Species identification and confirmation of human and animal cell lines: a PCR-based method

Misidentification and cross-contamination of cell lines are major problems of cell cultures that can make scientific results and their reproducibility unreliable. This paper describes a PCR-based method for easily identifying or confirming the species of origin of cell lines by using a panel of oligonucleotides specific for the nine animal species most common in cell culture laboratories. A panel of 35 human and animal cell lines, whose species of origin were previously confirmed by isoenzyme assay, was studied with nine species-specific primer pairs that specifically anneal to DNA sequences codifying for human, cat, dog, mouse, rat, horse, rabbit, African Green monkey cytochrome c oxidase subunit I (cox I), and one primer pair specific for the cytochrome b gene of Chinese hamster. The amplified fragments were analyzed by electrophoresis in ethidium bromide-stained 2% agarose gels. The method is simple, rapid, highly sensitive, and useful for routinely monitoring the species identity of cell cultures.     

Identification of cross-contaminated animal cells by PCR and isoenzyme analysis

Animal cell lines have become very popular substrates for the production of vaccines and biopharmaceuticals. Characterization of candidate production cell lines is central to ensure product safety and maintenance of consistency in the manufacture of biologicals. Nested PCR and isoenzyme analysis have been used widely to prove the identity and purity of various cell lines and primary cells individually and also after deliberate cross-contamination. The nested PCR based on the Cytochrome b (Cyt b) gene of mitochondrial DNA (Mt DNA) was found to be more sensitive than isoenzyme analysis in detecting low levels of contaminants (as low as 1%). Interestingly, competition between different co-cultured cell lines has shown in one case that cross-contamination need not always results in a mixed cell population. The nested PCR technique for the Cyt b gene described in this study appears to be a potential replacement for isoenzyme analysis and here we demonstrate the PCR method used is sensitive and reliable for cell line authentication in a simple, rapid and reliable format to help assure the authenticity of cell substrates for the production of safe vaccines and biopharmaceuticals.     

A simple method using β-globin polymerase chain reaction for the species identification of animal cell lines—A progress report

Continuous cell lines are widely used in cell biology and serve as model systems in basic and applied research. Fundamental requirements for the use of cell lines are a well-identified origin and the exclusion of cross-contamination by prokaryotic or eukaryotic cells. Because the cross-contamination of one cell line with another cell line may occur in a concealed manner, special emphasis must be taken to (1) prevent such an "accident" and (2) monitor regularly the identity of the cell line(s) in use. Apart from human cell lines, mouse-, rat-, and hamster-derived cell lines are used in basic cell culture and biotechnology. We established a polymerase chain reaction (PCR) assay to detect and confirm the species origin for these species and to detect interspecies cross-contamination. Our PCR method is based on oligonucleotide primers annealing to specific sequences in the beta-globin gene, which were designed to amplify one deoxyribonucleic acid (DNA) segment only per analyzed sample. We confirmed the species identity of 82 cell lines as human, mouse, rat, and Syrian hamster by beta-globin PCR. The DNAs from eight additional cell lines of less frequently used species were not amplified with the primers chosen. Cross-contamination of 5-10% of either mouse or rat DNA was detectable. One species-specific primer pair was sufficient for confirmation of the expected species, and for identification of an unknown cell line the combination of two or more primer pairs is suggested. Our PCR assay represents a powerful, fast, easy, robust, and inexpensive method for speciation and does not need any elaborate sequencing or computer-based analysis system.     

Identification and authentication of animal cell culture by polymerase chain reaction amplification and DNA sequencing

Polymerase chain reaction (PCR) amplification and deoxyribonucleic acid (DNA) sequence analysis were used to identify the species origin of cell lines used in a cell culture facility where various cell lines of different species are routinely propagated. The aldolase gene family was selected for PCR amplification because the DNA sequences of this gene are highly conserved over a wide range of animals and humans. A total of 36 cell lines representing 13 different species were selected for this study. The DNA from each cell line was amplified, and PCR products were analyzed by agarose gel electrophoresis. The results showed unique profiles of amplified bands on agarose gels that allowed differentiation among non-closely related species. However, DNA amplification of closely related species, including rat and mouse or human and primate, resulted in similar and indistinguishable banding patterns that could be further differentiated by DNA sequence analysis. These results suggested that aldolase gene amplification coupled with DNA sequence analysis is a useful tool for identification of cell lines and has potential application for use in identification of interspecies cross-contamination.     

A molecular marker for the identification of the zoonotic reservoirs of Lyme borreliosis by analysis of the blood meal in its European vector Ixodes ricinus.

The efficacy of the mitochondrially encoded cytochrome b gene as a molecular marker for the discrimination of the reservoir host species of the Lyme borreliosis spirochete, Borrelia burgdorferi sensu lato (s.l.), in its European vector Ixodes ricinus (Acari: Ixodidae) was determined. Degenerate PCR primers were designed which amplified orthologous regions of the cytochrome b gene in several animal species which act as B. burgdorferi s.l. reservoirs and hosts for I. ricinus. PCR products were amplified and characterized by hybridization and restriction fragment length polymorphism analysis. Restriction fragment length polymorphism analysis of a 638-bp PCR product with HaeIII and DdeI revealed unique restriction fragment profiles, which allowed the taxonomic identification of animals to the genus level. A system was devised for the detection of the larval host blood meal from the remnants in unfed nymphal I. ricinus ticks by nested PCR amplification. An inverse correlation was demonstrated between amplicon size and successful PCR amplification of host DNA from the nymphal stage of the tick. The stability of the cytochrome b product as a marker for the identification of the larval host species in the nymphal instar was demonstrated up to 200 days after larval ingestion (approximately 165 days after molting) by reverse line blotting with a host-specific probe. This assay has the potential for the determination of the reservoir hosts of B. burgdorferi s.l. by using extracts from the same individual ticks for both the identification of the host species and the detection of the Lyme borreliosis spirochete.     

Analysis of three marine fish cell lines by rapd assay

We tested the applicability of the random amplified polymorphic deoxyribonucleic acid (RAPD) analysis for identification of three marine fish cell lines FG, SPH, and RSBF, and as a possible tool to detect cross-contamination. Sixty commercial 10-mer RAPD primers were tested on the cell lines and on samples collected from individual fish. The results obtained showed that the cell lines could be identified to the correspondent species on the basis of identical patterns produced by 35-48% of the primers tested; the total mean similarity indices for cell lines versus correspondent species of individual fish ranged from 0.825 to 0.851, indicating the existence of genetic variation in these cell lines in relation to the species of their origin. Also, four primers, which gave a monomorphic band pattern within species/line, but different among the species/line, were obtained. These primers can be useful for identification of these cell lines and for characterization of the genetic variation of these cell lines in relation to the species of their origin. This supported the use of RAPD analysis as an effective tool in species identification and cross-contamination test among different cell lines.     

Identity tests: determination of cell line cross-contamination

Cell line cross-contamination is a phenomenon that arises as a result of the continuous cell line culture. It has been estimated that around 20% of the cell lines are misidentified, therefore it is necessary to carry out quality control tests for the detection of this issue. Since cell line cross-contamination discovery, different methods have been applied, such as isoenzyme analysis for inter-species cross-contamination; HLA typing, and DNA fingerprinting using short tandem repeat and a variable number of tandem repeat for intra-species cross-contamination. The cell banks in this sense represent the organizations responsible for guaranteeing the authenticity of cell lines for future research and clinical uses.     

DNA fingerprinting of human cell lines using PCR amplification of fragment length polymorphisms

Summary Methods for monitoring cell line identification and authentication include species-specific immunofluorescence, isoenzyme phenotyping, chromosome analysis, and DNA fingerprinting. Most previous studies of DNA fingerprinting of cell lines have used restriction fragment length polymorphism analysis. In this study, we examined the utility of an alternative and simpler method of cell line DNA fingerprinting—polymerase chain reaction (PCR) amplification of fragment length polymorphisms. Fourteen human cell lines previously found by other methods to be either related or disparate were subjected to DNA fingerprinting by PCR amplification of selected fragment length polymorphism loci. Cell identification patterns by this method were concordant with those obtained by isoenzyme phenotyping and restriction fragment length polymorphism-DNA fingerprinting, and were reproducible within and between assays on different DNA extracts of the same cell line. High precision was achieved with electrophoretic separation of amplified DNA products on high resolution agarose or polyacrylamide gels, and with fragment length polymorphism (FLP) loci-specific “allelic ladders” to identify individual FLP alleles. Determination of the composite fingerprint of a cell line at six appropriately chosen fragment length polymorphism loci should achieve a minimum discrimination power of 0.999. The ability of PCR-based fragment length polymorphism DNA fingerprinting to precisely and accurately identify the alleles of different human cell lines at multiple polymorphic fragment length polymorphism loci demonstrates the feasibility of developing a cell line DNA fingerprint reference database as a powerful additional tool for future cell line identification and authentication.     

A proteomics approach to identifying fish cell lines

Fish cell lines are relatively easy to culture and most have simple growth requirements that make cross contamination a potential problem. Cell line contamination is not an uncommon incident in laboratories handling more than one cell line and many reports have been made on cross contamination of mammalian cell lines. Although problems of misidentification and cross-contamination of fish cell lines have rarely been reported, these are issues of concern for cell culturists that can make scientific results and their reproducibility unreliable. Proper identification of cell lines is thus crucial and protocols for routine and rapid screening are preferred. Cytogenetic evaluation, DNA fingerprinting, microsatellite analysis and PCR methods have been published for inter-species identification of many cell lines, but discerning intra-species contamination has been challenging. More complex DNA fingerprinting and hybridization techniques coupled with isoenzyme analysis have been developed to discriminate intra-species contamination, however, these require complex and time consuming procedures to enable cell identification thus are difficult to apply for routine use. A simple proteomic approach has been made to identify several fish cell lines derived from tissues of the same or differing species. Protein expression signatures (PES) of the evaluated fish cell lines have been developed using 2-DE and image analysis. A higher degree of concordance was seen among cell lines derived from rainbow trout, than from other fish species. Similar concordance was seen in cells derived from the same tissues than from other tissues within the same species. These profiles have been saved in an electronic databank and could be made available to be used for discerning the origins of the various cell lines evaluated. This proteomic approach could thus serve as an additional, valuable and reliable technique for the identification of fish cell lines.     

The necessity of identity assessment of animal intestinal cell lines: A case report

Eight intestinal cell lines, established from different animal species were submitted to DSMZ (German Collection of Microorganisms and Cell Cultures) in order to analyze their species of origin and their microbial contamination. Species identity was determined by PCR targeting mitochondrial genes and hence confirmed by sequencing the amplified PCR products. For three cell lines (CIEB, CLAB, PSI-1) we confirmed the species identity, whereas the species of origin of the three other cell lines (B6, B10XI and IPEC) was not the expected one: B6 and B10XI cells, which were supposed to be of chicken origin were identified as porcine cells. IPEC, allegedly a sub clone of the well-known porcine intestinal cell line IPEC-J2, was of bovine instead of porcine origin. However, two further IPEC-clones, namely IPEC-1 and IPEC-J2, provided by another source were shown to be derived from the correct species (i.e. pig). Furthermore, six out of these eight cell lines turned out to be highly contaminated with mycoplasma. Alerted by this high incidence of infected and false specified cell lines, we feel obliged to inform all those working with animal intestinal cell lines and we strongly recommend verifying the species identity before using them. Also, the presence of mycoplasma should be tested when taking the cells in culture for the first time, and this mycoplasma control should be repeated at regular time intervals (e.g. every 4 weeks).     

Species identification in cell culture: a two-pronged molecular approach

Species identification of cell lines and detection of cross-contamination are crucial for scientific research accuracy and reproducibility. Whereas short tandem repeat profiling offers a solution for a limited number of species, primarily human and mouse, the standard method for species identification of cell lines is enzyme polymorphism. Isoezymology, however, has its own drawbacks; it is cumbersome and the data interpretation is often difficult. Furthermore, the detection sensitivity for cross-contamination is low; it requires large amounts of the contaminant present and cross-contamination within closely related species may go undetected. In this paper, we describe a two-pronged molecular approach that addresses these issues by targeting the mitochondrial genome. First, we developed a multiplex PCR-based assay to rapidly identify the most common cell culture species and quickly detect cross-contaminations among these species. Second, for speciation and identification of a wider variety of cell lines, we amplified and sequenced a 648-bp region, often described as the “barcode region” by using a universal primer mix targeted at conserved sequences of the cytochrome C oxidase I gene (COI). This method was challenged with a panel of 67 cell lines from 45 diverse species. Implementation of these assays will accurately determine the species of cell lines and will reduce the problems of misidentification and cross-contamination that plague research efforts.     

麂属动物陈旧皮张标本的DNA提取及PCR扩增

本实验用改进的方法从保存于标本馆的动物皮张标本中提取ＤＮＡ,所得ＤＮＡ片段的分子量从１００ｂｐ到１ｋｂ以上。利用线粒体ＤＮＡ细胞色素ｂ通用引物和ＰＣＲ技术,从小麂、印度麂、贡山麂、费氏麂、黑麂ＤＮＡ中扩增出３０７ｂｐ的细胞色素ｂ特异片段。用２８种限制性内切酶对从新鲜血样和从陈旧皮张标本中所得扩增片段进行酶切分析,发现只有４个酶在这个片段上有切点,其中ＨａｅⅢ和ＨａｐⅡ的识别位点在各种麂中有所不同。     

Completion of hepatitis C virus replication cycle in heterokaryons excludes dominant restrictions in human non-liver and mouse liver cell lines

Hepatitis C virus (HCV) is hepatotropic and only infects humans and chimpanzees. Consequently, an immunocompetent small animal model is lacking. The restricted tropism of HCV likely reflects specific host factor requirements. We investigated if dominant restriction factors expressed in non-liver or non-human cell lines inhibit HCV propagation thus rendering these cells non-permissive. To this end we explored if HCV completes its replication cycle in heterokaryons between human liver cell lines and non-permissive cell lines from human non-liver or mouse liver origin. Despite functional viral pattern recognition pathways and responsiveness to interferon, virus production was observed in all fused cells and was only ablated when cells were treated with exogenous interferon. These results exclude that constitutive or virus-induced expression of dominant restriction factors prevents propagation of HCV in these cell types, which has important implications for HCV tissue and species tropism. In turn, these data strongly advocate transgenic approaches of crucial human HCV cofactors to establish an immunocompetent small animal model.     

Alginate cell encapsulation: new advances in reproduction and cartilage regenerative medicine

Cell lines represent valuable tools for basic research and diagnostic applications as well as for the production of biological products such as antibodies or vaccines. For all cell culturists, a well-identified origin of their cell lines as well as the periodic re-examination of their identity should be a basic requirement. We established a simple polymerase chain reaction (PCR) to verify or identify rodent and human cell lines. Since mouse-, rat-, Chinese hamster- and Syrian hamster-derived cell lines represent the most frequently used rodent cell lines, our investigations were focused on these species. Our assay used oligonucleotide primers annealing to sequences within the β-actin and the β-globin gene and to repetitive DNA. Primers were designed mostly from intron sequences of the genes aiming to amplify only one specific DNA segment and thus enabling to exclude easily false DNA. More than 130 cells lines originating from the five species were analyzed in that study. Our PCR revealed specific profiles for all species investigated. No further methods like DNA sequencing or fragment length polymorphism analysis were needed to differentiate these species. The results introduce our PCR-assay as a rapid, specific and routinely feasible tool in order to identify or distinguish rodent cell lines from each other and from human cell lines.     

Transmission of organelles in triploid hybrids produced by gametosomatic fusions of two Nicotiana species

Summary Gametosomatic hybrids produced by the fusion of microspore protoplasts of Nicotiana tabacum Km⁺Sr⁺ with somatic cell protoplasts of N. rustica were analysed for their organelle composition. For the analysis of mitochondrial (mt)DNA, species-specific patterns were generated by Southern hybridization of restriction endonuclease digests of total DNA and mtDNA with four DNA probes of mitochondrial origin: cytochrome oxidase subunit I, cytochrome oxidase subunit II, 26s rDNA and 5s-18s rDNA. Of the 22 hybrids analyzed, some had parental-type pattern for some probes and novel-type for the others, indicating interaction between mtDNA of the two parent species. For chloroplast (cp)DNA analysis, species-specific patterns were generated by Southern hybridization of restriction endonuclease digests of total DNA with large subunits of ribulose bisphosphate carboxylase and cpDNA as probes. All the hybrids had N. rustica-specific patterns. Hybrids were not resistant to streptomycin, a trait encoded by the chloroplast genome of N. tabacum. In gametosomatic fusions of the two Nicotiana species, mitochondria but not the chloroplasts are transmitted from the parent contributing microspore protoplasts.     

Molecular markers to discriminate among four pest species of Helicoverpa (Lepidoptera: Noctuidae)

The four significant pest species in the Helicoverpa genus (H. armigera, H. assulta, H. punctigera and H. zea) are morphologically similar and can only be reliably distinguished through dissection of adult genitalia. Two partial regions of the mitochondrial DNA (mtDNA), the cytochrome oxidase subunit I (COI) and the cytochrome b (Cyt b) genes were amplified by PCR and digested with restriction endonucleases. The restriction patterns, generated by the endonucleases BstZ17I and HphI, demonstrated reliable differentiation of the four Helicoverpa pest species. This technique is fast, reliable and effective at distinguishing specimens irrespective of their life stages and offers support to conventional taxonomic differentiation based on morphological characters.     

Identification of newly established <Emphasis Type="Italic">Spodoptera littoralis</Emphasis> cell lines by two DNA barcoding markers

Cell line authentication is crucial in determining the identity of cell lines and detecting any cross-contamination. The identity of three newly established Spodoptera littoralis cell lines (Spli-C, Spli-B, and Spli-S) was confirmed by DNA fingerprinting. In this study, we used two universal primers sets to amplify two DNA fragments in different positions in the mitochondrial cytochrome C oxidase 1 gene (COI). The PCR reaction succeeded in amplifying two target DNA amplicons. The first amplicon had ~650 bp, while the second had ~410 bp. By comparing the obtained informative sequences with those in the GenBank sequence database, the results showed 100% similarity between the S. littoralis cell lines and their host. The same similarity ratio was observed between the Sf21, Tni, and Cp cell lines, which are used widely, and their hosts. The informative sequences were then used for phylogenetic analyses. In addition to the high efficiency of this technique, it showed high reproducibility in two different laboratories. DNA barcoding using the two sets of the universal primers used in this study can be a fast and a reliable method for insect cell line identification.     

Molecular evidence for a fourth species within the Isotoma viridis group (Insecta, Collembola)

For identification of single species within the Isotoma viridis group, we present polymerase chain reaction–restriction fragment length polymorphism (PCR–RFLP) as a fast and efficient DNA-based molecular method. We used five PCR primers amplifying the cytochrome oxidase II (COII) region (760 bp) of the mitochondrial DNA. The sequences clearly separated four species ( I. viridis , I. riparia , I. anglicana and I. caerulea ) out of samples from Norway, Sweden, Germany and Switzerland. Examination of genetic variation and phylogenetic relationship did not support the separation of two colour pattern forms of I. viridis into distinct species. For RFLP, several restriction enzymes were tested for their ability to produce not only species-specific restriction fragment patterns but to discriminate more than one species per enzyme used with as few cleavage sites as possible. Such a design should render a clear fragment pattern when performing a double digest. These demands appear to be fulfilled best by the combination of the restriction enzymes Mfe I, Nci I and one of Aci I, Bst EII, Nde I, or Sfc I. From the enzymes tested in a previous study, Ase I proved to be reliable, whereas Mbo I can no longer be recommended.     

Isoenzyme analysis as a rapid method for the examination of the species identity of cell cultures

Summary One of the major problems in cell culturing is the misidentification or cross-contamination of authentic continuous cell lines. We applied a rapid and efficient isoelectric focusing (IEF) technique for the routine analysis to detect interspecies contamination of cell cultures and for the identification of unknown animal cell lines. The method is based on the isoelectric separation of a specific set of intracellular enzymes which can be used to distinguish between cell lines of human, murine, or other mammalian origin. By means of preformed agarose gels, standardized conditions and equipment, this technique is especially applicable for routine work and allows the analysis of a large number of unknown samples with reproducible results. One hundred seventy-seven cell lines which have been sent to the Department of Human and Animal Cell Cultures at the DSM (Deutsche Sammlung von Mikroorganismen and Zellkulturen) were analyzed for species authentication; only three cell lines were found not to be of the presumed species. Our study strongly emphasizes standardized IEF as an efficient and rapid method for routinely monitoring the authenticity of cell lines.     

多重实时荧光PCR检测牛、山羊和绵羊源性成分

根据牛、山羊和绵羊线粒体细胞色素b基因序列, 设计特异性引物和以不同荧光素标记的Taqman探针。通过对PCR反应体系和反应条件的优化筛选, 建立能同时鉴别牛、山羊和绵羊源性成分的多重实时荧光PCR方法。采用本文方法与国标GB/T 20190-2006方法分别对17种不同源性动物DNA和200份不同来源样品DNA进行牛羊源性成分检测, 数据显示两者检测结果符合率达100%, 特异性相当。与国标方法相比, 本试验方法不需电泳、酶切和测序, 即可在一个PCR反应中同时鉴别检测牛、山羊和绵羊3种源性成分, 检测效率提高近3倍; 灵敏度更高, 比国标方法灵敏10倍; 适用性更广, 除了饲料, 还适用于肉品、奶品、生皮和动物油脂等动物产品的牛羊源性成分检测。