Development of Chromosomal Segment Substitution Lines from a Backcross Recombinant Inbred Population of Interspecific Rice Cross

A backcross recombinant inbred line population consisting of 202 lines was developed from Xieqingzao B//Xieqingzao B / Dongxiang wild rice. The population was assayed with DNA markers and phenotyped on planthopper resistance and yield traits. A linkage map consisting of 119 DNA markers and spanned for 1188 cM over the 12 rice chromosomes was constructed. Thirty-two chromosomal segment substitution lines were selected based on the percentage of Xieqingzao B allele at marker loci. These lines are of great potential for gene mapping and alien gene introgression.

Development and genetic analysis of wheat double substitution lines carrying Hordeum vulgare 2H and Thinopyrum intermedium 2Ai#2 chromosomes

Thinopyrum intermedium and barley are two close relatives of wheat and carry many genes that are potentially valuable for the improvement of various wheat traits. In this study we created wheat double substitution lines by hybridizing different wheat–Th. intermedium and wheat–barley disomic alien substitution lines, with the aim of using genes in Th. intermedium and barley for wheat breeding and investigating the genetic behavior of alien chromosomes and their wheat homoeologs. As expected, we obtained two types of wheat double substitution lines,2D2Ai#2(2B)2H( A) and 2A2 Ai#2(2B)2H(2D), in which different group 2 wheat chromosomes were replaced by barley chromosome 2 H and Th. intermedium chromosome 2Ai#2. The new materials were characterized using molecular markers, genomic in situ hybridization(GISH), and fluorescent in situ hybridization(FISH). GISH and FISH experiments revealed that the double substitution lines harbor 42 chromosomes including 38 wheat chromosomes, a pair of barley chromosomes, and a pair of Th. intermedium chromosomes. Analysis using specific DNA markers showed that two pairs of wheat homoeologous group 2 chromosomes in the new lines were substituted by a pair of 2H and a pair of 2Ai#2 chromosomes. Chromosome 2H showed a higher transmission rate than 2Ai#2, and both chromosomes were preferentially transmitted between generations via female gametes. Evaluation of botanic and agronomic traits demonstrated that,compared with their parents, the new lines showed similar growth habits and plant type but differences in plant height, flowering date, and self-fertility. Cytological observations using different probes suggested that the double substitution lines showed nearly normal genetic behavior before and during meiosis. The novel substitution lines can potentially be used in wheat meiosis research and breeding programs.

小麦-十倍体长穗偃麦草双重异代换系的分子细胞遗传学及抗条锈病鉴定

十倍体长穗偃麦草[Thinopyrum ponticum(Popd.)Barkworth and Dewey]具有抗寒、抗旱、耐盐碱、茎秆粗壮、穗长花多等优异性状,是小麦遗传改良的重要基因资源。本课题组从小麦与十倍体长穗偃麦草的杂交后代中筛选出一份抗条锈病的衍生系CH18067,本研究对其进行形态学、细胞学、原位杂交、分子标记、抗条锈病性等综合鉴定。细胞学观察结果显示,CH18067的体细胞染色体数目为42条,在减数分裂中期Ⅰ的染色体构型为2n=21Ⅱ,在减数分裂后期Ⅰ同源染色体可均等分离,表明其细胞学遗传稳定。利用寡核苷酸探针Oligo-pTa535(红色)和Oligo-pSc119.2(绿色)对CH18067进行FISH鉴定,结果显示,CH18067缺失小麦2D和4D染色体,同时含有2对具有特殊带型的染色体;通过对CH18067进行FISH-GISH、mc-GISH、液相芯片以及染色体核型分析,发现2对具有特殊带型的染色体中,在长臂和短臂末端均呈现Oligo-pTa535探针红色带型的染色体为十倍体长穗偃麦草的2J染色体,在着丝粒位置和长臂末端均呈现Oligo-pTa535探针红色带型的染色体为十倍体长穗偃麦草的4J^(S)染色体,说明CH18067为小麦-十倍体长穗偃麦草2J(2D)+4J^(S)(4D)双重异代换系。在第二部分同源群和第四部分同源群分别筛选出3个特异性标记,可用于追踪小麦遗传背景中长穗偃麦草的2J和4J^(S)染色体。形态学和条锈病抗性鉴定结果显示,CH18067具有矮秆、长粒等特性,且在成株期高抗小麦条锈病。以上结果表明,CH18067可作为小麦条锈病抗性育种和遗传研究的候选种质。

Molecular Cytogenetic Characterization of Wheat-Thinopyrum elongatum Addition,Substitution and Translocation Lines with a Novel Source of Resistance to Wheat Fusarium Head Blight

Thinopyrum elongatum （2n = 2x = 14, EE）, a wild relative of wheat, has been suggested as a potentially novel source of resistance to several major wheat diseases including Fusarium Head Blight （FHB）. In this study, a series of wheat （cv. Chinese Spring, CS） substitution and ditelosomic lines, including Th. elongatum additions, were assessed for Type II resistance to FHB. Results indicated that the lines containing chromosome 7E of Th. elongatum gave a high level of resistance to FHB, wherein the infection did not spread beyond the inoculated floret. Furthermore, it was determined that the novel resistance gene（s） of 7E was located on the short-ann （7ES） based on sharp difference in FHB resistance between the two 7E ditelosomic lines for each arm. On the other hand, Th. elongatum chromosomes 5E and 6E likely contain gene（s） for susceptibility to FHB because the disease spreads rapidly within the inoculated spikes of these lines. Genomic in situ hybridization （GISH） analysis revealed that the alien chromosomes in the addition and substitution lines were intact, and the lines did not contain discernible genomic aberrations. GISH and multicolor-GISH analyses were further performed on three trans- location lines that also showed high levels of resistance to FHB. Lines TA3499 and TA3695 were shown to contain one pair of wheat-Th. elongatum translocated chromosomes involving fragments of 7D plus a segment of the 7E, while line TA3493 was found to contain one pair of wheat-Th, elongatum translocated chromosomes involving the D- and A-genome chromosomes of wheat. Thus, this study has established that the short-arm of chromosome 7E of Th. elongatum harbors gene（s） highly resistant to the spreading of FHB, and chromatin of 7E introgressed into wheat chromosomes largely retained the resistance, implicating the feasibility of using these lines as novel material for breeding FHB-resistant wheat cultivars.

小麦-中间偃麦草二体异代换系山农0095的选育及其鉴定

利用小麦品种烟农15与中间偃麦草直接杂交,以烟农15为回交亲本对其杂种F1回交2次,再经自交3次,从BC2F4中选出种质系山农0095。利用形态学、细胞学、种子醇溶蛋白酸性聚丙烯酰胺凝胶电泳(A-PAGE)、RAPD和GISH等方法对其进行鉴定。结果表明,山农0095平均株高78cm,穗长17.3cm,穗粒数74个,旗叶长36.3cm,旗叶宽3.03cm,茎秆粗壮,多花多实,繁茂性好;其根尖细胞染色体数目为2n=42,花粉母细胞减数分裂中期Ⅰ(PMCMⅠ)染色体构型为2n=21Ⅱ;它与烟农15的杂种F1在减数分裂中期Ⅰ的大多数花粉母细胞能观察到2个单价体,平均染色体构型为2n=20.08Ⅱ+1.84Ⅰ。A-PAGE鉴定结果表明,山农0095在β区出现一条中间偃麦草的特异带;从180个RAPD引物中筛选出一个特异引物S186(5′-GATACCTCGG-3′),能够在山农0095中扩增出一条约900bp中间偃麦草的特异带,标记为S186900;以中间偃麦草基因组DNA为标记探针、中国春基因组DNA为封阻的原位杂交结果进一步表明,山农0095的42条染色体中含有2条完整的中间偃麦草染色体,是小麦-中间偃麦草的二体异代换系。

普通小麦-华山新麦草异代换系的选育及细胞遗传学研究

利用缺体小麦与小麦-华山新麦草七倍体杂种（2n＝49，AABBDDN）杂交，F1再与相应’的缺体小麦回交2次，在BC2F1境检选出2n＝41的植株，同时套袋自交，选育出5A和3D两种异代换系。单体代换植株自交产生二体代换植株的频率为23．16％。5A代换植株在减数分裂中期121Ⅱ的出现频率平均为84.52％，3D代换植株21Ⅱ的出现频率平均为62.61％。异代换系均生长旺盛，结实正常，说明异染色体能较好地补偿所缺失的小麦染色体。

一个小麦-中间偃麦草异代换系的形态学和细胞学鉴定

中间偃麦草含有丰富的优良基因 ,在小麦的遗传改良中具有重要利用价值 .对从中间偃麦草与小麦品种烟农 15杂种后代 BC2 F4 中选育的小麦种质系山农 0 0 95进行形态学和细胞学鉴定 ,结果表明 :山农 0 0 95株高 78cm,穗长 17.3cm,旗叶长 36 .3cm,旗叶宽 3.0 3cm,茎杆粗壮 ,繁茂性好 ,既长又宽的旗叶、长圆锥型穗是其显著的形态学特征 ;其根尖细胞染色体数目为 2 n=4 2 ,花粉母细胞减数分裂中期 PMC M 染色体构型为 2 n=2 1 ;它与普通小麦的杂种 F1 PMC M 绝大多数细胞出现 2个单价体 ,没有观察到多价体 ,平均染色体构型为 2 n=2 0 .0 8 +1.84 .以上结果表明 ,山农 0 0 95是一个小麦 -中间偃麦草的双体异代换系 .

普通小麦-华山新麦草异代换系和附加系的C-分带鉴定

利用染色体C-分带技术,对普通小麦-华山新麦草异代换系和附加系进行了细胞学鉴定。鉴定结果表明,普通小麦-华山新麦草的3个异代换系H921-6-12为5A/Nh5代换、H922-9-12为3B/Nh4代换、H924-3-4为3D/Nh4代换,2个异附加系H8911-1-2-6为Nh4附加、H9014-154-2为Nh7附加。初步推断华山新麦草的Nh5和Nh4染色体分别能补偿普通小麦的5A和3B,3D的缺失。

长穗偃麦草基因组中与耐低磷营养胁迫有关的基因的染色体定位

以中国春－长穗偃麦草二体异附加系和二体异代换系为材料，对其耐低磷营养胁迫特性进行鉴定和遗传分析。结果表明：（1）长穗偃麦草的4E与6E染色体携有耐低磷营养胁迫的基因，且其效应远远超过背景亲本中国春。（2）强烈抑制耐低磷胁迫特性的基因位于5E染色体。（3）2E和3E染色体的附加系与代换系耐低磷特性的表现不一致。尽管2E和3E的附加系对低磷营养胁迫极为敏感，但无论在对照或低磷胁迫条件下，其相应的异代换系却显著优于其附加系和中国春。此外，对附加系和代换系表现不一致的原因进行了讨论。

小麦远缘杂交后代对小麦全蚀病抗病性研究

研究了小麦-华山新麦草衍生系和小麦-簇毛麦衍生系19份材料苗期对小麦全蚀病菌禾顶囊壳小麦变种的抗病性,对9份抗病性较高的材料进行田间全生育期抗病性测试.结果表明:9份材料在不同生育期抗病性表现不同,苗期抗病性均高,越冬期无死亡;V2代换系、H922-9-12和V9125-2在返青期抗病性较高,病根严重度低于5.5%;H922-9-12和V9129-1在扬花期抗病性表现较好,成穗率可达80%;H922-9-12和V2代换系在成熟期抗病性较高,白穗率在13.8%以下.对照小偃6号高度感病,蒙燕94-4高度抗病.

小麦-大麦异代换系的创制及鉴定研究

利用"缺体回交法"以小大麦二体异附加系WBA9816作父本与阿勃缺体小麦杂交,创制小大麦异代换系.F1再用该异附加系回交,回交后代通过细胞学鉴定,筛选2n=43的双单体植株套袋自交,从自交后代群体培育出WBS02126;用原位杂交GISH和染色体C-分带技术鉴定表明,WBS02126为2D/2H异代换系;田间试验结果显示,WBS02126生长发育良好,育性基本正常,表现弱春性,叶片宽厚上挺,叶色淡绿,棒状穗,小穗排列紧密,长芒,早熟,综合抗病性好.

小麦—中间偃麦草抗条锈衍生系的分子细胞遗传学研究

应用缺体回交法 ,以部分阿勃缺体为母本 ,中 4为父本 ,培育出 1个对目前条锈病优势小种和新小种高抗至免疫的小麦—中间偃麦草衍生系 N90 2 5 - 3 - 3 - 2 - 1 - 1。研究表明 ,该选系在形态学和细胞学上已经基本稳定 ,染色体构型为 2 n=42 =2 1″,抗病性来自中间偃麦草(Thinopyron intermedium)。以中间偃麦草 DNA为探针 ,对 N90 2 5 - 3 - 3 - 2 - 1 - 1进行基因组原位杂交分析结果证明 ,它为小麦—中间偃麦草异代换

普通小麦-华山新麦草异代换系的分子细胞遗传学研究

利用荧光原位杂交和染色体 C-分带技术对普通小麦 -华山新麦草的异代换系进行了研究 .荧光原位杂交结果显示 :异代换系 H92 1- 6 - 12和 H92 4 - 3- 4均含有 2条华山新麦草的染色体 .对这 2个材料和华山新麦草进行染色体 C-分带带型比较 ,结果认为 :H92 1- 6 - 12可能是普通小麦 -华山新麦草的 5 A / N5h 代换系 ,H92 4 - 3- 4可能是 3D/ N4 h代换系 .

抗白粉病小偃麦异代换系的细胞学和RAPD鉴定

利用细胞学和RAPD方法,对从长穗偃麦草与普通小麦复合杂交后代中选育的抗白粉病小麦种质系山农87074-526和山农87074-551进行了鉴定。结果表明,两种质系的根尖细胞染色体数目均为2n=42,花粉母细胞减数分裂中期Ⅰ(PMC MⅠ)染色体构型为2n=21Ⅱ;二者杂交F_1 PMC MⅠ染色体构型亦为2n=21Ⅱ,两种质系分别与小麦中国春的杂种F_1 PMC MⅠ染色体构型均为2n=20Ⅱ+2Ⅰ,说明两种质系为相同的双体异代系。在苗期和成株期两种质系对白粉病15号菌种均表现免疫,其白粉病抗性为显性,并且来自长穗僵麦草,抗白粉病基因位于它们所含的偃麦草染色体上。从80个随机引物中,筛选出2个引物OPE13和OPH15能在两种质系中稳定地扩增出长穗偃麦草亲本的特异DNA片段。

普通小麦-簇毛麦异附加系和异代换系的C-分带鉴定

用改良的C-分带技术鉴定南京农业大学细胞遗传研究室获得的普通小麦的簇毛麦V_2、V_3、V_4、V_6、V_7染色体异附加系和V_2、V_5异代换系,得到与N-分带和染色体配对分析一致的结果,并且由于C-分带可同时鉴别小麦全部21对染色体,鉴定出V_2异代换系中被代换掉的小麦染色体为1A。

长穗偃麦草酸性磷酸酶与碱性磷酸酶编码基因的染色体定位

以一套中国春-长穗偃麦草二体异附加系与二体异代换系为材料,用等电聚焦(IEF)研究长穗偃麦草基因组中酸性磷酸酶(AcPh)与碱性磷酸酶(APH)编码基因的染色体定位。结果表明,AcPh大多聚焦于pH5～7范围内,其编码基因位于3E染色体,而APH编码基因则位于4E染色体。由于5E染色体的附加,AcPh活性带强度显著减弱。

小麦–华山新麦草异代换系DH2322的分子细胞遗传学鉴定

利用分子标记、细胞学、基因组原位杂交(GISH)等技术,结合田间农艺性状调查,对小麦–华山新麦草七倍体材料H8911与硬粒小麦D4286杂交F4代分离群体中株系DH2322进行了综合鉴定。华山新麦草基因组特异SCAR标记鉴定表明,DH2322含有华山新麦草遗传物质;细胞遗传学观察显示,DH2322染色体构型为2n=42=21 II;有丝分裂和花粉母细胞减数分裂中期I基因组原位杂交(GISH)鉴定表明,DH2322的染色体由40条小麦染色体和2条华山新麦草Ns染色体构成,且2条Ns染色体能完全配对为一个二价体;SSR和STS分子标记分析表明,DH2322缺失小麦D基因组的2D染色体,而含有华山新麦草的2Ns染色体;农艺性状分析结果表明,DH2322具有双亲的形态学特征,结实性好,穗长和穗粒数显著大于亲本。

小麦-中间偃麦草异代换系的细胞学和SSR标记鉴定

中间偃麦草含有丰富的优良基因,在小麦的遗传改良中具有重要利用价值。对从八倍体小偃麦TAI-7045与普通小麦复合杂交后代中选育的小麦种质系CH-9916进行细胞学鉴定,其根尖细胞染色体数目为2n=42,为六倍体普通小麦,在苗期和成株期CH-9916对条锈病均表现免疫,中抗白粉病。通过SSR标记鉴定分析,其可能是由偃麦草的染色体代换了小麦的2D染色体。以上结果表明,种质系CH-9916可能是一个异代换系。

抗大麦黄矮病毒小麦-中间偃麦草二体异代换系的选育和细胞、生化、分子生物学鉴定

结合花药培养和常规选育 ,从 77_5 433×中 5杂交组合后代中选育出 6个抗大麦黄矮病毒 (barleyyellowdwarfvirus ,BYDV)、染色体数目为 42的小麦 (TriticumaestivumL .)新种质 ,并用减数分裂配对分析、单体小麦测交法、基因组原位杂交、C分带、同工酶等电聚焦和RAPD对上述材料进行了综合鉴定 ;表明这些材料都是小麦_中间偃麦草(AgropyronintermediumGarten)二体异代换系 ,其抗病性来自其携带的一对中间偃麦草染色体 (来源于中 5 )。

小偃麦种质系SN0606的形态学和细胞学分析

对从中间偃麦草与小麦品种烟农15杂种后代中选育的小麦种质系SN0606进行主要农艺性状调查和细胞学鉴定,结果表明:SN0606平均株高87.0 cm,平均穗长10.5 cm,小穗数23个,穗粒数56;其根尖细胞染色体数目为2n=42,花粉母细胞减数分裂中期Ⅰ(PMCMⅠ)染色体构型为2n=21Ⅱ;与普通小麦的杂种F1PMC MⅠ染色体构型为2n=0.78Ⅰ+20.61Ⅱ,SN0606可能是一个小麦—中间偃麦草的二体异代换系。