基于陆地棉茎尖转录组序列的genic-SSR标记的开发与评价

利用软件MISA和SSR Locator 对陆地棉（Gossypium hirsutum L.）Coker312茎尖转录组测序得到的73515条Unigene序列进行分析,查找到4507个SSR位点,分布于4039条转录本序列中,SSR出现频率为5.5%,非编码区的SSR位点要显著高于编码区（2853/1654）。SSR重复基元中,三核苷酸重复基元占主导地位（51.03%）,且AAG/CTT （20.08%）类型最多;其次是二核苷酸重复基元（28.76%）,主要为AG/CT（55.47%）。利用引物批量设计软件共开发1569对SSR引物,在陆地棉TM-1、海岛棉3-79 (G. barbadense L.)、阿非利加棉(G. herbaceum L.)、雷蒙德氏棉(G. raimondii Ulbrich.)四个棉种中进行初步评价,其中1117对引物能在四个棉种间扩增出稳定的条带,扩增率为71.2%。选择650对能稳定扩增出条带的引物,在涉及5个棉种（增加了亚洲棉（G. arboreum L.））的13份材料中进一步筛选,83对引物能在13份材料中扩增出特异性条带, PIC变幅在0.121～0.648之间,平均值为0.422,其中80对引物能在7份陆地棉材料中扩增出特异性条带,平均PIC值为0.336;挑选5对在本实验室作图亲本鲁棉研22和鲁原343间有明显多态的引物进行连锁分析,其中4对成功连锁到本实验室构建的遗传图谱上。本研究丰富了棉属genic-SSR的数量,为棉属遗传作图、性状关联分析提供了更多引物选择。     

Selection of highly informative and user-friendly microsatellites (SSRs) for genotyping of cultivated potato

Characterization of nearly 1,000 cultivated potato accessions with simple sequence repeats (SSRs; also referred to as microsatellites) has allowed the identification of a reference set of SSR markers for accurate and efficient genotyping. In addition, 31 SSRs are reported here for a potato genetic map, including new map locations for 24 of them. A first criterion for this proposed reference set was ubiquity of the SSRs in the eight landrace cultivar groups of the potato, Solanum tuberosum. All SSRs tested in the present study displayed the same allele phenotypes and allele size range in the diverse germplasm set as in the advanced potato cultivar germplasm in which they were originally discovered. Thirteen of 13 SSR products from all cultivar groups are shown to cross-hybridize with the corresponding SSR product of the source cultivar to ascertain sequence homology. Other important SSR selection criteria are quality of amplification products, locus complexity, polymorphic index content, and well-dispersed location on a potato genetic map. Screening of 156 SSRs allowed the identification of a highly informative and user-friendly set comprising 18 SSR markers for use in characterization of potato genetic resources. In addition, we have identified true- and pseudo-multiplexing SSRs for even greater efficiency.Communicated by F. Salamini     

基于转录组数据高通量发掘扶桑绵粉蚧微卫星引物

【目的】扶桑绵粉蚧Phenacoccus solenopsis Tinsley是我国重要的检疫性害虫。简单重复序列(simple sequence repeat,SSR)研究在遗传图谱和物理图谱的构建、分子标记辅助育种、品种鉴定、基因定位、遗传多样性、动植物分类和进化等方面具有重要意义。筛选的SSR引物将为扶桑绵粉蚧遗传多样性分析、进化分析及入侵生物学等奠定基础。【方法】利用高通量搜索的方法对扶桑绵粉蚧转录组中28 120条unigenes的数据进行搜索。【结果】共找到1 781个SSR位点。扶桑绵粉蚧转录组中SSRs的主要重复类型是单核苷酸重复,占SSR总数的89.44%;其次是三核苷酸重复,占SSR总数的7.52%。单核苷酸重复里主要是A/T基序,占了总量的87.42%。基于筛选的SSRs,运用Primer 3软件进行引物的批量设计,共有481个unigenes成功设计引物,共设计出1 228对引物。【结论】研究表明利用扶桑绵粉蚧转录组数据开发SSR标记是可行的,本研究开发的引物将为扶桑绵粉蚧遗传多样性分析、进化分析及入侵生物学等奠定基础。     

Mapping and characterization of new EST-derived microsatellites for potato (Solanum tuberosum L.)

Microsatellites, or simple sequence repeats (SSRs) are very useful molecular markers for a number of plant species. They are commonly used in cultivar identification, plant variety protection, as anchor markers in genetic mapping, and in marker-assisted breeding. Early development of SSRs was hampered by the high cost of library screening and clone sequencing. Currently, large public SSR datasets exist for many crop species, but the number of publicly available, mapped SSRs for potato is relatively low (~100). We have utilized a database mining approach to identify SSR-containing sequences in The Institute For Genomic Research Potato Gene Index database (), focusing on sequences with size polymorphisms present in this dataset. Ninety-four primer pairs flanking SSR sequences were synthesized and used to amplify potato DNA. This study rendered 61 useful SSRs that were located in pre-existing genetic maps, fingerprinted in a set of 30 cultivars from South America, North America, and Europe or a combination thereof. The high proportion of success (65%) of expressed sequence tag-derived SSRs obtained in this work validates the use of transcribed sequences as a source of markers. These markers will be useful for genetic mapping, taxonomic studies, marker-assisted selection, and cultivar identification.     

Sequence Polymorphism Discovery in Wheat Microsatellite Flanking Regions using Pyrophosphate Sequencing

Sequence polymorphisms such as insertion/deletions (indels) and single nucleotide polymorphisms (SNP) are suitable for automated analysis of molecular markers and useful for cultivar identification, genetic mapping and trait association. While they are abundant, their initial discovery, comprising detection, validation and characterisation of sequence polymorphisms, is time consuming and expensive. This is especially true for multi-allellic hexaploid wheat. We investigated simple sequence repeat (SSR) flanking regions as a source for sequence polymorphisms in wheat. SSRs have a potentially high polymorphic frequency, there are a large number of highly characterised markers available, tested primers are published and most are single locus. Of 126 markers investigated, polymorphisms were found in 33 (26%) when tested in 10 wheat varieties. No new primers needed to be designed, the published primer sequences were used as PCR primers and then as sequencing primers. Polymorphism was detected by resequencing using a modification of pyrophosphate sequencing (Pyrosequencing^®) which yielded quality sequencing from the first base after the primer with up to 80 bases of information. Our method of pyrophosphate sequencing of SSRs, although not suitable for full-length sequencing, is an attractive method to directly find sequence polymorphism in varieties of interest using the abundant, well characterised and published SSR markers.     

Development of genomic simple sequence repeat markers in opium poppy by next-generation sequencing

Opium poppy (Papaver somniferum L.) is an important pharmaceutical crop with very few genetic marker resources. To expand these resources, we sequenced genomic DNA using pyrosequencing technology and examined the DNA sequences for simple sequence repeats (SSRs). A total of 1,244,412 sequence reads were obtained covering 474 Mb. Approximately half of the reads (52 %) were assembled into 166,724 contigs representing 105 Mb of the opium poppy genome. A total of 23,283 non-redundant SSRs were identified in 18,944 contigs (11.3 % of total contigs). Trinucleotide and tetranucleotide repeats were the most abundant SSR repeats, accounting for 49.0 and 27.9 % of all SSRs, respectively. The AAG/TTC repeat was the most abundant trinucleotide repeat, representing 19.7 % of trinucleotide repeats. Other SSR repeat types were AT-rich. A total of 23,126 primer pairs (98.7 % of total SSRs) were designed to amplify SSRs. Fifty-three genomic SSR markers were tested in 37 opium poppy accessions and seven Papaver species for determination of polymorphism and transferability. Intraspecific polymorphism information content (PIC) values of the genomic SSR markers were intermediate, with an average 0.17, while the interspecific average PIC value was slightly higher, 0.19. All markers showed at least 88 % transferability among related species. This study increases sequence coverage of the opium poppy genome by sevenfold and the number of opium poppy-specific SSR markers by sixfold. This is the first report of the development of genomic SSR markers in opium poppy, and the genomic SSR markers developed in this study will be useful in diversity, identification, mapping and breeding studies in opium poppy.     

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。     

Allelic diversity of simple sequence repeats among elite inbred lines of cultivated sunflower.

Simple sequence repeat (SSR) markers were developed for cultivated sunflower (Helianthus annuus L.) from the DNA sequences of 970 clones isolated from genomic DNA libraries enriched for (CA)n,, (CT)n, (CAA)n, (CATA)n, or (GATA)n. The clones harbored 632 SSRs, of which 259 were unique. SSR markers were developed for 130 unique SSRs by designing and testing primers for 171 unique SSRs. Of the total, 74 SSR markers were polymorphic when screened for length polymorphisms among 16 elite inbred lines. The mean number of alleles per locus was 3.7 for dinucleotide, 3.6 for trinucleotide, and 9.5 for tetranucleotide repeats and the mean polymorphic information content (PIC) scores were 0.53 for dinucleotide, 0.53 for trinucleotide, and 0.83 for tetranucleotide repeats. Cluster analyses uncovered patterns of genetic diversity concordant with patterns produced by RFLP fingerprinting. SSRs were found to be slightly more polymorphic than RFLPs. Several individual SSRs were significantly more polymorphic than RFLP and other DNA markers in sunflower (20% of the polymorphic SSR markers had PIC scores ranging from 0.70 to 0.93). The newly developed SSRs greatly increase the supply of sequence-based DNA markers for DNA fingerprinting, genetic mapping, and molecular breeding in sunflower; however, several hundred additional SSR markers are needed to routinely construct complete genetic maps and saturate the genome.     

Genome-Wide Comparative Analyses of Microsatellites in Papaya

Microsatellites, or simple sequence repeats (SSRs), are highly polymorphic and universally distributed in eukaryotes. SSRs have been used extensively as sequence tagged markers in genetic studies. Recently, the functional and evolutionary importance of SSRs has received considerable attention. Here we report the mining and characterization of the SSRs in papaya genome. We analyzed SSRs from 277.4 Mb of whole genome shotgun (WGS) sequences, 51.2 Mb bacterial artificial chromosome (BAC) end sequences (BES), and 13.4 Mb expressed sequence tag (EST) sequences. The papaya SSR density was one SSR per 0.7 kb of DNA sequence in the WGS, which was higher than that in BES and EST sequences. SSR abundance was dramatically reduced as the repeat length increased. According to SSR motif length, dinucleotide repeats were the most common motif in class I, whereas hexanucleotides were the most copious in class II SSRs. The tri- and hexanucleotide repeats of both classes were greater in EST sequences compared to genomic sequences. In class I SSR, AT and AAT were the most frequent motifs in BES and WGS sequences. By contrast, AG and AAG were the most abundant in EST sequences. For SSR marker development, 9,860 primer pairs were surveyed for amplification and polymorphism. Successful amplification and polymorphic rates were 66.6% and 17.6%, respectively. The highest polymorphic rates were achieved by AT, AG, and ATG motifs. The genome wide analysis of microsatellites revealed their frequency and distribution in papaya genome, which varies among plant genomes. This complete set of SSRs markers throughout the genome will assist diverse genetic studies in papaya and related species.     

Development of soybean aphid genomic SSR markers using next generation sequencing

Simple sequence repeats (SSRs) or microsatellites are very useful molecular markers, owing to their locus-specific codominant and multiallelic nature, high abundance in the genome, and high rates of transferability across species. The soybean aphid (Aphis glycines Matsumura) has become the most damaging insect pest of soybean (Glycine max (L.) Merr.) in North America, since it was first found in the Midwest of the United States in 2000. Biotypes of the soybean aphid capable of colonizing newly developed aphid-resistant soybean cultivars have been recently discovered. Genetic resources, including molecular markers, to study soybean aphids are severely lacking. Recently developed next generation sequencing platforms offer opportunities for high-throughput and inexpensive genome sequencing and rapid marker development. The objectives of this study were (i) to develop and characterize genomic SSR markers from soybean aphid genomic sequences generated by next generation sequencing technology and (ii) to evaluate the utility of the SSRs for genetic diversity or relationship analyses. In total 128 SSR primer pairs were designed from sequences generated by Illumina GAII from a reduced representation library of A. glycines. Nearly 94% (120) of the primer pairs amplified SSR alleles of expected size and 24 SSR loci were polymorphic among three aphid samples from three populations. The polymorphic SSRs were successfully used to differentiate among 24 soybean aphids from Ohio and South Dakota. Sequencing of PCR products of two SSR markers from four aphid samples revealed that the allelic polymorphism was due to variation in the SSR repeats among the aphids. These markers should be particularly useful for genetic differentiation among aphids collected from soybean fields at different localities and regions. These SSR markers provide the soybean aphid research community with the first set of PCR-based codominant markers developed from the genomic sequences of A. glycines.     

杂交兰转录组SSR信息分析及EST-SSR标记开发应用

该研究主要开发筛选适用于杂交兰的EST-SSR引物,为杂交兰种质资源评价和遗传变异研究等提供可靠的分子标记。该研究对杂交兰进行转录组高通量测序,挖掘SSR位点和开发EST-SSR标记,并对不同种质的遗传多样性进行分析。结果表明,从31724条杂交兰Unigene中检测出18603个SSR位点,SSR出现频率为58.64%;SSR位点中的主导类型是单核苷酸重复,占总SSR的65.10%,其次是二核苷酸(23.56%)和三核苷酸(10.76%)重复;优势重复基元为A/T、AG/CT、AT/AT和AAG/CTT,分别占总位点的64.72%、13.74%、8.19%和2.51%。利用Primer Premier 5.0共设计了565对SSR引物,从筛选出的64对有效扩增引物中随机选择28对引物,对40份杂交兰种质进行多态性验证与遗传关系分析,其中16对(占57.14%)引物表现出可重复的高多态性,平均多态信息量(PIC)达0.789。基于扩增的多态性SSR信息,40份种质资源可聚为4类,聚类结果与其遗传背景基本一致。该研究印证了转录组测序获得的Unigene是SSR标记开发的有效来源,开发的EST-SSR引物可为杂交兰及近缘种的良种鉴别、遗传图谱构建、分子标记辅助育种及功能基因挖掘等提供有价值的候选标记。     

ISSR分子标记及其在植物遗传学研究中的应用

ISSR分子标记是在SSR标记基础上发展起来的一种新技术,其基本原理是在SSR的5′或3′端加锚1~4个嘌呤或嘧啶碱基,然后以此为引物,对两侧具有反向排列SSR的一段基因组DNA序列进行扩增。重复序列和锚定碱基是随机选择的,扩增产物经聚丙烯酰胺或琼脂糖凝胶电泳分离后,每个引物可以产生比RAPD方法更多的扩增片段,因此,ISSR标记是一种快速、可靠、可以提供有关基因组丰富信息的DNA指纹技术。ISSR标记呈孟德尔式遗传,在多数物种中是显性的,目前已广泛用于植物品种鉴定、遗传作图、基因定位、遗传多样性、进化及分子生态学研究中。 ISSR Markers and Their Applications in Plant Genetics WANG Jian-bo Key Laboratory of MOE for Plant Developmental Biology,Wuhan University,Wuhan 430072,China Abstract:Recently,inter-simple sequence repeat (ISSR) markers have emerged as an alternative system with reliability and advantages of microsatellites (SSR).The technique involves amplification of genomic segments flanked by inversely oriented and closely spaced microsatellite sequences by a single primer or a pair of primers based on SSRs anchored 5′ or 3′ with 1-4 purine or pyramidine residues.The sequences of repeats and anchor nucleates are arbitrarily selected.Coupled with the separation of amplification products on a polyacrylamide or agarose gels,ISSR amplification can reveal a much larger number of fragments per primer than RAPD.It is concluded that ISSR technique provides a quick,reliable and highly informative system for DNA fingerprinting.ISSR markers are inherited in Mendelin mode and segregated as dominant markers.This technique has been widely used in the studies of cultivar identification,genetic mapping,gene tagging,genetic diversity,evolution and molecular ecology. Key words：molecular markers; ISSR; plant;applications