＭＶ承受种胚干燥脱水的机制,比较了该病毒在豌豆（ Ｐｉｓｕｍ ｓａｔｉｖｕｍ Ｌ．） 新鲜胚与干燥胚子叶细胞中的稳定性与分布方式。在新鲜的、未成熟胚的子叶细胞中,ＰＳｂＭＶ的外壳蛋白（ＣＰ） 受到部分降解,该病毒粒体及其ＣＰ在细胞质内呈环核分布。在干燥、成熟的胚的子叶细胞中,ＰＳｂＭＶ的外壳蛋白未受到任何降解,其粒体和ＣＰ不再呈环核分布,而是存在于位于细胞质边缘的多聚体中。免疫金标记电镜检查证明这类多聚体中含有ＰＳｂＭＶ的粒体。很明显,种胚的干燥脱水过程可改变ＰＳｂＭＶ在子叶细胞中的稳定性与分布方式,粒体多聚体的形成可能有助于ＰＳｂＭＶ在干燥脱水的胚细胞中的稳定与存活     

The potyvirus recessive resistance gene, sbm1, identifies a novel role for translation initiation factor eIF4E in cell-to-cell trafficking

From the characterization of the recessive resistance gene, sbm1, in pea we have identified the eukaryotic translation initiation factor, eIF4E, as a susceptibility factor required for infection with the Potyvirus, Pea seed-borne mosaic virus. A functional analysis of the mode of action of the product of the dominant allele revealed a novel function for eIF4E in its support for virus movement from cell-to-cell, in addition to its probable support for viral RNA translation, and hence replication. Different resistance specificities in two independent pea lines were explained by different mutations in eIF4E. On the modelled structure of eIF4E the coding changes were in both cases lying in and around the structural pocket involved in binding the 5'-m7G cap of eukaryotic mRNAs. Protein expression and cap-binding analysis showed that eIF4E encoded by a resistant plant could not bind to m7G-Sepharose, a result which may point to functional redundancy between eIF4E and the paralogous eIF(iso)4E in resistant peas. These observations, together with related findings for other potyvirus recessive resistances, provide a more complete picture of the potyvirus life cycle.     

Studies on the nodulation of strain-specific resistant pea lines using single,mixed and delayed inoculation by Rhizobium leguminosarum

Symbiotic interactions between peas and Rhizobium leguminosarum were investigated by inoculating four pea lines, three of which are strain-specific resistant to the European strain 311d, with various combinations of two strains of Rhizobium, 311d and Tom⁺⁺. The strains were almost equally good to infect the susceptible European cultivar Hero when added singly inoculated. After mixed inoculation (1:1 proportion) strain analysis by ELISA revealed that the nodules were preferentially formed by 311d, although some Tom⁺⁺ nodules were also found mainly on the upper part of the root. Our conclusion is that Tom⁺⁺ is less compatible in comparison with 311d. In addition, we found that as the Hero plants emerged, they were becoming more resistant towards infection with not adapted bacteria. The strain-specific resistant lines from Afghanistan belong to two different systems: Afgh. I, completely resistant to 311d and highly nodulating with Tom⁺⁺, and Afgh. III, incompletely resistant to 311d and poorly nodulating with Tom⁺⁺. Mixed inoculations resulted in nodule depressions, as compared to single inoculations with Tom⁺⁺ ranging from 87% to 14%. The ability of 311d to block infection sites on the roots were found to depend on the degree of symbiotic adaptation between Afgh. I and Tom⁺⁺, respectively Afgh. III and Tom⁺⁺. Strain analysis after double strain inoculation of Afgh. I plants revealed that some nodules were induced by strain 311d. Thus, the presence of Tom⁺⁺ in this case influences the degree of host resistance. However, in Afgh. III plants the resistance towards nodulation were unaffected by the presence of Tom⁺⁺. We suggest that the degree of symbiotic adaptation may change the barrier of resistance towards infection.     

Vegetative Compatibility and Virulence Diversity of <i>Verticillium dahliae</i> from Okra (<i>Abelmoschus esculentus</i>) Plantations in Turkey and Evaluation of Okra Landraces for Resistance to <i>V. dahliae</i>

Forty-four V. dahliae isolates were collected from symptomatic vascular tissues of okra plants each from a different field in eight provinces located in the eastern Mediterranean and western Anatolia regions of Turkey during 2006- 2009. Nitrate-nonutilizing (nit) mutants of V. dahliae from okra were used to determine heterokaryosis and genetic relatedness among isolates. All isolates from okra plants were grouped into two vegetative compatibility groups (VCGs) (1 and 2) and three subgroups as 1A (13.6%, 6/44), 2A (20.5%, 9/44) and 2B (65.9%, 29/44) according to international criteria. Pathogenicity tests were performed on a susceptible local okra (A. esculentus) landrace in greenhouse conditions. All isolates from VCG1A and VCG2B induced defoliation (D) and partial defoliation (PD) symptoms, respectively. Other isolates from VCG2A gave rise to typical leaf chlorosis symptoms without defoliation. The obtained data showed that the virulence level of V. dahliae isolates from okra was related to their VCG belongings. Eighteen okra landraces from diverse geographical origins were screened for resistance to VCG2B and VCG1A of V. dahliae. The results indicated that all landraces were more susceptible to highly virulent VCG1A-D pathotype displaying D or PD symptoms depending on their susceptibility levels with a mean disease severity index of 3.52 than to less virulent VCG2B-PD pathotype of V. dahliae displaying PD and ND symptoms with a mean disease severity index of 2.52. Significant differences were observed among the landraces; however, none of them exhibited a level of resistance. Okra landraces; Çorum, Hatay Has and Şanlıurfa displayed the lowest level of susceptibility or little tolerance to both D and PD pathotypes. VCG2B of PD was prevailing in the surveyed areas and VCG1A of D was the most virulent of the VCGs identified. Introduction of resistant genotypes to Turkish okra germplasm from different sources and breeding new resistant okra cultivars are critical for the sustainability of okra production.     

玉米种质资源抗矮花叶病鉴定

采用摩擦接种方法,鉴定了3995份玉米种质对玉米矮花叶病毒(SCMV-MDB)的抗病性。经重复鉴定,筛选出抗病优良自交系73份,抗病丰产杂交种80份。玉米不同类群种质,对SCMV-MDB的抗病性有明显差异,改良Reid、Lancaster、旅大红骨类群种质大部分表现感病;塘四平头、外杂先锋选系类群种质大多数表现抗病。在不同类型种质中,硬粒型、马齿型和半马齿型表现抗病的较多,糯质型较少,甜质型和爆裂型中尚未发现抗源。     

Analysis of simple sequence repeat markers linked with blast disease resistance genes in a segregating population of rice (Oryza sativa)

Among 120 simple sequence repeat (SSR) markers, 23 polymorphic markers were used to identify the segregation ratio in 320 individuals of an F(2) rice population derived from Pongsu Seribu 2, a resistant variety, and Mahsuri, a susceptible rice cultivar. For phenotypic study, the most virulent blast (Magnaporthe oryzae) pathotype, P7.2, was used in screening of F(2) population in order to understand the inheritance of blast resistance as well as linkage with SSR markers. Only 11 markers showed a good fit to the expected segregation ratio (1:2:1) for the single gene model (d.f. = 1.0, P < 0.05) in chi-square (χ(2)) analyses. In the phenotypic data analysis, the F(2) population segregated in a 3:1 (R:S) ratio for resistant and susceptible plants, respectively. Therefore, resistance to blast pathotype P7.2 in Pongsu Seribu 2 is most likely controlled by a single nuclear gene. The plants from F(2) lines that showed resistance to blast pathotype P7.2 were linked to six alleles of SSR markers, RM168 (116 bp), RM8225 (221 bp), RM1233 (175 bp), RM6836 (240 bp), RM5961 (129 bp), and RM413 (79 bp). These diagnostic markers could be used in marker assisted selection programs to develop a durable blast resistant variety.