PCR-based methods for detecting DNA damage and its repair at the sub-gene and single nucleotide levels in cells

Three PCR-based methods are described that allow covalent drug-DNA adducts, and their repair, to be studied at various levels of resolution from gene regions to the individual nucleotide level in single copy genes. A quantitative PCR (QPCR) method measures the total damage on both DNA strands in a gene region, usually between 300 and 3000 base pairs in length. Strand-specific QPCR incorporates adaptations that allow damage to be measured in the same region as QPCR but in a strand-specific manner. Single-strand ligation PCR allows the detection of adduct formation at the level of single nucleotides, on individual strands, in a single copy gene in mammalian cells. If antibodies to the DNA adducts of interest are available, these can be used to capture and isolate adducted DNA for use in single-strand ligation PCR increasing the sensitivity of the assay.     

Quantitative detection of residual E. coli host cell DNA by real-time PCR

E. coli has been widely used as a host system to manufacture recombinant proteins for human therapeutic use. Among impurities to be eliminated during the downstream process, residual host cell DNA is a major interest for safety. Residual E. coli host cell DNA in the final products are usually determined using conventional slot blot hybridization assay or total DNA Threshold assay, although these methods are time consuming, expensive, and relatively insensitive. Therefore a sensitive real-time PCR assay for specific detection of residual E. coli DNA was developed and compared with slot blot hybridization assay and Threshold assay to validate the overall capability of these methods. Specific primer pair for amplification of the E. coli 16S rRNA gene was selected to improve the sensitivity, and E. coli host cell DNA was quantified by use of SYBR Green 1. The detection limit of real-time PCR assay in the optimized condition was calculated to be 0.042 pg genomic DNA, which is much higher than those of slot blot hybridization assay and Threshold assay of which detection limit were 2.42 and 3.73 pg genomic DNA, respectively. The real-time PCR assay was validated to be more reproducible, accurate, and precise than slot blot hybridization assay and Threshold assay. The real-time PCR assay may be a useful tool for quantitative detection and clearance validation of residual E. coli DNA during the manufacturing process for recombinant therapeutics.     

Measuring gene-specific nucleotide excision repair in human cells using quantitative amplification of long targets from nanogram quantities of DNA

We have been developing a rapid and convenient assay for the measurement of DNA damage and repair in specific genes using quantitative polymerase chain reaction (QPCR) methodology. Since the sensitivity of this assay is limited to the size of the DNA amplification fragment, conditions have been found for the quantitative generation of PCR fragments from human genomic DNA in the range of 6-24 kb in length. These fragments include: (1) a 16.2 kb product from the mitochondrial genome; (2) 6.2, 10.4 kb, and 15.4 kb products from the hprt gene, and (3) 13.5, 17.7, 24.2 kb products from the human beta-globin gene cluster. Exposure of SV40 transformed human fibroblasts to increasing fluences of ultraviolet light (UV) resulted in the linear production of photoproducts with 10 J/m(2) of UVC producing 0.085 and 0.079 lesions/kb in the hprt gene and the beta-globin gene cluster, respectively. Kinetic analysis of repair following 10 J/m(2) of UVC exposure indicated that the time necessary for the removal of 50% of the photoproducts, in the hprt gene and beta-globin gene cluster was 7.8 and 24.2 h, respectively. Studies using lymphoblastoid cell lines show very little repair in XPA cells in both the hprt gene and beta-globin locus. Preferential repair in the hprt gene was detected in XPC cells. Cisplatin lesions were also detected using this method and showed slower rates of repair than UV-induced photoproducts. These data indicate that the use of long targets in the gene-specific QPCR assay allows the measurement of biologically relevant lesion frequencies in 5-30 ng of genomic DNA. This assay will be useful for the measurement of human exposure to genotoxic agents and the determination of human repair capacity.     

Removing residual DNA from Vero-cell culture-derived human rabies vaccine by using nuclease

The clearance of host cell DNA is a critical indicator for Vero-cell culture-derived rabies vaccine. In this study, we evaluated the clearance of DNA in Vero-cell culture-derived rabies vaccine by purification process utilizing ultrafiltration, nuclease digestion, and gel filtration chromatography. The results showed that the bioprocess of using nuclease decreased residual DNA. Dot-blot hybridization analysis showed that the residual host cell DNA was <100 pg/ml in the final product. The residual nuclease in rabies vaccine was less than 0.1 ng/ml protein. The residual nuclease could not paly the biologically active role of digestion of DNA. Experiments of stability showed that the freeze-drying rabies virus vaccine was stable and titers were >5.0 IU/ml. Immunogenicity test and protection experiments indicated mice were greatly induced generation of neutralizing antibodies and invoked protective effects immunized with intraperitoneal injections of the rabies vaccine. These results demonstrated that the residual DNA was removed from virus particles and nuclease was removed by gel filtration chromatography. The date indicated that technology was an efficient method to produce rabies vaccine for human use by using nuclease.     

Development of a novel adenovirus purification process utilizing selective precipitation of cellular DNA

The use of recombinant adenoviral vectors for vaccination and gene therapy requires the development of purification processes that are cost-effective, scalable, and capable of robust host cell DNA clearance. An adenovirus purification process was developed which incorporates selective precipitation of host cell DNA, enabling a reduction in the use of costly nucleases and chromatographic resins while substantially improving DNA and protein clearance capabilities. In this work, three cationic detergents were evaluated for their capacity to selectively precipitate DNA from adenovirus-containing cell lysate. Parameters including pH, sodium chloride concentration, nonionic surfactant concentration, and cell density were investigated during development of the precipitation step. In a novel application, the cationic detergent domiphen bromide was found to have superior selectivity for host cell DNA. In addition, domiphen bromide-induced precipitation of adenovirus was shown to be reversible, which reduces the importance of mixing. Precipitation of DNA in the cell lysate coupled with primary clarification resulted in 3 logs of DNA clearance and improved impurity clearance in the subsequent ultrafiltration step. As a result, nuclease treatment and/or anion exchange chromatography can be eliminated, or included exclusively to improve process robustness.     

Damage formation and repair efficiency in the p53 gene of cell lines and blood lymphocytes assayed by multiplex long quantitative polymerase chain reaction

We examined ultraviolet (UV) irradiation and cisplatin treatment damage formation and repair efficiency in the p53 tumor suppressor gene of various cultured cell lines and lymphocytes using a nonradioactive multiplex long quantitative polymerase chain reaction (QPCR) assay, which amplified a 7-kb fragment of the target gene and a 500-bp fragment of the template control to successfully increase the sensitivity and reliability of the assay. The multiplex long QPCR detected a lesion frequency of 0.63 lesions/10kb/10J/m(2) in the p53 gene of fibroblast cells. In addition, the multiplex long QPCR assay detected pronounced differences in the repair of UV damage in the p53 gene among repair-proficient CRL-1475 cells and repair-deficient XP-A and XP-C cells. The multiplex long QPCR assay was also evaluated as a sensitive assay for the detection of DNA damage induced by cisplatin. The data indicated that the lesion frequency in the p53 gene was 1.27-1.75 times higher in the H23 cisplatin-sensitive cell than in the H1435 cisplatin-resistant cell at the IC(70) dose. After 8-h and 24-h repair periods, only 13 and 75% of cisplatin-induced damage had been removed in the H23 cells, whereas these values were 92 and 100% in the H1435 cells. In addition, our data indicate that multiplex long QPCR is a sensitive method for validly estimating repair in freshly isolated lymphocytes. The results suggest that the current protocol of the multiplex long QPCR method can be used to assess the damage formation and repair efficiency of various agents at biologically relevant doses and to allow a more precise determination of gene-specific repair in disease susceptibility and drug resistance in epidemiological studies.     

Chromatographic clarification overcomes chromatin-mediated hitch-hiking interactions on Protein A capture column

Protein A capture chromatography is a critical unit operation in the clearance of host cell protein (HCP) impurities in monoclonal antibody (mAb) purification processes. Though one of the most effective purification steps, variable levels of protein impurities are often observed in the eluate. Coelution of HCP impurities is suggested to be strongly affected by the presence of chromatin complexes (Gagnon et al., 2014; Koehler et al., 2019). We investigated the effect of removal of DNA complex and HCP reduction pre-Protein A on the HCP clearance performance of the Protein A capture step itself. We found that only reduction of DNA in the Protein A load consistently lowered HCP in the Protein A eluate. Reduction of HCP in the Protein A load stream did not produce a significant increase in the chromatography HCP clearance performance. These results are consistent across three different biosimilar therapeutic mAbs expressed by the same Chinese hamster ovary (CHO) cell line (i.e., CHO^BC® of Polpharma Biologics). This result demonstrates that optimization of the mAb purification process utilizing Protein A as the primary capture step depends primarily on being able to effectively clear DNA and associated complexes early in the process, rather than trying to incorporate HCP reduction at the harvest cell culture fluid.     

Chromatographic detection of residual cellular DNA on short monolithic columns

Analysis of crude samples from biotechnological processes is often required to demonstrate that residual host cell impurities are reduced or eliminated during purification. Current knowledge suggests that a continuous-cell-line DNA can be considered a cellular contaminant rather than a significant risk factor requiring removal to extremely low levels. Anion-exchange chromatography is one of the most important methods used in the downstream processing and analysis of different biomolecules. In this article, an application using Convective Interaction Media monolithic columns to improve the detection of residual cellular DNA is described.     

Design and validation of a new method to detect and quantify residual host cell DNA in human recombinant erythropoietin (rEPO)

During the purification of human recombinant erythropoietin (rEPO) from host cells, residual DNA may remain in final products. This contamination is a risk factor for patients and may result in the inactivation of some tumor suppressor genes or activation of oncogenes if its concentration is more than the standard defined by WHO. Based on WHO’s criteria, acceptable level of residual DNA in biopharmaceuticals is less than 10–100?pg/dose. In this study, we have designed a sensitive and specific quantitative real-time polymerase chain reaction (PCR) assay for the detection of residual DNA in human rEPO products. All reported sequences of CHO’s GAPDH gene were retrieved from GenBank, and a multiple alignment was performed using Mega 6 software to find conserved regions of the gene. Primers and probe were designed by AlleleID7 software for the highly conserved region. Quantitative real-time PCR showed an R² value more than 0.99 and the efficiency equal to 101% indicating a highly accurate and efficiency of the reaction, respectively. Based on the standard curve, the limit of detection of the assay was determined to be 10?copies/µL (0.00967?fg/µL). In addition, the inter- and intra-assay of the test were determined to be 1.14% and 0.65%, respectively, which are in acceptable range according to the WHO’s guidelines.     

荧光定量PCR精确检测人胚胎干细胞线粒体DNA拷贝数方法的建立

建立一种精确定量人胚胎干细胞线粒体DNA拷贝数的方法。构建包含线粒体DNANDl和核单拷贝基β-globin基因序列的重组质粒作为标准品;收集无饲养层培养体系下人胚胎干细胞DNA样本,结合2个单独的Taqman探针实时荧光定量PCR对待测样本中线粒体NDl和核β-globin基因分别进行定量,从而对人胚胎干细胞线粒体DNA的含量进行了精确定量。结果提示,人胚胎干细胞线粒体DNA的平均拷贝数／细胞为1321±228。研究表明,该技术可对人胚胎干细胞线粒体DNA拷贝数进行准确的测定,为研究培养条件对人胚胎干细胞线粒体DNA拷贝数的影响及优化体外培养条件奠定了基础。     

Mapping of picoeucaryotes in marine ecosystems with quantitative PCR of the 18S rRNA gene

A quantitative PCR (QPCR) assay based on the use of SYBR Green I was developed to assess the abundance of specific groups of picoeukaryotes in marine waters. Six primer sets were designed targeting four different taxonomic levels: domain (Eukaryota), division (Chlorophyta), order (Mamiellales) and genus (Bathycoccus, Micromonas, and Ostreococcus). Reaction conditions were optimized for each primer set which was validated in silico, on agarose gels, and by QPCR against a variety of target and non-target cultures. The approach was tested by estimating gene copy numbers for Micromonas, Bathycoccus, and Ostreococcus in seawater samples to which cultured cells were added in various concentrations. QPCR was then used to determine that rRNA gene (rDNA) copy number varied from one to more than 12,000 in 18 strains of phytoplankton. Finally, QPCR was applied to environmental samples from a Mediterranean Sea coastal site and the results were compared to those obtained by Fluorescent in situ hybridization (FISH). The data obtained demonstrate that Chlorophyta and more specifically Mamiellales were important in these waters, especially during the winter picoplankton bloom. The timing of major abundance peaks of the targeted species was similar by QPCR and FISH. When used in conjunction with other techniques such as FISH or gene clone libraries, QPCR appears as very promising to quickly obtain data on the ecological distribution of important phytoplankton groups. Data interpretation must take into account primer specificity and the varying rRNA gene copy number among eukaryotes.     

Determination of beta-defensin genomic copy number in different populations: a comparison of three methods

Background

There have been conflicting reports in the literature on association of gene copy number with disease, including CCL3L1 and HIV susceptibility, and β-defensins and Crohn''s disease. Quantification of precise gene copy numbers is important in order to define any association of gene copy number with disease. At present, real-time quantitative PCR (QPCR) is the most commonly used method to determine gene copy number, however the Paralogue Ratio Test (PRT) is being used in more and more laboratories.

Findings

In this study we compare a Pyrosequencing-based Paralogue Ratio Test (PPRT) for determining beta-defensin gene copy number with two currently used methods for gene copy number determination, QPCR and triplex PRT by typing five different cohorts (UK, Danish, Portuguese, Ghanaian and Czech) of DNA from a total of 576 healthy individuals. We found a systematic measurement bias between DNA cohorts revealed by QPCR, but not by the PRT-based methods. Using PRT, copy number ranged from 2 to 9 copies, with a modal copy number of 4 in all populations.

Conclusions

QPCR is very sensitive to quality of the template DNA, generating systematic biases that could produce false-positive or negative disease associations. Both triplex PRT and PPRT do not show this systematic bias, and type copy number within the correct range, although triplex PRT appears to be a more precise and accurate method to type beta-defensin copy number.     

地高辛标记探针检测Vero细胞狂犬病疫苗残余Vero细胞DNA含量

地高辛标记Vero细胞DNA,并制备成DNA探针,以此探针进行点杂交,确定探针的工作浓度,特异性及灵敏度,并用此法监测Vero细胞狂犬病疫苗浓缩原液纯化工艺的Vero细胞DNA去除率,测定精制Vero细胞狂犬病疫苗成品中残余Vero细胞DNA含量,结果明显,该法特异性强,重复性好,快速简便,灵敏度高,检测值可达5pg/剂量,可用于精制ero细胞狂犬病疫苗纯化工艺的质量控制和半成品检定。     

Short interspersed DNA element-mediated detection of UVB-induced DNA damage and repair in the mouse genome, in vitro, and in vivo in skin.

We report a sensitive, SINE (Short Interspersed DNA Element)-mediated, PCR-based, DNA damage detection assay. Here, the SINE assay is used for detection of UVB-induced DNA damage and repair in cultured mouse cells and in vivo, in mouse skin. The unique feature of the SINE assay is its ability to support simultaneous amplification of multiple, random segments of genomic DNA. This can be accomplished due to the remarkable abundance, dispersion and conservation of SINEs in mammalian genomes. The most abundant SINEs in the mouse genome are the B1 elements, at a copy number of 50,000-80,000. Due to their strong sequence conservation, primers complementary to the B1 consensus sequence anneal to the majority of their targets in the genome. Consequently, long segments of genomic DNA located between pairs of B1 elements are efficiently amplified by PCR. Thus, in conjunction with the fact that many types of DNA adducts form blocks for thermostable polymerase, the B1 element anchored PCR makes a sensitive and versatile tool for assessing the overall integrity of the transcribed regions in mouse genome. We measured UVB-dose (0.1-3 kJ m-2) dependent formation of photoproducts in DNA from cultured cells, and after 20 h observed a substantial removal of damage at doses lower or equal to 0.6 kJ m-2. The sensitivity of detection of UVB-photoproducts formation and repair was compared to that of the conventional, single locus-targeting QPCR. Using the SINE assay we also have shown the distribution of UVB and UVC induced DNA adducts at a single nucleotide resolution within the B1 elements in mouse DNA. Lastly, we demonstrated that the sensitivity of the SINE assay is adequate for measurement of UVB-dose (1-6 kJ m-2) dependent formation and subsequent removal of photoproducts in vivo, in mouse skin.     

Development of a purification process for adenovirus: controlling virus aggregation to improve the clearance of host cell DNA

The clearance of host cell DNA is a critical goal for purification process development for recombinant Ad5 (rAd5) based vaccines and gene therapy products. We have evaluated the clearance of DNA by a rAd5 purification process utilizing nuclease digestion, ultrafiltration, and anion exchange (AEX) chromatography and found residual host cell DNA to consistently reach a limiting value of about 100 pg/10(11) rAd5 particles. Characterization of the purified rAd5 product using serial AEX chromatography, hydroxyapatite chromatography, or nuclease treatment with and without particle disruption showed that the residual DNA was associated with virus particles. Using a variety of additional physical characterization methods, a population of rAd5 virus in an aggregated state was detected. Aggregation was eliminated using nonionic detergents to attenuate hydrophobic interactions and sodium chloride to attenuate electrostatic interactions. After implementation of these modifications, the process was able to consistently reduce host cell DNA to levels at or below 5 pg/10(11) rAd5 particles, suggesting that molecular interactions between cellular DNA and rAd5 are important determinants of process DNA clearance capability and that the co-purifying DNA was not encapsidated.     

Quantitative real-time polymerase chain reaction for determination of plasmid copy number in bacteria

A method for determination of plasmid copy number (PCN) in bacteria by real-time quantitative polymerase chain reaction (QPCR) was developed as an alternative to current PCN assays. Conventional methods for PCN estimation are generally not of high throughput, laborious, have low reproducibility, require large amounts of biological samples and are applicable only for a narrow dynamic range. Real-time QPCR, using the ABI Prism 7000, was able to sensitively detect the quantity of the pUC ori based plasmid, NS3, transformed into Escherichia coli host, DH5alpha, to be 411+/-6.1. The PCN of pBR322 plasmid DNA in DH5alpha was estimated to be 40+/-0.6 which is within its previously reported PCN range of approximately 30 to 70. QPCR was found to show good reproducibility and high sensitivity in detecting a two fold difference in template concentration, and a wide linear dynamic range covering 0.5 pg to 50 ng of DNA. PCNs of DH5alpha bearing plasmids pBR322 and NS3 computed from real-time QPCR assay were validated by that of agarose gel assay, and a marginal difference of only 13.0% and 10.7% was found for the two plasmids respectively. The QPCR assay was able to detect changes in PCN of plasmid producing DH5alpha during the course of a 2 l batch fermentation.     

Specific detection of residual CHO host cell DNA by real-time PCR.

Chinese hamster ovary cells have been widely used to manufacture recombinant proteins for human therapeutic use. A sensitive quantitative real-time polymerase chain reaction assay for the detection of residual Chinese hamster (Cricetulus griseus) DNA is presented in this paper. The assay is reasonably affordable and can be adapted for high-throughput screening using 96-well format. Real-time PCR primers were designed to amplify a 150bp region of a genomic fragment from hamster DNA. The specificity of the probe was evaluated in real-time PCR reactions using genomic DNA from mouse fibroblast, human kidney and hamster ovary cell lines as template. Sensitivity of real-time PCR was compared on genomic DNA from hamster cell line CHO DG44. These primers can be used in real-time PCR reactions to detect presence of contaminating hamster DNA in purified protein samples down to sensitivity of 300fg genomic DNA.     

Quantification of mitochondrial DNA copy number: Pre-analytical factors

Mitochondrial DNA (mtDNA) content is important for understanding many cellular processes. Several pre-analytical factors, from sample collection to DNA extraction can affect measurement of mtDNA copy number. In the present study, whole blood samples yielded a higher mtDNA copy number than buffy coat samples. mtDNA content is affected by the cell separation method used and the time between blood withdrawal and cell separation. Thus, reference values must be established with the same type of sample. As to the DNA isolation and purification method, the manual phenol method can give randomly false high values. The QIAamp DNA Mini Kit provided the most highly reproducible mtDNA/nDNA yield.     

Quantification of the carbazole 1,9a-dioxygenase gene by real-time competitive PCR combined with co-extraction of internal standards

The fluorogenic probe assay, competitive polymerase chain reaction (PCR) and co-extraction with internal standard cells were combined to develop a rapid, sensitive, and accurate quantification method for the copy number of a target carbazole 1,9a-dioxygenase gene (carAa) and the cell number of Pseudomonas sp. strain CA10. The internal standard DNA was modified by replacement of a 20-bp long region with one for binding a specific probe in fluorogenic PCR (TaqMan). The resultant DNA fragment was similar to the corresponding region of the intact carAa gene in terms of G+C content. When used as a competitor in the PCR reaction, the internal standard DNA was distinguishable from the target carAa gene by two specific fluorogenic probes with different fluorescence labels, and was automatically detected in a single tube using the ABI7700 sequence detection system. To minimize variations in the efficiency of cell lysis and DNA extraction between the samples, the co-extraction method was combined. A mini-transposon was used to introduce competitor DNA into the genome of other pseudomonads, and the resultant construct was used as the standard cell. After the addition of a fixed amount of the internal standard cells to soil samples, total DNA was extracted (co-extraction). Using this method, the copy number of the carAa gene and the cell number of strain CA10 in soil samples could be quantified rapidly.