Analysis of gene-specific DNA damage and repair using quantitative polymerase chain reaction

Soon after discovery of the polymerase chain reaction (PCR), various laboratories have attempted to use quantitative PCR (QPCR) to detect DNA damage in specific gene segments. The development of techniques that facilitate long PCR increased the sensitivity of the assay so that biologically relevant doses of DNA-damaging agents could be assessed. QPCR has been used to survey DNA damage induced by different genotoxicants and to establish the repair kinetics of numerous genes. Current work seeks to analyze damage and repair in specific genes from animals exposed to specific DNA-damaging agents such as oxidative stress.     

Real-time quantitative polymerase chain reaction

In Charcot-Marie-Tooth type 1A disease (CMTIA), heterozygosity for the peripheral myelin protein 22 (PMP22) duplication increases the gene dose from two to three, whereas, in hereditary neuropathy with liability to pressure palsies (HNPP), heterozygosity for the PMP22 deletion reduces the gene dose from two to one. Thirty-eight Norwegian patients with CMT1, 4 patients with HNPP, 15 asymptomatic family members, and 45 normal controls were studied using the ABI 7700 sequence detection system and the TaqMan method of real-time quantitative polymerase chain reaction (PCR). Using a comparative threshold cycle (Ct) method and albumin as reference gene, the gene copy number by PMP22 gene duplication or deletion on chromosome 17p11.2-12 was quantified. The PMP22 duplication ratio ranged from 1.50 to 2.21, the PMP22 deletion ratio ranged from 0.44 to 0.55, and the PMP22 ratio in normals ranged from 0.82 to 1.27. All samples were run in triplicate, with a mean standard deviation of 0.07 (range 0.01-0.17). Thirty-four of thirty-eight CMT1 patients (89.6%) had the PMP22 duplication and the four HNPP patients had the PMP22 deletion. This was not found in any of the asymptomatic family members or the controls. Real-time quantitative PCR is a sensitive, specific, and reproducible method for diagnosing PMP22 duplication and deletion. The method is fast, allowing 13 patients to be diagnosed in 2 h. It involves no radioisotopes and requires no post-PCR handling. In our opinion, real-time quantitative PCR is the first method of choice in diagnosing PMP22 duplication and deletion.     

Theoretical uncertainty of measurements using quantitative polymerase chain reaction.

Current quantitative polymerase chain reaction (PCR) protocols are only indicative of the quantity of a target sequence relative to a standard, because no means of estimating the amplification rate is yet available. The variability of PCR performed on isolated cells has already been reported by several authors, but it could not be extensively studied, because of lack of a system for doing kinetic data acquisition and of statistical methods suitable for analyzing this type of data. We used the branching process theory to simulate and analyze quantitative kinetic PCR data. We computed the probability distribution of the offspring of a single molecule. We demonstrated that the rate of amplication has a severe influence on the shape of this distribution. For high values of the amplification rate, the distribution has several maxima of probability. A single amplification trajectory is used to estimate the initial copy number of the target sequence as well as its confidence interval, provided that the amplification is done over more than 20 cycles. The consequence of possible molecular fluctuations in the early stage of amplification is that small copy numbers result in relatively larger intervals than large initial copy numbers. The confidence interval amplitude is the theoretical uncertainty of measurements using quantitative PCR. We expect these results to be applicable to the data produced by the next generation of thermocyclers for quantitative applications.     

Flow cytometric detection of specific genes in genetically modified bacteria using in situ polymerase chain reaction

Abstract Mycelium of Pleurotus ostreatus var. florida with a decreased growth rate contained seven double-stranded RNA segments and isometrical virus particles with diameters of 24 and 30 nm. Mycelium with a normal growth rate lacked dsRNA. Protoclones from virus-containing mycelium contained one to seven of these dsRNA segments in varying concentrations. The exact correlation between slow growth and the presence of dsRNA molecules could not be established. Infection of virus-free protoplasts with PEG-precipitated virus particles resulted in mycelium that stably maintained the 2.4 kbp dsRNA.     

Applications of real-time polymerase chain reaction for quantification of microorganisms in environmental samples

Due to the advanced development of fluorogenic chemistry, quantitative real-time polymerase chain reaction (qRT-PCR) has become an emerging technique for the detection and quantification of microorganisms in the environment. Compared with the conventional hybridization- and PCR-based techniques, qRT-PCR not only has better sensitivity and reproducibility, but it is also quicker to perform and has a minimum risk of amplicon carryover contamination. This article reviews the principle of this emerging technique, its detection reagents, target DNAs, quantification procedures, and affecting factors. The applications of qRT-PCR for the quantification of microorganisms in the environment are also summarized.     

定量聚合酶链反应评估去白细胞滤器去除血液成分中巨细胞病毒的效果

为了评估目前常用的去白细胞滤器去除血液成分中人巨细胞病毒( HCMV) 的效果, 我们在献血员中筛选获得HCMV-IgG、pp65 皆阴性的血液, 分离外周血单个核细胞( PBMC) , 将HCMV 感染的人成纤维细胞与PBMC 共培养, 感染HCMV 的PBMC 经抗人成纤维抗体和抗CD45 磁珠2 次分选纯化后, 将CD45 + 单核细胞加回原全血中, 建立HCMV 潜伏感染的模型, 再用去白细胞滤器过滤。用实时聚合酶链反应( PCR) 定量测定过滤前、后血液样本中的病毒载量, 残留成纤维细胞所含的HCMV 通过定量反转录PCR( RT - PCR) 扩增脯-4-羟化酶exon12a mRNA 来校正。结果显示, 使用去白细胞滤器后, 每单位( 200 ml) 全血血液中, 白细胞的去除率为99. 98% 。全血中平均HCMV 病毒载量从3 742 拷贝/ μl 降至22. 57 拷贝/ μl, 降低2. 50 log10 , 说明去白细胞滤器虽然可明显减少全血中HCMV 病毒的载量, 但并不能完全去除病毒。     

Characterization of Superoxide dismutase genes from Gram-positive bacteria by polymerase chain reaction using degenerate primers

Abstract An internal fragment representing approximately 85% of sod genes from seven Gram-positive bacteria was amplified by using degenerate primers in a polymerase chain reaction assay. The DNA sequences of sod polymerase chain reaction products from Clostridium perfringens, Enterococcus faecalis, Enterococcus faecium, Lactococcus lactis, Staphylococcus aureus, Streptococcus agalactiae, Streptococcus pneumoniae , and Streptococcus pyogenes were determined. Comparisons of their deduced amino acid sequences with those of the corresponding regions of the SOD proteins from Bacillus stearothermophilus, Listeria monocytogenes , and Streptococcus mutans revealed strong relatedness. Phylogenetic analysis of SOD peptides showed that members of the genera Streptococcus and those of the genera Enterococcus constitute two well-supported monophyletic groups. The method described in this study provides a means for easy recovery of sod genes and the construction of sod mutants of various Gram-positive pathogens.     

Amplification of DNA from native populations of soil bacteria by using the polymerase chain reaction.

Specific DNA sequences from native bacterial populations present in soil, sediment, and sand samples were amplified by using the polymerase chain reaction with primers for either "universal" eubacterial 16S rRNA genes or mercury resistance (mer) genes. With standard amplification conditions, 1.5-kb rDNA fragments from all 12 samples examined and from as little as 5 micrograms of soil were reproducibly amplified. A 1-kb mer fragment from one soil sample was also amplified. The identity of these amplified fragments was confirmed by DNA-DNA hybridization.     

Amplification of DNA from native populations of soil bacteria by using the polymerase chain reaction.

Specific DNA sequences from native bacterial populations present in soil, sediment, and sand samples were amplified by using the polymerase chain reaction with primers for either "universal" eubacterial 16S rRNA genes or mercury resistance (mer) genes. With standard amplification conditions, 1.5-kb rDNA fragments from all 12 samples examined and from as little as 5 micrograms of soil were reproducibly amplified. A 1-kb mer fragment from one soil sample was also amplified. The identity of these amplified fragments was confirmed by DNA-DNA hybridization.     

An effective method to extract DNA from environmental samples for polymerase chain reaction amplification and DNA fingerprint analysis

A rapid direct-extraction method was used to obtain DNA from environmental soil samples. Heat, enzymes, and guanidine isothiocyanate were utilized to lyse cells. The DNA was purified by agarose gel electrophoresis, amplified with 16S rRNA-based primers by use of the polymerase chain reaction, and then digested with the restriction endonucleasePalI. The extraction method was used to obtain DNA from a variety of plants, bacteria, and fungi includingGossypium hirsucum (cotton),Pseudomonas, Bacillus, Streptomyces, andColletotrichum. Up to 100 g DNA/g (wet weight) of soil and 400 g DNA/g of plant material were recovered. Restriction endonuclease analysis patterns of amplified rDNA from pure microbial cultures and plant species contained three to five different DNA fragments. Amplified rDNA of mixed population DNA extracts from soil samples, digested with the restriction endonucleasePalI, contained 12–20 DNA fragments, appearing as sample fingerprints. Results from eight environmental soil samples that were analyzed suggest that the amplified rDNA fingerprints can be used to help characterize the genetic and biological diversity of the microbial populations in these samples.     

Molecular detection of plant pathogenic bacteria using polymerase chain reaction single-strand conformation polymorphism

The application of polymerase chain reaction (PCR) technology to molecular diagnostics holds great promise for the early identification of agriculturally important plant pathogens. Ralstonia solanacearum, Xanthomoans axonopodis pv. vesicatoria, and Xanthomonas oryzae pv. oryzae are phytopathogenic bacteria, which can infect vegetables, cause severe yield loss. PCR-single-strand conformation polymorphism (PCR-SSCP) is a simple and powerful technique for identifying sequence changes in amplified DNA. The technique of PCR-SSCP is being exploited so far, only to detect and diagnose human bacterial pathogens in addition to plant pathogenic fungi. Selective media and serology are the commonly used methods for the detection of plant pathogens in infected plant materials. In this study, we developed PCR-SSCP technique to identify phytopathogenic bacteria. The PCR product was denatured and separated on a non-denaturing polyacrylamide gel. SSCP banding patterns were detected by silver staining of nucleic acids. We tested over 56 isolates of R. solanacearum, 44 isolates of X. axonopodis pv. vesicatoria, and 20 isolates of X. oryzae pv. oryzae. With the use of universal primer 16S rRNA, we could discriminate such species at the genus and species levels. Species-specific patterns were obtained for bacteria R. solanacearum, X. axonopodis pv. vesicatoria, and X. oryzae pv. oryzae. The potential use of PCR-SSCP technique for the detection and diagnosis of phytobacterial pathogens is discussed in the present paper.     

Kinetics of baculovirus replication and release using real-time quantitative polymerase chain reaction.

The study of viral-based processes is hampered by (a) their complex, transient nature, (b) the instability of products, and (c) the lack of accurate diagnostic assays. Here, we describe the use of real-time quantitative polymerase chain reaction to characterize baculoviral infection. Baculovirus DNA content doubles every 1.7 h from 6 h post-infection until replication is halted at the onset of budding. No dynamic equilibrium exists between replication and release, and the kinetics are independent of the cell density at the time of infection. No more than 16% of the intracellular virus copies bud from the cell.     

Production of discrete high specific activity DNA probes using the polymerase chain reaction

Conditions are described for the synthesis of discrete DNA probes with high specific activity using the polymerase chain reaction. This method enables the production of DNA probes between any two oligonucleotide sequences from cloned or uncloned templates. These probes are uniform in length and their specific activity (1 × 10⁹ cpm/μg) is comparable to probes produced by other methods.     

Characterization of polymerase chain reaction amplification of specific alleles

Under certain conditions, polymerase chain reaction (PCR) can be used to differentially amplify one allele over another. To characterize the phenomenon, we have made a series of PCR primers and determined whether differential amplification could be detected after agarose gel electrophoresis. Two allele pairs were examined; one pair represents a transversion and one pair represents a transition. The following conclusions emerge: (i) when the 3' or the 3' penultimate base of the oligonucleotide mismatched an allele, no amplification product could be detected; (ii) when the mismatches were 3 and 4 bases from the 3' end of the primer, differential amplification was still observed, but only at certain concentrations of magnesium chloride; (iii) the mismatched allele can be detected in the presence of a 40-fold excess of the matched allele; (iv) primers as short as 13 nucleotides were effective; and (v) the specificity of the amplification could be overwhelmed by greatly increasing the concentration of target DNA.     

Rapid method for processing soil samples for polymerase chain reaction amplification of specific gene sequences.

Bacterial cells can be differentially separated from soil colloids on the basis of their buoyant densities. By using this principle, a modified sucrose gradient centrifugation protocol has been developed for separating bacterial cells from most of the soil colloids. Since the bacterial cell suspension still contained some colloidal soil particles, which inhibited polymerase chain reaction amplification, a new "double" polymerase chain reaction method of analysis was adopted for amplification of Tn5-specific gene sequences. This new protocol allowed rapid detection of small numbers (1 to 10 CFU/g) of bacterial cells present in soil samples.