Genetic control of the spring growth habit in old local cultivars and landraces of common wheat from Siberia

The inheritance of the spring growth habit was studied in 63 old local cultivars and landraces of common wheat from Eastern and Western Siberia and the Tyva Republic. Minimal polymorphism was observed for the dominant Vrn genes, controlling the spring growth habit in landraces of these regions. The control was digenic and involved the Vrn1 and Vrn2 dominant genes in the majority (95%) of cultivars and was monogenic in three cultivars. None of the cultivars had the Vrn3 dominant gene, characteristic of the neighboring regions of China and Central Asia. Among 137 old local cultivars and landraces of Siberia, only one (cultivar Sibirskaya (K-23347) from Irkutsk oblast, was comparable in the response to the natural short day (photoperiod) to Chinese cultivars. Comparison of the results and the data reported for commercial cultivars revealed that the genotype frequencies of the dominant Vrn genes in Siberian landraces and commercial cultivars of common wheat remained essentially unchanged at least for the past 100 years. At the same time, Siberian landraces significantly differed in Vrn dominant gene frequencies from cultivars of the adjacent regions. It was assumed that the control of the spring growth habit by the two Vrn dominant genes is optimal for the climatic conditions of Siberia.     

The Characterization and Geographical Distribution of the Genes Responsible for Vernalization Requirement in Chinese Bread Wheat

The frequency and distribution of the major vernalization requirement genes and their effects on growth habits were studied.Of the 551 bread wheat genotypes tested,seven allelic combinations of the three Vrn.1 genes were found to be responsible for the spring habit,three for the facultative habit and one for the winter habit.The three Vrn-1 genes behaved additively with the dominant allele of Vrn-A1 exerting the strongest effect.The allele combinations of the facultative genotypes and the discovery of spring genotypes with "winter" allele of Vrn-1 implied the presence of as yet unidentified alleles/genes for vernalization response.The dominant alleles of the three Vrn-1 genes were found in all ten ecological regions where wheat Is cultivated in China,with Vrn-D1 as the most common allele in nine and Vrn-A1 in one.The combination of vrn-A 1vrnB 1Vrn-D1 was the predominant genotype in seven of the regions.Compared with landraces,improved varieties contain a higher proportion of the spring type.This was attributed by a higher frequency of the dominant Vrn-A1 and Vrn-B1 alleles in the latter.Correlations between Vrn-1 allelic constitutions and heading date,spike length,plant type as well as cold tolerance were established.     

Comparative genetic analysis of the hexaploid wheat Triticum petropavlovskyi Udasz. et Migusch. and Triticum aestivum L

A poorly studied species of hexaploid wheat Triticum petropavlovskyi Udacz. et Migusch. was compared with common wheat Triticum aestivum L. by means of monosomic and genetic analyses of F2 hybrids. Triticum petropavlovskyi was found to carry 13 dominant genes determining its morphological and physiological characters and regular bivalent conjugation of chromosomes. These genes were allelic to the respective genes of common wheat and were located in the same chromosomes. The modes of gene interaction were also the same. There was simple dominance for most genes studied and complementary interaction for the genes of hybrid dwarfism and hybrid necrosis. Triticum petropavlovskyi had the following dominant genes: Hg (downy glume); Rg1 (red glume color); Hl (downy leaf); Hn (downy node); Pa (pubescent auricles); Q (speltlike ears); D1 (grass-clump dwarfism); Ne1 (hybrid necrosis); Ph1 and Ph2 (genes of bivalent conjugation preventing homoeologous chromosomes from pairing); and Vrn1, Vrn2, Vrn3, and Vrn4 (genes of the spring habit). The gene Vrn1, which caused an increase in ear emergence time and a pronounced response to vernalization, was poorly expressed. T. petropavlovskyi was earlier demonstrated to have a species-specific gene P or Eg (elongated glume), which was not allelic to the gene Eg of the tetraploid T. polonicum L. The data obtained indicate that T. petropavlovskyi has originated from T. aestivum via mutations.     

Molecular characterization of vernalization response genes in Canadian spring wheat.

Vernalization response (Vrn) genes play a major role in determining the flowering/maturity times of spring-sown wheat. We characterized a representative set of 40 western Canadian adapted spring wheat cultivars/lines for 3 Vrn loci. The 40 genotypes were screened, along with 4 genotypes of known Vrn genes, using previously published genome-specific polymerase chain reaction primers designed for detecting the presence or absence of dominant or recessive alleles of the major Vrn loci: Vrn-A1, Vrn-B1, and Vrn-D1. The dominant promoter duplication allele Vrn-A1a was present in 34 of 40 cultivars/lines, whereas the promoter deletion allele Vrn-A1b was present in only 1 of the western Canadian cultivars (Triticum aestivum L. 'Rescue') and 2 of its derivative chromosomal substitution lines. The intron deletion allele Vrn-A1c was not present in any line tested. Only 4 of the western Canadian spring wheat cultivars tested here carry the recessive vrn-A1 allele. The dominant allele of Vrn-B1 was detected in 20 cultivars/lines. Fourteen cultivars/lines had dominant alleles of Vrn-A1a and Vrn-B1 in combination. All cultivars/lines carried the recessive allele for Vrn-D1. The predominance of the dominant allele Vrn-A1a in Canadian spring wheat appears to be due to the allele's vernalization insensitivity, which confers earliness under nonvernalizing growing conditions. Wheat breeders in western Canada have incorporated the Vrn-A1a allele into spring wheats mainly by selecting for early genotypes for a short growing season, thereby avoiding early and late season frosts. For the development of early maturing cultivars with high yield potential, different combinations of Vrn alleles may be incorporated into spring wheat breeding programs in western Canada.     

Application of RAPD for making DNA markers to Vrn genes

The possibility of using the PCR with arbitrary primers to mark Vrn genes, Vrn3 in particular, was investigated. RAPD-analysis of DNA of near isogenic lines on Vrn1, Vrn2 and Vrn3 loci in genefone of four varieties of winter wheat were carried out. Monogenic dominant lines by Vrn3 locus possessed 657 b.p. polymorphic DNA fragment. The possibility of using this polymorphic DNA amplicon as a molecular marker was confirmed by results of RAPD-analysis of DNA of some commercial wheat varieties of different ecological-geographic origin possessing dominant Vrn3 alleles, as well as by RAPD-analysis of F2 population from cross of monogenic Vrn3 dominant spring line with its recurrent parent--winter wheat variety Mironovskaya 808. The results of RAPD are comparable with hybridological analysis data concerning type of development of plants from F2 population.     

Effect of the 5R(5A) alien chromosome substitution on the growth habit and winter hardiness of wheat

The growth habit, ear emergence time, and frost tolerance of wheat/rye substitution lines have been studied in cultivars Rang and Mironovskaya Krupnozernaya whose chromosome 5A is substituted with chromosome 5R of Onkhoyskaya rye. Hybrid analysis has demonstrated that the spring habit of the recipient cultivars Rang and Mironovskaya Krupnozernaya is controlled by dominant gene Vrn-A1 located in chromosome 5A. Onokhoyskaya rye has a dominant gene for the spring habit (Sp1) located in chromosome 5R. It has been found that the resultant 5R(5A) alien-substitution lines have a winter type of development and ears do not emerge during summer in plants sown in spring. The change in growth habit has been shown to be related to the absence of the rye Spl gene expression in the substitution lines. The winter hardiness of winter 5R(5A) alien-substitution lines has been studied under the environmental conditions of Novosibirsk. Testing the lines in the first winter demonstrated that their winter survival is 20-27%. The possible presence of the frost resistance gene homeoallelic to the known genes Fr1 and Fr2 of the common wheat located on chromosomes 5A and 5D, respectively, is discussed.     

Genetic diversity of local spring bread wheats (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.) of West and East Siberia in gliadin genes

A considerable polymorphism in gliadin genes was detected in the wheat landraces of West Siberia (Altai krai, Omsk oblast, and Kurgan oblast) and the local cultivars characteristic of several East Siberian regions (Krasnoyarsk krai, Irkutsk oblast, Tuva, and Yakutia), and the genetic formulas were determined. The common alleles characteristic of the wheats of both regions were detected, namely, Gli-A1f, Gli-A1j, Gli-A1i, Gli-A1m, Gli-B1e, Gli-B1m, Gli-D1a, Gli-A2q, Gli-A2k, Gli-A2u, Gli-D2a, and Gli-D2q, as well as 14 novel alleles unknown earlier. It was demonstrated that several genotypes had formed in Siberia. Of them, the genotypes Gli-A1f_Gli-B1e_Gli-D1a and Gli-A1j_Gli-B1e_Gli-D1a occur both in West and East Siberia, whereas the genotypes Gli-A1i_Gli-B1m_Gli-D1a_Gli-A2new10, Gli-A1m_Gli-B1b_Gli-D1a_Gli-A2f, and Gli-A1m_Gli-B1m_Gli-D1a_Gli-A2u are found only in East Siberia.     

Trends in genetic diversity change of spring bread wheat cultivars released in Russia in 1929-2003

Using genealogy analysis, we studied genetic diversity of 340 cultivars of spring bread wheat that were released on the territory of Russia in 1929-2003. Trends in the temporal change of genetic diversity were inferred from analysis of a set of n x m matrices, where n is the number of the released cultivars and m is the number of original ancestors. The pool of original ancestors of the spring bread wheat cultivars for the total period of study included 255 landraces, of which 88 were from the former USSR and modern Russia. The original ancestors showed great differences in their presence in the cultivar sets examined and, consequently, in their importance for the gene pool of Russian spring wheats. The distributions of contributions of dominant original ancestors to cultivar diversity were significantly different in different regions, indicating that the ancestors were specific for the cultivation conditions. During the last 75 years, the genetic diversity of the spring bread wheat cultivars has been increasing owing to the wide use of foreign material in Russian breeding programs. However, our analysis showed that about 60 landraces, including the Russian ones, were lost during the studied time period. The lost part makes up 35% of the gene pool of the Russian original ancestors. It is reasonable to assume that the lost landraces carried a gene complex f or adaptation to specific Russian environments. Specificity of the contributions of the original ancestors in the sets of cultivars produced in different breeding centers was established. A comparative analysis of genetic similarity of cultivars was carried out using coefficients of parentage. Significant differences in this parameter between breeding institutes and regions of cultivation were revealed.     

Genetics of growth habit (spring vs winter) in common wheat: confirmation of the existence of dominant gene Vrn4

The number of dominant Vrn genes in common wheat, Triticum aestivum L., is estimated. Data were obtained supporting Pugsley's and Gotoh's data on the presence of a dominant gene Vrn4 in near-isogenic line 'Triple Dirk F'. The presence of a dominant gene Vrn4 in line 'Gabo-2' of cultivar 'Gabo', which was used by Pugsley as a donor of the gene Vrn4 for the near-isogenic line 'Triple Dirk F', was also confirmed. The Vrn2 and Vrn4 relationship and their chromosomal location are discussed. It was demonstrated that the dominant Vrn8 gene which was introgressed from Triticum sphaerococcum to common wheat by Stelmakh and Avsenin is allelic to Vrn4. While genes Vrn6^sc and Vrn7^sc which were introgressed from rye, Secale cereale L., by the above-mentioned authors are not allelic to the genes Vrn1, Vrn2, Vrn3 and Vrn4.Communicated by J.W. Snape     

Unlocking the diversity of genebanks: whole-genome marker analysis of Swiss bread wheat and spelt

Key message

High-throughput genotyping of Swiss bread wheat and spelt accessions revealed differences in their gene pools and identified bread wheat landraces that were not used in breeding.

Abstract

Genebanks play a pivotal role in preserving the genetic diversity present among old landraces and wild progenitors of modern crops and they represent sources of agriculturally important genes that were lost during domestication and in modern breeding. However, undesirable genes that negatively affect crop performance are often co-introduced when landraces and wild crop progenitors are crossed with elite cultivars, which often limit the use of genebank material in modern breeding programs. A detailed genetic characterization is an important prerequisite to solve this problem and to make genebank material more accessible to breeding. Here, we genotyped 502 bread wheat and 293 spelt accessions held in the Swiss National Genebank using a 15K wheat SNP array. The material included both spring and winter wheats and consisted of old landraces and modern cultivars. Genome- and sub-genome-wide analyses revealed that spelt and bread wheat form two distinct gene pools. In addition, we identified bread wheat landraces that were genetically distinct from modern cultivars. Such accessions were possibly missed in the early Swiss wheat breeding program and are promising targets for the identification of novel genes. The genetic information obtained in this study is appropriate to perform genome-wide association studies, which will facilitate the identification and transfer of agriculturally important genes from the genebank into modern cultivars through marker-assisted selection.

     

Trends in Genetic Diversity Change of Spring Bread Wheat Cultivars Released in Russia in 1929–2003

Using genealogy analysis, we studied genetic diversity of 340 cultivars of spring bread wheat that were released on the territory of Russia in 1929–2003. Trends in the temporal change of genetic diversity were inferred from analysis of a set of n × m matrices, where n is the number of the released cultivars and m is the number of original ancestors. The pool of original ancestors of the spring bread wheat cultivars for the total period of study included 255 landraces, of which 88 were from the former USSR and modern Russia. The original ancestors showed great differences in their presence in the cultivar sets examined and, consequently, in their importance for the gene pool of Russian spring wheats. The distributions of contributions of dominant original ancestors to cultivar diversity were significantly different in different regions, indicating that the ancestors were specific for the cultivation conditions. During the last 75 years, the genetic diversity of the spring bread wheat cultivars has been increasing owing to the wide use of foreign material in Russian breeding programs. However, our analysis showed that about 60 landraces, including the Russian ones, were lost during the studied time period. The lost part makes up 35% of the gene pool of the Russian original ancestors. It is reasonable to assume that the lost landraces carried a gene complex f or adaptation to specific Russian environments. Specificity of the contributions of the original ancestors in the sets of cultivars produced in different breeding centers was established. A comparative analysis of genetic similarity of cultivars was carried out using coefficients of parentage. Significant differences in this parameter between breeding institutes and regions of cultivation were revealed.     

Effect of the 5R(5A) Alien Chromosome Substitution on the Growth Habit and Winter Hardiness of Wheat

The growth habit, ear emergence time, and frost tolerance of wheat/rye substitution lines have been studied in cultivars Rang and Mironovskaya Krupnozernaya whose chromosome 5A is substituted with chromosome 5R of Onkhoyskaya rye. Hybrid analysis has demonstrated that the spring habit of the recipient cultivars Rang and Mironovskaya Krupnozernaya is controlled by dominant gene Vrn-A1 located in chromosome 5A. Onokhoyskaya rye has a dominant gene for the spring habit (Sp1) located in chromosome 5R. It has been found that the resultant 5R(5A) alien-substitution lines have a winter type of development and ears do not emerge during summer in plants sown in spring. The change in growth habit has been shown to be related to the absence of the rye Sp1 gene expression in the substitution lines. The winter hardiness of winter 5R(5A) alien-substitution lines has been studied under the environmental conditions of Novosibirsk. Testing the lines in the first winter demonstrated that their winter survival is 20–27%. The possible presence of the frost resistance gene homeoallelic to the known genes Fr1 and Fr2 of the common wheat located on chromosomes 5A and 5D, respectively, is discussed.     

Genealogical analysis of the diversity of spring barley cultivars released in former Czechoslovakia and modern Czechia

Genealogical analysis was employed in studying the time course of changes in genetic diversity of spring barley cultivars released in former Czechoslovakia and the modem Czech Republic. Cultivars from different regions proved to significantly differ in the distribution of dominant ancestor contributions, suggesting a specificity of original ancestors to different cultivation conditions. A comparison of cultivar groups differing in end use showed that the genetic diversity of malting cultivars was significantly lower than that of feed cultivars, although modern malting and feed cultivars of Czechia and Slovakia have virtually the same genetic basis. Temporal analysis showed that diversity tended to increase through decades. While new original ancestors were introduced in pedigrees, especially in the past 30 years, the number of local landraces and old cultivars gradually decreased. The losses accounted for about two-thirds of the local germplasm. Thus, a substantial increase in genetic diversity was accompanied by genetic erosion of the local spring barley gene pool of former Czechoslovakia. A cluster structure was observed for the set of spring barley cultivars released in the postwar period. The coefficient of parentage averaged overall possible pairs of cultivars introduced in the Czech National List was estimated at 0.11. It was concluded that the genetic diversity of modern spring barley cultivars in the Czech Republic is at an acceptable level.     

Genealogical analysis of the diversity of spring barley cultivars released in former Czechoslovakia and modern Czech Republic

Genealogical analysis was employed in studying the time course of changes in genetic diversity of spring barley cultivars released in former Czechoslovakia and the modern Czech Republic. Cultivars from different regions proved to significantly differ in the distribution of dominant ancestor contributions, suggesting a specificity of original ancestors to different cultivation conditions. A comparison of cultivar groups differing in end use showed that the genetic diversity of malting cultivars was significantly lower than that of feed cultivars, although modern malting and feed cultivars of Czechia and Slovakia have virtually the same genetic basis. Temporal analysis showed that diversity tended to increase through decades. While new original ancestors were introduced in pedigrees, especially in the past 30 years, the number of local landraces and old cultivars gradually decreased. The losses accounted for about two-thirds of the local germplasm. Thus, a substantial increase in genetic diversity was accompanied by genetic erosion of the local spring barley gene pool of former Czechoslovakia. A cluster structure was observed for the set of spring barley cultivars released in the postwar period. The coefficient of parentage averaged over all possible pairs of cultivars introduced in the Czech National List was estimated at 0.11. It was concluded that the genetic diversity of modern spring barley cultivars in the Czech Republic is at an acceptable level.     

Genetic variation of Vp1 in Sichuan wheat accessions and its association with pre-harvest sprouting response

Pre-harvest sprouting (PHS) in bread wheat is a major abiotic constraint reducing yield and influencing the production of high quality grain. In China both spring and winter wheat regions are affected by PHS. Sichuan lies in southwest China, where the most of rainfall occurs during April to September when wheat is harvested. The present investigation was conducted to identify the allelic variability of Vp1, a gene that plays a role in maintenance and induction of dormancy, among Sichuan landraces and recent cultivars with different dormancy levels and to find potential sources of PHS resistance for breeding. Sichuan landrace and cultivar wheat accessions had a wide range of dormancy levels. The average germination index (GI) of Sichuan landrace accessions was 0.232, whereas at 0.674 it was much higher for cultivars. The different dormancy levels between landraces and cultivars indicated that pre-harvest sprouting resistance might have been neglected in recent Sichuan wheat breeding programs. The average GI of white grained accessions was higher than for red grained accessions. Particular Vp-1B gene fragments were specific in landraces or cultivars and in white or red grained accessions. The results indicated that Vp-1B markers could be used to distinguish cultivars and landraces. Significant relationships between certain Vp-1B allelesand GI of Sichuan wheat accessions were shown by Spearman’s rank correlation analysis.     

黄淮南片冬麦区主导品种春化基因及冬春性分析

以1950～2007年黄淮南片冬麦区的127个主导小麦品种为材料,利用第5同源群的春化基因分子标记对其进行了春化基因检测,并分析了小麦品种的春化基因与其冬春性的对应关系及黄淮南片冬麦区8次品种更换中春化基因与品种冬春性的演变规律.结果表明,参试品种中没有品种携带显性Vrn-A1基因,7个品种含有Vrn-B1基因(5.5%),2个品种含有Vrn-B1+Vrn-D1基因(1.6%),56个品种含有Vrn-D1基因(44.1%).春化基因类型与品种冬春特性基本相符,春化基因控制着小麦品种的冬春特性.主导品种含春化显性基因频率的变化趋势与冬春性变化规律存在较大差异,与传统方法相比,仅用春化基因来确定品种冬春性存在一定的不完善之处.采用春化基因分子标记与传统的冬春性鉴定方法相结合来认识品种冬春性、预测品种的抗寒性对黄淮南片冬麦区的小麦品种利用更具有指导意义.     

Genetic differentiation of hexaploid wheat inferred from analysis of microsatellite loci

Landraces of wheat can serve as important potential sources for extending the genetic basis of selection cultivars. Analysis of microsatellites and typing of polymorphism in a representative sample of 347 genotypes, including landraces and selection cultivars, was performed using a set of 38 selected oligonucleotide primer pairs. Each genotype had a unique allele combination at 39 microsatellite loci examined. Classification of genotypes with respect to the level of their similarity was performed using cluster analysis. The data obtained pointed to genetic differentiation of hexaploid wheat. The groups of cultivars, the formation of which was thought to be associated with the main old areas of wheat cultivation in Europe and Asia, were identified. The basis of each of the groups was formed by landraces of common wheat. The differences between the groups identified were associated with multiple changes in the wheat genome and were expressed as quantitative differences in the allele frequencies of microsatellite loci. The results of the study are of interest in terms of understanding the structure of wheat genetic diversity and revealing the pathways of evolution of this culture.     

Use of RAPD- and STS-analysis for marking genes of a homeologic group from chromosome 5 of common wheat

The search for STS (sequence-tagged site) and RAPD (random amplified polymorphic DNA) markers tightly linked to some genes of homeologous group 5 chromosomes of common wheat Triticum aestivum L., more specifically, awns inhibitor genes (B1), vernalization response gene (Vrn1), and homeologous chromosome pairing gene (Ph1), was conducted. To estimate the linkage of the gene with the marker, wheat lines marked with recessive alleles b1 and vrn1 were used. RELP (restriction fragment length polymorphism) and SSR (simple sequence repeat) analyses of isogenic wheat lines were conducted to characterize the chromosomal region transferred to the isogenic line from the donor parent. In RAPD analysis of isogenic wheat lines marked with recessive alleles b1 and vrn1, 95 arbitrary primers were used. To develop STS markers, analysis of the primary structure of RELP markers Xpsr426 and Xcdo504, tightly linked to the Vrn1 gene, and the Xpsr1201 marker, located at the Ph1 locus, was carried out. Two markers that are tightly linked to the Vrn1 gene (5AL)--RAPD marker Xr405 and STS marker Xsts426--were obtained in this work. In addition, there is every reason to believe that Xsts426 can be used as a PCR marker of genes Vrn2 (5BL) and Vrn3 (5DL), while Xsts1201, of the gene Ph1 (5BL).