Tomato susceptibility to Alternaria stem canker:Parameters involved in host-specific toxin-induced leaf necrosis

AAL-toxin causes severe necrosis in leaves of susceptible tomato cultivars at nanomolar concentrations. In resistant tomato cultivars harbouring the semi-dominant Alternaria stem canker resistance locus necrosis is also observed, however at much higher toxin concentrations, in both lines the percentage of the leaf area exhibiting necrosis is dependent on toxin concentration and on length of toxin exposure. However, at the same toxin concentration, periods of toxin exposure resulting in similar necrosis are much longer for the resistant than for the susceptible tomato. It was demonstrated that toxin uptake in the leaves does not imply toxin uptake in the cells since a discrepancy was observed between death of protoplasts, isolated from leaves cut for protoplast isolation immediately after incubation on AAL-toxin and necrosis in leaves when further incubated on water. However, when after exposure to AAL-toxin leaves were further incubated on water for 24 h before they were cut for protoplast isolation, a correlation was found between leaf necrosis and death of protoplasts. This suggests that further transport is needed in leaves after toxin uptake, bringing toxin to all the cells, that cannot occur in leaves cut for protoplast isolation. Light plays an important role in AAL-toxin induced necrosis and it was shown that length of light exposure controls necrosis development like toxin concentration and length of toxin exposure. The product of these 3 parameters can provide a good hint to predict the extent of leaf necrosis. The effect of light might be restricted to differentiated leaf tissue, since it was not observed in callus tissue

Analysis of RAPD and AFLP markers linked to resistance to Fusarium oxysporum f. sp. lactucae race 2 in lettuce (Lactuca sativa L.)

Root rot of lettuce, which is caused by Fusarium oxysporum f. sp. lactucae (FOL), is a critical problem in the production of lettuce. FOL-resistant lettuce genetic resources have been identified and used in breeding programs to produce FOL-resistant cultivars. However, the genetic characteristics of resistance genes have not been studied in depth and, therefore, no DNA markers are presently available for these genes. In this study, we analyzed the RRD2 (resistance for root rot disease race 2) locus, which confers resistance to FOL race 2. Resistance loci were analyzed using two cultivars of crisphead lettuce: VP1013 (resistant) and Patriot (susceptible). The segregation patterns of resistant phenotypes in F-2 indicated a single major locus. To define the positions of resistance loci, a linkage map was constructed using amplified fragment length polymorphism and random amplified polymorphic DNA (RAPD) markers. Quantitative trait loci analysis revealed the position of the major resistance locus. A high LOD score was observed for RAPD-marker WF25-42, and this marker showed good correspondence to the phenotype in different cultivars and lines. We successfully developed a sequence characterized amplified region marker from WF25-42.ArticleEUPHYTICA. 187(1):1-9 (2012)journal articl

Behaviour of the disease resistance gene Asc in protoplasts of Lycopersicon esculentum mill

Action of Asc, a single dominant Mendelian gene controlling disease response at the whole plant level, was detected at the level of individual cells. Protoplasts, freshly isolated from resistant (Asc/Asc) and susceptible (asc/asc) tomato isolines, were differentially sensitive to AAL toxin as observed in planta. Protoplast mortality was toxin concentration dependent in both isolines and required the same 24-36 h time frame as necrosis in leaflet tissue, but asc/asc protoplasts were 10-fold less sensitive (0.15 µM) and Asc/Asc protoplasts were over 100-fold less sensitive (> 150 µM) than corresponding leaflet tissue. Light was required for necrosis in leaflets but not in protoplasts; asc/asc leaflets kept in darkness remained green for 48 h at 100-fold excess toxin concentration whereas protoplasts showed equivalent sensitivity in light or dark. Aging diminished toxin sensitivity in both leaflets and in protoplasts. Fully expanded asc/asc leaflets were less than half as sensitive to AAL toxin (~ 30% necrosis) as rapidly expanding leaflets (~ 87% necrosis) while protoplasts from equivalent leaflets were only 80% as sensitive to AAL toxin 2 days after isolation and insensitive after 9 days. These data indicated that the action of the Asc gene is expressed in protoplasts, the process of cell death is analogous in single cells and intact leaves, but that additional processes expressed in differentiated tissue can modify Asc response to AAL-toxin.

Tomato susceptibility to Alternaria stem canker: Parameters involved in host-specific toxin-induced leaf necrosis

AAL-toxin causes severe necrosis in leaves of susceptible tomato cultivars at nanomolar concentrations. In resistant tomato cultivars harbouring the semi-dominant Alternaria stem canker resistance locus necrosis is also observed, however at much higher toxin concentrations, in both lines the percentage of the leaf area exhibiting necrosis is dependent on toxin concentration and on length of toxin exposure. However, at the same toxin concentration, periods of toxin exposure resulting in similar necrosis are much longer for the resistant than for the susceptible tomato. It was demonstrated that toxin uptake in the leaves does not imply toxin uptake in the cells since a discrepancy was observed between death of protoplasts, isolated from leaves cut for protoplast isolation immediately after incubation on AAL-toxin and necrosis in leaves when further incubated on water. However, when after exposure to AAL-toxin leaves were further incubated on water for 24 h before they were cut for protoplast isolation, a correlation was found between leaf necrosis and death of protoplasts. This suggests that further transport is needed in leaves after toxin uptake, bringing toxin to all the cells, that cannot occur in leaves cut for protoplast isolation. Light plays an important role in AAL-toxin induced necrosis and it was shown that length of light exposure controls necrosis development like toxin concentration and length of toxin exposure. The product of these 3 parameters can provide a good hint to predict the extent of leaf necrosis. The effect of light might be restricted to differentiated leaf tissue, since it was not observed in callus tissue.

Magyar Könyvszemle

Under arrhenotoky, unfertilized haploid eggs develop as males but under thelytoky they develop into diploid females after they have undergone diploidy restoration. In the parasitoid wasp Venturia canescens both reproductive modes occur. Thelytoky is genetically determined but the underlying genetics of diploidy restoration remain unknown. In this study we aim to identify the genes and/or proteins that control thelytoky. cDNA-amplified fragment length polymorphism (cDNA-AFLP) analysis of total ovarian RNA and two-dimensional protein electrophoresis in combination with mass spectrometry revealed putative transcripts and proteins involved in arrhenotokous and thelytokous development. The detected tubulin and actin protein differences are most likely functionally related to the two types of reproduction