A candidate gene survey of quantitative trait loci affecting chemical composition in tomato fruit.

In tomato, numerous wild-related species have been demonstrated to be untapped sources of valuable genetic variability, including pathogen-resistance genes, nutritional, and industrial quality traits. From a collection of S. pennellii introgressed lines, 889 fruit metabolic loci (QML) and 326 yield-associated loci (YAL), distributed across the tomato genome, had been identified previously. By using a combination of molecular marker sequence analysis, PCR amplification and sequencing, analysis of allelic variation, and evaluation of co-response between gene expression and metabolite composition traits, the present report, provides a comprehensive list of candidate genes co-localizing with a subset of 106 QML and 20 YAL associated either with important agronomic or nutritional characteristics. This combined strategy allowed the identification and analysis of 127 candidate genes located in 16 regions of the tomato genome. Eighty-five genes were cloned and partially sequenced, totalling 45,816 and 45,787 bases from S. lycopersicum and S. pennellii, respectively. Allelic variation at the amino acid level was confirmed for 37 of these candidates. Furthermore, out of the 127 gene-metabolite co-locations, some 56 were recovered following correlation of parallel transcript and metabolite profiling. Results obtained here represent the initial steps in the integration of genetic, genomic, and expressional patterns of genes co-localizing with chemical compositional traits of the tomato fruit.

Enhancing crop yield in Solanaceous species through the genetic manipulation of energy metabolism.

The improvement of crop yield has been endeavoured for centuries; whereas traditional breeding strategies have achieved this, until recently transgenic approaches to yield improvement have generally been less successful. In this mini-review, we discuss metabolic engineering strategies specifically targeting energy metabolism as a strategy for yield enhancement.

Cloning and expression of a sorghum gene with homology to maize vp1. Its potential involvement in pre-harvest sprouting resistance.

Pre-harvest sprouting (PHS) in sorghum is related to the lack of a normal dormancy level during seed development and maturation. Based on previous evidence that seed dormancy in maize is controlled by the vp1 gene, we used a PCR-based approach to isolate two Sorghum bicolor genomic and cDNA clones from two genotypes exhibiting different PHS behaviour and sensitivity to abscisic acid (ABA). The two 699 amino acid predicted protein sequences differ in two residues at positions 341 (Gly or Cys within the repression domain) and 448 (Pro or Ser) and show over 80, 70 and 60% homology to maize, rice and oat VP1 proteins respectively. Expression analysis of the sorghum vp1 gene in the two lines shows a slightly higher level of vp1 mRNA in the embryos susceptible to PHS than in those resistant to PHS during embryogenesis. However, timing of expression was different between these genotypes during this developmental process. Whereas for the former the main peak of expression was observed at 20 days after pollination (DAP), the peak in the latter was found at later developmental stages when seed maturation was almost complete. Under favourable germination conditions and in the presence of fluridone (an inhibitor of ABA biosynthesis), sorghum vp1 mRNA showed to be consistently correlated with sensitivity to ABA but not with ABA content and dormancy.

The TATA-less promoter of VP1, a plant gene controlling seed germination.

Vp1 is a seed-specific gene involved in the control of dormancy and germination. We here present the complete sequence of the sorghum vp1 promoter/enhancer region highlighting its main features, especially the lack of canonical TATA and CAAT boxes and the presence of elements responsive to abscisic acid and light. The region closest to the start of transcription is highly homologous to the partial proximal sequence reported for the maize vp1 promoter. This region is interrupted by a 57-nt stretch containing 14 CT microsatellite repeats. We observed a poor overall homology to the promoter from abi3 gene, the Arabidopsis counterpart bearing a similar coding sequence. However, there exists a high degree of homology (89%) between a TATA-rich 103-bp stretch of the sorghum vp1 promoter located about 700 nt upstream of the startpoint and miniature inverted transposable elements (MITEs) interspersed within the sorghum seed-specific kafirin cluster. This sorghum MITE-like element displays considerable homology (68%) to the TATA-less promoter from the sorghum NADP-malate dehydrogenase gene and lesser similarity to the Tourist, Pilgrim and Batuta MITEs previously identified within the promoter from the maize Abp1 (auxin-binding protein) gene.

Analysis of an abscisic acid (ABA)-responsive gene promoter belonging to the Asr gene family from tomato in homologous and heterologous systems.

Asr is a family of genes that maps to chromosome 4 of tomato. Asr2, a recently reported member of this family, is believed to be regulated by abscisic acid (ABA), stress and ripening. A genomic Asr2 clone has been fully sequenced, and candidate upstream regulatory elements have been identified. To prove that the promoter region is functional in vivo, we fused it upstream of the beta-glucuronidase (GUS) reporter gene. The resulting chimeric gene fusion was used for transient expression assays in papaya embryogenic calli and leaves. In addition, the same construct was used to produce transgenic tomato, papaya, tobacco, and potato plants. Asr2 upstream sequences showed promoter function in all of these systems. Under the experimental conditions tested, ABA stimulated GUS expression in papaya and tobacco, but not in tomato and potato systems.