A transposon insertion in the Arabidopsis SSR16 gene causes an embryo-defective lethal mutation

The SSR16 gene of Arabidopsis has been identified as a gene encoding a ribosomal protein S16 homolog through analysis of a transposon insertion mutation. The insertion mutation is lethal, arresting embryonic development at approximately the transition from the globular to the heart stage of embryonic development. Co-segregation of the mutant phenotype with the transposon-borne drug-resistance marker and loss of the inserted transposon concomitant with phenotypic reversion provided evidence that the transposon had caused the mutation. Sequences flanking the insertion site were amplified from DNA of viable heterozygotes by thermal asymmetric interlaced (TAIL) PCR. The amplified fragment flanking the 3' end of the inserted element was sequenced and found to be identical to an Arabidopsis expressed sequence tag (EST). The EST, in turn, contained a coding sequence homologous to the ribosomal protein S16 (RPS16) of bacteria such as Escherichia coli, Bacillus subtilis and Salmonella typhimurium , as well as Neurospora crassa mitochondria and higher plant plastids. Thus the gene identified by the embryo-defective lethal insertion mutation encodes an RPS16 homolog and has been designated the SSR16 gene.     

Structure and polymorphism of a fragment of the Pain-1 vacuolar invertase locus in Solanum species

A fragment of the Pain-1 vacuolar invertase locus was sequenced and its structure and polymorphism were characterized in 17 species of the genus Solanum, including the subgenera Potatoe, Solanum, Leptostemonum, Minon, and Brevantherum. The fragment size varied from 603 to 977 bp as a result of multiple indels in the region of intron III. A total of 80 single nucleotide polymorphisms were found in the coding region, of which 34 caused amino acid substitution in the protein product. Several substitutions and indels were specific to individual taxons or taxon groups, including potato and tomato species. The genetic distances and phylogenetic trees obtained supported the commonly accepted taxonomic classification of the species, indicating that the Pain-1 fragment is suitable for taxonomic identification and phylogenetic studies in Solanaceae.     

Efficient targeting of plant disease resistance loci using NBS profiling

The conserved sequences in the nucleotide-binding sites of the nucleotide-binding site-leucine-rich repeat (NBS-LRR) class of disease resistance (R) genes have been used for PCR-based R-gene isolation and subsequent development of molecular markers. Here we present a PCR-based approach (NBS profiling) that efficiently targets R genes and R-gene analogs (RGAs) and, at the same time, produces polymorphic markers in these genes. In NBS profiling, genomic DNA is digested with a restriction enzyme, and an NBS-specific (degenerate) primer is used in a PCR reaction towards an adapter linked to the resulting DNA fragments. The NBS profiling protocol generates a reproducible polymorphic multilocus marker profile on a sequencing gel that is highly enriched for R genes and RGAs. NBS profiling was successfully used in potato with several restriction enzymes, and several primers targeted to different conserved motifs in the NBS. Across primers and enzymes, the NBS profiles contained 50–90% fragments that were significantly similar to known R-gene and RGA sequences. The protocol was similarly successful in other crops (including tomato, barley, and lettuce) without modifications. NBS profiling can thus be used to produce markers tightly linked to R genes and R-gene clusters for genomic mapping and positional cloning and to mine for new alleles and new sources of disease resistance in available germplasm.Communicated by H.F. Linskens     

The detection of genome polymorphism in Stachys species using RAPD

Molecular genome analysis was for the first time carried out in the genus Stachys. RAPD analysis proved to be suitable for identifying the species-specific markers, studying the interspecific DNA polymorphism, and detecting the genetic changes that arise during in vitro culturing of Stachys sieboldii. In addition, RAPD was used for screening genetic variation in S. sieboldii regenerants obtained at various phytohormone concentrations. High cytokinin concentrations and multiple regeneration were shown to induce genetic changes detectable with RAPD patterns. High DNA polymorphism was demonstrated for two types of S. sieboldii callus cultures and for plants regenerated from a callus culture.     

The Detection of Genome Polymorphism in Stachys Species Using RAPD

Molecular genome analysis was for the first time carried out in the genus Stachys. RAPD analysis proved to be suitable for identifying the species-specific markers, studying the interspecific DNA polymorphism, and detecting the genetic changes that arise during in vitro culturing of Stachys sieboldii. RAPD was also used for screening genetic variation in S. sieboldii regenerants obtained at various phytohormone concentrations. High cytokinin concentrations and multiple regeneration were shown to induce genetic changes detectable in RAPD patterns. High DNA polymorphism was detected for two types of S. sieboldii callus cultures and for plants regenerated from a callus culture.     

Using RAPD for Estimating Genetic Polymorphism in and Phylogenetic Relationships among Species of the Genus Lycopersicon (Tourn.) Mill.

RAPD genome analysis of 53 species and cultivars of the genusLycopersicon (Tourn.) Mill. revealed their high genetic polymorphism (Tourn.) Mill., based on which their phylogenetic relationships were inferred. In total, 248 polymorphic DNA fragments were amplified. Intraspecific polymorphism was maximum (79%) in L. peruvianum and minimum (9%) in L. parviflorum. In general, genome divergence among cross-pollinating tomato species was substantially higher than in self-pollinating species. An UPGMA dendrogram constructed from the RAPD patterns was consisted with the Lycopersicon phylogeny inferred from the molecular data of RFLP, ISSR, and microsatellite analyses and with a classification based on morphological characters. The relationships of taxa within the genus Lycopersicon are discussed.     

RAPD Analysis of the Genome in Species of the Genus Hordeum

Random amplification of polymorphic DNA (RAPD) was used to analyze six species, three populations, and seven regional cultivars of barley. A unique pattern of amplified DNA products was obtained for each species of the genus Hordeum.High polymorphism of barley species was revealed. Specific fragments were found in most RAPD patterns; the fragments can be used as molecular markers of corresponding species and subspecies. Several other DNA fragments were shown to serve as molecular markers of the H genome. Specific RAPD patterns were obtained for each population and each cultivar of H. vulgaresensu lato. In total, variation between the populations and between the cultivars was substantially lower than between species. Cluster analysis (UPGMA) was used to estimate genetic distances between theHordeumspecies, between the H. spontaneumpopulations, and between regional H. vulgarecultivars and a dendrogram was constructed.