Detection of H-1 parvovirus and Kilham rat virus by PCR.

H-1 virus and Kilham rat virus (KRV) are autonomous parvoviruses which generally cause subclinical infections in rats and can cause persistent infections in cell cultures. In this study, primer sets specific for either H-1 or KRV were designed on the basis of DNA sequence comparisons of the rodent parvoviruses. The specificities of the H-1 and KRV-specific primer sets were determined by testing viral preparations of seven different parvoviruses and nine other viruses known to infect rodents. The H-1-specific PCR assay amplified the expected 254-bp product only in the presence of H-1 viral DNA and was able to detect as little as 100 fg of H-1 viral DNA. The KRV-specific PCR assay generated the expected 281-bp product only when KRV viral DNA was used as the template and was able to detect as little as 10 pg of KRV viral DNA. Each assay was able to detect its respective virus in tissues from rats experimentally infected with H-1 or KRV. In contrast, no product was amplified by either assay with tissues from mock-infected rats. Our findings indicate that these PCR assays provide rapid, specific, and sensitive methods for the detection of H-1 or KRV infection in rats and cell culture systems.     

Comparison of loop-mediated isothermal amplification, real-time PCR, and virus isolation for the detection of herpes simplex virus in genital lesions

This study compares herpes simplex virus (HSV) type-specific loop-mediated isothermal amplification (LAMP) with virus isolation and real-time PCR. Genital tract specimens were obtained from 25 patients with genital lesions; two swab samples were collected from the vulva and cervix of each patient, for a total of 50 specimens. After culturing, 10 of 50 (20%) samples were positive for HSV-1 and 12 of 50 (24%) samples were positive for HSV-2. None of the patients excreted both HSV-1 and HSV-2 virus. An original HSV type-specific LAMP assay (30 min reaction) was compared with virus isolation and HSV type-specific real-time PCR. Viral DNA was detected by LAMP in 9 of 10 HSV-1 isolated samples and 11 of 12 HSV-2 isolated samples. No viral DNA was detected in samples without virus isolation. Thus, if virus isolation was used as the standard method, the LAMP protocol was highly sensitive and specific. In comparing LAMP to real-time PCR, viral DNA was detected by the LAMP method in 9 of 12 HSV-1 DNA positive samples and 11 of 18 HSV-2 DNA positive samples. If real-time PCR was used as the standard method, then, sensitivity of the LAMP method (in particular, for HSV-2) was low. Taking this into consideration, the LAMP reaction was extended to 60 min. This led to an increase in sensitivity, resulting in an additional one and three samples testing positive for HSV-1 LAMP and HSV-2 LAMP, respectively, compared to the original LAMP protocol. Therefore, the sensitivity of the LAMP method increased to about 80%.     

Analysis of DNA in fresh and fixed tissue by the polymerase chain reaction.

The polymerase chain reaction (PCR) was used to amplify viral or oncogene sequences from frozen or formalin-fixed, paraffin-embedded tissue sections. Methods for preparing fixed, embedded colonic tissue for PCR amplification of c-K-ras sequences from genomic DNA and for amplification of viral DNA from other tissues, including brain, lung, and liver, were evaluated. The effect of formalin fixation on the efficiency of amplification was also determined. While there seemed to be only a modest variation in the efficiency of the PCR for amplification of single-copy human genes, regardless of the methods used for tissue preparation, amplification of viral DNA sequences against a human genomic DNA background was more efficient when the DNA was purified to some degree before amplification of the tissue. We used the PCR to examine frozen and fixed embedded tissue sections for the presence of Epstein-Barr virus (EBV) and cytomegalovirus (CMV) DNA. One patient with a heart-lung transplant succumbed to a lymphoproliferative disorder, and EBV genome was present in tissues with abnormal lymphoid infiltrates. CMV was also present in bronchial lavages from the same patient, where cytologic diagnosis was not apparent. Another patient with a liver transplant showed CMV genome in multiple liver biopsies, with negative histologic results for CMV. In vitro DNA amplification with the PCR demonstrated sensitivity superior to that of histology in detecting CMV and EBV in the cases examined.     

Detection of herpesvirus DNA by the polymerase chain reaction (PCR) in vitreous samples from patients with necrotising retinitis

AIMS: Viral uveitis and retinitis, usually caused by herpesviruses, are common in immunosuppressed patients. The diagnosis of viral anterior uveitis and retinitis is usually clinical. The polymerase chain reaction (PCR) has been used for the diagnosis of some viral infections, especially those caused by herpesviruses. This paper reports the use of PCR in the diagnosis of viral retinitis in vitreous samples from Brazilian patients. METHODS: PCR was used for the diagnosis of necrotising retinitis in vitreous samples from patients from the Hospital S?o Geraldo, Universidade Federal de Minas Gerais, Brazil. The vitreous samples were collected by paracentesis and stored until analysis. Samples were analysed by PCR using specific primers designed to amplify herpes simplex virus 1 (HSV-1), varicella zoster virus (VZV), or human cytomegalovirus (HCMV). In a case of anterior uveitis, PCR was performed with a sample from the anterior chamber. RESULTS: Herpesvirus DNA was amplified in 11 of 17 samples. HCVM DNA was detected in nine samples but DNA from HSV-1 and VZV were detected only once each. CONCLUSION: These results strongly suggest that PCR could be used for a rapid complementary diagnosis of viral uveitis and retinitis. A prospective study to evaluate the PCR results, clinical evolution, and treatment is imperative to corroborate the real value of PCR in diagnosis and how it could help the clinicians' approach.     

Detection and quantification of infectious hypodermal and hematopoietic necrosis virus and white spot virus in shrimp using real-time quantitative PCR and SYBR Green chemistry

A rapid and highly sensitive real-time PCR detection and quantification method for infectious hypodermal and hematopoietic necrosis virus (IHHNV), a single-stranded DNA virus, and white spot virus (WSV), a double-stranded DNA (dsDNA) virus infecting penaeid shrimp (Penaeus sp.), was developed using the GeneAmp 5700 sequence detection system coupled with SYBR Green chemistry. The PCR mixture contains a fluorescence dye, SYBR Green, which upon binding to dsDNA exhibits fluorescence enhancement. The enhancement of fluorescence was proportional to the initial concentration of the template DNA. A linear relationship was observed between the amount of input plasmid DNA and cycle threshold (C(T)) values over a range of 1 to 10(5) copies of the viral genome. To control the variation in sampling and processing among samples, the shrimp beta-actin gene was amplified in parallel with the viral DNA. The C(T) values of IHHNV- and WSV-infected samples were used to determine absolute viral copy numbers from the standard C(T) curves of these viruses. For each virus and its beta-actin control, the specificity of amplification was monitored by using the dissociation curve of the amplified product. Using genomic DNA as a template, SYBR Green PCR was found to be 100- to 2000-fold more sensitive than conventional PCR, depending on the virus, for the samples tested. The results demonstrate that SYBR Green PCR can be used as a rapid and highly sensitive detection and quantification method for shrimp viruses and that it is amenable to high-throughout assay.     

A simplified method for the extraction of baculoviral DNA for PCR analysis: a practical application

There are two major strategies to genetically modify baculoviruses. One uses a bacmid-based system which replicates in Escherichia coli using a bacterial origin of replication. The other employs a transfer vector and viral DNA which are co-transfected into insect cells and utilise host enzyme-mediated homologous recombination. Putative recombinants are then typically screened by plaque assay. The bacmid system is more convenient, but it requires a number of complex construction and isolation steps to obtain the correct bacmid genome. Generally, the transfer vector method is preferable when only a small number of genetic modifications are required. In this study a rapid and reliable method was developed to extract baculovirus DNA for PCR analysis from cultured insect cells. Briefly, viral DNA was isolated in three steps: SDS lysis, chloroform extraction and ethanol precipitation. The method was tested for direct screening of recombinant viruses in plaque assays. Contrary to previous reports, baculovirus DNA was isolated directly from viral plaques and successfully analysed by PCR. No prior amplification of the virus by passage in tissue culture was necessary. The major advantage of this method was a reduction in assay times from a few days to a few hours. Moreover, this method is very convenient for detecting baculoviruses in cell culture: cross-contamination within viral stocks, monitoring mixed viral infection and confirmation of viral genomic integrity.     

Comparison of virus isolation and various polymerase chain reaction methods in the diagnosis of mucocutaneous herpesvirus infection

We compared two polymerase chain reaction (PCR) assays (simple and multiplex) and viral isolation to detect herpes simplex virus 1 (HSV-1) and varicella-zoster virus (VZV) in 15 clinical specimens from 13 patients with mucocutaneous herpetic infections. HSV-1 or VZV DNA was detected in 13 specimens by simple PCRs (HSV-1 or VZV PCR) and in 12 specimens by multiplex PCR. On the other hand, viral isolation was positive for 9 specimens only. The PCR protocols used in this study are not only more sensitive and faster than the traditional viral isolation and conventional PCR protocols but also can distinguish rapidly HSV-1 from VZV. We propose the PCRs described here for rapid and precise identification of etiological agents of mucocutaneous herpetic infections.     

Comparative studies on the detection of hepatitis B virus DNA in frozen and paraffin sections by the polymerase chain reaction.

The polymerase chain reaction (PCR) is an extremely sensitive technique that has been used for detection of DNA sequences in formalin-fixed, paraffin-embedded tissues. In order to verify that hepatitis B virus (HBV) DNA sequences are adequately preserved in routinely processed liver tissues, we performed PCR with five different primer pairs for HBV sequences on DNA extracted by two different methods from paraffin and frozen liver sections. The amount of PCR products obtained with DNA templates extracted by the proteinase K-SDS method from frozen sections was significantly larger than that from paraffin sections. However, boiling of deparaffinized sections in water containing Chelex-100 resulted in ample amounts of PCR products irrespective of the primers used. On Southern blots, the location of the bands of amplified DNA obtained by the different methods was consistent with the predicted size, suggesting that the viral sequences had not been altered by processing. Although freezing of fresh tissue yields quantitatively more HBV DNA, formalin fixation qualitatively preserves the viral DNA sequences adequately for detection by PCR. Therefore, formalin-fixed, paraffin-embedded tissues may be used for the detection of viral DNA sequences by PCR. Application of the described procedure to routinely processed tissues significantly broadens the applicability of this powerful diagnostic and investigative method.     

Comparison of six nucleic acid extraction methods for detection of viral DNA or RNA sequences in four different non-serum specimen types.

BACKGROUND: Extraction of viral nucleic acids from serum samples is widely used in diagnostic pathology tests. However, the heterogeneous nature of non-serum samples may contribute to variations in the yields of viral nucleic acids with different extraction methods and specimen types. OBJECTIVES: Six different methods were compared for optimal extraction of viral DNA or RNA from four types of non-serum specimens. STUDY DESIGN: The DNA viruses used were herpes simplex virus and cytomegalovirus. The RNA viruses were poliovirus, rotavirus and small round structured virus. The specimens used were from respiratory, genital, faecal and peripheral blood mononuclear cell samples. The extracted nucleic acids were amplified by PCR and detected in an enzyme immunoassay using digoxygenin-labelled amplicons. RESULTS AND CONCLUSIONS: For extraction of viral DNA, the phenol-chloroform method yielded the highest amount of DNA as judged by endpoint titration. The three methods compared for extraction of viral RNA used guanidine isothiocyanate and the QiaRNA kit was shown to yield the highest amount of viral RNA.     

Detection and diagnosis of parapoxvirus by the polymerase chain reaction

The genus Parapoxvirus includes four members, bovine papular stomatitis virus (BPSV), pseudocowpox virus (PCPV), orf virus (ORFV) and parapoxvirus of red deer in New Zealand (PVNZ). A set of primers for polymerase chain reaction (PCR) was designed to detect viral DNA from cells infected with each of the four parapoxviruses. The set of primers resulted in the amplification of appropriately sized products from cells infected with BPSV, PCPV, ORFV and PVNZ, respectively. The PCR method was applied for the detection of seven field isolates of parapoxvirus from cattle, sheep and free-ranging wild Japanese serows. The expected size of DNA was amplified from cells infected with each of the seven isolates. No specific PCR products were detected from vaccinia virus-, fowlpox virus- and mock-infected cells. Moreover, by a semi-nested PCR with an inner primer and Southern blot analysis, viral DNA was detected from lesions of clinically affected cattle, sheep and Japanese serows. These results suggested that the PCR method used in this study was specific for the detection of parapoxviruses and thus useful for diagnosis of parapoxvirus infections, especially in discrimination from diseases with similar clinical symptoms.     

Comparison of a LightCycler-based real-time PCR for quantitation of Epstein-Barr viral load in different clinical specimens with semiquantitative PCR

Measurement of viral load is important in predicting and monitoring of Epstein-Barr virus (EBV)-associated diseases especially in immunocompromised patients. The objectives of this study were the development of a LightCycler-based real-time PCR assay using primers and probes which recognize the virus capsid antigen p23-encoding region and its comparison to the semiquantitative PCR. The LightCycler protocol shows a high degree of specificity and inter- and intra-assay reproducibility. Concerning sensitivity, a good correlation between both methods was demonstrated for standard plasmid DNA, reference DNA isolated from the EBV-genome containing Namalwa cell line, and DNA extracted from plasma/cerebrospinal fluid (CSF). The detection limit was determined with 1 copy/microl eluate for the standard plasmid DNA and with 500 copies/ml plasma or CSF. For DNA derived from peripheral blood mononuclear cells (PBMCs), a decrease of sensitivity by factor 10-100 was found when larger amounts of background DNA (500 and 100 ng) were used presuming an inhibitory effect of cellular DNA. This was supported by running dilutions of the plasmid standard carried out with EBV-negative Ramos cell DNA. Thus, the cut-off level was estimated with 100-500 copies/10(5) PBMCs, when 50 or 10 ng total DNA were tested. The results indicate that the real-time PCR described here is a first line tool for the determination of viral load in plasma and CSF. Semiquantitative nested PCR is used for screening of PBMCs viral load. Positive specimens containing more than 500 copies/10(5) cells are measured for exact values by real-time PCR. To circumvent inhibitory effects of cellular DNA, measurements should be carried out generally with 50-10 ng DNA.     

Rapid and biologically safe diagnosis of African swine fever virus infection by using polymerase chain reaction.

In order to circumvent the need for infectious virus for the diagnosis of African swine fever (ASF), we established the polymerase chain reaction (PCR) technique for the detection of ASF virus (ASFV) DNA. A 740-bp fragment that originated from the conserved region of the viral genome was partially sequenced. From this sequence, four PCR primers and one oligonucleotide probe were designed and synthesized. A specific 640-bp PCR product was amplified by using oligonucleotides 1 and 5 as primers and extracts of the following samples as templates: organs and plasma obtained from ASFV-infected pigs, ASFV-infected cell cultures, and cloned DNA fragments containing the same conserved genomic region as that in the original 740-bp clone. No specific reaction products were observed in the corresponding controls. The identities of the PCR products were confirmed either by a second amplification with nested primers or by hybridization with a specific, biotinylated oligonucleotide probe. PCR proved to be a quicker and more sensitive method than virus isolation followed by the hemadsorption test when spleen and plasma samples from experimentally ASFV-infected pigs were tested. Furthermore, cloned virus DNA could be used as a positive control in the place of a live virus control. This is advantageous whenever the use of live virus is undesirable.     

Detection of bovine retrospumavirus by the polymerase chain reaction

A polymerase chain reaction (PCR) assay was developed for detection of bovine retrospumavirus (bovine syncytial virus; BSV) provirus DNA. Two different sets of oligonucleotide primers complementary to sequences located in the gag and the pol/env gene regions were used and compared for their ability to amplify the targeted BSV sequences by PCR. The results obtained from this study have shown that it is possible to amplify the BSV provirus DNA sequences not only from total DNA of BSV-infected cell cultures, but also from total DNA of various tissues and peripheral blood mononuclear cells (PBMCs) that were collected from two rabbits experimentally infected with BSV. Sensitivities of the PCR for amplification of BSV gag and pol/env nucleic acid sequences from cell culture total DNA were 10 ng and 10 pg of DNA, respectively, as determined by the analysis of the amplified PCR products on ethidium bromide-stained agarose gels. The specificity of the PCR for both primer sets tested was confirmed when the amplified cDNA products of the expected size reacted positively with the corresponding virus-specific digoxigenin-labeled cDNA probes in Southern blot chemiluminescent hybridization assays. No amplification was obtained when the BSV-specific primers were used in the PCR with DNA material specific to either bovine leukemia virus (BLV) or bovine immunodeficiency virus (BIV) provirus genomic DNA. No cross-hybridization was obtained when the BSV-specific cDNA probes were allowed to react with BLV or BIV provirus DNA. The PCR targeting the gag and pol/env gene regions of the BSV provirus genome may be an alternative to conventional methods for the confirmation of the presence of BSV in cell cultures used for virus isolation, and for the diagnosis of BSV infection from bovine peripheral blood leukocytes.     

Long-term storage at tropical temperature of dried-blood filter papers for detection and genotyping of RNA and DNA viruses by direct PCR

In tropical countries the diagnosis of viral infections of humans or animals is often hampered by the lack of suitable clinical material and the necessity to maintain a cold chain for sample preservation up to the laboratory. This study describes the use of filter papers for rapid sample collection, and the molecular detection and genotyping of viruses when stored over long periods at elevated temperatures. Infected blood was collected on filter papers, dried and stored at different temperatures (22, 32 and 37 degrees C) for various periods (up to 9 months). Two animal viruses, African swine fever, a large double-stranded DNA virus and Peste des Petits Ruminants, a negative single-stranded RNA virus, were used to validate the method. Filter papers with dried blood containing virus or control plasmid DNA were cut in small 5mm(2) pieces and added directly to the PCR tube for conventional PCR. Nucleic acid from both viruses could still be detected after 3 months at 32 degrees C. Moreover, the DNA virus could be detected at least 9 months after conservation at 37 degrees C. PCR products obtained from the filter papers were sequenced and phylogenetic analysis carried out. The results were consistent with published sequences, demonstrating that this method can be used for virus genotyping.     

Detection of viral DNA to evaluate outcome of antiviral treatment of patients with recurrent genital herpes.

Culture of infectious virus, PCR amplification of viral DNA, and the appearance of genital skin lesions were used as markers to study the course of a recurrence of genital herpes in 40 patients treated with famciclovir or placebo. The highest frequency of patients with skin lesions occurred within the first 36 h following the onset of a recurrence, which also corresponded to the peak in the production of virus. While the timing of the peak in skin lesions was independent of the type of treatment, the frequency of lesions and the release of virus at the lesion site were both reduced by famciclovir treatment. Furthermore, patients receiving this antiviral agent showed a more rapid recovery time and a shorter period during which viral DNA could be detected at the lesion. PCR and then Southern blot hybridization greatly enhanced our ability to detect herpes simplex virus at the lesion site. This procedure proved to be of greater diagnostic value in assessing genital herpes than the standard culture method currently used. In addition, PCR was more sensitive in evaluating treatment effectiveness.     

Quantification of feline herpesvirus 1 DNA in ocular fluid samples of clinically diseased cats by real-time TaqMan PCR

A fluorogenic PCR was established for the quantification of feline herpesvirus 1 (FeHV-1) DNA in ocular fluid samples of clinically diseased cats. The new assay was specific for FeHV-1 and sensitive. The 100% detection rate ranged from 0.6 to 6 50% tissue culture infective doses per sample. When spiked samples with known quantities of virus were used, infectious virus titers and quantification of viral DNA by PCR correlated to each other in a linear fashion (R(2) = 0.9858) over a range of 4 orders of magnitude. Within this range, it was possible to calculate the FeHV-1 DNA content from a given infectious dose, and vice versa. The new diagnostic procedure was applied to ocular fluid samples from cats experimentally infected with FeHV-1 and specific FeHV-1-free cats. A good correlation between virus titer and quantitative PCR was observed, although only early in infection. In a second stage, the titer of infectious virus collapsed, while the PCR signal remained high. A constantly decreasing PCR signal accompanied by negative virus isolation was characteristic for a final stage of the infection. Finally, clinical samples from 20 cats that were suspected to suffer from FeHV-1 infection were analyzed. By comparing virus titers and quantitative PCR signals, it was possible to determine the current stage of the ongoing infection. Based on these findings, comparison of the results of consecutive samples allows the tracking of the course of the infection. Therefore, the new method combines the advantages of the two previously established conventional methods, qualitative PCR and virus isolation and titration.     

Tissue distribution of bovid herpesvirus-4 in inoculated rabbits and its detection by DNA hybridization and polymerase chain reaction

Summary A DNA hybridization technique, using the polyrepetitiveEcoRI L-fragment of bovid herpesvirus (BHV-4) as a probe, was developed to determine virus distribution in the tissues of BHV-4-infected pregnant rabbits. The cloned fragment did not react with the DNA of rabbits or of other herpesviruses, e.g., infectious bovine rhinotracheitis, bovine herpes virus mammillitis, and pseudorabies viruses. The detection limit was 10^–13g of DNA or approximately 600 genome equivalents of viral DNA, which indicates a level of sensitivity of one viral genome per 500 cells in our assay. Using conventional cell culture techniques, the virus was isolated from only one of fifteen infected rabbits and a few aborted fetuses. However, when organ culture or dot blot hybridization was used, BHV-4 was detected in all rabbits and their fetuses. Viral DNA was detected by DNA hybridization in spleen, ovary, uterus, lung, liver, salivary gland, lymph node, and placentome of adult rabbits and in a composite of fetal tissues. When polymerase chain reaction (PCR) was used, the virus was detected in several organs (including the nervous tissues) that were found negative by other techniques. These results indicate that blot hybridization and PCR are more sensitive than conventional techniques for studying the pathogenesis of BHV-4 in animals. The data obtained by these methods suggest that BHV-4 may be maintained in infected rabbits in a latent state in a variety of tissues including the nervous system.     

Detection and identification of human influenza viruses by the polymerase chain reaction

A series of oligonucleotide primers are described which hybridize to conserved regions of influenza virus cDNA and prime DNA synthesis in Taq polymerase catalyzed amplification reactions (PCR). Primers were designed to hybridize as nested pairs and, following a two-step amplification, produce uniquely sized DNA fragments diagnostic for viral type and subtype. Influenza A and B matrix-protein genes and the influenza C haemagglutinin gene were targets for the type-specific primers. Subtype-specific primers targeted conserved sequences within the three haemagglutinin or two neuraminidase subtypes of different human influenza isolates. The utility of this method was demonstrated using computer search methods and by accurately amplifying DNA from a variety of influenza A, B, and C strains. Type-specific primer sets showed a broad type specificity and amplified DNA from viral strains of unknown sequence. Restriction mapping and DNA sequencing showed that fragments amplified in this manner derived from the input template, confirming the accuracy of the method and demonstrating how PCR can be used to quickly derive sufficient sequence information for analysis of viral relatedness. Subtyping primers were able to distinguish accurately between the three haemagglutinin (H1, H2, H3) and two neuraminidase (N1, N2) alleles of human influenza A isolates. Again DNA was amplified from viruses of unknown sequence confirming that most of these primer sets may prove useful as broad range subtyping reagents. In order to simplify the work associated with analysis of many samples, we have also devised a rapid method for the isolation of viral RNA and synthesis of cDNA. Using this 'mini-prep' technique, it is possible to detect, amplify, and identify picogram quantities of influenza virus in a single day, confirming that PCR provides a useful alternative to existing methods of influenza detection.     

Detection of herpes simplex virus using the polymerase chain reaction followed by endonuclease cleavage.

The polymerase chain reaction (PCR) was used to amplify herpes simplex virus DNA using a single set of primers that amplify both herpes simplex virus I (HSVI) and II (HSVII). The viruses can be differentiated by a single restriction enzyme cleavage. Virus from dilutions of HSV-infected A549 cell suspensions were amplified and the infectivity endpoints of cell culture were compared with the PCR, and with another direct detection method, the enzyme-linked immunosorbent assay (ELISA). The PCR was capable of detecting virus at a 10(-4) dilution for both HSVI and HSVII, when the corresponding TCID50 endpoints were 10(-5.9) and 10(-5.7), respectively. The ELISA detected virus only down to the 10(-1) dilution. The amplification procedure showed the greatest sensitivity when an initial protease digestion was followed by filtration. The PCR may have use in detection of HSV in clinical situations in which a rapid result is desirable.