Effect of radiation dose on the production of and the extent of asymmetry in tomato asymmetric somatic hybrids

Summary Asymmetric somatic hybrids were recovered following fusion of tomato leaf mesophyll protoplasts with irradiated protoplasts isolated from Lycopersicon pennellii suspension cells. The asymmetry was determined by scoring the regenerants at between 20 and 24 loci using isozymes and restriction fragment length polymorphisms. In addition, three quantitative traits, fruit size, leaf shape, and stigma exsertion, were measured in the regenerants. The recovery of asymmetric somatic hybrids was as high as 50% of the regenerants, and there was no requirement for the transfer of a selectable marker gene from the irradiated partner. The amount of nuclear DNA transferred from the irradiated protoplast fusion partner was found to be inversely proportional to the radiation dose. It was possible to recover tomato asymmetric somatic hybrids which were self-fertile and contained limited amounts of genetic information from L. pennelli.     

Non-random inheritance of organellar genomes in symmetric and asymmetric somatic hybrids between Lycopersicon esculentum and L. pennellii

Summary The organization of the mitochondrial genome and the genotype of the chloroplast genome was characterized using restriction fragment length polymorphisms in a population (82 individuals) of symmetric and asymmetric somatic hybrids of tomato. The protoplast fusion products were regenerated following the fusion of leaf mesophyll protoplasts of Lycopersicon esculentum (tomato cv UC82) with suspension cell protoplasts of L. pennellii that had been irradiated with 5, 10, 15, 25, 50, or 100 kRads from a gamma source. The chloroplast genome in the somatic hybrids showed a random pattern of inheritance, i.e., either parental genome was present in equal numbers of regenerants, while in asymmetric somatic hybrids, the chloroplast genotype reflected the predominant nuclear genotype, i.e., tomato. The mitochondrial genome in the symmetric somatic hybrids showed a non-random pattern of inheritance, i.e., predominantly from the L. pennellii parent; asymmetric somatic hybrids had more tomato-specific mitochondrial sequences than symmetric somatic hybrids. The non-random inheritance of the chloroplast and mitochondrial DNA in these tomato protoplast fusion products appears to be influenced by the nuclear background of the regenerant.     

Responses to NaCl stress of cultivated and wild tomato species and their hybrids in callus cultures

Summary If in vitro culture is to be used for evaluating the salt tolerance of tomato hybrids and segregant populations in a breeding programme, it is previously necessary to get quick and reliable traits. In this work, growth and physiological responses to salinity of two interspecific hybrids between the cultivated tomato (Lycopersicon esculentum Mill) and its wild salt-tolerant species L pennellii are compared to those of their parents. The leaf callus of the first subculture was grown on media amended with 0, 35, 70, 105, 140, 175 and 210 mM NaCl for 40 days. Relative fresh weight growth of callus in response to increased salinity in the culture medium was much greater in L pennellii than in the tomato cultivars, and greater in the hybrids than in the wild species. Moreover, the different salt tolerance degree of hybrids was related to that of female parents. At high salt levels, only Cl^– accumulation was higher in L pennellii than in tomato cultivars, whereas in the hybrids both Cl^–, and Na⁺ accumulation were higher than in their parents. Proline increased with salinity in the callus of all genotypes; these increases were much higher in the tomato cultivars than in L pennellii, and the hybrids showed a similar response to that of the wild species. Salt-treated callus of the tomato cultivars showed significant increases in valine, isoleucine and leucine contents compared to control callus tissue. In contrast, these amino acids in callus tissues of the wild species and hybrids showed a tendency to decrease with increasing salinity.     

Chromosome association and pollen fertility of parental and interspecific hybrids of Lycopersicon esculentum X L. hirsutum and L. pennellii

Cytological studies were carried out on two wild species (L. hirsutum and L. pennellii) and the cultivated species (L. esculentum) of tomato and their F1 hybrids. Both parents and hybrids show a diploid chromosome number of 2n=24. The meiotic behaviour of the cultivated species showed a high degree of chromosome homology resulting in a high level of chiasmata frequency per bivalent. In contrast, the two wild species showed a slight increase in uniyalent frequency and a decrease in bivalent formation and chiasmata frequency. The meiotic behaviour of the hybrids showed a high level of univalents and low levels of bivalents as well as trivalents. Highly significant decreases in chiasmata frequency and increases in meiotic abnormalities, especially in the L. esculentum X L. pennellii hybrid, also were detected. The high meiotic irregularity and low chiasmata frequency recorded in the second hybrid indicated the disharmony and difference between its parental genomes and also served to predict its sterility. With regard to degree of pairing recorded in the hybrids, there is a possibility that sterility in such cases may refer to genetic factors in addition to the previously mentioned reasons. Pollen fertility showed no great difference between L. esculentum and L. hirsutum and their F1 hybrid, but a significant decrease was recorded in the L. esculentum X L. pennellii hybrid, which was clearly associated with high meiotic irregularity, low chiasmata frequency and chromosome association.     

Expression of unilateral incompatibility in pollen of Lycopersicon pennellii is determined by major loci on chromosomes 1, 6 and 10

Summary We have previously described gene introgression from the wild nightshade Solanum lycopersicoides into tomato (Lycopersicon esculentum) through the use of either diploid or sesquidiploid hybrids (the latter consisting of two genomes of L. esculentum and one genome of S. lycopersicoides). Both types of intergeneric hybrids display pollen sterility, but workable ovule fertility. Unilateral incompatibility prevents their direct hybridization with staminate L. esculentum. Pollen of a self-compattible form of the related wild species L. pennellii is compatible with pistils of L. esculentum x S. lycopersicoides hybrids. This trait was backcrossed from L. pennellii to L. esculentum in order to develop bridging lines that could be used to obtain progeny from the intergeneric hybrids and to study the inheritance of bridging ability. In progeny of L. esculentum x S. lycopersicoides hybrids pollinated with L. pennellii-derived bridging lines, preferential transmission of L. pennellii alleles was observed for certain isozyme and RFLP markers on chromosomes 1, 6 and 10. The skewed segregations suggest linkage to three major pollen-expressed compatibility loci. This was confirmed by observations of pollen tube growth, which indicated that compatibility with pistils of the diploid intergeneric hybrid occurred only in bridging lines at least heterozygous for the L. pennellii markers on chromosomes 1, 6 and 10. Compatibility with the sesquidiploid hybrid required only the chromosome 1 and 6 loci, indicating an apparent effect of gene dosage on expression of incompatibility in the pistil. In an F₂ L. esculentum x L. pennellii population, preferential transmission of L. pennellii alleles was observed for the same markers on chromosomes 1 and 10, as well as other markers on chromosomes 3, 11, and 12, but not 6. The chromosome 1 pollen compatibility locus maps to or near the S-locus, which determines S-allele specificity. The results are discussed in relation to existing genetic models for unilateral incompatibility, including the possible involvement of the S-locus.     

Recombination around the Tm2a and Mi resistance genes in different crosses of Lycopersicon peruvianum

The amount of recombination in three different intraspecific crosses of the wild tomato species Lycopersicon peruvianum was investigated for the short arm of chromosome 6 that harbors the Mi nematode resistance gene and the centromeric region of chromosome 9 that contains the Tm2a virus resistance gene. These two genes have been introgressed into the cultivated tomato and are associated with a significant reduction in recombination in the respective region when crossed to other L. esculentum lines. For both regions and all crosses within L. peruvianum significantly more recombination (up to more than ten fold) was observed in the gametes derived from the female parent than in those from the male parent. In general, the differences were more pronounced for chromosome 6 than for chromosome 9. The amount of recombination in the three intraspecific L. peruvianum crosses was compared with the amount of recombination observed in the standard interspecific cross used for the construction of a saturated genetic map of tomato (L. esculentum x L. pennellii). In two of three cases for each region, more recombination was observed in the intraspecific crosses and in one case for each region significantly less recombination was found in the intraspecific cross when compared to the interspecific cross. Specifically for the Mi-carrying region, crosses within L. peruvianum exhibited up to 15-fold more recombination than crosses between resistant and susceptible L. esculentum lines, and such crosses will allow the fine mapping of this gene for the purpose of map-based cloning.     

Fertility of somatic hybrids from protoplast fusions of Solanum brevidens and S. tuberosum

Summary Two sets of somatic hybrids between Solanum brevidens (2x) and S. tuberosum (2x and 4x) were evaluated for male fertility, meiotic regularity and female fertility. The somatic hybrids were tetraploids from 2x + 2x fusions and hexaploids from 2x + 4x fusions. Pollen stainability ranged from 0 to 83% in tetraploids and from 0 to 23% in hexaploids. The tetraploids had more regular meiosis, lower levels of micropollen and fewer unassociated chromosomes than hexaploids. However, except for a low level of selfing, the pollen of both sets of hybrids was ineffective in pollinations. The tetraploids, as females, crossed poorly with 2x and 4x tester species and selfed only at low levels. The hexaploid fusion hybrids also crossed poorly with the 2x tester species and selfed only to a limited degree; however, they crossed well with 4x testers. Seed set in crosses with S. tuberosum Group Andigena, and S. tuberosum Group Tuberosum cultivars Kathadin and Norland averaged 16.7, 15.6 and 28.6 seeds per fruit, respectively. Progeny from these crosses had 5x or nearly 5x ploidy levels. The results indicate that reasonable levels of female fertility can be obtained in somatic fusion hybrids of S. brevidens and S. tuberosum.Mention of a trademark, proprietary product, or vendor does not constitute a guarantee or warranty of the product by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable     

Molecular analysis of the extent of asymmetry in two asymmetric somatic hybrids of tomato

Summary Two somatic hybrid plants generated from a single fusion event between Lycopersicon esculentum and irradiated L. pennellii protoplasts have been analyzed at the molecular level. Over 30 loci have been analyzed using isozymes and RFLPs. All loci tested on chromosomes 2–10 were heterozygous, while those loci on chromosome 12 were homozygous L. pennellii in both somatic hybrids. In one of the somatic hybrids, 2850, loci on chromosome 1 were also homozygous L. pennellii. The other somatic hybrid, 28F5, was heterozygous at all chromosome 1 loci tested, but exhibited altered stoichiometry of parental bands as compared to the sexual hybrid. Loci on chromosome 2 from both somatic hybrids have altered stoichiometry, with L. pennellii alleles being four times more abundant than expected. Both somatic hybrids contain the L. esculentum chloroplast genome, while only L. pennellii polymorphisms have been detected in the mitochondrial genome.     

Pollen irradiation and possible gene transfer in Nicotiana species

Summary Progeny from crosses of Nicotiana langsdorffii with gamma irradiated pollen of Nicotiana alata Crimson Bedder showed skewed segregation in the F₂ favoring the maternal parent. This is probably not gene transfer in a strict sense, rather just an extreme case of reduced transmission of irradiated chromosomes, leading to massive overrepresentation of maternal genes. Gene transfer or mutational loss may explain some anomalous F₁ plants. Segregation in the F₂ progeny showed the presence of several genes from the irradiated pollen. Crosses of Nicotiana sylvestris, N. plumbaginifolia N. paniculata, and Petunia parodii with irradiated pollen from N. alata and Petunia hybrida showed no evidence of gene transfer, nor did experiments with irradiated mentor pollen. This indicates that gene transfer with irradiated pollen between non-crossing species or between species giving sterile hybrids is probably a rare phenomenon.     

A possible heterotic threshold in the potato and its implications for breeding

Summary Complex hybrids containing genomes from three different Solanum tuberosum Groups were synthesized (3-way hybrids), utilizing 2n gametes in 4x–2x crosses. Ten such families were compared to nine analogous two-Group (2-way) hybrid families and nine (1-way) families representing conventional Gp. Tuberosum breeding materials. The three types of crosses, representing three descending levels of heterozygosity, were placed in four field trials.The 3-way hybrids were never significantly superior to the 2-way hybrids for vigor, yield, or tuber type. When yields were adjusted for maturity differences, the 3-way hybrids tended to be inferior to the 2-way hybrids for yield. This suggests that there may be a heterotic threshold in the cultivated potato, beyond which point more heterozygosity does not result in greater vigor or more yield.While the 2-way and 3-way hybrids did not significantly differ from each other, they both dramatically surpassed the conventional 1-way crosses for vigor and yield (42%). The evidence of a possible heterotic threshold indicates that more sophisticated methods such as cell fusion and bilateral sexual polyploidization may not be necessary to exploit the full potential of the hybrid approach in the potato. A simple and direct 2-way hybridization approach may be optimal, or at least would seem comparable with other hybrid approaches, and is a technology ready for immediate and widespread implementation.     

Characterisation of a cytoplasmic male-sterile hybrid line between Lycopersicon peruvianum Mill. ×Lycopersicon pennellii Corr. and its crosses with cultivated tomato

 The cytoplasmic male-sterile (CMS) line CMS-pennellii (BC₁₀P₂ L. peruvianum×L. pennellii) and its complex hybrids with L. esculentum were studied. The established sterility was classified as the sporogenous type. As a result of the interaction of the genome of L. pennellii and the cytoplasm of L. peruvianum clear changes were established in the profiles of malic enzyme and esterase. Restriction fragment length polymorphism (RFLP) was detected between the mitochondrial (mt) genomes of CMS-pennellii and the cytoplasm donor, L. peruvianum, for two mtDNA probes: atpA and nad3. The established differences in the isozyme pattern and mt genomes are considered as useful markers to distinguish fertile and sterile plants. A breakthrough in the unilateral incompatibility of CMS-pennellii and the incorporation of the genome of L. esculentum on a CMS background is reported. The analysis of the complex hybrids assumes the interaction of two dominant genes – a maintainer gene from L. pennellii and a restorer gene from cultivated tomato. The hybrids produced with L. esculentum provide the basis for the development of a CMS system in cultivated tomato. Received: 25 May 1998 / Accepted: 26 August 1998     

Regeneration of somatic hybrid plants formed between Lycopersicon esculentum and L. pennellii

Summary Somatic hybrid plants have been regenerated following polyethylene glycol mediated fusion of leaf mesophyll protoplasts from tomato and protoplasts from Lycopersicon pennellii callus. Three different cultivars of tomato were used as sources of protoplasts: Early Girl, Manapal, and UC82B. Fusions were performed between protoplasts of these tomato cultivars and protoplasts of L. pennellii, and between protoplasts of the cultivars and protoplasts of L. pennellii that had been exposed to 3 or 6 krads of gamma radiation. Somatic hybrid plants were identified on the basis of heterozygous isozyme banding patterns, and leaf and flower morphology. Somatic hybrid plants were regenerated following fusion of tomato protoplasts with either untreated or irradiated L. pennellii protoplasts. All were heterozygous for isozyme loci on five different chromosomes. Regenerated somatic hybrids showed inheritance of either or both parental chloroplast genomes, but predominantly the L. pennellii mitochondrial genome. The regenerated somatic hybrid plants exhibited reduced fertility, less than 20% viable pollen. A total of 34 somatic hybrid calli were identified. Of these, 21 regenerated shoots, and 7 produced seed following manual pollinations.     

Asymmetric somatic hybrid plants between an interspecific Lycopersicon hybrid and Solanum melongena

Summary Asymmetric somatic hybrid plants were obtained by a modified PEG/DMSO fusion procedure between protoplasts derived from suspension cells of an interspecific tomato hybrid, Lycopersicon esculentum x L. pennellii, and mesophyll protoplasts of Solanum melongena, eggplant. The tomato hybrid was previously transformed with Agrobacterium tumefaciens and contained the kanamycin-resistance marker gene. Prior to fusion, the donor protoplasts of the tomato hybrid were gamma irradiated at 9.0 krad. Thus, non-division of irradiated tomato hybrid protoplasts coupled with kanamycin sensitivity of eggplant enabled selection of somatic cell hybrids. Forty-nine calli selected post-fusion regenerated leaf-like structures in the presence of 50 mg/l kanamycin. However, only four of the 49 calli regenerated intact shoots which rooted in the presence of 50 mg/l kanamycin and were later transferred to the greenhouse. Analysis of phosphoglucoisomerase and peroxidase isozymes, and Southern hybridization with a nuclear-specific pea 45 S ribosomal RNA gene confirmed somatic hybrid status. Cytology revealed that the four hybrid plants had chromosome numbers of 45, 60, 42 and 57, respectively; they were all sterile.     

Experimental hybridization between catfishes of the families Clariidae and Pangasiidae in Thailand

Synopsis Hybrids between the clariid speciesClarias macrocephalus andC. batrachus and the pangasiid speciesPangasius sutchi were obtained by hormone injection of brood stock and artificial fertilization. Pure parental crosses as well as all possible hybrid combinations were obtained. Fertility, hatchability, and post-yolk absorption survival was high (66–99%) in all pure parental crosses and in all crosses between the two species ofClarias. In crosses betweenClarias andPangasius fertilization was also very high (68–97%) but hatchability varied from 11 to 23% and post-yolk absorption survival from 0% inPangasius sutchi ×Clarias batrachus to about 50% inPangasius sutchi ×Clarias macrocephalus . The longest-lived hybrids ofPangasius andClarias were those ofPangasius sutchi ×Clarias macrocephalus which survived until the experiment was prematurely terminated due to contaminated food after 4 1/2 months, at which point they had grown to total lengths of 8–14cm. The hybrids comprised four morphotypes, two relativelyPangasius-like and two relativelyClarias-like, but all markedly different from the parental species.     

Hybridisation in the Littorina saxatilis species complex (Prosobranchia : Mollusca)

This paper details attempts to breed members of the L. saxatilis species complex in the laboratory and to construct interspecific hybrids between them. Success in reciprocal crosses between animals from the type localities of the species of Littorina saxatilis (Olivi) and Littorina rudis (Maton) indicates that these two taxa are synonymous. Six of the twelve possible reciprocal hybridisation crosses between the four species (L. saxatilis, L. arcana Hannaford Ellis, L. nigrolineata Gray and L. neglecta Bean) have been attempted, with only one proving successful, that between male L. saxatilis and female L. arcana. This hybrid cross produces viable offspring, although at a lower frequency than either of the parental crosses in the laboratory, while the reciprocal cross has, as yet, proved unsuccessful. Limited work on the F1 hybrids shows them to be inter-fertile and also capable of backcrossing with male L. saxatilis, but not with female L. saxatilis or L. arcana. Details are also given of attempts to find natural hybrids in sympatric populations of the species of the complex, using gel electrophoresis.     

Allotriploid somatic hybrids of diploid tomato (Lycopersicon esculentum Mill.) and monoploid potato (Solanum tuberosum L.)

Allotriploid somatic hybrids were obtained from fusions between protoplasts of diploid tomato and monohaploid potato. The selection of fusion products was carried out in two different ways: (1) The fusion of nitrate reductase-deficient tomato with potato gave rise only to hybrid calli if selection was performed on media lacking ammonium. Parental microcalli were rarely obtained and did not regenerate. (2) The fusion of cytoplasmic albino tomato with potato gave rise to albino and green hybrid calli and plants. Allotriploids were identified from the two somatic hybrid populations by counting chloroplast numbers in leaf guard cells and by flow cytometry of leaf tissue. Although some pollen fertility of allotriploids and pollen-tube growth of tomato, potato andLycopersicon pennellii into the allotriploid style were observed, no progeny could be obtained. The relevance of allotriploid somatic hybrids in facilitating limited gene transfer from potato to tomato is discussed.     

Unilateral incongruity in crosses involvingLycopersicon pennellii andL. esculentum is distinct from self-incompatibility in expression,timing and location

Both interspecific and intraspecific mechanisms restrict the exchange of genes between plants. Much research has focused on self incompatibility (SI), an intraspecific barrier, but research on interspecific barriers lags behind. We are using crosses betweenLycopersicon esculentum andL. pennellii as a model with which to study interspecific crossing barriers. The crossL. esculentum×L. pennellii is successful, but the reciprocal cross fails. Since the cross can be successfully made in one direction but not the other, gross genomic imbalance or chromosomal abnormality are precluded as causes. We showed that the lack of seed set observed in the crossL. pennellii×L. esculentum is due to the inability of pollen tubes to grow more than 2–3 mm into the style, whereas S1 crosses show continued slow pollen tube growth but, also, fail to set seed. These results indicate that the unilateral response is a barrier distinct from SI, differing from SI in the timing and location of expression in the style. We therefore suggest that this unilateral response in theL. pennellii×L. esculentum cross is more accurately referred to as unilateral incongruity (UI) rather than interspecific incompatibility. Periclinal chimeras were used to determine the tissues involved in UI. The results of crosses with the available chimeras indicate that the female parent must beL. pennellii at either LI (layer 1) or both LI and LII (layer 2) and the male parent must beL. esculentum at either LII or both LI and LII to observe UI similar to that seen in theL. pennellii×L. esculentum cross. Pollinations with a mixture of pollen fromL. pennellii and from transgenicL. esculentum plants harboring a pollen-specific GUS reporter gene marker were used to ascertain whether the growth of the pollen tubes of either species was modified as a possible means of overcoming UI. We found no evidence of communication between the two types of pollen tubes to either enhance or restrict all pollen tube growth.     

Fine Mapping of ui6.1, a Gametophytic Factor Controlling Pollen-Side Unilateral Incompatibility in Interspecific Solanum Hybrids

Unilateral incompatibility (UI) is a prezygotic reproductive barrier in plants that prevents fertilization by foreign (interspecific) pollen through the inhibition of pollen tube growth. Incompatibility occurs in one direction only, most often when the female is a self-incompatible species and the male is self-compatible (the “SI × SC rule”). Pistils of the wild tomato relative Solanum lycopersicoides (SI) reject pollen of cultivated tomato (S. lycopersicum, SC), but accept pollen of S. pennellii (SC accession). Expression of pistil-side UI is weakened in S. lycopersicum × S. lycopersicoides hybrids, as pollen tube rejection occurs lower in the style. Two gametophytic factors are sufficient for pollen compatibility on allotriploid hybrids: ui1.1 on chromosome 1 (near the S locus), and ui6.1 on chromosome 6. We report herein a fine-scale map of the ui6.1 region. Recombination around ui6.1 was suppressed in lines containing a short S. pennellii introgression, but less so in lines containing a longer introgression. More recombinants were obtained from female than male meioses. A high-resolution genetic map of this region delineated the location of ui6.1 to ∼0.128 MU, or 160 kb. Identification of the underlying gene should elucidate the mechanism of interspecific pollen rejection and its relationship to self-incompatibility.FLOWERING plants have evolved several reproductive barriers for preventing illegitimate hybridization with related species. These barriers may be expressed prefertilization and/or postfertilization. Unilateral incompatibility or incongruity (UI) is a prefertilization barrier that occurs when pollen of one species is rejected on pistils of a related species, while no rejection occurs in the reciprocal cross (De Nettancourt 1977). In theory, unilateral incompatibility should reinforce species identity in natural, sympatric populations of related taxa. This barrier also impedes the efforts of plant breeders to transfer traits from wild species into related crop plants. For example, the transfer of cytoplasmic traits from species with maternally inherited chloroplasts and mitochondria may be prevented by unilateral crossing barriers. Nuclear-encoded traits may also be inaccessible if F₁ interspecific hybrids are both male sterile and incompatible as female parents.In the Solanaceae, unilateral incompatibility is observed in crosses between cultivated tomato (Solanum lycopersicum, formerly Lycopersicon esculentum) and some related wild species. In general, pistils of the cultivated tomato act as a “universal acceptor,” in that they fail to recognize and reject pollen of other tomato species. In the reciprocal crosses, pollen of S. lycopersicum is rejected on styles of virtually all of the green-fruited species, but not on styles of other red or orange-fruited species (reviewed by Mutschler and Liedl 1994). This pattern is mostly consistent with the “SI × SC” rule, wherein pollen of self-compatible (SC) species (including cultivated tomato) are rejected on pistils of self-incompatible (SI) species, but not in the reverse direction (Lewis and Crowe 1958). Exceptions to the SI × SC rule in the tomato clade include species or populations that have lost self-incompatibility but retain the ability to reject pollen of tomato. This is the case for the facultative outcrossing species S. chmielewskii, the autogamous S. neorickii (formerly L. parviflorum), as well as marginal SC populations of normally SI species such as S. pennellii and S. habrochaites (formerly L. hirsutum). An SC accession of S. pennellii, LA0716, is exceptional in having lost the ability to reject self pollen, while retaining the ability to serve as pollen parent on styles of SI accessions of this species (and other SI species, including S. peruvianum and S. lycopersicoides) (Hardon 1967; Rick 1979; Quiros et al. 1986). In this regard, S. pennellii LA0716 conforms to the Lewis and Crowe (1958) model in that it behaves like a transitional form lacking SI function in the pistil but not in the pollen.Unilateral incompatibility may also occur in crosses between populations or races of a single species. In S. habrochaites for example, pollen from SC biotypes located at the northern or southern margins of its geographic range is rejected on pistils of the central, SI populations (Martin 1961, 1963). Furthermore, pollen from the northern SC group is rejected by styles of the southern SC populations. Yet pistils of both SC biotypes are able to reject pollen of cultivated tomato. Thus there appear to be at least three distinct unilateral crossing barriers, just within S. habrochaites, possibly indicating different pollen tube recognition and rejection systems. The F₁ N × S hybrid is SC, as expected, but SI plants are recovered in the F₂ generation, suggesting that the loss of SI occurred via independent mutations in the north and the south (Rick and Chetelat 1991).Interspecific F₁ hybrids between SI wild species and SC cultivated tomato are self-incompatible and reject pollen of cultivated tomato, indicating both traits are at least partially dominant (McGuire and Rick 1954; Martin 1963; Hardon 1967). Interestingly, pollen of the F₁ hybrids is incompatible on pistils of the wild species parent (i.e., including other individuals of the same accessions, but with nonmatching S alleles). This observation suggests that there are dominant factors from cultivated tomato that lead to pollen rejection on styles of the wild species, regardless of the pollen genotype. This apparent sporophytic effect contrasts with the purely gametophytic nature of pollen SI specificity in the Solanaceae (De Nettancourt 1977).Early studies of the inheritance of unilateral incompatibility in tomato suggested the involvement of several genes controlling the pistil response; however, the genetics of pollen responses have received little attention. In F₂ S. habrochaites (northern SC accession) × S. habrochaites (central SI accession), the rejection of pollen from the SC parent segregated as if controlled by one to two dominant genes from the SI accession (Martin 1964). In crosses of S. lycopersicum to both SI and SC accessions of S. pennellii, the intra- and interspecific crossing relations were largely consistent with the Lewis and Crowe (1958) model of stepwise mutation at the S locus (Hardon 1967); there was also evidence of a second barrier in the SC S. pennellii accession. In F₁ and BC₁ hybrids of S. lycopersicum × S. habrochaites, the segregation of unilateral and self-incompatibilities was consistent with the action of two major genes, with minor polygenes indicated as well (Martin 1967). More recently, several QTL underlying pistil-side unilateral and self-incompatibilities were mapped in BC₁ S. lycopersicum × S. habrochaites (Bernacchi and Tanksley 1997); the major QTL for both forms of pollen rejection was located at or near the S locus on chromosome 1, which controls SI specificity (Tanksley and Loaiza-Figueroa 1985).There are little data on pollen-side unilateral incompatibility factors in the tomato clade, or any other system. Our previous work identified two to three genetic loci from S. pennellii that are required for pollen to overcome incompatibility on pistils of S. lycopersicum × S. lycopersicoides or S. lycopersicum × S. sitiens hybrids (Chetelat and Deverna 1991; Pertuze et al. 2003). One of these factors mapped to the S locus, the other two were on chromosomes 6 and 10. In this system the female tester stocks were either diploid or allotriploid hybrids, the latter containing one genome of the wild, SI parent, plus two genomes of cultivated tomato; both types of hybrids reject pollen of cultivated tomato. The pollen parents were either F₁ S. lycopersicum × S. pennellii or bridging lines developed by backcrossing the F₁ to cultivated tomato and selecting for the ability to overcome stylar incompatibility. In the progeny, distorted segregation ratios were observed in which the S. pennellii alleles were preferentially transmitted, indicating linkage to gametophytic factors required forcompatibility.This experimental system has several advantages for detecting pollen (gametophytic) unilateral incompatibility genes. First, pollen-expressed factors are readily distinguished from pistil factors because only the former show linkage to S. pennellii specific markers. Second, pollen rejection is by unilateral, not self-incompatibility, since both species contributing to the pollen genotype, S. lycopersicum and S. pennellii, are SC. Finally, as we describe herein, the rejection of tomato pollen by pistils of the interspecific hybrids is weakened by the decreasing dosage of the S. lycopersicoides genome, which reduces the number of pollen factors required for compatibility. Thus, the gametophytic factors on chromosomes 1 and 6 (denoted hereinafter ui1.1 and ui6.1), when present in the same pollen, are sufficient for full compatibility on pistils of allotriploid interspecific hybrids, whereas they confer only partial compatibility on diploid hybrids.Our overall objectives are to identify the genes underlying both the chromosome 1 and chromosome 6 pollen-specific unilateral incompatibility factors from S. pennellii and to determine the nature of their interaction. Toward this goal, we report herein the high-resolution genetic and physical mapping of the ui6.1 region.     

Cytogenetical relationships between Rumex tuberosus,R. thyrsiflorus and R. acetosa and occurrence of polyploidy among their hybrids

Summary Reciprocal crosses were performed between Rumex tuberosus and two other taxa belonging to the Acetosa group: R. acetosa and R. thyrsiflorus. All three taxa are dioecious with the same chromosome numbers, XX + 12A, XYY+12A, but they differ from one another in the morphology of some autosomes. R. tuberosus and R. thyrsiflorus are similar in external morphology, while R. acetosa differs greatly from the other two taxa in external morphology as well as ecological characteristics.The F ₁ and F ₂ hybrids were fully vigorous and viable but their fertility was greatly reduced. Meiotic irregularities were observed in hybrids derived from all crosses. The most remarkable meiotic irregularity was diad formation after first meiotic division. The unreduced gametes derived from diads were responsible for the high frequency of polyploidy observed among the F ₂ hybrids. In the cross R. tuberosus × R. acetosa the whole F ₂ generation was tetraploid.It is concluded from the analysis performed that R. tuberosus, R. acetosa and R. thyrsiflorus are separate species, closely related to one another but already isolated by genetic and ecological barriers.     

A farnesyl pyrophosphate synthase gene expressed in pollen functions in S‐RNase‐independent unilateral incompatibility

Multiple independent and overlapping pollen rejection pathways contribute to unilateral interspecific incompatibility (UI). In crosses between tomato species, pollen rejection usually occurs when the female parent is self‐incompatible (SI) and the male parent self‐compatible (SC) (the ‘SI × SC rule’). Additional, as yet unknown, UI mechanisms are independent of self‐incompatibility and contribute to UI between SC species or populations. We identified a major quantitative trait locus on chromosome 10 (ui10.1) which affects pollen‐side UI responses in crosses between cultivated tomato, Solanum lycopersicum, and Solanum pennelliiLA0716, both of which are SC and lack S‐RNase, the pistil determinant of S‐specificity in Solanaceae. Here we show that ui10.1 is a farnesyl pyrophosphate synthase gene (FPS2) expressed in pollen. Expression is about 18‐fold higher in pollen of S. pennellii than in S. lycopersicum. Pollen with the hypomorphic S. lycopersicum allele is selectively eliminated on pistils of the F₁ hybrid, leading to transmission ratio distortion in the F₂ progeny. CRISPR/Cas9‐generated knockout mutants (fps2) in S. pennelliiLA0716 are self‐sterile due to pollen rejection, but mutant pollen is fully functional on pistils of S. lycopersicum. F₂ progeny of S. lycopersicum × S. pennellii (fps2) show reversed transmission ratio distortion due to selective elimination of pollen bearing the knockout allele. Overexpression of FPS2 in S. lycopersicum pollen rescues the pollen elimination phenotype. FPS2‐based pollen selectivity does not involve S‐RNase and has not been previously linked to UI. Our results point to an entirely new mechanism of interspecific pollen rejection in plants.