Linkage of isozyme loci in the mouse: Phosphoglucomutase-2 (Pgm-2), mitochondrial NADP malate dehydrogenase (Mod-2), and dipeptidase-1 (Dip-1)

The linkages of the isozyme genes Mod-2, Pgm-2, and Dip-1 have been determined in tests with established linkage group markers among inbred strains of mice. Unique alleles for both Mod-2 and Pgm-2 have been observed in the strain of SM/J. Linkage was determined from backcross progeny of the matings C57BL/6J×(SM/J×C57BL/6J)F₁, (SM/J×SWR/J)F₁×SM/J, and (SM/J×SWR/J)F₁×SJL/J. The gene Mod-2 is on linkage group 1. In a three-point cross of the loci Gpi-1, c, and Mod-2, the c locus was determined to be the middle gene. No double crossovers were observed. Our combined data show the following linkages: Gpi-1 to c, 28.3±3.2%; Gpi-1 to Mod-2, 33.3±3.0%; and c to Mod-2, 4.1±2.8%. The proposed gene order for four markers on LG I is Gpi-1-p-c-Mod-2. The gene Pgm-2 was linked to Gpd-1 (27.0±4.2%) on LGVIII. Two backcrosses segregating for Pgm-2 and b, (SM/J×DBA/2J) F₁×DBA/2J and (SM/J×DBA/2J)F₁×C57BR/cdJ, showed 9.1±4.3% recombination. The proposed gene order on LG VIII is b-Pgm-2-Gpd-1. The genes Pgm-1 and Pgm-2 are not linked (53.4±4.4%). Linkage of the isozyme genes Dip-1 and Id-1 on LG XIII was observed in backcross progeny of the crosses (SJL/J×C57BL/6J)F₁×SJL/J and C57BL/6J×(SM/J×C57BL/6J)F₁. The combined recombination was 23.8±2.8%. Two cases are established where genes whose enzyme products share substrate affinities (Pgm-1 and Pgm-2; Mod-1 and Mod-2) are not linked. Our data generally support the conclusion that functionally or metabolically related isozyme genes are not contiguous on mouse linkage groups.This investigation was supported in part by Public Health Service General Research Support Grant GM-09966 and in part by Public Health Service Training Grant 5T01 HD-00032-07 from the National Institute of Child Health and Human Development, and by Atomic Energy Commission contract AT(30-1)-3671.     

Estimation of recombination parameters between a quantitative trait locus (QTL) and two marker gene loci

Summary A new method is described to obtain maximum likelihood estimates of recombination frequencies between quantitative trait loci (QTL) and marker gene loci; it is based on Fisher's method of scoring and numerical differentiation. The method is applied to data from chromosome-doubled monoploid lines of barley originating from the F₁ generation of a cross between two well-adapted barley varieties. The lines segregated for marker gene loci ddt (DDT resistance) and s (short rachilla hairs) on chromosome 7. The quantitative trait of single-kernel weight was found statistically significantly associated with locus s, but not with locus ddt. The association is ascribed to a QTL designated Kw1. It could not be ascribed to pleiotropism at locus s since the recombination frequency between s and Kw1 (0.26±0.09) differed significantly from zero. The recombination frequencies between Kw1 and ddt and between ddt and s were 0.42±0.07 and 0.31±0.03, respectively, suggesting the locus order ddt, s, Kw1. The segregation ratio for alleles in locus Kw1 was estimated to be 4357, which is not significantly different from a 11 ratio. Means and standard deviations of single-kernel weight for lines with either of the two Kw1 alleles were estimated; the Kw1 locus accounted for 25% of the variance of the single kernel weight.     

Inheritance of two endosperm protein loci in rice (Oryza sativa L.)

Summary Previous studies indicated two types of phenotypic protein markers as two minor bands of SDS-PAGE for rice storage protein. A variant derived from a Pakistani variety, Dular, was found to show a mobility variant with Band 11, a relatively faster-moving band as compared to Band 10, while most of the other cultivated rices exhibited Band 10 at a molecular weight of around 100–110 K. Band 11 was also observed in several wild rice species. How this variant occurred is not known. Another marker is characterized by the presence of either Band 56 (slower-migrating band) or Band 57 (faster-migrating band) in most cultivars at a molecular weight of about 28–27 K. Most indica varieties developed in Taiwan have Band 57 and japonica varieties have Band 56. Genetic analysis of F₁, F₂ and F₃ seeds from interstrain crosses indicated that Band 10 versus Band 11 and Band 56 versus Band 57 are due to codominant alleles at two loci. Tests of independent inheritance between these two loci (Band 10/11 versus Band 56/57) indicated that there is no linkage between them. Both of these two protein loci encode for endosperm proteins and mostly belong to the minor polypeptide subunits of the glutelin fraction of rice seed proteins. Studies on reciprocal crosses indicate dosage effects as exhibited in band patterns. Variations in band intensity were frequently observed when the maternal genotype was different.     

Polymorphism and Inheritance of Seed Storage Protein in Sunflower

The data on polymorphism and inheritance of the seed storage protein helianthinin are presented. The results of hybrid analysis indicate that in the annual sunflower Helianthus annuus, helianthinin synthesis is controlled by at least three loci: HelA, HelB, and HelC. Codominant alleles controlling different electrophoretic variants of polypeptides were identified at each of the loci. The HelA locus was inherited independently of HelB and HelC in a series of dihybrid crosses. The frequencies of recombination between loci HelB and HelC estimated in F₂ and BC of two crossing combinations were respectively 21.8 and 19.0%. Segregation of the HelC-controlled variants in the progenies from the crosses of cultured sunflower with annual wild species and forms corresponded to that theoretically expected for Mendelian inheritance. The maternal type of helianthinin inheritance was observed in the progenies from the crosses of inbred H. annuus L. lines with perennial diploid and polyploid HelianthusL. species. Altered expression of the HelClocus was detected in some hybrid combinations. These alterations appeared in early (F₁, F₂) hybrid generations and were similar in different hybrid combinations. They did not depend on the perennial paternal species being more influenced by the maternal genotype and by the mode of obtaining hybrids (in an embryo culture or in the field). These results are explained by genomic shock generated by hybridization of genetically incompatible species.     

Fine mapping of trypanosomiasis resistance loci in murine advanced intercross lines

We have previously reported the results of genome-wide searches in two murine F₂ populations for QTLs that influence survival following Trypanosoma congolense infection. Three loci, Tir1, Tir2, and Tir3, were identified and mapped to mouse Chromosomes (Chrs) 17, 5, and 1 respectively, with confidence intervals (CIs) in the range 10–40 cM. The size of these CIs is to a large degree the consequence of limited numbers of recombination events in small chromosomal regions in F₂ populations. A number of population designs have been proposed to increase recombination levels in crosses, one of which is the advanced intercross line (AIL). Here we report fine mapping of Tir1, Tir2, and Tir3 in G6 populations of two independent murine AILs created by crossing the C57BL/6J strain with the A/J and BALB/cJ strains, respectively. Data were analyzed by two methods that gave equally informative and similar results. The three QTLs were confirmed in the A/J × C57BL/6J AIL and in the combined data set, but Tir2 was apparently lost from the BALB/cJ × C57BL/6J AIL. The reduction in CIs for the Tir loci ranged from 2.5 to more than ten-fold in G6 populations by comparison with CIs obtained previously in the equivalent F₂ generations. Mapping in the AILs also resolved the Tir3 locus into three trypanosomiasis resistance QTLs, revealing a degree of complexity not evident in extensive studies at the F₂ level. Received: 16 December 1999 / Accepted: 24 March 2000     

Stability of Hor1-specific YAC-clones and physical mapping of Hor1-loci in barley

 The hordeins are the major class of storage proteins in barley and are encoded by multigene families. Two YAC-clones specific for the C-hordein-coding Hor1-locus of barley (Hordeum vulgare L.) were selected. The clones were constructed with DNA from the cultivars ‘Franka’ and ‘Hockey’ and have insert sizes of 330 kb and 350 kb, respectively. Performing partial digestions and hybridizations with vector-specific probes, a restriction analysis was conducted using restriction enzymes with a 8-bp recognition sequence. Both clones cover the complete region of the Hor1-locus, but exhibit a different pattern of restriction sites reflecting the polymorphic nature of the locus on the scale of long-range restriction mapping. The maximal extent of the regions homologous to the Hor1-specific probe, pBSC5, was 105 kb in the ‘Hockey’-derived YAC and 190 kb in the yeast artificial chromosome constructed with ‘Franka’-DNA. Furthermore the high degree of instability observed with the Hor1-specific YAC-clones is discussed in conjunction with the structure of the Hor1-locus. Received: 19 December 1996 / Accepted: 31 January 1997     

Genetic mapping of the barley nitrate reductase-deficient nar1 and nar2 loci

Summary The nar2 locus that codes for a protein involved in molybdenum cofactor function in nitrate reductase and other molybdoenzymes was mapped to barley chromosome 7. F₂ genotypic data from F₃ head rows indicated nar2 is located 8.4±2.1 and 23.0± 4.6 cm from the narrow leaf dwarf (nld) and mottled seedling (mt2) loci, respectively. This locates the nar2 locus at 54.7±3.1 cm from the short-haired rachilla (s) locus near the centromere of chromosome 7. Close linkage of nar2 with DDT resistance (ddt) and high lysine (lys3) loci was detected but could not be quantified due to deviations from the individual expected 121 segregations for the ddt and lys3 genes. Southern blots of wheat-barley addition lines probed with a nitrate reductase cDNA located the NADH : nitrate reductase structural gene, nar1, to chromosome 6.Scientific Paper No. 7762. College of Agriculture and Home Economics Research Center, Washington State University, Project No. 0745. This investigation was supported in part by United States Department of Agriculture Grant No. 86-CRCR-1-2004     

Linkage mapping of ‘25-kDa globulin’ genes on homoeologous group-1 chromosomes of bread and durum wheat

Acid polyacrylamide-gel electrophoresis (A-PAGE) of ethanol-soluble proteins from the endosperm of bread and durum wheats reveals some bands encoded by genes on the homoeologous group-1 chromosomes with higher mobility than the -gliadins. The isolation of these proteins showed that they were the previously described 25-kDa globulins encoded by genes at the Glo-A1, Glo-B1, and Glo-D1 loci. The variability found among a collection of 51 bread and 81 durum wheats was very low: two allelic variants at Glo-A1 and no variants at Glo-B1 in each of the two species, and two allelic variants at Glo-D1 in bread wheat. Inheritance studies of 25-kDa globulin genes on group-1 chromosomes of bread and durum wheat were carried out on the F₂ progeny from four crosses, two in bread wheat and two in durum wheat. The linkage mapping of the 1A 25-kDa globulin genes of bread wheat was done based on four prolamin loci: Glu-A1, Glu-A3, Gli-A1 and Gli -A3. The percentages of recombination and the distances found allowed a re-evaluation of the linkage map of endosperm protein loci on this chromosome. The Glo-A1 locus was found to be located at the distal end of the short arm of 1A chromosome, at a distance of 5.23±1.99 cM from Gli-A1, 6.85±2.22 cM from Glu-A3, 22.64±3.62 cM from Gli-A1, and at a recombination percentage of 49.30±4.40 from Glu-A1. A similar distance between Gli-A1 and Glo-A1 (4.82±1.75 and 6.66±2.26 cM) was found in durum wheat. The distance between Gli-D1 and Glo-D1 on chromosome 1D was 2.86±1.39 cM.     

Fine linkage mapping enables dissection of closely linked quantitative trait loci for seed dormancy and heading in rice

Two quantitative trait loci (QTLs) for seed dormancy (tentatively designated Sdr1) and heading date (Hd8) have been mapped to approximately the same region on chromosome 3 by interval mapping of backcross inbred lines derived from crosses between the rice cultivars Nipponbare (japonica) and Kasalath (indica). To clarify whether Sdr1 and Hd8 could be dissected genetically, we carried out fine-scale mapping with an advanced backcross progeny. We selected a BC₄F₁ plant, in which a small chromosomal region including Sdr1 and Hd8, on the short arm of chromosome 3, remained heterozygous, whereas all the other chromosomal regions were homozygous for Nipponbare. Days-to-heading and seed germination rate in the BC₄F₂ plants showed continuous variation. Ten BC₄F₂ plants with recombination in the vicinity of Sdr1 and Hd8 were selected on the basis of the genotypes of the restriction fragment length polymorphism (RFLP) markers flanking both QTLs. Genotypes of those plants for Sdr1 and Hd8 were determined by advanced progeny testing of BC₄F₄ families. Sdr1 was mapped between the RFLP markers R10942 and C2045, and co-segregated with C1488. Hd8 was also mapped between C12534S and R10942. Six recombination events were detected between Sdr1 and Hd8. These results clearly demonstrate that Sdr1 and Hd8 were tightly linked. Nearly isogenic lines for Sdr1 and Hd8 were selected by marker-assisted selection.Communicated by D. Mackill     

Effect of the mouse scid mutation on meiotic recombination

The goal of this study was to determine the effect of the mouse severe combined immunodeficiency (scid) mutation on the rate of meiotic recombination, by standard backcross linkage analysis. For this purpose, we examined four crosses that involved F₁ hybrid animals heterozygous for the strain C57BL/6 and BALB/c genomes. In one set of reciprocal crosses, F₁ animals were homozygous scid/scid, and in a second set of reciprocal crosses, F₁ mice were homozygous wild-type (+/+) at the scid locus. Backcross progeny were typed for recombination between selected genetic markers on mouse Chromosomes (Chrs) 1, 4, 6, 7, 9, 15, and 17. Although some differences in recombination were observed over some intervals, the expression of the SCID phenotype did not appear to have a major or consistent effect on meiotic recombination. Received: 4 October 1995 / Accepted: 2 April 1996     

Recombination mapping of Gli-5, a new gliadin-coding locus on chromosomes 1A and 1B in common wheat

Inheritance studies of gliadin loci on chromosomes 1A and 1B were carried out in the progeny from crosses between cv Salmone and six other common wheat varieties. The map distance between the Rg-1 locus for glume colour and the gliadin locus Gli-B1 on the satellite of chromosome 1B was calculated as 2.0±0.6 cM. An additional gliadin locus, Gli-B5, was mapped between Gli-B1 and Rg-1, 1.4 cM from the former. A genetic distance of 1.8±0.4 cM was obtained between the Hg-1 locus for hairy glumes and a gliadin locus that seems to be remote from Gli-A1 and homoeologous to Gli-B5. Statistically significant differences in recombination values were found in the six crosses, indicating the influence of genotype on the frequency of recombination. The similarity in chromosomal location of seed storage protein genes in wheat, barley and rye is discussed.     

Biochemical polymorphism in the rat,Rattus norvegicus: Genetic study of four markers

The linkage of the hemoglobin (Hbb) and albino (c) loci has been determined from backcross progeny of the mating (WAG/Orl × Long Evans/Orl)F ₁ × WAG/Orl. The data give 9.1 ± 1.8% recombination. The backcross (August/Orl × WAG/Orl)F ₁ × August/Orl segregating for Hbb and pink-eyed yellow (p) shows 21.5±4.2% recombination. The proposed gene order on linkage group I is p-c-Hbb. Linkage of the seminal vesicle protein (Svp-1) and the nonagouti (a) loci has been determined from backcross progeny of the mating (August/Orl × Long Evans/Orl)F ₁ × Long Evans/Orl. The data show 7.1±3.4% recombination. Svp-1 thus represents an additional marker in linkage group V. Two new autosomal variants have been reported: The locus which controls a plasma protein's polymorphism has been designated Gl-1 with two codominant alleles Gl-1a and Gl-1b. The other locus, controlling a testis esterases polymorphism, has been assigned the symbol Es-3 and has two codominant alleles Es-3a and Es-3b. The absence of linkage of Gl-1 and Es-3 to each other and to five different loci has also been reported. Rat and mouse analogy with respect to these markers and established linkages is discussed.     

Testing Mendelian inheritance from field-collected parasites: Revealing duplicated loci enables correct inference of reproductive mode and mating system

Cryptic aspects of parasite population biology, e.g., mating systems, are increasingly being inferred from polymorphic and co-dominant genetic markers such as microsatellite loci. Underlying the use of such co-dominant markers is the assumption of Mendelian inheritance. The failure to meet this assumption can lead to artifactual statistics and erroneous population inferences. Here, we illustrate the importance of testing the Mendelian segregation and assortment of genetic markers and demonstrate how field-collected samples can be utilised for this purpose. To examine the reproductive mode and mating system of hermaphroditic parasites, we developed microsatellites for the cestode, Oochoristica javaensis. Among loci, we found a bimodal distribution of F_IS (a fixation index that quantifies the deviation from Hardy–Weinberg equilibrium within subpopulations) values where loci were either highly negative (close to −1) or highly positive (∼0.8). By conducting tests of Mendelian segregation from natural crosses, we determined that loci with negative F_IS values were in fact duplicated loci that were amplified by a single primer pair. Genetic crosses also provided linkage data and indicated that the duplicated loci most likely arose via tandem duplications rather than whole genome/chromosome duplications. By correcting for the duplicated loci, we were able to correctly infer that O. javaensis has sexual reproduction, but the mating system is highly inbred. To assist others in testing Mendelian segregation and independent assortment from natural samples, we discuss the benefits and limitations, and provide guidelines for particular parasite systems amenable to the methods employed here.     

An interstitial telomere array proximal to the distal telomere of mouse chromosome 13

Lambda clones of mouse DNA from BALB/c and C57BL/10, each containing an array of telomere hexamers, were localized by FISH to a region close to the telomere of Chr 13. Amplification of mouse genomic DNA with primers flanking SSRs within the cloned DNA showed several alleles, which were used to type eight sets of RI strains. The two lambda clones contained allelic versions of the interstitial telomere array, Tel-rs4, which is 495 bp in C57BL/10 and which includes a variety of sequence changes from the consensus telomere hexamer. Comparison of the segregation of the amplification products of the SSRs with the segregation of other loci in an interspecies backcross (C57BL/6JEi × SPRET/Ei) F₁× SPRET/Ei shows recombination suppression, possibly associated with ribosomal DNA sequences present on distal Chr 13 in Mus spretus, when compared with recombination in an interstrain backcross, (C57BL/6J × DBA/J) F₁× C57BL/6J, and with the MIT F₂ intercross. Analysis of recombination in females using a second interstrain backcross, (ICR/Ha × C57BL/6Ha) F₁× C57BL/6Ha, also indicates recombination suppression when compared with recombination in males of the same strains, using backcross C57BL/6Ha × (ICR/Ha × C57BL/6Ha) F₁. Thus, more than one cause may contribute to recombination suppression in this region. The combined order of the loci typed was D13Mit37–D13Mit30–D13Mit148–(D13Rp1, 2, 3, 4, Tel-rs4)–D13Mit53–D13Mit196–D13Mit77–(D13Mit78, 35). Data from crosses where apparently normal frequencies of recombination occur suggest that the telomere array is about 6 map units proximal to the most distal loci on Chr 13. This distance is consistent with evidence from markers identified in two YAC clones obtained from the region. Received: 24 September 1996/Accepted: 20 January 1997     

Genetic variation of an acid phosphatase (Acp-2) in the laboratory rat: Possible homology with mouse AP-1 and human ACP2

A genetic locus controlling the electrophoretic mobility of an acid phosphatase in the rat (Rattus norvegicus) is described. The locus, designed Acp-2, is not expressed in erythrocytes but is expressed in all other tissues studied. The product of Acp-2 hydrolyzes a wide variety of phosphate monoesters and is inhibited by l(+)-tartaric acid. Inbred rat strains have fixed either allele Acp-2^a or allele Acp-2^b. Codominant expression is observed in the respective F₁ hybrids. Backcross progenies revealed the expected 1:1 segregation ratio. Possible loose linkage was found between the Acp-2 and the Pep-3 gene loci at a recombination frequency of 0.36±0.06.Supported by the Deutsche Forschungsgemeinschaft (Grant Be 352/15) and by a grant from the Alexander-von-Humboldt-Stiftung (VB2-FLF).     

Genetic mapping of loci controlling diethylstilbestrol-induced thymic atrophy in the Brown Norway rat

Chronic estrogen administration can lead to thymic atrophy in rodents. In this article we report that the Brown Norway (BN) rat is sensitive to thymic atrophy induced by the estrogen diethylstilbestrol (DES). By contrast, DES does not induce significant thymic atrophy in the August × Copenhagen-Irish (ACI) strain. The sensitivity of the BN rat to DES-induced thymic atrophy appears to segregate as an incompletely dominant trait in crosses between the BN and ACI strains. In a (BN × ACI)F₂ population, we find strong evidence for three major genetic determinants of sensitivity to DES-induced thymic atrophy on rat Chromosome (RNO) 10 and RNO2. Genotypes at these loci, termed Esta1, 2, and 3, do not have a significant impact on the ability of DES to induce pituitary tumorigenesis or inhibit growth of these F₂ rats. These data indicate that the genetic factors that control DES-induced thymic atrophy are distinct from those that control the effects of DES on pituitary mass and body mass. The Esta intervals on RNO10 and RNO2 overlap with loci that control sensitivity to radiation-induced thymocyte apoptosis, as well as susceptibility to a variety of allergic and autoimmune pathologies, including allergic encephalitis, arthritis, and glomerulonephritis in rodents. These observations suggest that common genetic determinants may control sensitivity to estrogen-induced thymic atrophy, maintenance of thymocyte homeostasis, and immune function.     

Inheritance of high palmitic acid content in the seed oil of sunflower mutant CAS-5

 Sunflower genotypes with increased levels of palmitic acid (C16 : 0) in the seed oil could be useful for food and industrial applications. The objective of the present study was to determine the inheritance of the high C16 : 0 content in the sunflower mutant line CAS-5 (>25% of the total oil fatty acids). This mutant was reciprocally crossed with the lines HA-89 (5.7% C16 : 0) and BSD-2-691 (5.4% C16 : 0), the latter being the parental line from which CAS-5 was isolated. No maternal effect for the C16 : 0 content was observed from the analysis of F₁ seeds in any of the crosses. The inheritance study of the C16 : 0 content in F₁, F₂ and BC₁F₁ seeds from the crosses of CAS-5 with its parental line BSD-2-691 indicated that the segregation fitted a model of two alleles at one locus with partial dominance for the low content. The analysis of the fatty acid composition in the F₂ populations from the crosses with HA-89 revealed a segregation fitting a ratio 19 : 38 : 7 for low (<7.5%), middle (7.5–15%), and high (>25%) C16 : 0 content, respectively. This segregation was explained on the basis of three loci (P1, P2, P3) each having two alleles showing partial dominance for low content. The genotypes with a high C16 : 0 content were homozygous for the recessive allele p1 and for at least one of the other two recessive alleles, p2 or p3. This model was further confirmed with the analysis of the F₃ and the BC₁F₁ generations. It was concluded that both the recessive alleles p2 and p3 were already present in the BSD-2-691 line, the allele p1 being the result of a mutation from P1. This genetic study will facilitate breeding strategies associated with the incorporation of the high C16 : 0 trait into agronomically acceptable sunflower hybrids. Received: 30 March 1998 / Accepted: 13 August 1998     

Mapping quantitative trait loci using molecular marker linkage maps

Summary High-density restriction fragment length polymorphism (RFLP) and allozyme linkage maps have been developed in several plant species. These maps make it technically feasible to map quantitative trait loci (QTL) using methods based on flanking marker genetic models. In this paper, we describe flanking marker models for doubled haploid (DH), recombinant inbred (RI), backcross (BC), F₁ testcross (F₁TC), DH testcross (DHTC), recombinant inbred testcross (RITC), F₂, and F₃ progeny. These models are functions of the means of quantitative trait locus genotypes and recombination frequencies between marker and quantitative trait loci. In addition to the genetic models, we describe maximum likelihood methods for estimating these parameters using linear, nonlinear, and univariate or multivariate normal distribution mixture models. We defined recombination frequency estimators for backcross and F₂ progeny group genetic models using the parameters of linear models. In addition, we found a genetically unbiased estimator of the QTL heterozygote mean using a linear function of marker means. In nonlinear models, recombination frequencies are estimated less efficiently than the means of quantitative trait locus genotypes. Recombination frequency estimation efficiency decreases as the distance between markers decreases, because the number of progeny in recombinant marker classes decreases. Mean estimation efficiency is nearly equal for these methods.     

Inheritance of potato aphid resistance in hybrids between Lycopersicon esculentum and L. pennellii

Summary The potato aphid, Macrosiphum euphorbiae Thomas, is an important pest of tomato, Lycopersicon esculentum Mill., because it transmits tomato viruses and directly reduces crop yields by its feeding. This study was conducted to determine whether the wild tomato species, Lycopersicon pennellii (Corr.) D'Arcy, would be useful as a source of potato aphid resistance for tomato. Type IV trichome density and aphid resistance were assessed in six generations (P₁, P₂, F₁, F₂, BC₁P₁, and BC₁P₂) from crosses between L. pennellii (LA 716) and two tomato cultivars, New Yorker and VF Vendor. Weighted leastsquares were used in joint scaling tests to estimate the relative importance of gene effects on type IV trichome density and potato aphid resistance of the hybrids. A simple additive-dominance model adequately explained the variation in type IV trichome density. Models which included digenic epistatic effects were required to explain the variation in aphid resistance. Standard unit heritability estimates of aphid resistance in the backcross to L. esculentum were obtained by regression of BC₁F₂ off-spring families on BC₁F₁ parents. Regression coefficients and heritability estimates varied between years with the level and uniformity of the aphid infestation. In the 1985–1986 growing seasons, when aphid infestations were uniform, aphid resistance exhibited a moderate level of heritability (29.8% ± 14.1% and 47.1% ± 11.5% in New Yorker and VF Vendor backcross populations, respectively). The non-uniform aphid infestation of 1984 resulted in lower heritability estimates in the 1984–1985 growing seasons (16.1% ± 15.7% and 21.9% ± 14.8% in the New Yorker and VF Vendor backcross populations, respectively). Selection for potato aphid resistance would probably be most efficient if it were delayed until gene combinations are fixed in later generations, because of the large epistatic effects and the low heritability of this trait in seasons with variable aphid infestations.     

Intrachromosomal mapping of seven biochemical loci in barley,Hordeum vulgare

Seven biochemical loci, AmpA, Amy1, Amy2, Est-H5, Hor1, Hor2, and Wsp-H1, have been intrachromosomally mapped in the barley genome using a previously published RFLP-based genetic map. In all cases, the map locations confirmed prior chromosome assignments and agreed closely with the map positions of their homoeoloci in hexaploid wheat.