Establishment of molecular markers and linkage groups in two F2 populations of Upland cotton

Two F₂ populations of cotton (Gossypium hirsutum L.) from the crosses of HS46 x MARCABUCAG8US-1-88 (MAR) and HS46 x Pee Dee 5363 (PD5363) were characterized for restriction fragment length polymorphisms (RFLPs) using DNA probes. Seventy-three probe/enzyme combinations were used in the HS46 x MAR population analysis, which resulted in 42 informative polymorphic fragments. These 42 moleclar markers represented 26 polymorphic loci, which consisted of 15 codominant and 11 dominant (+/-) genotypes. Chi-square analyses of these loci fit expected genotypic ratios of 121 and 31, respectively An analysis of these loci with the MAPMAKER program resulted in the establishment of four linkage groups A, B, C, and D with 4,2,2, and 2 loci, respectively, as well as 16 unlinked loci. Six probe-enzyme combinations were assayed on the HS46 x PD5363 population, which resulted in 11 informative polymorphic fragments. These 11 fragments represented 6 polymorphic loci, 1 dominant (+/-) and 5 codominant genotypes. The MAPMAKER analysis of these loci yielded 2 linked loci. Thus, a total of 53 polymorphic fragments and 32 polymorphic loci, representing five linkage groups, were identified among the two families.Contribution of the USDA-ARS in cooperation with the Miss Agric For Exp Stn.     

Alcohol dehydrogenase genes: restriction fragment length polymorphisms for ADH4 (π-ADH) and ADH5 (χ-ADH) and construction of haplotypes among different ADH classes

Of the five human alcohol dehydrogenase (ADH) genes located in the region q21–25 of chromosome 4, genetic markers have been reported previously only for class I enzymes, ADH1-3. Here, new restriction fragment length polymorphisms (RFLPs) are described for the genes of two other classes, ADH4 () and ADH5 ( or formaldehyde dehydrogenase, FDH). The frequencies and modes of inheritance of these RFLPs were determined with DNA both from unrelated individuals and from families. A polymorphic PstI site is assigned to the fourth intron of the ADH4 gene. Pairwise linkage disequilibrium calculations for these new RFLPs and already known RFLPs at the ADH2 and ADH3 loci establish strong linkage disequilibria between polymorphic MspI and BstXI sites in the ADH5 gene as well as between XbaI and MspI sites in the ADH3 gene. Furthermore, linkage disequilibria were detected between RFLPs of the ADH2 and ADH3 genes as well as between those of the ADH4 and ADH5 genes. The latter disequilibrium implies a hitherto unknown physical proximity of two genes belonging to different ADH classes. The RFLPs were used to construct chromosomal haplotypes that include three ADH classes. Of the 16 possible haplotypes for four RFLP markers used here, 10 were experimentally detected. The potential application of the ADH RFLPs and haplotypes in linkage or association studies of inherited diseases such as familial alcoholism is discussed.     

Imputing missing yield trial data

Summary Intraspecific mitochondrial DNA (mtDNA) diversity was determined in 23 Phaseolus vulgaris genotypes, and compared to previously observed variability of morphoagronomic characters and isozyme loci. Twenty of the lines were collected from Malawian landraces; the other three were pure-bred cultivars. The mtDNAs were digested with eight restriction endonucleases, revealing complex banding patterns. Southern hybridization using cosmid clones covering about 200-kb of the genome showed a considerable amount of uniformity of the mtDNA banding patterns. However, five restriction fragment length polymorphisms (RFLPs) were detected, dividing the bean lines into two groups corresponding to the previously known Mesoamerican and Andean gene pools of P. vulgaris. The cultivar Mecosta was separated from the rest of the lines by an additional RFLP. At least two out of the six RFLPs are believed to be due to base-pair mutation events. Our results provide the first evidence that the cytoplasms of the two major germ plasm pools of beans are distinct.     

The β subunit locus of the human fibronectin receptor: DNA restriction fragment length polymorphism and linkage mapping studies

Summary The beta subunit of the human fibronectin receptor (FNRB) is a transmembrane protein belonging to the VLA (very late antigens of activation) family. Using pGEM-32, a 2.5-kb partial cDNA clone corresponding to the 3 portion of the human FNRB locus, multiple restriction fragment length polymorphisms (RFLPs) were revealed on DNAs from unrelated Caucasians. RFLPs detected by five enzymes, BanII, HinfI, KpnI, BglII, and SacI, are of the simple two-allele form, and pairwise linkage analyses of these RFLPs with numerous known DNA markers from the chromosome-10 pericentromeric region not only confirmed the chromosome-10 assignment of the functional FNRB gene but also supported its localization at p11.2 suggested by in situ hybridization. An infrequent MspI RFLP was detected by pB/R2, a 4.6-kb genomic clone from the FNRB locus. Another type of DNA polymorphism was also revealed by the cDNA clone and it was visualized on the Southern blot analyses as the presence or absence of an extra band (or a set of extra bands). It seems to stem from a stretch of DNA sequence present in some individuals at one single locus but absent in others, and is of non-chromosome-10 origin based on linkage analyses with known chromosome 10 markers. This presence/absence type of polymorphism could be revealed by all of the 25 restriction enzymes tested and is similar in nature to that previously reported with one of the human dihydrofolate reductase pseudogenes, DHFRP1. Dissection of the pGEM-32 clone demonstrated that the region revealing the non-chromosome-10 sequences is within a fragment about 1.7 kb in length extending from about 600 nucleotides preceding the stop codon down to the end of the cloned FNRB 3 untranslated region. Due to its high polymorphism information content (PIC) value (0.71 for haplotypes of BanII, HinfI, and KpnI RFLPs) and proximity to the centromere, FNRB will prove to be a highly useful marker for genetic linkage studies of multiple endocrine neoplasia type 2A (MEN2A) as well as for chromosome-10 linkage studies in general.     

Linkage Arrangement of RFLP loci in progenies from crosses between doubled haploid Asparagus officinalis L. clones

A preliminary genetic map of the dioecious species Asparagus officinalis L. (2n = 20) has been constructed on the basis of restriction fragment length polymorphism (RFLP) and isozyme marker data. With DNA samples digested with either EcoRI or HindIII 61 out of 148 probes (41%) identified RFLPs in six families of doubled haploid lines obtained through anther culture. A higher level of polymorphism (65%) was observed when a single family was screened for RFLPs using six distinct restriction enzymes. Segregation analysis of the BC progenies (40–80 individuals) resulted in a 418-cM extended map comprising 43 markers: 39 RFLPs, three isozymes and one morphological (sex). These markers are clustered in 12 linkage groups and four of them exhibited significant deviations from the expected 11 ratio. One isozyme and three RFLP markers were assigned to the sex chromosome.     

Saccharum spontaneum L. ‘SES 208’ genetic linkage map combining RFLP- and PCR-based markers

A 527 marker linkage map ofSaccharum spontaneum L. SES 208 (2n = 64) was established by analyzing 208 single-dose (SD) arbitrarily primed PCR polymorphisms, 234 SD RFLPs, 41 double-dose (DD) and one triple-dose (TD) polymorphisms. A map hypothesis constructed using these markers (minimum LOD = 4.00, = 0.25 M) had 64 linkage groups with 13 SD, nine DD, and one TD markers unlinked. Eight chromosome homology groups were identified by using DD fragments as well as SD RFLPs that identified more than one linkage group. Linkages in repulsion phase were absent from the map, as found in two previous genetic studies of this species. Together, these data demonstrate that SES 208 displayed polysomic segregation, a genetic behavior typical of autopolyploid species. As with previous studies, it was concluded that SES 208 behaved like an auto-octoploid, which was also in agreement with the number of homology groups observed. A ² was used to test whether the 527 markers were randomly distributed throughout the genome: both arbitrarily primed PCR markers and RFLPs had a distribution that was statistically indistinguishable from random. The integrated arbitrarily primed PCR-RFLP map had a predicted genomic coverage of 93% (considering only 442 SD polymorphisms) and an average interval between markers of 6 cM. SD markers were used to estimate the genome size of SES 208 at ca. 33 00 cM.     

Genetic diversity of oilseedBrassica napus germ plasm based on restriction fragment length polymorphisms

Oilseed rape (Brassica napus) is an important oilseed crop worldwide. Cultivars have been developed for many growing regions, however little is known about genetic diversity inB. napus germ plasm. The purpose of the research presented here was to study the genetic diversity and relationships ofB. napus accessions using restriction fragment length polymorphisms (RFLPs). Eighty threeB. napus accessions were screened using 43 genomic DNA clones which revealed 161 polymorphic fragments. Each accession was uniquely identified by the markers with the exception of the near-isogenic cvs Triton and Tower. The RFLP data were analyzed by cluster analysis of similarity coefficients and by principal component analysis. Overall, there were three major groups of cultivars. The first group included only spring accessions, the second mostly winter accessions and the third, rutabagas and oilseed rape accessions from China and Japan. These results indicate that withinB. napus, winter and spring cultivars represent genetically distinct groups. The grouping of accessions by cluster analysis was generally consistent with known pedigrees. This consistency included the grouping of lines derived both by backcrossing or self-pollination with their parents.     

The isolation of a genomic clone containing the apolipoprotein CII gene and the detection of linkage disequilibrium between two common DNA polymorphisms around the gene

Summary We report the isolation of a genomic clone containing the apolipoprotein CII (apo CII) gene and 5 and 3 flanking sequences. A detailed restriction map of the gene has been constructed and DNA fragments that are unique, or low copy number sequences in the genome have been identified. One of these detects a common restriction fragment length polymorphism (RFLP) with the enzyme BglI. Marked linkage disequilibrium is observed between this RFLP and that detected with the apo CII cDNA clone, even though the two variable restriction enzyme sites are approximately 12 kb apart. However, the usefulness of the apo CII gene as a marker for linkage studies is increased by the use of both RFLPs.     

Molecular identification of powdery mildew resistance genes in common wheat (Triticum aestivum L.)

RFLP markers for the wheat powdery mildew resistance genes Pm1 and Pm2 were tagged by means of near-isogenic lines. The probe Whs178 is located 3 cM from the Pm1 gene. For the powdery mildew resistance gene Pm2, two markers were identified. The linkage between the Pm2 resistance locus and one of these two probes was estimated to be 3 cM with a F₂ population. Both markers can be used to detect the presence of the corresponding resistance gene in commercial cultivars. Bulked segregant analysis was applied to identify linkage disequillibrium between the resistance gene Pm18 and the abovementioned marker, which was linked to this locus at a distance of 4 cM. Furthermore, the RAPD marker OPH-11₁₉₀₀ (5-CTTCCGCAGT-3) was selected with pools created from a population segregating for the resistance of Trigo BR 34. The RAPD marker was mapped about 13 cM from this resistance locus.     

A genetic map of melon (Cucumis melo L.) with RFLP, RAPD, isozyme, disease resistance and morphological markers

One hundred and ten markers were analysed for linkage in 218 F₂ plants derived from two divergent cultivars (Védrantais and Songwhan Charmi) of Cucumis melo (L.). Thirty-four RFLPs, 64 RAPDs, one isozyme, four disease resistance markers and one morphological marker were used to construct a genetic map spanning 14 linkage groups covering 1390 cM of the melon genome. RAPD and RFLP markers detected similar polymorphism levels. RFLPs were largely due to base substitutions rather than insertion/deletions. Twelve percent of markers showed distorted segregation. Phenotypic markers consisted of two resistance genes against Fusarium wilt (Fom-1 and Fom-2), one gene (nsv) controlling the resistance to melon necrotic spot virus, one gene (Vat) conferring resistance to Aphis gossypii, and a recessive gene for carpel numbers (3 vs 5 carpels: p).     

RFLP analysis of genomic regions associated with cooked-kernel elongation in rice

As a result of earlier breeding efforts, portions of the genome of Basmati 370 have been introgressed into a rice breeding line, B8462T3-710. Cooked-kernel elongation was increased in this breeding line to a level equal to that of Basmati 370. The objective of this study was to identify and locate quantitative trait loci (QTLs) associated with cooked-kernel elongation in an F3 population derived from a cross between B8462T3710 and the reduced-elongation recurrent parent variety, Dellmont. DNA from the parental lines and Basmati 370 as a control, were screened for RFLPs using 170 clones chosen to cover the rice genome at intervals of 8 cM on average. Eighteen markers identified RFLPs common to Basmati 370 and B8462T3-710, but different from Dellmont, suggesting possible associations with kernel elongation. The B8462T3-710/Dellmont F3 population was analyzed for segregation of those RFLPs and for kernel elongation. Analysis of variance of the kernel elongation ratio revealed that two markers, 14.6 cM apart on chromosome 8, are significantly associated with this trait (RZ323 P 0.005, RZ562 P 0.05). Interval mapping suggests a single QTL with a close proximity to RZ323. This QTL was tested in F6 lines derived from the same cross and the presence of the B8462T3-710 segment detected by RZ323 caused a highly significant increase of the kernel elongation ratio (P 0.04). In addition, the QTL for kernel elongation and a gene for aroma, which are major components of the grain quality characteristics of Basmati-type rices, showed linkage. The availability of linked markers to the QTL may facilitate early selection for kernel elongation in rice breeding programs.     

Organization of the genes encoding chalcone synthase in Pisum sativum

To analyze the regulation of defense-related genes by signal molecules produced by phytopathogens, we isolated genes that encode chalcone synthase (CHS) in Pisum sativum. We have obtained seven independent genomic clones that contain at least seven classes of CHS genes, identified by the hybridization analysis to CHS cDNA and by the restriction mapping analysis. Two of the genomic clones (clone 5 and 6) each contain two CHS genes in a tandem repeat. The nucleotide sequence analysis of CHS genomic clone 5 revealed that PsCHS1 and PsCHS2 were corresponding genes of the CHS cDNA clones, pCC6 and pCC2, respectively, as reported earlier. Both genes are interrupted by a single intron of 88 nucleotides with identical sequences, although exonic sequences and 5-flanking sequences are divergent. Nucleotide sequences of the introns in five other classes of CHS genes showed that three classes had an intron of 87 nt with a striking homology to each other, but that the intron of the other two classes of CHS genes showed heterogeneity both in size and nucleotide sequence. 5-upstream regions of PsCHS1 and PsCHS2 did not show sequence homology except the 31 bp identical sequence that contains the CCTACC motif resembling the box-1 sequence. Both PsCHS1 and PsCHS2 genes are shown to be induced by fungal elicitor by a primer extension analysis and a transient transformation analysis using pea protoplasts prepared from suspension cultured-cells.     

Genetic linkage mapping in peach using morphological,RFLP and RAPD markers

We have constructed a genetic linkage map of peach [Prunus persica (L.) Batsch] consisting of RFLP, RAPD and morphological markers, based on 71 F₂ individuals derived from the self-fertilization of four F₁ individuals of a cross between New Jersey Pillar and KV 77119. This progeny, designated as the West Virginia (WV) family, segregates for genes controlling canopy shape, fruit flesh color, and flower petal color, size and number. The segregation of 65 markers, comprising 46 RFLP loci, 12 RAPD loci and seven morphological loci, was analyzed. Low-copy genomic and cDNA probes were used in the RFLP analysis. The current genetic map for the WV family contains 47 markers assigned to eight linkage groups covering 332 centi Morgans (cM) of the peach nuclear genome. The average distance between two adjacent markers is 8 cM. Linkage was detected between Pillar (Pi) and double flowers (Dl) RFLP markers linked to Pi and flesh color () loci were also found. Eighteen markers remain unassigned. The individuals analyzed for linkage were not a random sample of all F₂ trees, as an excess of pillar trees were chosen for analysis. Because of this, Pi and eight other markers that deviated significantly from the expected Mendelian ratios (e.g., 121 or 31) were not eliminated from the linkage analysis. Genomic clones that detect RFLPs in the WV family also detect significant levels of polymorphism among the 34 peach cultivars examined. Unique fingerprint patterns were created for all the cultivars using only six clones detecting nine RFLP fragments. This suggests that RFLP markers from the WV family have a high probability of being polymorphic in crosses generated with other peach cultivars, making them ideal for anchor loci. This possibility was examined by testing RFLP markers developed with the WV family in three other unrelated peach families. In each of these three peach families respectively 43%, 54% and 36% of RFLP loci detected in the WV family were also polymorphic. This finding supports the possibility that these RFLP markers may serve as anchor loci in many other peach crosses.     

Molecular-marker analysis of seed-weight: genomic locations,gene action,and evidence for orthologous evolution among three legume species

The objectives of this study were to use molecular markers to: (1) identify quantitative trait loci (QTL) controlling seed-weight in soybean, (2) characterize the genetic basis of seed-weight expression, and (3) determine whether soybean shares orthologous seed-weight genes with cowpea and/or mung bean. An F₂ population was developed between a large-seeded Glycine max breeding line and a small-seeded G. soja plant introduction. DNA samples from 150 F₂ individuals were analyzed with 91 polymorphic genetic markers, including RFLPs, RAPDs and SSRs. Seed-weight was analyzed by randomly sampling 100 seeds from each of 150 greenhouse-grown F₂ individuals, and their 150 F₂₃ lines, from a replicated field trial. Markers associated with seed-weight were identified using the computer program MapMaker-QTL and a one-way analysis of variance. Three and five markers were significantly associated with seed-weight variation (P<0.01) in the F₂ and F₂₃ generations, respectively. Tests for digenic epistasis revealed three significant interactions in both generations. In a combined analysis, these markers and interactions explained 50 and 60% of the phenotypic variation for seed-weight in the F₂ and F₂₃ generations, respectively. Comparison of our results in soybean (Glycine) with those previously reported in cowpea and mung bean (Vigna) indicated that soybean and cowpea share an orthologous seed-weight gene. In both species, a genomic region significantly associated with seed-weight spanned the same RFLP markers in the same linkage order. A significant digenic interaction involving this genomic region was conserved in all three species. These results suggest that the exploitation of comparative QTL mapping is an invaluable tool for quantitative geneticists working with poorly characterized plant systems.     

Identification and localization of molecular markers linked to the Lr9 leaf rust resistance gene of wheat

Near-isogenic lines (NILs) for the leaf rust resistance gene Lr9 were screened for polymorphisms at the molecular level. RAPD (random amplified polymorphic DNA) primers as well as RFLP (restriction fragment length polymorphism) markers were used. Out of 395 RAPD primers tested, three showed polymorphisms between NILs, i.e., an additional band was found in resistant lines. One of these polymorphic bands was cloned and sequenced. Specific primers were synthesized, and after amplification only resistant lines showed an amplified product. Thus, these primers define a sequence-tagged site that is specific for the translocated fragment carrying the Lr9 gene. A cross between a resistant NIL and the spelt (Triticum spelta) variety Oberkulmer was made, and F₂ plants were analyzed for genetic linkage. All three polymorphisms detected by the PCR (polymerase chain reaction) and one RFLP marker (cMWG684) showed complete linkage to the Lr9 gene in 156 and 133 plants analyzed, respectively. A second RFLP marker (PSR546) was closely linked (8±2.4 cM) to the Lr9 gene and the other four DNA markers. As this marker maps to the distal part of the long arm of chromosome 6B of wheat, Lr9 and the other DNA markers also map to the distal region of 6BL. All three PCR markers detected the Lr9 gene in independently derived breeding lines and varieties, thus proving their general applicability in wheat breeding programs.     

Comparison of allozyme,RFLP, and RAPD markers for revealing genetic variation within and between trembling aspen and bigtooth aspen

We examined genetic variation in allozyme loci, nuclear DNA restriction fragment length polymorphisms (RFLPs), and random amplified polymorphic DNAs (RAPDs) in 130 trembling aspen (Populus tremuloides) and 105 bigtooth aspen (P. grandidentata) trees. In trembling aspen 10 out of 13 allozyme loci assayed (77%) were polymorphic (P), with 2.8 alleles per locus (A) and an expected heterozygosity (H_e) of 0.25. In contrast, bigtooth aspen had a much lower allozyme genetic variability (P=29%; A=1.4; H_e=0.08). The two species could be distinguished by mutually exclusive alleles at Idh-1, and bigtooth aspen has what appears to be a duplicate 6PG locus not present in trembling aspen. We used 138 random aspen genomic probes to reveal RFLPs in HindIII digests of aspen DNA. The majority of the probes were from sequences of low copy number. RFLP results were consistent with those of the allozyme analyses, with trembling aspen displaying higher genetic variation than bigtooth aspen (P=71%, A=2.7, and H_e=0.25 for trembling aspen; P=65%, A=1.8, and H_e=0.13 for bigtooth aspen). The two species could be distinguished by RFLPs revealed by 21 probes (15% of total probes assayed). RAPD patterns in both species were studied using four arbitrary decamer primers that revealed a total of 61 different amplified DNA fragments in trembling aspen and 56 in bigtooth aspen. Assuming a Hardy-Weinberg equilibrium, estimates of P=100%, A=2, and H_e=0.30 in trembling aspen and P=88%, A=1.9, and H_e=0.31 in bigtooth aspen were obtained from the RAPD data. Five amplified DNA fragments were species diagnostic. All individuals within both species, except for 2 that likely belong to the same clone, could be distinguished by comparing their RAPD patterns. These results indicate that (1) RFLPs and allozymes reveal comparable patterns of genetic variation in the two species, (2) trembling aspen is more genetically variable than bigtooth aspen at both the allozyme and DNA levels, (3) one can generate more polymorphic and species-specific loci with DNA markers than with allozymes in aspen, and (4) RAPDs provide a very powerful tool for fingerprinting aspen individuals.     

Polymorphisms in the α-amy1 gene of wild and cultivated barley revealed by the polymerase chain reaction

-Amylases are the key enzymes involved in the hydrolysis of starch in plants. The polymerase chain reaction (PCR) was used to detect polymorphisms in the length of amplified sequences between the annealing sites of two primers derived from published -amy1 gene sequences in barley. These two primers (Bsw1 and Bsw7), flanking the promoter region and the first exon, amplified two PCR fragments in barley. One of the amplified products, with the expected length of 820 bp, appeared together with another shorter PCR band of around 750 bp. This 750-bp fragment seems to be derived from an -amylase gene not reported previously. Both of the PCR products could be amplified from the two-rowed barley varieties tested, including cv Himalaya from which the sequence information was obtained. Five of the six-rowed barley varieties also have the two PCR fragments whereas another two have only the long fragment. These two fragments seem to be unique to barley, neither of them could be amplified from other cereals; for example, wheat, rye or sorghum. These two -amylase fragments were mapped to the long arm of 6H, the location of the -amy1 genes, using wheat-barley addition lines. Amplification of genomic DNA from wild barley accessions with primers Bsw1 and Bsw7 indicated that both of the fragments could be present, or the long and short fragments could be present alone. The results also demonstrated that the genes specifying these two fragments could be independent from each other in barley. The conserved banding pattern of these two fragments in the two-rowed barley varieties implies that artificial selection from these genes may have played an important role in the evolution of cultivated barley from wild barley.     

A PvuII polymorphism in the 5′ flanking region of the apolipoprotein AIV gene: its use to study genetic variation determining serum lipid and apolipoprotein concentration

Summary We have used a 1.05-kb unique genomic fragment from the 5 end of the apolipoprotein (apo) CIII gene to identify a restriction fragment length polymorphism (RFLP) detected with the restriction enzyme PvuII, in the apoCIII-apoAIV intergenic region. In a sample of 220 normolipidaemic individuals from the UK population, the frequency of the rare allele, VB2 is 0.054. The PvuII polymorphism is in apparent linkage equilibrium with three other RFLPs of this gene cluster, detected with the restriction enzymes XmnI, PstI and SstI, but in linkage disequilibrium with an RFLP in the apoCIII gene also detected with PvuII. Taken together, these five RFLPs have a PIC (polymorphism information content) value of 0.8, and therefore are informative for genetic studies. Individuals with the genotype VB1VB2 had lower mean concentrations of apoAI, and HDL-cholesterol than individuals with the genotype VB1VB1. However these differences were not statistically significant.     

Identification of restriction fragment length polymorphisms linked to genes controlling soluble solids content in tomato fruit

Summary Gene(s) conferring high soluble solids (SS) in tomato fruit had been backcrossed previously from a wild tomato species, Lycopersicon chmielewskii LA1028 ( 10% SS), into a L. esculentum cultivar, VF36 ( 5% SS), to derive a BC₅S₅ line, LA1563, similar to VF 36 but with 7–8% SS. DNAs from these lines and a tomato breeding line, H2038, were screened for restriction fragment length polymorphisms (RFLPs) using four restriction endonucleases and sixty clones chosen at random from a tomato cDNA library. Most of the cDNA clones (56) identified the same RFLP in VF 36 and LA1563 and a different RFLP in LA1028. However, two cDNA clones identified the same RFLP in LA1563 and LA1028 and a different RFLP in VF36. To determine whether RFLPs identified by these two cDNA clones were linked to SS genes, a H2038 x LA1563 F₂ population was screened for segregation of the RFLPs and for SS content. The segregation ratios of these RFLPs were consistent with ratios expected for codominant alleles at unlinked loci. Analysis of variance of SS content for different RFLP genotypic classes indicated that RFLP alleles at one of the loci were linked to genes controlling SS content. The RFLP allele from the high SS tomato line, LA1563, was associated with significantly higher SS content and, therefore, could be useful in selecting for high SS gene(s) in a tomato breeding program.     

Linkage disequilibrium relationships among four polymorphisms within the human fibrinogen gene cluster

The extent of linkage equilibrium was estimated among four recently characterized human fibrinogen restriction fragment length polymorphisms (RFLPs) using a randomly selected group of 110 individuals from California. Two coding region RFLPs, RsaI and MnlI (FGA codon 312 and FGB codon 448, respectively), and two RFLPs located in the 5 flanking region of the FGB gene, AluI (HindIII) and HaeIII, were analyzed. Maximum likelihood estimates based on genotypic data indicated that the RsaI polymorphism in the FGA gene was at apparent linkage equilibrium with the MnlI, AluI, and HaeIII sites in the FGB gene, but strong linkage disequilibrium was noted for the MnlI-AluI, MnlI-HaeIII, and AluI-HaeIII RFLP pairs within the latter gene. The discrepancy in disequilibrium relationships among these closely linked RFLPs may indicate a region of increased recombination between the FGA and FGB RFLP loci. The FGA RsaI polymorphism, when used in conjunction with any of the FGB sites examined, will provide more detailed linkage or association data than analyses that would utilize only FGB sites. Effective use of polymorphisms within the fibrinogen locus will aid analysis of the relationships between fibrinogen genotype, plasma fibrinogen levels, and risk of cardiovascular disease.