The genetic basis of pear-shaped tomato fruit

Molecular-marker analysis of a cross between yellow pear, a tomato variety bearing small, pear-shaped fruit, and the round-fruited, wild species, Lycopersicon pimpinellifolium LA1589, revealed that pear-shaped fruit is determined largely by a major QTL on chromosome 2 and, to a lesser extent, a minor QTL on chromosome 10. The locus on chromosome 2 was also detected in a cross between yellow pear and the round-fruited introgression line (IL2–5) which carried the distal portion of chromosome 2 from the Lycopersicon pennellii genome. Based on its map position, we propose that the locus detected on chromosome 2 is the same as a locus referred to as ovate in the early tomato literature (Linstrom 1926, 1927). The fruit-shape index (length/diameter) and neck constriction were highly correlated in both populations suggesting that ovate exerts control over both traits or that the genes for these traits are tightly linked on chromosome 2. Using two-way ANOVA test, the minor QTL on chromosome 10 showed no significant interaction with the ovate locus on chromosome 2 with respect to the fruit-shape index. For ovate round fruit was dominant to elongated fruit in the L. pimpinellifolium populations, but additive in the IL2–5 population. Thus far, no genes controlling fruit shape have been cloned. The molecular mapping of the ovate locus may ultimately lead to its isolation via map-based cloning. Received: 8 January 1999 / Accepted: 30 January 1999     

Genetics of actin-related sequences in tomato

Summary The genomic distribution of actin-related sequences in tomato was investigated using a cloned actin gene from soybean. Ten actin loci account for most of the hybridizing fragments observed with Southern analysis. Single loci were found on chromosomes 1, 3 and 10 and two loci on chromosome 4. One locus is linked to an unmapped isozyme marker, Sod-1. The four remaining actin loci are independent of each other and of any of the other markers tested. The number of actin loci in tomato (10) is greater than that estimated for soybean (8). As soybean is apparently a tetraploid and tomato a diploid, these results suggest that the number of actin loci has not been stable during the evolution of dicots. A number of these mapped loci lie in regions of the genome previously devoid of molecular markers and thus may be useful in basic and applied genetic research.     

Tight linkage between a nuclear male-sterile locus and an enzyme marker in tomato

Summary The linkage relationship of a nuclear male sterile locus, ms-10, was tested with two enzyme marker loci known to be on the same chromosome (long arm of chromosome 2). The results indicate the gene order is Est-1 — 18 cM — Prx-2 — 1.5 cM — ms-10. The linkage intensity of ms-10 and Prx-2 (1.5 cM) suggests that Prx-2 might provide a selectable marker for male-sterility. In accordance with this idea, the ms-10 allele was placed in cis with a rare-allele of Prx-2 (Prx-2 ¹). Selection on the basis of the codominant Prx-2 ¹ allele should allow for more rapid and efficient transfer of the recessive male sterile allele into an array of genetic backgrounds, thus promoting its use in hybrid seed production.     

Electrophoretic analysis of Allium alien addition lines

Summary Meiotic pairing in an interspecific triploid of Allium cepa and A. fistulosum, Delta Giant, exhibits preferential pairing between the two A. cepa genomes, leaving the A. fistulosum genome as univalents. Multivalent pairing involving A. fistulosum chromosomes occurs at a low level, allowing for recombination between the genomes. Ten trisomies were recovered from the backcross of Delta Giant x A. cepa cv., Temprana, representing a minimum of four of the eight possible alien addition lines. The alien addition lines possessed different A. fistulosum enzyme markers. Those markers, Adh-1, Idh-1 and Pgm-1 reside on different A. fistulosum chromosomes, whereas Pgi-1 and Idh-1 may be linked. Diploid, trisomic and hyperploid progeny were recovered that exhibited putative pink root resistance. The use of interspecific plants as a means to introgress A. fistulosum genes into A. cepa appears to be successful at both the trisomic and the diploid levels. If introgression can be accomplished using an interspecific triploid such as Delta Giant to generate fertile alien addition lines and subsequent fertile diploids, or if introgression can be accomplished directly at the diploid level, this will have accomplished gene flow that has not been possible at the interspecific diploid level.Journal article No. 1140, Agr. Expt. Stn. N.M. State Univ., Las Cruces, NM, USA     

Use of molecular markers in breeding for soluble solids content in tomato — a re-examination

Summbary Through earlier breeding efforts, portions of the genome of the wild species Lycopersicon chmielewskii have been introgressed into the cultivated tomato (Rick 1974). These introgressed chromosomal segments have been reported to increase soluble solids in fruit of certain tomato varieties (Rick 1974). Recently, two of the introgressed segments have been identified with RFLP markers and tested for effects on soluble solids in a single F2 population (Osborn et al. 1987). Based on results from that experiment, it was determined that one of the detected segments contains gene(s) controlling soluble solids and concluded that tomato varieties could be improved for this character by indirect selection for the linked RFLP marker (Osborn et al. 1987). In this report, we have independently tested the association between RFLP and isozyme markers and genes controlling soluble solids and other characters in the above described material. These experiments differ from the previous ones in that a set of 132 molecular markers (isozymes and DNA clones) of known chromosomal position have been used. Three introgressed chromosomal segments from L. chmielewskii have been identified using these markers. They map to the middle and the end of chromosome 7 (> 40 cM apart) and to the end of chromosome 10. The effects of these segments on soluble solids and other horticultural characters were tested in crosses with three different cultivars over a period of two years. Two of the three segments were found to increase soluble solids, however the effect of one of these was dependent on genetic background. Both segments were found to be associated with deleterious characters including increase in fruit pH, lower yield and small fruit. These results confirm the utility of molecular markers for detecting genes underlying quantitative variation but demonstrate the danger in establishing breeding programs around such linkages until the effects of the quantitative genes have been tested in a variety of genetic backgrounds and for associated effects on other characters of agronomic importance.     

Tomato genome is comprised largely of fast-evolving, low copy-number sequences

Summary Fifty random clones (350–2300 bp), derived from sheared, nuclear DNA, were studied via Southern analysis in order to make deductions about the organization and evolution of the tomato genome. Thirty-four of the clones were mapped genetically and determined to represent points on 11 of the 12 tomato chromosomes. Under moderate stringency conditions (80% homology required) 44% of the clones were classified as single copy. Under higher stringency, the majority of the clones (78%) behaved as single copy. Most of the remaining clones belonged to multicopy families containing 2–20 copies, while a few contained moderately or highly repeated sequences (10% at moderate stringency, 4% at high stringency). Divergence rates of sequences homologous to the 50 random genomic clones were compared with those corresponding to 20 previously described cDNA (coding sequence) clones. Rates were measured by probing each clone (random genomics and cDNAs) onto filters containing DNA from various species from the family Solanaceae (including potato, Datura, petunia and tobacco) as well as one species (watermelon) from another plant family, Cucurbitaceae. Under moderate stringency conditions, the majority of the random clones (single copy and repetitive) failed to detect homologous sequences in the more distantly related species, whereas approximately 90% of the 20 coding sequences analyzed could still be detected in all solanaceous species. The most highly repeated sequences appear to be the fastest evolving and homologous copies could be detected only in species most closely related to tomato. Dispersion of repetitive sequences, as opposed to tandem clustering, appears to be the rule for the tomato genome. None of the repetitive sequences discovered by this random sampling of the genome were tandemly arranged — a finding consistent with the notion that the tomato genome contains only a small fraction of satellite DNA. This study, along with a companion paper (Ganal et al. 1988), provides the first general sketch of the tomato genome at the molecular level and indicates that it is comprised largely of single copy sequences and these sequences, together with repetitive sequences are evolving at a rate faster than the coding portion of the genome. The small genome and paucity of highly repetitive DNA are favourable attributes with respect to the possibilities of conducting chromosome walking experiments in tomato and the fact that coding regions are well conserved among solanaceous species may be useful for distinguishing clones that contain coding regions from those that do not.     

Chloroplast DNA sequences integrated into an intron of a tomato nuclear gene

Summary DNA sequences capable of hybridizing with chloroplast DNA have previously been reported to exist in the nuclear genome of higher plants. Here we show that the third intron of the cultivated tomato (Lycopersicon esculentum) nuclear gene Cab-7, which resides on chromosome 10 and which we recently cloned and sequenced, contains two DNA fragments derived from the coding region of the chloroplast gene psbG. The first fragment, 133 bp long, is located at a site 63 bp from the 3 end of the 833 bp intron. The exact sequence of the 11 nucleotides at the 3 end of the inserting chloroplast sequence is also found at the 5 border of the insertion. A small (107 bp) chloroplast DNA fragment is inserted near the middle of the intron, again with the 3 end of the inserting element (6 bp) duplicated at the 5 border of the insertion. The second insert is a subfragment of the first insert, and is most likely directly derived from it. The psbG insertion sequence was found to be present in the Cab-7 gene of all tomato species examined but not in species from related genera (e.g. Solanum, Petunia, Nicotiana), suggesting that the original transposition event (chloroplast to nucleus) occurred relatively recently-since the divergence of the genus Lycopersicon from other genera in the family Solanaceae, but before radiation of species in that genus.     

The detection and estimation of linkage in polyploids using single-dose restriction fragments

Summary Restriction fragment length polymorphism (RFLP) linkage maps have been constructed in several major diploid crops. However, construction of RFLP maps directly in polyploids has lagged behind for several reasons: (1) there are a large number of possible genotypes for each DNA probe expected in a segregating population, and these genotypes cannot always be identified readily by their banding phenotypes; and (2) the genome constitutions (allopolyploidy versus autopolyploidy) in many high polyploids are not clearly understood. We present here an analysis of these problems and propose a general method for mapping polyploids based on segregation of single-dose restriction fragments (SDRFS). SDRFs segregate 1:1 (presence: absence) in gametes of heterozygous plants. Hypothetical allopolyploid and autopolyploid species with four ploidy levels of 2n = 4x, 6x, 8x, and 10x, are used to illustrate the procedures for identifying SDRFs, detecting linkages among SDRFs, and distinguishing allopolyploid versus autopolyploids from polyploids of unknown genome constitution. Family size required, probability of linkage, and attributes of different mapping populations are discussed. We estimate that a population size of 75 is required to identify SDRFs with 98% level of confidence for the four ploidy levels. This population size is also adequate for detecting and estimating linkages in the coupling phase for both allopolyploids and autopolyploids, but linkages in the repulsion phase can be estimated only in allopolyploids. For autopolyploids, it is impractical to estimate meaningful linkages in repulsion because very large family sizes (>750) are required. For high-level polyploids of unknown genome constitution, the ratio between the number of detected repulsion versus coupling linkages may provide a crude measurement of preferential chromosome pairing, which can be used to distinguish allopolyploidy from autopolyploidy. To create a mapping population, one parent (P₁) should have high heterozygosity to ensure a high frequency of SDRFs, and the second parent (P₂) should have a low level of heterozygosity to increase the probability of detecting polymorphic fragments. This condition could be satisfied by choosing outcrossed hybrids as one parental type and inbreds, haploids, or doubled haploids as the other parental type.Published as Paper No. 730 in the Journal Series of the Experiment Station, Hawaiian Sugar Planters' Association, and as Paper No. 792 in the Plant Breeding Series of Cornell University, Ithaca, NY 14853, USA     

Nonmammalian vertebrate skeletal muscles express two triad junctional foot protein isoforms.

Mammalian skeletal muscles express a single triad junctional foot protein, whereas avian muscles have two isoforms of this protein. We investigated whether either case is representative of muscles from other vertebrate classes. We identified two foot proteins in bullfrog and toadfish muscles on the basis of (a) copurification with [3H]epiryanodine binding; (b) similarity to avian muscle foot proteins in native and subunit molecular weights; (c) recognition by anti-foot protein antibodies. The bullfrog and toadfish proteins exist as homooligomers. The subunits of the bullfrog muscle foot protein isoforms are shown to be unique by peptide mapping. In addition, immunocytochemical localization established that the bullfrog muscle isoforms coexist in the same muscle cells. The isoforms in either bullfrog and chicken muscles have comparable [3H]epiryanodine binding capacities, whereas in toadfish muscle the isoforms differ in their levels of ligand binding. Additionally, chicken thigh and breast muscles differ in the relative amounts of the two isoforms they contain, the amounts being similar in breast muscle and markedly different in thigh muscle. In conclusion, in contrast to mammalian skeletal muscle, two foot protein isoforms are present in amphibian, avian, and piscine skeletal muscles. This may represent a general difference in the architecture and/or a functional specialization of the triad junction in mammalian and nonmammalian vertebrate muscles.     

Dominance Is the Major Genetic Basis of Heterosis in Rice as Revealed by Qtl Analysis Using Molecular Markers

A set of 194 F(7) lines derived from a subspecific rice cross showing strong F(1) heterosis was backcrossed to the two parents. The materials (388 BC(1)F(7) lines, 194 F(8) lines, two parents, F(1)) were phenotyped for 12 quantitative traits. A total of 37 significant QTLs (LOD >/= 2.0) was detected through 141 RFLP markers in the BC(1)F(7) populations. Twenty-seven (73%) quantitative trait loci (QTLs) were detected in only one of the BC(1)F(7) populations. In 82% of these cases, the heterozygotes were superior to the respective homozygotes. The remaining 10 (27%) QTLs were detected in both BC(1)F(7) populations, and the heterozygote had a phenotype falling between those of the two homozygotes and in no instances were the heterozygotes found to be superior to both homozygotes. These results suggest that dominance complementation is the major genetic basis of heterosis in rice. This conclusion was strengthened by the finding that there was no correlation between most traits and overall genome heterozygosity and that there were some recombinant inbred lines in the F(8) population having phenotypic values superior to the F(1) for all of the traits evaluated--a result not expected if overdominance was a major contributor to heterosis. Digenic epistasis was not evident.