Material‐dependent growth of human skin bacteria on textiles investigated using challenge tests and DNA genotyping

Aims: To investigate the influence of different fibre materials on the colonization of textiles by skin bacteria present in human sweat. Methods and Results: The total bacterial content of axillary sweat samples was determined using DNA quantification, and the diversity of bacteria present was investigated. Fabrics made of different fibres were then challenged with these sweat samples; the bacterial DNA was quantified, and the bacterial taxa present were determined. We found differences in the overall colonization, with polyester and polyamide showing the highest bacterial mass. Also, significant differences in the various taxa of bacteria present on the different materials were found. In general, synthetic materials showed a selective growth of bacterial taxa underrepresented in sweat. In contrast, a cellulose‐based material showed only very few taxa, identically with those predominant in sweat. Conclusions: Our investigations demonstrated that besides the bacterial content of sweat itself, the type of material has a strong impact on the bacterial colonization of textiles. Significance and Impact of the Study: Odour generation is one of several effects resulting from an interaction of skin bacteria with textiles, and it is a common experience that there are differences in odour generation by different materials. Our investigations suggest that a selective growth of potentially odour‐producing bacteria may account for this.     

煮沸裂解法和试剂盒法提取浸矿菌基因组DNA的比较

目的:在生物浸出中,微生物群落结构分析有着重要意义,而群落分析的基础是提取纯度高、损失少的基因组DNA。为了解决这一问题,本实验通过比较两种较常用的DNA提取方法,煮沸裂解法和试剂盒法,寻找一种灵敏、快速、经济实用的制备浸矿细菌基因组DNA的方法。方法:分别用煮沸裂解法和试剂盒法提取6种浸矿菌的基因组DNA,从所提取的基因组DNA浓度、纯度、回收率和对PCR扩增反应的影响方面比较了两种方法的提取效果;用两种方法来处理不同浓度梯度的一种菌,通过实时定量PCR来比较两种方法的灵敏性。结果:相同处理量(108个)的革兰氏阳性菌(1株)、革兰氏阴性菌(4株)、古菌(1株)经两种方法提取的基因组DNA差异较大,煮沸裂解法所得的6组基因组DNA更纯,其OD260/OD280的值更接近1.8-2.0(纯DNA的OD260/OD280在1.8-2.0之间),前者所提DNA回收率最大可达后者的16.7倍;煮沸裂解法只需较少菌(102个)便能让实时定量PCR检测到所提DNA模板浓度,比试剂盒法灵敏。结论:两种方法提取的基因组DNA均可用于后续的PCR扩增,此外,前者提取的DNA浓度随细菌浓度增加而呈线性增大,而后者随菌浓度增大,所提DNA量增加有限,因此,在生物浸出中微生物基因组DNA的提取可直接采用简单快速的煮沸提取法,为实验节约成本和时间。     

Evaluation of the ISO Standard 11063 DNA Extraction Procedure for Assessing Soil Microbial Abundance and Community Structure

Soil DNA extraction has become a critical step in describing microbial biodiversity. Historically, ascertaining overarching microbial ecological theories has been hindered as independent studies have used numerous custom and commercial DNA extraction procedures. For that reason, a standardized soil DNA extraction method (ISO-11063) was previously published. However, although this ISO method is suited for molecular tools such as quantitative PCR and community fingerprinting techniques, it has only been optimized for examining soil bacteria. Therefore, the aim of this study was to assess an appropriate soil DNA extraction procedure for examining bacterial, archaeal and fungal diversity in soils of contrasting land-use and physico-chemical properties. Three different procedures were tested: the ISO-11063 standard; a custom procedure (GnS-GII); and a modified ISO procedure (ISOm) which includes a different mechanical lysis step (a FastPrep ®-24 lysis step instead of the recommended bead-beating). The efficacy of each method was first assessed by estimating microbial biomass through total DNA quantification. Then, the abundances and community structure of bacteria, archaea and fungi were determined using real-time PCR and terminal restriction fragment length polymorphism approaches. Results showed that DNA yield was improved with the GnS-GII and ISOm procedures, and fungal community patterns were found to be strongly dependent on the extraction method. The main methodological factor responsible for differences between extraction procedure efficiencies was found to be the soil homogenization step. For integrative studies which aim to examine bacteria, archaea and fungi simultaneously, the ISOm procedure results in higher DNA recovery and better represents microbial communities.     

煮沸裂解法和试剂盒法提取浸矿菌基因组DNA的比较

目的：在生物浸出中,微生物群落结构分析有着重要意义,而群落分析的基础是提取纯度高、损失少的基因组DNA。为了解决这一问题,本实验通过比较两种较常用的DNA提取方法,煮沸裂解法和试剂盒法,寻找一种灵敏、快速、经济实用的制备浸矿细菌基因组DNA的方法。方法：分别用煮沸裂解法和试剂盒法提取6种浸矿菌的基因组DNA,从所提取的基因组DNA浓度、纯度、回收率和对PCR扩增反应的影响方面比较了两种方法的提取效果;用两种方法来处理不同浓度梯度的一种菌,通过实时定量PCR来比较两种方法的灵敏性。结果：相同处理量（108个）的革兰氏阳性菌（1株）、革兰氏阴性菌（4株）、古菌（1株）经两种方法提取的基因组DNA差异较大,煮沸裂解法所得的6组基因组DNA更纯,其OD260／OD280的值更接近1．8-2．0（纯DNA的OD260／OD280在1．8—2．0之间）,前者所提DNA回收率最大可达后者的16．7倍;煮沸裂解法只需较少菌（102个）便能让实时定量PCR检测到所提DNA模板浓度,比试剂盒法灵敏。结论：两种方法提取的基因组DNA均可用于后续的PCR扩增,此外,前者提取的DNA浓度随细菌浓度增加而呈线性增大,而后者随茵浓度增大,所提DNA量增加有限,因此,在生物浸出中微生物基因组DNA的提取可直接采用简单快速的煮沸提取法,为实验节约成本和时间。     

牙菌斑生物膜的形成与控制

牙菌斑生物膜是附着于牙釉质表面,由复杂的微生物群落构成的一种聚集体。牙菌斑生物膜的形成与生长对口腔健康有着直接或间接的影响,许多研究证实口腔疾病如龋齿和牙周病都与细菌的积累及牙菌斑的形成有关。在牙菌斑生物膜形态建成过程中,牙齿表面最初的定殖菌对生物膜的微生物组成和结构至关重要,这些初级定殖菌决定了后续与之结合形成共生体的微生物种类和数量。不同的微生物组成可能在与生物膜形成相关的口腔病理状况中发挥不同的作用。因此,本文就牙菌斑生物膜的生长及控制进行综述,介绍其微生物的早期定殖和成熟过程、以及通过物理和化学方法对牙菌斑生物膜的控制,以期为了解牙菌斑生物膜的形成机制及相关口腔疾病的预防和治疗提供有价值的参考。     

Chitosan’s biological activity upon skin-related microorganisms and its potential textile applications

Over the years the body of work relating chitosan and its possible skin-related applications has grown, showing that chitosan is active both as a free compound and as a functional finishing of textiles. As a free molecule chitosan proved itself to be an attractive option as it is biocompatible and has a demonstrated biological activity (e.g. growth inhibition or adhesion inhibition) upon multiple skin pathogens, even upon multidrug resistant species. Furthermore, chitosan has wound healing accelerating properties, which make it a prime candidate for possible control of skin related infections. Almost inconspicuously, textiles have been one the main lines of defense of the skin against foreign threats, acting as a physical barrier to microbial colonization and infection. With the advent of textile functionalization specially designed textiles with enhanced protective characteristics, such as antimicrobial capacity, have come to the forefront. Chitosan functionalized textiles have been shown to be effective inhibitors of microbial growth with even invasive multidrug resistant species, as MRSA, being inhibited. Therefore, chitosan and chitosan functionalized textiles present themselves as both an interesting alternative to traditional antibiotics and as a possible means to enhance current treatment strategies.     

Comparison of DNA and RNA quantification methods suitable for parameter estimation in metabolic modeling of microorganisms

Recent developments in cellular and molecular biology require the accurate quantification of DNA and RNA in large numbers of samples at a sensitivity that enables determination on small quantities. In this study, five current methods for nucleic acid quantification were compared: (i) UV absorbance spectroscopy at 260 nm, (ii) colorimetric reaction with orcinol reagent, (iii) colorimetric reaction based on diphenylamine, (iv) fluorescence detection with Hoechst 33258 reagent, and (v) fluorescence detection with thiazole orange reagent. Genomic DNA of three different microbial species (with widely different G+C content) was used, as were two different types of yeast RNA and a mixture of equal quantities of DNA and RNA. We can conclude that for nucleic acid quantification, a standard curve with DNA of the microbial strain under study is the best reference. Fluorescence detection with Hoechst 33258 reagent is a sensitive and precise method for DNA quantification if the G+C content is less than 50%. In addition, this method allows quantification of very low levels of DNA (nanogram scale). Moreover, the samples can be crude cell extracts. Also, UV absorbance at 260 nm and fluorescence detection with thiazole orange reagent are sensitive methods for nucleic acid detection, but only if purified nucleic acids need to be measured.     

DNA提取过程中混入的实验室空气微生物DNA定量

元基因组测序方法为微生物研究提供了有力的工具。但其中的DNA提取过程,会不可避免地混入实验室中的空气微生物。这些微生物DNA,是否会对一些极微量的元基因组检测 (如皮肤样本等) 结果造成影响,有多大影响,仍没有明确结论。本研究首先收集了实验室空气样品,用16S rRNA引物建立了基于qPCR的标准曲线,并检测了在开放环境下提取DNA过程中可掺杂的环境微生物DNA量。然后在开放环境下提取纯水DNA样品并进行元基因组分析,以确定掺杂环境微生物的种类。最后分别在生物安全柜和实验室开放环境下提取皮肤样本,并用鸟枪测序方法对样本的微生物组成进行分析,以评估掺杂环境微生物对元基因组检测结果的影响。结果显示,在实验室开放环境的DNA提取过程中,环境微生物的DNA残留可达28.9 pg,可达某些极微量样本DNA总量的30%。元基因组分析显示,样品中掺杂的环境微生物主要是痤疮杆菌Cutibacterium acnes、大肠杆菌Escherichia coli等皮肤常见细菌。与洁净皮肤样本的信息相比,开放环境下提取掺杂了数十种环境微生物,并导致主要菌种的丰度大幅降低,从而影响结果的真实性。因此,微量样品的DNA提取应在洁净环境下执行。     

快速、高效的羊绒羊毛织品DNA提取方法的建立

目的：建立一种快速、高效的羊绒羊毛纺织品DNA提取的方法。方法：采用chelex-100法的3种处理、试剂盒法分别提取羊绒羊毛织品的DNA,用18S rDNA片段、山羊和绵羊源性成分PCR扩增结果来比较提取效果。结果：试剂盒法提取DNA的效果优于chelex-100法,整个提取过程约需2h。9种供试材料均提取到DNA,且含有山羊和/或绵羊源性成分,与显微镜观察结果的符合率为100%。结论：建立的试剂盒法是一种快速、高效的适用于羊绒羊毛织品DNA提取的方法,为应用分子生物学方法鉴别山羊绒和绵羊毛奠定了基础。     

A simplified diphenylamine colorimetric method for growth quantification

Cell growth needs to be monitored in biological studies and bioprocess optimization. In special circumstances, such as microbial fermentations in media containing insoluble particles, accurate cell growth quantification is a challenge with current methods. Only the Burton method is applicable in such circumstances. The original Burton method was previously simplified by adopting a two-step sample pretreatment in perchloric acid procedure to eliminate the need for DNA extraction. Here, we further simplified the Burton method by replacing the previous two-step perchloric acid pretreatment with a new and one-step diphenylamine reagent pretreatment. The reliability and accuracy of this simplified method were assessed by measuring the biomass of four model microorganisms: Escherichia coli, Streptomyces clavuligerus, Saccharomyces cerevisiae, and Trichoderma reesei grown in normal media or those containing solid particles. The results demonstrate that this new simplified method performs comparably to the conventional methods, such as OD₆₀₀ or the previously modified Burton method, and is much more sensitive than the dry weight method. Overall, the new method is simple, reliable, easy to perform, and generally applicable in most circumstances, and it reduces the operation time from more than 12 h (for the previously simplified Burton method) to about 2 h.     

Automated measurement and quantification of heterotrophic bacteria in water samples based on the MPN method

Quantification of heterotrophic bacteria is a widely used measure for water analysis. Especially in terms of drinking water analysis, testing for microorganisms is strictly regulated by the European Drinking Water Directive, including quality criteria and detection limits. The quantification procedure presented in this study is based on the most probable number (MPN) method, which was adapted to comply with the need for a quick and easy screening tool for different kinds of water samples as well as varying microbial loads. Replacing tubes with 24-well titer plates for cultivation of bacteria drastically reduces the amount of culture media and also simplifies incubation. Automated photometric measurement of turbidity instead of visual evaluation of bacterial growth avoids misinterpretation by operators. Definition of a threshold ensures definite and user-independent determination of microbial growth. Calculation of the MPN itself is done using a program provided by the US Food and Drug Administration (FDA). For evaluation of the method, real water samples of different origins as well as pure cultures of bacteria were analyzed in parallel with the conventional plating methods. Thus, the procedure described requires less preparation time, reduces costs and ensures both stable and reliable results for water samples.     

Evaluation of rapid DNA extraction methods for the quantitative detection of fungi using real-time PCR analysis

Three comparatively rapid methods for the extraction of DNA from fungal conidia and yeast cells in environmental (air, water and dust) samples were evaluated for use in real-time PCR (TaqMan™) analyses. A simple bead milling method was developed to provide sensitive, accurate and precise quantification of target organisms in air and water (tap and surface) samples. However, quantitative analysis of dust samples required further purification of the extracted DNA by a streamlined silica adsorption procedure.     

An improved protocol and a new grinding device for extraction of genomic DNA from microorganisms by a two-step extraction procedure

Current protocols to extract genomic DNA from microorganisms are still laborious, tedious and costly, especially for the species with thick cell walls. In order to improve the effectiveness of extracting DNA from microbial samples, a novel protocol, defined as two-step extraction method, along with an improved tissue-grinding device, was developed. The protocol included two steps, disruption of microbial cells or spores by grinding the sample together with silica sand in a new device and extraction of DNA with an effective buffer containing cell lysis chemicals. The device was prepared by using a commercial electric mini-grinder, adapted with a grinding stone, and a sample cup processed by lathing from a polytetrafluoroethylene rod. We tested the method with vegetative cells of four microbial species and two microbial spores that have thick cell walls and are therefore hard to process; these included Escherichia coli JM109, Bacillus subtilis WB600, Sacchromyces cerevisiae INVSc1, Trichoderma viride AS3.3711, and the spores of S. cerevisiae and T. viride, respectively, representing Gram-positive bacteria, Gram-negative bacteria, yeast, filamentous fungi. We found that this new method and device extracted usable quantities of genomic DNA from the samples. The DNA fragments that were extracted exceeded 23 kb. The target sequences up to about 5 kb were successfully and exclusively amplified by PCR using extracted DNA as the template. In addition, the DNA extraction was finalized within 1.5 h. Thus, we conclude that this two-step extraction method is an effective and improved protocol for extraction of genomic DNA from microbial samples.     

Sensitive determination of microbial growth by nucleic acid staining in aqueous suspension

The determination of cell numbers or biomass in laboratory cultures or environmental samples is usually based on turbidity measurements, viable counts, biochemical determinations (e.g., protein and lipid measurements), microscopic counting, or recently, flow cytometric analysis. In the present study, we developed a novel procedure for the sensitive quantification of microbial cells in cultures and most-probable-number series. The assay combines fluorescent nucleic acid staining and subsequent fluorescence measurement in suspension. Six different fluorescent dyes (acridine orange, DAPI [4',6'-diamidino-2-phenylindole], ethidium bromide, PicoGreen, and SYBR green I and II) were evaluated. SYBR green I was found to be the most sensitive dye and allowed the quantification of 50,000 to up to 1.5 x 10(8) Escherichia coli cells per ml sample. The rapid staining procedure was robust against interference from rRNA, sample fixation by the addition of glutaric dialdehyde, and reducing agents such as sodium dithionite, sodium sulfide, and ferrous sulfide. It worked well with phylogenetically distant bacterial and archaeal strains. Excellent agreement with optical density measurements of cell increases was achieved during growth experiments performed with aerobic and sulfate-reducing bacteria. The assay offers a time-saving, more sensitive alternative to epifluorescence microscopy analysis of most-probable-number dilution series. This method simplifies the quantification of microbial cells in pure cultures as well as enrichments and is particularly suited for low cell densities.     

Selective removal of DNA from dead cells of mixed bacterial communities by use of ethidium monoazide

The distinction between viable and dead bacterial cells poses a major challenge in microbial diagnostics. Due to the persistence of DNA in the environment after cells have lost viability, DNA-based quantification methods overestimate the number of viable cells in mixed populations or even lead to false-positive results in the absence of viable cells. On the other hand, RNA-based diagnostic methods, which circumvent this problem, are technically demanding and suffer from some drawbacks. A promising and easy-to-use alternative utilizing the DNA-intercalating dye ethidium monoazide bromide (EMA) was published recently. This chemical is known to penetrate only into "dead" cells with compromised cell membrane integrity. Subsequent photoinduced cross-linking was reported to inhibit PCR amplification of DNA from dead cells. We provide evidence here that in addition to inhibition of amplification, most of the DNA from dead cells is actually lost during the DNA extraction procedure, probably together with cell debris which goes into the pellet fraction. Exposure of bacteria to increasing stress and higher proportions of dead cells in defined populations led to increasing loss of genomic DNA. Experiments were performed using Escherichia coli O157:H7 and Salmonella enterica serovar Typhimurium as model pathogens and using real-time PCR for their quantification. Results showed that EMA treatment of mixed populations of these two species provides a valuable tool for selective removal of DNA of nonviable cells by using conventional extraction protocols. Furthermore, we provide evidence that prior to denaturing gradient gel electrophoresis, EMA treatment of a mature mixed-population drinking-water biofilm containing a substantial proportion of dead cells can result in community fingerprints dramatically different from those for an untreated biofilm. The interpretation of such fingerprints can have important implications in the field of microbial ecology.     

SIMULTANEOUS PCR DETECTION OF BACTERIA AND MOLD DNA SEQUENCES IN PHARMACEUTICAL SAMPLES BY USING A GRADIENT THERMOCYCLER

A gradient thermocycler, the Stratagene RoboCycler 96-Gradient, was evaluated for the simultaneous PCR amplification of microbial genes which indicated the presence of Escherichia coli, Staphylococcus aureus, Pseudomonas aeruginosa, and Aspergillus niger in pharmaceutical samples. Suspensions of pharmaceutical products were inoculated with pure cultures of bacteria and mold. After a 24 h incubation, bacterial DNA was extracted from each enrichment broth using a mild lysis in Tris-EDTA-Tween 20 buffer containing proteinase K while mold DNA was extracted by boiling the samples in Tris-EDTA-SDS buffer for 1 h. A 10 μL aliquots of extracted DNA was added to Ready-To-Go PCR beads and specific primers for E. coli, S. aureus, and P. aeruginosa. However, 50 μL aliquots of extracted mold DNA were used for amplification of specific A. niger DNA sequences. The individual samples were loaded into the RoboCycler 96-Gradient thermocycler. Simultaneous detection of all microbial genes was performed by using a gradient profile that allowed the use of DNA primers with different annealing temperatures. Standard methods for quality control evaluation of pharmaceutical products required 6–8 days while simultaneous PCR detection of bacteria and mold DNA sequences was completed within 27 h.     

Quantification of bias related to the extraction of DNA directly from soils

In recent years, several protocols based on the extraction of nucleic acids directly from the soil matrix after lysis treatment have been developed for the detection of microorganisms in soil. Extraction efficiency has often been evaluated based on the recovery of a specific gene sequence from an organism inoculated into the soil. The aim of the present investigation was to improve the extraction, purification, and quantification of DNA derived from as large a portion of the soil microbial community as possible, with special emphasis placed on obtaining DNA from gram-positive bacteria, which form structures that are difficult to disrupt. Furthermore, we wanted to identify and minimize the biases related to each step in the procedure. Six soils, covering a range of pHs, clay contents, and organic matter contents, were studied. Lysis was carried out by soil grinding, sonication, thermal shocks, and chemical treatments. DNA was extracted from the indigenous microflora as well as from inoculated bacterial cells, spores, and hyphae, and the quality and quantity of the DNA were determined by gel electrophoresis and dot blot hybridization. Lysis efficiency was also estimated by microscopy and viable cell counts. Grinding increased the extracellular DNA yield compared with the yield obtained without any lysis treatment, but none of the subsequent treatments clearly increased the DNA yield. Phage lambda DNA was inoculated into the soils to mimic the fate of extracellular DNA. No more than 6% of this DNA could be recovered from the different soils. The clay content strongly influenced the recovery of DNA. The adsorption of DNA to clay particles decreased when the soil was pretreated with RNA in order to saturate the adsorption sites. We also investigated different purification techniques and optimized the PCR methods in order to develop a protocol based on hybridization of the PCR products and quantification by phosphorimaging.     

Direct measurement of roots in soil for single and mixed species using a quantitative DNA-based method

Molecular techniques present a new opportunity to study roots and their interactions in soil. Extraction and quantification of species-specific DNA directly from soil allows direct identification of roots in mixed swards reducing the need for labour-intensive methods to recover and identify individual roots. DNA was extracted directly from up to 0.5 kg of soil and the presence of individual species quantified using species-specific probes with quantitative real-time PCR. A range of plant and soil factors influenced the DNA content measured in roots and it was necessary to account for these influences when converting DNA amount to root mass. The utility of the method for quantitative root studies was demonstrated in an experiment to investigate the effect of lime on root growth of acid-soil resistant and sensitive perennial grasses grown together in an aluminium-toxic soil. The root mass of an acid-soil resistant species was unaffected by lime application, whereas that of an acid-soil sensitive species was restricted by soil acidity. Molecular techniques present a promising tool for quantification of root mass directly in soil and have applications for field studies involving mixed species of plants.     

Optimizing Taq Polymerase Concentration for Improved Signal-to-Noise in the Broad Range Detection of Low Abundance Bacteria

Background

PCR in principle can detect a single target molecule in a reaction mixture. Contaminating bacterial DNA in reagents creates a practical limit on the use of PCR to detect dilute bacterial DNA in environmental or public health samples. The most pernicious source of contamination is microbial DNA in DNA polymerase preparations. Importantly, all commercial Taq polymerase preparations inevitably contain contaminating microbial DNA. Removal of DNA from an enzyme preparation is problematical.

Methodology/Principal Findings

This report demonstrates that the background of contaminating DNA detected by quantitative PCR with broad host range primers can be decreased greater than 10-fold through the simple expedient of Taq enzyme dilution, without altering detection of target microbes in samples. The general method is: For any thermostable polymerase used for high-sensitivity detection, do a dilution series of the polymerase crossed with a dilution series of DNA or bacteria that work well with the test primers. For further work use the concentration of polymerase that gave the least signal in its negative control (H₂O) while also not changing the threshold cycle for dilutions of spiked DNA or bacteria compared to higher concentrations of Taq polymerase.

Conclusions/Significance

It is clear from the studies shown in this report that a straightforward procedure of optimizing the Taq polymerase concentration achieved “treatment-free” attenuation of interference by contaminating bacterial DNA in Taq polymerase preparations. This procedure should facilitate detection and quantification with broad host range primers of a small number of bona fide bacteria (as few as one) in a sample.     

不同粪便DNA提取方法比较分析北大核心CSCD

肠道微生物群落结构和多样性与人体疾病密切相关。然而,相关群落结构分析结果可能受到DNA提取质量等实验因素影响。因此,评估不同DNA提取方法对肠道特定种属的提取效果,对于全面、准确获取人体肠道微生物谱,深入探究肠道微生物群落结构具有指导意义。本研究旨在借助实时荧光定量PCR(real-time quantitative polymerase chain reaction,RT qPCR)技术,以DNA提取纯度、浓度,以及对肠道中特定种属微生物基因组DNA的提取丰度为指标,对5种DNA提取方法进行比较分析。结果表明,试剂盒Q的提取效果最佳,特别是对乳杆菌属和双歧杆菌属等革兰氏阳性菌的提取效果较好。N试剂盒的平均DNA提取浓度较Q试剂盒低,但在纯度方面,二者无显著性差异。与其他3种商用试剂盒(M、PSP、TG)相比,N方法对肠道内指定微生物基因组的提取效果仅次于Q试剂盒,位居第二。相比之下,M试剂盒提取所得DNA,质量较高,但浓度偏低,对于肠道内革兰氏阳性菌的提取效果不很理想。TG试剂盒和PSP试剂盒提取所得DNA在浓度、质量以及细菌丰度方面均不及其他验证的试剂盒。综上,Q试剂盒可作为肠道微生态研究相关实验中获取高质量基因组DNA的提取方法。本研究结果为肠道微生态研究相关实验中基因组DNA提取方法的选择提供参考依据。