The expanded tomato fruit volatile landscape

[EN] The present review aims to synthesize our present knowledge about the mechanisms implied in the biosynthesis of volatile compounds in the ripe tomato fruit, which have a key role in tomato flavour. The difficulties in identifiying not only genes or genomic regions but also individual target compounds for plant breeding are addressed. Ample variability in the levels of almost any volatile compound exists, not only in the populations derived from interspecific crosses but also in heirloom varieties and even in commercial hybrids. Quantitative trait loci (QTLs) for all tomato aroma volatiles have been identified in collections derived from both intraspecific and interspecific crosses with different wild tomato species and they (i) fail to co-localize with structural genes in the volatile biosynthetic pathways and (ii) reveal very little coincidence in the genomic regions characterized, indicating that there is ample opportunity to reinforce the levels of the volatiles of interest. Some of the identified genes may be useful as markers or as biotechnological tools to enhance tomato aroma. Current knowledge about the major volatile biosynthetic pathways in the fruit is summarized. Finally, and based on recent reports, it is stressed that conjugation to other metabolites such as sugars seems to play a key role in the modulation of volatile release, at least in some metabolic pathways.We wish to thank the Metabolomics facility at the IBMCP for technical assistance. AG was supported by grants from MinECO and FECYT. This work was facilitated by the European-funded COST action FA1106 QualityFruit.Rambla Nebot, JL.; Tikunov, Y.; Monforte Gilabert, AJ.; Bovy, A.; Granell Richart, A. (2014). The expanded tomato fruit volatile landscape. Journal of Experimental Botany. 65(16):4613-4623. doi:10.1093/jxb/eru128S461346236516Abegaz, E. G., Tandon, K. S., Scott, J. W., Baldwin, E. A., & Shewfelt, R. L. (2004). 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A chemical genetic roadmap to improved tomato flavor

[EN] Modern commercial tomato varieties are substantially less flavorful than heirloom varieties. To understand and ultimately correct this deficiency, we quantified flavor-associated chemicals in 398 modern, heirloom, and wild accessions. A subset of these accessions was evaluated in consumer panels, identifying the chemicals that made the most important contributions to flavor and consumer liking. We found that modern commercial varieties contain significantly lower amounts of many of these important flavor chemicals than older varieties. Whole-genome sequencing and a genome-wide association study permitted identification of genetic loci that affect most of the target flavor chemicals, including sugars, acids, and volatiles. Together, these results provide an understanding of the flavor deficiencies in modern commercial varieties and the information necessary for the recovery of good flavor through molecular breeding.This work was supported by the NSF (grant IOS-0923312 to H.K.), the China National Key Research and Development Program for Crop Breeding (grant 2016YFD0100307 to S.H.), the Leading Talents of Guangdong Province Program (grant 00201515 to S.H.), the National Natural Science Foundation of China (grant 31601756 to G.Z.), the European Research Council (grant ERC-2011-AdG 294691 YIELD to D.Z.), and the European Commission Horizon 2020 program (TRADITOM grant 634561 to A.G. and D.Z.) This work was also supported by the Chinese Academy of Agricultural Science (ASTIP-CAAS) and the Shenzhen municipal and Dapeng district governments. We acknowledge the assistance of L. 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