Avoiding Secondary Leaf Fall Disease of Rubber by Chemical Defoliation

Abstract

An intensive survey of cultivated plants throughout the island of Montserrat resulted in the identification of a number of viruses. Squash mosaic virus was found in cantaloupe, pumpkin and squash. There were cases of multiple infection of pumpkin and squash by cucumber and squash mosaic viruses. Potato virus Y was recovered from pepper and tomato. Bean yellow mosaic and cowpea mosaic viruses were found in red kidney bean and string bean while cowpea mosaic virus was found in cowpea and broad bean (Jamaica bean). Other viruses that were previously identified on the basis of field symptomatology were confirmed by host range and serology. Viruses were not recovered from sea island cotton or from sweet potato, although field symptoms on the sweet potato are similar to those caused by sweet potato mosaic virus. The leaf tissues of crop plants were inoculated to a wide range of indicator plants. Some of those that reacted systemically were examined by electron microscopy for virus particles and the sap extracted from them was used in serodiagnostic assays for virus identification. This is the first attempt to identify positively the viruses of crop plants on the island.     

Cowpea aphid-borne mosaic potyvirus: A review

Cowpea aphid-borne mosaic potyvirus (CABMV) is a cosmopolitan, economically significant seed-borne virus of cowpea. It can cause a yield loss of 13 - 87% under field conditions depending upon crop susceptibility, virus strain and the environmental conditions. CABMV has spread world-wide through the exchange of virus-infected germplasm material. The virus-infected seed provides the initial inoculum and aphids are responsible for the secondary spread of the disease under field conditions. The virus symptoms vary with the cowpea genotype and virus strain. Excellent sources of resistance are available for the breeding of resistant cultivars. Resistance in cowpea is conferred by either a dominant or a recessive gene. Enzyme-linked immunosorbent assay (ELISA) is the most appropriate method for the detection of the virus in the seed or plant tissue for seed certification programmes. Production of virus-free seed is another control option. Given the significance of the disease and the large area under cowpea cultivation in the world, we review knowledge of various aspects of the disease.     

Rhizobacteria‐mediated resistance against the blackeye cowpea mosaic strain of bean common mosaic virus in cowpea (Vigna unguiculata)

BACKGROUND: The present study investigated the effect of seven Bacillus‐species plant‐growth‐promoting rhizobacteria (PGPR) seed treatments on the induction of disease resistance in cowpea against mosaic disease caused by the blackeye cowpea mosaic strain of bean common mosaic virus (BCMV). RESULTS: Initially, although all PGPR strains recorded significant enhancement of seed germination and seedling vigour, GBO3 and T4 strains were very promising. In general, all strains gave reduced BCMV incidence compared with the non‐bacterised control, both under screen‐house and under field conditions. Cowpea seeds treated with Bacillus pumilus (T4) and Bacillus subtilis (GBO3) strains offered protection of 42 and 41% against BCMV under screen‐house conditions. Under field conditions, strain GBO3 offered 34% protection against BCMV. The protection offered by PGPR strains against BCMV was evaluated by indirect enzyme‐linked immunosorbent assay (ELISA), with lowest immunoreactive values recorded in cowpea seeds treated with strains GBO3 and T4 in comparison with the non‐bacterised control. In addition, it was observed that strain combination worked better in inducing resistance than individual strains. Cowpea seeds treated with a combination of strains GBO3 + T4 registered the highest protection against BCMV. CONCLUSION: PGPR strains were effective in protecting cowpea plants against BCMV under both screen‐house and field conditions by inducing resistance against the virus. Thus, it is proposed that PGPR strains, particularly GBO3, could be potential inducers against BCMV and growth enhancers in cowpea. Copyright © 2009 Society of Chemical Industry     

Southern bean Mosaic Virus the Causal Agent of a New Disease of Phaseolus vulgaris beans in Spain

Southern bean mosaic virus (SBMV) has been identified as the cause of a new disease in greenhouse-cultivated common bean (Phaseolus vulgaris), in the south-east of Spain. The identification was based on host range comparisons, morphological and serological characteristics of the virus, the size of its dsRNA species and the nucleotide sequence of an 810-bp fragment from ORF2. The virus could be clearly discriminated from the related sobemovirus Southern cowpea mosaic virus. This is the first report of SBMV in Spain.     

Relationships between co-infection with cowpea aphid-borne and cucumber mosaic viruses and yield of cowpea lines with varying resistance to these viruses

The effect of mixed infection of cowpea aphid-borne mosaic (CAMV) and cucumber mosaic (CMV) viruses on cowpea yield varied with the resistance levels of cowpea lines, since there was a strong interaction between the latter and virus infection types atP ≤ 0.01. In cowpea line TVu 3629, with low resistance to both viruses, mixed infection significantly(P ≤ 0.05) reduced most yield components as compared with single infections and uninoculated controls. However, in line TVu 15656, which is highly resistant to both viruses, the effect of mixed infections was not significantly different from that of single infections or from the control. Between these two extremes were cowpea lines TVu 13683 and TVu 410, which were mildly resistant to CMV and CAMV, respectively; single infections significantly reduced the yield components relative to control, although these were generally not different from mixed infections. CMV, hitherto considered to be not economically important in cowpea in Nigeria, could induce severe yield losses when present in mixed infection with CAMV in cowpea lines with low resistance to both viruses. However, since mixed infection did not affect the yield of the highly doubly-resistant TVu 15656 cowpea line, it may be possible to breed for combined resistance to both viruses.     

北京菜豆(Phaseolus Vulgaris)上的一种新病毒—和性黄色花叶病毒

 从北京郊区患有类似花叶病害的菜豆株上分离到一种线条状病毒(长约700至750nm)并于1983至1986年间加以研究。在温室内接种可以侵染菜豆、蚕豆、豌豆、大豆、决明、苋色藜及昆诺藜而不能侵染被接种的任何茄科植物.同标准的菜豆普遍花叶病毒(BCMV)相比,它不侵染茄科植物例如黄花烟(Nicotiana rustica)和矮牵牛(Petunia hybrida)在菜豆叶上也不产生坏死枯斑.此外它能侵染蚕豆、大豆、豌豆及决明而BCMV则不能.BCMV能侵染豇豆而这一分离物则不能.此分离物的物理性状为:钝化温度=56-580℃(十分钟),硫释限点=10^-3至10^-4,180℃下存治期为3天,A260/280=1.12.菜豆受侵叶组织易用光学显微镜观察到内含体包括一种片层叠合体.在电镜下超薄切片中可以看到风轮状体.极易用汁液摩接及用桃蚜(Myzus persic(接种.此病毒的衣壳蛋白亚基的分子量经测定为32,000道尔顿.此病毒与下列病毒即菜豆普通花叶病毒,菜豆黄色花叶病毒,黑眼豇豆花叶病毒,豌豆种传花叶病毒,三叶草黄脉病毒,莴苣花叶病毒及甜菜花叶病毒的抗血清均无反应.由于它在菜豆的"一窝猴"品种的叶片上产生沿脉黄色小点,因此认为这是一种新的独立的病毒,称之为菜豆和性黄色花叶病毒.     

Detection and identification of seed-borne viruses from cowpea (Vigna unguiculata (L.) Walp.) germplasm

Seedlings from 182 cowpea ( Vigna unguiculata ) pre-introductions/germplasm accessions from 12 countries were tested under greenhouse conditions for six seed-borne viruses. Twenty-one (13.3%) accessions from eight countries were found to be seed-infected with one of the three following viruses: blackeye cowpea mosaic (BlCMV) and cowpea aphid-borne mosaic (CABMV) potyviruses, and cucumber mosaic cucumovirus (CMV). Natural seed transmission incidence of 0–6.9%, 0–13.3%, and 0–2.0% were determined for BlCMV, CABMV and CMV respectively.   Another set of 2930 cowpea germplasm accessions, mostly from Botswana and Senegal (Africa), were examined under field conditions for detection and identification of seed-borne viruses. Only CABMV was detected in this material. Most of the lines were free from other viruses reported in cowpea seed. Eight isolates of BlCMV and 28 isolates of CABMV were derived from cowpea pre-introductions/germplasm accessions evaluated under greenhouse and field conditions.     

Novel cytopathological structures induced by mixed infection of unrelated plant viruses

ABSTRACT When two unrelated plant viruses infect a plant simultaneously, synergistic viral interactions often occur resulting in devastating diseases. This study was initiated to examine ultrastructural virus-virus interactions of mixed viral infections. Mixed infections were induced using potyviruses and viruses from other plant virus families. Novel ultrastructural paracrystalline arrays composed of co-infecting viruses, referred to as mixed virus particle aggregates (MVPAs), were noted in the majority of the mixed infections studied. When the flexuous rod-shaped potyvirus particles involved in MVPAs were sectioned transversely, specific geometrical patterns were noted within some doubly infected cells. Although similar geometrical patterns were associated with MVPAs of various virus combinations, unique characteristics within patterns were consistent in each mixed infection virus pair. Centrally located virus particles within some MVPAs appeared swollen (Southern bean mosaic virus mixed with Blackeye cowpea mosaic virus, Cucumber mosaic virus mixed with Blackeye cowpea mosaic virus, and Sunn hemp mosaic virus mixed with Soybean mosaic virus). This ultrastructural study complements molecular studies of mixed infections of plant viruses by adding the additional dimension of visualizing the interactions between the coinfecting viruses.     

Detection,isolation and characterization of cowpea mosaic virus in Egypt

Journal of Plant Diseases and Protection - Cowpea mosaic virus is among the most economically important viruses infecting cowpea. Incidence of infection was assessed in two governorates in Egypt,...     

Direct electron microscopy and serology with plant viruses in leaf material dried and stored over calciumchloride

Most of 43 viruses could easily be detected directly in 53 out of 66 leaf samples dried and stored over CaCl₂ for varying periods of time up to 20 1/2 years. Detection usually was with PTA pH 6.5, but alfalfa mosaic, cucumber mosaic and tomato aspermy viruses required PTA pH 3.0 to 4.0. Bean common mosaic, cowpea aphid-borne mosaic and cowpea mosaic viruses were also easily observed in newly dehydrated samples obtained for diagnosis from Morocco and Tanzania.Broad bean wilt virus, cowpea mosaic virus and cucumber mosaic virus were detected with agar gel-diffusion tests in dry leaf material ground in buffer. This serological assay demonstrated a high concentration of cucumber mosaic virus in leaf material dried over CaCl₂ 20 years ago. This paper further coroborates the value of the CaCl₂ method of dehydration and storage of plant viruses in leaf material.Samenvatting Zeer uiteenlopende plantevirussen kunnen goed worden bewaard in bladmateriaal van geïnfecteerde planten dat is gedroogd en bewaard boven CaCl₂. Bij rechtstreekse elektronenmicroscopische toetsing van 66 monsters met verschillende isolaten van 43 virussen konden in 53 monsters gemakkelijk virusdeeltjes worden waargenomen (Tabel 1 en Fig. 1 en 2). Meestal lukte dit met fosforwolfraamzuur pH 6,5 dat doorgaans voor in ruw plantesap voorkomende virussen wordt gebruikt. Bij luzernemozaïekvirus en komkommermozaïek virus gelukte dit alleen maar bij lagere pH (3,0 en 4,0). Ook het tomate-aspermievirus was dan veel gemakkelijker aantoombaar. Methylaminewolfraamzuur gaf geen beter resultaat.Draden van bonerolmozaïekvirus en van cowpea aphid-borne mosaic virus en bolletjes van cowpea mosaic virus waren snel waarneembaar in elektronenmicroscopische preparaten gemaakt van bladmateriaal van recent uit Marokko en Tanzania ontvangen monsters.Cowpea mosaic virus, tuinboneverwelkingsvirus en komkommermozaïekvirus konden eveneens gemakkelijk en snel serologisch worden aangetoond in met bufferoplossing vermalen droog blad van respectievelijk cowpea, erwt en tabak. Het laatstgenoemde, reeds 20 1/2 jaar geleden gedroogde bladmateriaal, bleek in vergelijking met pas geïnoculeerd vers blad van komkommer enChenopodium quinoa zelfs zeer veel serologisch actief virusmateriaal te bevatten (Fig. 3).De beschreven waarnemingen bevestigen nogmaals de waarde van de toegepaste methode van virusbewaring en tonen aan dat het mogelijk is vele virussen te herkennen in van elders ontvangen gedroogde bladmonsters, zonder het risico te lopen van virusontsnapping, zoals altijd aanwezig bij werk met toetsplanten in de kas.Guestworker from Istituto Sperimentale per la Patologia Vegetale, Rome, Italy, participating in the investigations from September 21 to December 21, 1977.     

Identification of blackeye cowpea mosaic virus from germplasm of yard-long bean and from soybean,and the relationships between blackeye cowpea mosaic virus and cowpea aphid-borne mosaic virus

Two potyvirus isolates, one from germplasm of yard-long bean (Vigna unguiculata ssp.sesquipedalis) introduced into the Netherlands, and another one from soybean plants (Glycine max) in Indonesia, were compared with two virus isolates of blackeye cowpea mosaic virus (BICMV) from the USA and a Moroccan isolate of cowpea aphid-borne mosaic virus (CAMV). It is proposed that all five isolates be now considered BICMV on the basis of host ranges, symptoms and serology. From our results, and a reassessment of the literature it is suggested to drop the name CAMV in favour of BICMV.Samenvatting Twee potyvirussen, de een in Nederland ingevoerd met genenmateriaal vanVigna unguiculata ssp.sesquipedalis en de ander uit planten van sojaboon (Glycine max) in Indonesië, werden vergeleken met twee isolaten van blackeye cowpea mosiac virus (BICMV) en een Marokkaans isolaat van cowpea aphid-borne mosaic virus (CAMV). Op grond van waardplantenreeksen, symptomen en serologie stellen de auteurs voor om alle vijf isolaten te beschouwen als BICMV. Gebaseerd op de verkregen resultaten en een kritische beschouwing van de literatuur wordt de aanbeveling gedaan om de naam CAMV te laten vallen ten gunste van BICMV.     

Sources of genetic resistance in cowpea (Vigna unguiculata (L.) Walp.) to cowpea aphid-borne mosaic potyvirus

Fifty-one cowpea (Vigna unguiculata (L.) Walp.) genotypes were tested by mechanical inoculation with seven geographically diverse isolates of cowpea aphid-borne mosaic potyvirus to identify resistant sources. Of 51 genotypes three, TVu-401, TVu-1582 and TVu-1593 were found immune to all the seven isolates. Forty-five genotypes gave different reactions to individual isolates. Several immune, resistant and tolerant genotypes against each isolate were identified. A considerable evidence of pathogenic variability among the virus isolates was also observed.     

检测植物病毒的三种血清学方法敏感性的比较

 以芋花叶病毒和豇豆花叶病毒为试验材料,进行了酶联免疫吸附试验,免疫吸附电子显微术和点免疫结合试验检测植物病毒的敏感性的研究。无论是检测感染组织粗汁液还是纯化的病毒,点免疫结合试验均优于酶联免疫吸附试验和免疫吸附电子显微术。在使用羟基吲(口乃木)磷酸盐和氮蓝四唑为碱性磷酸酶的底物时,点免疫结合试验检测纯化的豇豆花叶病毒的可测感度为0.35ng,芋花叶病毒为0.83ng。对三种检测植物病毒的血清学方法进行了比较,并讨论了点免疫结合试验的优点。     

Infection and necrosis of cowpea mesophyll cells by tobacco necrosis virus and two strains of tobacco mosaic virus

When cowpea mesophyll tissue with or without any epidermal layer was inoculated with tobacco necrosis virus (TNV), local necrotic lesions were produced. In epidermal strips isolated after inoculation of intact leaves local lesions were never observed. Homogenates of epidermal strips removed within 30 min after inoculation of the leaf with the cowpea strain of tobacco mosaic virus (Cp-TMV) or with TNV and incubated on agar for 2 or 4 days were not infectious. However, when clusters of mesophyll cells or vein pieces were still attached to the epidermal strips after stripping, the homogenates showed virus activity. When cowpea leaves were inoculated with Cp-TMV or a common strain of TMV (TMV-U) infective virus material was present in the mesophyll tissue as measured in the homogenates, at the moment of stripping, i.e. within 10 min after inculation.It may be concluded that cowpea mesophyll cells can act as primary sites of viral ingress into the leaf and that the epidermis is not required for necrosis production after virus inoculation.Samenvatting De mogelijkheid werd onderzocht om cowpea-mesofylcellen zonder de aanwezigheid van epidermiscellen met TNV te infecteren. Kleine lokale necrotische lesies werden 40–72 uur na inoculatie zichtbaar waaruit blijkt, dat bij cowpea de epidermis niet noodzakelijk is voor de vorming van TNV-lesies. Geïsoleerd epidermisweefsel vertoonde nooit lokale lesies. Homogenaten van met TNV geïnoculeerde en daarna geïsoleerde cowpea-epidermisstukjes werden getoetst op virusactivitiet. Als de stukjes volledig vrij waren van mesofylcellen of nerfweefsel, dan vond daarin geen virusvermeerdering plaats tijdens een incubatie van 2 of 4 dagen op agar. Als na het strippen nog enkele mesofylcellen of nerfstukjes aanwezig waren, kon wel enige virusactiviteit in de homogenaten worden aangetoond.In cowpeabladeren die geïnoculeerd werden met de cowpea-stam van TMV of de normale stam van TMV had infectieus virusmateriaal al binnen 10 min na inoculatie het mesofyl bereikt. Blijkbaar is in cowpeabladeren de epidermis niet noodzakelijk voor de binnenkomst van virus of voor de necroseproduktie na virusinoculatie.     

Infectivity analysis of a soybean isolate of Mungbean yellow mosaic India virus by agroinoculation

Yellow mosaic disease (YMD) of legumes endemic to South Asia are caused by begomoviruses transmitted by whiteflies. Based on molecular characterization, two distinct viruses – Mungbean yellow mosaic India virus (MYMIV) and Mungbean yellow mosaic virus (MYMV) – were found previously to be the etiological agents of YMD in legumes. Here, host range studies with a soybean isolate of MYMIV (MYMIV-[Sb]) were carried out by both whitefly transmission and agroinoculation. MYMIV-[Sb] was similar to a cowpea isolate of MYMIV (MYMIV-[Cp]) in its ability to infect cowpea, thus differing from blackgram (MYMIV) and mungbean (MYMIV-[Mg]) isolates, which do not infect cowpea. Genomic analysis of DNA A and DNA B components of these MYMIV isolates show characteristic differences in complete DNA B nucleotide sequence correlating with host range differences.     

RNAi‐based enhanced resistance to Cowpea severe mosaic virus and Cowpea aphid‐borne mosaic virus in transgenic cowpea

Cowpea (Vigna unguiculata) is one of the most important legumes cultivated in many parts of the world. The diseases caused by Cowpea severe mosaic virus (CPSMV) and Cowpea aphid‐borne mosaic virus (CABMV) are considered among the most important constraints on yield and quality, especially in Latin America and Africa. Here, the concept of using an RNA interference construct to silence the CPSMV proteinase cofactor gene and the CABMV coat protein gene is explored, in order to generate resistant transgenic cowpea plants. Ten cowpea transgenic lines were produced, presenting a normal phenotype and transferring the transgene to the next generation. Plants were tested for resistance to both CABMV and CPSMV by mechanical co‐inoculation. Seven lines presented milder symptoms when compared to the control and three lines presented enhanced resistance to both viruses. Northern analyses were carried out to detect the transgene‐derived small interfering RNA (siRNA) in leaves and revealed no correlation between siRNA levels and virus resistance. Additionally, in the symptomless resistant lines the resistance was homozygosis‐dependent. Only homozygous plants remained uninfected while hemizygous plants presented milder symptoms.     

菜豆普通花叶病毒RT-PCR检测及3′末端序列分析

根据哈尔滨地区豇豆感病植株的症状,初步鉴定感染豇豆的病毒为菜豆普通花叶病毒(Bean common mosaic virus, BCMV)。利用马铃薯Y病毒属通用引物扩增出病毒基因组3′末端序列,经BLAST检索表明该病毒为BCMV,将该序列与GenBank上的21个BCMV分离物的3′末端序列进行比较,显示其核苷酸序列与其他分离物的序列同源性为91.7%～97.3%。系统进化分析显示不同分离物可聚为5个类群,并显示出一定的寄主相关性。哈尔滨分离物BCMV X与2个浙江分离物、1个澳大利亚分离物聚为一支,且该4株分离物的寄主均为豇豆。RNA二级结构分析显示BCMV基因组3′末端非编码区形成4个茎环结构,不同分离物的序列变化并未引起茎环结构的明显变化。     

Effect of Figaren, an Antiviral Protein from Cucumis figarei, on Cucumber mosaic virus Infection

Local lesion formation on cowpea leaves was more than 50% inhibited by treatment with a 23 kDa RNase-like glycoprotein from Cucumis figarei, figaren, from 24 hr before to 1 hr after inoculation with Cucumber mosaic virus (CMV). CMV accumulation detected by ELISA in tobacco leaves treated with figaren 6 or 0 hr before inoculation with CMV was suppressed. When upper leaves of tobacco plants were treated with figaren and inoculated 10 min later with CMV, mosaic symptoms were delayed for 5–7 days on most of the tobacco plants, and some plants remained asymptomatic. From fluorescence in situ hybridization, infection sites were present in figaren-treated cowpea or melon leaves after inoculation with CMV, though the sites were reduced in number and size compared with those in water-treated control leaves. The amount of CMV RNAs and CMV antigen in melon protoplasts inoculated with CMV and subsequently incubated with figaren similarly increased with time as did that in the control. ELISA and local lesion assays indicated that CMV infection on the upper surfaces of the leaves of tobacco, melon, cowpea and C. amaranticolor whose lower surfaces had been treated with figaren 5–10 min before CMV inoculation was almost completely inhibited. Figaren did not inhibit CMV infection on the opposite untreated leaf halves of melon, cowpea and C. amaranticolor, whereas it almost completely inhibited CMV infection on the untreated halves of leaves of tobacco. CMV infection was not inhibited in the untreated upper or lower leaves of the four plants. These data suggest that figaren does not completely prevent CMV invasion but does inhibit the initial infection processes. It may also induce localized acquired resistance in host plants. Received 10 October 2000/ Accepted in revised form 6 February 2001