Your search keyword '"Gail M. Timmerman-Vaughan"' showing total 14 results

1. Molecular Characterisation of a Supergene Conditioning Super-High Vitamin C in Kiwifruit Hybrids

Author

Jibran Tahir, Gail M. Timmerman-Vaughan, Richard C. Macknight, Elena Hilario, Mareike Knaebel, Alan G. Seal, William A. Laing, Sean Bulley, Matthew Chisnall, Martin Shaw, Ross N. Crowhurst, Robyn Lee, Andrew Catanach, Simon C. Deroles, John McCallum, and Susan Thomson

Subjects

0106 biological sciences, 0301 basic medicine, vitamin C, Locus (genetics), Plant Science, Biology, Quantitative trait locus, 01 natural sciences, Article, 03 medical and health sciences, lcsh:Botany, kiwifruit, genomics, Allele, polyploidy, Ecology, Evolution, Behavior and Systematics, Genetics, Ecology, Chromosome, Ascorbic acid, Major gene, lcsh:QK1-989, 030104 developmental biology, breeding, Backcrossing, ascorbic acid, Ploidy, 010606 plant biology & botany

Abstract

During analysis of kiwifruit derived from hybrids between the high vitamin C (ascorbic acid, AsA) species Actinidia eriantha and A. chinensis, we observed bimodal segregation of fruit AsA concentration suggesting major gene segregation. To test this hypothesis, we performed whole-genome sequencing on pools of hybrid genotypes with either high or low AsA fruit. Pool-GWAS (genome-wide association study) revealed a single Quantitative Trait Locus (QTL) spanning more than 5 Mbp on chromosome 26, which we denote as qAsA26.1. A co-dominant PCR marker was used to validate this association in four diploid (A. chinensis &times, A. eriantha) &times, A. chinensis backcross families, showing that the A. eriantha allele at this locus increases fruit AsA levels by 250 mg/100 g fresh weight. Inspection of genome composition and recombination in other A. chinensis genetic maps confirmed that the qAsA26.1 region bears hallmarks of suppressed recombination. The molecular fingerprint of this locus was examined in leaves of backcross validation families by RNA sequencing (RNASEQ). This confirmed strong allelic expression bias across this region as well as differential expression of transcripts on other chromosomes. This evidence suggests that the region harbouring qAsA26.1 constitutes a supergene, which may condition multiple pleiotropic effects on metabolism.

Published

2019

2. Genetic diversity, population structure and genome-wide marker-trait association analysis emphasizing seed nutrients of the USDA pea (Pisum sativum L.) core collection

Author

Gail M. Timmerman-Vaughan, Jinguo Hu, Kevin E. McPhee, Chasity Watt, Ted Kisha, Rebecca J. McGee, Soon-Jae Kwon, Michael A. Grusak, Allan Brown, and Clarice J. Coyne

Subjects

Genetic diversity, food and beverages, Phenotypic trait, Biology, Biochemistry, RAPD, Sativum, Genetic marker, Botany, Genetics, Microsatellite, Allele, Molecular Biology, Genetic association

Abstract

Genetic diversity, population structure and genome-wide marker-trait association analysis was conducted for the USDA pea (Pisum sativum L.) core collection. The core collection contained 285 accessions with diverse phenotypes and geographic origins. The 137 DNA markers included 102 polymorphic fragments amplified by 15 microsatellite primer pairs, 36 RAPD loci and one SCAR (sequence characterized amplified region) marker. The 49 phenotypic traits fall into the categories of seed macro- and micro-nutrients, disease resistance, agronomic traits and seed characteristics. Genetic diversity, population structure and marker-trait association were analyzed with the software packages PowerMarker, STUCTURE and TASSEL, respectively. A great amount of variation was revealed by the DNA markers at the molecular level. Identified were three sub-populations that constituted 56.1%, 13.0% and 30.9%, respectively, of the USDA Pisum core collection. The first sub-population is comprised of all cultivated pea varieties and landraces; the second of wild P. sativum ssp. elatius and abyssinicum and the accessions from the Asian highland (Afghanistan, India, Pakistan, China and Nepal); while the third is an admixture containing alleles from the first and second sub-populations. This structure was achieved using a stringent cutoff point of 15% admixture (q-value 85%) of the collection. Significant marker-trait associations were identified among certain markers with eight mineral nutrient concentrations in seed and other important phenotypic traits. Fifteen pairs of associations were at the significant levels of P ≤ 0.01 when tested using the three statistical models. These markers will be useful in marker-assisted selection to breed pea cultivars with desirable agronomic traits and end-user qualities.

Published

2012

3. Mendel, 150 years on

Author

Gail M. Timmerman-Vaughan, T. H. Noel Ellis, Julie M.I. Hofer, Clarice J. Coyne, and Roger P. Hellens

Subjects

Genetics, Transposable element, biology, Genetic Linkage, Pigmentation, Alternative splicing, food and beverages, History, 19th Century, Flowers, Plant Science, Quantitative trait locus, History, 18th Century, biology.organism_classification, Pisum, Quantitative Trait, Heritable, Sativum, Genes, Genetic linkage, Missense mutation, Gene

Abstract

Mendel's paper 'Versuche über Pflanzen-Hybriden' is the best known in a series of studies published in the late 18th and 19th centuries that built our understanding of the mechanism of inheritance. Mendel investigated the segregation of seven gene characters of pea (Pisum sativum), of which four have been identified. Here, we review what is known about the molecular nature of these genes, which encode enzymes (R and Le), a biochemical regulator (I) and a transcription factor (A). The mutations are: a transposon insertion (r), an amino acid insertion (i), a splice variant (a) and a missense mutation (le-1). The nature of the three remaining uncharacterized characters (green versus yellow pods, inflated versus constricted pods, and axial versus terminal flowers) is discussed.

Published

2011

4. Marker development and characterisation of Hordeum bulbosum introgression lines: a resource for barley improvement

Author

Kevin J. F. Farnden, P. A. Johnston, Gail M. Timmerman-Vaughan, and Richard Pickering

Subjects

Crops, Agricultural, Genetic Markers, Germplasm, Secale, DNA, Plant, Genotype, Molecular Sequence Data, Gene Dosage, Introgression, Biology, Genes, Plant, Polymorphism, Single Nucleotide, Chromosomes, Plant, Gene mapping, Sequence Homology, Nucleic Acid, Cleaved amplified polymorphic sequence, Genetics, Alleles, Expressed Sequence Tags, Base Sequence, Chromosome Mapping, food and beverages, Chromosome, Hordeum, Exons, General Medicine, biology.organism_classification, Diploidy, Chromatin, Introns, Mutagenesis, Insertional, Hybridization, Genetic, Hordeum vulgare, Ploidy, Agronomy and Crop Science, Gene Deletion, Biotechnology

Abstract

A set of 110 diploid putative introgression lines (ILs) containing chromatin introgressed from the undomesticated species Hordeum bulbosum L. (bulbous barley grass) into cultivated barley (Hordeum vulgare L.) has been identified using a high-copy number retrotransposon-like PCR marker, pSc119.1, derived from rye (Secale cereale L.). To evaluate these lines, 92 EST-derived markers were developed by marker sequencing across four barley cultivars and four H. bulbosum genotypes. Single nucleotide polymorphisms and insertions/deletions conserved between the two species were then used to develop a set of fully informative cleaved amplified polymorphic sequence markers or size polymorphic insertion/deletion markers. Introgressed chromatin from H. bulbosum was confirmed and genetically located in 88 of these lines using 46 of the EST-derived PCR markers. A total of 96 individual introgressions were detected with most of them (94.8%) extending to the most distal marker for each respective chromosome arm. Introgressions were detected on all chromosome arms except chromosome 3HL. Interstitial or sub-distal introgressions also occurred, with two located on chromosome 2HL and one each on 3HS, 5HL and 6HS. Twenty-two putative ILs that were positive for H. bulbosum chromatin using pSc119.1 have not had introgressions detected with these single-locus markers. When all introgressions are combined, more than 36% of the barley genetic map has now been covered with introgressed chromatin from H. bulbosum. These ILs represent a significant germplasm resource for barley improvement that can be mined for diverse traits of interest to barley breeders and researchers.

Published

2009

5. Ascochyta blight disease of pea (Pisum sativum L.): defence-related candidate genes associated with QTL regions and identification of epistatic QTL

Author

Gail M. Timmerman-Vaughan, Leire Moya, Ross N. Crowhurst, Sarah R. Murray, and Tonya J. Frew

Subjects

0106 biological sciences, 0301 basic medicine, Genetic Markers, Candidate gene, DNA, Plant, Genetic Linkage, Population, Quantitative Trait Loci, Plant disease resistance, Quantitative trait locus, Genes, Plant, 01 natural sciences, Synteny, 03 medical and health sciences, Family-based QTL mapping, Ascomycota, Medicago truncatula, Genetics, education, Disease Resistance, Plant Diseases, education.field_of_study, biology, Peas, food and beverages, Chromosome Mapping, Epistasis, Genetic, General Medicine, Sequence Analysis, DNA, Ascochyta, biology.organism_classification, 030104 developmental biology, Phenotype, Epistasis, Agronomy and Crop Science, 010606 plant biology & botany, Biotechnology, Microsatellite Repeats

Abstract

Advances have been made in our understanding of Ascochyta blight resistance genetics through mapping candidate genes associated with QTL regions and demonstrating the importance of epistatic interactions in determining resistance. Ascochyta blight disease of pea (Pisum sativum L.) is economically significant with worldwide distribution. The causal pathogens are Didymella pinodes, Phoma medicaginis var pinodella and, in South Australia, P. koolunga. This study aimed to identify candidate genes that map to quantitative trait loci (QTL) for Ascochyta blight field disease resistance and to explore the role of epistatic interactions. Candidate genes associated with QTL were identified beginning with 101 defence-related genes from the published literature. Synteny between pea and Medicago truncatula was used to narrow down the candidates for mapping. Fourteen pea candidate sequences were mapped in two QTL mapping populations, A26 × Rovar and A88 × Rovar. QTL peaks, or the intervals containing QTL peaks, for the Asc2.1, Asc4.2, Asc4.3 and Asc7.1 QTL were defined by four of these candidate genes, while another three candidate genes occurred within 1.0 LOD confidence intervals. Epistasis involving QTL × background marker and background marker × background marker interactions contributed to the disease response phenotypes observed in the two mapping populations. For each population, five pairwise interactions exceeded the 5% false discovery rate threshold. Two candidate genes were involved in significant pairwise interactions. Markers in three genomic regions were involved in two or more epistatic interactions. Therefore, this study has identified pea defence-related sequences that are candidates for resistance determination, and that may be useful for marker-assisted selection. The demonstration of epistasis informs breeders that the architecture of this complex quantitative resistance includes epistatic interactions with non-additive effects.

Published

2015

6. Sequence tagged site markers linked to the sbm1 gene for resistance to pea seedborne mosaic virus in pea

Author

A. C. Russell, Gail M. Timmerman-Vaughan, and Tonya J. Frew

Subjects

Genetics, Germplasm, Mosaic virus, biology, food and beverages, Plant Science, Marker-assisted selection, biology.organism_classification, Sequence-tagged site, chemistry.chemical_compound, chemistry, Genetic linkage, Molecular marker, Pea seed-borne mosaic virus, Restriction fragment length polymorphism, Agronomy and Crop Science

Abstract

Resistance to pea seed-borne mosaic virus (PSbMV) pathotype P-1 in peas is conferred by sbm1 with recessive inheritance. PSbMV is an economically important pathogen with world-wide distribution that causes significant losses in pea yield and reduces seed and produce quality. The sbm1 gene was previously mapped to linkage group VI on molecular linkage maps of the pea genome. To improve plant breeders' ability to develop varieties resistant to PSbMV, two random amplified polymorphic DNA markers (G05―2537 and L01―910) and one restriction fragment length polymorphism (P446) linked to sbm1 have been identified. The genomic sequences for these markers have been characterized and the information used to develop three simple polymerase chain reaction-based STS (sequence tagged site) assays. Linkage analysis in two F 2 populations showed that the most tightly linked of these three STS loci (sG05―2537) is approximately 4 cM from sbm1. Characterization of a collection of resistant and susceptible germplasm demonstrated a strong correlation between STS alleles and sbm1 alleles, indicating the utility of these markers for marker-assisted selection in breeding programmes using a range of germplasm sources.

Published

2002

7. Kanamycin is effective for selecting transformed peas

Author

Pauline A. Cooper, Meeghan Pither-Joyce, Brent Gilpin, Gail M. Timmerman-Vaughan, J. E. Grant, Sonja J. Hoglund, and Jill Reader

Subjects

food.ingredient, Rhizobiaceae, biology, fungi, food and beverages, Kanamycin, Plant Science, General Medicine, Genetically modified crops, Agrobacterium tumefaciens, biology.organism_classification, Pisum, Horticulture, Transformation (genetics), Sativum, food, Botany, Genetics, medicine, Agronomy and Crop Science, Cotyledon, medicine.drug

Abstract

Immature cotyledons from six cultivars and breeding lines of Pisum sativum were cocultivated with Agrobacterium tumefaciens and selected on a medium containing kanamycin. Transformed plants were recovered with a success rate of between 0.8 and 3.4% of explants treated. The plasmids used were based on pGA643 and have a nos promoter driving an nptII gene. Progeny from the primary transformants showed stable inheritance of the nos-nptII gene.

Published

1998

8. The transfer of a powdery mildew resistance gene from Hordeum bulbosum L to barley (H. vulgare L.) chromosome 2 (2I)

Author

Gail M. Timmerman-Vaughan, A. M. Hill, M. Michel, and R. A. Pickering

Subjects

Genetic transfer, food and beverages, Introgression, General Medicine, Plant disease resistance, Biology, Gene mapping, Botany, Genetics, Poaceae, Hordeum vulgare, Agronomy and Crop Science, Gene, Powdery mildew, Biotechnology

Abstract

Hordeum bulbosum L. is a source of disease resistance genes that would be worthwhile transferring to barley (H. vulgare L.). To achieve this objective, selfed seed from a tetraploid H. vulgare x H. bulbosum hybrid was irradiated. Subsequently, a powdery mildew-resistant selection of barley phenotype (81882/83) was identified among field-grown progeny. Using molecular analyses, we have established that the H. bulbosum DNA containing the powdery mildew resistance gene had been introgressed into 81882/83 and is located on chromosome 2 (2I). Resistant plants have been backcrossed to barley to remove the adverse effects of a linked factor conditioning triploid seed formation, but there remains an association between powdery mildew resistance and non-pathogenic necrotic leaf blotching. The dominant resistance gene is allelic to a gene transferred from H. bulbosum by co-workers in Germany, but non-allelic to all other known powdery mildew resistance genes in barley. We propose Mlhb as a gene symbol for this resistance.

Published

1995

9. Identification of Mendel's White Flower Character

Author

Andrew C. Allan, Abdelhafid Bendahmane, Susan Thomson, Mark Fiers, Kathy E. Schwinn, Gail M. Timmerman-Vaughan, Tonya J. Frew, T. H. Noel Ellis, Kevin M. Davies, Jeanne M. E. Jacobs, Julie M.I. Hofer, Roger P. Hellens, Carol Moreau, Kui Lin-Wang, Clarice J. Coyne, and Sarah R. Murray

Subjects

Candidate gene, Mutant, lcsh:Medicine, Plant Biology, Color, Flowers, Biology, Genes, Plant, Genome, Genetics and Genomics/Plant Genetics and Gene Expression, Plant Biology/Plant Genetics and Gene Expression, Gene mapping, Genetics and Genomics/Population Genetics, RNA, Messenger, Allele, lcsh:Science, Gene, Alleles, Synteny, Genetics, Multidisciplinary, Genetics and Genomics/Functional Genomics, lcsh:R, food and beverages, Genetics and Genomics, Genetics and Genomics/Gene Expression, White (mutation), Genetics and Genomics/Gene Function, Mutation, lcsh:Q, Genetics and Genomics/Gene Discovery, Research Article

Abstract

Background: The genetic regulation of flower color has been widely studied, notably as a character used by Mendel and his predecessors in the study of inheritance in pea. Methodology/Principal Findings: We used the genome sequence of model legumes, together with their known synteny to the pea genome to identify candidate genes for the A and A2 loci in pea. We then used a combination of genetic mapping, fast neutron mutant analysis, allelic diversity, transcript quantification and transient expression complementation studies to confirm the identity of the candidates. Conclusions/Significance: We have identified the pea genes A and A2. A is the factor determining anthocyanin pigmentation in pea that was used by Gregor Mendel 150 years ago in his study of inheritance. The A gene encodes a bHLH transcription factor. The white flowered mutant allele most likely used by Mendel is a simple G to A transition in a splice donor site that leads to a mis-spliced mRNA with a premature stop codon, and we have identified a second rare mutant allele. The A2 gene encodes a WD40 protein that is part of an evolutionarily conserved regulatory complex.

Published

2010

10. Construction and characterization of two bacterial artificial chromosome libraries of pea (Pisum sativum L.) for the isolation of economically important genes

Author

P. N. Rajesh, Khalid Meksem, Michael A. Grusak, M. T. McClendon, Kevin McPhee, Walling Jg, K. E. Keller, Gail M. Timmerman-Vaughan, Jeffry L. Shultz, Debra Ann Inglis, Norman F. Weeden, R. R. Martin, Sarah R. Murray, E. W. Storlie, David A. Lightfoot, Clarice J. Coyne, and C. M. Li

Subjects

Germplasm, Genetics, Genetic Markers, Bacterial artificial chromosome, Chromosomes, Artificial, Bacterial, biology, Peas, food and beverages, Chromosome, General Medicine, biology.organism_classification, Genes, Plant, Genome, Intergenic region, Pea seed-borne mosaic virus, Low copy number, Molecular Biology, Gene, Biotechnology, Gene Library

Abstract

Pea ( Pisum sativum L.) has a genome of about 4 Gb that appears to share conserved synteny with model legumes having genomes of 0.2–0.4 Gb despite extensive intergenic expansion. Pea plant inventory (PI) accession 269818 has been used to introgress genetic diversity into the cultivated germplasm pool. The aim here was to develop pea bacterial artificial chromosome (BAC) libraries that would enable the isolation of genes involved in plant disease resistance or control of economically important traits. The BAC libraries encompassed about 3.2 haploid genome equivalents consisting of partially HindIII-digested DNA fragments with a mean size of 105 kb that were inserted in 1 of 2 vectors. The low-copy oriT-based T-DNA vector (pCLD04541) library contained 55 680 clones. The single-copy oriS-based vector (pIndigoBAC-5) library contained 65 280 clones. Colony hybridization of a universal chloroplast probe indicated that about 1% of clones in the libraries were of chloroplast origin. The presence of about 0.1% empty vectors was inferred by white/blue colony plate counts. The usefulness of the libraries was tested by 2 replicated methods. First, high-density filters were probed with low copy number sequences. Second, BAC plate-pool DNA was used successfully to PCR amplify 7 of 9 published pea resistance gene analogs (RGAs) and several other low copy number pea sequences. Individual BAC clones encoding specific sequences were identified. Therefore, the HindIII BAC libraries of pea, based on germplasm accession PI 269818, will be useful for the isolation of genes underlying disease resistance and other economically important traits.

Published

2007

11. Validation of quantitative trait loci for Ascochyta blight resistance in pea ( Pisum sativum L.), using populations from two crosses

Author

Tanveer Khan, Michael Boyd Lakeman, Margy Gilpin, Gail M. Timmerman-Vaughan, A. C. Russell, Ruth C. Butler, Karla Falloon, Sarah R. Murray, Tonya J. Frew, and P. A. Johnston

Subjects

Germplasm, Crops, Agricultural, animal diseases, genetic processes, Population, Quantitative Trait Loci, Quantitative trait locus, Sativum, Ascomycota, Genetics, Blight, Cultivar, education, Crosses, Genetic, DNA Primers, Plant Diseases, Sequence Tagged Sites, education.field_of_study, biology, Reproduction, fungi, Peas, food and beverages, Chromosome Mapping, General Medicine, Fungi imperfecti, Western Australia, Ascochyta, biology.organism_classification, Immunity, Innate, Random Amplified Polymorphic DNA Technique, Agronomy and Crop Science, Nucleic Acid Amplification Techniques, Polymorphism, Restriction Fragment Length, Biotechnology, New Zealand

Abstract

Resistance to Ascochyta blight of pea was genetically characterized by mapping quantitative trait loci (QTLs) using two crosses, 3147-A26 (A26, partially resistant) × cultivar Rovar (susceptible) and 3148-A88 (A88, partially resistant) × Rovar, with the aim of developing an increased understanding of the genetics of resistance and of identifying linked molecular markers that may be used to develop resistant germplasm. Molecular linkage maps for both crosses were aligned so that the results of QTL mapping could be compared. Ascochyta blight disease severity in response to natural epidemics was measured in field trials conducted in Western Australia and New Zealand. Eleven putative QTLs for Ascochyta blight resistance were identified from the A26 × Rovar population and 14 putative QTLs from the A88 × Rovar population. Six QTLs were associated with the same genomic regions in both populations. These QTLs reside on linkage groups II, III, IV, V, and VII (two QTLs). The severity of Ascochyta blight disease symptoms on pea increases during field epidemics as plants mature; therefore, QTLs for plant reproductive maturity were mapped. Six QTLs were detected for plant maturity in the A26 × Rovar population, while five plant maturity QTLs were mapped in the A88 × Rovar population. QTLs for plant maturity coincide with Ascochyta blight resistance QTLs in four genomic regions, on linkage groups II (two regions), III, and V. The plant maturity and Ascochyta blight resistance QTLs on III were linked in repulsion phase. Therefore, the coincidence of these QTLs may be explained by linkage of distinct loci for the two traits. The QTLs on linkage groups II and V were linked in coupling phase; therefore, linked QTLs for resistance and maturity may be present in these regions, or the Ascochyta blight resistance QTLs detected in these regions are the result of pleiotropic effects of plant-maturity genetic loci.

Published

2003

12. Linkage mapping of quantitative trait loci controlling seed weight in pea (Pisum sativum L.)

Author

A. C. Russell, Gail M. Timmerman-Vaughan, Tonya J. Frew, John McCallum, and N. F. Weeden

Subjects

Genetics, Bulked segregant analysis, food and beverages, General Medicine, Biology, Quantitative trait locus, biology.organism_classification, RAPD, Vigna, Sativum, Gene mapping, Genetic linkage, Restriction fragment length polymorphism, Agronomy and Crop Science, Biotechnology

Abstract

Quantitative trait loci (QTLs) affecting seed weight in pea (Pisum sativum L.) were mapped using two populations, a field-grown F2 progeny of a cross between two cultivated types (‘Primo’ and ‘OSU442-15’) and glasshouse-grown single-seed-descent recombinant inbred lines (RILs) from a wide cross between a P. sativum ssp. sativum line (‘Slow’) and a P. sativum ssp. humile accession (‘JI1794’). Linkage maps for these crosses consisted of 199 and 235 markers, respectively. QTLs for seed weight in the ‘Primo’ x ‘OSU442-15’ cross were identified by interval mapping, bulked segregant analysis, and selective genotyping. Four QTLs were identified in this cross, demonstrating linkage to four intervals on three linkage groups. QTLs for seed weight in the ‘JI1794’ x ‘Slow’ cross were identified by single-marker analyses. Linkage were demonstrated to four intervals on three linkage groups plus three unlinked loci. In the two crosses, only one common genomic region was identified as containing seed-weight QTLs. Seed-weight QTLs mapped to the same region of linkage group III in both crosses. Conserved linkage relationships were demonstrated for pea, mungbean (Vigna radiata L.), and cowpea (V. unguiculata L.) genomic regions containing seed-weight QTLs by mapping RFLP loci from the Vigna maps in the ‘Primo’ x ‘OSU442-15’ and ‘JI1794’ x ‘Slow’ crosses.

Published

1995

13. DNA markers for disease resistance breeding in peas (Pisum sativum L.)

Author

A. Hill, Gail M. Timmerman-Vaughan, B.J. Gilpin, T.J. Frew, and A.C. Russell

Subjects

Germplasm, Genetics, General Computer Science, Genetic marker, Genetic linkage, food and beverages, Ascochyta pisi, Plant breeding, Biology, Quantitative trait locus, Plant disease resistance, Pea enation mosaic virus, biology.organism_classification

Abstract

Introducing resistance genes through plant breeding remains an important and effective means of protecting plants from diseases. Plant species commonly carry genes for disease resistance within their collective germplasm base. Disease resistance can either be monogenic (ie. encoded by a single gene) or quantitative (ie. encoded by a number of genes). The first step in disease resistance breeding is to identify accessions carrying the resistance phenotype. The conventional process of breeding for resistance involves making controlled crosses and selecting sexual progeny for improved disease resistance. While relatively straight-forward for dominantly-inherited single gene resistance, this process becomes progressively more difficult and time-comsuming for resistance encoded by single genes with recessive inheritance and for quantitatively inherited resistance. Through the process of genetic linkage mapping, molecular markers which are linked to disease resistance genes can be identified, and these can then be applied in plant breeding programmes to assist in resistance gene introgression. Our research group has identified DNA tags for a number of genes for resistance to diseases affecting peas (Pisum sativum L.). For example, DNA markers linked to recessive genes for resistance to pea seed-borne mosaic virus (PSbMV) pathotype P-1 (Timmerman et al. 1993) and to powdery mildew fungus (Timmerman et al. 1994) have been identified. These genes are termed sbm-1 and er-1, respectively. In more recent research, we have identified markers linked to the dominantly inherited gene for resistance to pea enation mosaic virus (PEMV). This gene is termed En. The molecular markers linked to these three monogenic disease resistance genes have been applied in a field pea breeding programme to develop germplasm containing multiple disease resistance phenotypes. DNA tags linked to sbm-1 and er-1 have been used in conjunction with limited direct testing for disease resistance. Although widely distributed throughout the world, PEMV does not occur in New Zealand; therefore breeding for resistance to PEMV requires the use of overseas disease testing or DNA tags. The DNA tags linked to En have been used in the early stages of cultivar development without direct testing for disease resistance. The genes contributing to quantitatively inherited disease resistance can also be characterised using linkage maps and DNA markers and DNA tags can be developed (Michelmore 1995). Experiments to map the genes for resistance to Ascochyta blight of peas are currently underway, using a QTL mapping experimental design. Similar experiments have been carried out by our research group to map genes for two other quantitatively inherited traits, seed weight (Timmerman-Vaughan et al. 1996) and green seed colour (McCallum et al. 1997). Ascochyta blight is a serious disease of peas which is caused by a trio of fungal pathogens: Mycosphaerella pinodes, Ascochyta pisi and Phoma medicaginis. Accessions with improved resistance to Ascochyta blight have been identified among peas bred by the Crop & Food Research field pea breeding programme. Using these accessions as the resistant parents, large populations of F 2 progeny and their descendants have been developed. The genotypes of these segregating

Published

1997

14. Biochemical and genetic linkage analysis of green seed color in field pea

Author

Tonya J. Frew, John McCallum, Gail M. Timmerman-Vaughan, and A. C. Russell

Subjects

food.ingredient, Genetic inheritance, biology, food and beverages, Horticulture, Quantitative trait locus, biology.organism_classification, Pigment, Field pea, food, Genetic linkage analysis, visual_art, Botany, Genetics, visual_art.visual_art_medium, Allele, Cotyledon

Abstract

Developmental, environmental, and genetic factors affecting seed color were studied in the progeny of a cross between two white-flowered (aa) green cotyledon (ii) field peas (Pisum sativum L.): the pale large-seeded Marrowfat cultivar Primo and the greener small-seeded Prussian Blue OSU442-15. Changes in chlorophyll and carotenoid content during seed development of the parental genotypes were determined by high performance liquid chromatography analysis. Both cultivars accumulated similar pigment quantities per seed, but pigment loss was greater during maturation of `Primo'. Bleached and unbleached mature seed tissues also were compared for pigment composition. Lutein was the predominant pigment in bleached cotyledons of both cultivars. Only trace amounts of pheophytins were detected in unbleached seed. In both genotypes, chlorophyll A : B ratios were ≈1:1 in seed coats compared to 3:1 in cotyledons. Objective measurements of seed color in terms of luminance (lightness) and chrominance (hue and saturation) were made in YUV color space by video image analysis. Inheritance of seed color was studied in an F2 population derived from the `Primo' × `OSU442-15' cross and inbred descendants. Quantitative trait loci (QTL) for seed color were localized by interval mapping using a linkage map of 199 molecular markers spanning most of the genome and by bulked segregant analysis and selective genotyping. Four genomic regions affecting seed color were detected. A major gene accounting for 61% of the phenotypic variance in seed lightness (Y luminance component) was identified on linkage group V linked to r locus. Another major gene, which accounted for 56% of the phenotypic variance in seed hue (U chrominance component), was mapped to a linkage group containing group III and IV markers. A QTL with smaller effect on seed hue (U and V chrominance components) was detected on linkage group VII. Support for overdominant allelic interaction for a QTL on linkage group I, adjacent to the legumin locus Lg-J, was obtained by selective genotyping of the seed lightness distributional extremes.