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1.
Due to the short growing season in the high northern latitudes, the development of early maturing spring wheat (Triticum aestivum L.) cultivars is important to avoid frost damage which can lower production and quality. We investigated earliness of flowering and maturity, and some associated agronomic traits, using a set of randomly selected high northern latitude adapted spring wheat cultivars (differing in maturity) and their F1 and F2 crosses made in a one-way diallel mating design. The parents, and their F1 and F2 crosses were evaluated under field conditions over 2 years. Anthesis and maturity times were controlled by both vernalization response and earliness per se genes, mainly acting additively. Non-additive genetic effects were more important in controlling grain fill duration, grain yield and plant height. Additive × additive epistatic effects were detected for all traits studied except time to anthesis. Segregation analyses of the F2 populations for time to anthesis indicated the presence of different vernalization response genes. Molecular genetic analyses revealed the presence of Vrn-A1 and Vrn-B1 genes in the parental cultivars. Narrow-sense heritability was medium to high (60–86%) for anthesis and maturity times but low to medium (13–55%) for grain fill duration, plant height and grain yield. Selection for early flowering/maturity in early segregating generations would be expected to result in genetic improvement towards earliness in high latitude spring wheats. Incorporation of the vernalization responsive gene Vrn-B1 in combination with vernalization non-responsive gene Vrn-A1 into spring wheats would aid in the development of early maturing cultivars with high grain yield potential for the high latitude wheat growing regions of the northern hemisphere.  相似文献   

2.
Ear emergence time and response to vernalization were investigated in 12 alien substitution lines in which a pair of chromosomes 5A of recipient spring wheat cultivars was replaced by a pair of chromosomes 5R of Siberian spring rye ‘Onokhoiskaya’. The recipients were 12 spring cultivars of common wheat, each carrying different Vrn genes. Spring rye ‘Onokhoiskaya’ had the Sp1 (now called Vrn-R1) gene for spring growth habit located on chromosome 5R, but its expression was weaker. The Vrn-R1 gene had no effect on growth habit, ear emergence time and response to vernalization in wheat-rye substitution lines. Ears emerged significantly later in the 5R(5A) alien substitution lines than in the recipient wheat cultivars with the Vrn-A1/Vrn-B1/vrn-D1 or Vrn-A1/vrn-B1/Vrn-D1 genotypes. No difference in ear emergence time was found between most of the 5R(5A) alien substitution lines and the cultivars carrying the recessive vrn-A1 gene. The presence of the Vrn2a and Vrn2b alleles at the Vrn2 (now called Vrn-B1) locus located on wheat chromosome 5B was confirmed.The replacement of chromosome 5A by chromosome 5R in wheat cultivars ‘Rang’ and ‘Mironovskaya Krupnozernaya’, which carries the single dominant gene Vrn-A1, converted them to winter growth habit. In field studies near Novosibirsk the winter hardiness of 5R(5A) wheat–rye substitution lines of ‘Rang’ and ‘Mironovskaya Krupnozernaya’ was increased by 20–47% and 27–34%, respectively, over the recurrent parents.  相似文献   

3.
孙道杰  冯毅  王辉  闵东红  李学军 《作物学报》2008,34(11):1953-1957
春化基因VRN-B3是小麦开花素基因TaFT,为探索该基因在品种间的保守性及其与小麦开花早晚的关系,根据TaFT基因序列(GenBank accession No.: DQ890162)设计特异PCR引物,扩增了13个品种中该基因的编码区。通过测序和序列比对,发现不同品种间该基因编码区的DNA序列存在多态性,序列翻译发现5个品种的表达产物FT蛋白发生变异。利用中国春的非整倍体材料将TaFT基因定位在7BS染色体上。参考品种的冬春性及开花时间,推测冬性品种正常的FT蛋白(同DQ890162翻译的氨基酸序列一致)可加速开花,FT蛋白变异则延迟开花;春性品种的FT蛋白变异与否对开花期影响不大,推测TaFT基因的效应可能被春性品种的显性春化基因所掩盖。  相似文献   

4.
M. Ahmad  Mark E. Sorrells 《Euphytica》2002,123(2):235-240
A wheat microsatellite locus, Xgwm 261, whose 192-bp allele closelylinked to the dwarfing gene Rht8, on chromosome 2D, was used toscreen 71 wheat cultivars from 13 countries to assess the variation at thislocus. Screening of this wheat collection showed that a 165-bp allele anda 174-bp allele were the most frequent. None of the New Zealand cultivarspossessed a 192-bp allele specific to Rht8, while only one cultivarfrom the US produced this important allele. The frequency of a 192-bpallele among these wheat cultivars was 5.63%. The highest allelefrequency was observed for a 174-bp fragment (52.11%) followed by a165-bp fragment (26.76%). The only durum wheat `Cham 1', did notshow any amplification due to the absence of D genome. Four new novelalleles, 180-bp, 198-bp, 200-bp and 204-bp present in the US and NewZealand wheat cultivars are reported.  相似文献   

5.
Understanding the genetic factors governing developmental patterns and flowering time in breeding materials is required for the development of new wheat varieties for a specific environment. Iran is among the largest wheat producers in the arid and semi-arid regions of the Middle East and North Africa. The wheat germplasm grown in Iran is either developed nationally or is introduced from the CIMMYT global wheat program. For decades, the wheat breeding program in Iran focused on generating new varieties better able to grow in the predominant Iranian climatic conditions such as humidity at the reproductive stage, high temperature during reproductive stages (terminal heat stress), moderate temperature during the cropping season, and high probability of frost damage during early stages of growth. There have also been sub-programs aimed at developing drought and salinity-tolerant wheat cultivars in Iran. Knowledge of cultivars’ growth habits in Iran is currently limited to flowering in spring-sown nurseries. We identified allelic diversity in loci involved in vernalization response (Vrn) and photoperiod sensitivity (Ppd) in 60 bread wheat cultivars developed in Iran, CIMMYT, or ICARDA. This study revealed that the spring growth habit observed in most of the cultivars is conferred by a combination of recessive vrn-A1 and dominant Vrn-D1, Vrn-B1, and/or Vrn-B3 loci. This implies that most of the cultivars have minimal vernalization requirements for overwintering. Perhaps cold winters, even in the southern regions of Iran, provide sufficient vernalization conditions for cultivars possessing the recessive vrn-A1 allele. The germplasm investigated in this study revealed no evidence indicating selection for or against any specific Vrn and Ppd allele in our wheat breeding program.  相似文献   

6.
用STS标记检测春化基因Vrn-A1在中国小麦中的分布   总被引:2,自引:1,他引:1  
张晓科  夏先春  何中虎  周阳 《作物学报》2006,32(7):1038-1043
在证实Vrn-A1春化基因的STS标记与CAPS标记结果一致的基础上,用STS标记检测了全国主要麦区历史上大面积推广和当前主栽的250份品种的春化基因Vrn-A1。结果表明,中国品种Vrn-A1基因平均分布频率为36.8%,不同麦区的分布频率不同,依次为东北春麦区=北部春麦区=西北春麦区(100%)>新疆冬春麦区(42.9%)>西南冬麦区(35.3%)>黄淮冬麦区(19.8%)>长江中下游冬麦区(17.4%)>北部冬麦区(3.0%),这与冬春特性有关。在长江中下游冬麦区和西南冬麦区品种中,Vrn-A1基因分布频率随着时间推移呈降低趋势;在黄淮冬麦区品种中,20世纪50到70年代呈上升趋势,随后呈下降趋势。在年最大推广面积大于66.7万hm2的58份品种中,Vrn-A1基因的频率为27.6%。这些信息有助于改良小麦品种的适应性和提高产量潜力。  相似文献   

7.
N. Watanabe  S.F. Koval 《Euphytica》2003,129(3):259-265
The chlorophyll a:b ratio of chlorina mutants is much higher than that of wild type plants. Physical mapping of the chlorina mutant loci (cn-A1, cn-B1 and cn-D1) of common wheat (Triticum aestivum L.) and durum wheat (T. turgidum L.) was carried out with partial deletion lines of Chinese Spring(CS) of the long arms of homoeologous group7 chromosomes. F1 plants of partial deletion lines with near-isogenic lines (ANK-32A and ANK-32B) of the spring bread wheat Novosibirskaya 67 and a near-isogenicline of durum wheat LD222, ANW-7B were evaluated for chlorophyll a:b ratio of the leaves. Hemizygous and heterozygous plants were more easily distinguished by chlorophyll a:b ratio than by visual observation. The dose effects of the chlorina loci on chlorophyll a:b ratio were also confirmed. The position of the allele on the chromosome was localized by fraction length, the comparative values between whole chromosome and partially deleted chromosome. The locus cn-A1 was localized on the region of 83% distal from the centromere on the long arm of chromosome 7A, cn-B1 locus was localized on the region between 69% and 78% distal from the centromere on the long arm of chromosome 7B, and cn-D1 locus was localized on the region between 76% and 77% distal from the centromere on the long arm of chromosome 7D. We consider the map derived by deletion mapping is more accurate than the map calculated from recombination frequency. This revised version was published online in July 2006 with corrections to the Cover Date.  相似文献   

8.
Bulgarian common wheat cultivars released in the period 1925–2003 were studied using the gibberellic acid (GA) test and microsatellite analysis of the Xgwm261 locus on chromosome 2DS to identify the semi-dwarfing (Rht) genes. The old cultivars, isolated through selection from landraces, carried rare alleles (211- and 215-bp) at Xgwm261 locus, and those developed by hybridisation to foreign cultivars, carried the 165- and 174-bp alleles. Forty-two (55.3%) of 76 modern cultivars were GA-responsive. The 192-bp allele, diagnostic for Rht8, was observed in 64 (84.2%) modern cultivars, of which 37 carry Rht8 alone, and 27 possess a combination of Rht8 and a GA-insensitive allele viz. Rht-B1d (17); Rht-D1b (6) and Rht-B1b (4). The 174-bp allele is present in seven cultivars, only one of which is photoperiod-sensitive, and the rest are day-length insensitive. The 203-bp allele was found in six modern cultivars. Cultivars carrying the Rht8 allele are the most widespread and some of them have been cultivated for a long period. Cultivars with the `Saitama 27' allele (Rht-B1d) are the most productive and are second in distribution in the country. The recently observed trend for increasing the proportion of cultivars with GA-insensitive Rht genes is probably due to their combination with the 192-bp allele of Xgwm261 locus tightly linked to the Ppd-D1, to the break of the link between the 174-bp allele and ppd-D1, and to the introduction of other genes influencing flowering time.  相似文献   

9.
Summary In order to obtain high levels of environmental adaptability in wheat varieties it is essential they flower at times appropriate to particular environmental conditions. The influence of three distinct genetic systems that together determine time of flowering is reviewed here.Vernalization genes are seen to be particularly important to winter wheats for their direct or indirect effects on winter hardiness. Vernalization genes play a minor role in determining flowering time in autumn sown winter wheats but insensitivity is essential if spring sown wheats are to flower.Day length sensitive photoperiod genes play a major role in determining flowering time and adaptability of autumn sown wheats. Insensitivity can promote yield advantages of over 35% in Southern European environments. 15% in Central Europe and offers benefits even in the UK. At present only a single allele of Ppd1 appears to have been introduced into commercial European wheat varieties. The merits of alternative Ppd1 alleles or different loci are discussed.The influence of earliness per se genes that determine flowering time independently of environmental stimuli is less well documented than the effect of photoperiod and vernalization genes. It is likely that genes on chromosomes belonging to groups 2, 3, 4, 6 and 7 may act to modify flowering time independently of environmental stimuli probably by determining numbers of vegetative and floral primordia being initiated or the rate of initiation of the primordia. Earliness per se genes appear to be widespread in European wheats and play a significant role in determining the exact time plants flower.  相似文献   

10.
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11.
Producing higher yields under organic conditions is generally hampered by weeds and lesser nutrient supply. In wheat certain adaptive traits like early season vigour, taller plants, and shorter life cycle have been reported to help plants compete with weeds and produce satisfactory yields. In this experiment we tested the hypothesis ‘that early flowering and maturity conferred by insensitive vernalization alleles Vrn-A1a and/or Vrn-B1 has a yield advantage under organic conditions’ in Canadian spring wheat germplasm. We genotyped 32 cultivars for their vernalization gene composition (Vrn-A1a, Vrn-B1 and Vrn-D1) and studied these cultivars in organic and conventional management systems. We found 88 % of the cultivars possessed vernalization (Vrn) insensitive allele Vrn-A1a either alone or in combination with Vrn-B1. There were no differential affects between the cultivars having insensitive Vrn allele at either single locus (Vrn-A1a) or two (Vrn-A1a, Vrn-B1) under organic and conventional field conditions; except for days to maturity, where cultivars having only Vrn-A1a allele matured earlier. This earlier maturity did not translate to any yield advantage under organic field conditions. Overall, the cultivars grown under organic conditions were earlier flowering, lower yielding with lower test weight compared to the conventional management system. Significant cultivar × environment interactions were found for grain yield, grain protein content and grain fill rate. For grain protein content, cross-over interactions of the cultivars between the management systems were observed. Three cultivars (Marquis, Unity and Minnedosa) exhibited minimal comparative loss in grain yield and grain protein content under organic field conditions, and hence could potentially serve as parents for organic wheat breeding programs.  相似文献   

12.
In beet production, flowering is an undesirable trait which drastically reduces yield. BOLTING TIME CONTROL 1 (BTC1) and BvBBX19 are major floral regulators in beet. Their proteins have been suggested to interact to jointly regulate their downstream targets BvFT1 and BvFT2. Annual and biennial BTC1 haplotypes differ by six non‐synonymous SNPs and a large insertion in the promoter of the biennial btc1 allele. We describe a new BTC1 allele which displays three nucleotide polymorphisms in the coding sequence and an 8‐bp insertion in the promoter region compared to the annual BTC1d allele. The protein lacks a low‐complexity region, which likely alters its suggested ability to bind BvBBX19. Our findings demonstrate that little sequence variation in BTC1 is sufficient to turn an annual into a biennial genotype. Our results shed new light on the evolution of cultivated beets, and the identified btc1l allele offers new possibilities to breed winter beets.  相似文献   

13.
Wheat landraces carry abundant genetic variation in heading and flowering times. Here, we studied flowering-related traits of two Nepalese varieties, KU-4770 and KU-180 and a Japanese wheat cultivar, Shiroganekomugi (SGK). These three wheat varieties showed similar flowering time in a common garden experiment. In total, five significant quantitative trait loci (QTLs) for three examined traits, the heading, flowering and maturation times, were detected using an F2 population of SGK/KU-4770. The QTLs were found at the Ppd-1 loci on chromosomes 2B and 2D and the 2B QTL was also confirmed in another F2 population of SGK/KU-180. The Ppd-D1 allele from SGK and the Ppd-B1 alleles from the two Nepalese varieties might be causal for early-flowering phenotype. The SGK Ppd-D1 allele contained a 2-kb deletion in the 5′ upstream region, indicating a photoperiod-insensitive Ppd-D1a allele. Real-time PCR analysis estimating the Ppd-B1 copy number revealed that the two Nepalese varieties included two intact Ppd-B1 copies, putatively resulting in photoperiod insensitivity and an early-flowering phenotype. The two photoperiod-insensitive Ppd-1 homoeoalleles could independently contribute to segregation of early-flowering individuals in the two F2 populations. Therefore, wheat landraces are genetic resources for discovery of alleles useful for improving wheat heading or flowering times.  相似文献   

14.
Based on studies of the distribution of alleles at the important Rht and Ppd loci on wheat chromosomes 4B, 4D and 2D, different groups of winter wheat cultivars registered in the Czech and Slovak Republics during the period 1976–2007 were examined for a range of agronomic traits using official data from multi-location trials. Significant variation for all traits was detected among and between genotype groups. The frequent introduction of ‘Rht-D1b’ cultivars from the UK and Western Europe to the Czech Republic since 1995 has positively influenced lodging resistance and undoubtedly also yielding ability, but negatively affected winter-hardiness and bread making quality. An improved opportunity for earlier flowering cultivars with high winter-hardiness levels, in combination with high bread-making quality, can be obtained with genotypes carrying the Xgwm261 allele 192-bp that is probably indicative of the presence of Rht8. While GA insensitive Rht genes caused approximately a 10 cm reduction of plant height, the 192-bp allele at Xgwm261 was not associated, in these conditions, with a significant reduction in plant height when compared to Xgwm261 alleles 165- and 174-bp. Likewise, the photoperiod insensitive allele Ppd-D1a did not have a significant effect on plant height and it had not adversely affected other characters. Later heading genotypes carrying Xgwm261 alleles174- and 165-bp, often in combination with Ppd-D1b, could probably guarantee broader adaptability, which is highly desirable for changeable weather conditions. While the presence of the 192-bp allele was clearly associated with suitability for cultivation in the warmer maize growing regions, this was not so obvious for Ppd-D1a, particularly when combined with the 174-bp allele. GA responsive genes did not, apparently, influence adaptability to the different growing conditions. These studies reveal that there were both shortcomings and benefits attributable to the use of germplasm from different origins when introducing Rht and Ppd alleles. These results should be helpful to breeders in optimizing the choice of parents for crossing, and selection strategy in these target environments.  相似文献   

15.
In wheat, the transition from the vegetative to reproductive stage is primarily controlled by the series of vernalisation (Vrn-1) genes located on the homoeologous group 5 chromosomes. Up to 2009, only two alleles at the Vrn-B1 locus were known: one dominant, spring, allele (now designated Vrn-B1a) and the other recessive, winter, (vrn-B1) allele. Recently, two additional dominant alleles, Vrn-B1b and Vrn-B1c, were described. In this study, we screened a range of hexaploid spring wheat germplasms for the presence of different Vrn-B1 alleles using new diagnostic molecular markers. Our results show that the Vrn-B1a allele was the most prevalent, being present in 55.3 % of the 2,495 accessions examined, followed by the recessive vrn-B1 allele, which occurred in 31.5 % of the accessions. The novel alleles Vrn-B1b and Vrn-B1c were found in 5.3 and 7.9 % of all accessions, respectively.  相似文献   

16.
孙道杰  冯毅  王辉  闵东红  李学军 《作物学报》2008,34(11):1953-1957
春化基因VRN-B3是小麦开花素基因TaFT,为探索该基因在品种间的保守性及其与小麦开花早晚的关系,根据TaFT基因序列(GenBank accession No.: DQ890162)设计特异PCR引物,扩增了13个品种中该基因的编码区。通过测序和序列比对,发现不同品种间该基因编码区的DNA序列存在多态性,序列翻译发现5个品种的表达产物FT蛋白发生变异。利用中国春的非整倍体材料将TaFT基因定位在7BS染色体上。参考品种的冬春性及开花时间,推测冬性品种正常的FT蛋白(同DQ890162翻译的氨基酸序列一致)可加速开花,FT蛋白变异则延迟开花;春性品种的FT蛋白变异与否对开花期影响不大,推测TaFT基因的效应可能被春性品种的显性春化基因所掩盖。  相似文献   

17.
H. H. Bi  Y. W. Sun  Y. G. Xiao  L. Q. Xia 《Euphytica》2014,195(2):197-207
Pre-harvest sprouting (PHS) of wheat greatly reduces the quality and economic value of grain, and PHS resistance is one of the most important traits in wheat breeding. Red-grained wheat varieties are generally more resistant to PHS than white-grained ones; however, some are still susceptible. The red pigment of red-grained wheat is synthesized through the flavonoid biosynthetic pathway, in which the dihydroflavonol-4-reductase gene (DFR) is one of the genes involved in anthocyanin synthesis. In this study, a set of 120 red-grained Chinese wheat cultivars and lines with distinct PHS resistance were used to characterize TaDFR genotype variations and their association with PHS resistance. Whereas no variation or functional variation of TaDFR genes was detected on chromosomes 3A and 3D, a novel TaDFR allele, designated TaDFR-Bb, was explored on chromosome 3B. Compared with TaDFR-Ba, an 8 bp insertion (CTCTAGGA) was identified in the promoter region of TaDFR-B in most of the PHS resistant red-grained wheat varieties and advanced lines. Based on this, a CAPS marker was designed and validated with a set of Chinese red-grained wheat cultivars and lines with distinct PHS resistance. In most cases, TaDFR-Bb was associated with higher PHS resistance. An association study indicated that wheat varieties with the 8 bp insertion (average seed germination index 23.6 %) were significantly more resistant (P < 0.01) to PHS than those without the insertion (average seed germination index 69.5 %). Further study on gene expression demonstrated that the insertion led to increased TaDFR-B expression in cultivars with PHS resistance. Transient expression of TaDFR-B in coleoptiles of wheat cv. Chinese Spring revealed that increasing TaDFR gene expression did not induce the synthesis of anthocyanins.  相似文献   

18.
Photoperiod response is of great importance for optimal adaptation of bread wheat cultivars to specific environments, and variation is commonly associated with allelic differences at the Ppd-D1 locus on chromosome 2D. A total of 926 Chinese wheat landraces and improved cultivars collected from nine wheat growing zones were tested for their genotypes at the Ppd-D1 locus using allele-specific markers. The average frequency of the photoperiod-insensitive Ppd-D1a allele was 66.0%, with the frequencies of 38.6 and 90.6% in landraces and improved cultivars, respectively. However, the Ppd-D1a allele was present in all improved cultivars released after 1970 except for spring wheats in high latitude northwestern China, and winter wheats in Gansu and Xinjiang. The presence of the Ppd-D1a allele in landraces and improved cultivars increased gradually from north to south, illustrating the relationship between photoperiod response and environment. Ppd-D1a in Chinese wheats is derived from three sources, Japanese landrace Akagomughi and Chinese landraces Mazhamai and Youzimai. The current information is important for understanding the broad adaptation of improved Chinese wheat cultivars. F. P. Yang and X. K. Zhang contributed equally to this work.  相似文献   

19.
中国主要小麦品种春化基因的STS标记鉴定   总被引:2,自引:0,他引:2  
本文选取来自中国各麦区的260份小麦品种,用STS标记对其Vrn-A1、Vrn-B1、Vrn-D1和Vrn-B3四个春化基因位点进行检测,并结合小麦田间生长情况记录,探讨春化基因的4个位点显隐性情况对品种冬春性的影响.结果表明,各位点显性基因频率以Vrn-D1位点最高,而Vrn-A1和Vrn-B1显性等位基因对品种冬春性的影响高于Vrn-D1和Vrn-B3基因,且所含显性春化基因越多的品种生长习性越偏向春性.另发现,Vrn-A1仅存在于春性品种中;而对于冬性品种来说,各位点均不含显性春化基因.本文标记鉴定结果与田间冬春性观察具有较高的一致性,在小麦育种及品种推广中具有较高的指导意义和应用价值.  相似文献   

20.
The Ppd-A1 genotype of 240 Japanese wheat cultivars and 40 foreign cultivars was determined using a PCR-based method. Among Japanese cultivars, only 12 cultivars, all of which were Hokkaido winter wheat, carried the Ppd-A1a allele, while this allele was not found in Hokkaido spring wheat cultivars or Tohoku-Kyushu cultivars. Cultivars with a photoperiod-insensitive allele headed 6.9–9.8 days earlier in Kanto and 2.5 days earlier in Hokkaido than photoperiod-sensitive cultivars. The lower effect of photoperiod-insensitive alleles observed in Hokkaido could be due to the longer day-length at the spike formation stage compared with that in Kanto. Pedigree analysis showed that ‘Purple Straw’ and ‘Tohoku 118’ were donors of Ppd-A1a and Ppd-D1a in Hokkaido wheat cultivars, respectively. Wheat cultivars recently developed in Hokkaido carry photoperiod-insensitive alleles at a high frequency. For efficient utilization of Ppd-1 alleles in the Hokkaido wheat-breeding program, the effect of Ppd-1 on growth pattern and grain yield should be investigated. Ppd-A1a may be useful as a unique gene source for fine tuning the heading time in the Tohoku-Kyushu region since the effect of Ppd-A1a on photoperiod insensitivity appears to differ from the effect of Ppd-B1a and Ppd-D1a.  相似文献   

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