In viticulture, biotype identification problems have traditionally been solved using ampelography, ampelometry and chemical traits analysis. However, these tools have resulted in several false attributions, in particular when used at the clonal level. The availability of relatively cheap, reliable and reproducible tools to identify genetic differences at the clonal level would greatly facilitate the work of clonal patenting. In this work, 24 accessions of ‘Traminer’ cultivars were characterized using molecular markers. Three different approaches were applied: simple sequence repeats (SSR), amplified fragment length polymorphism (AFLP) and methyl‐sensitive amplified length polymorphism (MSAP). Results showed that SSRs were not a powerful tool for clonal distinction. In contrast, the AFLP technique was able to distinguish 16 out of the 24 cultivars, even though the average similarity was high (97.1%). The MSAP technique was used to evaluate qualitative differences in the degree of DNA methylation among clones. Results suggest that morphological differences among clones are probably due to the synergetic effect of genetic and epigenetic modifications, and that clonal identification could be greatly improved using molecular tools such as AFLP and MSAP.
A 2 kb DNA fragment, upstream of the rice b-tubulin isotype 16 (Ostub16) coding sequence, was isolated using inverse PCR and screening of a tubulin-enriched l library. An intron (863 bp) present in the 5¢ untranslated region (5¢ UTR) is spliced out to produce the most abundant mRNA species which corresponds to the previously cloned Ostub16 cDNA. Transient expression assays performed on rice embryogenic calluses with chimeric Ostub16::GUS constructs demonstrated that the entire 2 kb upstream sequence has a strong promoter activity, and that the 863 bp intron is required for high-level GUS expression. In addition, the intron sequence is capable per se of sustaining a weak but consistent GUS expression. Two rare Ostub16 transcripts, with a start site mapping within this intron sequence, were detected in rice coleoptile cells. The transcription start site mapped at position ±290 with respect to the ATG codon, and the shorter molecule originated from splicing of the same precursor mRNA. Therefore transcriptional expression of rice b-tubulin isotype 16 results in the synthesis of two premRNA molecules (I and II) encoding for three different mRNA species. We discuss these ®ndings in terms of function and molecular evolution of the mechanisms that control plant b-tubulin gene expression.
TBP (tubulin-based polymorphism) is a new molecular marker based tool that relies on the presence of intron-specific DNA polymorphisms of the plant beta-tubulin gene family. The multifunctional and essential role of the tubulin proteins is reflected in the conservation of regions within their primary amino acid sequence. The ubiquitous nature of this gene family can be exploited using primers that amplify the first intron of different beta-tubulin isotypes, revealing specific fingerprints. The method is rapid, simple, and reliable and does not require preliminary sequence information of the plant genome of interest. The ability of TBP to discriminate between accessions and species in oilseed rape, coffee, and lotus is shown. In all cases, TBP was able to detect specific genetic polymorphisms in the context of a simplified and readily appreciable pattern of DNA amplification. The application of TBP for assessing genetic diversity and genome origins in disseminated plant landraces rather than in highly inbred cultivated species is also discussed.
Plant calcium-dependent protein kinases (CDPKs) are involved in calcium-mediated signal transduction pathways. Their expression is finely tuned in different tissues and in response to specific signals, but the mechanism of such a regulation is still largely unknown. OsCDPK2 gene expression is modulated in vivo during rice (Oryza sativa L.) flower development and is downregulated by white light in leaves. In order to identify OsCDPK2 regulatory sequences, we amplified and cloned both the 5' and 3'-flanking regions of the gene. Sequence analysis revealed that the leader sequence is interrupted by an intron, whose regulatory role was investigated. Different ss-gucuronidase (GUS) expression vectors, carrying combinations of the putative OsCDPK2 regulatory regions, were generated and GUS expression was analyzed both in transient assays and in transgenic rice plants. The whole 5'-flanking sequence was able to drive GUS expression in rice calli and leaves transiently transformed with the biolistic technique. Analysis of the GUS expression pattern in transgenic plants revealed strong activity in root tips, leaf veins and mesophyll cells, in flower reproductive organs and in mature pollen grains. Expression was also shown to be subject to an intron-mediated enhancement (IME) mechanism, since the deletion of the leader intron sequence from chimeric OsCDPK2::GUS plasmids almost completely abolished GUS activity. Furthermore, in transiently transformed leaves, GUS expression driven by the OsCDPK2 promoter-leader region was constitutively observed regardless of light or dark exposure. Light-regulated expression was restored by inserting the OsCDPK2 3' untranslated region (3'UTR) downstream of the chimeric OsCDPK2::GUS transcription unit, suggesting that light down-regulation is mediated by a mechanism driven by the 3'UTR.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.