Genomic changes at early stages of formation of allopolyploid <Emphasis Type="Italic">Aegilops longissima × Triticum urartu</Emphasis>

Using the model of synthetic allopolyploid Aegilops longissima TL05 × Triticum urartu TMU06 of the first generation, the degree and character of changes in subtelomeric, microsatellite and random amplified DNA sequences (RAPD) on early stage of polyploidization was estimated. Study of genome changes was performed by comparing PCR fragments of the allopolyploid and its parental forms. For analysis of subtelomeric DNA, we used 66 pairs of primers composed of 11 singular primers designed for these chromosomal regions sequences of cereals. RAPD analysis was performed with usage of 38 primers, in microsatellite (SSR) analysis 23 primer pairs were used. RAPD analysis appeared to be a more effective PCR-based method to identify genome changes. Absence of some RAPD fragments typical for parental genome in allopolyploid TL05 × TMU06 was shown using 13 primers of 38 (34%), and with usage of subtelomeric primers the changes in PCR fragments were shown only for one of 66 pairs of primers (1.5%). SSR loci were stable during the polyploidization process. Subsequent analysis of PCR fragments absent in the synthetic allopolyploid showed that high level of genome changes in RAPD analysis is probably connected with more effective ability of this method to reveal point mutations. Some data was found suggesting that not all genome changes observed in experimentally synthesized allopolyploids of the first generation are consequences of coadaptation of few genomes in one nucleus.     

Rapid changes of microsatellite flanking sequence in the allopolyploidization of new synthesized hexaploid wheat

Polyploidy has been found to be very common inplants. Comparative genome studies have revealed thateven species that were considered as typical diploidsincluding maize[1], soybean[2], Arabidopsis[3] have un-dergone polyploidization during their evolution. Ge-nome polyploidization is a major force of evolutionthat affects genome size and gene copy number[4,5]. Polyploids can be formed via the duplication ofgenomes, either of the same genomes (autopolyploid)or of diverged genomes with homoe…     

Rapid changes of microsatellite flanking sequence in the allopolyploidization of new synthesized hexaploid wheat

It was suggested that the rapid changes of DNA sequence and gene expression occurred at the early stages of allopolyploid formation. In this study, we revealed the microsatellite (SSR) differences between newly formed allopolyploids and their donor parents by using 21 primer sets specific for D genome of wheat. It was indicated that rapid changes had occurred in the “shock” process of the allopolyploid formation between tetraploid wheat and Aegilops tauschii. The changes of SSR flanking sequence resulted in appearance of novel bands or disappearance of parental bands. The disappearance of the parental bands showed much higher frequencies in comparison with that of appearance of novel bands. Disappearance of the parental bands was not random. The frequency of disappearance in tetraploid wheat was much higher than in Ae. tauschii, i. e. the disappearance frequency in AABB genome was much higher than in D genome. Changes of SSR flanking sequence occurred at the early stage of F₁ hybrid or just after chromosome doubling. From the above results, it can be inferred that SSR flanking sequence region was very active and was amenable to change in the process of polyploidization. This suggested that SSR flanking sequence probably had special biological function at the early stage of ployploidization. The rapid and directional changes at the early stage of polyploidization might contribute to the rapid evolution of the newly formed allopolyploid and allow the divergent genomes to act in harmony.     

Analysis of 5S rDNA changes in synthetic allopolyploids Triticum x Aegilops

By the example of three synthetic allopolyploids: Aegilops sharonensis x Ae. umbellulata (2n =28), Triticum urartu x Ae. tauschii (2n =28), T. dicoccoides x Ae. tauschii (2n =42) the 5S rDNA changes at the early stage of allopolyploidization were investigated. Using fluorescent in situ hybridization (FISH), the quantitative changes affecting the separate loci of one of the parental genomes were revealed in plants of S3 generation of each hybrid combination. Souther hybridization with genomic DNA of allopolyploid T. urartu x Ae. tauschii (TMU38 x TQ27) revealed lower intensity of the fragments from Ae. tauschii compared with the T. urartu fragments. It may be confirmation of the reduction of signal on 1D chromosome that was revealed in this hybrid using FISH. Both appearance of a new 5S rDNA fragments and full disappearance of fragments from parental species were not showed by Southern hybridization, as well as PCR-analysis of 5-15 plants of S2-S3 generations. The changes were not found under comparison of primary structure of nine 5S rDNA sequences of allopolyploid TMU38 x TQ27 with analogous sequences from parental species genomes. The observable similarity by FISH results of one of the studied synthetic allopolyploids with natural allopolyploid of similar genome composition indicates the early formation of unique for each allopolyploid 5S rDNA organization.     

Variations of tandem repeat, regulatory element, and promoter regions revealed by wheat-rye amphiploids.

To better understand the evolution of allopolyploids, 4 different combinations between wheat (Triticum aestivum L.) and rye (Secale cereale L.) including 12 F1 hybrids and 12 derived amphiploids were analyzed and compared with their direct parental plants by PCR analysis using 150 wheat SSR (single sequence repeat) markers and by FISH analysis using a rye-specific repetitive sequence (pSc200) as a probe. Nine SSR markers amplified rye-specific fragments whose sizes ranged from 471 bp to 1089 bp. These fragments contain regulatory elements and (or) promoters. Some of these fragments were amplified from all 24 progenies, while others were amplified from a subset of the progenies. The disappearance of rye-specific fragments from some progenies was caused by sequence elimination or DNA modification. Marker Xgwm320 amplified a new fragment (403 bp), a rye-specific tandem repeat, from some of the progenies. Twenty-eight SSR markers displayed microsatellite variation in progenies derived from 'Chinese Spring' x 'Jinzhou-heimai', but none of the 150 SSR markers displayed microsatellite variation in the progenies derived from the other three combinations. FISH signals of pSc200 were eliminated from one telomere/subtelomere of 4 chromosomes of 'Kustro' during allopolyploidization and expanded in amphiploids derived from 'Chinese Spring' x 'AR106BONE'. Thus, allopolyploidization in wheat-rye can be accompanied by rapid variation of tandem repeats, regulatory elements, and promoter regions. The alterations of repetitive sequence pSc200 indicate coordination between the constituent genomes of the newly formed amphiploids. Different genetic backgrounds of parents appear to affect genome changes during allopolyploidization.     

小麦A/B染色体组SSR标记在新小麦合成前后的比较研究

微卫星分子标记已广泛用于普通小麦遗传和进化研究。由于人工合成小麦与小麦品种之间存在高的遗传多样性,人工合成小麦已被大量应用于小麦分子标记工作中。但是,目前还缺乏人工合成小麦的异源六倍化过程对微卫星影响的研究。本研究直接比较了四倍体小麦与节节麦远缘杂交并经染色体加倍获得人工合成小麦前后,位于普通小麦A/B染色体组不同染色体臂上的66个特异引物揭示的微卫星位点的保守性和可转移性。结果表明,除了一个引物在新合成小麦中扩增出供体亲本没有的新带,一个引物在节节麦扩增出的产物在新合成小麦中消失,其他的所有微卫星引物的扩增产物在小麦合成前后是保守的,没有变异发生。所有的引物能够在四倍体小麦中扩增出微卫星产物,四倍体小麦中的扩增产物也出现在新的人工合成小麦中;有70%的引物能够在节节麦扩增出产物,其中的绝大多数产物也出现在新的人工合成小麦中。因此,普通小麦A/B染色体组的这些微卫星引物除了在人工合成小麦的A/B染色体组中扩增出产物,还能在其D染色体组中扩增出产物,也就是说,这些引物对人工合成小麦而言,并非是A/B染色体组特异的。根据该研究结果,讨论了小麦微卫星的可转移性和特异性问题,重点讨论了在应用人工合成小麦构建的遗传群体进行微卫星分子标记中的应用价值及其应该注意的问题。     

巴氏蘑菇微卫星序列的分离及其对Co60辐射诱变菌株的鉴别

根据链霉素磁珠和生物素特异结合的特性,用生物素标记的二聚核苷酸重复序列探针从巴氏蘑菇的基因组中分离微卫星序列。将结合于链霉素磁珠上的标记探针同两端连接已知序列人工接头的巴氏蘑菇DNA酶切片段杂交。洗脱未杂交DNA片段后,用磁珠富集的片段建立微卫星文库。挑取522个菌落用对应重复序列为引物进行PCR筛选,得到48个阳性克隆,经测序有32个菌落含微卫星序列。微卫星富集效率为阳性克隆数的67%,总克隆数的6%。除去重复或无效的微卫星序列,在设计出的12对用于鉴别85个巴氏蘑菇的Co60辐射变异株微卫星引物中,有4对引物总共扩增出明显的变异菌株17个。证明有些微卫星位点可用于巴氏蘑菇辐射变异品种的指纹筛选与鉴别。     

Analysis of 5S rDNA changes in synthetic allopolyploids <Emphasis Type="Italic">Triticum</Emphasis> × <Emphasis Type="Italic">Aegilops</Emphasis>

Changes of 5S rDNA at the early stage of allopolyploidization were investigated in three synthetic allopolyploids: Aegilops sharonensis × Ae. umbellulata (2n = 28), Triticum urartu × Ae. tauschii (2n = 28), and T. dicoccoides × Ae. tauschii (2n = 42). Fluorescent in situ hybridization (FISH) revealed quantitative changes affecting separate loci of one of the parental genomes in S₃ plants of each hybrid combination. Southern hybridization with genomic DNA of the allopolyploid T. urartu × Ae. tauschii (TMU38 × TQ27) revealed a lower intensity of signals from Ae. tauschii fragments compared with those derived from T. urartu. This confirmed the signal reduction revealed for chromosome 1D of this hybrid by FISH. Neither Southern hybridization nor PCR testing of 5–15 plants of the S₂-S₃ generations revealed an appearance of new 5S rDNA fragments or a complete disappearance of parental fragments from the allopolyploids under study. No changes were found by aligning nine 5S rDNA sequences of the allopolyploid TMU38 × TQ27 with corresponding sequences of the parental species. The similarity between one of the synthetic allopolyploids examined and a natural allopolyploid with the same genome composition points to an early formation of the 5S rDNA organization unique for each allopolyploid.     

Detection of the introgression of genome elements of the Aegilops cylindrica host. into the Triticum aestivum L. genome by ISSR and SSR analysis

To reveal sites of the donor genome in wheat crossed with Aegilops cylindrica, which acquired conferred resistance to fungal diseases, a comparative analysis of introgressive and parental forms was conducted. Two systems of PCR analysis, ISSR and SSR-PCR, were employed. Upon use of 7 ISSR primers in genotypes of 30 individual plants BC1 F9 belonging to lines 5/55-91 and 5/20-91, 19 ISSR loci were revealed and assigned to introgressive fragments of Aegilops cylindrica genome in Triticum aestivum. The 40 pairs of SSR primers allowed the detection of seven introgressive alleles; three of these alleles were located on common wheat chromosomes in the B genome, while four alleles, in the D genome. Based on data of microsatellite analysis, it was assumed that the telomeric region of the long arm of common wheat chromosome 6A also changed. ISSR and SSR methods were shown to be effective for detecting variability caused by introgression of foreign genetic material into the genome of common wheat.     

Detection of the introgression of genome elements of the <Emphasis Type="Italic">Aegilops cylindrica</Emphasis> host into the <Emphasis Type="Italic">Triticum aestivum</Emphasis> L. genome by ISSR and SSR analysis

To reveal sites of the donor genome in wheat crossed with Aegilops cylindrica, which acquired conferred resistance to fungal diseases, a comparative analysis of introgressive and parental forms was conducted. Two systems of PCR analysis, ISSR and SSR–PCR, were employed. Upon use of 7 ISSR primers in genotypes of 30 individual plants BC₁F₉ belonging to lines 5/55-91 and 5/20-91, 19 ISSR loci were revealed and assigned to introgressive fragments of Aegilops cylindrica genome in Triticum aestivum. The 40 pairs of SSR primers allowed the detection of seven introgressive alleles; three of these alleles were located on common wheat chromosomes in the B genome, while four alleles, in the D genome. Based on data of microsatellite analysis, it was assumed that the telomeric region of the long arm of common wheat chromosome 6A also changed. ISSR and SSR methods were shown to be effective for detecting variability caused by introgression of foreign genetic material into the genome of common wheat.Translated from Genetika, Vol. 40, No. 12, 2004, pp. 1654–1661.Original Russian Text Copyright © 2004 by Galaev, Babayants, Sivolap.     

一种新的分子标记方法－随机微卫星扩增多态DNA (RMAPD)

随机微卫星扩增多态DNA（RMAPD）是利用随机引物和微卫星的上游或下游引物一起作为该扩增的引物,在Taq DNA聚合酶、MgCl2、dNTPs和模板DNA等共同作用下进行PCR扩增的一种新型分子标记方法。其核心是RMAPD引物的有效性问题。通过对西农萨能奶山羊群体RMAPD电泳检测、数据统计分析及验证实验等证明RMAPD的引物是有效的。通过与微卫星和RAPD标记比较,发现RMAPD标记在扩增引物、扩增程序和重复性等方面区别于微卫星和RAPD标记;它是RAPD标记的一种广义的延伸,但又不完全等同于RAPD标记。因此,确定RMAPD是一种新的分子标记方法。该方法也具有DNA标记的特点,在群体遗传结构和亲缘关系分析以及标记辅助选择等遗传育种领域具有广阔的应用前景。     

荔枝SSR标记的研究

以无核荔枝A4号为实验材料,应用选择性扩增微卫星（SAM）法分离、克隆了100个简单序列重复（SSR）序列,其中88个非重复,可用。加上搜索数据库所获得的1个SSR序列,一共89个序列用于特异引物的设计。仅从71个序列的82个基因座设计出特异引物。合成41条特异引物(与5′锚定简并引物配对,个别相互配对),对其中的39个基因座进行检测。其中15对引物扩增出相应大小的片段,另外11对引物扩增出非预期片段。最后,以37个荔枝种质的基因组DNA为模板,从26对出带的引物中,筛选出多态性引物21对,获得了22个荔枝基因座特异性SSR标记。     

Identification of wild and cultivated Hordeum species using two-primer RAPD fragments

Random amplified polymorphic DNAs (RAPD) analysis has been adapted to assess the degree of RAPD polymorphism within the genus Hordeum to determine if this approach can distinguish wild and cultivated species. Nineteen wild and seven cultivated accessions were evaluated using 4 random 10-mer primers. The potential of the RAPD assay was further increased by combining two primers in a single polymerase chain reaction (PCR). RAPD fragments generated by two pairs of arbitrary 10-mer primers discriminated six wild species and one cultivated species by banding profiles. The size of the amplified DNA fragments ranged from 150 to 2300 base pairs. 33 %percent of the fragments were common to both wild and cultivated species; 67% were specific to either wild or cultivated species. The average difference in fragments was less within the species than among the species. By comparing RAPD fingerprints of wild and cultivated barley, markers were identified among the set of amplified DNA fragments which could be used to distinguish wild and cultivated Hordeum species. This revised version was published online in July 2006 with corrections to the Cover Date.     

RAPD及SRAP两种分子标记技术对苦瓜杂交种纯度的鉴定分析

以F1代苦瓜杂交种如玉11号及其亲本为材料,利用RAPD及SRAP两种分子标记技术对这3种苦瓜基因组DNA进行比较分析,以获得该杂交种及其亲本（或母本）差异目的基因片段。经过多次对该3种苦瓜叶片DNA提取,PCR扩增及其PCR产物的琼脂糖凝胶电泳分析,在供试的46个RAPD引物及121对SRAP引物中,筛选出1个RAPD引物及1对SRAP引物能区分该苦瓜杂交种及其母本种子,通过进一步验证分析,证明该两种分子标记的特异引物可作为如玉11号苦瓜杂交种子的纯度鉴定之用。     

Regeneration of asymmetric somatic hybrid plants from the fusion of two types of wheat with Russian wildrye

Two types of protoplasts of wheat (Triticum aestivum L. cv. Jinan 177) were used in fusion experiments—cha9, with a high division frequency, and 176, with a high regeneration frequency. The fusion combination of either cha9 or 176 protoplasts with Russian wildrye protoplasts failed to produce regenerated calli. When a mixture of cha9 and 176 protoplasts were fused with those of Russian wildrye, 14 fusion-derived calli were produced, of which seven differentiated into green plants and two differentiated into albinos. The morphology of all hybrid plants strongly resembled that of the parental wheat type. The hybrid nature of the cell lines was confirmed by cytological, isozyme, random amplified polymorphic DNA (RAPD) and genomic in situ hybridization (GISH) analyses. GISH analysis revealed that only chromosome fragments of Russian wildrye were transferred to the wheat chromosomes of hybrid calli and plants. Simple sequence repeat (SSR) analysis of the chloroplast genome of the hybrids with seven pairs of wheat-specific chloroplast microsatellite primers indicated that all of the cell lines had band patterns identical to wheat. Our results show that highly asymmetric somatic hybrid calli and plants can be produced via symmetric fusion in a triparental fusion system. The dominant effect of two wheat cell lines on the exclusion of Russian wildrye chromosomes is discussed.Abbreviations GISH Genome in situ hybridization - RAPD Random amplified polymorphic DNA - SCF Small chromosome fragment - SSR Simple sequence repeat     

Pathogenic and molecular characterisations of pigeonpea wilt pathogen Fusarium udum

Thirty two pathogenic isolates of Fusarium udum from different pigeonpea growing areas in India were studied for pathogenic and molecular variability. Pathogenic variability was tested on 12 pigeonpea differential genotypes, which revealed prevalence of five variants in F. udum. The amount of genetic variation was evaluated by Polymerase Chain Reaction (PCR) amplification with 20 random amplified polymorphic DNA (RAPD) markers and nine microsatellite markers. All amplifications revealed scorable polymorphisms among the isolates, and a total of 137 polymorphic fragments were scored for the RAPD markers and 16 alleles for the simple sequence repeat (SSR) markers. RAPD primers showed 86% polymorphism. Genetic similarity was calculated using Jaccard's similarity coefficient and cluster analysis was used to generate a dendrogram showing relationships between them. Isolates could be grouped into three subpopulations based on molecular analysis. Results indicated that there is high genetic variability among a subpopulation of F. udum as identified by RAPD and SSR markers and pathogenicity on differential genotypes.     

基于转录组数据的齿缘刺猎蝽微卫星分子标记开发

【目的】齿缘刺猎蝽Sclomina erinacea是我国猎蝽科天敌昆虫常见种类,其不同地理种群存在明显形态差异。本研究旨在利用已经获得的齿缘刺猎蝽转录组数据筛选微卫星位点,为齿缘刺猎蝽种群遗传多样性和遗传分化研究开发可靠的微卫星分子标记。【方法】基于高通量测序技术平台Illumina HiSeq^TM 2000获得齿缘刺猎蝽转录组数据(42 215条unigenes),利用MISA软件进行搜索发掘SSR标记;利用Primer Premier 3软件设计SSR引物,从中随机选取54对SSR引物,利用PCR技术在中国齿缘刺猎蝽9个地理种群上进行验证。【结果】利用MISA软件搜索到微卫星位点2 395个,它们分布在2 107条unigenes上,其主要重复类型是三核苷酸重复(占总SSR的44.43%),其次是二核苷酸重复(占总SSR的40.08%),再次是四核苷酸重复(占总SSR的12.94%)。利用Primer Premier 3 软件成功设计出2 000余对SSR引物。随机选取的54对引物对9个齿缘刺猎蝽不同地理种群进行的SSR位点PCR扩增结果表明,共有16对引物较好地扩增出目的片段。【结论】研究表明利用齿缘刺猎蝽转录组数据可以大量发掘微卫星分子标记。本研究为进一步开展齿缘刺猎蝽的种群遗传学研究奠定了基础。     

磁珠富集法开发北柴胡多态性简单序列重复标记

目的:利用磁珠富集法分离北柴胡微卫星序列,以开发北柴胡微卫星引物,获得有多态性的简单序列重复(SSR)标记。方法:用生物素标记的混合探针(AC)15、(AG)15、(MAB)12和两端连接已知序列人工接头的北柴胡基因组DNA酶切片段混和后与磁珠杂交,构建微卫星序列富集的小片段插入文库;利用接头引物分别与生物素探针引物Biotin-(AC)15、Biotin-(AG)15、Biontin-(MAB)12形成3个组合,用PCR方法对文库进行初步筛选;对可能的阳性克隆子进行测序复筛,选取微卫星侧翼序列足够长的序列设计引物,用荧光标记的基因分型技术以栽培柴胡种质为材料分析其多态性。结果:开发了5对多态性SSR标记,它们在5份柴胡栽培种质中共扩增出30.70个多态性等位基因,平均每条引物可以扩增出6.14个多态性等位基因;观察等位基因数最多13个,最少3个;有效等位基因数最多11.4个,最少1.6个。同时分析了4对EST-SSR引物,比较了2种SSR标记扩增结果。结论:磁珠富集法是开发柴胡多态性SSR标记的有效方法。     

Sequence-tagged microsatellite profiling (STMP): a rapid technique for developing SSR markers

We describe a technique, sequence-tagged microsatellite profiling (STMP), to rapidly generate large numbers of simple sequence repeat (SSR) markers from genomic or cDNA. This technique eliminates the need for library screening to identify SSR-containing clones and provides an approximately 25-fold increase in sequencing throughput compared to traditional methods. STMP generates short but characteristic nucleotide sequence tags for fragments that are present within a pool of SSR amplicons. These tags are then ligated together to form concatemers for cloning and sequencing. The analysis of thousands of tags gives rise to a representational profile of the abundance and frequency of SSRs within the DNA pool, from which low copy sequences can be identified. As each tag contains sufficient nucleotide sequence for primer design, their conversion into PCR primers allows the amplification of corresponding full-length fragments from the pool of SSR amplicons. These fragments permit the full characterisation of a SSR locus and provide flanking sequence for the development of a microsatellite marker. Alternatively, sequence tag primers can be used to directly amplify corresponding SSR loci from genomic DNA, thereby reducing the cost of developing a microsatellite marker to the synthesis of just one sequence-specific primer. We demonstrate the utility of STMP by the development of SSR markers in bread wheat.