A dispersed family of repetitive DNA sequences exhibits characteristics of a transposable element in the genus Lycopersicon.

A segment of DNA 5' to the transcribed region of an auxin-regulated gene, ARPI, from Lycopersicon esculentum Mill. cv. VFN8 contains a sequence with the structural characteristics of a transposable element. The putative element (Lyt1) is 1340 bp long, has terminal inverted repeats of approximately 235 bp and is flanked by 9-bp direct repeats. Lyt1 has a structure similar to the Robertson's Mutator (Mu) family from maize. The terminal inverted repeats are 80% AT-rich, are 96.6% identical, and define a larger family of repetitive elements. Southern analysis and genomic dot-blot reconstructions detected at least 41 copies of Lyt1-hybridizing sequences in red-fruited Lycopersicon spp. (L. esculentum, L. pimpinellifolium and L. cheesmanii), and 2-8 copies in the green-fruited species (L. hirsutum, L. pennellii, L. peruvianum, L. chilense and L. chmielewskii). There were two to four copies in the Solanum spp. closely allied with the genus Lycopersicon (S. lycopersicoides, S. ochranthum and S. juglandifolium), while the more distantly related Solanum spp. showed little (one to two copies in S. tuberosum) to no (S. quitoense) detectable hybridization under stringent conditions. Linkage analysis in the F2 progeny of a cross between L. esculentum and L. cheesmanii indicated that at least six loci that hybridize to the Lyt1 sequence are dispersed in the genome. Polymerase chain reaction and Southern analyses revealed that some red-fruited accessions and L. chmielewskii lacked Lyt1 5' to the transcribed region of ARPI. Subsequent sequence analysis indicated that only one copy of the 9-bp direct repeat (target site) was present, suggesting that transposition of the element into the ARPI gene occurred after the divergence of the red-fruited and green-fruited Lycopersicon species.

Genetic variation in homothallic and hyphal swelling isolates of Pythium ultimum var. ultimum and P. utlimum var. sporangiferum.

Genetic variation in a collection of 22 Pythium ultimum isolates was analyzed using restriction fragment length polymorphisms (RFLPs), random amplified polymorphic DNA (RAPD), and sequence characterized amplified regions (SCARs) as genetic markers. Qualitative evidence for the occurrence of sexual outcrossing in the field, asexual mechanisms affecting variation, and differences in aggressiveness between isolates was found. Codominant SCAR and RFLP markers detected multiple alleles in several isolates. Genetic analysis of F1 progeny from a cross indicates that heterozygosity is one cause of multiple alleles and contributes to genetic variation. Segregation analysis of F2 progeny fit diploid expectations and supported the use of the molecular markers for phenetic analysis. One isolate contained three alleles at one locus suggesting that polyploidy, aneuploidy or heterokaryosis may also contribute to genetic variation. Phenetic analysis using UPGMA clustering of Nei's distance calculated from RFLP data, UPGMA clustering of similarity matrixes calculated from RAPD data, and principle component analysis of RAPD data revealed no clustering of the three morphological types of Pythium ultimum (var. ultimum, var. sporangiferum, and group HS). Our results suggest that the three morphological variants of this homothallic oomycete are not genetically distinct.

The evaluation of eye patching in the treatment of traumatic corneal epithelial defects.

The objective of this study was to compare the rates of healing for patched and non-patched traumatic corneal epithelial defects (CEDs) after 1 day of treatment. To achieve this we initiated a randomized, controlled, prospective, clinical investigation comparing patching vs. non-patching of CEDs. Patients were evaluated initially and at 24 h using slit lamp biomicroscopy, and each corneal epithelial defect was documented on standardized initial and follow-up grid sheets. Percentage of healing and healing rates were determined by comparing the grid sheets. Our results found no significant difference in abrasion size between the two groups, but there was found to be a significantly improved rate of healing at follow-up in non-patched patients. This study demonstrates a significant improvement in the healing rate of traumatic CEDs in the non-patched group as compared to the patched group; therefore, the use of eye patching is not mandatory for corneal epithelial healing to occur.

Inheritance of resistance to blackmold (Alternaria alternata (Fr.) Keissler) in two interspecific crosses of tomato (Lycopersicon esculentum ×L. cheesmanii f.typicum).

Inheritance of resistance to blackmold, a disease of ripe tomato fruit caused byAlternaria alternata, was studied in two interspecific crosses. The parents, F1 and F2 generations of a cross between the susceptibleLycopersicon esculentum Mill. cultivar 'Hunt 100' and the resistantL. Cheesmanii f.typicum Riley accession LA 422, and the parents, F1, F2, F3, and BC1 P2 generations of a cross between the susceptibleL. Esculentum cv. 'VF 145B-7879' and LA 422 were evaluated. The following disease evaluation traits were used: symptom rating (a symptom severity rating based on visual evaluation of lesions), diseased fruit (the number of diseased fruits divided by the total number of fruit scored), and lesion size (a function derived from the actual lesion diameter). Generation means analysis was used to determine gene action. The data of the 'Hunt 100' × LA 422 cross fit an additive-dominance model for all three traits. The 'VF 145B-7879' × LA 422 cross data best fit a model that included the additive × additive and additive × dominance interaction components for the trait diseased fruit, whereas higher-order epistatic models would have to be invoked to fit the data for the traits symptom rating and lesion size. A minimum of one gene segregated for all three traits. Broad-sense heritability estimates ranged from 0.09 to 0.16 for all three traits, indicating that selection for improved resistance to blackmold will require selection on a family performance basis.

Outcrossing in the homothallic oomycete, Pythium ultimum, detected with molecular markers.

The oomycete Pythium ultimum is homothallic, thus a single isolate completes the sexual stage in pure culture. It has been generally assumed that homothallic oomycetes are predominantly inbreeding. In P. ultimum, antheridia occasionally develop from hyphae not directly connected to the oogonium and appear to participate in fertilization, suggesting a possible mechanism for outcrossing. We have used molecular markers to confirm that outcrossing can occur between isolates of P. ultimum. Genetic markers based on randomly amplified polymorphic DNA (RAPD) and restriction fragment length polymorphisms (RFLP) were used to distinguish isolates in a collection of P. ultimum. Two isolates displaying a high level of polymorphism were mixed and placed on media which allows the development of the sexual stage. RAPD markers were used to screen single oospore progeny to identify potential hybrids between the two parental isolates. Subsequent self-fertilization of one putative F1 yielded a F2 population which demonstrated segregation and independent assortment of RAPD and RFLP markers. A similar strategy was used to show that an isolate which is incapable of producing oospores in pure culture can outcross when mixed with a homothallic isolate. These results suggest that other homothallic oomycetes may be capable of outcrossing, and sexual reproduction may, therefore, play an important role in the generation of variation in homothallic oomycetes.

Fine mapping of three quantitative trait loci for late blight resistance in tomato using near isogenic lines (NILs) and sub-NILs.

An earlier study identified quantitative trait loci (QTLs) lb4, lb5b, and lb11b for quantitative resistance to Phytophthora infestans (late blight) in a backcross population derived from crossing susceptible cultivated tomato ( Lycopersicon esculentum) with resistant L. hirsutum. The QTLs were located in intervals spanning 28-47 cM. Subsequently, near-isogenic lines (NILs) were developed for lb4, lb5b, and lb11b by marker-assisted backcrossing to L. esculentum. Sub-NILs containing overlapping L. hirsutum segments across each QTL region were selected and used to validate the QTL effects, fine-map QTLs, and evaluate potential linkage drag between resistance QTLs and QTLs for horticultural traits. The NILs and sub-NILs were evaluated for disease resistance and eight horticultural traits at three field locations. Resistance QTLs were detected in all three sets of NIL lines, confirming the BC(1) mapping results. Lb4 mapped near TG609, and between TG182 and CT194, on chromosome 4, a 6.9-cM interval; lb5b mapped to an 8.8-cM interval between TG69a and TG413 on chromosome 5, with the most likely position near TG23; and lb11b mapped to a 15.1-cM interval on chromosome 11 between TG194 and TG400, with the peak centered between CT182 and TG147. Most QTLs for horticultural traits were identified in intervals adjacent to those containing the late blight resistance QTLs. Fine mapping of these QTLs permits the use of marker-assisted selection for the precise introgression of L. hirsutum segments containing late blight resistance alleles separately from those containing deleterious alleles at horticulturally important QTLs.