The genetic and functional analysis of flavor in commercial tomato: the <i>FLORAL4</i> gene underlies a QTL for floral aroma volatiles in tomato fruit

Tikunov, Yury; Roohanitaziani, Raana; Meijer‐Dekens, Fien; Molthoff, Jos; Paulo, João; Finkers, Richard; Capel, Iris; Moreno, Fátima Carvajal; Maliepaard, Chris; Vries, Mariska Nijenhuis-de; Labrie, C.W.; Verkerke, W.; Heusden, A.W. van; Eeuwijk, Fred van; Visser, R.G.F.; Bovy, Arnaud

doi:10.1111/tpj.14795

Cited by 38 publications

(36 citation statements)

References 61 publications

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“…For this reason, we standardized the potential positional error across the reported studies by setting an empirically defined window of ±2.5 Mb around each identified QTL. This window was derived from the average inter-study standard deviation of QTL positions of the three most functionally explored tomato aroma loci-floral aroma on chromosome 4 [25,90,99,102], smoky aroma on chromosome 9 [25,90,102] and the malodorous locus on chromosome 8 [92,93,99]. The major genetic factors underlying these QTLs were identified and, therefore, the dispersion of QTL positions in these different studies could most likely be attributed to non-genetic sources of variation.…”

Section: Construction Of a Unified Qtl Map Of Tomato Aromamentioning

confidence: 99%

The Genetic Basis of Tomato Aroma

Martina

Tikunov

Portis

et al. 2021

Genes

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Tomato (Solanum lycopersicum L.) aroma is determined by the interaction of volatile compounds (VOCs) released by the tomato fruits with receptors in the nose, leading to a sensorial impression, such as “sweet”, “smoky”, or “fruity” aroma. Of the more than 400 VOCs released by tomato fruits, 21 have been reported as main contributors to the perceived tomato aroma. These VOCs can be grouped in five clusters, according to their biosynthetic origins. In the last decades, a vast array of scientific studies has investigated the genetic component of tomato aroma in modern tomato cultivars and their relatives. In this paper we aim to collect, compare, integrate and summarize the available literature on flavour-related QTLs in tomato. Three hundred and 5ifty nine (359) QTLs associated with tomato fruit VOCs were physically mapped on the genome and investigated for the presence of potential candidate genes. This review makes it possible to (i) pinpoint potential donors described in literature for specific traits, (ii) highlight important QTL regions by combining information from different populations, and (iii) pinpoint potential candidate genes. This overview aims to be a valuable resource for researchers aiming to elucidate the genetics underlying tomato flavour and for breeders who aim to improve tomato aroma.

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Section: Construction Of a Unified Qtl Map Of Tomato Aromamentioning

confidence: 99%

The Genetic Basis of Tomato Aroma

Martina

Tikunov

Portis

et al. 2021

Genes

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“…On the other hand, 3-methylbutanol precursor, the branched-chain amino acid leucine, was significantly increased, while no differences were observed in phenylalanine content. Even if gene editing validated the effect of FLORAL4 deleterious mutations in planta, the decarboxylase activity of the gene could not be verified in vivo (Tikunov et al 2020).…”

Section: Transcriptomic Gwas and Metabolomic Approaches To Understanmentioning

confidence: 99%

Section: Transcriptomic Gwas and Metabolomic Approaches To Understanmentioning

confidence: 99%

“…A recent study also mapped a QTL for phenylpropanoid-derived volatiles (2-phenylethanol, phenylacetaldehyde and 1-nitro-2-phenylethane) on chromosome 4, using a diversity panel of 94 cultivars and several F 2 and F 6 populations of a half diallel cross (Tikunov et al 2020). Near isogenic lines, harbouring the marker alleles associated to the genomic region on chromosome 4 for either low or high phenylpropanoid volatiles, allowed to confirm the correlation of this locus with fruity and rose-hip aroma (Tikunov et al 2020). Fine-mapping the locus on chromosome 4 narrowed down to 11 genes in the associated region, and one of them showed high similarity to a 3-methyl-2-oxobutanoate dehydrogenase, an enzyme with decarboxylase activity, and which may be involved in the decarboxylation of phenylalanine, to produce the common precursor of the three volatiles (Table 2).…”

Section: Transcriptomic Gwas and Metabolomic Approaches To Understanmentioning

confidence: 99%

“…Tieman et al (2017) detected a locus on chromosome 9 linked to the two metabolicallyrelated volatiles, and suggested that E8, a specific highlyexpressed ripening-related gene, could be the candidate based on the analysis of silenced tomato lines, even if the molecular mechanism remained unclear. On the other hand, using a combination of omics approaches, Tikunov et al (2013Tikunov et al ( , 2020 highlighted the role of a non-smoky glycosyltransferase (NSGT1), also located on chromosome 9, and responsible for the volatile release. Very recently, and taking advantage of the new long-read technology sequencing, a collection of 100 tomato accessions was sequenced, shedding light upon structural variants underlying important domestication traits, including the smoky locus (Alonge et al 2020).…”

Section: Transcriptomic Gwas and Metabolomic Approaches To Understanmentioning

confidence: 99%

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Combining metabolomic and transcriptomic approaches to assess and improve crop quality traits

et al. 2021

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Plant quality trait improvement has become a global necessity due to the world overpopulation. In particular, producing crop species with enhanced nutrients and health-promoting compounds is one of the main aims of current breeding programs. However, breeders traditionally focused on characteristics such as yield or pest resistance, while breeding for crop quality, which largely depends on the presence and accumulation of highly valuable metabolites in the plant edible parts, was left out due to the complexity of plant metabolome and the impossibility to properly phenotype it. Recent technical advances in high throughput metabolomic, transcriptomic and genomic platforms have provided efficient approaches to identify new genes and pathways responsible for the extremely diverse plant metabolome. In addition, they allow to establish correlation between genotype and metabolite composition, and to clarify the genetic architecture of complex biochemical pathways, such as the accumulation of secondary metabolites in plants, many of them being highly valuable for the human diet. In this review, we focus on how the combination of metabolomic, transcriptomic and genomic approaches is a useful tool for the selection of crop varieties with improved nutritional value and quality traits.

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