Light signaling genes and their manipulation towards modulation of phytonutrient content in tomato fruits

Due to its economic importance, ease of genetic manipulation, cultivation and processing, the tomato plant has been a target for increasing and diversifying content of fruit phytonutrients by transgenic and non-transgenic approaches. The tomato high pigment (hp) mutations exemplify the latter alternative and due to their positive effect on fruit lycopene content, they were introgressed into elite tomato germplasm for cost effective extraction of this important carotenoid. Interestingly, hp mutant fruits are also characterized by higher fruit levels of other functional metabolites, phenotypes caused by mutations in central genes regulating light signal-transduction. This gene identification suggests that modulation of light signaling machinery in plants may be highly effective towards manipulation of fruit phytonutrients but has never been thoroughly reviewed. This review therefore summarizes the progress which has been made on this valuable approach, emphasizing the consequences of transgenic modulation of light signaling components on the functional properties of the tomato fruit.     

Restriction enzyme analysis of tomato chloroplast and chromoplast DNA

Plastid DNA was isolated from the chloroplasts of tomato (Lycopersicon esculentum var Traveler 76) leaves and the chromoplasts of ripe tomato fruit. Comparisons of the two DNAs were made by restriction endonuclease analysis using PvuII, HpaI, and Bg1I. No differences in the electrophoretic banding patterns of the restricted plastid DNAs were detected, indicating that no major rearrangements, losses, or gains of plastid DNA accompany the transition from chloroplast to chromoplast.     

Characterization and mapping of a gene controlling shoot regeneration in tomato

The superior regeneration capacity of Lycopersicon peruvianum was introduced into the cultivated tomato Lycopersicon esculentum by backcrossing hybrid material with the tomato genotype VF11. In segregating material derived from these backcrosses, the ability to regenerate shoots on root explants cultured on a zeatin-containing medium, was highly correlated with the ability to regenerate shoots on established callus cultures. The efficient shoot-regenerating root explant system permitted us to study the genetics of this trait and to locate the genes involved, using a set of morphological markers defining all 12 tomato chromosomes. Depending on the tomato genotype, mono, -di- or trigenic ratios were observed. It is concluded that a dominant L. peruvianum allele at a locus (Rg-1) near the middle of chromosome 3 determines efficient shoot regeneration on root explants in tomato in combination with dominant alleles at one or two other loci of either L. peruvianum or L. esculentum origin. The map location of the Rg-1 locus was refined further using a number of chromosome-3-specific RFLPs. The addition of new classical and RFLP linkage data to existing literature data and subsequent processing resulted in a revised and integrated map of tomato chromosome 3. From a morphological and physiological analysis of genotypes differing in Rg phenotype, it is concluded that the genetic component associated with regeneration determines the maintenance of morphogenetic competence and not the sensitivity to hormones.     

The mapping of phytochrome genes and photomorphogenic mutants of tomato

The map positions of five previously described phytochrome genes have been determined in tomato (Lycopersicon esculentum Mill.) The position of the yg-2 gene on chromosome 12 has been confirmed and the classical map revised. The position of the phytochrome A (phy A)-deficient fri mutants has been refined by revising the classical map of chromosome 10. The position of the PhyA gene is indistinguishable from that of the fri locus. The putative phyB1-deficient tri mutants were mapped by classical and RFLP analysis to chromosome 1. The PhyB1 gene, as predicted, was located at the same position. Several mutants with the high pigment (hp) phenotype, which exaggerates phytochrome responses, have been reported. Allelism tests confirmed that the hp-2 mutant is not allelic to other previously described hp (proposed here to be called hp-1) mutants and a second stronger hp-2 allele (hp-2 ^j ) was identified. The hp-2 gene was mapped to the classical, as well as the RFLP, map of chromosome 1. Received: 24 May 1996 / Accepted: 14 June 1996     

The nematode-resistance gene,<Emphasis Type="Italic"> Mi-1</Emphasis>, is associated with an inverted chromosomal segment in susceptible compared to resistant tomato

The gene Mi-1 confers effective resistance in tomato (Lycopersicon esculentum) against root-knot nematodes and some isolates of potato aphid. This locus was introgressed from L. peruvianum into the corresponding region on chromosome 6 in tomato. In nematode-resistant tomato, Mi-1 and six homologs are grouped into two clusters separated by 300 kb. Analysis of BAC clones revealed that the Mi-1 locus from susceptible tomato carried the same number and distribution of Mi-1 homologs, as did the resistant locus. Molecular markers flanking the resistant and susceptible loci were in the same relative orientation, but markers between the two clusters were in an inverse orientation. The simplest explanation for these observations is that there is an inversion between the two clusters of homologs when comparing the Mi-1 loci from L. esculentum and L. peruvianum. Such an inversion may explain previous observations of severe recombination suppression in the region. Two Mi-1 homologs identified from the BAC library derived from susceptible tomato are not linked to the chromosome 6 locus, but map to chromosome 5 in regions known to contain resistance gene loci in other solanaceous species.Communicated by J.S. Heslop-Harrison     

fw 2.2:a major QTL controlling fruit weight is common to both red- and green-fruited tomato species

We have shown that a major QTL for fruit weight (fw2.2) maps to the same position on chromosome 2 in the green-fruited wild tomato species, Lycopersicon pennellii and in the red-fruited wild tomato species, L. pimpinellifolium. An introgression line F₂ derived from L. esculentum (tomato) x L. pennellii and a backcross 1 (BC₁) population derived from L. esculentum x L. pimpinellifolium both place fw2.2 near TG91 and TG167 on chromosome 2 of the tomato highdensity linkage map. fw2.2 accounts for 30% and 47% of the total phenotypic variance in the L. pimpinellifolium and L. pennellii populations, respectively, indicating that this is a major QTL controlling fruit weight in both species. Partial dominance (d/a of 0.44) was observed for the L. pennellii allele of fw 2.2 as compared with the L. esculentum allele. A QTL with very similar phenotypic affects and gene action has also been identified and mapped to the same chromosomal region in other wild tomato accessions: L. cheesmanii and L. pimpinellifolium. Together, these data suggest that fw2.2 represents an orthologous QTL (i.e., derived by speciation as opposed to duplication) common to most, if not all, wild tomato species. High-resolution mapping may ultimately lead to the cloning of this key locus controlling fruit development in tomato.     

Map-based cloning in crop plants. Tomato as a model system: I. Genetic and physical mapping of jointless

A map-based cloning scheme is being used to isolate the jointless (j) gene of tomato. The jointless locus is defined by a single recessive mutation that completely suppresses the formation of the fruit and flower pedicel and peduncle abscission zone. jointless was mapped in an F₂ population of an interspecific cross between Lycopersicon esculentum and Lycopersicon pennellii to a 7.1 cM interval between two restriction fragment length polymorphism (RFLP) markers TG523 and TG194. Isogenic DNA pools were then constructed from a subset of the mapping population and screened with 800 random decamers for random amplification of polymorphic DNA (RAPD) polymorphisms. Five new RAPD markers were isolated and mapped to chromosome 11, two of which were mapped within the targeted interval. One marker, RPD158, was mapped 1.5 cM to the opposite side of jointless relative to TG523 and thus narrowed the interval between the closest flanking markers to 3.0 cM. Physical mapping by pulse-field gel electrophoresis using TG523 and RPD158 as probes demonstrated that both markers hybridize to a common 600 kb SmaI restriction fragment. This provided an estimate of 200 kb/cM for the relationship between physical and genetic distances in the region of chromosome 11 containing the j locus. The combined results provide evidence for the feasibility of the next step toward isolation of the jointless gene by map-based cloning — a chromosome walk or jump to jointless.     

Identification of RAPD markers linked to the Tm-2 locus in tomato

Tm-2 and Tm-2a are genes conferring resistance to tomato mosaic virus in Lycopersicon esculentum. They are allelic and originated from different lines of L. peruvianum, a wild relative of tomato. In this study, random amplified polymorphic DNA (RAPD) markers linked to these genes were screened in nearly isogenic lines (NILs). To detect RAPDs differentiating NILs, 220 different 10-base oligonucleotide primers were examined by the polymerase chain reaction (PCR), and 43 of them generated 53 consistent polymorphic fragments among the NILs. Out of these 53 fragments, 13 were arbitrarily chosen and examined in respect of whether they were linked to the netted virescent (nv) gene, since nv is tightly linked to the Tm-2 locus and its phenotype is more easily distinguishable. As a result, all 13 markers were shown to be linked to nv, and hence to the Tm-2 locus. Among them, two fragments specific to the NIL carrying Tm-2 three specific to the NIL carrying Tm-2a, and four specific to both of these NILs were closely linked to nv.     

High-resolution linkage analysis and physical characterization of the EIX-responding locus in tomato

An ethylene-inducing xylanase (EIX) from Tricohoderma viride is a potent elicitor of ethylene biosynthesis, localized cell death and other defense responses in specific cultivars of tobacco (Nicotiana tabacum) and tomato (Lycopersicon esculentum). Wild species of tomato, such as Lycopersicon cheesmanii and Lycopersicon pennellii, do not respond to EIX treatment. The F₁ progeny of a L. esculentum×L. cheesmanii and a L. esculentum×L. pennellii cross responded to EIX treatment with an increase in ethylene biosynthesis and the induction of localized cell death. The F₂ progeny of the above mentioned crosses segregated 3:1 (responding:non-responding). We mapped the EIX-responding locus (Eix) to the short arm of chromosome 7 using a population of introgression lines (ILs), containing small RFLP-defined chromosome segments of L. pennellii introgressed into L. esculentum. RFLP analysis of 990 F₂ plants that segregated for the introgressed segment mapped the Eix locus 0.1 cM and 0.9 cM from the flanking markers TG61 and TG131, respectively. Using the marker TG61 we isolated a yeast artificial chromosome (YAC) clone that carries 300-kb DNA segments derived from the Eix region. By mapping the ends of this YAC clone we show that it spans the Eix locus. Thus, positional cloning of the Eix locus appears feasible. Received: 20 March 1999 / Accepted: 30 April 1999     

Genetic analysis and FISH mapping of the Colourless non-ripening locus of tomato

Cnr (Colourless non-ripening) is a dominant pleiotropic ripening mutation of tomato (Lycopersicon esculentum) which has previously been mapped to the proximal region of tomato chromosome 2. We describe the fine mapping of the Cnr locus using both linkage analysis and fluorescence in situ hybridisation (FISH). Restriction fragment length polymorphism (RFLP)-, amplified restriction fragment polymorphism (AFLP)-, and cleaved amplified polymorphic sequence (CAPS)-based markers, linked to the Cnr locus were mapped onto the long arm of chromosome 2. Detailed linkage analysis indicated that the Cnr locus was likely to lie further away from the top of the long arm than previously thought. This was confirmed by FISH, which was applied to tomato pachytene chromosomes in order to gain an insight into the organisation of hetero- and euchromatin and its relationship to the physical and genetic distances in the Cnr region. Three molecular markers linked to Cnr were unambiguously located by FISH to the long arm of chromosome 2 using individual BAC probes containing these single-copy sequences. The physical order of the markers coincided with that established by genetic analysis. The two AFLP markers most-closely linked to the Cnr locus were located in the euchromatic region 2.7-cM apart. The physical distance between these markers was measured on the pachytene spreads and estimated to be approximately 900 kb, suggesting a bp:cM relationship in this region of chromosome 2 of about 330 kb/cM. This is less than half the average value of 750 kb/cM for the tomato genome. The relationship between genetic and physical distances on chromosome 2 is discussed. Received: 11 January 2001 / Accepted: 30 April 2001     

Pigment Bodies in Fruits of Crimson and High Pigment Lines of Tomatoes

Pigment bodies in fruits of crimson (og^c), high pigment (hp),and crimson-high pigment (og^c hp) lines of tomatoes were observedby electron and light microscopy and compared with those ofnormal red lines and a yellow cultivar. During chloroplast-chromoplasttransformation, two main structurally distinct bodies are produced,their total and relative amounts apparently accounting for theentire range of colours (from very deep red to yellow) characterizingthe mature fruits of these different colour lines. The longnarrow crystalloids, believed to be lycopene, form in associationwith an extended thylakoid system; in senescing (over-ripe)fruit many of these are reduced to shorter irregular forms.The rounded globules are believed to be beta-carotene dissolvedin lipid material derived from membrane lysis. Analytical resultscorroborate microscopic observations that the effect of theog^c gene, as compared with the r⁺ gene for normal red colour,is to increase the lycopene content and lower the beta-carotenecontent. The effect of the hp gene is to increase the levelsof both pigments. The results support the view that the genescontrol the development of fruit pigments which affect chromoplastultrastructure. Lycopersicon esculentum Mill, tomato, fruit, pigment bodies, beta-carotene, lycopene     

Identification and characterization of a novel locus controlling early fruit development in tomato

Cultivated tomatoes (Lycopersicon esculen- tum) encompass a wide range of fruit size and shape variants. This variation provides the basis for dissecting the genetic and molecular pathways of ovary and fruit development. One fruit shape variant is displayed by the cultivar Sun 1642 (TA491). TA491 has an elongated fruit phenotype, while the wild relative L. pimpinellifolium LA1589 produces fruit that are nearly perfect spheres, a shape typical of wild tomatoes. Developmental studies indicated that the differences in fruit shape between TA491 and LA1589 are determined by events occurring immediately after pollination and extending to 14 days post-pollination. Quantitative trait mapping revealed a single major locus on chromosome 7 (named sun) to be responsible for the differential development of TA491 and LA1589 fruit. Other fruit shape loci characterized in tomato (e.g. fs8.1 and ovate) exert their effects before anthesis and early in ovary development. sun is the first major locus identified in tomato controlling fruit shape through post-pollination events. Received: 17 November 2000 / Accepted: 24 November 2000     

RAPD markers associated with salt tolerance in an interspecific cross of tomato (Lycopersicon esculentum×L. pennellii)

This study was conducted to identify randomly amplified polymorphic DNA (RAPD) markers associated with quantitative trait loci (QTLs) conferring salt tolerance during germination in tomato. Germination response of an F₂ population (2000 individuals) of a cross between UCT5 (Lycopersicon esculentum, salt-sensitive) and LA716 (L. pennellii, salt-tolerant) was evaluated at a salt-stress level of 175 mM NaCl+17.5 mM CaCl₂ (water potential ca. –9.5 bars). Germination was scored visually as radicle protrusion at 6-h intervals for 30 consecutive days. Individuals at both extremes of the response distribution (i.e., salt-tolerants and salt-sensitives) were selected. The selected individuals were genotyped for 53 RAPD markers and allele frequencies at each marker locus were determined. The linkage association among the markers was determined using a “Mapmaker” program. Trait-based marker analysis (TBA) identified 13 RAPD markers at eight genomic regions that were associated with QTLs affecting salt tolerance during germination in tomato. Of these genomic regions, five included favorable QTL alleles from LA716, and three included favorable alleles from UCT5. The approximate effects of individual QTLs ranged from 0.46 to 0.82 phenotypic standard deviation. The results support our previous suggestion that salt tolerance during germination in tomato is polygenically controlled. The identification of favorable QTLs in both parents suggests the likelihood of recovering transgressive segregants in progeny derived from these genotypes. Results from this study are discussed in relation to using marker-assisted selection in breeding for salt tolerance. Received: 16 June 1997 / Revision received: 11 August 1997 / Accepted: 2 September 1997     

Fine mapping of the<Emphasis Type="Italic"> parthenocarpic fruit</Emphasis> (<Emphasis Type="Italic">pat</Emphasis>) mutation in tomato

The parthenocarpic fruit (pat) gene of tomato is a recessive mutation conferring parthenocarpy, which is the capability of a plant to set seedless fruits in the absence of pollination and fertilization. Parthenocarpic mutants offer a useful method to regulate fruit production and a suitable experimental system to study ovary and fruit development. In order to map the Pat locus, two populations segregating from the interspecific cross Lycopersicon esculentum × Lycopersicon pennellii were grown, and progeny plants were classified as parthenocarpic or wild-type by taking into account some characteristic aberrations affecting mutant anthers and ovules. Through bulk segregant analysis, we searched for both random and mapped AFLPs linked to the target gene. In this way, the Pat locus was assigned to the long arm of chromosome 3, as also confirmed by the analysis of a set of L. pennellii substitution and introgression lines. Afterwards, the Pat position was refined by using simple sequence repeats (SSRs) and conserved ortholog set (COS) markers mapping in the target region. The tightest COSs were converted into CAPS or SCAR markers. At present, two co-dominant SCAR markers encompassing a genetic window of 1.2 cM flank the Pat locus. Considering that these markers are orthologous to Arabidopsis genes, a positional cloning exploiting the tomato-Arabidopsis microsynteny seems to be a short-term objective.Communicated by F. Salamini     

Comparative analysis of polymorphism and chromosomal location of tomato microsatellite markers isolated from different sources

Previously isolated tomato (Lycopersicon esculentum) microsatellite markers were mainly clustered in the centromeric heterochromatin and not located in euchromatic regions. To achieve a more-uniform distribution of microsatellite markers for genome mapping purposes, a set of tomato microsatellite markers containing dinucleotide simple sequence repeats were developed by screening genomic libraries enriched for single-copy sequences, and screening the tomato EST database. The tomato microsatellites isolated in these ways were characterized by combinations of different types of repeated motifs and they were polymorphic in a set of L. esculentum varieties detecting up to four alleles. A total of 20 markers were placed on the genetic map of tomato. Interestingly, all markers isolated from genomic libraries enriched for single-copy sequences by PstI-pre-digestion mapped into the centromeric regions. The majority of markers derived from EST sequences contained predominantly AT microsatellites and were located in euchromatic regions. Received: 22 December 2000 / Accepted: 4 May 2001     

Morphological and molecular characterization of fertile tetraploid somatic hybrids produced by protoplast electrofusion and PEG-induced fusion between Lycopersicon esculentum Mill. and Lycopersicon peruvianum Mill.

Summary Mesophyl protoplasts of two genotypes of cultivated tomato (Lycopersicon esculentum Mill.) and one of its wild relative species (Lycopersicon peruvianum Mill.) were fused by using electrofusion and polyethyleneglycol-induced fusion. Forty-three fertile tetraploid somatic hybrid plants, each deriving from separate calli, were recovered from both fusion procedures. Electrofusion appeared more efficient than chemical fusion for the production of somatic hybrids. These plants appeared morphologically similar, whatever the fusion procedure and tomato genotype. They had intermediate leaf, inflorescence, and flower morphology. After self-pollination, the hybrids set fruit of intermediate size and color. The hybrid nature of these plants was confirmed by isoelectric focusing of the Rubisco small subunits used as nuclear markers. L. esculentum and L. peruvianum were distinguished by means of two chloroplast markers: CF1-ATPase subunit as analyzed by isoelectro-focusing and ct DNA restriction patterns. All hybrids displayed both ct markers of only one parent with no biased transmission. Mitochondrial (mt) DNAs were prepared from flower buds by using miniaturized CsCl gradients. Preliminary analysis indicated that mt genomes from the hybrids all differed from those of both parents. mt DNA Sall restriction enzyme analysis revealed that all but two hybrids contained one novel fragment of 13.5 kb. Gene mapping experiments showed that the mt apocytochrome b and ATPase subunit 9 homologies in the somatic hybrid mt DNA resembled L. esculentum and L. peruvianum, respectively; the mt nad5 probe distinguished at least four distinct patterns in the hybrids. These results indicated that mt DNA rearrangements involving intergenomic recombinations occurred through protoplast fusion. A greater mt DNA polymorphism was induced with chemical fusion than with electrofusion.     

Restriction endonuclease analysis of plastid DNA from tomato, potato and some of their somatic hybrids

Summary The buoyant density and endonuclease restriction patterns of potato (Solanum tuberosum L.) and tomato (Lycopersicon esculentum) ptDNA were examined and compared with those of their somatic hybrids. The plastids from these plants, both of which belong to the family of Solanaceae, contain a single DNA species whose density of 1.697 gcm^-3 and size of approximately 156 kbp are similar to those of ptDNA from other higher plants. The Sal I restriction patterns were indistinguishable; however, those obtained with Kpn I, Pst I, and Eco RI disclosed that each species possesses a unique ptDNA. These observations suggest a relatively recent divergence of both species. Of the twelve hybrid lines screened, eight contained exclusively potato ptDNa and four contained only tomato ptDNA at a 0.1–3% level of detection. Rearrangements of modifications of DNA were not detected. The plastid identities of three hybrid lines that had previously been analyzed by isoelectric focusing of RuBPcase subunits (Melchers et al. 1978) agreed with those determined by restriction endonuclease analysis.Abbreviations used in the text ptDNA plastid DNA, chloroplast DNA - cDNA copy DNA - RuBPcase ribulose bisphosphate carboxylase/oxygenase - LSU large subunit of RuBPcase - kbp kilobase pairs - SDS sodium dodecyl sulfate - SSC standard saline citrate - IEF isoelectric focusing     

Paracentromeric sequences on tomato chromosome 6 show homology to human satellite III and to the mammalian CENP-B binding box

In order to isolate centromeric sequences from tomato (Lycopersicon esculentum) chromosome 6, a large-scale RAPD screen was performed. Among 1500 polymorphic RAPD markers tested, 100 were identified as chromosome 6-specific, using a L. esculentum substitution line carrying chromosome 6 from L. pennellii. Fifty-seven of these markers proved to originate from L. pennellii, and of these, 13 were genetically mapped between the morphological markers yellow virescent (yv) and thiaminless (tl), which flank the centromere. These markers could be assigned to three genetic loci, with 11 of the markers mapping to a single locus. Further resolution of this cluster was achieved using radiation-induced deletions that removed yv or tl but not the centromere. Seven markers were shown to be located outside all of the deletions. These seven markers and three of the other markers of the cluster were cloned and sequenced. Five of the clones are present as single-copy or low-copy-number sequences and five represent middle repetitive sequences. Three sequences show homology to the mammalian CENP-B binding box; clone AG12 contains two of these boxes and also shows homology to human satellite III. Received: 13 January 1998 / Accepted: 21 April 1998     

Map-based cloning in crop plants. Tomato as a model system: I. Genetic and physical mapping of jointless

A map-based cloning scheme is being used to isolate the jointless (j) gene of tomato. The jointless locus is defined by a single recessive mutation that completely suppresses the formation of the fruit and flower pedicel and peduncle abscission zone. jointless was mapped in an F₂ population of an interspecific cross between Lycopersicon esculentum and Lycopersicon pennellii to a 7.1 cM interval between two restriction fragment length polymorphism (RFLP) markers TG523 and TG194. Isogenic DNA pools were then constructed from a subset of the mapping population and screened with 800 random decamers for random amplification of polymorphic DNA (RAPD) polymorphisms. Five new RAPD markers were isolated and mapped to chromosome 11, two of which were mapped within the targeted interval. One marker, RPD158, was mapped 1.5 cM to the opposite side of jointless relative to TG523 and thus narrowed the interval between the closest flanking markers to 3.0 cM. Physical mapping by pulse-field gel electrophoresis using TG523 and RPD158 as probes demonstrated that both markers hybridize to a common 600 kb SmaI restriction fragment. This provided an estimate of 200 kb/cM for the relationship between physical and genetic distances in the region of chromosome 11 containing the j locus. The combined results provide evidence for the feasibility of the next step toward isolation of the jointless gene by map-based cloning — a chromosome walk or jump to jointless.