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.

Susceptibility of coxsackievirus B3 laboratory strains and clinical isolates to the capsid function inhibitor pleconaril: antiviral studies with virus chimeras demonstrate the crucial role of amino acid 1092 in treatment.

OBJECTIVES: At present, most promising compounds to treat enterovirus-induced diseases are broad-spectrum capsid function inhibitors which bind into a hydrophobic pocket in viral capsid protein 1 (VP1). Coxsackievirus B3 (CVB3) Nancy was the only prototypic enterovirus strain shown to be pleconaril-resistant. This study was designed to better understand the polymorphism of the hydrophobic pocket in CVB3 laboratory strains and clinical isolates and its implications for treatment with the capsid function inhibitor pleconaril. METHODS: Pleconaril susceptibility was determined in cytopathic effect-inhibitory, plaque reduction or virus yield assays. Sequence analysis of the genome region coding for VP1 and/or subsequent alignment of amino acids lining the hydrophobic pocket of five CVB3 laboratory strains and 20 clinical isolates were carried out. Virus chimeras and computational analysis were used to prove the role of amino acid 1092. RESULTS AND CONCLUSIONS: Despite high conservation of pocket amino acids, polymorphism was detected at positions 1092, 1094 and 1180. Neither Pro-1094-->Thr nor Val-1180-->Ile altered efficacy of pleconaril treatment. But the amino acid at position 1092 was strongly associated with susceptibility of CVB3 to the capsid inhibitor. Whereas leucine was involved in resistance, isoleucine and valine were detected in pleconaril-susceptible CVB3. Results from antiviral assays with hybrid viruses demonstrate the crucial role of amino acid 1092 in pleconaril susceptibility. A resistant cDNA-generated CVB3 became pleconaril-susceptible after accepting parts from the genome region encoding Ile-1092 into its capsid. Computational analysis suggests that conformational changes in the hydrophobic pocket occur when leucine is substituted for isoleucine or valine and that this change leads to susceptibility to pleconaril.

A new ultrasensitive way to circumvent PCR-based allele distinction: direct probing of unamplified genomic DNA by solution-phase hybridization using two-color fluorescence cross-correlation spectroscopy.

Single-molecule fluorescence methods enable a new class of nucleic acid assays to be performed that are not possible with PCR-based methods. In this basic study, the methylene tetrahydrofolate reductase (MTHFR)-genotypes (normal, homozygous mutated, as well as heterozygous mutated) were directly detected for the first time onto unamplified double-stranded genomic DNA in solution down to femtomolar allele concentrations (10(-15) M) in a homogeneous assay format. This was accomplished by taking advantage of the decrease by a factor of 40 to 100 in fluorescence background signals of the non-bound nonlinear hybridization probes in two colors and two-color fluorescence cross-correlation spectroscopy. The designed 'intelligent' probes contained the built-in 5'-fluorescent dyes rhodamine green and Alexa633, respectively, and the 3'-non-fluorescent quenchers BHQ1 and BHQ3, respectively, with perfectly matched spectral overlaps for both dye-quencher combinations. Upon binding of two appropriate probes that were sequence-specific for the genotype, the steady-state fluorescence in two colors increased by about two orders of magnitude. The obtained allele sensitivity of femtomolar and the specificity of the described molecular interactions allow PCR-based allele distinction to be circumvented. Furthermore, the results present an alternative to existing hybridization approaches that are currently used with and without amplification at the 'many-molecule' level and the 'single-molecule' level.

Enhancing sensitivity of human herpes virus diagnosis with DNA microarrays using dendrimers.

DNA microarray technology has become a promising new tool for the detection and identification of viral pathogens in human plasma and cell cultures. For exploration of this technology, we have developed DNA microarrays that encode capture oligonucleotide probes for different human herpes viruses: herpes simplex virus (HSV) HSV-1, HSV-2, varicella zoster virus (VZV), Epstein-Barr virus (EBV), cytomegalovirus (CMV), and HHV-6. The on-chip hybridization is accomplished with the PCR amplicons of the respective human herpes virus types. In this original article, we attached multiple Cy3-fluorophores to the branched 5' ends of the labeling oligonucleotide primers. For the first time, we experimentally demonstrated that the self-designed, knowledge-based, and focused microarrays specifically hybridized to fluorophore-labeled pathogenic DNAs using dendrimer technology. The fluorescence signal enhancement via the dendrimers was up to 30 times compared with the quenched single Cy3-fluorophore-labeled HSV-1 DNA. The on-chip signal-amplifying effect depended upon the number of branches and the concentration of fluorophore-labeled pathogenic DNAs. Treblers were superior to doublers, as trebler-labeled nucleic acids had fluorescence-signal-enhancing effects over a broad range of labeled DNA concentrations exemplified for the quenched single Cy3-fluorophore-labeled HSV-1 and non-quenched single Cy3-fluorophore-labeled CMV DNAs.

Detection of multiple human herpes viruses by DNA microarray technology.

BACKGROUND: The detailed characterization of virus DNA is a challenge, and the genotyping that has been achieved to date has only been possible because researchers have sent a great deal of time and effort to do so. Instead of the simultaneous detection of hundreds of viruses on a single high-density DNA-chip at very high costs per chip, we present here an alternative approach using a well-designed and tailored microarray which can establish whether or not a handful of viral genes are present in a clinical sample. METHODS: In this study we applied a new concept of microarray-based, optimized and robust biochemistry for molecular diagnostics of the herpesviruses. For comparison, all samples were genotyped using standard procedures. RESULTS: The biochemical procedure of a knowledge-based, low-density microarray was established based on the molecular diagnostics of human herpes viruses: herpes simplex virus (HSV) HSV-1, HSV-2, varicella zoster virus (VZV), Epstein-Barr virus (EBV), cytomegalovirus (CMV), and HHV-6. The study attempted to optimize parameters of microarray design, surface chemistry, oligonucleotide probe spotting, sample labeling and DNA hybridization to the developed DNA microarray. The results of 12 900 hybridization reactions on about 150 configured herpes virus microarrays showed that the established microarray-based typing procedure was reproducible, virus-specific and sufficiently sensitive with a lower limit of 100 viral copies per mL sample. CONCLUSIONS: The developed method utilizes low-fluorescence background coverslips, epoxy surface chemistry, standardized oligonucleotide probe spotting, PCR-labeling with Cy3 of isolated DNA, array hybridization, and detecting of specific spot fluorescence by an automatic microarray reader. We expect the configured microarray approach to be the method for high-throughput associated studies on human herpes viruses.

Specifically associated PCR products probed by coincident detection of two-color cross-correlated fluorescence intensities in human gene polymorphisms of methylene tetrahydrofolate reductase at site C677T: a novel measurement approach without follow-up mathematical analysis.

Whole blood samples of known methylene tetrahydrofolate reductase (MTHFR) genotypes from 24 individuals were examined at site C677T. Their amplified DNA products were assessed by two-color fluorescence cross-correlation measurements and agarose gel electrophoresis/capillary gel electrophoresis. DNA subpopulations were identified which were not associated with the proper genotype by primer combinations and cycling conditions called multiplexes. We confirmed that DNA analysis by two-color fluorescence cross-correlation measurements allowed the detection of fluorescence signals specifically associated with the proper genotypes in a mixture of amplified nontarget DNA molecules without DNA sizing. The measurement approach does not require complex, follow-up mathematical analysis and is applicable to any single nucleotide polymorphisms. The simple immunogenetic model showed how the approach works to reveal specific DNA target by preventing detection of nontarget DNA. Under those experimental conditions, a new ultrasensitive, and specific method for clinical immunologists is born.

Virus diagnostics on microarrays.

Whereas the majority of microarray applications still deal with expression analysis for gathering information about levels of gene products at certain cell states, other approaches simply ask the question whether particular genes, which are usually indicative for particular microorganisms and pathogens, are present in a sample or not. Investigations that are more detailed try to evaluate the presence of particular subtypes of a given pathogen. The combination of microarray technology and virus diagnostics promises to generate an ideal platform for fast, sensitive, specific, and parallelized virus diagnostics. Performing virus diagnostics on microarrays, however, requires other basic techniques to be optimized. This is necessary in order to obtain unambiguous and reproducible results, which are compatible with the needs for clinical routine. Parameters that have to be considered include supports, coupling chemistry, chemical oligonucleotide synthesis, signal enhancement strategies, and optimal coordination of PCR reactions, hybridizations, and signal detection, as well as interpretation strategies. Finally, considerations should be given to economic aspects, one chip-one patient strategies and low integrated arrays as a custom-tailored way to fast and accurate diagnostic tools.

C677T single nucleotide polymorphisms of the human methylene tetrahydrofolate reductase and specific identification : a novel strategy using two-color cross-correlation fluorescence spectroscopy.

BACKGROUND: A methylene tetrahydrofolate reductase (MTHFR) deficiency at site C677T renders the enzyme thermolabile and consequently represents a risk factor for vascular disease, neural tube defects, preeclampsia, and thrombosis. Highly specific identification techniques for genotyping are mandatory to give guidance for the diagnosis and monitoring of this deficiency. METHODS: A new approach for performing genotyping has been introduced with the identification of single nucleotide polymorphisms of the human MTHFR. It is based on PCR followed by two-color cross-correlation fluorescence spectroscopy (FCS). Experiments were carried out with green- and red-tagged allele-specific primers, which were fully compatible with the two-color fluorescence cross-correlation setup at 488 nm and 633 nm excitation wavelengths. RESULTS: The measured data of the amplification mixes (tubes) were normalized as the maximum correlation amplitude of each tube. Correlated and uncorrelated data were optically separated in the amplification mixes by their characteristic correlation times, which significantly differed from each other. The correlated data were generated in the presence of the proper mutated genotype template, whereas uncorrelated data were due to the absence of the proper genotype template. Furthermore, the specific association of the two-color fluorescence correlated signals with the target DNA was experimentally proven. Using this novel two-color cross-correlation approach, the MTHFR genotypes, which were determined in 21 clinical samples, showed concordance with methods involving a PCR-based assay with hexachloro-6-carboxy-fluorescein (HEX)- and 6-carboxy-fluorescein (FAM)-tagged allele-specific primers and a subsequent separation step with capillary electrophoresis, yet are simpler to perform. There was no evidence of a central trend of false-positive or false-negative results. We demonstrated how the novel, ultrasensitive typing system could be applied to studies where researchers are trying to perfect their assays and are often working with the unknown, or application to problematic assays in a clinical environment for those involved in molecular diagnosis. CONCLUSIONS: We present an alternative method to those commonly used in genotyping. Two-color cross-correlation FCS allows the detection of the fluorescence signals specifically associated with the heterozygous mutated, the homozygous mutated, and normal individuals, as exemplified in this study. The presence of nonspecific amplification products, which interfere with subsequent DNA analysis, could therefore highlight the need for two-color cross-correlation FCS as a means of discriminating between specific association of the fluorescence signals with the target DNA and DNA not related to the target.

Sequencing of porcine enterovirus groups II and III reveals unique features of both virus groups.

The molecular classification of the porcine enterovirus (PEV) groups II and III was investigated. The sequence of the almost complete PEV-8 (group II) genome reveals that this virus has unique L and 2A gene regions. A reclassification of this group into a new picornavirus genus is suggested. PEV group III viruses are typical enteroviruses. They differ from other enteroviruses by a prolonged stem-loop D of the 5'-cloverleaf structure.

Mouse heart Na+ channels: primary structure and function of two isoforms and alternatively spliced variants.

We isolated two full-length cDNA clones from the adult murine heart that encode two different voltage-gated Na+ channels: mH1 and mH2. Sequence comparisons indicated that mH1 is highly homologous to rat SCN5A, whereas mH2 is highly homologous to SCN4A, expressed in rat skeletal muscle. Electrophysiological properties of mH1 channels strongly resembled the tetrodotoxin (TTX)-resistant Na+ current of mouse ventricular cells, whereas mH2 channels activated at more positive potentials and were highly sensitive to TTX [50% inhibitory constant (IC50) = 11 nM]. We found that mH2 is not expressed in cardiac cells of neonatal mice, but appears to be upregulated during the development. Besides these Na+ channel isoforms, we also detected two alternatively spliced mH1 variants that were characterized by deletions within the sequence coding for the intracellular loop between domains II and III. One of the shortened channels, mH1-2, developed Na+ currents indistinguishable from those of mH1. The other splice variant (mH1-3) did not form functional channels. Quantitative reverse transcriptase-polymerase chain reaction indicated that RNA preparations of the adult mouse heart contain 54% mH1, 25% mH1-2, 16% mH2, and 5% mH1-3. Conclusively, mH1 generates the main portion of the mouse cardiac TTX-resistant Na+ current and mH2 is a candidate for TTX-sensitive currents previously described in adult cardiomyocytes. Furthermore, the presence of mH1-2 and mH1-3 transcripts indicates that alternative splicing plays a role in the regulation of functional Na+ channels in cardiomyocytes.