The effect of fixation on detection of B-cell clonality by polymerase chain reaction.

It has been suggested that neutral buffered formalin (NBF)-fixed, paraffin-embedded, or fresh specimens might provide satisfactory DNA templates for polymerase chain reaction (PCR) assays used in establishing the clonality and presumptive B-cell lineage of lymphoma. The suitability of other fixatives used by hematopathologists, such as B5, is still undetermined. Thirty cases were identified from the files of the Cleveland Clinic Foundation, Cleveland Ohio, that showed abnormal immunoglobulin heavy chain (IgH) rearrangement by Southern blot analysis (SBA). Corresponding paraffin-embedded tissue samples fixed in NBF (21 cases), B5 (18 cases), Hollande's fixative (17 cases), zinc formalin (ZF) (5 cases), and Bouin's fixative (3 cases) were studied. With use of consensus primers against the framework 3 (FR3) and FR2 regions of the VH gene, paired against JH primer(s), PCR analysis was performed. bcl-2/IgH translocation was also studied. Ten reactive lymphoid samples were used as controls, and 40 cases were evaluated. Successful amplification of a clonal proliferation was manifested as one or two discrete narrow bands in the appropriate size range. The sensitivity of detecting clonality was 95, 94, 67, 80, and 0% for NBF, Hollande's fixative, B5, ZF, and Bouin's fixative, respectively. Although NBF and Hollande's fixative were 100% specific, consistent false-positive results were a major problem with B5-fixed tissue. Paraffin-embedded tissue, fixed in NBF, Hollande's fixative, and ZF solutions, may be used for DNA extraction and PCR assays for establishing B-cell clonality. The precipitating fixative B5 and Bouin's solution should not be used for this purpose until the issue of false-positive results is resolved.     

Novel polymerase chain reaction approach for full-coding p53 mutation detection in microdissected archival tumors.

Evidence suggests that up to 25% of p53 mutations are outside of exons 5-8 and that insertions, deletions, and polymorphic sites in the p53 gene may play a significant role in the process of carcinogenesis. A novel polymerase chain reaction (PCR) approach for the analysis of the entire p53 coding and splice site regions from microdissected, formalin-fixed, paraffin-embedded tumor tissues has been developed which allows multiple genetic analyses to be performed from one primary amplification reaction. The method was initially evaluated using well-characterized cell lines. In addition to confirming the published p53 mutations for HT29, Molt 4, A431, and HN5, a 16 base pair (bp) duplication within intron 3 was detected in both the A431 and HT29 cell lines. Analysis of archival samples of ovarian cancer identified the same 16-bp duplication and coding region variations. In all samples, using GenBank submission U94788 as a reference, a C-insertion was detected at nucleotide positions 11818 and 11874 within intron 2. At nucleotide position 14168, within intron 7, a T-to-G base change was found. This novel PCR approach has the potential to reduce the amount of clinical material required by up to 95%, thus facilitating retrospective studies on archival tumor collections. Furthermore, a wider analysis of the p53 gene, including splice sites and intronic regions, may yield additional information regarding cancer predisposition, response to therapy, and progression.     

The polymerase chain reaction for Mycoplasma gallisepticum detection

On the basis of the aligned 16S rRNA sequences of Mollicutes, a pair of primers was chosen for the detection of Mycoplasma gallisepticum. When used in the polymerase chain reaction (PCR), the primers detected a specific amplification of all Mg strains tested, yielding an expected 330 bp product. Amplification was not detected when other Mollicutes or E. coli were used as PCR templates. SPF chickens were experimentally inoculated with two strains of M. gallisepticum or Mycoplasma iowae. Tracheal swabs were collected 8, 15, 20 and 28 days after inoculation, and cultured for mycoplasma or tested by PCR. PCR products were detected by hybridization with a digoxigenin-labeled probe and by chemilumines-cence. The results showed that culture was positive for 49/73 swabs while PCR detected 70/72 positive samples. Thus, PCR can provide the basis of a sensitive, specific, rapid and non-radio-active method for detecting M. gallisepticum.     

Use of polymerase chain reaction for detection of Chlamydia trachomatis.

A polymerase chain reaction (PCR) assay was developed for detection of Chlamydia trachomatis DNA. From the published sequence of the common C. trachomatis plasmid, two primer sets were selected. Detection of amplified sequences was done by agarose gel electrophoresis of cleaved or uncleaved amplified sequences, Southern hybridization, or dot blot analysis. The PCR assay was optimized and, after 40 cycles of amplification with primer set II, demonstrated a sensitivity of 10(-17) g of DNA, which corresponds to the detection of one copy of the plasmid. Because of the high sensitivity, we developed a closed system in which airborne contamination was minimized. Analysis of 228 clinical samples tested by cell culture, IDEIA enzyme immunosorbent assay (Medico-Nobel, Boots-Celltech Ltd., Berkshire, United Kingdom), and PCR showed a sensitivity of 100%, a specificity of 93% when PCR was compared with cell culture, and a corrected specificity of 99% when PCR was compared with cell culture or IDEIA.     

Limitations of clonality analysis of B cell proliferations using CDR3 polymerase chain reaction.

BACKGROUND/AIMS: Detection of clonal immunoglobulin heavy chain (IgH) rearrangements by the polymerase chain reaction (PCR) is an attractive alternative to Southern blotting in lymphoma diagnostics. However, the advantages and limitations of PCR in clonality analysis are still not fully appreciated. In this study, clonality was analysed by means of PCR, focusing in particular on the sample size requirements when studying extremely small samples of polyclonal and monoclonal lesions. MATERIALS/METHODS: High resolution complementarity determining region 3 (CDR3) PCR was used to investigate the minimum number of cells and the amount of tissue required for the detection of a polyclonal population, both for fresh cells and formalin fixed, paraffin wax embedded tissue. Subsequently, frozen and paraffin wax embedded samples of 76 B cell lymphoproliferative disorders, 43 of which were tested by means of Southern blotting, were analysed to establish the sensitivity of this assay. These specimens included 12 chronic lymphocytic leukaemias (CLLs), nine mantle cell lymphomas (MCLs), 10 follicular lymphomas (FLs), and 45 mucosa associated lymphoid tissue (MALT) lymphomas. The specificity was tested on reactive lymph nodes (n = 19), tonsils (n = 4), peripheral blood lymphocyte fractions (n = 4), and biopsies with gastritis (n = 21). RESULTS: In reactive tissue, 20 ng of high molecular weight DNA derived from 6.5-9 x 10(3) B cells was sufficient to obtain a polyclonal PCR result. With smaller amounts "pseudoclonality" could be induced. When using paraffin wax blocks, undiluted DNA isolated from tonsillar tissue of at least 1 mm2 was necessary to obtain a polyclonal pattern. The sensitivity required to detect clonality in paraffin wax embedded and frozen tissue by PCR for FL (40% and 60%, respectively) was lower than that for MALT lymphomas (60% and 86%, respectively), CLL (78% and 89%, respectively), and MCL (88% and 100%, respectively). PCR specificity was 96% and 100% for frozen and paraffin wax embedded tissue, respectively. CONCLUSION: The minimum amount of template for CDR3 PCR is approximately 20 ng of high molecular weight DNA or 1 mm3 of B cell rich paraffin wax embedded normal tonsillar tissue, but care has to be taken to avoid pseudoclonality when low numbers of B cells are present. Duplicate or triplicate tests should be performed to avoid misinterpretation. The specificity of the PCR assay is almost 100%, whereas sensitivity depends on a combination of factors, such as lymphoma type and tissue fixation. Because frozen samples yield better results, obtaining fresh material for the PCR assay is recommended, especially when analysing FL and MALT lymphomas.     

Rapid polymerase chain reaction assays for Brevibacillus laterosporus detection

The identification of the ubiquitous spore‐forming bacterium Brevibacillus laterosporus, whose interest in pharma, agriculture, and other industrial sectors is raising, mostly relies on 16S ribosomal RNA gene sequence analysis. However, due to bacterial gene homology, this method appears insufficient for a proper discrimination of this species, so that the availability of other target genes is necessary. Leveraging the morphological and genetic feature uniqueness of B. laterosporus, a sensitive and reliable detection and quantification method based on polymerase chain reaction (PCR) and quantitative PCR assays, respectively, was developed. Targeting a highly conserved spore surface protein‐related gene, B. laterosporus could be easily found in different matrices including soil, food, and insect body. Primer set selectivity was confirmed to be very specific and no false positives or negatives were observed using DNA of different bacterial species as a template. The method developed is also suitable for the rapid identification of newly isolated B. laterosporus strains.     

Determination of lineage and clonality in diffuse lymphomas using the polymerase chain reaction technique

Malignant lymphomas of the diffuse mixed or diffuse large cell subtype are immunologically heterogeneous and morphologic features do not allow prediction of lineage. Applications of immunophenotypic and gene rearrangement techniques has greatly improved our ability to determine clonality and lineage. Nevertheless, some diffuse lymphomas are composed of numerous reactive cells accompanying a small clonal population, thereby making determination of clonality difficult, even with gene rearrangement techniques. In this study, we report two malignant lymphomas in which immunophenotypic and genotypic studies failed to elucidate evidence of clonality. In both cases, the polymerase chain reaction amplified segments of DNA containing the bcl-2/JH sequence, providing evidence of clonality and suggesting B-cell lineage. We conclude that the polymerase chain reaction technique may be useful in the diagnosis of some diffuse mixed and large cell lymphomas.     

The polymerase chain reaction for detection of T-cell antigen receptor expression.

Applications of the polymerase chain reaction have revolutionized the field of immunogenetics, particularly in studies of human leukocyte antigen class II polymorphism, and more recently in the analysis of T-cell receptor usage. However, the enormous diversity and variability of the T-cell receptor complex have made the amplification of the complete repertoire difficult. Several methods have been devised to address this problem. Each system is described with recent examples of its use and an assessment of its advantages and disadvantages. The use of quantitative polymerase chain reaction in T-cell receptor analysis is also discussed. The elucidation of the T-cell repertoire involved in a pathogenic process can have therapeutic implications, given the success of reversing experimental autoimmune disorders by directing specific forms of immunotherapy against V region gene products.     

Nested polymerase chain reaction for detection of Mycobacterium tuberculosis in clinical samples.

The nested polymerase chain reaction technique was compared with the conventional smear and culture methods for detection of Mycobacterium tuberculosis. The nested polymerase chain reaction used in this study showed excellent specificity, sensitivity, and agreement with the conventional methods for 417 clinical samples, indicating a contribution to the rapid diagnosis of mycobacterial infectious diseases.     

Silicon inhibition effects on the polymerase chain reaction: a real-time detection approach

In the miniaturization of biochemical analysis systems, biocompatibility of the microfabricated material is a key feature to be considered. A clear insight into interactions between biological reagents and microchip materials will help to build more robust functional bio-microelectromechanical systems (BioMEMS). In the present work, a real-time polymerase chain reaction (PCR) assay was used to study the inhibition effects of silicon and native silicon oxide particles on Hepatitis B Virus (HBV) DNA PCR amplification. Silicon nanoparticles with different surface oxides were added into the PCR mixture to activate possible interactions between the silicon-related materials and the PCR reagents. Ratios of silicon nanoparticle surface area to PCR mixture volume (surface to volume ratio) varied from 4.7 to 235.5 mm2/microL. Using high speed centrifugation, the nanoparticles were pelleted to tube inner surfaces. Supernatant extracts were then used in subsequent PCR experiments. To test whether silicon materials participated in amplifications directly, in some cases, entire PCR mixture containing silicon nanoparticles were used in amplification. Fluorescence histories of PCR amplifications indicated that with the increase in surface to volume ratio, amplification efficiency decreased considerably, and within the studied ranges, the higher the particle surface oxidation, the stronger the silicon inhibition effects on PCR. Adsorption of Taq polymerase (not nucleic acid) on the silicon-related material surface was the primary cause of the inhibition phenomena and silicon did not participate in the amplification process directly.     

Multiplex polymerase chain reaction.

The polymerase chain reaction (PCR) is a widely utilized assay for specifically amplifying small fragments of DNA. Multiplex PCR is the amplification of more than one DNA fragment per reaction and has many potential uses. When more than one primer set per reaction tube is utilized, the total number of tubes in any one experiment may be reduced, conserving expensive reagents and decreasing possible contamination. Multiplex PCR allows for an assay of the gene of interest and assures that the amplification process proceeds as expected with the use of a companion control genome primer set. Multiplex PCR is useful in assaying DNA extracted from samples of immunocompromised patients in which more than one infectious agent may be suspected such as simultaneous EBV and CMV detection. Multiplex PCR offers many advantages over single reaction PCR and has been found to be an useful adjunct in our laboratory.     

A novel,essential control for clonality analysis with human androgen receptor gene polymerase chain reaction

The most widely used technique for determining clonality based on X-chromosome inactivation is the human androgen receptor gene polymerase chain reaction (PCR). The reliability of this assay depends critically on the digestion of DNA before PCR with the methylation-sensitive restriction enzyme HpaII. We have developed a novel method for quantitatively monitoring the HpaII digestion in individual samples. Using real-time quantitative PCR we measured the efficiency of HpaII digestion by measuring the amplification of a gene that escapes X-chromosome inactivation (XE169) before and after digestion. This method was tested in blood samples from 30 individuals: 2 healthy donors and 28 patients with myelodysplastic syndrome. We found a lack of XE169 DNA reduction after digestion in the granulocytes of two myelodysplastic syndrome patients leading to a false polyclonal X-chromosome inactivation pattern. In all other samples a significant reduction of XE169 DNA was observed after HpaII digestion. The median reduction was 220-fold, ranging from a 9.0-fold to a 57,000-fold reduction. Also paraffin-embedded malignant tissue was investigated from two samples of patients with mantle cell lymphoma and two samples of patients with colon carcinoma. In three of these cases inefficient HpaII digestion led to inaccurate X-chromosome inactivation pattern ratios. We conclude that monitoring the efficiency of the HpaII digestion in a human androgen receptor gene PCR setting is both necessary and feasible.     

Nested polymerase chain reaction for high-sensitivity detection of enteroviral RNA in biological samples.

A method based on nested polymerase chain reaction was developed for the detection of enteroviral genomes in biological samples. By taking advantage of the conserved 5' noncoding region of the enteroviral RNA, two sets of primers were utilized, enabling the detection either of a broad range of enteroviruses or of group B coxsackieviruses only. The sensitivity of the method is close to the detection of single molecules of viral RNA in as much as 1 mg of tissue sample. A preliminary study showed the usefulness of this technique for the analysis of endomyocardial biopsy samples from patients with idiopathic dilated cardiomyopathy and myocarditis.     

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Sensitive detection of Helicobacter pylori by using polymerase chain reaction.

A polymerase chain reaction (PCR) for the specific detection of Helicobacter pylori was developed with a single primer pair derived from the nucleotide sequence of the urease A gene of H. pylori. We achieved specific amplification of a 411-bp DNA fragment in H. pylori. After 35 cycles of amplification, the product could be detected by agarose gel electrophoresis and contained conserved single HinfI and AluI restriction sites. This fragment was amplified in all 50 strains of H. pylori tested, but it was not detected in other bacterial species, showing the PCR assay to be 100% specific. PCR DNA amplification was able to detect as few as 10 H. pylori cells. PCR detected H. pylori in 15 of 23 clinical human gastric biopsy samples, whereas culturing and microscopy detected H. pylori in only 7 of the samples found to be positive by PCR. Additional primer pairs based on the urease genes enabled the detection of H. pylori in paraffin-embedded human gastric biopsy samples. The detection of H. pylori by PCR will enable both retrospective and prospective analyses of clinical samples, elucidating the role of this organism in gastroduodenal disease.     

Comparison of a conventional polymerase chain reaction with real-time polymerase chain reaction for the detection of neurotropic viruses in cerebrospinal fluid samples

Purpose: To compare a conventional polymerase chain reaction (PCR) and real-time PCR for the detection of neurotropic DNA viruses. Materials and Methods: A total of 147 cerebrospinal fluid (CSF) samples was collected from patients attending a tertiary care hospital in South India for a period from 2005 to 2008. All these samples were tested using a conventional multiplex/uniplex PCR and a real-time multiplex/uniplex PCR. This technique was used to detect a large number of herpes viruses responsible for central nervous system infections, including HSV-1, HSV-2, VZV, CMV and EBV and the polyoma virus JCV. Results: Overall, in the entire set of samples, the real-time PCR yielded 88 (59.9%) positives and conventional PCR had six (4.1%) positives. Conclusion: Our results suggest that the real-time PCR assay was more sensitive compared with the conventional PCR. The advantage of real-time PCR is that it can be performed much faster than conventional PCR. Real-time PCR is less time-consuming, less labour-intensive and also reduces the chance of contamination as there is no post-amplification procedure. In the entire study population, the major viruses detected using real-time PCR were EBV (34%), HSV-2 (10.8%) and VZV (6.8%).