Analytic validation of a quantitative real-time PCR assay to measure CMV viral load in whole blood.

Cytomegalovirus (CMV) is a significant cause of morbidity and mortality in immunocompromised patients. We compared the CMV pp65 antigenemia test with a less labor intensive quantitative polymerase chain reaction (PCR) assay in 109 whole blood samples predominantly from transplant patients and patients with AIDS. DNA was amplified on an Applied Biosystems 7900 instrument using a TaqMan probe targeting the CMV polymerase gene and the APOB human control gene. The DNA assay was linear over a 6-log range from 8 to 800,000 CMV genomes per reaction; coefficient of variation was 20%. CMV DNA was undetectable in 20 blood samples from healthy donors whereas it was detected in 55 of 109 patient samples. Results were concordant in a nonlinear fashion with those of the antigenemia test in 90/109 (83%). Evaluation of the discrepancies suggested that either PCR or antigenemia assays could be falsely negative when virus levels were quite low. A point mutation interfered with probe binding in 1 sample. A second real-time PCR targeting the immediate early gene was even more likely to be false negative. In summary, CMV viral load measurement targeting the polymerase gene is nearly equivalent to the antigenemia assay for detecting and monitoring active CMV infection in whole blood samples.     

Monitoring of viral load by quantitative plasma PCR during active cytomegalovirus infection of individual liver transplant patients

A quantitative PCR test, the Cobas Amplicor CMV Monitor, was used for the monitoring of viral load in the peripheral blood of 27 individual liver transplant patients and correlated with cytomegalovirus (CMV) pp65 antigenemia. Altogether, 243 specimens were analyzed. During the first 3 months, 20 patients showed PCR positivity which correlated with pp65 antigenemia. Of those, 13 patients developed symptomatic CMV infection 27 to 52 days after transplantation, with a significantly higher peak viral load in PCR and in pp65 assay compared with the seven asymptomatic infections (median 10,200 versus 2,240 copies/ml, P < 0.05, and median 100 versus 30 pp65-positive cells/50,000 leukocytes, P < 0.01). Five were primary infections of D+/R- cases (donor CMV seropositive and recipient seronegative) and demonstrated, except in one case, a high peak viral load (>10,000 copies/ml; range, 10,200 to 21,600 copies, and > or =50 positive cells, range, 50 to 800 cells). The peak viral loads of the six D+/R+ patients with symptomatic infection varied widely (range, 2,290 to 126,000 copies and 50 to 300 positive cells). Two D-/R+ patients developed symptomatic infection with a lower viral load (range, 1,120 to 6,510 copies and 25 to 100 positive cells). All symptomatic infections were successfully treated with ganciclovir. The asymptomatic infections all in D+/R+ patients with low copy numbers (<5,500 copies) were monitored until CMV disappeared. One of the seven PCR-negative patients had one sample with low antigenemia, but the subsequent specimens were all negative. The time-related correlation of the two methods was also good. In summary, quantitative PCR could equally well be used as the CMV pp65 assay for the monitoring of viral load in individual transplant patients.     

Quantitative-competitive PCR monitoring of viral load following experimental guinea pig cytomegalovirus infection

Human cytomegalovirus (HCMV) is the most common cause of congenital viral infection in the developed world, and can lead to significant morbidity. Animal models of HCMV infection are required for study of pathogenesis, because of the strict species-specificity of cytomegalovirus (CMV). Among the small animal CMV models, the guinea pig CMV (GPCMV) has unique advantages, in particular its propensity to cross the placenta, causing disease in utero. In order to develop quantitative endpoints for vaccine and antiviral therapeutic studies in the GPCMV model, a quantitative-competitive PCR (qcPCR) assay was developed, based on the GPCMV homolog of the HCMV UL83 gene, GP83. Optimal amplification of GPCMV DNA was observed using primers spanning a 248 base pair (bp) region of this gene. A 91 bp deletion of this cloned fragment was generated for use as an internal standard (IS) for PCR amplification. Standard curves based upon the fluorescent intensity of full-length external target to IS were compared with signal intensity of DNA extracted from blood and organs of experimentally infected guinea pigs in order to quantify viral load. Viral load in newborn guinea pigs infected transplacentally was determined and compared with that of pups infected with GPCMV as neonates. Viral loads were highest in pups infected as neonates. The most consistent isolation and highest quantities of viral DNA were observed in liver and spleen, although viral genome could be readily identified in brain, lung, and salivary gland. Viral load determination should be useful for monitoring outcomes following vaccine studies, as well as responses to experimental antiviral agents.     

Whole blood real-time quantitative PCR for cytomegalovirus infection follow-up in transplant recipients.

BACKGROUND: Cytomegalovirus (CMV) remains a major opportunistic agent among transplant recipients. While detection of CMV pp65-lower matrix protein (pp65Ag) is still widely used for monitoring CMV infection, real-time PCR assays have been recently developed for routine quantitation of CMV DNA. However, correlations are lacking between results of pp65Ag and quantitative PCR assays and there is no consensus yet as to the more appropriate blood compartment (whole blood (WB), leukocytes, plasma) to be tested with PCR assays. OBJECTIVES: The aims of the study were to determine, in a population of transplant recipients: (i) the correlation between pp65Ag and CMV quantitative real-time PCR in our setting and (ii) the utility of plasma CMV DNA quantitation in comparison to WB quantitation. METHODS: In 170 blood samples (from 61 solid organ or bone marrow transplant recipients) with pp65Ag results, CMV quantitation was performed in WB and plasma using an in-house real-time quantitative PCR. RESULTS: Real-time PCR and pp65Ag results in WB were correlated: thresholds of 10 and 50(+) cells/200,000 cells were equivalent to 3.3 log(10)copies/mL (2,000 copies/mL) and 3.8 log(10)copies/mL (6,300 copies/mL), respectively. When WB viral load was >or=3.6 log(10)copies/mL, the risk to have a negative plasma CMV DNA result was 相似文献   

Quantitative measurement of infectious murine cytomegalovirus genomes in real-time PCR

Acute virus replication in murine (M) CMV infected C57BL/6 (Cmv1(r)) mice is severely limited by Ly49H+ NK cells, but not in MCMV infected BALB/c or BXD8 (Cmv1(s)) mice that lack Ly49H+ NK cells. Interestingly, other NK cell receptors may also play a role in MCMV immunity, as CMV encoded gp40 protein can diminish expression of protein ligands recognized by the NK cell receptor NKG2D. To determine whether other additional gene products might influence MCMV immunity, we designed an efficient, sensitive and reliable method for screening resistance or susceptibility phenotypes in mice. Although multiple methods are frequently used to detect and quantify infectious MCMV in mouse tissue samples collected during acute viral infection, these are not readily adaptable to high-throughput screening strategies. Hence, we utilized real-time PCR for detection and quantitative measurement of infectious MCMV genomes present in various tissues of infected mice. MCMV genomic sequence was accurately and reproducibly detected over the range 10(2)-10(8) molecules in mouse genomic DNA samples using this methodology. Importantly, it was found that quantitative real-time PCR and viral plaque assay measurements of MCMV in tissues collected from infected mice, including resistant and susceptible strains, were directly correlated. Moreover, quantitative real-time PCR results obtained during a 3-week time-course study of virus replication in spleens, livers and salivary glands of infected mice demonstrated sensitive, accurate and reproducible detection and measurement of infectious MCMV.     

Detection of human cytomegalovirus DNA by real-time quantitative PCR

A real-time PCR assay was developed to quantify human cytomegalovirus (CMV) DNA. This assay was used to demonstrate a higher CMV DNA load in plasma of bone marrow transplant patients than in that of blood donors. The CMV load was higher in CMV antigen-positive patients than in antigen-negative patients.     

Quantitative analysis of cytomegalovirus load using a real-time PCR assay

A novel real-time PCR assay system was developed to quantify the cytomegalovirus (CMV) genome load. The real-time PCR assay could detect from 6 to over 10(6) copies of CMV-DNA with a wide linear range. The virus load of immunocompromised patients with symptomatic CMV infections was quantified and compared to that of asymptomatic ones. In symptomatic patients, all 17 peripheral blood leukocytes were positive for CMV DNA, and its mean value was 10(3.3) copies/10(6) cells. On the other hand, only 9 of 38 samples (24%) were positive in the asymptomatic patients, and its mean titer was lower (10(2.0) copies/10(6) cells) than that of the symptomatic group (P = 0.002). In plasma, the virus genome was detected in 13 out of 17 samples from symptomatic patients (76%), and its mean value was 10(4.0) copies/ml. In contrast, for the asymptomatic group, only one out of 36 samples were positive (3%). Finally, this system was used to monitor two patients with CMV infections serially. The CMV DNA copy number changed with their clinical symptoms and anti-CMV therapy, and virtually paralleled the result of the pp65 antigenemia assay in both cases. In one patient with the cord blood transplantation, however, the CMV DNA became positive faster than the antigenemia assay. These results indicate that this assay is sensitive and useful for estimating the CMV genome load not only in peripheral blood leukocytes but also in plasma. It can be very helpful for diagnosing CMV-related diseases and monitoring the virus load in patients with CMV infections.     

Use of quantitative real-time PCR to monitor the response of Chlamydophila felis infection to doxycycline treatment

Fifteen cats infected with Chlamydophila felis were monitored for the presence of C. felis DNA on ocular swabs by using real-time PCR and for clinical signs of disease. The cats were assigned to three groups: oral doxycycline at 10 mg/kg of body weight/day for 7 days (six cats), oral doxycycline at 10 mg/kg/day for 14 days (five cats), and an untreated control group (four cats). The untreated cats remained positive for C. felis throughout the trial; clinical signs were most severe on days 14 to 21 postinfection, and then they declined. Treatment with 7 and 14 days of doxycycline decreased C. felis relative copy numbers and clinical signs rapidly. C. felis became undetectable in some of the cats during or after treatment. However, after the cessation of treatment, a recurrence of high relative copy numbers of C. felis and severe clinical signs in all cats was seen. Rescue treatment with 21 days of doxycycline was successful at eliminating infection in eight of the cats; a further 28 days of doxycycline was required to eliminate infection in the remaining three cats. It was concluded that 7, 14, and, in some cases, 21 days of treatment with oral doxycycline will not eliminate C. felis infection. At least 28 days of treatment with doxycycline is required to ensure elimination of the organism. Real-time PCR is a sensitive technique for monitoring C. felis infection and the response to antibiotic treatment.     

Use of real-time PCR to measure Epstein-Barr virus genomes in whole blood

The measurement of the Epstein–Barr viral load in peripheral blood has been recognised as an important way of monitoring the response to treatment in patients with Epstein–Barr virus (EBV)-related malignancies. In particular, EBV load in transplant recipients can be used as a predictive parameter for Post-transplant Lymphoproliferative Disorder (PTLD). The aim was to develop a rapid and reliable PCR protocol for the quantification of the cell-associated EBV genome. Real-time PCR using TaqMan methodology was established. This technique was applied to determine the EBV load in various study groups including healthy controls, transplant recipients, patients on haemodialysis, and patients with infectious mononucleosis. The baseline level of EBV genomes in the immunosuppressed renal transplant recipients was significantly different from that in the healthy controls.     

实时定量PCR检测HBV核酸载量测量不确定度的构成分析

 目的 研究实时荧光定量PCR用于乙型肝炎病毒（HBV）核酸载量检测时的测量不确定度构成。 方法 采用实时荧光定量PCR检测乙型肝炎患者血清标本中HBV核酸载量，收集检测过程中的各类数据，计算以下6种来源的测量不确定度，对该方法的测量不确定度构成进行评估。⑴标本浓缩的不确定度（uenrich）；⑵核酸提取的不确定度（uex）；⑶扩增反应体系的不确定度（upcr）；⑷热循环仪的不确定度（uins）；⑸数据处理的不确定度（uana）；⑹加样枪的不确定度（upip）。其中热循环仪的不确定度检测样本数为7份，其他各种不确定度检测的样本数为10份。 结果 核酸浓度为5.610E+07拷贝/ml的标本，其浓缩过程来源的相对不确定度达0.437；核酸提取来源的浓度真值无偏估计在6.585E+03、9.067E+04、7.223E+06拷贝/ml样本的相对不确定度分别为0.249、0.173、0.140；热循环仪和数据分析来源的相对不确定度分别为0.020和不大于0.050。 结论 标本制备过程中的浓缩和DNA提取步骤所带来的不确定度是实时荧光定量PCR检测HBV核酸载量测量不确定度的主要分量，因此标本制备处理的方法与标准操作程序能否有效地提取核酸并去除PCR反应的抑制物对于该项检测十分关键；起始模板浓度与测量不确定度相关，低浓度的样本显示出更大的相对不确定度。     

实时荧光定量PCR检测乙型肝炎病毒核酸载量的测量不确定度构成分析

目的 研究实时荧光定量PCR用于HBV核酸载量检测时的测量不确定度构成.方法 采用实时荧光定量PCR检测乙型肝炎患者血清标本中HBV核酸载量,收集检测过程中的各类数据,计算以下6种来源的测量不确定度,对该方法的测量不确定度构成进行评估.(1)标本浓缩的不确定度(uenrich);(2)核酸提取的不确定度(uex);(3)扩增反应体系的不确定度(upcr);(4)热循环仪的不确定度(uins);(5)数据处理的不确定度(uana);(6)加样枪的不确定度(upip).其中热循环仪的不确定度检测样本数为7份,其他各种不确定度检测的样本数为10份.结果 核酸浓度为5.610E+07拷贝/ml的标本,其浓缩过程来源的相对不确定度达0.437核酸提取来源的浓度真值无偏估计在6.585E+03、9.067E+04、7.223E+06拷贝/ml样本的相对不确定度分别为0.249、0.173、0.140;热循环仪和数据分析来源的相对不确定度分别为0.020和不大于0.050.结论 标本制备过程中的浓缩和DNA提取步骤所带来的不确定度是实时荧光定量PCR检测HBV核酸载量测量不确定度的主要分量,因此标本制备处理的方法与标准操作程序能否有效地提取核酸并去除PCR反应的抑制物对于该项检测十分关键;起始模板浓度与测量不确定度相关,低浓度的样本显示出更大的相对不确定度.     

Optimization of quantitative detection of cytomegalovirus DNA in plasma by real-time PCR

Previous studies have shown that detection of cytomegalovirus (CMV) DNA in plasma is less sensitive than the antigenemia assay for CMV surveillance in blood. In 1,983 blood samples, plasma PCR assays with three different primer sets (UL125 alone, UL126 alone, and UL55/UL123-exon 4) were compared to the pp65 antigenemia assay and blood cultures. Plasma PCR detected CMV more frequently in blood specimens than either the antigenemia assay or cultures, but of the three PCR assays, the double-primer assay (UL55/UL123-exon 4) performed best with regard to sensitivity, specificity, and predictive values compared to antigenemia: 122 of 151 antigenemia-positive samples were detected (sensitivity, 80.1%), and there were 122 samples that were PCR positive-antigenemia negative (specificity, 93%). Samples with discrepant results had a low viral load (median, 0.5 cells per slide; 1,150 copies per ml) and were often obtained from patients receiving antiviral therapy. CMV could be detected by other methods in 15 of 29 antigenemia positive-PCR negative samples compared to 121 of 122 PCR positive-antigenemia negative samples (P < 0.001). On a per-subject basis, 21 of 25 patients (antigenemia positive-PCR negative) and all 57 (PCR positive-antigenemia negative) could be confirmed at different time points during follow-up. The higher sensitivity of the double-primer assay resulted in earlier detection compared to antigenemia in a time-to-event analysis of 42 CMV-seropositive stem cell transplant recipients, and two of three patients with CMV disease who were antigenemia negative were detected by plasma PCR prior to the onset of disease. Interassay variability was low, and the dynamic range was >5 log(10). Automated DNA extraction resulted in high reproducibility, accurate CMV quantitation (R = 0.87, P < 0.001), improved sensitivity, and increased speed of sample processing. Thus, primer optimization and improved DNA extraction techniques resulted in a plasma-based PCR assay that is significantly more sensitive than pp65 antigenemia and blood cultures for detection of CMV in blood specimens.     

Multiplex,quantitative, real-time PCR assay for cytomegalovirus and human DNA

We created a multiplex, quantitative, real-time PCR assay that amplifies cytomegalovirus (CMV) and human DNA in the same reaction tube, allowing for a viral load determination that is normalized to measured human DNA. The assay targets a conserved region of the CMV DNA polymerase gene that is not affected by known drug resistance mutations. All 36 strains of CMV detected by culture or qualitative PCR in a population of lung transplant recipients were detected. The assay detected 1 to 10 copies of CMV plasmid DNA. The analytic sensitivity was not affected by the presence of DNA from 10(6) human cells but was reduced approximately 10-fold by alkaline lysates of leukocyte preparations. CMV quantitation was linear over a range of 10(1) to 10(6) copies. The intraassay and interassay coefficients of variation were 29 and 40%. Human DNA was regularly detected in patient plasma samples, and the amount was increased by storage of blood at room temperature before plasma separation and by plasma separation techniques that allowed leukocyte contamination. Applied to whole blood, the assay provides a measurement of CMV DNA in relation to cellular content without a need for cell counting procedures. Applied to plasma, the assay can reveal artifactual increases in plasma CMV levels resulting from leukocyte contamination. Further study of the utility of this assay to monitor patient populations at risk for CMV disease is warranted.     

Diagnosis of invasive mold infection by real-time quantitative PCR

We report the design and evaluation of a quantitative real-time polymerase chain reaction (PCR) assay to diagnose invasive mold infection (IMI) by detecting mold DNA in the serum. This assay detected 200 fg to 20 ng (5-log range) mold DNA and permitted a cutoff of 110 fg (3 genomes). Human or candidal DNA was not amplified. Specificity also was demonstrated by negative results in all 35 patients (76 serum samples) with unlikely IMI at the cutoff. For patients with possible, probable, and documented IMI diagnosed by a combination of clinical, microbiologic, and histologic criteria, this real-time PCR showed positivity in 40% (12/30), 68% (19/28), and 85% (11/13) cases, respectively, in testing of multiple serum samples. The overall serum positivity rate for these patients was 15.1% (73/483). Quantitative analysis of the positive serum samples estimated the bodily circulating mold burden to be 1.6 x 10(5) genomes (5.3 ng) by geometric mean with 4.2 x 10(7) genomes (1,400 ng) the highest. These results suggest that for the diagnosis of IMI, this real-time PCR may be a promising alternative to other invasive methods. Further evaluation is underway.     

Relationship of cytomegalovirus load assessed by real-time PCR to pp65 antigenemia in organ transplant recipients

BACKGROUND: Cytomegalovirus (CMV) infection in immunocompromised patients can lead to viremia associated with morbidity and mortality. Monitoring of viral loads in blood is critical for initiating and monitoring antiviral treatment. OBJECTIVES: Validate quantitative real-time PCR assay targeting the US17 and UL54 regions of the CMV genome for automated DNA and extraction and amplification. STUDY DESIGN: 3422 blood specimens from organ transplant recipients, including longitudinal specimens from 12 organ transplant recipients, were tested by CMV PCR and pp65 antigenemia. RESULTS: CMV PCR for both US17 and UL54, was more sensitive and detected CMV DNA earlier and for longer than the CMV pp65 antigenemia test. Using antigenemia results as a reference standard, an optimal cutoff of 500 normalized copies was calculated for both US17 and UL54 PCR targets based on high sensitivity, specificity, and positive and negative predictive values. CMV DNA levels tracked well with clinical symptoms, response to treatment, and antigenemia. CONCLUSIONS: Detection of persistent increases in CMV DNA levels above 500 normalized copies by this real-time PCR assay is indicative of symptomatic CMV disease in organ transplant recipients. Quantitative real-time PCR for CMV DNA can be used in lieu of antigenemia for monitoring CMV infection and determining when to initiate preemptive treatment.     

Development and evaluation of a real-time quantitative PCR for the detection of human cytomegalovirus

A novel real-time quantitative PCR (QPCR) assay is described for monitoring CMV DNA load in clinical specimens using the LightCycler. The assay is rapid (< 40 min), easy to carry out, robust, reliable and is capable of detecting from 10 to over 2 x 10(5) CMV DNA copies with a wide linear range. Amplification and detection occur simultaneously, avoiding the need for post-PCR analysis and thereby minimising the risk of carryover contamination. The assay proved to be accurate, specific and reproducible when evaluated in three different laboratories. In addition, LightCycler results were comparable with those of TaqMan, an independent real-time QPCR assay.     

Quantitative analysis of human herpesvirus 8 viral load using a real-time PCR assay

We have developed a quantitative real-time PCR (TaqMan) assay aimed at measuring the cellular human herpesvirus 8 (HHV-8) DNA load in various clinical samples. Standard curves were obtained by serial dilutions of a control plasmid containing both HHV-8 (ORF73 gene) and the cellular target (human albumin gene). The assay appeared to be very sensitive (100% detection rate for at least 10 copies per well) and specific and was easily reproducible (less than 3% intra-assay variability, 5% interassay variability). This method allowed us to quantify precisely the average HHV-8 copy number per cell in various persistently HHV-8-infected cell lines (BBG-1 cells, n = 200; BC-1 cells, n = 59; BCBL-1 cells, n = 70). A retrospective study was also conducted to assess the HHV-8 DNA load in 12 human immunodeficiency virus-infected patients with either Kaposi's sarcoma (KS; seven patients monitored over a 3-month period) or multicentric Castleman's disease (MCD; five patients). The HHV-8 DNA load ranged from 0 to 9,171 copies/10(6) cells in low-risk KS patients (T0, I0, S0 according to the classification of the AIDS Clinical Trials group). We also measured the viral loads in MCD patients either during symptomatic periods or during remission. The results are in agreement with previously published data, with high viral loads correlating with clinical symptoms (1.3 x 10(6) copies/10(6) cells) and low viral loads correlating with asymptomatic periods (less than 5,000 copies/10(6) cells).