一种对甲螨无形态损伤的DNA提取技术

甲螨是一类重要的土壤动物,体型微小,一般具有较厚的体壁。本研究针对甲螨这一特定类群,探讨了一种无形态特征损伤的DNA提取技术。通过结合试剂盒DNA提取法,并适当改进实验条件,设计出一套行之有效的DNA提取流程。通过对提取DNA之后的标本进行形态学观察,发现其主要的分类学特征均保存完好,可以作为凭证标本长期保存。本研究所提供的DNA提取技术既可以提取出足够的DNA又可以保留凭证标本,因此能有效促进甲螨分子分类学相关研究。     

一种快速高效提取病原真菌DNA作为PCR模板的方法

真菌rDNA-ITS序列分析适合于较高等级水平的生物群体间的系统分析。真菌DNA的提取采用传统的方法,步骤繁琐,需要较长时间。采用Chelex-100法提取真菌DNA,使用PCR扩增rDNA-ITS序列评价提取核酸的质量。结果显示,该方法具有经济、简便、快速、高效的特点,是一种比较理想的提取真菌基因组DNA作为PCR模板的方法。     

堆肥中微生物总DNA的高效提取

采用化学裂解和酶解相结合的方法,选择加入PVPP的高盐缓冲液作为细胞裂解的反应体系,并以PEG-8000进行DNA沉淀,从高有机含量的堆肥样品中进行微生物总DNA的提取。结果表明,从4种性质不同的堆肥中均获得了高质量的微生物总DNA,所得的DNA分子片段在23kb左右;每克干重堆肥的总DNA提取量为63.54±12.08μg~106.50±28.36μg,A260/A280大于1.6,A260/A230大于1.8,不用经过纯化可以直接进行PCR扩增和限制性酶切;以该DNA为模板进行微生物区系的DGGE分析,显示了丰富的微生物多样性。该方法减少了通常环境样品DNA提取过程中的纯化步骤,减少了DNA的损失,为从事微生物分子生态学,尤其是那些针对高有机含量以及获取极为不易的环境样品的研究而言是十分有益的。     

一种从土壤生物结皮中有效提取DNA的方法

在干旱、半干旱地区稀疏的高等植被间, 常有一层生物土壤结皮。       

An effective DNA extraction protocol for brown algae

Successful extraction of total DNA from brown algae, which are generally polysaccharide and polyphenol rich, is often problematic using current methods. Persistent polysaccharide and polyphenolic compounds can hinder further application of modern molecular techniques requisite to molecular‐based evolutionary studies. Our broad and long‐term research goals with fucalean taxa, especially Sargassum, and problems with existing DNA extraction methods were an impetus to develop a reliable DNA extraction method. Initial research established hexadecyltrimethylammonium bromide (CTAB) based total‐DNA methods as the most viable for further empirical development. Several constituents effective at either complexing secondary compounds or creating a reductive extraction environment were increased in concentration or added to the extraction buffer. These seemingly minor changes resulted in the creation of a highly reductive extraction buffer and effective total‐ DNA harvesting technique. We detail these modifications and demonstrate the reliability of the modified protocol with a variety of brown algae and tissue preservation methods. Such DNA is shown to be suitable for a variety of molecular techniques.     

An efficient method for DNA extraction from cyanobacteria isolated from hypersaline and marine environments

Cyanobacteria are ancient organisms surviving on the earth due to their simple nutritional requirements and ability to produce distinct secondary metabolites that can combat detrimental environmental impacts. In order to understand these abilities of cyanobacteria at the molecular level, it is necessary to extract high‐quality genomic DNA. However, the presence of secondary metabolites and exopolysaccharides hinders the DNA extraction from these organisms, especially from hypersaline environments. Here we have developed and compared a new method with two known methods of DNA extraction from environmental isolates. The results clearly indicate that the new optimized method yielded large amount of DNA with high purity. Additionally, the extracted DNA showed reduced degradation and excellent overall quality, which can be used directly for downstream purposes such as PCR and sequencing.     

A rapid and efficient method for the extraction of total DNA from mature leaves of the data palm (Phoenix dactylifera L.)

A method is presented for the rapid isolation of high-molecular-weight DNA from mature leaves of date palm (Phoenix dactylifera L.), using a CTAB-based buffer. The method yields up to 800 μg of DNA from 1 g of leaf tissues. The procedure was also suitable for DNA extraction from callus or buds from tissue culture. The DNA obtained through this method was a good substrate for at least seventeen restriction endonucleases. This method was also used to extract DNA from mature leaves of coconut and may be applicable to other species of palms.     

An efficient method for DNA isolation from red algae

A simple, inexpensive and efficient method was developed for rapid isolation of totalgenomic DNA from 15 red algal species. It resulted in 0.1 g high quality DNAfrom 1 mg fresh algal material, with an A₂₆₀/A₂₈₀ratio of 1.68–1.90.Using this rapidly isolated DNA, the 18S ribosomal RNA genes (rDNA) and the nuclearribosomal DNA of the internal transcribed spacer (ITS) regions were amplified. Thetested DNA was suitable for restriction endonuclease digestion, genetic markeranalysis and polymerase chain reaction (PCR) amplification, and may be valid forother genetic manipulation.     

A rapid non-destructive DNA extraction method for insects and other arthropods

Preparation of arthropods for morphological identification often damages or destroys DNA within the specimen. Conversely, DNA extraction methods often destroy the external physical characteristics essential for morphological identification. We have developed a rapid, simple and non-destructive DNA extraction technique for arthropod specimens. This technique was tested on four arthropod orders, using specimens that were fresh, preserved by air drying, stored in ethanol, or collected with sticky or propylene glycol traps. The technique could be completed in 20 min for Coleoptera, Diptera and Hemiptera, and 2 min for the subclass Acarina, without significant distortion, discolouration, or other damage to the specimens.     

A simple and efficient method for DNA extraction from grapevine cultivars andVitis species

A quick, simple, and reliable method for the extraction of DNA from grapevine species, hybrids, andAmpelopsis brevipedunculata (Vitaceae) has been developed. This method, based on that of Doyle and Doyle (1990), is a CTBA-based extraction procedure modified by the use of NaCl to remove polysaccharides and PVP to eliminate polyphenols during DNA purification. The method has also been used successfully for extraction of total DNA from other fruit species such as apple (Malus domestica), apricot (Prunus armeniaca), cherry (Prunus avium), peach (Prunus persica), plum (Prunus domestica), and raspberry (Rubus idaeus). DNA yield from this procedure is high (up to 1 mg/g of leaf tissue). DNA is completely digestible with restriction endonucleases and amplifiable in the polymerase chain reaction (PCR), indicating freedom from common contaminating compounds.     

盐肤木基因组DNA提取方法改进及AFLP体系的建立

经过反复试验,摸索出一种提取高质量植物基因组DNA的方法:改良的4×CTAB法.以盐肤木叶片为实验材料,提取到高质量的基因组DNA,建立了酶切、连接、预扩增、选择性扩增的AFLP反应体系.通过两种引物组合"E+3/M+3"和"E+2/M+3"策略筛选出8对条带分辨率高、多态性好的引物组合,优化了盐肤木的AFLP银染反应...     

A Rapid DNA Minipreparation Method Suitable for AFLP and Other PCR Applications

A rapid DNA minipreparation method was developed for rice and other plant species. This method uses an Eppendorf tube and 1-ml pipette tip to grind plant tissues, and requires only one transfer for DNA isolation. In a single day, one person can complete DNA isolation from more than 120 leaf samples. The yields of the DNA samples ranged from 2.3 to 5.2 g from 25–50 mg fresh leaf tissue. DNA samples extracted using this method from rice were completely digested with five restriction enzymes (EcoR I, EcoR V, Hind III, Mse I and Pst I) and were successfully used for AFLP and other PCR applications.     

Ready-to-use DNA extracted with a CTAB method adapted for herbarium specimens and mucilaginous plant tissue

This report summarizes major changes in previously published protocols for DNA extraction to improve the quality of DNA extracted from plants. Here, we highlight the critical modifications in the original protocols. The efficiency of these changes results in high-quality DNA ready to use in a variety of phytogenetically distant plant families, in particular species with mucopolysaccharides. The DNA obtained can be used without further purification in various molecular biology assays, including direct sequencing and AFLP and RAPD (random-amplified polymorphic DNA) analyses. The effectiveness of this method is proven by the amplification and sequencing of PCR products of up to 1 kb with DNA extracted from herbarium tissue ≥60 years old. This versatility is not usually found in DNA extraction protocols. In addition, this method is quick, adaptable to standard laboratories, and most important, safer and more cost-effective.     

An efficient purification and fractionation of genomic DNA from soil by modified troughing method

AIMS: The aim of this study was to utilize a modified troughing method for purification of large genomic DNA obtained from microbiota in natural environment and for fractionation of genomic DNA into many size ranges that facilitates construction of metagenomic library. METHODS AND RESULTS: Genomic DNA extracted from soil or termite gut was purified by the modified troughing method which utilized gel electrophoresis in the presence of 30% PEG8000. The method performed better than various purification kits and allowed no significant loss in the amount of DNA recovered. In addition, the efficiency of the modified troughing method for DNA size fractionation was investigated. DNA size fractionation was achieved with repetitive rounds of electrophoresis and DNA collection to obtain DNA with many size ranges. CONCLUSIONS: The modified troughing method is a simple and efficient method for purification of genomic DNA and for DNA size fractionation. SIGNIFICANCE AND IMPACT OF THE STUDY: The modified troughing method is a straightforward and inexpensive technique readily available for anyone working with environmental genomic DNA. It facilitates cloning of genomic DNA and enhances rapid discovery of useful bioactive compounds from microbial resources.     

Molecular phylogeny of oribatid mites (Oribatida, Acari): evidence for multiple radiations of parthenogenetic lineages

Nucleotide sequences of the D3 expansion segment and its flanking regions of the 28S rDNA gene were used to evaluate phylogenetic relationships among representative sexual and asexual oribatid mites (Oribatida, Acariformes). The aim of this study was to investigate the hypothesis that oribatid mites consist of species-rich clusters of asexual species that may have radiated while being parthenogenetic. Furthermore, the systematic position of the astigmate mites (Astigmata, Acariformes) which have been hypothesised to represent a paedomorphic lineage within the oribatid mites, is investigated. This is the first phylogenetic tree for oribatid mites s.l. (incl. Astigmata) based on nucleotide sequences. Intraspecific genetic variation in the D3 region was very low, confirming the hypothesis that this region is a good species marker. Results from neighbour joining (NJ) and maximum parsimony (MP) algorithms indicate that several species-rich parthenogenetic groups like Camisiidae, Nanhermanniidae and Malaconothridae are monophyletic, consistent with the hypothesis that some oribatid mite groups diversified despite being parthenogenetic. The MP and maximum likelihood (ML) method indicated that the D3 region is a good tool for elucidating the relationship of oribatid mite species on a small scale(genera, families) but is not reliable for large-scale taxonomy, because branches from the NJ algorithm collapsed in the MP and ML tree. In all trees calculated by different algorithms the Astigmata clustered within the oribatid mites, as proposed earlier.     

一种经济快速提取丝状真菌基因组DNA的方法

以螺旋木霉(Trichoderma SpiraleXX)、小克银汉霉(Cunninghamella phaeospora MK)和卵形孢球托霉(Gongronella butleri XT)3种丝状真菌为材料,采用改进的CTAB法提取基因组DNA.方法改进后无需液氮、聚乙烯砒咯烷酮(PVP)和NaAc等试剂,过程简洁,且所需菌体量少,提取的DNA纯度较好,适用于一次微量提取多个样品的基因组DNA.此方法得到的基因组DNA可用于PCR扩增.     

一种快速提取基因组DNA的方法

采采用氧化硅超顺磁性纳米磁珠和自己设计的试剂体系及提取流程,建立了一种基因组DNA的快速提取方法,该方法以氧化硅磁珠为固相吸附载体,盐酸胍、 -巯基乙醇和SDS为主要裂解吸附试剂。以全血或培养细胞为实验材料进行基因组DNA的提取结果显示用本文建立的方法提取100 L小鼠抗凝血,可得2～3 g基因组DNA, OD260/OD280为1.8 ± 0.05,其纯度可满足后续的酶切和PCR生物操作要求。该方法整个提取过程只需12分钟,不需特殊实验条件同时可省略蛋白酶K的消化过程和离心操作,适用于一般实验室的需求,是一种操作简便、快速高效的提取方法。     

单粒干燥大豆种子基因组DNA提取的有效方法

大豆基因组DNA的提取是进行大豆分子生物学研究的基础.以大豆干燥的种子为材料,将SDS法和CTAB法结合在一起并进行了一定的改进,有效的提取了基因组DNA.通过电泳、紫外分光光度计检测和ISSR标记分析验证这种方法是提取大豆干种子基因组DNA的有效方法.     

A simple method for extraction of DNA from fungi and yeasts with anhydrous hydrogen fluoride

A novel method is described for the extraction of DNAs from fungi and yeasts. Anhydrous hydrogen fluoride (HF) selectively cleaves their cell walls under mild conditions (for 5 min at 0°C), enabling the effective extraction of DNAs from organisms with a cell wall. A possible mechanism for this method concerning the selective cleavage of O-glycosidic linkages in cell walls has been described previously [(1977) Anal. Biochem. 82, 289–309]. The extracted DNA is intact: in fact, the yeast DNA is directly applicable for restriction analysis and transformation of Escherichia coli.