福尔马林保存鱼类标本中大片段DNA的提取

从福尔马林保存的鱼类标本中获得高质量DNA是比较困难的。我们对前人的方法进行了如下改进：1）在标本的前处理过程中,通过长时间的缓冲液浸泡、短暂的加温、真空干燥来消除福尔马林对样品的影响;2）在样品消化过程中,加入相对过量的蛋白酶K和还原剂;3）提取DNA后立即进行PCR反应,并增加反应的循环次数和提高退火温度。通过这些改进,我们成功地从福尔马林保存的鱼类标本中提取出了高质量DNA;通过对比不同方法（福尔马林、酒精及冰冻）处理过的标本的DNA测序结果,表明该方法是值得信赖的;标本从死亡到用福尔马林处理之间的时间延搁可能是影响所提取的DNA质量的重要因素。     

Improved high-throughput sunflower and cotton genomic DNA extraction and PCR fidelity

The extraction of high-quality genomic DNA for PCR amplification from sunflower (Helianthus annuus) and cotton (Gossypium spp.) is challenging because of the presence of polysaccharides, secondary metabolites, and polyphenolics in the tissues. A high-throughput DNA extraction protocol was needed in our laboratory for simple sequence repeats (SSR)-marker screening and other molecular analyses that do not require organic extraction steps of phenol or chloroform. Here we describe 2 improved highthroughput protocols for DNA extraction and in-PCR modification that result in successful PCR amplification of sunflower and cotton. While the sunflower DNA extraction protocol uses reducing agents such as sodium metabisulfite and dithiothreitol (DTT), the cotton protocol uses polyvinylpyrrolidone (PVP) in PCR reactions and reducing agents in the DNA extraction procedure.     

DNA提取的应用与相关技术分析

为了分析影响提取DNA的有关因素,采用标准酚—氯仿抽提法和蛋白酶消化法提取DNA。结果表明,平均每mL全血可提取200 ~ 300μgDNA;新鲜组织及OCT包埋冰冻组织提取DNA,平均每0.2g组织可获得200~300μgDNA;直接将石蜡标本提取物制作模版,PCR扩增良好。从4种组织中均获得较为纯净的DNA;OCT对组织DNA无不良影响。 Abstract:To explore influence factors of DNA extraction,the protease and phenol-chloroform method was used to extract DNA in whole blood,fresh tissues,frozen tissues embedding with OCT and tissues embedding in paraffin.It results that 200~300μg DNA was extracted from 1ml whole blood or 0.2g fresh tissues or frozen tissue embedding with OCT.DNA extracted from paraffin specimen can be directly used in PCR amplification.Purity DNA can be extracted from four kinds of different tissues.OCT hasn't harmful effect on tissue DNA extraction.     

Expression profiling using human tissues in combination with RNA amplification and microarray analysis: assessment of Langerhans cell histiocytosis

Summary. Advances in molecular genetics have led to sequencing of the human genome, and expression data is becoming available for many diverse tissues throughout the body, allowing for exciting hypothesis testing of critical concepts such as development, differentiation, homeostasis, and ultimately, disease pathogenesis. At present, an optimal methodology to assess gene expression is to evaluate single cells, either identified physiologically in living preparations, or by immunocytochemical or histochemical procedures in fixed cells in vitro or in vivo. Unfortunately, the quantity of RNA harvested from a single cell is not sufficient for standard RNA extraction methods. Therefore, exponential polymerase-chain reaction (PCR) based analyses, and linear RNA amplification including amplified antisense (aRNA) RNA amplification and a newly developed terminal continuation (TC) RNA amplification methodology have been used in combination with microdissection procedures such as laser capture microdissection (LCM) to enable the use of microarray platforms within individual populations of cells obtained from a variety of human tissue sources such as biopsy-derived samples {including Langerhans cell histiocytosis (LCH)} as well as postmortem brain samples for high throughput expression profiling and related downstream genetic analyses.     

Noncryogenic Preservation of Mammalian Tissues for DNA Extraction: An Assessment of Storage Methods

Reliable field methods for the storage of tissues to be used for DNA extraction and amplification are critical to many studies employing molecular techniques. Protection from DNA degradation was compared among three commonly used methods of noncryogenic storage of tissues over a time scale of 2 years. All three methods prevented DNA degradation during storage for at least 6 months. DMSO (dimethyl sulfoxide)-salt solution provided the best protection from DNA degradation of tissues stored for up to 2 years. High molecular weight DNA was recovered from lysis buffer in which tissue was stored for 2 years, however, moderate amounts of degraded DNA was also present. High molecular weight DNA was recovered from tissues stored in ethanol for 2 years, however, the yield was relatively small compared to the other two noncryogenic storage techniques. Much of the DNA degradation in ethanol preserved tissues appeared to occur during the extraction procedure and can be reduced by soaking the tissue in lysis buffer for a few hours prior to beginning the extraction. The yield of PCR products was greatest from DNA extracted from DMSO-salt solution preserved tissues, whereas DNA from tissues stored in either lysis buffer or ethanol produced lower yields.     

Detection of polymerase chain reaction-amplified malarial DNA in infected blood and individual mosquitoes

Chelex treatment of Plasmodium falciparum and P. berghei infected tissues, in lieu of organic extraction, was followed directly by polymerase chain reaction amplification of primed circumsporozoite gene sequences. The amplified DNA products were detected in stained gels and hybridization blots of extracts from individual infected mosquitoes and dissected mosquito tissues as well as small volumes of infected blood. Parasite development, within the mosquito midgut and salivary gland, was also monitored as a function of time post infectious blood meal. The temporal presence of amplifiable circumsporozoite gene sequences in the infected mosquito midgut lumen, midgut endothelium, and salivary glands corresponded directly to the visual identification of ookinetes, oocysts, and salivary gland sporozoites, respectively.     

DNA recovery from ancient tissues: problems and perspectives

The recovery, amplification and sequencing of nucleic acids from ancient smaples opens new possibilities in many different fields, such as anthropology, archeaology, population genetics, animal and plant evolutionary studies, and forensic medicine. The sample processing for DNA extraction and PCR amplification represents the most delicate phase of ancient DNA analysis, with a major impact on the reproducibility and reliability of the results. In this paper some extraction protocols are reviewed and discussed, with particular reference to the removal of the inhibitory substances usually present in extract from ancient tissues. The effect of contamination from extraneous DNA, a possible source of misleading results, is discussed and guidelines to detect and circumvent the problem are given.     

LITHIUM CHLORIDE EXTRACTION OF DNA FROM THE SEAWEED PORPHYRA PERFORATA (RHODOPHYTA)1

Lithium chloride facilitates the softening of cell walls resulting in a simple, quick (2 h) method for DNA extraction from the red seaweed Porphyra perforata J. Agardh. A 5-min treatment of tissues in Lid at 55°C extracts DNA that is relatively free of the viscous polysaccharides and proteins that are usually coextracted in large amounts from cell walls and cytoplasm. This protocol does not require grinding of tissues, hydroxyapatite binding, cetyl trimethyl ammonium bromide treatments, enzymatic treatments, phenol extraction, or CsCl-gradient centrifugation. The resulting DNA is of sufficient quality to be used as a template for polymerase chain reaction amplification.     

Quantitative PCR Method for Diagnosis of Citrus Bacterial Canker

For diagnosis of citrus bacterial canker by PCR, an internal standard is employed to ensure the quality of the DNA extraction and that proper requisites exist for the amplification reaction. The ratio of PCR products from the internal standard and bacterial target is used to estimate the initial bacterial concentration in citrus tissues with lesions.     

Quantitative PCR method for diagnosis of citrus bacterial canker

For diagnosis of citrus bacterial canker by PCR, an internal standard is employed to ensure the quality of the DNA extraction and that proper requisites exist for the amplification reaction. The ratio of PCR products from the internal standard and bacterial target is used to estimate the initial bacterial concentration in citrus tissues with lesions.     

聚合酶链反应技术检测禽网状内皮组织增殖病病毒

目的建立聚合酶链反应(PCR)技术检测禽网状内皮组织增殖病病毒(REV)的方法。方法提取感染REV-T和脾坏死病毒(SNV)的SPF鸡胚成纤维细胞DNA为模板,利用前病毒长末端重复序列(LTR)区引物进行扩增。采集肿瘤病鸡,以及人工感染REV 28 d后鸡肝脏、脾脏、肾脏、心脏、胸腺、法氏囊等器官,进行扩增。同时将采集的脏器组织,进行HE染色和免疫组化试验(IHC)。结果REV-T感染的组织未检测出电泳条带,而SNV感染的细胞中检测到了一条300bp特异而清晰的电泳条带,而且SNV感染的鸡组织中,PCR方法检测到了特异的条带。通过HE染色和免疫组化技术观察到了肿瘤组织,肿瘤细胞的形态、分布。结论PCR检测REV更快捷,特异更好。     

Tissue storage and primer selection influence pyrosequencing‐based inferences of diversity and community composition of endolichenic and endophytic fungi

Next‐generation sequencing technologies have provided unprecedented insights into fungal diversity and ecology. However, intrinsic biases and insufficient quality control in next‐generation methods can lead to difficult‐to‐detect errors in estimating fungal community richness, distributions and composition. The aim of this study was to examine how tissue storage prior to DNA extraction, primer design and various quality‐control approaches commonly used in 454 amplicon pyrosequencing might influence ecological inferences in studies of endophytic and endolichenic fungi. We first contrast 454 data sets generated contemporaneously from subsets of the same plant and lichen tissues that were stored in CTAB buffer, dried in silica gel or freshly frozen prior to DNA extraction. We show that storage in silica gel markedly limits the recovery of sequence data and yields a small fraction of the diversity observed by the other two methods. Using lichen mycobiont sequences as internal positive controls, we next show that despite careful filtering of raw reads and utilization of current best‐practice OTU clustering methods, homopolymer errors in sequences representing rare taxa artificially increased estimates of richness c. 15‐fold in a model data set. Third, we show that inferences regarding endolichenic diversity can be improved using a novel primer that reduces amplification of the mycobiont. Together, our results provide a rationale for selecting tissue treatment regimes prior to DNA extraction, demonstrate the efficacy of reducing mycobiont amplification in studies of the fungal microbiomes of lichen thalli and highlight the difficulties in differentiating true information about fungal biodiversity from methodological artefacts.     

Detection of Toxoplasma gondii DNA by polymerase chain reaction in experimentally desiccated tissues

Despite toxoplasmosis being a common infection among human and other warm-blooded animals worldwide, there are no findings about Toxoplasma gondii evolutionary forms in ancient populations. The molecular techniques used for amplification of genetic material have allowed recovery of ancient DNA (aDNA) from parasites contained in mummified tissues. The application of polymerase chain reaction (PCR) to paleoparasitological toxoplasmosis research becomes a promising option, since it might allow diagnosis, acquisition of paleoepidemiological data, access to toxoplasmosis information related origin, evolution, and distribution among the ancient populations. Furthermore, it makes possible the analysis of parasite aDNA aiming at phylogenetic studies. To standardize and evaluate PCR applicability to toxoplasmosis paleodiagnostic, an experimental mummification protocol was tested using desiccated tissues from mice infected with the ME49 strain cysts, the chronic infection group (CIG), or infected with tachyzoites (RH strain), the acute infection group (AIG). Tissues were subjected to DNA extraction followed by PCR amplification of T. gondii B1 gene. PCR recovered T. gondii DNA in thigh muscle, encephalon, heart, and lung samples. AIG presented PCR positivity in encephalon, lungs, hearts, and livers. Based on this results, we propose this molecular approach for toxoplasmosis research in past populations.     

DNA isolation from dry and fresh samples of polysaccharide-rich plants

DNA extraction is difficult in a variety of plants because of the presence of metabolites that interfere with DNA isolation procedures and downstream applications such as DNA restriction, amplification, and cloning. The chemotypic heterogeneity among species may not permit optimal DNA yield with a single protocol; thus, even closely related species may require different isolating protocols. Here we describe a modified procedure based on the hexadecyltrimethylammonium bromide (CTAB) method to isolate DNA from tissues containing high levels of polysaccharides. The procedure is applicable to both dry and fresh tissues and was tested on chickpea seeds, soybean, and wheat leaves. This method solved the problems of DNA degradation, contamination, and low yield due to binding and/or coprecipitation with starches and polysaccharides. The isolated DNA proved amenable to PCR amplification and restriction digestion.     

Detection of Vibrio vulnificus biotypes 1 and 2 in eels and oysters by PCR amplification.

DNA extraction procedures and PCR conditions to detect Vibrio vulnificus cells naturally occurring in oysters were developed. In addition, PCR amplification of V. vulnificus from oysters seeded with biotype 1 cells was demonstrated. By the methods described, V. vulnificus cells on a medium (colistin-polymyxin B-cellobiose agar) selective for this pathogen were detectable in oysters harvested in January and March, containing no culturable cells (< 67 CFU/g), as well as in oysters harvested in May and June, containing culturable cells. It was possible to complete DNA extraction, PCR, and gel electrophoresis within 10 h by using the protocol described for oysters. V. vulnificus biotype 2 cells were also detected in eel tissues that had been infected with this strain and subsequently preserved in formalin. The protocol used for detection of V. vulnificus cells in eels required less than 5 h to complete. Optimum MgCl2 concentrations for the PCR of V. vulnificus from oysters and eels were different, although the same primer pair was used for both. This is the first report on the detection of cells of V. vulnificus naturally present in shellfish and represents a potentially powerful method for monitoring this important human and eel pathogen.     

Analysis of Genetic Diversity amongIxoraCultivars (Rubiaceae) using Random Amplified Polymorphic DNA

We have optimized the genomic DNA extraction method from freshand dry laminas, as well as fresh and dry corolla lobes ofIxoracultivars.Some woody tropical species such as these contain excessiveamounts of phenolic compounds that co-precipitate with DNA resultingin poor or no amplification during the polymerase chain reaction(PCR). Repeated precipitation with CsCl coupled with phenol:chloroformextraction yielded high quality DNA suitable for consistentPCR amplification. The DNA from fresh laminas of 22 cultivarsofIxorawas subjected to random amplified polymorphic DNA (RAPD)analysis. Individual taxa could be identified using specificDNA markers from the RAPD profiles. Cluster analysis of datafrom six primers grouped all 22 cultivars distinctly under twocultivar groups, viz.,IxoraCoccinea andI.Javanica. The percentagegenetic similarity was calculated for all the cultivars basedon the RAPD data. The two cultivar groups and the outgroup plantswere also clearly distinguishable with polar ordination usinga matrix of genetic dissimilarities (one minus similarity).Our data indicate that besides the use of RAPD markers for identificationof particularIxoracultivars within a germplasm collection, thephylogenetic relationships generated by RAPD analysis may beuseful for future breeding programmes. IxoraL. cultivars; Rubiaceae; RAPD fingerprinting; DNA extraction; woody tropical species     

Sample extraction techniques for enhanced proteomic analysis of plant tissues

Major improvements in proteomic techniques in recent years have led to an increase in their application in all biological fields, including plant sciences. For all proteomic approaches, protein extraction and sample preparation are of utmost importance for optimal results; however, extraction of proteins from plant tissues represents a great challenge. Plant tissues usually contain relatively low amounts of proteins and high concentrations of proteases and compounds that potentially can limit tissue disintegration and interfere with subsequent protein separation and identification. An effective protein extraction protocol must also be adaptable to the great variation in the sets of secondary metabolites and potentially contaminating compounds that occurs between tissues (e.g., leaves, roots, fruit, seeds and stems) and between species. Here we present two basic protein extraction protocols that have successfully been used with diverse plant tissues, including recalcitrant tissues. The first method is based on phenol extraction coupled with ammonium acetate precipitation, and the second is based on trichloroacetic acid (TCA) precipitation. Both extraction protocols can be completed within 2 d.     

Extraction, amplification and characterization of wood DNA from dipterocarpaceae

A successful DNA extraction from wood yielding appropriate DNA quality for PCR amplification allows molecular genetic investigations of wood tissue. Genotypes, the origin of sampled material, and species can be identified based on an investigation of wood if suitable information on genetic variation patterns within and among species is available. Potential applications are in forensics and in the control of the timber and wood trade. We extracted DNA from wood of Dipterocarpaceae, a family that dominates rainforests and comprises many important timber species in Southeast Asia. Several different DNA isolation techniques were compared and optimized for wood samples from natural populations and from wood processing enterprises. The quality of the DNA was tested by spectrophotometry, PCR amplification, and PCR inhibitor tests. An average DNA yield of 2.2 μg was obtained per 50–100 mg of dried wood sample. Chloroplast DNA (cpDNA) regions of different length were amenable to PCR amplification from the extracted DNA. Modification of DNA isolation techniques by the addition of polyvinylpyrrolidone (PVP) addition up to 3.1% into lysis buffer reduced PCR inhibition effectively. In order to evaluate the extraction method, we analyzed leaves and wood from the same tree by PCR amplification, genotyping and sequencing of chloroplast microsatellites.