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.     

T-DNA-tagged chromosome 12 in donor Lycopersicon esculentum × L. pennellii is retained in asymmetric somatic hybrids with recipient Solanum lycopersicoides

Summary Asymmetric somatic hybrid plants were recovered after fusing irradiated mesophyll protoplasts of donor Lycopersicon esculentum × L. pennellii (EP) interspecific hybrid with callus-derived protoplasts of recipient Solanum lycopersicoides. EP plant A54 had been previously transformed by an agrobacterium vector, and the T-DNA insert mapped to the L. esculentum chromosome 12. The T-DNA insert conferred kanamycin resistance to EP that was subsequently used to select cell fusion products and recover asymmetric hybrid plants that retained tagged chromosome 12. Doses of 50- and 100-Gy irradiation promoted the elimination of only a few donor chromosomes. At 200 Gy, the regenerated plants had ploidy levels higher than tetraploid. However, the T-DNA tagged chromosome 12 was always retained in the asymmetric hybrid plants tested. Likewise, all plants from the 100-Gy series, with the exception of number 160, were mixoploid in the root-tip cells. Such mixoploid asymmetric somatic hybrids could be stabilized by inducing adventitious shoots on leaf strips cultured on shoot regeneration medium containing kanamycin. The asymmetric hybrid plants did not produce viable seed when self-pollinated or backcrossed to tomato or S. lycopersicoides. Present address: Department of Biology, University College of London, Gower Street, London, UK     

Characterization of aLycopersicon esculentum xSolanum lycopersicoides somatic hybrid lacking a glutamate oxaloacetate transaminase isozyme

Morphological, cytological, isozyme and chloroplast DNA analyses were used to determine possible mechanism(s) for the loss of glutamate oxaloacetate transaminase-4 (GOT-4) isozyme activity in a somatic hybrid. Plant 204-1, derived by cell fusion between tomato (Lycopersicon esculentum) andSolanum lycopersicoides, was characterized for bothGot-4 and acid phosphatase-2 (Aps-2), two isozyme loci which are closely linked (recombination 2.5 cM). This hybrid was determined to be chimeric for bothGot-4 andAps-2. TheS. lycopersicoides plant used to provide cells for the fusion was determined to be heterozygous for bothGot-4 andAps-2. Only oneS. lycopersicoides allelic form ofAps-2 andGot-4 was found in plant 204-1. This observation indicated that either the alternative copy of theS. lycopersicoides chromosome region encodingGot-4 andAps-2 is deleted or the entire chromosome is absent. Plant 204-1 was cytologically determined to be aneuploid with approximately 62 chromosomes. Sixty-two somatic hybrids of separate callus origin were analysed for GOT-4 and a high proportion (27%) lacked theS. lycopersicoides form ofGot-4. The loss of this allele and the linkedAps allele most likely occurred in the suspension culture ofS. lycopersicoides used to provide cells for fusion.     

Molecular mapping of chromosome segments introgressed from Solanum lycopersicoides into cultivated tomato (Lycopersicon esculentum)

The wild nightshade Solanum lycopersicoides (accessionLA2951) was backcrossed to the cultivated tomato (Lycopersicon esculentum cv ’VF36’), then inbred through single-seed descent for several generations. Over 300 backcross-inbred families thereby derived were genotyped at 139 marker loci, consisting of RFLPs, allozymes, and monogenic morphological markers, to identify introgressed S. lycopersicoides chromosomes and segments thereof. The pattern of genotypes observed in the lines indicated a high degree of overall synteny between the S. lycopersicoides genome and that of tomato. Two putative single-copy RFLP probes revealed secondary loci in this wide cross. Recovery of the L. esculentum genome was more rapid than expected, with an average value in the BC₂ generation of 97.8%, versus the expected value of 87.5%. This was due to widespread segregation distortion that favored L. esculentum alleles as well as a tendency for plants homozygous for in- trogressed segments to be partially or completely male-sterile, thereby preventing the fixation of S. lycopersicoides markers in many lines. Despite these difficulties, nearly every S. lycopersicoides marker (or approximately 98% of the genome, measured in centi Morgans) was represented in at least 1 backcross-inbred line, with only a region on chromosome 4L missing from the population as a whole. Although the extent of transmission and fixation of introgressed segments varied according to chromosome, overall approximately 66% of the S. lycopersicoides genome was represented by homozygous in- trogressions with sufficient fertility to reproduce by self-pollination. An excess of terminal (vs. interstitial) segments was noted, and putative heterozygous substitutions for chromosomes 6, 7, 8, and 10 were found. Recombination within certain introgressed regions was reduced over 100-fold. These backcross-inbred lines are expected to facilitate the genetic analysis of traits identified in S. lycopersicoides and their transfer into horticultural tomatoes. Received: 16 March 1999 / Accepted: 22 June 1999     

Meiosis in hybrids betweenLycopersicon esculentum andSolanum pennellii

Meiotic chromosome cytology was compared betweenSolanum pennellii, Lycopersicon esculentum, and the F₁ hybrid. Pachytene chromosomes are very similar in gross morphology, but several of theS. pennellii chromosomes were found to have somewhat longer chromatic regions with discrete chromomeres, and darkly staining chromomeres in the achromatic regions.Little evidence could be found for the existence of rearrangements between chromosomes of the two species. With respect to chromomere pattern, on the other hand, a number of differences were seen. Meiosis in the hybrid is strictly regular. Only size inequalities occur in certain bivalents.Considering the evidence from chromosome pairing, hybridization compatibility, hybrid fertility, and plant morphology, it is concluded that the phylogenetic relationship is much closer betweenS. pennellii andL. esculentum than it is between either one andS. lycopersicoides. Attention is called to the present unsatisfactory placement ofS. pennellii and to the need for revising the taxonomy to place it andL. esculentum in the same genus, possibly in the same subgeneric category.This research was supported in part by grant G-10704 of the National Science Foundation.     

Molecular analysis of single copy and repetitive genes on chromosome 2 in intergeneric tomato somatic hybrid plants

Restriction fragment polymorphisms were used to identify and quantify the nuclear contributions from each parent to somatic hybrid plants between tomato (Lycopersicon esculentum Mill.) cv. Sub-Arctic Maxi and Solanum lycopersicoides Dun. Three single-copy clones, 2–13, 2–17, and 3–288, and a clone for the 45s ribosomal RNA, pHA2, all mapped to chromosome 2 of tomato, were used in analysis of 47 somatic hybrids. The amount of hybridizing probe for each parental band was quantified by densitometry of the autoradiograph film. Analyses with the three single-copy clones indicated that there were more than two S. lycopersicoides copies in most somatic hybrid plants. For at least one somatic hybrid there was a loss of one tomato copy. No evidence was found for more than two copies donated from tomato or loss of a copy from S. lycopersicoides. Most of the observed variation in copy number of the single-copy clones was consistent with chromosomal changes occurring in the suspension cells from which S. lycopersicoides parental protoplasts were derived.The number of copies of rDNA derived from each parent varied independently of the number of copies of single-copy clones from each parent. Changes in the copy number of rDNA occurred in both tomato and S. lycopersicoides genomes.     

Mapping of loci from <Emphasis Type="Italic">Solanum lycopersicoides</Emphasis> conferring resistance or susceptibility to <Emphasis Type="Italic">Botrytis cinerea</Emphasis> in tomato

Cultivated tomato (Solanum lycopersicum, syn. Lycopersicon esculentum) is susceptible to the necrotrophic ascomycete and causal agent of gray mold, Botrytis cinerea. Resistance to this fungal pathogen is elevated in wild relatives of tomato, including Solanum lycopersicoides. An introgression line population (IL) containing chromosomal segments of S. lycopersicoides within the background of tomato cv. VF36 was used to screen the genome for foliar resistance and susceptibility to B. cinerea. Based on this screen, putative quantitative trait loci (QTL) were identified, five for resistance and two for susceptibility. Four resistance QTL decreased infection frequency while the fifth reduced lesion diameter. One susceptibility QTL increased infection frequency whereas the other increased lesion diameter. Overlapping chromosomal segments provided strong evidence for partial resistance on chromosomes 1 and 9 and for elevated susceptibility on chromosome 11. Segregation analysis confirmed the major resistance QTL on the long arm of chromosome 1 and susceptibility on chromosome 11. Linkage of partial resistance to chromosome 9 could not be confirmed. The usefulness of these data for resistance breeding and for map-based cloning of foliar resistance to B. cinerea is discussed.     

Somatic hybrid plants between Lycopersicon esculentum and Solanum lycopersicoides

Summary Leaf mesophyll protoplasts of Lycopersicon esculentum (2n=2x=24) were fused with suspension culture-derived protoplasts of Solanum lycopersicoides (2n=2x=24) and intergeneric somatic hybrid plants were regenerated following selective conditions. A two phase selection system was based on the inability of S. lycopersicoides protoplasts to divide in culture in modified medium 8E and the partial inhibition of L. esculentum protoplasts by the PEG/DMSO fusion solution. At the p-calli stage, putative hybrids were visually selected based on their hybrid vigor and lime-green coloration in contrast to slower growing parental calli characterized by a watery, whitish-brown coloration. Early identification of the eight hybrid plants studied was facilitated by isozyme analysis of leaf tissue samples taken from plants in vitro at the rooting stage. Regenerated plants growing in planting medium were further verified for hybridity by 5 isozymes marking 7 loci on 5 chromosomes in tomato. These included Skdh-1 mapped to chromosome 1 of tomato, Pgm-2 on chromosome 4, Got-2 and Got-3 on chromosome 7, Got-4 on chromosome 8, and Pgi-1 and Pgdh-2 both on chromosome 12. Fraction I protein small subunits further confirmed the hybrid nature of the plants with bands of both parents expressed in all hybrids. The parental chloroplasts could not be differentiated by the isoelectric points of the large subunit. Seven of the eight somatic hybrids had a chromosome number ranging from the expected 2n=4x=48 to 2n=68. Mixoploid root-tip cells containing 48, 53, 54 or 55 chromosomes for two of the hybrids were also observed.Michigan Agricultural Experiment Station Journal Article No. 11736. Supported by Grant No. I-751-84R from BARD — The United States — Israel Binational Agricultural Research and Development Fund     

Recombination in sesquidiploid hybrids of Lycopersicon esculentum × Solanum lycopersicoides and derivatives

Summary Sesquidiploid hybrids of L. esculentum (L) x S. lycopersicoides (S) were backcrossed to L via L. pennellii (P) as a bridging species in order to detect and measure recombination. Although use of P injected its traits into the populations, the investigated traits were proven to originate from S. The appearance of S traits in diploids in the immediate progeny of sesquidiploids but mainly of derived alien addition types proved the occurrence of recombination at rates varying from 1.6% to 16%. In subsequent BC's, these traits were inherited in dominant Mendelian fashion, except for deviations favoring recurrent parent alleles, sometimes with highly significant deviations from 11. Inheritance was investigated in BC and F₂ ex BC for 13 traits with strong phenotypic modifications of morphological, physiological, and isozymic nature. Monogenic determination was confirmed in most instances by tight linkages. For most of the traits, small progenies allowed only rough estimates of linkage intensities, but for Wa (gene for White anthers, universal in S), a test cross with four markers on chromosome 8 established its locus 2 cM distal to dl, proximally on 8L. Also noteworthy is the linkage of Dls, a gene determining sensitivity of flowering to long days, close to sp, situated subterminally on 6L. For the majority of traits, these manifestations of linkage proved that the appearance of S traits resulted from recombination, not alien chromosome substitution — a conclusion also reinforced by observations of chromosome pairing in alien addition types and diploid derivatives. Recombined S alleles have loci in various chromosome positions. Although they were discovered on the shorter chromosomes (nos. 6–12), hybridization barriers precluded tests with the longer chromosomes. Thus, no evidence was found for restriction of recombination to certain chromosomes or chromosomal regions. The prospects therefore appear favorable for deriving valuable traits from the S parent.     

FINE STRUCTURE OF SYNAPSED CHOMOSOMES IN F1 LYCOPERSICON ESCULENTUM-SOLANUM LYCOPERSICOIDES AND ITS PARENTS

Typical synaptinemal complexes consisting of electron-dense central and lateral elements and much less dense outer fibrillar material are formed at meiotic prophase in Lycopersicon esculentum (tomato), Solanum lycopersicoides, their diploid hybrid, and occasionally in tomato haploids (in which an average of about one chromosome region per cell is synapsed nonhomologously). Complexes in the hybrid (in which the chromosomes synapse completely but often fail to form chiasmata) are similar to those in the parents. Complexes in the haploid are similar to those of diploid tomato. The data suggest that synaptinemal complexes form whenever chromosomes undergo meiotic synapsis, regardless of whether synapsis leads to chiasmata.     

S-related protein can be recombined with self-compatibility in interspecific derivatives ofLycopersicon

Stylar proteins involved in the self-incompatible (SI) response ofLycopersicon hirsutum have been identified and mapped to the locus that controls SI (S locus).L. esculentum, a self-compatible (SC) species of cultivated tomato, does not display these proteins. Hybrids between SCL. esculentum and SIL. hirsutum are self-sterile despite these individuals bearing pollen containing theS allele ofL. esculentum. In progeny derived from backcrossing the hybrids toL. esculentum, there was a strong correlation between the presence of theS allele fromL. hirsutum and self-infertility. However, this relationship was uncoupled in a number of backcross (BC) progeny. The SI response appeared to be nonexistent in two self-fertile BC individuals that were heterozygous for theS allele ofL. hirsutum, based on Mendelian segregation of a tightly linked DNA marker,CD15, in selfed progeny. Among these progeny self-fertile individuals that were homozygous for theL. hirsutum allele of the linked marker were also determined to be homozygous for anS-related protein ofL. hirsutum through test crosses withL. esculentum. Therefore, plants were produced that were homozygous for a functionalS allele but were self-fertile. This result and other evidence suggest that theS-related proteins are not sufficient to elicit a self-incompatible response inL. esculentum and that there is a mutation(s) inL. esculentum somewhere other than theS locus that leads to self-compatibility.     

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.     

Cytogenetic characterization of <Emphasis Type="Italic">Solanum lycopersicoides</Emphasis> Dun. Alien chromosome additions in cultured tomato

Cytogenetic analysis of five Solanum lycopersicoides monosomic alien addition lines of tomato was carried out. Meiotic analysis showed that additional chromosomes caused serious abnormalities. It was demonstrated that different chromosomes of S. lycopersicoides had different effects on chromosome pairing. For instance, associations formed between chromosomes II and IV of S. lycopersicoides and chromosomes of cultured tomato were trivalents, while chromosome XI in all cells was present as a univalent. Pachytene analysis showed that chromosomes of homeologous group II paired at their long arms, and their nucleolus organizer regions were of different sizes. The use of molecular markers provided accelerated identification of the introgression of S. lycopersicoides genetic material.     

Asymmetric somatic hybrids between Lycopersicon esculentum and irradiated Lycopersicon peruvianum

Summary Asymmetric somatic hybrids of Lycopersicon esculentum and Lycopersicon peruvianum were obtained by fusion of leaf protoplasts from both species after irradiation of protoplasts or leaf tissue of L. peruvianum with 50, 300, or 1,000 Gy of gamma-rays. These radiation doses were sufficient to abolish the growth of the L. peruvianum protoplasts. The hybrids were selected for their ability to regenerate plants; this regeneration capacity derived from L. peruvianum. All asymmetric hybrid plants were aneuploid. The ploidy level, the morphology, and the regeneration rate were analyzed in relation to the radiation dose applied to L. peruvianum. After a low dose (50 Gy), most hybrids had near-triploid chromosome numbers, whereas after a high dose (300 or 1,000 Gy), most hybrids had near-pentaploid numbers. The morphology of the asymmetric hybrids was intermediate between that of L. esculentum and symmetric somatic hybrids of both species (obtained without irradiation treatment), and approached the morphology of L. esculentum to a greater extent after a high dose of irradiation. The asymmetric hybrids regenerated more slowly than the symmetric hybrids and regeneration proceeded more slowly after a high dose than after a low dose of irradiation. The high-dose hybrids also grew more slowly, flowered less, and set fruits less than the low-dose hybrids. No seeds could be obtained from any asymmetric hybrid.     

Somatic hybrids between Solanum etuberosum and diploid,tuber bearing Solanum clones

Electrofusion was used to obtain somatic hybrids between Solanum etuberosum (2n=2x=24) and two diploid potato lines. These hybridizations were conducted to determine if haploidxwild species hybrids are better fusion partners than conventional S. tuberosumGp. Tuberosum haploids. Restriction fragment length polymerase (RFLP) analyses of the putative somatic hybrids confirmed that each parental genome was present. The somatic hybrids between S. etuberosum and a haploid S. tuberosum clone, US-W730, were stunted and had curled, purple leaves. In contrast, somatic hybrids between S. etuberosum and a haploidxwild species hybrid (US-W 730 haploidx S. berthaultii), were vigorous and generally tuberized under field conditions. These hybrids were designated as E+BT somatic hybrids. Analyses of 23 E+BT somatic hybrids revealed a statistically significant bias towards the retention of S. etuberosum chloroplasts. Stylar incompatibilities were observed when the E+BT somatic hybrids were used as pollen donors in crosses with S. tuberosum cultivars. Reciprocal crosses did not show this incompatibility. The progeny were vigorous and had improved tuber traits when compared to the maternal E+BT parent. RFLP analyses of three sexual progeny lines confirmed the presence of all 12 S. etuberosum chromosomes. In two of these lines, RFLPs that marked each of the 24 chromosome arms of S. etuberosum were present. However, RFLP markers specific for regions on chromosomes 2, 7, and 11 were missing from the third clone. Because other markers for these chromosomes were present in the progeny line, these results indicated the likelihood of pairing and recombination between S. etuberosum and S. tuberosum chromosomes.     

Genome composition of asymmetric hybrids in relation to the phylogenetic distance between the parents. Nucleus-chloroplast interaction

Summary A series of fusion experiments were performed between protoplasts of a cytoplasmic albino mutant of tomato, Lycopersicon esculentum (ALRC), and gamma-irradiated protoplasts of L. hirsutum and the Solanum species S. commersonii, S. etuberosum and S. nigrum. These species were chosen for their different phylogenetic relationships to tomato. In all fusion combinations except from those between ALRC and S. nigrum, green calli were selected as putative fusion products and shoots regenerated from them. They were subsequently analyzed for their morphology, nuclear DNA composition and chloroplast DNA origin. The hybrids obtained between ALRC and L. hirsutum contained the chloroplasts of L. hirsutum and had the flower and leaf morphology of L. esculentum. After Southern blot analysis, using 13 restriction fragment length polymorphisms (RFLPs) randomly distributed over all chromosomes, all hybrids showed L. esculentum hybridization patterns. No chromosomes of L. hirsutum were found. These results indicate that these hybrids were true cybrids.The putative asymmetric hybrids, obtained with S. commersonii and S. etuberosum, showed phenotypic traits of both parents. After hybridization with species-specific repetitive nuclear DNA probes it was found that nuclear material of both parents was present in all plants. In the case of S. nigrum, which combination has the greatest phylogenetic distance between the fusion parents, no hybrid plants could be obtained. The chloroplast DNA of all hybrid plants was of the donor type suggesting that chloroplast transfer by asymmetric protoplast fusion can overcome problems associated with large phylogenetic distances between parental plants.     

Donor chromosome elimination and organelle composition of asymmetric somatic hybrid plants between an interspecific tomato hybrid and eggplant

Morphology, the extent of elimination of donor chromosomes and the organelle composition of highly asymmetric somatic hybrid plants between a interspecific tomato hybrid Lycopersicon esculentum x L. pennellii (EP) as donor and a Solarium melongena, eggplant (E), recipient, were studied. Morphologically, the somatic hybrids most resemble eggplant but, due to polyploidy, growth is slower relative to both fusion parents. The somatic hybrids produce flowers that are characterized by abnormal styles, stigmas and by anthers which do not produce pollen. Limited amounts of donor EP genomic DNA were found in the three somatic hybrid plants (H18-1, H18-2 and H18-3), by dot-blot hybridization with probe pTHG2, equivalent to 6.23,5.41, and 5.95% EP, respectively. These percentages translated to the presence of 3.59, 2.90 and 3.19 average-size EP chromosomes in plants H1 8-1,-2 and-3, respectively. RFLP determination of L. esculentum- and L. pennellii-specific chromosomes revealed that only fragments of eight to ten out of the 24 EP chromosomes (EP has 12 L. esculentum and 12 L. pennellii chromosomes) are present in the asymmetric somatic hybrid plants. Loci of L. esculentum and L. pennellii were evenly represented in plants H18-1, -2, and -3: four to five from L. esculentum and four to five from L. pennellii. All somatic hybrid plants retained locus TG22, chromosome 4, from both EP species. Although the regeneration of plants, H18-1, -2 and-3 was from one callus, loci TG31 and TG79 of L. esculentum chromosome 2 and L. pennellii chromosome 9, respectively, were missing in hybrid plant H18-1. The three somatic hybrid plants all had chloroplast DNA fragments specific for S. melongena. The mitochondrial genome (mtDNA) in the asymmetric somatic hybrids showed predominantly the pattern of eggplant; however, some eggplant-specific polymorphic bands were not present in the three plants.     

Species-specific DNA sequences for identification of somatic hybrids between Lycopersicon esculentum and Solanum acaule

Summary Species-specific highly repeated DNA sequences can be used to screen the progeny of protoplast fusions combining different species. Such probes are easy to clone and can be detected by fast methods, e.g., hybridization to total genomic DNA. Furthermore, due to their high copy number, hybridization signals are strong and represent more than one locus, unlike isozymes or resistance markers. After cloning and screening for species-specific DNA sequences we characterized the highly repeated DNA sequences of the solanaceous species Solanum acaule and Lycopersicon esculentum var. gilva. DNA sequencing and hy ridization revealed a prominent, tandemly arranged satellite DNA repeat of 162 bp in Lycopersicon esculentum and a different satellite repeat of 183 bp, also tandemly organized, in Solanum acaule. Each repeat is absent in the respective other species. Therefore, we have used these DNA repeats as markers to distinguish regenerated interspecific somatic hybrids from the respective fusion partners. These hybrids were clearly identified by Southern hybridization and dot-blot assays to the respective ³²P-labelled satellite DNA.     

Restriction fragment length polymorphism analysis of somatic hybrids between Lycopersicon esculentum and irradiated L. peruvianum: evidence for limited donor genome elimination and extensive chromosome rearrangements

Summary The genome composition of asymmetric somatic hybrids, obtained by fusion of leaf protoplasts fromLycopersicon esculentum and gamma-irradiated leaf protoplasts fromL. peruvianum, was characterised by Southern blot analysis using 29 restriction fragment length polymorphism markers. Eight low dose hybrids and seven high dose hybrids (irradiation dose 50 Gray and 300 Gray, respectively) were analysed. By densitometric scanning of the autoradiographs, the number of alleles for each locus of the component species was established. In general, elimination of alleles from the irradiatedL. peruvianum donor genome was limited and ranged from 17%–69%. ThreeL. peruvianum loci, located on chromosomes 2, 4 and 7, were present in all asymmetric hybrids, suggesting linkage to the regeneration capacity trait which was used in selecting them. The loss of donor genome was dose-dependent. Low dose hybrids contained more alleles, loci and complete chromosomes fromL. peruvianum than high dose hybrids, whereas the high dose hybrids contained more incomplete chromosomes. In most hybrids someL. esculentum alleles were lost. The possible implications of these results for the use of asymmetric hybrids in plant breeding are discussed.     

A novel ditertiary tetrasomic in tomato

Cytogenetic studies were carried out on a ditertiary tetrasomic, 2n + 2 (5L·7S), of tomato (Lycopersicon esculentum Mill.). In studies of transmission of the 5L·7S chromosome, male and female rates of 57.1% and 74.5%, respectively, were found—the highest yet reported for any tomato aneuploid. Additionally, two 5L·7S tertiary chromosomes were transmitted through the female gametophyte, the maximum duplication known to be tolerated by this developmental stage. Monotertiary tetrasomics of a novel type, 2n + 5L·5S + 5L·7S, were recovered in the selfed progeny of 2n + 2(5L·7S). The usefulness of the ditertiary tetrasomic for the production of double trisomics and for dosage and experimental evolutionary studies is elaborated.