We have developed a simple, rapid, and reliable protocol for the small-scale purification of DNA and RNA from, e.g., human serum and urine. The method is based on the lysing and nuclease-inactivating properties of the chaotropic agent guanidinium thiocyanate together with the nucleic acid-binding properties of silica particles or diatoms in the presence of this agent. By using size-fractionated silica particles, nucleic acids (covalently closed circular, relaxed circular, and linear double-stranded DNA; single-stranded DNA; and rRNA) could be purified from 12 different specimens in less than 1 h and were recovered in the initial reaction vessel. Purified DNA (although significantly sheared) was a good substrate for restriction endonucleases and DNA ligase and was recovered with high yields (usually over 50%) from the picogram to the microgram level. Copurified rRNA was recovered almost undegraded. Substituting size-fractionated silica particles for diatoms (the fossilized cell walls of unicellular algae) allowed for the purification of microgram amounts of genomic DNA, plasmid DNA, and rRNA from cell-rich sources, as exemplified for pathogenic gram-negative bacteria. In this paper, we show representative experiments illustrating some characteristics of the procedure which may have wide application in clinical microbiology.
The objective of the present study was the development of a diagnostic reverse transcription (RT)-PCR for the specific detection of enterovirus (EV) RNA in clinical specimens controlled by an internal control (IC) RNA. The IC RNA contains the same primer binding sites as EV RNA but has a different probe region. The IC RNA was packaged into an MS2 phage core particle (armored) and was added to the clinical sample to allow monitoring of both extraction efficiency and RT-PCR efficiency. Serial dilutions of the IC RNA were made, and the detection limit of the RT-PCR was tested in a background of EV RNA-negative cerebrospinal fluid. The sensitivity and specificity of the RT-PCR assay were tested by using all 64 known EV serotypes, several non-EV serotypes, and two Quality Control for Molecular Diagnostics ( The human enteroviruses (EVs) are members of the family Picornaviridae, are ubiquitous, and are mainly enterically transmitted. EVs have traditionally been identified by serotype-specific antisera in a virus-neutralizing test, and 66 EV types are known to infect humans (19). The 66 EV serotypes were initially recognized and divided into five major groups: polioviruses (PV; types 1 to 3), coxsackieviruses A (CVAs; types 1 to 22 and 24), coxsackieviruses B (CVBs; types 1 to 6), echoviruses (types 1 to 7, 9, 11 to 27, and 29 to 33), and EV types 68 to 71 (17). Recent molecular analyses have proved that echovirus types 22 and 23 are genetically distinct from the members of the genus Enterovirus and have been reclassified in a separate genus, Parechovirus, in the family Picornaviridae (13,20,23).Infections with EVs cause a wide range of clinical outcomes, such as asymptomatic infections, aseptic meningitis (meningeal inflammation in the absence of a bacterial pathogen), encephalitis, paralytic poliomyelitis, and myocarditis. Although the majority of EV infections do not cause significant disease, infection can cause serious illness, especially in infants and immune-compromised patients. EV infections are the most common cause of aseptic meningitis and account for 80 to 90% of all cases of central nervous system infections for which a possible causative agent is identified (24). In the neonate, aseptic meningitis-induced complications and poor outcomes of EV infections generally occur within the first 2 days of life (1, 2). Aseptic meningitis in immune-competent adults is characterized by sudden onset of fever, but neurological abnormalities are rare, and both short-term and long-term outcomes are generally good. Encephalitis caused by EV infections is a less common but a more severe disease than aseptic meningitis (18,29,30). Immune-compromised children and adults who are infected with EV may develop chronic meningitis and encephalitis, which may last for years before becoming fatal (16).The early clinical symptoms of meningitis caused by viruses, bacteria, and fungi are quite similar and are difficult to distinguish, but the diagnosis, therapy, and outcome of disease caused by these pathogens vary considerably. A reli...
Syncytium-inducing (SI) phenotype suppression at seroconversion after intramuscular inoculation of a non-syncytium-inducing/SI phenotypically mixed human immunodeficiency virus population
Two distinct biological phenotypes of human immunodeficiency virus (HIV) have been described: the non-syncytium-inducing (NSI) phenotype, best characterized by the inability to infect MT-2 cells, and the syncytium-inducing (SI) phenotype, with the ability to infect MT-2 cells. The earliest virus population observed following HIV transmission is generally of the NSI phenotype, even after exposure to inocula of mixed NSI/SI phenotype. In this study, the issue of intrapatient selection of virus phenotype following transmission was addressed by studying two cases of accidental transmission. A comparison of the sequences of the V1-V2 and the V3 coding regions of the envelope gene and the p17 region of the gag gene showed that the donor-recipient pairs were tightly clustered in all gene segments, but away from local and published transmission controls. The intrasample variation of the p17 sequence was greater in the recipients and smaller in the donors than that of the V3 region sequence, indicating selection of V3 at transmission. In these transmission cases, the effects of an intravenous inoculation of a small quantity of blood containing predominantly SI V3 sequences (6 of 8 clonal sequences) were compared with those of an intramuscular inoculation of a large quantity of blood containing predominantly NSI viruses (14 of 16 clonal sequences). Both SI and NSI V3 regions were demonstrated to be phenotypic expressions of genetically related viral strains. The inoculation of the predominantly SI virus population resulted in the persistence of an SI virus population in the recipient and a rapid CD4+ T-cell decline. The inoculation of the predominantly NSI population resulted in a selective amplification of SI viruses before seroconversion, followed by a suppression of SI viruses at seroconversion and a rapid decline of CD4+ T-cell numbers. These data suggest that the suppression of SI viruses can be accomplished following the development of HIV-specific immunity and that the ability to suppress SI viruses does not prevent the development of immunodeficiency.
Improved Silica-Guanidiniumthiocyanate DNA Isolation Procedure Based on Selective Binding of Bovine Alpha-Casein to Silica Particles
DNA purified from clinical cerebrospinal fluid and urine specimens by a silica-guanidiniumthiocyanate procedure frequently contained an inhibitor(s) of DNA-processing enzymes which may have been introduced by the purification procedure itself. Inhibition could be relieved by the use of a novel lysis buffer containing alpha-casein. When the novel lysis buffer was used, alpha-casein was bound by the silica particles in the first step of the procedure and eluted together with DNA in the last step, after which it exerted its beneficial effects for DNA-processing enzymes. In the present study we have compared the novel lysis buffer with the previously described lysis buffer with respect to double-stranded DNA yield (which was nearly 100%) and the performance of DNA-processing enzymes.
Human Cytomegalovirus DNA in Plasma and Serum Specimens of Renal Transplant Recipients Is Highly Fragmented
Quantitation of cytomegalovirus (CMV) DNA in plasma and serum by PCR is increasingly used to identify patients at risk for developing CMV disease and to monitor the efficacy of antiviral therapy. Although CMV DNA levels are generally interpreted as viral loads, the exact nature of the viral DNA in these specimens is unknown. We studied the state of CMV DNA in plasma and serum specimens obtained from three renal transplant recipients at peak viral DNA levels during primary CMV infection. For this purpose, DNA isolated from these specimens was fractionated by size, and CMV DNA levels in the resulting DNA fractions were measured by quantitative PCR targeted at large (578-bp) and small (134-bp) amplicons. These experiments showed that the molecular sizes of DNA fragments from which CMV DNA is amplified were small (<2,000 bp), indicating that CMV DNA in plasma and serum is highly fragmented. Furthermore, CMV DNA levels were consistently higher when targeted at the smaller amplicon, providing additional evidence for the fragmentation of viral DNA. In conclusion, the first results with three patients have shown that CMV DNA in plasma and serum is highly fragmented and does not necessarily reflect the amount of infectious virus. These observations have potential consequences for understanding CMV pathogenesis and interpreting CMV DNA levels in individual patient management.Infection with cytomegalovirus (CMV) (human herpesvirus 5) is an important cause of morbidity and mortality in immunocompromised individuals, such as transplant recipients and AIDS patients. In the management of CMV infection, preemptive treatment strategies, aimed at preventing CMV disease in high-risk patients, are receiving increasing attention. For the benefit of such strategies, quantitative detection of CMV DNA in the blood compartment by PCR is increasingly used to identify patients at risk for CMV disease. In addition, measurements of viral DNA load may be important for monitoring the efficacy of antiviral treatment and predicting the development of drug resistance (3,22,27).The genome of human CMV consists of a large (about 230,000-bp) double-stranded linear DNA molecule which is encapsidated within a double protein shell and a lipid envelope (24). Most of the CMV DNA in the blood compartment is present in abortively infected polymorphonuclear leukocytes (4,12,16,26); less DNA is found in peripheral blood mononuclear cells, part of which, upon differentiation into macrophages, support viral replication (12,26,28). In addition, circulating, productively infected endothelial cells may be a source of CMV DNA (16, 18). CMV DNA can also be detected in serum and plasma, which are convenient specimens for CMV DNA load measurement (10,15,19,29). In recent years, many studies on the qualitative and quantitative detection of CMV DNA in these specimens have been reported, which generally show that levels of CMV DNA found in plasma or serum are significantly lower than those found in white blood cells (4,5,13,15,33).At present, it is unclear whether CMV ...
Performance of the New Bayer VERSANT HCV RNA 3.0 Assay for Quantitation of Hepatitis C Virus RNA in Plasma and Serum: Conversion to International Units and Comparison with the Roche COBAS Amplicor HCV Monitor, Version 2.0, Assay
We have evaluated the VERSANT HCV RNA 3.0. Assay (HCV 3.0 bDNA assay) (Bayer Diagnostics, Berkeley, Calif.), which is an improved signal amplification procedure for the HCV 2.0 bDNA assay for the quantitation of hepatitis C virus (HCV) RNA in serum or plasma of HCV-infected individuals. The HCV 3.0 bDNA assay has a linear dynamic range of 2.5 ؋ 10 3 to 4.0 ؋ 10 7 HCV RNA copies per ml (c/ml). The performance of the HCV 3.0 bDNA assay was evaluated using three different test panels. An overall specificity of 96.8% relative to the detection limit of the HCV 3.0 bDNA assay was found. The intra-and interrun reproducibilities for both the dilution panel and the NAP (AcroMetrix, Benicia, Calif.) panel were consistent with coefficients of variation of less than 9%. Quantitation with the HCV 3.0 bDNA assay was linear over the entire range of both panels (ranges of 4.4 ؋ 10 3 to 3.5 ؋ 10 6 c/ml and 5 ؋ 10 3 to 2 ؋ 10 6 IU/ml, respectively), with correlation coefficients of 0.999, slopes close to one, and intercepts close to zero.
BackgroundGastrointestinal symptoms, in particular diarrhoea, are common in non-treated HIV-1 infected individuals. Although various enteric pathogens have been implicated, the aetiology of diarrhoea remains unexplained in a large proportion of HIV-1 infected patients. Our aim is to identify the cause of diarrhoea for patients that remain negative in routine diagnostics.MethodsIn this study stool samples of 196 HIV-1 infected persons, including 29 persons with diarrhoea, were examined for enteropathogens and HIV-1. A search for unknown and unexpected viruses was performed using virus discovery cDNA-AFLP combined with Roche-454 sequencing (VIDISCA-454).ResultsHIV-1 RNA was detected in stool of 19 patients with diarrhoea (66%) compared to 75 patients (45%) without diarrhoea. In 19 of the 29 diarrhoea cases a known enteropathogen could be identified (66%). Next to these known causative agents, a range of recently identified viruses was identified via VIDISCA-454: cosavirus, Aichi virus, human gyrovirus, and non-A non-B hepatitis virus. Moreover, a novel virus was detected which was named immunodeficiency-associated stool virus (IASvirus). However, PCR based screening for these viruses showed that none of these novel viruses was associated with diarrhoea. Notably, among the 34% enteropathogen-negative cases, HIV-1 RNA shedding in stool was more frequently observed (80%) compared to enteropathogen-positive cases (47%), indicating that HIV-1 itself is the most likely candidate to be involved in diarrhoea.ConclusionUnexplained diarrhoea in HIV-1 infected patients is probably not caused by recently described or previously unknown pathogens, but it is more likely that HIV-1 itself plays a role in intestinal mucosal abnormalities which leads to diarrhoea.
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