红莲型杂交稻(红莲2号)及其骨干亲本的RAPD分析与鉴定

利用RAPD技术,从248个随机寡核苷酸引物（10－mer）中筛出18个引物对红莲型杂交稻组合红莲2号及其亲本（T－07A、T－07B、YD6－05）,另6个红莲型胞质不育系的骨干恢复和汕优63及其亲本共14份水稻材料进行分析。共检测到173个多态性标记。聚类分析结果表明：不育系与保持系间因核背景相似,遗传差异很小;杂种（F1）的基因型更倾向于恢复系;恢复系与保持系间遗传距离的相对较大,但各恢复系之间的遗传距离较小。利用这些标记能有效地地区交组合中不育系,保持系、恢复系和杂种（F1）。     

基因工程培育可恢复的植物雄性不育系的研究进展

植物雄性不育是植物杂种优势利用的资源, 具有重要的生产利用价值。植物雄性不育可从自然突变、人工诱变和远缘杂交中发现, 现在可通过细胞工程和基因工程等方法来创造。文章综述了利用基因工程方法制备雄性不育品系及其相应的育性恢复策略, 分为“单组分策略”和“双组分策略”。其中利用“单组分策略”制备的不育植株是条件型雄性不育(可逆转的雄性不育), 它能在特定的条件下实现雄性可育与不育的转换, 实践中可直接作为两用系(不育系和保持系)用于两系法杂交制种; “双组分策略”是利用基因互作和亲本杂交直接培育雄性不育系, 或利用基因互作原理分别研制不育系和恢复系, 用于三系法生产杂交种。文章分析了 “单组分策略”和“双组分策略”的基因工程方法培育雄性不育系及其相应育性恢复策略优缺点, 对以上两种技术路线在实际应用中的现状作了分析和展望。     

红麻UG93细胞质雄性不育系、保持系及恢复系间的遗传多样性分析

利用8条核基因组ISSR引物和7对叶绿体基因组SSR引物(cpSSR),对9对红麻UG93细胞质雄性不育系/保持系及5个恢复系的细胞核、细胞质遗传多样性进行分析.结果表明:各材料的核基因组遗传相似系数在0.333～1.000之间,其中保持系间、保持系和恢复系间、恢复系间的平均相似系数分别为0.583、0.689和0.8...     

叶用芥菜细胞质雄性不育系0912A的胞质效应和杂种优势分析

通过异地多代的育性鉴定及花器形态观察来调查叶用芥菜细胞质雄性不育系0912A的不育性及结籽能力;同时分别以不育系0912A和其保持系0912B为母本,与5个典型叶用芥菜自交系配成10个同核异质的杂交种,以研究hau胞质的胞质效应并测定杂种优势.结果显示:该不育系败育彻底稳定,不育株率和不育度均为100％,有正常的结籽能力;不育系杂种一代与产最相关性状的杂种优势明显,但品质性状无优势;hau胞质在单株重上的负效应较明显,在其他性状上的负效应相对较弱,但hau胞质组合F1的单株重杂种优势依然显著,且胞质效应受杂交父本核影响,通过选择合适的杂交父本配组,细胞质的负效应可以减轻或消除.     

主要作物光温敏核雄性不育基因的研究进展与应用*

光温敏核雄性不育系在不同的生态环境条件下可以实现一系两用,简化制种程序,是农作物杂交种子生产的一种重要资源。简要介绍了主要作物杂交种子生产方式,综述了水稻、小麦、玉米、谷子等作物光温敏核雄性不育系的研究进展以及在两系杂交种子生产上的应用,并探讨了光温敏核雄性不育系的应用前景。     

Deep re-sequencing of a widely used maintainer line of hybrid rice for discovery of DNA polymorphisms and evaluation of genetic diversity

Genetic diversity within parental lines of hybrid rice is the foundation of heterosis utilization and yield improvement. Previous studies have suggested that genetic diversity was narrow in cytoplasmic male sterile (CMS/A line) and restorer lines (R line) for Three-line hybrid rice. However, the genetic diversity within maintainer lines (B line), especially at a genome-wide scale, remains largely unknown. In the present study, we performed deep re-sequencing of the elite maintainer line V20B (Oryza sativa L. ssp. indica). We then compared the V20B sequence with the 93-11 (Oryza sativa L. ssp. indica) genome sequence. 112.1 × 106 paired-end reads (PE reads) were generated with approximately 30-fold sequencing depth. The V20B PE reads uniquely covered 87.6 % of the 93-11 genome sequence. Overall, a total of 660,778 single-nucleotide polymorphism (SNPs) and 266,301 insertions and deletions (InDels) were identified, yielding an average of 2.1 SNPs/kb and 0.8 InDels/kb. Genome-wide distribution of the SNPs and InDels was non-random, and variation-rich and variation-poor regions were identified in all chromosomes. A total of 20,562 non-synonymous SNPs spanning 8,854 genes were annotated. Our results identified DNA polymorphisms at the genome-wide scale and uncovered the high level of genetic diversity between V20B and 93-11. Our results proved that next-generation sequencing technologies can be powerful tools to study genome-wide DNA polymorphisms, to query genetic diversity, and to enable molecular improvement efforts with Three-line hybrid rice. Further, our results also indicated that 93-11 could be used as core germplasm for the improvement of wild-abortive CMS lines and the maintainer lines.     

A new fertility restorer locus linked closely to the Rfo locus for cytoplasmic male sterility in radish

In this study, we have investigated a new fertility restorer (Rf) locus for cytoplasmic male sterility (CMS) in radish. We have obtained a CMS-Rf system consisting of sterile line '9802A1', maintainer line '9802B1' and restorer line '9802H'. F(1) plants from cross between sterile line '9802A1' and restorer line '9802H' were all male fertile, self pollination of F(1) plants produced an F(2) segregating population consisting of 600 individuals. The segregating population was found to fit a segregation ratio 3:1 for male fertile and sterile types, indicating that male fertility is restored by a single dominant gene (termed Rfo2) in the CMS-Rf system. Based on the DNA sequence of Rfo/Rfk1 (AJ535623), just one full length gene in the sterile line '9802A1', in the restorer line '9802H' and in the male fertile line '2006H', was cloned, respectively. The three sequences correspond to the same gene with two alleles: Rfob in '9802H' and rfob in '9802A1' and '2006H'. These two alleles differ from Rfo/Rfk1 and rfk1 (AJ535624) alleles by two synonymous base substitutions, respectively. Based on the differences between the Rfob and rfob genes, one PCR-based marker was developed, and designated Marker 1, which is identical to the corresponding region of Rfob by sequence analysis. In the F(2) segregating population described above, the Marker 1 was present in 5 sterile plants and in 453 fertile plants, absent in 4 fertile plants and in 138 sterile plants, and was found to fit a segregation ratio 3:1 indicating that Rfob was single copy in '9802H'. Linkage analysis showed that the Rfo2 locus for our CMS-Rf system was distant from the Rfo locus by about 1.6 cM. The sterile line '9802A1' was pollinated by the male fertile line '2006H' and the resulting F(1) plants were all male fertile. These results indicated that the male fertility of radish CMS can be restored by a new Rf locus, which linked tightly to the Rfo locus.     

Transfer of wild abortive cytoplasmic male sterility through protoplast fusion in rice

Wild abortive cytoplasmic male sterility has been extensively used in hybrid seed production in the tropics. Using protoplast fusion between cytoplasmic male sterile and fertile maintainer lines; we report here, transfer of wild abortive cytoplasmic male sterility to the nuclear background of RCPL1-2C, an advance breeding line which also served as maintainer of this cytoplasm. In total, 27 putative cybrids between V20A and RCPL1-2C and 23 lines between V20A and V20B were recovered and all of them were sterile. DNA blots prepared from the mitochondrial DNA of the cybrid lines from both the sets were probed with orf155 that is known to exhibit polymorphism between the mitochondrial DNA of the male-sterile and fertile maintainer lines. Hybridization of orf155 to 1.3 kb HindIII-digested mitochondrial DNA fragment of the cybrids showed transfer of mitochondrial DNA from wild abortive cytoplasmic male-sterile line to the maintainers, viz. RCPL 1-2C and V20B. Expression of male sterility was confirmed by the presence of sterile pollen grains and the lack of seed setting due to selfing in all the cybrid lines. These cybrids, on crossing with respective fertile maintainers set seeds that in turn, produced sterile BC1 plants. DNA blots from HindIII-digested mitochondrial DNA of these BC1 plants when probed with orf155 again exhibited localization of orf155 in wild abortive cytoplasm-specific 1.3 kb HindIII-digested mitochondrial DNA fragments. This demonstrated that the cytoplasmic male sterility transferred through protoplast fusion retained intact female fertility and was inherited and expressed in BC1 plants. Fusion-derived CMS lines, on pollination with pollen grains from restorer, showed restoration of fertility in all the lines. The results demonstrate that protoplasts fusion can be used for transferring maternally inherited traits like cytoplasmic male sterility to the desired nuclear background which can, in turn, be used in hybrid seed production programme of rice in the tropical world.     

苎麻atp6和atp9基因的克隆表达及与细胞质雄性不育的相关性

摘要: 根据GenBank报道的双子叶植物线粒体atp6和atp9基因编码区保守序列设计简并引物, 通过PCR技术从苎麻细胞质雄性不育系、保持系和恢复系(简称“三系”) mtDNA中扩增目的基因片段, 发现所得序列开放阅读框虽不完整, 但与GenBank报道的其他植物线粒体atp6和atp9基因同源性分别高于94%和85%。采用DNA Walking步移法分别从3′端和5′端扩增两个基因片段的未知侧翼序列, 分离出完整的苎麻线粒体atp6和atp9基因, 包含了完整的开放阅读框。其中“三系”的atp6基因在mtDNA水平、转录和翻译调控水平、蛋白质水平上均无差异。不育系atp9基因在编码区3′端与保持系和恢复系相比存在若干个碱基的差异和缺失; RT-PCR分析还表明, 不育系atp9基因在现蕾期和盛花期的表达量很高。推测不育系atp9基因的结构变异和/或异常表达与苎麻细胞质雄性不育(CMS)的关系密切。     

水稻配子体、孢子体细胞质雄性不育系线粒体蛋白质的分析

利用SDS-聚丙烯酰胺凝胶电泳方法分析了水稻配子体细胞质雄性不育系粤泰A、保持系粤泰B、F_1代泰优2号、恢复系胜优2号和孢子体细胞质雄性不育系马协A、保持系马协B、F_1代马协63、恢复系明恢63及另一种孢子体细胞质雄性不育系珍汕97A、保持系珍汕97B、F_1代汕优63、恢复系明恢63黄化苗的线粒体蛋白质。结果表明,粤泰A、B、F_1、恢复系之间出现6条多肽带的差异,马协A、B、F_1、恢复系之间出现4条多肽带的差异,珍汕97A、B、F_1、恢复系之间出现2条多肽带的差异。     

A chimeric <Emphasis Type="Italic">Rfo</Emphasis> gene generated by intergenic recombination cosegregates with the fertility restorer phenotype for cytoplasmic male sterility in radish

In this work, we have identified a chimeric pentatricopeptide repeat (PPR)-encoding gene cosegregating with the fertility restorer phenotype for cytoplasmic male sterility (CMS) in radish. We have constructed a CMS-Rf system consisting of sterile line ‘9802A2’, maintainer line ‘9802B2’ and restorer line ‘2007H’. F₂ segregating population analysis indicated that male fertility is restored by a single dominant gene in the CMS-Rf system described above. A PPR gene named Rfoc was found in the restorer line ‘2007H’. It cosegregated with the fertility restorer in the F₂ segregating population which is composed of 613 fertile plants and 187 sterile plants. The Rfoc gene encodes a predicted protein 687 amino acids in length, comprising 16 PPR domains and with a putative mitochondrial targeting signal. Sequence alignment showed that recombination between the 5′ region of Rfob (EU163282) and the 3′ region of PPR24 (AY285675) resulted in Rfoc, indicating a recent unequal crossing-over event between Rfo and PPR24 loci at a distance of 5.5 kb. The sterile line ‘9802A2’ contains the rfob gene. In the F₂ population, Rfoc and rfob were observed to fit a segregation ratio 1:2:1 showing that Rfoc was allelic to Rfo. Previously we have reported that a fertile line ‘2006H’, which carries the recessive rfob gene, is able to restore the male fertility of CMS line ‘9802A1’ (Wang et al. in Theor Appl Genet 117:313–320, 2008). However, here when conducting a cross between the fertile line ‘2006H’ and CMS line ‘9802A2, the resulting plants were male sterile, which shows that sterile line ‘9802A2’ possesses a different nuclear background compared to ‘9802A1’. Based on these results, the genetic model of fertility restoration for radish CMS is also discussed.     

温度对双低两用核不育水稻96-5-2S与培矮64S育性的影响

在自然变温、人工控温及冷水灌溉条件下,比较研究了温度对双低两用核不育水稻96－5－2S与两用核不育水稻培矮64S育性影响的差异。结果表明：（1）当它们在雄性育性转换温敏感期1－12d平均自然日均温23.0-23.8℃的低温时,96－5－2S表现不良,套袋自交结实率为0,而培矮46S可育,套袋自交结实率为0．1％－4．5％;（2）在它们雄性育性转换温敏感期用22℃恒温处理5d,96－5－2S败育彻底,套袋自交结实率为0,而培矮64S可育,套袋自交结实率为10．7％;用17℃恒温处理6d,96－5－2S与培矮64S均可育,但96－5－2S套袋自交结实率（6．8％）显著高于培矮64S（2．5％）;（3）在它们雄性育性转换温和不同温度的冷水串灌15d,水深维持在20cm左右,当水温为22－22．5℃时,96－5－2S不育,结实率为0,而培矮64S可育,结实率为18．5％;当水温为19．5－21．5℃时,96－5－2S与培矮64S均可育,但96－5－2S结实率（2．5％－45．1％）显著或极显著低于培矮64S（50．4％－56．9％）以上结果说明：导致双低两用核不育水稻96－5－2S雄性不育的起点温度与导致其生理不育的下限温度均低,其不育性比培矮64S更稳定,耐寒性比培矮64S更强,即可确保制种安全,又可确保自身繁殖,对加快两系法杂交水稻的发展步伐将起到重要的促进作用。     

水稻雄性不育系珍汕97A小孢子发育过程中的微管骨架

水稻（Oryza sativaL.)雄性不育系珍汕97A,保持系珍汕97B和恢复系测64三系小孢子发生过程的研究表明;恢复系测64小孢子母细胞细胞质浓,有明显的微管荧光围绕着细胞核。小孢子母细胞经两次减数分裂形成四分体。四分体和小孢子的微管从细胞核表面向胞质周缘延伸,形成放射性排列格局,花粉发育正常。细胞质中有少量点状微管荧光,保持系珍汕97B小孢子发生过程的细胞形态和微管结构与恢复系测64相似。但细胞质中的点状微管荧光多一些。雄性不育系珍汕97A小孢子发生早期,小孢子母细胞内出现液泡,核中染色质凝集,微管荧光很弱,没有清晰的微管丝结构。细胞质中有许多点状微管荧光等不正常现象。小孢子母细胞经过减数分裂形成的四分体也没有清晰的丝状微管结构。随后,所有的小孢子迅速败育,雄性不育系珍汕97A在小孢子母细胞发生的很早时期,微管结构就明显不正常。     

水稻配子体,孢子体细胞质雄性不育系线粒体体外翻译产物的分析

对水稻配子体细胞质雄性不育系粤泰Ａ,保持系粤泰Ｂ,Ｆ１代泰优２号和孢子体细胞质雄性不育系珍汕９７Ａ,保持系珍汕９７Ｂ,Ｆ１代汕优６３及另一种孢子体细胞质雄性不育系马协Ａ,保持系马协Ｂ,Ｆ１代马协６３的黄化苗线粒体离体翻译产物进行ＳＤＳ－ＰＡＧＥ分析。结果表明：粤泰Ａ的线粒体比粤泰Ｂ,泰优２号少合成２条多肽,Ｂ与Ｆ１的带型相近,Ａ特异合成４０．７ｋＤ多肽;     

BT型细胞质雄性不育水稻及其三系的线粒体DNA研究

用RAPD技术对BT型水稻胞质雄性不育系秀A及其保持系秀B、恢复系湘晴以及杂种F1代的线粒体DNA进行了比较分析。结果表明不育系与其保持系间存在显著差异;不育系与其F1之间mtDNA也存在差异。在引物OPJ－08的扩增产物中,秀A扩增出一条分子量为800bp的多态性片段,在引物OPK－10的扩增产物中,杂种F1扩增出一条分子量为900bp的片段。把这两片段回收、克隆并制备探针,OPJ－08800的Southern杂交结果显示不育系与其F1杂交图谱存在多态性;OPK－10900的Suthern杂交结果显示不育系与其保持系同存在差异。推测这两片段与育性可能有一定的联系。     

几个优良籼稻亲本品质性状的配合力和杂种优势分析

以3个不育系和10个恢复系为材料,采用NCII交配设计研究10个米质性状的配合力和杂种优势。结果表明：①大多数品质性状的量值介于双亲之间,除粒重表现一定的超亲优势、垩白度和粒宽表现一定的正向平均优势外,其他品质性状优势不明显。②杂种稻米的品质性状主要受不育系或恢复系的影响,其中粒长、粒宽和直链淀粉含量3个性状,不育系的影响要高于恢复系;而对于整精米率、粒重、垩白率、垩白度和糊化温度,则恢复系的影响要高于不育系。③就优质育种的利用价值而言,不育系以广占63-4S为好,恢复系以扬稻6号为好,R527、镇恢084次之,用上述亲本选配的杂交组合米质较好;恢复系特青、盐恢559表现为一般配合力效应低,特殊配合力方差小,优质育种利用价值不大。     

Fine mapping of a gene for non-pollen type thermosensitive genic male sterility in rice (Oryza sativa L.)

The thermo-sensitive genic male sterility (TGMS) lines play a crucial role in two-line hybrid rice production. For a practical TGMS line, the stability of male sterility is one of the most important technical indicators. In this study, XianS, a spontaneous mutant with stable male sterility from an indica rice cultivar Xianhuangzhan, was classified as a non-pollen type TGMS line. The critical non-pollen sterility point temperature of XianS was determined as 27°C. Genetic analysis demonstrated that the non-pollen sterility in XianS was controlled by a single recessive gene. Using SSR markers and bulked segregant analysis, the TGMS gene in XianS was fine mapped to a 183 kb interval between RMAN81 and RMX21 on chromosome 2. Two markers, 4039-1 and RMX14 completely cosegregated with this gene. Allelism test indicated that the non-pollen phenotype in seven non-pollen type TGMS lines from different sources, XianS, AnnongS-1, Q523S, Q524S, N28S, G421S, and Q527S is caused by the same TGMS gene. Although the location of TGMS gene in XianS is close to the gene OsNAC6, a previously identified candidate gene of tms5 in AnnongS-1, the sequence of OsNAC6 and its promoter region was identical in TGMS line XianS, AnnongS-1, and wild-type Xianhuangzhan. These results suggest that the non-pollen type TGMS trait probably be controlled by the same TGMS gene in different TGMS rice lines, but its real candidate gene still need to be further studied and identified.     

A fertile revertant from petaloid cytoplasmic male-sterile carrot has a rearranged mitochondrial genome

 A spontaneously derived fertile plant was recovered from a petaloid cytoplasmic male-sterile (CMS) carrot inbred line. Genetic analysis indicated a single nuclear gene was responsible for the restoration to fertility. Within a family segregating for the nuclear restorer in combination with the sterility-inducing cytoplasm, fertile plants were recovered that could not restore fertility when crossed to sterile genotypes. Genetic analysis indicated cytoplasmic reversion for fertility, and Southern analysis, comparing mtDNA organization of the fertile revertant and its CMS progenitor, identified mitochondrial genome rearrangements. Hybridization of cosmids representing a 108-kb subgenomic circle of the sterile line to DNA of a fertile maintainer and fertile revertant lines indicated a similar mtDNA organization for these genotypes that was distinct from that of the sterile line. Six restriction fragments totalling 43.2 kb were common to the fertile maintainer and revertant and absent in the sterile; other restriction fragments totalling 38.2 kb were present only for the sterile line. Unique fragments of low stoichiometry, two for the fertile maintainer and three for the revertant, distinguished these lines. The reversion to fertility in the sterile line could have resulted from the amplification of a mitochondrial submolar genome highly homologous to that found in the fertile maintainer line. Received: 4 October 1997/Accepted: 12 December 1997     

Soluble proteins and isoenzymes from seeds of diverse male steriles of sorghum, (Sorghum bicolor (L.) Moench)

Summary A comparison of soluble protein, esterase, GDH and ADH isoenzyme patterns in seeds of different steriles, maintainers and restorer lines exhibited similarities as well as differences. Soluble protein patterns from sterile and maintainer lines differed both qualitatively and quantitatively. Based on the esterase patterns, male steriles with different cytoplasms could be separated into three groups (i) Ck 60A and B; Nagpur A and B, (ii) M 35-1A and 1 B, M 31-2A and 2B, (iii) G1A and B, VZM2A and 2B. Each group could further be differentiated on the basis of minor differences in esterase isoenzyme patterns within each group. ADH and GDH patterns in general were similar in both sterile and maintainer lines.Abbreviations ADH Alcohol dehydrogenase - GDH Glutamate dehydrogenase - NAD Nicotinamide adenine dinucleotide     

Linkage analysis of a fertility restoring mutant generated from CMS rice

 DNA polymorphism between a cytoplasmic male-sterile rice line II-32A, the male-fertile maintainer counterpart II-32B, a fertile revertant (T24), as well as two commercial indica restorers, was analyzed with randomly amplified polymorphic DNA (RAPD). A very low degree of polymorphism was found between the revertant T24 and II-32A compared with that of indica rice varieties. This result, together with agronomic and genetic evidence, suggests the revertant to be a product of a nuclear mutation. An analysis of polymorphism between II-32A and the revertant T24 with 510 RAPD decamer primers identified the co-segregating markers OPB07₆₄₀ and OPB18₁₀₀₀ to be linked to a sterile allele of the restoring locus in the revertant T24, at a distance of 5.3 cM. RAPD analysis of a mapping population of Tesanai2/CB with primer OPB07 revealed linkage of OPB07₆₄₀ with RG374 (10.8 cM) and RG394 (8.8 cM) on chromosome 1. Thus the restorer gene, designated Rf ₅, was tentatively localized between RG374 and RG394 on chromosome 1 and appears to be independent of other mapped restorer genes in rice. Received: 11 November 1997 / Accepted: 17 December 1997