环形电极介导的小麦基因转化

用环形电极电激法有效地将外源DNA导入完整的小麦幼胚组织中。电激的物理参数采用770V／cm场强、800μF电容、100μg／mL质粒DNA(含有bar和GUS双标记基因),幼胚被电激3次。经PCR和Southern杂交分析表明,外源基因已稳定整合到小麦基因组中,转化频率为7．5％,高于相同处理条件下基因枪法的转化频率(4．2％)。     

一种适于PCR扩增的小麦基因组DNA快速提取法

许多小麦分子生物学研究需要对大量的小麦样品进行PCR检测,因此,建立一种快速提取小麦基因组DNA的方法十分必要。根据国外报道的一种快速提取水稻和玉米基因组DNA的方法,我们对部分提取步骤进行变动后,在小麦上进行了尝试,长度为1．5kb的片段能得到稳定的扩增。该方法样品研磨在1.5ml的离心管内进行,后续操作不用酚、氯仿、CTAB、SDS和巯基乙醇,整个提取过程不需要使用通风橱,操作步骤简单,花费时间少,而且提取的小麦基因组DNA完整性好,量也较可观。一个DNA样品可供50～100次PCR反应使用,适用于小麦遗传多样性、分子标记辅助选择、转基因后代检测以及引物筛选、分子标记定位等多种研究。     

簇毛麦基因组特异性PCR标记的建立和应用

以普通小麦中国春、簇毛麦、中国春－簇毛麦二体附加系和代换系为材料进行RAPD分析,筛选出一个簇毛麦基因组特异性RAPD片段OPFO2757,该片段分布于簇毛麦所有染色体上。在对OPFO2757进行克隆、测序的基础上,设计一对PCR引物,建立了簇毛麦基因组特异性PCR标记。用这对PCR引物对不同普通小麦品种、不同硬粒小麦品种、不同居群的簇毛麦、中国春－簇毛麦二体附加系、中国春－簇毛麦二体代换系、普通小麦－簇毛麦双二倍体、硬粒小麦－簇毛麦双二倍体等材料进行扩增,凡具有簇毛麦染色体的材料都能扩增出一条长为677bp的DNA片段,而不具簇毛麦染色体的材料包括大麦、黑麦、长穗偃麦草、中间偃麦草等不能扩增出该片段。所以,该特异性PCR标记可用于快速跟踪检测小麦背景中的簇毛麦染色体。     

小麦基因组研究进展

本文从小麦遗传图谱、物理图谱、比较基因组、基因组测序和EST 5个方面,介绍国内外小麦基因组的研究进展。我们利用W7984×Opata重组近交系的RFLP作图群体,对33个与小麦水分利用效率有关的性状进行了QTL遗传图谱比较分析,结果显明：在第一部分同源群染色体（1A,1B）上的着丝粒周围,分布有控制光合作用和根系特性的基因簇。在第二部分同源染色体上,有控制单株水分利用效率、根冠形态和生长发育的基因簇存在。在第六部分同源染色体上,6A和6B上都分别有由控制根系多个QTL组成的基因簇,6D染色体着丝粒周围有一个大的基因簇,由7个控制叶片和单株水分利用效率的QTL组成,说明第六部分同源染色体在小麦水分利用效率遗传方面起重要作用。 Abstract:Research development of genetic mapping,physics mapping,genome sequencing and expressed sequence tags in wheat have been reviewed in this paper.RFLP genetic linkage map of wheat recombinant inbred lines derived from W7984×Opata,was used to study QTL of 33 traits associated with water use efficiency.Compared with QTL map of 7 group homeologues chromosomes,the results were showed as follows:nearby the centromeric region of 1A and 1B chromosome,the gene cluster of controlling photosynthetic and root traits were located.The gene clusters of controlling water use efficiency per plant,root and plant height and growth rate were located on the 2 group chromosomes.The gene clusters of controlling root traits were located on the 6A an 6B chromosome,there was a big gene cluster mad up by 7 QTLs controlling water use efficiency of wheat leaf and per plant nearby the centromeric region of 6D chromosome.It showed that 6th homeologous chromosomes play an important role in controlling water use efficiency in wheat.     

不同小麦基因型对γ射线辐照敏感性的分子解析

本研究以63份小麦品种(系)的风干种子为材料,分别利用0 Gy、100 Gy、150 Gy和250 Gy剂量的60Coγ射线辐照,通过种子发芽试验和基因表达等方法,探讨不同小麦基因型间辐射敏感性差异及辐射敏感性相关基因的表达模式。结果表明:根据苗高损伤效应,将63份不同小麦基因型分为敏感型(核优1号、中优206和太原703等)、较敏感型(旱选10号、济麦20和中麦175等)、较钝感型(德抗961、豫麦68和淮麦20等)和钝感型(衡观136、邯6172和偃展4110等)4类。所选材料γ射线辐照后,敏感型基因型中Ta Ku70和Ta Ku80基因诱导表达明显,钝感型基因型中Ta Ku70和Ta Ku80基因诱导表达不明显。本研究表明不同小麦基因型间辐射敏感性差异明显且与Ta Ku70和Ta Ku80基因表达模式有关。     

彩色小麦基因发掘和种质资源育种利用北大核心CSCD

随着人类对彩色营养功能小麦需求越来越大,彩色小麦遗传研究越来越深入,彩色小麦品种越来越多,但我国彩色小麦种质资源家底不清。为了满足国内外对彩色小麦营养遗传育种方面的迅猛需求,本文综述了彩色小麦基因和种质资源育种利用进展,首先介绍了彩色小麦基因来源的种质资源,其次介绍了彩色小麦染色体组及系谱,第三是首次全面总结了我国彩色小麦育种和种质资源创新的进展。我国近24年来审定了61个彩色小麦品种,其中紫(黑)粒品种50个,蓝粒小麦品种10个,绿粒小麦品种1个,还育成了19个彩色小麦种质新资源,其中近4年是我国彩色小麦品种审定最多的年份。河南省、山东省、河北省、山西省是我国4大彩色小麦育种和产业化基地。彩色小麦品种大部分来源于彩色小麦和普通小麦杂交,彩色小麦基因主要来自于小麦与野生一粒小麦、野生二粒小麦、偃麦草、黑麦、赖草等远缘杂交。有48个彩色小麦品种籽粒蛋白质含量超过14%,4个彩色小麦品种籽粒蛋白质含量超过18%,4个彩色小麦品种面团稳定时间超过10 min。针对彩色小麦遗传育种和产业化存在的问题,建议作物种质资源保护与利用要遵循“有差异,就选择;能遗传,可定向;有价值,就保藏;需鉴定,要精准;扬其长,广利用”的基本原则。以上资料将为我国彩色小麦遗传育种研究提供大量有用信息和基因种质资源,推动我国彩色小麦遗传育种研究深入发展。     

苏云金芽孢杆菌毒蛋白基因在小麦基因组中的甲基化修饰

通过花粉管通道法将苏云金芽孢杆菌（Ｂａｃｉｌｌｕｓｔｈｕｒｉｎｇｉｅｎｓｉｓ）毒蛋白基因（Ｂｔ．ｔｏｘｉｎｇｅｎｅ）转进了小麦品种京花５号与８６Ａｌ。利用点杂交、Ｓｏｕｔｈｅｒｎ杂交和ＰＣＲ等技术鉴定了转化植株的当代和子代,证实了Ｂｔｔｏｘｉｎｇｅｎｅ的导入与对小麦染色体的整合。利用对腺嘌呤（Ａ）与胞嘧啶（Ｃ）甲基化敏感与否的限制性内切酶组（ｍｅｄｈｙｌａｔｉｏｎ－（ｕｎ）ｓｅｎｓｉｔｉｖｅｒｅｓｔｒｉｃｔｉｏｎｅｎｚｙｍｅｇｒｏｕｐ,ＭＲＥＧ）酶切和ＲＣＲ扩增（ＭＲＥＧ－ＰＣＲ）,对转化子代中的Ｂｔ基因片段甲基化形式进行了研究。结果表明,整合在小麦基因组中的Ｂｔ基因的Ａ和Ｃ的甲基化形式发生了变化     

琼脂糖和聚丙烯酰胺凝胶电泳技术检测小麦基因组DNA RAPD扩增产物的方法学比较

通过20%(wv)的琼脂糖凝胶和5%(wv)的聚丙烯酰胺凝胶电泳对小麦白粉病抗、感特性品种基因组DNA的RAPD检测结果表明:5%聚丙烯酰胺凝胶对线性DNA分子(01～20kb)和长度相差100bp以下的DNA分子的分离较20%的琼脂糖凝胶电泳效果好。因此,我们研究出了一项利用聚丙烯酰胺凝胶电泳检测小麦白粉病抗、感特性的新技术,在工作中建立了一种适合于检测小麦基因组DNA结构差异的电泳方法。该方法主要包括:(1)丙烯酰胺和亚甲基双丙烯酰胺的新配比;(2)分离DNA片段的最佳凝胶浓度;(3)电泳条件;(4)脱色、漂洗、银染、显色过程。实验发现,该技术对于小麦白粉病抗、感特性检测中的小片段和长度相差100bp以下的线性DNAPCR扩增结果的分辨效果较好。应用该技术在抗感品种间已经发现了DNA水平上的差异。     

硬粒小麦基因组中疑似硒蛋白生物信息分析

目的：用生物信息学的方法对硬粒小麦基因组中疑似硒蛋白的氨基酸序列进行综合分析,进一步找寻其为硒蛋白的生物信息依据,并初步分析推断其功能。方法：利用Vector NTI等多种生物信息学工具对硬粒小麦AYl46587．1序列中发现的疑似硒蛋白编码序列进行综合分析研究。结果：发现2段目标编码序列具有与某些蛋白酶相似的生物信息学特征,并推测其蛋白编码具有目前未知的机理。结论：推断AYl46587．1序列中存在编码未知硒蛋白的编码段,其编码的硒蛋白参与硬粒小麦胚芽生长发育时期能量调节。     

组蛋白去乙酰化酶抑制剂(HDACi)对小麦基因编辑效率的影响及转录组学分析

主要研究组蛋白去乙酰化酶抑制剂(HDACi)与染色质状态以及CRISPR/Cas9的编辑效率之间的关系。利用不同浓度的尼克酰胺(0,2.5和5 mmol/L)和丁酸钠(0,5和10 mmol/L)对小麦幼苗处理7 d和14 d,结果显示丁酸钠处理会抑制幼苗的生长,而尼克酰胺对幼苗影响较小。对尼克酰胺处理的小麦幼苗进行转录组测序,发现了一些有利于促进染色质状态开放的基因:6个甲基转移酶合成通路基因。此外对未发生编辑的TaAGO4a基因编辑转基因小麦材料的T2代进行尼克酰胺处理,结果显示5 mmol/L处理14 d时检测到1株3A和3B基因组均杂合编辑的植株,编辑效率从0提高到8.3%,其它处理组和对照组均没有检测到编辑。本研究证明尼克酰胺确实可以提高小麦基因编辑效率,为提高小麦基因编辑效率提供了一种新策略。     

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.     

植物外源基因组成分鉴定方法的研究进展

具外源基因组成分(外源染色体/染色体片段/基因)植株是目前进行基因组学研究以及作物改良的重要材料。迄今为止,已建立了基于性状观测、染色体分析、特异蛋白、DNA序列4种鉴定外源基因组成分的策略。其中,基于DNA序列的分子标记技术是当前鉴定外源基因组成分的主要手段,文中归纳了用于小麦、甘蓝等重要作物外源基因组成分的分子标记,且对简单重复序列(Simple sequence repeat, SSR)、插入缺失(Insertion-deletion,InDel)、单核苷酸多态性(Single nucleotide polymorphism,SNP)等9种标记进行了系统的比较。相比单一的鉴定方法,组合法更全面精准,文中对各组合法的应用情况进行统计和分析,提供了小麦族、芸薹族等作物的最佳鉴定组合。新一代分子标记InDel、SNP易实现高通量检测,对于外源渗入基因的精细定位展现了一定的优越性。此外,可以考虑一些新鉴定方法的加入,如微阵列比较基因组杂交(Microarray-based comparative genomic hybridization,array-CGH)、抑制差减杂交(Suppression subtractive hybridization,SSH)。     

非Robertsonian类型小黑麦易位系的研究

非Robertsonian类型小黑麦易位系的研究@胡含$中国科学院遗传研究所植物细胞与染色体工程国家重点实验室!北京100101小黑麦;;易位系     

Development and application of EST-based markers specific for chromosome arms of rye (Secale cereale L.)

To develop a set of molecular markers specific for the chromosome arms of rye, a total of 1,098 and 93 primer pairs derived from the expressed sequence tag (EST) sequences distributed on all 21 wheat chromosomes and 7 rye chromosomes, respectively, were initially screened on common wheat 'Chinese Spring' and rye cultivar 'Imperial'. Four hundred and fourteen EST-based markers were specific for the rye genome. Seven disomic chromosome addition lines, 10 telosomic addition lines and 1 translocation line of 'Chinese Spring-Imperial' were confirmed by genomic in situ hybridization and fluorescencein situ hybridization, and used to screen the rye-specific markers. Thirty-one of the 414 markers produced stable specific amplicons in 'Imperial', as well as individual addition lines and were assigned to 13 chromosome arms of rye except for 6RS. Six rye cultivars, wheat cultivar 'Xiaoyan 6' and accessions of 4 wheat relatives were then used to test the specificity of the 31 EST-based markers. To confirm the specificity, 4 wheat-rye derivatives of 'Xiaoyan 6 × German White', with chromosomes 1RS, 2R and 4R, were amplified by some of the EST-based markers. The results indicated that they can effectively be used to detect corresponding rye chromosomes or chromosome arms introgressed into a wheat background, and hence to accelerate the utilization of rye genes in wheat breeding.     

应用荧光原位杂交和RFLP标记检测多小穗小麦新种质10-A中的黑麦染色质

利用ＡＰＡＧＥ、荧光原位杂交技术和ＲＦＬＰ标记,对导入黑麦（ＳｅｃａｌｅｃｅｒｅａｌｅＬ．）多小穗等性状创制的小麦新种质１０＿Ａ进行了分子标记检测。ＡＰＡＧＥ分析发现,１０＿Ａ与其他１ＲＳ／１ＢＬ易位系一样,含有１ＲＳ的醇溶蛋白标记位点Ｇｌｄ１Ｂ３。以黑麦基因组总ＤＮＡ作探针,用中国春（Ｔｒｉｔｉｃｕｍａｅｓｔｉｖｕｍｃｖ．ＣｈｉｎｅｓｅＳｐｒｉｎｇ）基因组ＤＮＡ作封阻,与１０＿Ａ根尖细胞有丝分裂染色体进行荧光原位杂交。结果表明,黑麦的１ＲＳ易位到１０＿Ａ中。用２５个ＲＦＬＰ探针进行Ｓｏｕｔｈｅｒｎ分析,进一步发现１０＿Ａ的１ＢＳ特异限制性片段发生丢失,代之以黑麦１ＲＳ的特异限制性片段,而位于其他染色体上的特异限制性片段未发生缺失。据此认为,多小穗小麦新种质１０＿Ａ属于１ＲＳ／１ＢＬ易位系。同时还讨论了１０＿Ａ在小麦遗传改良中的利用情况。     

Isolation and characterization of wheat-rye recombinants involving chromosome arm 1DS of wheat

Summary The introgression of genetic material from alien species is assuming increased importance in wheat breeding programs. One example is the translocation of the short arm of rye chromosome 1 (1RS) onto homoeologous wheat chromosomes, which confers disease resistance and increased yield on wheat. However, this translocation is also associated with dough quality defects. To break the linkage between the desirable agronomic traits and poor dough quality, recombination has been induced between 1RS and the homoeologous wheat arm IDS. Seven new recombinants were isolated, with five being similar to those reported earlier and two havina new type of structure. All available recombinantsw ere characterized with DNA probes for the loci Nor-R1, 5SDna-R1, and Tel-R1. Also, the amount of rye chromatin present was quantified with a dispersed rye-specific repetitive DNA sequence in quantitative dot blots. Furthermore, the wheat-rye recombinants were used as a mapping tool to assign two RFLP markers to specific regions on chromosome arms 1DS and 1RS of wheat and rye, respectively.     

Whole genome development of intron targeting (IT) markers specific for <Emphasis Type="Italic">Dasypyrum villosum</Emphasis> chromosomes based on next-generation sequencing technology

Dasypyrum villosum (Dv), a wild relative of wheat, is an important and useful gene resource for wheat improvement. A large number of wheat-Dv aneuploid lines harboring whole or fragments of Dv chromosomes have been developed. However, the lack of sufficient molecular markers hindered accurate identification of Dv chromatin, especially when the introgressed fragments are small. Development of molecular markers covering the whole Dv genome and evenly distributed on different chromosome regions is not only useful for the detection of the introgressed alien chromatin in wheat background, but also provides evidence of the syntenic relationship between homoeologous chromosomes. In the present study, in order to develop high density and evenly distributed molecular markers on individual Dv chromosomes, genomic DNA of Dv leaves was sequenced and assembled. Sequence assemblies of all wheat chromosomes were first used to identify exon–exon junctions and localize introns in Dv. Intron length polymorphisms suitable for designing Dv primers flanking introns were evaluated, and a total of 1624 intron targeting (IT) markers was designed. By using the Chinese Spring, the Triticum durum-Dv amphiploid and the Dv sequenced DNA libraries, 841 IT molecular markers specific for Dv chromosomes were developed, with maximum efficiency up to 51.79%. We assigned the 841 IT markers to seven Dv chromosomes (1V–7V) using seven wheat–Dv chromosome addition and substitution lines: 135 to 1V, 175 to 2V, 120 to 3V, 89 to 4V, 140 to 5V, 71 to 6V, and 111 to 7V, respectively. Using T. aestivum-Dv telosomic and whole arm translocation lines, they were further located on the short or long chromosome arms. These specific markers for individual chromosomes of Dv provided efficient tools for the characterization of structural variation involving the individual chromosome of Dv, as well as for the selection of useful genes located on individual Dv chromosome in breeding programs.     

Use of fluorescence genomic in situ hybridization (GISH) to detect the presence of alien chromatin in wheat lines differing in nuclear DNA content

BACKGROUND: Many times small differences in genome size are reported between or within plant species in which no cytologic confirmation is made. Attempts to repeat these studies have met with limited success. The controversy then becomes whether or not these small differences that were not confirmed cytologically are real. The present study was undertaken to determine if the approximately 1% nuclear variation seen by flow cytometry among wheat lines selected for aluminum response was due to actual chromatin differences. METHODS: The three parental wheat cultivars used in the aluminum selection along with the isolines resulting from the selection were analyzed. One parental line had previously been reported to have alien chromatin substituted for the corresponding wheat homologous chromatin. Genomic in situ hybridization was used to determine the presence or absence of rye chromatin in three cultivars and six near-isolines of wheat. RESULTS: Upon observing metaphase chromosomes of the Century parent and its isolines, two of the chromosomes were observed to be one-half yellow-orange, indicating rye chromatin with the remaining portion of the chromosomes and the other 40 wheat chromosomes having no label indicating wheat chromatin. In the Chisholm parent and its isolines, none of the chromosomes were labeled, indicating the absence of rye chromatin. In addition, none of the third parents' chromosomes had the rye yellow-orange signal. CONCLUSIONS: The wheat lines with the larger DNA contents were observed to have alien DNA present. DNA differences between the normal wheat chromosomes and the substituting alien chromatin were calculated based on total chromosome length. The increase in genome size of the wheat lines containing the alien chromatin appears to be the result of the alien chromatin having approximately 43% more DNA than the wheat chromatin it is replacing. Thus, the small DNA difference previously reported by flow cytometry was demonstrated to be a real DNA variation due to the presence of small fragments of alien chromosomes added to the wheat genome.     

A comparative genetic and cytogenetic mapping of wheat chromosome 5B using introgression lines

The genetic map of chromosome 5B has been constructed by using microsatellite (SSR) analysis of 381 plants from the F2 population produced by cross of the Chinese Spring (CS) and Renan cultivars. Initially, 180 SSR markers for the common wheat 5B chromosome have been used for analysis of these cultivars. The 32 markers able to detect polymorphism between these cultivars have been located on the genetic map of chromosome 5B. Cytogenetic mapping has involved a set of CS 5B chromosome deletion lines. Totally, 51 SSR markers have been located in ten regions (deletion bins) of this chromosome by SSR analysis of these deletion lines. Five genes—TaCBFIIIc-B10, Vrn-B1, Chi-B1, Skr, and Ph1—have been integrated into the cytogenetic map of chromosome 5B using the markers either specific of or tightly linked to the genes in question. Comparison of the genetic and cytogenetic maps suggests that recombination is suppressed in the pericentromeric region of chromosome 5B, especially in the short arm segment. The 18 markers localized to deletion bins 5BL16-0.79-1.00 and 5BL18-0.66-0.79 have been used to analyze common wheat introgression lines L842, L5366-180, L73/00i, and L21-4, carrying fragments of alien genomes in the terminal region of 5B long arm. L5366-180 and L842 lines carry a fragment of the Triticum timopheevii 5GL chromosome, while L73/00i and L21-4 lines, a fragment of the Aegilops speltoides 5SL chromosome. As has been shown, the translocated fragments in these four lines are of different lengths, allowing bin 5BL18-0.66-0.79 to be divided into three shorter regions. The utility of wheat introgression lines carrying alien translocations for increasing the resolution of cytogenetic mapping is discussed.     

Molecular and cytological characterization of genomic variability in hexaploid wheat 'Lindstr?m'.

'Lindstr?m' wheat (AABBDD+rye B chromosomes) was used to study the effects of alien chromatin introgressed into a wheat genetic background, subjecting the wheat genome to a new and transient allopolyploidisation episode. Using this experimental material, we have previously demonstrated that no large-scale chromosomal translocations occurred as a result of the genomic constitution of the addition line. However, we have shown that the presence of a number of rye B chromosomes is associated with changes in the interphase organization and expression patterns of wheat rDNA loci. We have now extended our studies to focus on a further characterization of 'Lindstr?m' 5S rDNA loci and also on high molecular weight glutenin subunit (HMW-GS) patterns. In the process, we have uncovered an unusually large variant of the 5S rDNA locus on wheat chromosome 1B (not to be confused with rye B chromosomes) and 2 novel HMW glutenin y-type alleles. These changes are not directly related to variation in rye B chromosome number in the present material, but the fact that a new, and still segregating, 1Dy HMW-GS gene was identified indicates a recent timescale for its origin. Strikingly, the 'Lindstr?m' 5S rDNA 1B locus integrates a unit sharing 94% homology with a rye 5S rDNA sequence, suggesting the possibility that the wheat locus was colonized by highly homologous rye sequences during the breeding of 'Lindstr?m', when the rye and wheat genomes were together, albeit briefly, in the same nucleus.