直接从人工老化的菜心干种子中提取基因组DNA用于RAPD分析

利用40℃、100％朋对菜心种子进行人工加速老化处理获得了不同活力的种子批,利用平衡酚-氯仿法直接从人工老化的菜心干种子中提取基因组DNA,并对提取的基因组DNA进行了趾PD扩增。结果表明,所提取的基因组DNA量多,而且比较整齐一致。引物S208扩增所获得的基因组DNA指纹图谱上的DNA带清晰、明亮,从而表明利用本方法从人工老化菜心干种子中直接提取的基因组DNA完全可以用于RAPD分析。     

直接从人工老化的菜心干种子中提取基因组DNA用于RAPD分析

利用 4 0℃、1 0 0 %RH对菜心种子进行人工加速老化处理获得了不同活力的种子批 ,利用平衡酚_氯仿法直接从人工老化的菜心干种子中提取基因组DNA ,并对提取的基因组DNA进行了RAPD扩增。结果表明 ,所提取的基因组DNA量多 ,而且比较整齐一致。引物S2 0 8扩增所获得的基因组DNA指纹图谱上的DNA带清晰、明亮 ,从而表明利用本方法从人工老化菜心干种子中直接提取的基因组DNA完全可以用于RAPD分析。     

黑翅土白蚁基因组DNA提取方法的优化

目的 为快速地提取到质量较好的黑翅土白蚁基因组DNA进行白蚁种群多样性的研究,对基因组DNA提取方法进行了比较与改进.方法 先初步采取CTAB法与蛋白酶K法对黑翅土白蚁基因组DNA的提取方法进行比较,再利用正交设计法对蛋白酶K法中裂解液、蛋白酶、RNA酶及作用时间4个因素进行优化.结果 蛋白酶K法获得的基因组DNA的质量与产量稍优于CTAB法;较佳的提取步骤组合为:裂解液150 μL,蛋白酶K 6μL,作用时间1h,RNA酶可不添加.结论 采用优化后的方法获得的基因组DNA为模板进行PCR扩增,得到了清晰、稳定的扩增谱带,完全可用于相关后续实验.     

香蕉枯萎菌基因组DNA提取方法的研究

以香蕉枯萎菌菌株为试验材料,在SDS～CTAB法和高盐沉淀法等基础上加以改进,对两种提纯香蕉枯萎菌基因组DNA的方法进行了比较研究。结果表明：高盐沉淀法是适合于香蕉枯萎菌基因组DNA提取的方法。该方法提取的DNA OD260／OD280的比值为1．841,DNA产量为0．81mgDNA／g菌丝体。基因组DNA经琼脂糖凝胶电泳得到一条带型较宽且清晰的DNA谱带,基本无DNA碎带;将提取的DNA直接用于PCR扩增,得到带多而且清晰、整齐、基本无拖尾的RAPD图谱。     

高质量毕赤酵母基因组DNA提取方法比较

旨在比较5种毕赤酵母基因组DNA的提取法,以便获得简便高效的提取高质量酵母基因组DNA的优化方法。分别使用蜗牛酶破壁法,超声波破碎法,液氮研磨法,Lyticase破壁法,试剂盒法提取毕赤酵母基因组DNA,然后进行DNA电泳检测以及紫外分光光度计测定DNA浓度和纯度。结果显示,5种方法均能提取出酵母基因组DNA,而酶法所提取的酵母基因组DNA质量最好。由此证实,蜗牛酶法成本低、效果好,是理想的提取高质量酵母基因组DNA的方法,完全满足后续试验要求。     

苛求芽孢杆菌基因组DNA提取方法的比较

目的:比较不同方法提取苛求芽孢杆菌基因组DNA的差异。方法:用经典CTAB提取法、改进CTAB法(溶菌酶处理结合CTAB提取法)、UniQ柱吸附提取法制备苛求芽孢杆菌基因组DNA,比较产物完整性和用于PCR扩增的有效性。结果:三种方法制备基因组DNA纯度接近,但改进CTAB法产率最高,UniQ法产率最低。经典CTAB法和UniQ法提取基因组DNA易降解。三种方法所得基因组DNA用于PCR扩增效率接近。结论:溶菌酶裂解结合CTAB提取更适合制备苛求芽孢杆菌基因组DNA。     

煤地质环境微生物总基因组DNA提取方法的优化

高质量的DNA是进行分子生物学研究的基础。通过对传统DNA抽提方法(酚-氯仿法)进行改进,并以Rhodococcus sp.R04和煤粉为实验材料对细胞破碎条件进行优化,建立了一种可用于煤地质环境微生物基因组DNA高效提取的改良方法。以改良法和商业试剂盒提取煤地质环境微生物基因组DNA,通过琼脂糖凝胶电泳、细菌及古菌特异性片段的PCR扩增来评价所提取DNA的质量。改良法和试剂盒法均能获得煤地质环境微生物基因组DNA,并能用于多种特异性PCR扩增。与试剂盒提取的DNA相比,改良法获得的DNA片段主带明显,约占总DNA含量的50%,分子量大小接近23 kb,并且提取量大,约为试剂盒的5-10倍。同时,能用于如DNA文库构建和宏基因组测序等。此外,改良法所用试剂普通,价格便宜,提取的煤地质环境微生物基因组DNA质量较高,适于实验室和科学研究。     

SDSC-TAB和高盐沉淀法提取香蕉枯萎病菌基因组DNA的比较

以香蕉枯萎病菌菌株为试验材料,采用SDS- CTAB法和高盐沉淀法提纯香蕉枯萎病菌基因组DNA。结果表明:高盐沉淀法是适合于香蕉枯萎病菌基因组DNA提取的方法。该方法提取的DNAOD2 60 2 80值显示产物纯度较高;经琼脂糖凝胶电泳得到一条带型较宽且清晰的DNA谱带,DNA浓度较高,基本无DNA碎带;不用RNase处理,已无RNA的干扰,无需任何纯化处理即可用于PCR扩增和RAPD分析。同时对DNA提取过程中的细节问题进行了探讨与分析。     

一种快速、经济提取外周凝血基因组DNA方法的建立

目的：建立一种经济、快速且高质量提取人体外周凝血DNA的方法。方法：摸索最佳的匀浆条件,对外周凝血块进行匀浆,采用Ⅺ法对匀浆液进行基因组DNA的提取,通过凝胶电泳、单重PCR和多重PCR检测凝血基因组DNA的提取产量和质量。并分别与常规的凝血基因组DNA提取方法,即蛋白酶K消化法,以及提取抗凝血基因组DNA的Ⅺ法进行比较分析。结果：最佳的匀浆条件为：39000map,15秒。在此条件下提取的基因组DNA完整性好,纯度和产量与蛋白酶K消化法提取凝血DNA和KI法提取抗凝血DNA的结果相比,没有统计学差异。单重PCR和多重PCR也获得了理想的扩增结果。结论：与常规的外周凝血提取方法相比（蛋白酶K消化法）,本方法节省了时间和成本,能快速、经济、有效地提取外周凝血基因组DNA,可用于后续的科研和临床诊断需要,解决了部分科研机构血液基因组DNA的样本来源问题。     

一种快速、经济提取外周凝血基因组DNA 方法的建立

目的:建立一种经济、快速且高质量提取人体外周凝血DNA的方法。方法:摸索最佳的匀浆条件,对外周凝血块进行匀浆,采用KI法对匀浆液进行基因组DNA的提取,通过凝胶电泳、单重PCR和多重PCR检测凝血基因组DNA的提取产量和质量,并分别与常规的凝血基因组DNA提取方法,即蛋白酶K消化法,以及提取抗凝血基因组DNA的KI法进行比较分析。结果:最佳的匀浆条件为:39000 rmp,15秒。在此条件下提取的基因组DNA完整性好,纯度和产量与蛋白酶K消化法提取凝血DNA和KI法提取抗凝血DNA的结果相比,没有统计学差异。单重PCR和多重PCR也获得了理想的扩增结果。结论:与常规的外周凝血提取方法相比(蛋白酶K消化法),本方法节省了时间和成本,能快速、经济、有效地提取外周凝血基因组DNA,可用于后续的科研和临床诊断需要,解决了部分科研机构血液基因组DNA的样本来源问题。     

猕猴桃叶DNA的AFLP分析

以猕猴桃幼叶为材料提取基因组DNA并进行AFLP扩增。对主要实验步聚包括DNA纯化、DNA的酶切、酶切片段与接头的连接、PCR扩增、电泳、以及银染等方面的反应参数进行比较和优选,初步摸索出适合于猕猴桃叶为材料的AFLP程序,并得到较为清晰可辩的AFLP指纹图谱,为开展猕猴桃遗传多态性研究和在分子水平上开展物种生物学分析提供一个实用的手段。     

AFLP标记的特点及其在昆虫学研究中的应用

扩增片段长度多态性（AFLP）是一种新兴的很有效的分子遗传标记方法, 它通过对基因组DNA限制性内切酶酶切片段进行选择性扩增而揭示多态性,具有快速、经济简便、不需要预先知道模板DNA的信息、模板需要量少、重复性高、结果可靠及具有很高的信息含量等优点。AFLP也具有缺点,主要是标记是显性的,同其他显性标记一样,不能区分杂合体和纯合体,因而不能更好地估算种群遗传的变异,对种群遗传结构的分析不能提供更多的统计信息;AFLP技术较复杂,而且经常使用放射性同位素,对模板DNA质量要求也较高。为了克服AFLP的这些缺点,人们又在其基础上发展了其他相关技术,例如AFRP、SAMPL、DALP和TE-AFLP等。目前AFLP在昆虫方面的应用还不是很多,处于初级阶段,主要应用在生态型鉴定、种群遗传分析、连锁图谱构建等方面,相信随着其技术的发展完善,必将会越来越多地应用于昆虫学的研究中。     

Strain typing of shiitake (<Emphasis Type="Italic">Lentinula edodes</Emphasis>) cultivars by AFLP analysis,focusing on a heat-dried fruiting body

To validate strain typing by amplified fragment length polymorphism (AFLP) analysis in shiitake (Lentinula edodes) cultivars, the reproducibility of AFLP markers with DNA extracted from the heat-dried fruiting body was evaluated. DNAs were extracted from three different portions of the heat-dried fruiting body – the stipe, pileus, and gill – and AFLP analysis of all parts was carried out using two combinations of selected amplification primer pairs. AFLP profiles of DNA from the gill tissue of heat-dried fruiting body were almost identical to those of cultured mycelia in the same strains, although it was difficult to detect reproducible AFLP profiles from stipe and pileus DNA. These results indicated that AFLP analysis would be applicable for strain typing with heat-dried fruiting bodies of L. edodes by using the DNA extracted from gills.Contribution No. 364 of the Tottori Mycological Institute     

Suitability of genomic DNA synthesized by strand displacement amplification (SDA) for AFLP analysis: genotyping single spores of arbuscular mycorrhizal (AM) fungi

Limited biological samples of microbial origin often yield insufficient amounts of genomic DNA, making application of standard techniques of genetic analysis, like amplified fragment length polymorphism (AFLP), virtually impossible. The Phi29 DNA polymerase based whole genome amplification (WGA) method has the potential to alleviate this technical bottleneck. In the present work, we have sought to investigate the suitability of genomic DNA synthesized using Phi29 based WGA for AFLP analysis. We first used genomic DNA from Saccharomyces cerevisiae to optimize the protocol for the use of SDA-amplified DNA for AFLP analysis. Based on the optimized protocol we obtained AFLP fingerprints which were indistinguishable from the non-amplified genomic DNA. Finally, AFLP analysis was performed using SDA synthesized genomic DNA from single spores of various species of arbuscular mycorrhizal (AM) fungi. Unique and highly reproducible fingerprints for each species were obtained. The present study introduces the application of WGA-mediated AFLP to AM fungal biology; similarly, our protocol could be useful for other microbial genomes currently not amenable to genetic analysis owing to the paucity of starting template.     

Genetic variation among natural isolates of the ectomycorrhizal hypogenous fungus,Rhizopogon roseolus from Japanese pine forests inferred using AFLP markers

Genetic variation among 45 Rhizopogon roseolus isolates from 21 different regions of Japan were inferred using amplified fragment length polymorphism (AFLP) markers. Using three primer pair combinations, AFLP analysis reproducibly produced a total of 223 DNA fragments, 74.4% of which were polymorphic. Pairwise dissimilarity of AFLP patterns between isolates ranged from 0.043 to 0.228. Cluster analysis and principal coordinate analysis of AFLP data generally showed four major clusters from geographically distinct areas. The findings suggested that the Japanese populations of R. roseolus from different geographical regions can be distinguished based on AFLP characters.     

Genomic typing of Escherichia coli O157:H7 by semi-automated fluorescent AFLP analysis

Escherichia coli serotype O157:H7 isolates were analyzed using a relatively new DNA fingerprinting method, amplified fragment length polymorphism (AFLP). Total genomic DNA was digested with two restriction endonucleases (EcoRI and MseI), and compatible oligonucleotide adapters were ligated to the ends of the resulting DNA fragments. Subsets of fragments from the total pool of cleaved DNA were then amplified by the polymerase chain reaction (PCR) using selective primers that extended beyond the adapter and restriction site sequences. One of the primers from each set was labeled with a fluorescent dye, which enabled amplified fragments to be detected and sized automatically on an automated DNA sequencer. Three AFLP primer sets generated a total of thirty-seven unique genotypes among the 48 E. coli O157:H7 isolates tested. Prior fingerprinting analysis of large restriction fragments from these same isolates by pulsed-field gel electrophoresis (PFGE) resulted in only 21 unique DNA profiles. Also, AFLP fingerprinting was successful for one DNA sample that was not typable by PFGE, presumably because of template degradation. AFLP analysis, therefore, provided greater genetic resolution and was less sensitive to DNA quality than PFGE. Consequently, this DNA typing technology should be very useful for genetic subtyping of bacterial pathogens in epidemiologic studies.     

Detection of genetic variation among single-spore isolates and identification of genets ofArmillaria ostoyae by AFLP analysis with Texas RedTM-labeled selective primer

AFLP (amplified fragment length polymorphism) analysis was applied toArmillaria ostoyae isolates (single-spore isolates and field isolates from the same forest). For detection of AFLP, we have developed a modified method using DNA sequencer with Texas Red-labeled selective primer. In analysis of single-spore isolates, this technique provided large numbers of highly polymorphic DNA markers, which can be used to identify genets. The results suggested that outbreeding might be common inA. ostoyae.     

The status of AFLP in the genomics era and a pipeline for converting AFLPs into single-locus markers

Even though next-generation sequencing (NGS) has now become the predominant state-of-the-art technique for genotyping populations, amplified fragment length polymorphism (AFLP) DNA fingerprinting is still a relevant method, thanks to its versatility, cost-effectiveness, independence of prior sequence information and broad applicability. Even though the number of AFLP studies reached its peak in 2012, it is still applied extensively for phylogenetic analysis, genotyping or identifying non-model species, which often feature complex and large genomes. For these purposes, tools continue to be developed for designing AFLP studies, scoring AFLPs or handling AFLP data. Moreover, AFLP studies embrace the NGS technology; for example, the whole-genome sequence of model species is used to design more efficient AFLP studies for non-model species. Conversely, in complexity reduction of polymorphic sequences and restriction site-associated DNA sequencing studies, polymorphisms are often found to be present in many restriction sites, which can still be studied as AFLPs. We discuss the latest advances in AFLP-based studies in the era of NGS and anticipate that AFLP will remain a relevant method in the near future, even for species with a known genome, owing to its many promising new features such as methylation-sensitive-AFLP. Here, we also present an optimized pipeline for converting AFLP markers into single-locus markers, which can be applied in both traditional AFLP and NGS studies.     

Use of AFLP Markers for Gene Mapping and QTL Detection in the Rat

The AFLP technique is a new DNA marker technology based on the selective amplification of restriction fragments. Multiple polymorphic markers are simultaneously produced and can be tested in one PCR. No prior information on genomic DNA sequences is needed. In the current study, we contribute 18 AFLP markers to the linkage map of the rat. Seven AFLP markers were assigned to specific chromosomes by analysis of a (BN × ACI)F1 × ACI backcross progeny. Another 11 AFLP markers were mapped by using a panel of the H × B/B × H recombinant inbred (RI) strains. Genotypes of these AFLP markers were also tested for correlations with some blood pressure phenotypes in the RI strains. Suggestive correlation was found between the mean arterial pressure and two closely linked AFLP markers located on chromosome 20. The current study illustrates the value of AFLP markers for the construction of linkage maps and the detection of quantitative trait loci.     

High-resolution genotyping of Campylobacter strains isolated from poultry and humans with amplified fragment length polymorphism fingerprinting.

For epidemiological studies of Campylobacter infections, molecular typing methods that can differentiate campylobacters at the strain level are needed. In this study we used a recently developed genotyping method, amplified fragment length polymorphism (AFLP), which is based on selective amplification of restriction fragments of chromosomal DNA, for genetic typing of Campylobacter jejuni and Campylobacter coli strains derived from humans and poultry. We developed an automated AFLP fingerprinting method in which restriction endonucleases HindIII and HhaI were used in combination with one set of selective PCR primers. This method resulted in evenly distributed band patterns for amplified fragments ranging from 50 to 500 bp long. The discriminatory power of AFLP was assessed with a C. jejuni strain, an isogenic flagellin mutant, and distinct C. jejuni strains having known pulsed-field gel electrophoresis and fla PCR-restriction fragment length polymorphism genotypes. Unrelated C. jejuni strains produced heterogeneous patterns, whereas genetically related strains produced similar AFLP patterns. Twenty-five Campylobacter strains obtained from poultry farms in The Netherlands grouped in three C. jejuni clusters that were separate from a C. coli cluster. The band patterns of 10 C. jejuni strains isolated from humans were heterogeneous, and most of these strains grouped with poultry strains. Our results show that AFLP analysis can distinguish genetically unrelated strains from genetically related strains of Campylobacter species. However, desirable genetically related strains can be differentiated by using other genotyping methods. We concluded that automated AFLP analysis is an attractive tool which can be used as a primary method for subtyping large numbers of Campylobacter strains and is extremely useful for epidemiological investigations.