A Statistical Approach to Identify Ancient Template DNA

One of the key problems in the study of ancient DNA is that of authenticating sequences obtained from PCR amplifications of highly degraded samples. Contamination of ancient samples and postmortem damage to endogenous DNA templates are the major obstacles facing researchers in this task. In particular, the authentication of sequences obtained from ancient human remains is thought by many to be rather challenging. We propose a novel approach, based on the c statistic, that can be employed to help identify the sequence motif of an endogenous template, based on a sample of sequences that reflect the nucleotide composition of individual template molecules obtained from ancient tissues (such as cloned products from a PCR amplification). The c statistic exploits as information the most common form of postmortem damage observed among clone sequences in ancient DNA studies, namely, lesion-induced substitutions caused by cytosine deamination events. Analyses of simulated sets of templates with miscoding lesions and real sets of clone sequences from the literature indicate that the c-based approach is highly effective in identifying endogenous sequence motifs, even when they are not present among the sampled clones. The proposed approach is likely to be of general use to researchers working with DNA from ancient tissues, particularly from human remains, where authentication of results has been most challenging. [Reviewing Editor: Dr. Magnus Nordborg]     

Metabolic profiling and phylogenetic analysis of medicinal Zingiber species: Tools for authentication of ginger (Zingiber officinale Rosc)

Phylogenetic analysis and metabolic profiling were used to investigate the diversity of plant material within the ginger species and between ginger and closely related species in the genus Zingiber (Zingiberaceae). In addition, anti-inflammatory data were obtained for the investigated species. Phylogenetic analysis demonstrated that all Zingiber officinale samples from different geographical origins were genetically indistinguishable. In contrast, other Zingiber species were significantly divergent, allowing all species to be clearly distinguished using this analysis. In the metabolic profiling analysis, the Z. officinale samples derived from different origins showed no qualitative differences in major volatile compounds, although they did show some significant quantitative differences in non-volatile composition, particularly regarding the content of [6]-, [8]-, and [10]-gingerols, the most active anti-inflammatory components in this species. The differences in gingerol content were verified by HPLC. The metabolic profiles of other Zingiber species were very different, both qualitatively and quantitatively, when compared to Z. officinale and to each other. Comparative DNA sequence/chemotaxonomic phylogenetic trees showed that the chemical characters of the investigated species were able to generate essentially the same phylogenetic relationships as the DNA sequences. This supports the contention that chemical characters can be used effectively to identify relationships between plant species. Anti-inflammatory in vitro assays to evaluate the ability of all extracts from the Zingiber species examined to inhibit LPS-induced PGE(2) and TNF-alpha production suggested that bioactivity may not be easily predicted by either phylogenetic analysis or gross metabolic profiling. Therefore, identification and quantification of the actual bioactive compounds are required to guarantee the bioactivity of a particular Zingiber sample even after performing authentication by molecular and/or chemical markers.     

Mouse cell line authentication

The scientific community has responded to the misidentification of human cell lines with validated methods to authenticate these cells; however, few assays are available for nonhuman cell line identification. We have developed a multiplex polymerase chain reaction assay that targets nine tetranucleotide short tandem repeat (STR) markers in the mouse genome. Unique profiles were obtained from seventy-two mouse samples that were used to determine the allele distribution for each STR marker. Correlations between allele fragment length and repeat number were determined with DNA Sanger sequencing. Genotypes for L929 and NIH3T3 cell lines were shown to be stable with increasing passage numbers as there were no significant differences in fragment length with samples of low passage when compared to high passage samples. In order to detect cell line contaminants, primers for two human STR markers were incorporated into the multiplex assay to facilitate detection of human and African green monkey DNA. This multiplex assay is the first of its kind to provide a unique STR profile for each individual mouse sample and can be used to authenticate mouse cell lines.     

古代DNA研究中污染的控制和识别

现代分子生物学中PCR技术的发展使得直接分析古代动植物和人类材料中的DNA成为可能,这为考古学、人类学和古生物学提供了一种新的研究手段。但由于PCR技术的高度敏感性和古代DNA含量的极其微量性,古代DNA研究也极易受现代DNA污染。如何甄别所获得的DNA是真实的古代DNA而不是污染的现代DNA是所有古代DNA研究工作者都要面临的挑战,污染的控制和识别也因此成为古代DNA研究中一个至关重要的问题。本文将着重讨论在古代DNA研究的各个步骤中应如何进行有效的污染控制和识别。     

DNA barcoding,microarrays and next generation sequencing: recent tools for genetic diversity estimation and authentication of medicinal plants

DNA barcoding, microarray technology and next generation sequencing have emerged as promising tools for the elucidation of plant genetic diversity and its conservation. They are proving to be immensely helpful in authenticating the useful medicinal plants for herbal drug preparations. These newer versions of molecular markers utilize short genetic markers in the genome to characterize the organism to a particular species. This has the potential not only to classify the known and yet unknown species but also has a promising future to link the medicinally important plants according to their properties. The newer trends being followed in DNA chips and barcoding pave the way for a future with many different possibilities. Several of these possibilities might be: characterization of unknown species in a considerably less time than usual, identification of newer medicinal properties possessed by the species and also updating the data of the already existing but unnoticed properties. This can assist us to cure many different diseases and will also generate novel opportunities in medicinal drug delivery and targeting.     

标本DNA研究进展

标本DNA是十分重要的遗传资源。在生物的起源及进化研究中,应用越来越广泛。详细介绍了标本DNA的特性、提取方法、扩增、测序、甄别、时限及已经取得的一系列成果,并对其中存在的问题进行了分析和评述。     

Specific,sensitive and rapid Curcuma longa turmeric powder authentication in commercial food using loop-mediated isothermal nucleic acid amplification

Turmeric (Curcuma longa) is a rhizomatous plant of the ginger family Zingiberaceae that is usually dried and ground into powder for use as a seasoning. Because turmeric has become increasingly popular in the functional food market, adulteration of C. longa by other turmeric species is becoming an increasingly significant problem. In this study, loop-mediated isothermal amplification (LAMP) was developed for the detection of C. longa DNA for turmeric authentication. ITS2-26S rDNA was used for the LAMP primer designation. The results demonstrated that the specific primers exhibited high specificity, authenticated C. longa DNA within 30 min at 65 °C isothermally and had no cross-reaction with other adulterants. LAMP was sensitive to 0.1 ng of turmeric C. longa DNA, and only 0.01% of C. longa turmeric powder in the sample was required for DNA amplification. The sensitivity of LAMP was 10-fold higher than that of PCR (0.1%) from a previous report. Moreover, all the collected commercial turmeric products were positively detected by LAMP and RtF-LAMP (real-time fluorescence LAMP). The developed LAMP assay not only had higher specificity and rapidity than that of other methods but could also be applied to authenticate turmeric to prevent adulteration in food products.     

High performance thin layer chromatography as a method to authenticate Hoodia gordonii raw material and products

Hoodia gordonii which contains the perceived active molecule, P57, is a plant used in many weight loss products that are highly susceptible to adulteration due to increased public demand and limited availability. Rapid and simple methods for authentication and confirmation of the presence of P57 are desirable for the quality control of H. gordonii raw material and products. High performance thin layer chromatography (HPTLC) analysis of several H. gordonii raw material samples collected from different locations as well as weight loss products was carried out on silica gel plates and developed in a mobile phase of toluene:chloroform:ethanol (40:40:12.5 v/v/v). Liebermann–Burchard (LB) reagent was used as derivatising agent since it is specific for glycosides and triterpenes (such as P57) and the plates were viewed under UV light at 365 nm. This method produced good separation of the compounds in complex mixtures with well-defined bands including that of the P57 band (R_f 0.42), which was confirmed by liquid chromatography coupled to mass spectrometry (LC–MS) after preparative thin layer chromatography (TLC). All the HPTLC results obtained for the H. gordonii raw materials and products were confirmed with quantitative LC–MS analyses, which confirmed the qualitative reliability of the HPTLC method. The HPTLC method was used successfully to develop a chemical fingerprint for authentication and reliable confirmation of the presence of P57 in H. gordonii raw material and products.     

Rapid identification and authentication of closely related animal cell culture by polymerase chain reaction

Animal cell lines are important resources for research and diagnostic applications. Cross-contamination and misidentification of cell lines, however, can cause major problems for research (for example, false results that come from contamination cells may mislead the science). Hence, it is imperative to routinely monitor cell lines for identity and authenticity. Here, we extend our previous work on identification and authentication of animal cell culture by polymerase chain reaction (PCR) amplification and DNA sequencing. A PCR-based method for rapid identification and authentication of closely related cell lines was described. In this method, two new primers were designed based on high homology in the aldolase gene family. Used together with our previous primers, the combinations of primers were able to differentiate closely related species, including human from monkey and mouse from rat. This PCR assay provides a rapid, simple, sensitive, and cost-effective method for authentication of closely related cell lines. The findings and conclusions in this report are those of the authors and do not necessarily represent the views of the funding agency.     

花椒cpDNA trnL-F间隔区序列的特征及其在混淆品鉴别中的应用

目的:通过分析花椒cpDNA trnL-F间隔区序列特点,探讨该序列在花椒与其混淆品鉴别中的意义.方法:对花椒及其混淆品进行cpDNA trnL-F间隔区序列比较研究.结果:花椒cpDNA trnL-F间隔区序列为349bp、AT百分比为62.1%.尽管花椒的果实在外部形态,物理特性上与混淆品差异较小,但在cpDNA trnL-F间隔区序列上却存在着显著而稳定的差异.该序列在属以下的分类阶元中同源性极高,可达100%.结论:根据cpDNA trnL -F间隔区碱基序列的差异,能有效地鉴别花椒及其属以上分类阶元的混淆品.