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。     

猪传染性胃肠炎病毒S基因B和C抗原位点片段在毕赤酵母中的表达

采用基因重组的方法构建了含有猪传染性胃肠炎病毒S基因B和C抗原位点片段的巴斯德毕赤酵母Pichiapastoris分泌型表达载体pPIC9K-ts,经线性化后采用电穿孔法将其导入毕赤酵母GS115中,大量筛选后获得高效表达外源蛋白的毕赤酵母工程菌株GS115/pPIC9K-ts。表达蛋白经Dot-ELISA检测具有良好的抗原性。本研究为TGE的血清学检测方法的建立提供了必要的物质基础。     

血液基因组DNA的快速提取方法

目的:研究血液中基因组DNA的简便快速提取方法。方法:取新鲜抗凝血,以红细胞裂解液除去红细胞,再破碎白细胞,除去杂蛋白,获得基因组DNA。结果:所得基因组DNA完整、无断裂,含量和纯度均较高。以所提基因组DNA作为模板能很好的扩增出p21因子启动子序列,因此该法所提取的DNA是完整可靠的。结论:该法能简便、快速、安全、廉价的提取血液中的基因组DNA,并适用于临床检测和分子生物学研究。     

一种提取全血基因组DNA的改良方法

目的:将碘化钾法和试剂盒法相结合,建立一种安全无毒、快速、经济、有效的提取全血基因组DNA的方法。方法:用0.2%Na Cl裂解红细胞收集全血中的白细胞,用5 mol/L KI裂解白细胞膜,再用试剂盒提取DNA,采用紫外分光光度仪、凝胶电泳、荧光定量PCR进行检测。结果:本法提取300μL抗凝血可得基因组DNA 5~12μg,D260nm/D280nm为1.86±0.02。原本提取100次全血基因组DNA的试剂量提升到可提取200次。结论:改良法提高了试剂盒的使用率,所得基因组DNA稳定,是一种操作简便、快速高效并节省试验经费的提取方法。     

里氏木霉α-半乳糖苷酶基因agl2在毕氏酵母中高效表达

通过反转录PCR从里氏木霉RutC-30 基因中克隆到α-半乳糖苷酶基因agl2,将其构建到具有AOX1强启动子的表达载体pPIC9K中,线性化后转化到毕氏酵母GS115中进行表达。结果表明agl2基因在毕氏酵母GS115中得到了高效表达,在50 L发酵罐中高密度发酵168 h,酶活达最高值1 106 U/mL。经PCR产物鉴定,结果表明agl2基因已整合到毕氏酵母GS115基因组中。     

一种快速、有效、经济的提取酵母质粒的方法

目的：建立一种经济有效、快速简便、稳定的提取酵母质粒的方法。方法：用葡糖苷酸酶消化酵母细胞壁以获取原生质体,然后采用碱裂解法裂解原生质体以获得质粒。结果：与采用商品化离心柱法试剂盒所提取的质粒相比,用该法获取的酵母质粒在PCR分析及转化效果方面没有差异。结论：建立了一种经济有效、快速简便、稳定的提取酵母质粒的方法。     

毕赤酵母STE13基因敲除对GGH表达及其生物活性的影响

目的:重组毕赤酵母GS115/pPIC9K-GGH表达的人胰高血糖素样肽-1-人血清白蛋白融合蛋白[(GLP-1 A2G)2-HSA,GGH]的细胞活性测评结果显示生物活性较低,这可能与其表达过程中蛋白降解有一定关联.通过对毕赤酵母GS115 STE13基因的敲除,获得一株完整表达蛋白GGH的毕赤酵母宿主,并进一步提高其表达产物GGH的生物活性.方法:采用基于PCR技术介导的Cre-Loxp系统重组技术成功敲除宿主菌GS115的STE13基因,得到一株STE13缺陷型菌株GS115/D13,并通过细胞活性测评系统检测GS115/D13表达产物GGH的生物活性.结果:通过对STE13基因缺陷型菌株GS115/D13与出发菌株GS115/W发酵表达对比,显示GS115/D13菌株表达融合蛋白GGH生物活性有明显提升,且表达量提高了25.8％,两菌株生长无明显差异.结论:STE13基因的敲除成功缓解了GGH表达过程中的降解问题,并相对出发菌株GS115/W大幅度提高了蛋白生物活性.     

磁珠法快速提取基因组DNA的实验研究

针对临床标本基因组DNA的提取方法缺乏广泛适用性,提取步骤繁琐,需要进行离心操作,并且提取过程中会用到苯酚、氯仿等有机试剂,会对操作人员有一定的危害性等不足,本研究拟建立一种适用于临床标本的基因组DNA快速提取方法。在传统的基因组DNA提取试剂和方法的基础上,本研究采用二氧化硅修饰的超顺磁珠设计了一种基因组DNA快速提取方法;探讨磁珠用量、裂解液p H、盐酸胍浓度等因素对基因组DNA提取效率的影响并采用凝胶电泳实验进行验证。当磁珠用量在50~100μg/100 mg样品,裂解液p H约为6,盐酸胍的浓度为6 mol/L时基因组DNA提取效果好、效率高,且磁珠的用量与吸附表面积成正比,但达到一定用量后不会增加提取量,对于100 mg肺组织,适宜的磁珠用量为80μg。此基因组DNA提取方法高效省时,简便快捷,性价比高,适用临床大量样本基因组DNA提取。     

巴斯德毕赤酵母表达系统中甘油阻遏相关基因GR1的分离克隆与鉴定

目的：分离克隆并鉴定巴斯德毕赤酵母表达系统中甘油阻遏相关基因。方法：PCR扩增LacZ基因,克隆至pPLC9载体,构建pPIC9-LacZ表达载体,经Sal I线性化后转化巴斯德毕赤酵母GS115,构建GS115-LacZ模式菌株;用限制酶介导整合（REMI）技术使GS115-LacZ菌体基因组产生随机突变,筛选甘油去阻遏的GS115-LacZ△菌体;Southern blot鉴定GS115-LacZ△基因组,用质粒拯救技术和TAIL-PCR克隆未知基因序列并测序。结果：得到甘油去阻遏的GS115-LacZ△菌体,经Southern blot分析,突变仅发生在1个基因中;通过质粒拯救和TAIL-PCR,分离得到阻遏相关基因GR1,共2863bp,经在线BLAST,发现其编码一种过氧化物酶体自吞噬相关蛋白。结论：分离得到阻遏相关基因GR1,与过氧化物酶体自吞噬相关,提示过氧化物酶体自吞噬相关基因可能对醇氧化酶启动子AOX1的转录活性有影响。     

大量Pichia pastoris酵母基因组DNA的提取

巴斯德毕赤酵母(Pichia pastoris)表达系统是目前应用最广泛的外源基因表达系统之一,提取酵母基因组是研究酵母必需的方法之一.针对常用的几种毕赤酵母基因组DNA的制备方法进行比较,并对玻璃珠法进行改进.改良的玻璃珠法不但具有省时省力、操作简便且结果稳定的优,适合于大量DNA的提取.该方法的革新将对酵母重组子的PCR鉴定检测及表达产品DNA相关检测提供更高效稳定的保证,将成为酵母等类似微生物基因组DNA制备的首选方法.     

Extraction of genomic DNA from yeasts for PCR-based applications

We have developed a quick and low-cost genomic DNA extraction protocol from yeast cells for PCR-based applications. This method does not require any enzymes, hazardous chemicals, or extreme temperatures, and is especially powerful for simultaneous analysis of a large number of samples. DNA can be efficiently extracted from different yeast species (Kluyveromyces lactis, Hansenula polymorpha, Schizosaccharomyces pombe, Candida albicans, Pichia pastoris, and Saccharomyces cerevisiae). The protocol involves lysis of yeast colonies or cells from liquid culture in a lithium acetate (LiOAc)-SDS solution and subsequent precipitation of DNA with ethanol. Approximately 100 nanograms of total genomic DNA can be extracted from 1 × 10(7) cells. DNA extracted by this method is suitable for a variety of PCR-based applications (including colony PCR, real-time qPCR, and DNA sequencing) for amplification of DNA fragments of ≤ 3500 bp.     

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.     

A simplified universal genomic DNA extraction protocol suitable for PCR

Conventional genomic DNA extraction protocols need expensive and hazardous reagents for decontamination of phenolic compounds from the extracts and are only suited for certain types of tissue. We developed a simple, time-saving and cost-efficient method for genomic DNA extraction from various types of organisms, using relatively innocuous reagents. The protocol employs a single purification step to remove contaminating compounds, using a silica column and a non-hazardous buffer, and a chaotropic-detergent lysing solution that hydrolyzes RNA and allows the selective precipitation of DNA from cell lysates. We used this system to extract genomic DNA from different tissues of various organisms, including algae (Dunaliella salina), human peripheral blood, mouse liver, Escherichia coli, and Chinese hamster ovary cells. Mean DNA yields were 20-30 μg/cm(3) from fresh tissues (comparable to yields given by commercial extraction kits), and the 260/280 nm absorbance ratio was 1.8-2.0, demonstrating a good degree of purity. The extracted DNA was successfully used in PCR, restriction enzyme digestion and for recombinant selection studies.     

Rapid isolation of yeast genomic DNA: Bust n' Grab

Background

Mutagenesis of yeast artificial chromosomes (YACs) often requires analysis of large numbers of yeast clones to obtain correctly targeted mutants. Conventional ways to isolate yeast genomic DNA utilize either glass beads or enzymatic digestion to disrupt yeast cell wall. Using small glass beads is messy, whereas enzymatic digestion of the cells is expensive when many samples need to be analyzed. We sought to develop an easier and faster protocol than the existing methods for obtaining yeast genomic DNA from liquid cultures or colonies on plates.

Results

Repeated freeze-thawing of cells in a lysis buffer was used to disrupt the cells and release genomic DNA. Cell lysis was followed by extraction with chloroform and ethanol precipitation of DNA. Two hundred ng – 3 μg of genomic DNA could be isolated from a 1.5 ml overnight liquid culture or from a large colony. Samples were either resuspended directly in a restriction enzyme/RNase coctail mixture for Southern blot hybridization or used for several PCR reactions. We demonstrated the utility of this method by showing an analysis of yeast clones containing a mutagenized human β-globin locus YAC.

Conclusion

An efficient, inexpensive method for obtaining yeast genomic DNA from liquid cultures or directly from colonies was developed. This protocol circumvents the use of enzymes or glass beads, and therefore is cheaper and easier to perform when processing large numbers of samples.

     

Extraction of high-quality genomic DNA from latex-containing plants

The isolation of intact, high-molecular-mass genomic DNA is essential for many molecular biology applications including long PCR, endonuclease restriction digestion, Southern blot analysis, and genomic library construction. Many protocols are available for the extraction of DNA from plant material. However, for latex-containing Asteraceae (Cichorioideae) species, standard protocols and commercially available kits do not produce efficient yields of high-quality amplifiable DNA. A cetyltrimethylammonium bromide protocol has been optimized for isolation of genomic DNA from latex-containing plants. Key steps in the modified protocol are the use of etiolated leaf tissue for extraction and an overnight 25 degrees C isopropanol precipitation step. The purified DNA has excellent spectral qualities, is efficiently digested by restriction endonucleases, and is suitable for long-fragment PCR amplification.     

DNA isolation protocol for the medicinal plant lemon balm (Melissa officinalis, Lamiaceae)

Lemon balm (Melissa officinalis) is a medicinal plant that is widely used as a sedative or calmant, spasmolytic and antibacterial agent and sleep aid. This has led to a high demand for lemon balm products, resulting in the extinction of this species in some of its natural habitats. Molecular techniques have increasingly been used in plant diversity conservation and isolation of PCR amplifiable genomic DNA is an important pre-requisite. Lemon balm contains high levels of polyphenols and polysaccharides, which pose a major challenge for the isolation of high-quality DNA. We compared different genomic DNA extraction protocols, including traditional phenol-chloroform DNA extraction protocols and two commercial kits for DNA purification for their ability to produce good-quality DNA from fresh leaves of five lemon balm genotypes. Quality and quantity of the DNA samples were determined using 0.8% agarose gel electrophoresis and a spectrophotometer. The DNA purity was further confirmed by PCR amplification using barley retrotransposon LTR base primers. The spectral quality of DNA as measured by the A(260)/A(280) ratio ranged from 1.46 to 2.37. The Fermentase genomic DNA purification kit and the CTAB extraction protocol using PVP and ammonium acetate to overcome the high levels of polyphenols and polysaccharides yielded high-quality DNA with a mean A(260)/A(280) ratio of 1.87. The quantity of DNA and its PCR purity were similar with all the protocols, but considering the time and cost required for extraction of DNA from a large number of samples, the CTAB protocol using PVP and ammonium acetate is suitable for lemon balm.     

Modified low‐salt CTAB extraction of high‐quality DNA from contaminant‐rich tissues

The increasing use of high‐throughput sequencing platforms has made the isolation of pure, high molecular weight DNA a primary concern for studies of a diverse range of organisms. Purification of DNA remains a significant challenge in many tissue and sample types due to various organic and inorganic molecules that coprecipitate with nucleic acids. Molluscs, for example, contain high concentrations of polysaccharides which often coprecipitate with DNA and can inhibit downstream enzymatic reactions. We modified a low‐salt CTAB (MoLSC) extraction protocol to accommodate contaminant‐rich animal tissues and compared this method to a standard CTAB extraction protocol and two commercially available animal tissue DNA extraction kits using oyster adductor muscle. Comparisons of purity and molecular integrity showed that our in‐house protocol yielded genomic DNA generally free of contaminants and shearing, whereas the traditional CTAB method and some of the commercial kits yielded DNA unsuitable for some applications of massively parallel sequencing. Our open‐source MoLSC protocol provides a cost‐effective, scalable, alternative DNA extraction method that can be easily optimized and adapted for sequencing applications in other contaminant‐rich samples.     

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。     

Buccal cell DNA extraction: yield, purity, and cost: a comparison of two methods

Simple and cost-effective methods are needed to extract DNA in order to use it in large-scale studies. Blood is an excellent DNA source; however, it is costly and invasive thus an alternative is needed. Several kits and chemical protocols using buccal cells have been proposed for DNA extraction. The objective of the study is to evaluate buccal NaOH chemical protocol and Nucleospin Tissue Kit (BD Biosciences, Macery-Nagel, Germany) for DNA extraction. DNA swab samples were collected from 300 voluntary participants. DNA yields and purity were measured by NaOH and Nucleospin Tissue Kit techniques; the cost and time consumption for DNA extraction per sample were assessed as well. Results have shown that DNA amount and purity extracted by NaOH procedure was compared to that of the kit (p = 0.164; p = 0.249, respectively). NaOH method was considered cheaper and less time consuming (0.06 versus 3.80 USD, and 1.33 versus 3.59 minutes per sample, p < 0.001). Buccal cell derived DNA extracted by NaOH protocol can be considered a feasible substitute for more expensive and time-consuming kits.     

Efficient isolation method for high‐quality genomic DNA from cicada exuviae

In recent years, animal ethics issues have led researchers to explore nondestructive methods to access materials for genetic studies. Cicada exuviae are among those materials because they are cast skins that individuals left after molt and are easily collected. In this study, we aim to identify the most efficient extraction method to obtain high quantity and quality of DNA from cicada exuviae. We compared relative DNA yield and purity of six extraction protocols, including both manual protocols and available commercial kits, extracting from four different exoskeleton parts. Furthermore, amplification and sequencing of genomic DNA were evaluated in terms of availability of sequencing sequence at the expected genomic size. Both the choice of protocol and exuvia part significantly affected DNA yield and purity. Only samples that were extracted using the PowerSoil DNA Isolation kit generated gel bands of expected size as well as successful sequencing results. The failed attempts to extract DNA using other protocols could be partially explained by a low DNA yield from cicada exuviae and partly by contamination with humic acids that exist in the soil where cicada nymphs reside before emergence, as shown by spectroscopic measurements. Genomic DNA extracted from cicada exuviae could provide valuable information for species identification, allowing the investigation of genetic diversity across consecutive broods, or spatiotemporal variation among various populations. Consequently, we hope to provide a simple method to acquire pure genomic DNA applicable for multiple research purposes.