Serodiagnosis of Burkholderia mallei Infections in Horses: State‐of‐the‐art and Perspectives

Burkholderia mallei causes glanders or farcy in solipeds, a disease that must be reported to the OIE (Office International des Epizooties, Paris, France). The number of reported outbreaks has increased steadily during the last decade. Serodiagnosis is hampered by the considerable number of false‐positives and ‐negatives of the internationally prescribed tests. The major problem leading to low sensitivity and specificity of complement fixation test (CFT) and enzyme‐linked immunosorbent assay (ELISA) has been linked to the test antigens currently used, i.e. crude preparations of whole cells. Future perspectives for the development and evaluation of serological test kits using well‐characterized single antigens are discussed in the light of recent molecular research on B. mallei and the closely related saprozoonotic agent B. pseudomallei.     

珍黄88(湘椒29号)辣椒的选育

珍黄88的母本6427是从广西地方品种经自交纯化而成的优良黄皮尖椒自交系;父本8215为叶少、部分茎节短缩、肉厚疏松的辣椒高代自交系。该品种中熟,定植至采收青椒约50 d(天),产量2500～2800 kg·(667 m~2)~(-1),抗病毒病,中抗疫病,适于山东、广东等黄皮尖椒外运基地栽培;果实长牛角形,果表黄绿无皱,果型直,肉厚腔小,商品性好,耐贮运。     

Prepenetration stages in infection of clematis by Phoma clematidina

A detailed study of conidial germination, germ-tube growth and the formation of infection structures in Phoma clematidina , the causal agent of clematis wilt, is described for two clematis varieties differing in disease resistance. On both the resistant and susceptible varieties, the fungus entered leaves and stems by direct penetration of the cuticle, often, but not always, following the formation of infection structures. More germ tubes per conidium were formed on the susceptible host, but these germ tubes were on average shorter than on the resistant host. Although germ tubes regularly entered the plant via trichomes, stomata were not found to be sites of entry. Following penetration of the cuticle of resistant plants, germ-tube growth was sometimes restricted to the subcuticular region, and halo formation occurred at the sites where penetration was attempted. Subcuticular growth and halo formation were not observed on susceptible plants. These observations may partly explain the resistance of small-flowered clematis varieties to P. clematidina .     

Sporulation of Pyrenopeziza brassicae (light leaf spot) on oilseed rape (Brassica napus) leaves inoculated with ascospores or conidia at different temperatures and wetness durations

In controlled environment experiments, sporulation of Pyrenopeziza brassicae was observed on leaves of oilseed rape inoculated with ascospores or conidia at temperatures from 8 to 20°C at all leaf wetness durations from 6 to 72 h, except after 6 h leaf wetness duration at 8°C. The shortest times from inoculation to first observed sporulation ( l ₀), for both ascospore and conidial inoculum, were 11–12 days at 16°C after 48 h wetness duration. For both ascospore and conidial inoculum (48 h wetness duration), the number of conidia produced per cm² leaf area with sporulation was seven to eight times less at 20°C than at 8, 12 or 16°C. Values of Gompertz parameters c (maximum percentage leaf area with sporulation), r (maximum rate of increase in percentage leaf area with sporulation) and l ₃₇ (days from inoculation to 37% of maximum sporulation), estimated by fitting the equation to the observed data, were linearly related to values predicted by inserting temperature and wetness duration treatment values into existing equations. The observed data were fitted better by logistic equations than by Gompertz equations (which overestimated at low temperatures). For both ascospore and conidial inoculum, the latent period derived from the logistic equation (days from inoculation to 50% of maximum sporulation, l ₅₀) of P. brassicae was generally shortest at 16°C, and increased as temperature increased to 20°C or decreased to 8°C. Minimum numbers of spores needed to produce sporulation on leaves were ≈25 ascospores per leaf and ≈700 conidia per leaf, at 16°C after 48 h leaf wetness duration.     

Detection and typing of tomato yellow leaf curl viruses

The denomination Tomato yellow leaf curl virus (TYLCV) comprises several viruses that cause severe damage to tomato crops in warm and temperate regions worldwide. TYLCV viruses are widespread in the Mediterranean Basin, in which two species have been reported: Tomato yellow leaf curl Sardinia virus (TYLCSV) and Tomato yellow leaf curl virus (TYLCV, previously TYLCV-Is). The availability of methods convenient for the diagnosis of these viruses is essential. We have investigated several alternatives for reliable detection and differentiation of TYLCSV and TYLCV. Triple-antibody sandwich enzyme-linked immunosorbent assay (TAS-ELISA) proved to be very useful for large-scale diagnosis in field situations, but lacked discriminating capacity and sensitivity in the stages of infection in which low virus titre is present. The DNA-based methods are suited to laboratory operations and plant disease clinics, where accuracy of detection and discrimination of viruses is required. Polymerase chain reaction–restriction fragment length polymorphism (PCR–RFLP) was the most reliable method to discriminate between TYLCSV and TYLCV, but is not suited to high sample turnover. For large-scale testing, tissue print hybridization assay provides a reliable and sensitive alternative to PCR.     

Construction of a cDNA library of Bemisia tabaci for use in the ''yeast two-hybrid screen'' method

Bemisia tabaci was reported for the first time in the Mediterranean part of Croatia in 2000. It was found in glasshouses in the agricultural area between the towns of Trogir and Omis, on the following crops: Euphorbia pulcherrima , Thunbergia grandiflora , Cucumis sativus (cucumber), Solanum melongena (aubergine), Phaseolus spp. (beans), Ficus carica (fig), Rubus spp. and several weeds of the families Asteraceae and Solanaceae . In 2001, monitoring for the pest was organized all over the country, in each of the 21 counties. In each county, there were several monitoring points so that all the major vegetable and flower producers were included. A special effort was made to record the spread of B. tabaci in the region where it was first found, bearing in mind that optimal conditions for outdoor spread exist along the Adriatic coast. Yellow sticky traps and visual inspection are used to monitor for B. tabaci . Eradication measures are being applied, and regulatory measures have been taken to prevent further spread of B. tabaci to continental parts of Croatia.