The use of cell culture for subchromosomal introgressions of barley yellow dwarf virus resistance from Thinopyrum intermedium to wheat.

Barley yellow dwarf virus (BYDV) resistance has been transferred to wheat from a group 7 chromosome of Thinopyrum (Agropyron) intermedium. The source of the resistance gene was the L1 disomic addition line, which carries the 7Ai-1 chromosome. The resistance locus is on the long arm of this chromosome. BYDV resistant recombinant lines were identified after three or more generations of selection against a group 7 Th. intermedium short arm marker (red coleoptile) and selection for the presence of BYDV resistance. One recombinant line produced by ph. mutant induced homoeologous pairing and 14 recombinant lines induced by cell culture have been identified. Resistance in seven of the cell culture induced recombinants has been inherited via pollen according to Mendelian segregation ratios for up to eight generations. Meiotic analysis of heterozygotes indicates that the alien chromatin in the cell culture induced recombinants is small enough to allow regular meiotic behaviour. The ph-induced recombinant was less regular in meiosis. A probe, pEleAcc2, originally isolated from Th. elongatum and that hybridizes to dispersed repeated DNA sequences, was utilised to detect Th. intermedium chromatin, which confers resistance to BYDV, in wheat backgrounds. Quantification of these hybridization signals indicated that the translocations involved a portion of alien chromatin that was smaller than the complete long arm of 7Ai-1. Restriction fragment length polymorphism analysis confirmed the loss of the short arm of 7Ai-1 and indicated the retention of segments of the long arm of 7Ai-1. Two 7Ai-1L DNA markers always assorted with the BYDV resistance. A third 7Ai-IL DNA marker was also present in seven of eight recombinants. In all recombinants except TC7, the 7Ai-1L markers replaced the 7DL markers. None of the wheat group 7 markers was missing from TC7. It is concluded that all the resistant lines are the result of recombination with wheat chromosome 7D, except line TC7, which is the result of recombination with an unidentified nongroup 7 chromosome.     

Characterization of derivatives from wheat-Thinopyrum wide crosses

Partial amphiploids are lines that contain 42 (38-42) wheat and 14 (14-18) alien chromosomes. They are derived by backcrossing wheat onto hybrids between wheat and either Thinopyrum intermedium (6x) or Th. ponticum (10x). GISH analysis has shown that, with possibly one exception, the alien genomes (chromosome sets) in partial amphiploids are found to be hybrids i.e. composed of chromosomes from more than one alien genome. The individual partial amphiploids are meiotically stable and nearly perfectly fertile, but hybrids between different lines were characterized by varying numbers of unpaired chromosomes and consequently variable degrees of sterility. Translocated chromosomes involving different Thinopyrum genomes or Thinopyrum and wheat genomes were found in partial amphiploids and consequently in the addition lines derived from them. Partial amphiploids have proven to be an excellent tertiary gene pool for wheat improvement, containing resistance to biotic stresses not present in wheat itself. Resistance to Barley Yellow Dwarf Virus (BYDV) and Wheat Streak Mosaic Virus (WSMV) have been found in partial amphiploids and addition lines derived from both Th. intermedium and Th. ponticum. Excellent resistance to Fusarium head blight has been found on a Th. intermedium chromosome that had substituted for chromosome 2D in wheat. Genes for resistance to leaf rust and stem rust have already been incorporated into wheat and tagged with molecular markers.     

Disomic Thinopyrum intermedium addition lines in wheat with barley yellow dwarf virus resistance and with rust resistances.

Zhong 5 is a partial amphiploid (2n = 56) between Triticum aestivum (2n = 42) and Thinopyrum intermedium (2n = 42) carrying all the chromosomes of wheat and seven pairs of chromosomes from Th. intermedium. Following further backcrossing to wheat, six independent stable 2n = 44 lines were obtained representing 4 disomic chromosome addition lines. One chromosome confers barley yellow dwarf virus (BYDV) resistance, whereas two other chromosomes carry leaf and stem rust resistance; one of the latter also confers stripe rust resistance. Using RFLP and isozyme markers we have shown that the extra chromosome in the Zhong 5-derived BYDV resistant disomic addition lines (Z1, Z2, or Z6) belongs to the homoeologous group 2. It therefore carries a different locus to the BYDV resistant group 7 addition, L1, described previously. The leaf, stem, and stripe rust resistant line (Z4) carries an added group 7 chromosome. The line Z3 has neither BYDV nor rust resistance, is not a group 2 or group 7 addition, and is probably a group 1 addition. The line Z5 is leaf and stem rust resistant, is not stripe rust resistant, and its homoeology remains unknown.     

抗黄矮病小麦新品系YW443的分子细胞遗传学鉴定

以小麦－中间偃麦草二体附加系Ｌ１衍生抗病系ＰＰ９－１为抗源,与小麦推广品种陕７８５９．丰抗８号杂交并自交,在Ｆ６代中选到农艺性状优良的高抗黄矮病小麦新品系ＹＷ４４３。对ＹＷ４４３及其亲本进行抗病性鉴定。结果表明：ＹＷ４４３高抗大麦黄矮病毒ＧＰＶ、ＧＡＶ株系。利用基因组原位杂交,ＲＦＬＰ分析和ＲＡＰＤ分析,研究诉遗传构成及其抗病基因染色体归属。结果表明：ＹＷ４４３（２ｎ＝４３）的遗传构成了４０条（２     

小偃麦附加系Z1和Z2中外源染色体2Ai-2的结构组成

小偃麦附加系Z1和Z2中外源染色体2Ai-2的结构组成@张增燕$中国农业科学院作物育种栽培研究所!北京100081@辛志勇$中国农业科学院作物育种栽培研究所!北京100081@陈孝$中国农业科学院作物育种栽培研究所!北京100081小偃麦;;附加系;;染色体     

Research progress in BYDV resistance genes derived from wheat and its wild relatives

Barley yellow dwarf virus （BYDV） may cause a serious disease affecting wheat worldwide. True resistance to BYDV is not naturally found in wheat. BYDV resistance genes are found in more than 10 wild relative species belonging to the genera of Thinopyrum, Agropyron, Elymus, Leymus, Roegneria, and Psathyrostachy. Through wide crosses combining with cell culture, use ofph mutants, or irradiation, 3 BYDV resistance genes in Th. intermedium, including Bdv2, Bdv3 and Bdv4, were introgressed into common wheat background. Various wheat-Th, intermedium addition and substitution, translocation lines with BYDV-resistance were developed and characterized, such as 7D-TAi#1 （bearing Bdv2）, 7B-7Ai#1, 7D-7E （beating Bdv3）, and 2D-2Ai-2 （bearing Bdv4） translocations. Three wheat varieties with BYDV resistance from Th. intermedium were developed and released in Australia and China, respectively. In addition, wheat-Agropyron cristatum translocation lines, wheat-Ag, pulcherrimum addition and substitution lines, and a wheat-Leymus multicaulis addition line （line24） with different resistance genes were developed. Cytological analysis, morphological markers, biochemical markers, and molecular markers associated with the alien chromatin carrying BYDV resistance genes were identified and applied to determine the presence of alien, chromosomes or segments, size of alien chromosome segments, and compositions of the alien chromosomes. Furthermore, some resistance-related genes, such as RGA, P450, HSP70, protein kinases, centrin, and transducin, were identified, which expressed specifically in the resistance translocation lines with Bdv2. These studies lay the foundations for developing resistant wheat cultivars and unraveling the resistance mechanism against BYDV.     

携带抗黄矮病基因的中间偃麦草染色体2Ai_2特异的分子标记

The wheat-Thinopyrum intermedium addition lines Z1,Z2 contain a pair of Th. intermedium chromosomes 2Ai-2 carrying the gene with resistance to barley yellow dwarf virus (BYDV). Genomic in situ hybridization (GISH) was used to analyze the chromosome constitution of Z1,Z2 by using genomic DNA probes from Th. intermedium and Pseudoroegneria strigosa. The results showed that the chromosome constitution of either Z1 or Z2 composes of 42 wheat chromosomes and two Th. intermedium chromosomes (2Ai-2). The 2Ai-2 chromosome is St-E intercalary translocation, in which the E genomic chromosome segment translocated into the middle region of the long arm of chromosome belonging to St genome. With the genomic DNA probe of Ps. strigosa, the GISH pattern specific to the 2Ai-2 chromosome may be used as a molecular cytogenetic marker. A detailed RFLP analysis on Z1, Z2 and their parents was carried out by using 12 probes on the wheat group 2 chromosomes. Twenty RFLP markers specific to the 2Ai-2 chromosome were identified. Two RAPD markers of OPR16 –350 and OPH09 -1580, specific to the 2Ai-2 chromosome, were identified from 280 RAPD primers. These molecular markers could be used to assisted-select translocation lines with small segment of the 2Ai-2 chromosome and provide tools to localize the BYDV resistance.     

携带抗黄矮病基因的中间偃麦草染色体2Ai—2特异的分子标记

小麦－中间偃麦草二体异附加系Ｚ１、Ｚ２具有一对携带抗黄矮病基因的中间偃麦草染色体２Ａｉ－２。利用中间偃麦草（Ｔｈｉｎｏｐｙｒｕｍ ｉｎｔｅｒｍｅｄｉｕｍ （Ｈｏｓｔ） Ｂａｋｗｏｔｈ ａｎｄ Ｄｅｗｅｙ）和拟鹅冠草（Ｐｓｅｕｄｏｒｏｅｇｎｅｉａ ｓｔｒｉｇｏｓａ）基因组ＤＮＡ作探针,对Ｚ１、Ｚ２进行基因组原位杂交分析。结果表明,Ｚ１、Ｚ２附加的一对中间偃麦草染色体２Ａｉ－２为Ｓｔ－Ｅ染色体,Ｅ组染     

兼抗抗白粉病和黄矮病小麦育种材料的创造与鉴定

白粉病和黄矮病是小麦生产上的重要病害,近几年来这两种病害经常在我国一些小麦产区同时发生。为解决该问题,本研究通过杂交、回交方法将抗黄矮病的Bdv2基因（源自于YW642）和抗白粉病的Pm21基因（源自于CB037）聚合在一起,育成了兼抗黄矮病和白粉病的小麦新材料。通过田间抗病性鉴定与分子标记辅助选择相结合,得到聚合了Bdv2基因和Pm21基因的BC1代小麦22株,F2代小麦51株。农艺性状调查显示,这些含Pm21和Bdv2基因的双抗白粉病和黄矮病小麦新材料的农艺性状优于感病植株和原先的亲本,可以在小麦白粉病和黄矮病兼性抗病育种中作为优异种质资源加以利用。     

组织培养与普通小麦异源易位系选育

以中国春小麦品种中８６０１、澳大利亚栽培小麦品种Ｓｕｎｓｔａｒ、Ｍｉｌｌｅｗａ作母本,与抗大麦黄矮病毒病（ＢａｒｌｅｙＹｅｌｌｏｗＤｗａｒｆＶｉｒｕｓ,简称ＢＹＤＶ）的小麦－中间偃麦草异附加系Ｌ１杂交,取杂种的幼胚和幼穗作离体培养,获得大量再生植株。经酶联免疫吸附分析（ＥＬＩＳＡ）、限制性内切酶长度多态性分析（ＲＦＬＰ）、染色体数目的检查和田间抗性鉴定,在再生植株回交后代中获得了抗ＢＹＤＶ的杂合易位株,经自交和花药培养纯合,选育出Ｄ１０９１、Ｄ１０９４、Ｄ１６５８、ＴＣ５、ＴＣ６、ＴＣ７等一批抗性稳定或基本稳定的普通小麦选系。以白黑麦６Ｒ二体附加系为抗源,与严重感染白粉病的陕７８５９杂交,经幼胚培养在再生植株回交后代中筛选到白粉病免疫的普通小麦杂合易位系。研究结果表明：在小麦远缘杂交中,组织培养可以作为导入外源基因产生易位的手段之一加以利用。     

Molecular characterization of a Thinopyrum intermedium group 2 chromosome (2Ai-2) conferring resistance to barley yellow dwarf virus.

The wheat--Thinopyrum intermedium addition lines Z1 and Z2 carry 21 pairs of wheat chromosomes and one pair of Th. intermedium chromosomes (2Ai-2) conferring resistance to barley yellow dwarf virus (BYDV). GISH results using the genomic DNA of Pseudoroegneria strigosa (S genome) as the probe indicated that the 2Ai-2 chromosome in Z1 and Z2 is an S-J intercalary translocation. Most of the 2Ai-2 chromosome belongs to the S genome, except for about one third in the middle region of the long arm that belongs to the J genome. The results of detailed RFLP analyses confirmed that the 2Ai-2 chromosome is extensively homoeologous to wheat group 2 chromosomes. Some new RFLP markers specific to the 2Ai-2 chromosome were identified. A RAPD marker, OP-R16(340), specific to the 2Ai-2 chromosome, was screened. We converted the RAPD marker into a sequence-characterized amplified region (SCAR) marker (designated SC-R16). The study establishes the basis for selecting translocation lines with small segments of the 2Ai-2 chromosome and localizing the BYDV resistance gene when introgressed into a wheat background.     

Thinopyrum 7Ai-1-derived small chromatin with Barley Yellow Dwarf Virus (BYDV) resistance gene integrated into the wheat genome with retrotransposon

Thinopyrum intermedium is a useful source of resistance genes for Barley Yellow Dwarf Virus (BYDV), one of the most damaging wheat diseases. In this study, wheat/Th. intermedium translocation lines with a BYDV resistance gene were developed using the Th. intermedium 7Ai-1 chromosome. Genomic in situ hybridization (GISH), using a Th. intermedium total genomic DNA probe, enabled detection of 7Ai-1-derived small chro-matins containing a BYDV resistance gene, which were translocated onto the end of wheat chromosomes in the lines Y95011 and Y960843. Random amplified polymorphic DNA (RAPD) analyses using 120 random 10-mer primers were conducted to compare the BYDV-resistant translocation lines with susceptible lines. Two primers amplified the DNA fragments specific to the resistant line that would be useful as molecular markers to identify 7Ai-1-derived BYDV resistance chromatin in the wheat genome. Additionally, the isolated Th. intermedium-specific retrotransposon-like sequence pTi28 can be used to identify Th. intermedium chromatin transferred to the wheat genome.     

Effect of BYDV Infection on the Cell Surface Glycoproteins in Common Wheat,Wheatgrass and Octoploid Wheat-Wheatgrass

Changes in the cell surface glycoproteins in common wheat 3B-2, Agropyron intermedium and octoploid wheat-wheatgrass Zhong 5 after the inoculation with barley yellow dwarf virus (BYDV) were sdudied using electron microscopy and ruthenium red staining. The results indicated that, after the inoculation with BYDV, different changes in cell surface glycoproreins were observed in the plant species with different levels of resistance. In A. intermediurn which is immune to BYDV, inoculation with BYDV did not cause significant change in cell surface glycoprotein layer. In cotoploid wheat-wheatgrass Zhong 5 which is highly resistent to BYDV, BYDV infection caused significant thickening in most cell surface glycoprotein layer. In common wheat 3B-2 which is susceptible to BYDV, BYDV infection did not cause thickening in cell surface glycoprotein layer, but in most cells, glycoproteins on the cell surface were partially peeled off or disappeared completely. Therefore, it is suggested that the glycoproteins on cell surface play certain roles in BYDV resistance. The phenomenon of the thickening of cell surface glycoprotein layer caused by BYDV infection was possibly a resistant reaction to the virus.     

Structural organization of an alien Thinopyrum intermedium group 7 chromosome in U.S. soft red winter wheat (Triticum aestivum L.).

Barley yellow dwarf virus (BYDV) resistance in soft red winter wheat (SRWW) cultivars has been achieved by substituting a group 7 chromosome from Thinopyrum intermedium for chromosome 7D. To localize BYDV resistance, a detailed molecular genetic analysis was done on the alien group 7 Th. intermedium chromosome to determine its structural organization. Triticeae group 7 RFLP markers and rye specific repetitive sequences used in the analysis showed that the alien chromosome in the P29 substitution line has distinguishing features. The 350-480 bp rye telomeric sequence family was present on the long arm as determined by Southern and fluorescence in situ hybridization. However, further analysis using a rye dispersed repetitive sequence indicated that this alien chromosome does not contain introgressed segments from the rye genome. The alien chromosome is homoeologous to wheat chromosomes 7A and 7D as determined by RFLP analysis. Presence of the waxy gene on chromosomes 7A, 7B, and 7D but its absence on the alien chromosome in P29 suggests some internal structural differences on the short arm between Th. intermedium and wheat group 7 chromosomes. The identification of rye telomeric sequences on the alien Thinopyrum chromosome and the homoeology to wheat chromosomes 7A and 7D provide the necessary information and tools to analyze smaller segments of the Thinopyrum chromosome and to localize BYDV resistance in SRWW cultivars.     

Identification and characterization of wheat-wheatgrass translocation lines and localization of barley yellow dwarf virus resistance.

Stable introgression of agronomically important traits into crop plants through wide crossing often requires the generation and identification of translocation lines. However, the low efficiency of identifying lines containing translocations is a significant limitation in utilizing valuable alien chromatin-derived traits. Selection of putative wheatgrass-wheat translocation lines based on segregation ratios of progeny from gamma-irradiated seed using a standard phenotypic analysis resulted in a low 4% success rate of identifying barley yellow dwarf virus (BYDV) resistant and susceptible translocation lines. However, 58% of the susceptible progeny of this irradiated seed contained a Thinopyrum intermedium chromosome-specific repetitive sequence, which indicated that gamma-irradiation-induced translocations occurred at high rate. Restriction fragment length polymorphism (RFLP) analysis of susceptible lines containing alien chromatin, their resistant sister lines and other resistant lines showed that more than one third of the progeny of gamma-irradiated double monosomic seeds contained wheatgrass-wheat translocations. Genomic in situ hybridization (GISH) analysis of selected lines confirmed that these were wheatgrass-wheat translocation lines. This approach of initially identifying BYDV susceptible deletion lines using an alien chromosome-specific repetitive sequence followed by RFLP analysis of their resistant sister lines efficiently identified resistant translocation lines and localized the BYDV resistance to the distal end of the introgressed Th. intermedium chromosome.     

向普通小麦导入纤毛鹅观草抗黄矮病基因的研究──Ⅰ.F_1和BC_1的产生及其细胞遗传学

为了将纤毛鹅观草Z1010对黄矮病毒株系PAV和RPV的抗性基因转入普通小麦,通过幼胚拯救,获得了纤毛鹅观草Z1010×普通小麦品种莱州953的杂种F1,以及用5个普通小麦品种（系）回交的BC1衍生系。对杂种F1及BC1植株的细胞学分析表明,纤毛鹅观草Z1010不仅对Ph基因具有很强的抑制作用,而且能使杂种F1形成未减数配子,对细胞遗传学资料的进一步分析认为,通过部分同源染色体间的交换将纤毛鹅观草Z1010的抗黄矮病基因转入小麦是可能的。     

小麦叶锈病新抗源筛选

小麦叶锈病是小麦生产的主要病害之一,发病严重时往往导致大幅度减产。叶锈菌生理小种的变异易导致抗病基因抗性的丧失,因此不断获得新抗源对小麦抗病育种至关重要。小麦近缘植物中含有丰富的小麦育种所需的抗病基因。本研究从小麦-近缘植物双二倍体、附加系、代换系或易位系等创新种质中筛选出小麦叶锈病新抗源,为利用这些新抗源打下基础。苗期对116份供试材料人工接种美国堪萨斯州流行的小麦叶锈菌混合生理小种 (Lrcomp) ,其中部分材料人工接种09-9-1441-1等5个中国当前流行的叶锈菌生理小种进行抗性鉴定,筛选获得新抗源。116份种质中,31份免疫、近免疫或高抗Lrcomp。含有希尔斯山羊草、尾状山羊草、拟斯卑尔脱山羊草、两芒山羊草、卵穗山羊草、沙融山羊草、柱穗山羊草、顶芒山羊草、小伞山羊草、偏凸山羊草、中间偃麦草、茸毛偃麦草、长穗偃麦草、粗穗披碱草、栽培黑麦、非洲黑麦、提莫菲维染色质的部分种质免疫或高抗Lrcomp,而含二角山羊草、无芒山羊草、沙生冰草、多年生簇毛麦和一年生簇毛麦染色质的种质表现中感至高感Lrcomp。希尔斯山羊草4S染色体、尾状山羊草C#1和D#1染色体和两芒山羊草、顶芒山羊草中可能含有未被报道的抗Lrcomp的新基因,值得进一步向小麦转育。小麦-粗穗披碱草1HtS.1BL罗伯逊易位系对Lrcomp及 09-9-1441-1和09-9-1426-1等5个中国当前流行叶锈菌生理小种近免疫,值得利用染色体工程等方法获得小片段抗病易位系应用于我国小麦抗叶锈育种。     

应用原位杂交及RAPD技术标记抗黄矮病小麦一中间偃麦草染色体异附加系

以生物素（Ｂｉｏｔｉｎ－１６－ｄＵＴＰ）标记中间偃麦草基因组 ＤＮＡ为探针,与抗黄矮病小麦－中间偃麦草染色体异附加系Ｚ６进行原位杂交,鉴定出附加的１对中间偃麦草染色体。对异附加系 Ｚ６和 Ｌ１及它们的小麦亲本进行了 ＲＡＰＤ分析,从 １２０个随机引物中,筛选出 ２个引物可以扩增出附加染色体的特异ＤＮＡ片段,可作为鉴定寻人小麦的中间偃麦草染色质的分子标记。     

小麦背景下 BYDV抗性携带染色体的遗传行为

在鉴定遗4212中BYDV抗性携带染色体的染色体组起源以及被代换小麦染色体的基础上,研究了BYDV抗性携带染色体补偿小麦染色体的能力以及传递率等问题.结果表明,BYDV抗性携带染色体能较好补偿小麦第2、第5以及第7部分同源群的染色体;在二体代换系中,该染色体优先取代2D小麦染色体、而非2A、2B小麦染色体;(77-5433×遗4212)自交F2群体中共出现10种染色体组成类型,其中一种为非预期类型,染色体数目变异较大而结构变异较少;该染色体的传递率以及携带该染色体配子的传递率分别为56.3%和33%,低于理论值75%和50%;并结合遗4212染色体组成鉴定结果探讨了相关结果产生的原因.染色体原位杂交是研究小麦背景下外源染色体遗传行为快速而准确的方法.     

Molecular verification and characterization of BYDV-resistant germ plasms derived from hybrids of wheat with Thinopyrum ponticum and Th. intermedium

Twenty-five partial amphiploids (2n=8x=56), which were derived from hybrids of wheat (Triticum aestivum L.) with either Thinopyrum ponticum (Podpera) Liu & Wang, Th. intermedium (Host) Barkworth & D. Dewey, or Th. junceum (L.) A. Löve, were assayed for resistance to BYDV serotype PAV by slot-blot hybridization with viral cDNA of a partial coat protein gene. Three immune lines were found among seven partial amphiploids involving Th. ponticum. Seven highly resistant lines were found in ten partial amphiploids involving Th. intermedium. None of eight partial amphiploids or 13 addition lines of Chinese Spring — Th. junceum were resistant to BYDV. Genomic in situ hybridization demonstrated that all of the resistant partial amphiploids, except TAF46, carried an alien genome most closely related to St, whether it was derived from Th. ponticum or Th. intermedium. The two partial amphiploids carrying an intact E genome of Th. ponticum are very susceptible to BYDV-PAV. In TAF46, which contains three pairs of St- and four pairs of E-genome chromo somes, the gene for BYDV resistance has been located to a modified 7 St chromosome in the addition line L1. This indicates that BYDV resistance in perennial polyploid parents, i.e., Th. ponticum and Th. intermedium, of these partial amphiploids is probably controlled by a gene(s) located on the St-genome chromosome(s).