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1.
Zhi-Wei Wang Lei Gao Hai Zhou Liu Shi Yong Mei Yuan Zhou Chang Ping Xiang Ting Wang 《Euphytica》2012,186(2):313-320
A male sterile plant appeared in the radish breeding program at the Hubei Academy of Agricultural Sciences, Hubei, China.
In its progeny, a two-type (half of plants male sterile, the other half male fertile) line 01GAB was established. An F2 population of 260 plants from a cross of male-sterile 01GAB and a male fertile line 9802H segregated for male fertility in
a 3:1 ratio indicating that fertility was restored by a single dominant gene, here designated RsMs. A PCR-based DNA marker specific to the male fertility Rfob gene in 9802H was absent in 01GAB. Linkage analysis placed the RsMs locus 10.7 cM away from the Rfo locus. In an F2 population of hybrids between 01GAB and male fertile 9802B, a co-dominant DNA marker for the RSultr3.2A (a radish sulfate transporter gene) locus was linked to the RsMs locus at 1.5 cM suggesting that fertility restoration in 01GAB was located in the region with known male sterility restorers
in radish. However, no maintainer for the 01GAB source of male sterility has been identified so far. Cytological observations
have shown that the abnormalities in male sterile anthers first appeared in tapetum at the tetrad stage, followed by a hypertrophy
of the tapetal cells at the vacuolate microspore period. These results suggest that male sterility in 01GAB is likely to be
genetic in nature, or it may represent a new type of the cytoplasmic male sterility. 相似文献
2.
Fine mapping of Rf2, a major locus controlling pollen fertility restoration in sorghum A1 cytoplasm,encodes a PPR gene and its validation through expression analysis 
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下载免费PDF全文 Praveen Madugula Anurag G. Uttam Vilas A. Tonapi Madhusudhana Ragimasalawada 《Plant Breeding》2018,137(2):148-161
Sorghum is one of the pioneering cereal crops where cytoplasmic male sterility (CMS) was successfully exploited for mass production of F1 hybrid seed. Mapping genes for fertility restoration (Rf) is an important aspect of understanding the molecular basis of fertility restoration in crop plants. In this study, we fine‐mapped a fertility restoration locus, Rf2 of sorghum reported earlier (Jordan, Mace, Henzell, Klein, & Klein, 2010 ), involving two F2 populations (296A × RS29 and 296A × DSV1) and newly developed SSR markers delimited Rf2 locus to 10.32‐kb region on chromosome 2. The Rf2 locus was tightly linked with two new SSRs, MS‐SB02‐3460 (0.14 cM) and MS‐SB02‐3466 (0.75 cM) on both sides, and hosted only one gene (Sobic.002G057050) of PPR gene family. Another new SSR marker developed in the study, MS‐SB02‐37912, forms the part of PPR gene and could act as a perfect marker in marker‐assisted breeding for fertility restoration involving Rf2 in sorghum breeding. The strong involvement of Sobic.002G057050 gene in fertility restoration was supported through RNA expression analysis. 相似文献
3.
油菜Nsa CMS候选恢复基因的来源及表达 总被引:1,自引:0,他引:1
根据同源序列法克隆的Nsa CMS候选恢复基因PPR618的序列,采用PCR方法在Nsa CMS不育系、恢复系、原始体细胞杂交亲本以及其他甘蓝型油菜品种中共克隆出22个同源序列。序列分析表明,野芥亲本野油18、甘蓝型油菜亲本中双4号各含有2个同源序列,而Nsa CMS 4个恢复系则分别含有3、1、1、1个同源序列。恢复系中候选恢复基因的序列与野芥亲本野油18的同源序列的一致性在93%以上,其中恢1、恢3和恢4中至少有一个同源序列与野油18的第一个同源序列完全相同,恢2中的同源序列与野油18的第2个同源序列完全相同;但与甘蓝型油菜的同源序列一致性均低于80%,说明候选恢复基因来源于新疆野芥,而不是甘蓝型油菜。除了原来的PPR618外,获得了3个来源于恢复系的新候选恢复基因。候选恢复基因在序列上与萝卜和矮牵牛的恢复基因一致性较高。半定量RT-PCR分析表明,候选恢复基因在恢复系中多个组织都有表达,但在根、茎中表达量特别少。随着营养器官到生殖器官的发育逐渐升高,候选恢复基因在恢复系中表达量最高的是雄性败育关键时期, 即1.5~2.5 mm的花蕾中,但不育系中的同源基因在茎中的表达量则相对高于其他组织。 相似文献
4.
Kyuhyun Kim Young-Pyo Lee Heerae Lim Taeho Han Soon-Kee Sung Sunggil Kim 《Euphytica》2010,175(1):79-90
Previously, novel cytoplasmic male-sterility (CMS) caused by DCGMS cytoplasm was discovered in radish (Raphanus sativus L.) introduced from Uzbekistan. We performed extensive progeny tests and identified two fertility restorer lines (‘R171’
and ‘R121’) for this new CMS. Two F1 hybrid populations were self-pollinated and backcrossed to produce F2 and BC populations. Inheritance patterns of male-sterility in segregating populations varied depending on paternal lines.
Segregation of male-sterility in F2 populations originating from the cross between MS19 and R121 showed that a single locus was involved in fertility restoration.
However, populations originating from the cross between MS15 and R171 showed the involvement of more than one restorer-of-fertility
genes. The single fertility restorer locus identified in the cross between MS19 and R121 was designated Rfd1 locus. Bulked segregant analysis was performed using RAPD and AFLP, which identified one marker each. Both RAPD and AFLP
markers were converted into simple PCR-based co-dominant markers after their isolated flanking sequences were analyzed. Indels
773-bp and 67-bp in length were identified between two Rfd1 allele-linked flanking sequences of the RAPD and AFLP fragments, respectively, then utilized to develop simple PCR markers.
In addition, we prove that the newly identified Rfd1 locus is independent of the Rfo locus, another radish fertility restorer for CMS caused by Ogura cytoplasm. 相似文献
5.
Shivakumar Shidenur Vikram Jeet Singh Kunnummal Kurungara Vinod Subbaiyan Gopala Krishnan Surendra Kumar Ghritlahre Haritha Bollinedi Ranjith K. Ellur Brijesh Kumar Dixit Binder Singh Mariappan Nagarajan Ashok Kumar Singh Prolay Kumar Bhowmick 《Plant Breeding》2019,138(5):553-567
Hybrid rice based on wild‐abortive cytoplasmic male sterility (WA‐CMS) is important in boosting rice production, which requires diverse parents to harness heterosis. For this, exploiting the diversity of japonica through tropical japonica (TRJ) lines is an excellent route. In this study, 310 TRJ‐based new plant type (NPT) lines were developed and evaluated for Rf3 and Rf4 genes. Gene‐based (DRRM‐Rf3‐5 and DRRM‐Rf3‐10) and functional marker (RMS‐SF21‐5) targeted Rf3 locus, while gene‐linked (RM6100) and functional marker (RMS‐PPR9‐1) targeted the Rf4 locus. The frequency of the restorer allele of Rf3 gene was lower when compared to that of Rf4. Combined phenotypic and molecular screening using gene‐based and functional markers identified 42 lines that carried Rf3 and/or Rf4 genes. All the selected lines produced fertile F1s when crossed to a WA‐CMS line, “Pusa 6A”, but with varying levels of spikelet fertility. This is the first report of a marker‐cum‐phenotype‐based restorer selection using TRJ‐derived lines. Multilocation evaluation of these lines at three locations indicated better adaptation for grain yield in some of the lines. 相似文献
6.
Inheritance and allelic relationships of fertility restoration genes for seven new sources of male-sterile cytoplasm in sunflower 总被引:2,自引:0,他引:2
The inheritance of fertility restoration of six mitomycin C and streptomycin‐induced cytoplasmic male‐sterile (cms) mutants and one cms line derived from Native American cultivar PI 432513 in sunflower was evaluated. These seven new cms sources were also compared with the commercially used cms PET1 (Helianthus petiolaris Nutt.) cytoplasm, using USDA inbred lines with restoration genes (Rf1) specific for cms PET1 and new restoration lines identified for cms PI 432513. Restoration genes for cms PI 432513 were found in ‘Armavir’, VNIIMK, P21 and male‐fertile (MF) plants of PI 432513. F2 and F3 segregation ratios of crosses between cms PI 432513 and these restoration sources indicated a single dominant gene controlled fertility restoration. Progenies of cms PI 432513 testcrossed with F1’s of half‐diallel crosses among the respective four homozygous restoration lines and RHA 274 suggested that the restoration genes of RHA 274, VNIIMK, P21 and PI 432513 were at the same locus. Restoration genes from VNIIMK, P21 and PI 432513 satisfactorily restored pollen stainability in the heterozygous condition. A very weak expression of the Rf gene in ‘Armavir’ was observed in the heterozygous condition. Fertility restoration capability of these genes for the six mutant cms HA 89 and cms HA 89 (in PET1 cytoplasm) was observed. The mutant cms HA 89 lines were also restored completely by RHA 266, RHA 274, RHA 280 and RHA 296, and F2’s segregation ratios indicated single dominant gene control, implying a common cytoplasmic male sterility in all lines. F1’s of half‐diallel crosses among RHA 266, RHA 273, RHA 274, RHA 280 and RHA 296 were testcrossed onto the cms lines, and their all MF progenies among lines, except RHA 280, confirmed that fertility restoration was controlled by a single Rf1 gene locus. The restoration gene in confection line RHA 280, namely Rf3, was at a different locus than Rf1 and was equally capable of restoring all the cms lines. Cms HA 89 mutants and cms PI 432513 are in H. annuus cytoplasm, and are agronomically equal in hybrid performance to the cms PET1 used in commercial sunflower hybrids. These new cms lines will provide immediate alternative cms sources for reducing the genetic vulnerability resulting from the exclusive use of the single cms source PET1 in sunflower hybrid production. 相似文献
7.
We report the development of an improved cytoplasmic male sterile (CMS) system of Brassica juncea carrying cytoplasm of the wild species Diplotaxis berthautii. Flowers of the CMS line are smaller than the euplasmic line but have improved nectaries. Anthers are slender and fail to
extend to the level of stigma. Female fertility of the CMS line is comparable to the euplasmic line. Fertility restorers of
Moricandia arvensis and D. catholica-based alloplasmic CMS systems of B. juncea were found capable of restoring male fertility to this new CMS line. The fertility restoration is monogenic and gametophytic.
Southern analysis showed that the cytoplasm of the CMS line is different from euplasmic B. juncea and other CMS systems restored by the same restorer lines. Northern analysis of the CMS, fertility restored and euplasmic
lines using eight mitochondrial gene probes revealed altered atpA expression associated with male sterility. Cleaved amplified polymorphic sequence (CAPS) markers were identified for the
plastid gene psbB, which could be useful for a quick identification of this CMS line.
S.R. Bhat and P. Kumar contributed equally to this work. 相似文献
8.
K. Mikolajczyk M. Dabert J. Nowakowska J. Podkowinski W. Poplawska I. Bartkowiak‐Broda 《Plant Breeding》2008,127(6):647-649
The Rfo fertility restorer gene for the Ogura cytoplasmic male sterility (CMS) applied for oilseed rape hybrid seed production can be monitored with the use of the RAPD OPC021150 marker while molecular breeding. The aim of this work was to convert the RAPD marker into a more suitable SCAR marker. Total DNA was isolated from a doubled haploid line derived from the line BO20 (INRA, France). A fragment of 1150‐bp linked to the Rfo gene was PCR amplified with the use of the RAPD OPC02 primer, cloned and sequenced. A pair of primers was designed and PCR amplification was performed to develop a SCAR marker for the Rfo gene. The new marker was applied for analysis of 220 oilseed rape lines comprising doubled haploid and inbred restorer lines, restored hybrids as well as F1 and F2 recombinant generations involving restorer lines. Simultaneously, the RAPD OPC02 marker was used and it revealed that the markers are equivalent to each other. However, the developed new SCAR marker has made the analysis more practical, rapid and efficient. 相似文献
9.
Comparison of two fertility restoration systems against photoperiod-sensitive cytoplasmic male sterility in wheat 总被引:2,自引:0,他引:2
K. Murai 《Plant Breeding》2002,121(4):363-365
A ‘two‐line system’ using photoperiod‐sensitive cytoplasmic male sterility (PCMS) caused by Aegilops crassa cytoplasm under a long‐day photoperiod ( 15 h) has been proposed as a new means of producing hybrid varieties in common wheat. The PCMS line is maintained by self‐pollination under short‐day conditions, and hybrid seeds can be produced through outcrossing of the PCMS line with a pollinator under long‐day conditions. Two kinds of fertility restoration systems against the PCMS are known. One is involved with a set of multiple fertility‐restoring (Rf) genes in the wheat cultivar ‘Norin 61’ located on (at least) chromosomes 4A, 1D, 3D and 5D. The other is controlled by a single dominant major Rf gene, Rfd1, located on the long arm of chromosome 7B in the wheat cultivar ‘Chinese Spring’. To examine the degree of fertility restoration by these two systems, nine PCMS lines were crossed with ‘Norin 61’ and ‘Chinese Spring’ as the restorer lines, and the F1 hybrids were investigated. The degree of fertility restoration was estimated by comparing the seed set rates in the F1 hybrids having the Ae. crassa cytoplasm and those with normal cytoplasm. The results revealed that the fertility restoration ability of a set of multiple Rf genes in ‘Norin 61’ was higher than that of the Rfd1 gene in ‘Chinese Spring’. 相似文献
10.
Summary Identification and location of fertility restoring genes facilitates their deployment in a hybrid breeding program involving cytoplasmic male sterility (CMS) system. The study aimed to locate fertility restorer genes of CMSWA system on specific chromosomes of rice using primary trisomics of IR36 (restorer), CMS (IR58025A) and maintainer (IR58025B) lines. Primary trisomic series (Triplo 1 to 12) was crossed as maternal parent with the maintainer line IR58025B. The selected trisomic and disomic F1 plants were testcrossed as male parents with the CMS line IR58025A. Plants in testcross families derived from disomic F1 plants (Group I crosses) were all diploid; however, in the testcross families derived from trisomic F1 plants (Group II crosses), some trisomic plants were observed. Diploid plants in all testcross families were analyzed for pollen fertility using 1% IKI stain. All testeross families from Group I crosses segregated in the ratio of 2 fertile: 1 partially fertile+partially sterile: 1 sterile plants indicating that fertility restoration was controlled by two independent dominant genes: one of the genes was stronger than the other. Testcross families from Group II crosses segregated in 2 fertile: 1 partially fertile+ partially sterile: 1 sterile plants in crosses involving Triplo 1, 4, 5, 6, 8, 9, 11 and 12, but families involving triplo 7 and triplo 10 showed significantly higher X2 values, indicating that the two fertility restorer genes were located on chromosome 7 and 10. Stronger restorer gene (Rf-WA-1) was located on chromosome 7 and weaker restorer gene (Rf-WA-2) was located on chromosome 10. These findings should facilitate tagging of these genes with molecular markers with the ultimate aim to practice marker-aided selection for fertility restoration ability. 相似文献
11.
Isolation and genetic characterization of a fertility-restoring revertant induced from cytoplasmic male sterile rice 总被引:2,自引:0,他引:2
Summary A male fertile revertant was isolated from M1 of a cytoplasmic male sterile indica rice line II-32A, the dry seeds of which were treated with 60Co- rays at a dose of 290 Gy. The acquired revertant T24 was morphologically and agronomically similar to II-32B, the maintainer of II-32A. Testcrosses of the revertant with II-32A and Zhenshan 97A showed that the revertant was able to restore the fertility of CMS lines. Genetic analysis of the progenies between T24 and II-32A, Zhenshan 97A XieqingzaoA and DZhenshan 97A, which have different cytoplasms, showed that the fertility restoration of four CMS lines by T24 involved one nuclear gene, indicating that T24 was a result of the mutation of one nuclear gene. The mechanism of the restoration of CMS line by T24 was obviously different from other restorers such as Minghui 63 and 20964, which were shown to behave in two gene mode in fertility restoration. The discovery of the revertant T24 contributes to the understanding of CMS and fertility restoration of CMS in rice. The T24 and its parent II-32A may constitute a pair of near isogenic lines for the restoring gene, which should be valuable materials for molecular genetic analysis of CMS. 相似文献
12.
Cytoplasmic male‐sterile (CMS) lines are being used to produce hybrid seeds. Thus far, four CMS sources in soybean [Glycine max (L.) Merr.] have been reported in China. However, they are not sufficient or efficient in meeting the requirements of commercial soybean hybrid seed production. In this study, 33 varieties were tested for CMS using 45 crosses among 37 landraces and 17 annual wild soybean accessions (Glycine soja Sieb. et Zucc.). The cross of N23661 × N23658 showed partial to complete male sterility in backcross generations, while the corresponding reciprocal cross showed normal male fertility. Thus, the cytoplasm of N23661 is male‐sterile, the continuously backcrossed line is a male‐sterile line (designated NJCMS4A), and N23658 is its maintainer (designated NJCM4B). The male fertility of NJCMS4A was restored by another accession, Nansheng9403. Accordingly, NJCMS4A along with its maintainer and restorer composes a complete set of three lines for producing hybrid soybean. Using mitochondrial markers and sequence analyses, NJCMS4A is a CMS line with its cytoplasm not identical to the four previously reported CMS sources in soybean. 相似文献
13.
The restorer gene for soybean M‐type cytoplasmic male sterility,Rf‐m,is located in a PPR gene‐rich region on chromosome 16 下载免费PDF全文
下载免费PDF全文 Dagang Wang Lei Zhang Jiekun Li Guoyu Hu Qian Wu Haiyan Jiang Zhiping Huang 《Plant Breeding》2016,135(3):342-348
Over the past decade, M‐type cytoplasmic male sterility (CMS) line W931A and a variety of restorer lines have been exploited for the release of hybrid seeds in soybean (Glycine max). However, the identities of restorer genes in the nuclei of soybean restorer lines are still unclear. In this study, we analysed the inheritance pattern of restorer locus Rf‐m from restorer line WR016 and constructed a high‐resolution map of this locus. Results showed that Rf‐m in WR016 is a monogenic dominant gene located within a 162.4‐kb region on chromosome 16, which is flanked on each side by new developed simple sequence repeat (SSR) markers GmSSR1602 and GmSSR1610 at a distance of 0.11 and 0.25 cM, respectively. Nineteen open reading frames (ORFs) were predicted in this region. Of these, seven genes arranged in tandem on chromosome 16 encode pentatricopeptide repeat (PPR) proteins, which is similar to other reported restorer loci in plants. These results lay a solid foundation for map‐based cloning of the Rf‐m gene and will be helpful for marker‐assisted selection of elite CMS restorer lines. 相似文献
14.
Summary Ten cytoplasmic male sterile (CMS) sunflower (Helianthus annuus L.) lines were crossed with nine maintainer or male fertility restorer lines in a diallel crossing scheme. Based on fertility restoration of the F1 generation, CMS lines were divided into four groups. At least two new sources of CMS, CMS PET2 and CMS GIG1, were found to be potentially useful for commercial production of hybrids. Environment had an influence on fertility restoration of one CMS line, CMS MAX1. Effective restoration of male fertility for CMS RIG1, CMS ANN2, and CMS ANN3 was not found. 相似文献
15.
小麦K型不育系育性恢复基因的遗传分析 总被引:6,自引:0,他引:6
选用K型不育系豫麦3号、S43及其相应的保持系,与恢复系豫麦2号和豫麦49组配了不育系//保持系/恢复系、不育系//不育系/恢复系和不育系/恢复系//保持系三种回交群体,对小麦K型不育系育性恢复基因进行了遗传分析。结果表明,不同恢复力的恢复系携带的恢复基因对数不同,恢复力较强的豫麦2号携带2对主效基因,恢复力较低的豫麦49仅携带1对主效基因。此外,还有微效基因对育性恢复起作用,这种基因不仅存在于恢复系中,也存在于不育系(保持系)中。在K型细胞质背景下,不携带恢复基因的雄配子的传递率很低,而雌配子传递正常。 相似文献
16.
发掘水稻新型雄性不育细胞质源CMS-FA,育成系列优质米不育系和系列新质源恢复系,组配成强优势杂交稻组合的基础上研究新质源雄性不育恢复系的恢复基因遗传。采用新质源(CMS-FA)不育系金农1A与恢复系金恢3号杂交获得杂交F1代种子,种植F1代,收获自交F2代种子。用F1分别与不育系或保持系回交,获得(不育系//不育系/恢复系和不育系/恢复系//保持系)2个测交群体。同时种植P1、P2、F1、F2、B1F1和B2F1等群体,考察花粉染色率、套袋结实率和自然结实率,卡平方测验遗传分离适合度。结果表明,不育系与恢复系杂交F1代正常可育,育性恢复(可育)基因为显性遗传。F2代分离出可育︰不育适合3︰1,育性恢复(可育)基因为1对显性基因控制。B1F1和B2F1代2个测交群体的可育︰不育都适合1︰1分离规律,验证了F2代育性恢复(可育)单基因的遗传模式。暂时确定新质源(CMS-FA)核质互作三系的基因型为不育系S(SS)、保持系F(SS)和恢复系S(FF)。 相似文献
17.
Y. S. Sodhi A. K. Pradhan J. K. Verma N. Arumugam A. Mukhopadhyay D. Pental 《Plant Breeding》1994,112(3):223-227
Eighteen genotypes of Brassica napus were crossed to a cytoplasmic male sterile (CMS) line of B. napus BO 15 carrying B. tournefortii cytoplasm (‘tour’ cytoplasm). Fourteen genotypes were found to be stable maintainers of the ‘tour’ CMS. Of the remaining four genotypes, GSL-1 and ‘Asahi-natane’ were found to be heterozygous and ‘Mangun’ and ‘Yudal’ were homozygous for the restorer gene. Analysis of the F1 and F2 progenies of (CMS) BO 15 בMangun’ and (CMS) BO 15 בYudal’ showed that fertility restoration is controlled by a single dominant gene. The availability of a number of stable maintainer lines and the simple inheritance pattern of fertility restorer gene makes ‘tour’ CMS a useful system for hybrid seed production in rapeseed. 相似文献
18.
两套粳稻雄性不育系(A)及其保持系(B)分别与宁恢3-2(R)杂交、回交、自交、获得两个组合的 F_1(A/R)、B_2(A//A/R)、B_2′(A//B/R)、F_2和 F_3,以花粉育性和种子育性作为恢复度指标,研究宁恢3-2育性恢复力的遗传。 结果表明,BT 六千辛 A 和 L 平壤3号 A的花粉以染败为主,在光学显微镜下不易区分分离世代植株中可育和不育花粉,故不宜用花粉育性作为恢复度指标进行遗传分析。以种子育性为指标,发现两个不育系是配子体不育类型,宁恢3-2对它们的育性恢复力是由一对显性恢复基因控制的。 相似文献
19.
There are two cytoplasmic male sterility (CMS)‐systems in chives (Allium schoenoprasum L.), which can be employed in hybrid breeding. However, the probability for selection of maintainer genotypes from German open pollinated varieties is not known. Therefore, the allelic frequencies of the restorer genes X and T involved in CMS1 were determined in 12 German commercial chive varieties by test crossing single plants to male sterile, temperature‐insensitive genotypes [(S1)xxT] for segregation analyses of offspring. Temperature sensitive genotypes [(S1)xxT_] are able to produce pollen at higher temperatures, and should therefore be excluded from hybrid breeding to avoid self‐pollination of the maternal parent. The mean value of the frequency of the non‐restoring allele x in the populations examined was 0.62. The mean value of the allele t, which is responsible for the temperature insensitivity, was 0.9. As a consequence of these allelic frequencies about one‐third of all plants of the chive varieties examined were designated CMS1 maintainer genotypes, leading to the production of temperature insensitive male sterile lines. The incidence of CMS2 maintainers in the German varieties examined was nearly four times lower than CMS1 maintainers. The mean value of the frequency of the non‐restoring allele st2 involved in the CMS2‐system was 0.29. 相似文献