Development of a strand-specific RT-PCR based assay to detect the replicative form of hepatitis C virus RNA

Technique for strand-specific gene-expression analysis and monitoring of primer-independent cDNA synthesis in reverse transcription

Primer-independent cDNA synthesis during reverse transcription hinders quantitative analysis of bidirectional mRNA synthesis in eukaryotes as well as in cells infected with RNA viruses. We report a simple RT-PCR-based assay for strand-specific gene-expression analysis. By modifying the cDNA sequence during reverse transcription, the opposite strands of target sequences can be simultaneously detected by postamplification melting curve analysis and primer-initiated transcripts are readily distinguished from nonspecifically primed cDNA. We have utilized this technique to optimize the specificity of reverse transcription on a panel of 15 target genes. Primer-independent reverse transcription occurred for all target sequences when reverse transcription was performed at 42°C and accounted for 11%-57% of the final PCR amplification products. By raising the reaction temperature to 55°C, the specificity of reverse transcription could be increased without significant loss of sensitivity. We have also demonstrated the utility of this technique for analysis of (+) and (-) RNA synthesis of influenza A virus in infected cells. Thus, this technique represents a powerful tool for analysis of bidirectional RNA synthesis.

The specific infectivity of hepatitis C virus changes through its life cycle

Hepatitis C virus (HCV) causes liver diseases, such as hepatitis, liver cirrhosis, steatosis, and hepatocellular carcinoma. To understand the life cycle and pathogenesis of HCV, the one-step growth of HCV in a cell culture system was analyzed using a highly infectious variant of the JFH1 clone. The observed profiles of HCV RNA replication indicated that the synthesis of negative-strand RNAs occurred at 6 h (h) after infection, followed by the active synthesis of positive-strand RNAs. Our measurements of infectious virus production showed that the latent period of HCV was about 12 h. The specific infectivity of HCV particles (focus-forming unit per viral RNA molecule) secreted to the extracellular milieu early in infection was about 30-fold higher than that secreted later during infection. The buoyant densities of the infectious virion particles differed with the duration of infection, indicating changes in the compositions of the virion particles.

Experimental infection of the honeybee (Apis mellifera L.) with the chronic bee paralysis virus (CBPV): infectivity of naked CBPV RNAs

Chronic paralysis is an infectious and contagious disease of the honeybee (Apis mellifera L.) and is caused by the chronic bee paralysis virus (CBPV). This disease leads to death in adult bees and is therefore a serious threat for colony health. CBPV is a positive single-stranded RNA virus and its genome is composed of two RNA segments, RNA 1 and RNA 2, 3674 nt and 2305 nt, respectively. Although CBPV shares some characteristics with viruses classified into families Nodaviridae and Tombusviridae, it has not been assigned to any viral taxa yet. The characterisation of CBPV proteins and their functions are needed to better understand the mechanisms of CBPV infection. However, since honeybee cell lines are not yet available, experimental infection of adult bees is the only method currently available to propagate the virus. With the objective of studying CBPV proteins using the viral genome, we used experimental infection in adult bees to evaluate the infectivity of naked CBPV RNAs by direct inoculation. Our results demonstrated that an injection of naked RNAs, ranging from 10(9) to 10(10) CBPV copies, caused chronic paralysis. Bees inoculated with naked RNA showed chronic paralysis signs 5 days after inoculation. Moreover, injected RNAs replicated and generated viral particles. We therefore provide an in vivo experimental model that will be useful tool for further studies by using a reverse genetics system.

No evidence for translation of pog, a predicted overlapping gene of Solenopsis invicta virus 1

An overlapping open reading frame (ORF) with a potential to encode a functional protein has been identified within the 3'-proximal ORF of Solenopsis invicta virus 1 (SINV-1) and three bee viruses. This ORF has been referred to as predicted overlapping gene (pog). Protein motif searches of POG revealed weak relationships precluding assignment of a potential function. Neither a transcript nor a protein encoded by the pog ORF has been detected. However, recently, a protein encoded by the corresponding +1 overlapping ORF (termed ORFx) in the Israeli acute paralysis virus (IAPV) was demonstrated by recombinant means as well as in IAPV-infected honey bees. The objective of our study was to attempt to provide empirical evidence for the presence of a pog-derived protein from SINV-1-infected fire ants. A number of different laboratory and field SINV-1-infected Solenopsis invicta preparations were examined by western blotting for the presence of a POG protein sequence. In every case, these preparations failed to yield any detectable bands when probed with a polyclonal antibody preparation raised to a portion of the pog predicted protein sequence. Although impossible to prove a negative result, proper controls used in these studies suggested that the pog ORF is not translated into a functional protein in SINV-1.

Metatranscriptomics and pyrosequencing facilitate discovery of potential viral natural enemies of the invasive Caribbean crazy ant, Nylanderia pubens

BACKGROUND

Nylanderia pubens (Forel) is an invasive ant species that in recent years has developed into a serious nuisance problem in the Caribbean and United States. A rapidly expanding range, explosive localized population growth, and control difficulties have elevated this ant to pest status. Professional entomologists and the pest control industry in the United States are urgently trying to understand its biology and develop effective control methods. Currently, no known biological-based control agents are available for use in controlling N. pubens.

METHODOLOGY AND PRINCIPAL FINDINGS

Metagenomics and pyrosequencing techniques were employed to examine the transcriptome of field-collected N. pubens colonies in an effort to identify virus infections with potential to serve as control agents against this pest ant. Pyrosequencing (454-platform) of a non-normalized N. pubens expression library generated 1,306,177 raw sequence reads comprising 450 Mbp. Assembly resulted in generation of 59,017 non-redundant sequences, including 27,348 contigs and 31,669 singlets. BLAST analysis of these non-redundant sequences identified 51 of potential viral origin. Additional analyses winnowed this list of potential viruses to three that appear to replicate in N. pubens.

CONCLUSIONS

Pyrosequencing the transcriptome of field-collected samples of N. pubens has identified at least three sequences that are likely of viral origin and, in which, N. pubens serves as host. In addition, the N. pubens transcriptome provides a genetic resource for the scientific community which is especially important at this early stage of developing a knowledgebase for this new pest.

The complete genome sequence of a single-stranded RNA virus from the tarnished plant bug, Lygus lineolaris (Palisot de Beauvois)

The complete genome sequence of a single-stranded RNA virus infecting the tarnished plant bug, Lygus lineolaris (Palisot de Beauvois), was identified by sequencing cDNA prepared from insects collected from the Mississippi Delta. The 9655 nucleotide positive-sense single-stranded RNA genome of the L. lineolaris single-stranded RNA virus (LyLV-1) contained a single open reading frame of 8958 nucleotides encoding a 2986 amino acid genome polypeptide. The open reading frame was flanked by untranslated regions of 603 and 69 nucleotides at the 5'- and 3'- ends of the genome, respectively. Database searches and homology based modeling was used to identify four capsid proteins (VP1-VP4), helicase/AAA-ATPase, cysteine protease (C3P), protease 2A, and the RNA-directed RNA polymerase (RdRp). In addition, a region with weak similarity to the eukaryotic structural maintenance of chromosome (SMC) domain was identified near the amino-terminal of the polyprotein and adjacent to the VP1 domain. The amino acid sequence of LyLV-1 was approximately 44.4% similar to that of sacbrood virus (SBV) of the honey bee. The genomic organization of both viruses showed remarkable similarity with the exception of highly divergent amino acid regions flanking fairly conserved structural and non-structural polypeptide regions. High similarity to the SBV genome and similarities in the genome organization and amino acid sequence with the viruses of the family Iflaviridae suggested that LyLV-1 was a novel member of this family. Virus particles were 39 nm in diameter and appeared to transmit vertically via eggs. Although this virus may only cause covert infections under normal conditions, the potential for using this virus in biological control of L. lineolaris is discussed.

Effects of invasive parasites on bumble bee declines

Bumble bees are a group of pollinators that are both ecologically and economically important and declining worldwide. Numerous mechanisms could be behind this decline, and the spread of parasites from commercial colonies into wild populations has been implicated recently in North America. Commercial breeding may lead to declines because commercial colonies may have high parasite loads, which can lead to colonization of native bumble bee populations; commercial rearing may allow higher parasite virulence to evolve; and global movement of commercial colonies may disrupt spatial patterns in local adaptation between hosts and parasites. We assessed parasite virulence, transmission mode, and infectivity. Microparasites and so-called honey bee viruses may pose the greatest threat to native bumble bee populations because certain risk factors are present; for example, the probability of horizontal transmission of the trypanosome parasite Crithidia bombi is high. The microsporidian parasite Nosema bombi may play a role in declines of bumble bees in the United States. Preliminary indications that C. bombi and the neogregarine Apicystis bombi may not be native in parts of South America. We suggest that the development of molecular screening protocols, thorough sanitation efforts, and cooperation among nongovernmental organizations, governments, and commercial breeders might immediately mitigate these threats.

Interplay between NS3 protease and human La protein regulates translation-replication switch of Hepatitis C virus

HCV NS3 protein plays a central role in viral polyprotein processing and RNA replication. We demonstrate that the NS3 protease (NS3^pro) domain alone can specifically bind to HCV-IRES RNA, predominantly in the SLIV region. The cleavage activity of the NS3 protease domain is reduced upon HCV-RNA binding. More importantly, NS3^pro binding to the SLIV hinders the interaction of La protein, a cellular IRES-trans acting factor required for HCV IRES-mediated translation, resulting in inhibition of HCV-IRES activity. Although overexpression of both NS3^pro as well as the full length NS3 protein decreased the level of HCV IRES mediated translation, replication of HCV replicon RNA was enhanced significantly. These observations suggest that the NS3^pro binding to HCV IRES reduces translation in favor of RNA replication. The competition between the host factor (La) and the viral protein (NS3) for binding to HCV IRES might regulate the molecular switch from translation to replication of HCV.

Temporal analysis of the honey bee microbiome reveals four novel viruses and seasonal prevalence of known viruses, Nosema, and Crithidia

Honey bees (Apis mellifera) play a critical role in global food production as pollinators of numerous crops. Recently, honey bee populations in the United States, Canada, and Europe have suffered an unexplained increase in annual losses due to a phenomenon known as Colony Collapse Disorder (CCD). Epidemiological analysis of CCD is confounded by a relative dearth of bee pathogen field studies. To identify what constitutes an abnormal pathophysiological condition in a honey bee colony, it is critical to have characterized the spectrum of exogenous infectious agents in healthy hives over time. We conducted a prospective study of a large scale migratory bee keeping operation using high-frequency sampling paired with comprehensive molecular detection methods, including a custom microarray, qPCR, and ultra deep sequencing. We established seasonal incidence and abundance of known viruses, Nosema sp., Crithidia mellificae, and bacteria. Ultra deep sequence analysis further identified four novel RNA viruses, two of which were the most abundant observed components of the honey bee microbiome (∼10(11) viruses per honey bee). Our results demonstrate episodic viral incidence and distinct pathogen patterns between summer and winter time-points. Peak infection of common honey bee viruses and Nosema occurred in the summer, whereas levels of the trypanosomatid Crithidia mellificae and Lake Sinai virus 2, a novel virus, peaked in January.

Strand-specific PCR of UV radiation-damaged genomic DNA revealed an essential role of DNA-PKcs in the transcription-coupled repair

Background

In eukaryotic cells, there are two sub-pathways of nucleotide excision repair (NER), the global genome (gg) NER and the transcription-coupled repair (TCR). TCR can preferentially remove the bulky DNA lesions located at the transcribed strand of a transcriptional active gene more rapidly than those at the untranscribed strand or overall genomic DNA. This strand-specific repair in a suitable restriction fragment is usually determined by alkaline gel electrophoresis followed by Southern blotting transfer and hybridization with an indirect end-labeled single-stranded probe. Here we describe a new method of TCR assay based on strand-specific-PCR (SS-PCR). Using this method, we have investigated the role of DNA-dependent protein kinase catalytic subunit (DNA-PKcs), a member of the phosphatidylinositol 3-kinase-related protein kinases (PIKK) family, in the TCR pathway of UV-induced DNA damage.

Results

Although depletion of DNA-PKcs sensitized HeLa cells to UV radiation, it did not affect the ggNER efficiency of UV-induced cyclobutane pyrimidine dimers (CPD) damage. We postulated that DNA-PKcs may involve in the TCR process. To test this hypothesis, we have firstly developed a novel method of TCR assay based on the strand-specific PCR technology with a set of smart primers, which allows the strand-specific amplification of a restricted gene fragment of UV radiation-damaged genomic DNA in mammalian cells. Using this new method, we confirmed that siRNA-mediated downregulation of Cockayne syndrome B resulted in a deficiency of TCR of the UV-damaged dihydrofolate reductase (DHFR) gene. In addition, DMSO-induced silencing of the c-myc gene led to a decreased TCR efficiency of UV radiation-damaged c-myc gene in HL60 cells. On the basis of the above methodology verification, we found that the depletion of DNA-PKcs mediated by siRNA significantly decreased the TCR capacity of repairing the UV-induced CPDs damage in DHFR gene in HeLa cells, indicating that DNA-PKcs may also be involved in the TCR pathway of DNA damage repair. By means of immunoprecipitation and MALDI-TOF-Mass spectrometric analysis, we have revealed the interaction of DNA-PKcs and cyclin T2, which is a subunit of the human transcription elongation factor (P-TEFb). While the P-TEFb complex can phosphorylate the serine 2 of the carboxyl-terminal domain (CTD) of RNA polymerase II and promote transcription elongation.

Conclusion

A new method of TCR assay was developed based the strand-specific-PCR (SS-PCR). Our data suggest that DNA-PKcs plays a role in the TCR pathway of UV-damaged DNA. One possible mechanistic hypothesis is that DNA-PKcs may function through associating with CyclinT2/CDK9 (P-TEFb) to modulate the activity of RNA Pol II, which has already been identified as a key molecule recognizing and initializing TCR.

Strand-specific real-time RT-PCR for distinguishing influenza vRNA, cRNA, and mRNA

Real-time RT-PCR is used to quantify individual influenza viral RNAs. However, conventional real-time RT-PCR, using strand-specific primers, has been shown to produce not only the anticipated strand-specific products, but also substantial amounts of non-strand-specific products, indicating lack of specificity. Therefore, in this study, a novel strand-specific real-time RT-PCR method was established to quantify the three types of influenza viral RNA (vRNA, cRNA, and mRNA) separately. This method is based on reverse transcription using tagged primers to add a 'tag' sequence at the 5' end and the hot-start method. Real-time PCR using the 'tag' portion as the forward primer and a segment-specific reverse primer ensured the specificity for quantifying the three types of RNA. Using this method, specific target RNA was detected at 100-100,000-folds higher level than other types of RNA. This method was also used to evaluate the vRNA, cRNA, and mRNA levels of segments 5 and 6 in MDCK cells infected with influenza A virus at different time point post-infections. The cRNA level was 1/10 to 1/100 lower than that of the vRNA and mRNA. Moreover, different dynamics of vRNA, cRNA, and mRNA synthesis were observed; the copy number of the vRNA gradually increased throughout the infection, the cRNA increased and then plateaued, while the mRNA increased and then decreased. This novel method thus provides data critical for understanding the influenza virus life cycle, including transcription, replication, and genome incorporation into virions.

Detection of replicating negative-sense RNAs in CaCo-2 cells infected with human astrovirus

Human astrovirus (HAstV) is the second most important cause of viral diarrhea and acute gastroenteritis in infants under five. However, determination of the infectivity of clinical isolates is difficult, and the replication cycle of HAstV is not yet fully understood. In this study, it was attempted to detect negative-sense (-)RNAs generated during the replication of RNA viruses. We used clinical isolates of HAstV to infect CaCo-2 cells. Reverse transcription using only a sense primer followed by PCR using both sense and antisense primers showed that (-)RNAs were first detected in CaCo-2 cells between 9 and 12 h postinfection (p.i.). However, these (-)RNAs were not detected when cells were treated with the protein synthesis inhibitor cycloheximide during HAstV infection. Next, RT with only an antisense primer followed by PCR was performed to detect (+)RNA of HAstVs after production of (-)RNAs during replication. RT-PCR results using the antisense primer revealed that the amount of (+)RNA began to increase starting 9 h p.i., indicating an accumulation of the newly synthesized (+)RNA genome. Cycloheximide was observed to abrogate the increase of newly made (+)RNA during HAstV infection. In conclusion, the use of sense or antisense primers during the RT reaction together with cycloheximide enabled us to quantitatively detect (-)RNAs, and this proved to be an useful tool in understanding the replication cycle of HAstV.

Real-time RT-qPCR assay for the analysis of human influenza A virus transcription and replication dynamics

A quantitative real-time reverse transcriptase PCR (RT-qPCR) assay was developed for the analysis of influenza A virus transcription and replication dynamics in mammalian cell culture. The assay is based on a polarity- and sequence-specific reverse transcription used to distinguish specifically between viral genomes (vRNA(-)), replicative intermediates (cRNA(+)) and viral messenger RNAs (vmRNA(+)) of segments 4 (HA), 6 (NA), 7 (M) and 8 (NS) during the life cycle of influenza virus. Synthetic viral RNAs used as reference standards for validation and quantitation were prepared for each viral RNA type and segment. Assay validation demonstrated linearity over five orders of magnitude, sensitivity of 1.0 x 10(3) to 8.9 x 10(3) of viral RNA molecules, repeatability and reproducibility of less than 0.8-3.1% CV (coefficient of variation). Dynamics of influenza A virus infection in adherent MDCK cells, a substrate considered for human influenza vaccine manufacturing, were analyzed. In general, mainly vmRNA(+) were synthesized during early phases of infection at about 0.6 hpi, followed immediately by cRNA(+) synthesis and after a short delay of about 1.9 hpi viral genome replication could be detected. The vRNA(-)s were synthesized in equimolar amounts and similar dynamics whereas preferential synthesis of NS1 vmRNA(+) in early transcription phases and a delay for M1 vmRNA(+) was found.

Vesicular stomatitis virus genomic RNA persists in vivo in the absence of viral replication

Our previous studies using intranasal inoculation of mice with vesicular stomatitis virus (VSV) vaccine vectors showed persistence of vector genomic RNA (gRNA) for at least 60 days in lymph nodes in the absence of detectable infectious virus. Here we show high-level concentration of virus and gRNA in lymph nodes after intramuscular inoculation of mice with attenuated or single-cycle VSV vectors as well as long-term persistence of gRNA in the lymph nodes. To determine if the persistence of gRNA was due to ongoing viral replication, we developed a tagged-primer approach that was critical for detection of VSV mRNA specifically. Our results show that VSV gRNA persists long-term in the lymph nodes while VSV mRNA is present only transiently. Because VSV transcription is required for replication, our results indicate that persistence of gRNA does not result from continuing viral replication. We also performed macrophage depletion studies that are consistent with initial trapping of VSV gRNA largely in lymph node macrophages and subsequent persistence elsewhere in the lymph node.

Molecular approaches to the analysis of deformed wing virus replication and pathogenesis in the honey bee, Apis mellifera

Background

For years, the understanding of the pathogenetic mechanisms that underlie honey bee viral diseases has been severely hindered because of the lack of a cell culture system for virus propagation. As a result, it is very imperative to develop new methods that would permit the in vitro pathogenesis study of honey bee viruses. The identification of virus replication is an important step towards the understanding of the pathogenesis process of viruses in their respective hosts. In the present study, we developed a strand-specific RT-PCR-based method for analysis of Deformed Wing Virus (DWV) replication in honey bees and in honey bee parasitic mites, Varroa Destructor.

Results

The results shows that the method developed in our study allows reliable identification of the virus replication and solves the problem of falsely-primed cDNA amplifications that commonly exists in the current system. Using TaqMan real-time quantitative RT-PCR incorporated with biotinylated primers and magnetic beads purification step, we characterized the replication and tissue tropism of DWV infection in honey bees. We provide evidence for DWV replication in the tissues of wings, head, thorax, legs, hemolymph, and gut of honey bees and also in Varroa mites.

Conclusion

The strategy reported in the present study forms a model system for studying bee virus replication, pathogenesis and immunity. This study should be a significant contribution to the goal of achieving a better understanding of virus pathogenesis in honey bees and to the design of appropriate control measures for bee populations at risk to virus infections.

Self-priming of reverse transcriptase impairs strand-specific detection of dengue virus RNA

Dengue virus infection is the most frequent arthropod-borne infection affecting humans in the world. Our understanding of the pathophysiological events leading to mild or severe outcomes of the disease remains limited by the fact that viral target cells in the human body are poorly characterized. One of the most sensitive strategies for detecting cells supporting active replication of this positive-strand RNA virus is the search for the replicative intermediate, an antigenome of negative polarity, by RT-PCR. However, a phenomenon described as 'false priming' of the reverse transcriptase (RT) prevents strand-specific detection. The results of the current study showed that this event corresponds to cDNA synthesis that is independent of any primer addition. This property was general to all RNAs tested and was not associated with small free nucleic acids, such as tRNAs and microRNAs. Rather, it corresponded to initiation of cDNA synthesis from the 3' end of the RNA template, and a model is proposed in which the template RNA snaps back upon itself and creates a transient RNA primer suitable for the RT. Such a property would explain why many assays proposed for detection of a replicative intermediate are not specific, and may help in the development of a molecular biology protocol that could allow replication studies of RNA viruses of human interest, such as dengue virus, hepatitis C virus and enteroviruses.

Human liver transplantation as a model to study hepatitis C virus pathogenesis

Hepatitis C is a leading etiology of liver cancer and a leading reason for liver transplantation. Although new therapies have improved the rates of sustained response, a large proportion of patients (approximately 50%) fail to respond to antiviral treatment, thus remaining at risk for disease progression. Although chimpanzees have been used to study hepatitis C virus biology and treatments, their cost is quite high, and their use is strictly regulated; indeed, the National Institutes of Health no longer supports the breeding of chimpanzees for study. The development of hepatitis C virus therapies has been hindered by the relative paucity of small animal models for studying hepatitis C virus pathogenesis. This review presents the strengths of human liver transplantation and highlights the advances derived from this model, including insights into viral kinetics and quasispecies, viral receptor binding and entry, and innate and adaptive immunity. Moreover, consideration is given to current and emerging antiviral therapeutic approaches based on translational research results.

Quantitation of replication of the HCV genome in human livers with end-stage cirrhosis by strand-specific real-time RT-PCR assays: methods and clinical relevance

HCV replicates in liver via an intermediate negative strand RNA. To study the relevance of HCV genome replication, quantitative strand-specific HCV real-time RT-PCR assays were developed and applied to livers explanted because of end-stage cirrhosis. The assays have broad ranges of determination and a high reproducibility and accuracy. Analysis of five different samples showed an even distribution of HCV genomes in four livers. Hepatic concentrations of positive (PS)- and negative (NS)-strand RNA did correlate with each other, with PS/NS ratios ranging between 3 and 340. Hepatic concentrations of HCV-PS or -NS RNA did not correlate with serum HCV-RNA levels or with genotypes. A high HCV envelope-2 protein expression correlated with a low NS concentration. HCV-PS and -NS levels, E2 protein expression and genotype did not correlate with biochemical tests or with histological changes in the explanted liver, but the ratio NS/PS, a marker of viral replication, correlated with the severity of the recurrent post-transplant hepatitis caused by HCV. This suggests the existence of an extra-hepatic location of HCV with comparable viral replication rate being responsible for the infection of the newly transplanted liver.

Multiplex detection of Solenopsis invicta viruses -1, -2, and -3

Multiplex reverse transcription and polymerase chain reaction (PCR) methods were developed to detect Solenopsis invicta viruses -1, -2, and -3 simultaneously in their host, the red imported fire ant, S. invicta. cDNA synthesis was conducted in a single reaction containing an oligonucleotide primer specific for each virus. Multiplex PCR was subsequently conducted with oligonucleotide primer pairs specific for each virus. The method was specific and sensitive, capable of detecting as few as 500 copies of the viral genomes consistently. Specificity was verified by PCR and amplicon sequencing. The method was evaluated against field-collected samples of ant workers from colonies in Argentina (n=135 ant colonies) and the United States (n=172 ant colonies). The prevalence of each virus in fire ant colonies varied considerably from site to site. A number of colonies exhibited multiple virus infections. However, the multiple SINV infection rate was lower than for single infections. Comparison of viral infection prevalence between S. invicta colonies in Argentina and the U.S. showed no statistical differences, regardless of infection category. This method is anticipated to facilitate epidemiological and related studies concerning the S. invicta viruses in fire ants.

Deformed wing virus: replication and viral load in mites (Varroa destructor)

Deformed wing virus (DWV) normally causes covert infections but can have devastating effects on bees by inducing morphological deformity or even death when transmitted by the ectoparasitic mite Varroa destructor. In order to determine the role of V. destructor in the development of crippled wings, we analysed individual mites for the presence and replication of DWV. The results supported the correlation between viral replication in mites and morphologically deformed bees. Quantification of viral genome equivalents revealed that mites capable of inducing an overt DWV infection contained 10(10)-10(12) genome equivalents per mite. In contrast, mites which could not induce crippled wings contained a maximum of only 10(8) viral genome equivalents per mite. We conclude that the development of crippled wings not only depends on DWV transmission by V. destructor but also on viral replication in V. destructor and on the DWV titre in the parasitizing mites.

Detection of hepatitis C virus in thyroid tissue from patients with chronic HCV infection

Thyroid dysfunctions are common in chronic hepatitis C virus (HCV) infection. HCV-RNA has been detected by reverse-transcription polymerase chain reaction (PCR) in thyroid from HCV infected patients with acquired immunodeficiency syndrome. However, morphological evidence of HCV replication in thyroid cells from immune competent patients has not been provided. In situ hybridization and real-time-PCR were used to analyze HCV-RNA replication in thyroid tissue from 11 patients (3 anti-HCV, serum HCV-RNA positive; 8 anti-HCV negative). Genomic and antigenomic HCV-RNA was detected in the thyroid of the 3 anti-HCV positive patients at concentrations of 2.6 x 10(4), 1.7 x 10(4), and 8.6 x 10(3) copies/microg of total RNA (genomic) and 3.2 x 10(2), 4.3 x 10(3) and 2.9 x 10(2) HCV-RNA copies/microg of total RNA (antigenomic). No HCV-RNA was detected in the thyroid tissue of the 8 anti-HCV negative patients. Presence of genomic/antigenomic HCV-RNA in the 3 anti-HCV positive cases was confirmed by in situ hybridization. Signals were observed in the cytoplasm of the thyroid cells. In conclusion, the data obtained indicate that HCV may infect cells of the thyroid in immune competent patients with chronic HCV infection. The pathogenic implications of this finding merit further research.

Development of a Taqman RT-PCR assay for the detection and quantification of negatively stranded RNA of human enteroviruses: evidence for false-priming and improvement by tagged RT-PCR

Human enteroviruses are among the most common viruses infecting humans. These viruses are known to be able to infect a wide range of tissues and are believed to establish persistent infections. Enteroviruses are positive-sense single-stranded RNA viruses whose replication involves the synthesis of negative strand intermediates. Therefore, the specific detection of negatively stranded viral RNA in tissues or cells is a reliable marker of active enteroviral replication. The present report presents the development of a real-time RT-PCR allowing the specific detection and quantification of negatively stranded viral RNA. Since it was known that specific amplification of single-stranded RNA can be made difficult by false-priming events leading to false-positive or overestimated results, the assay was developed by using a tagged RT primer. This tagged RT-PCR was shown to be able to amplify specifically negative RNA of enteroviruses grown in cell cultures by preventing the amplification of cDNAs generated by false-priming.

Development and evaluation of a sensitive enzyme-linked oligonucleotide-sorbent assay for detection of polymerase chain reaction-amplified hepatitis C virus of genotypes 1-6

A high-throughput polymerase chain reaction (PCR)-based enzyme-linked oligonucleotide-sorbent assay (ELOSA) was developed for use in the diagnostic testing of serum from patients who may be infected with different hepatitis C virus (HCV) genotypes. Twelve genotype-specific 5'-aminated DNA-coated probes were designed based on the variable 5'-untranslated region sequences of the HCV genotypes 1-6. Using 100 clinical serum samples, the performance of the PCR-ELOSA method was compared with Roche's COBAS Amplicor HCV Monitor V2.0 assay and the VERSANT HCV genotype assay (LiPA), and the overall agreement was 99% at the level of HCV genotypes with a detection range of 2.0 x 10(2) to 1.0 x 10(7)IU/ml for PCR-ELOSA. The PCR-ELOSA was more comprehensive as demonstrated by the fact that approximately 20% of the samples with different subtypes could be discriminated by this method but not by LiPA. In addition, the PCR-ELOSA system showed high accuracy (CV<or=6.36%) and even higher reproducibility (CV<or=5.55%). Thus, this novel PCR-ELOSA system provides a sensitive and versatile alternative to current HCV detection assays.

Revisiting the Saccharomyces cerevisiae predicted ORFeome

Accurately defining the coding potential of an organism, i.e., all protein-encoding open reading frames (ORFs) or "ORFeome," is a prerequisite to fully understand its biology. ORFeome annotation involves iterative computational predictions from genome sequences combined with experimental verifications. Here we reexamine a set of Saccharomyces cerevisiae "orphan" ORFs recently removed from the original ORFeome annotation due to lack of conservation across evolutionarily related yeast species. We show that many orphan ORFs produce detectable transcripts and/or translated products in various functional genomics and proteomics experiments. By combining a naïve Bayes model that predicts the likelihood of an ORF to encode a functional product with experimental verification of strand-specific transcripts, we argue that orphan ORFs should still remain candidates for functional ORFs. In support of this model, interstrain intraspecies genome sequence variation is lower across orphan ORFs than in intergenic regions, indicating that orphan ORFs endure functional constraints and resist deleterious mutations. We conclude that ORFs should be evaluated based on multiple levels of evidence and not be removed from ORFeome annotation solely based on low sequence conservation in other species. Rather, such ORFs might be important for micro-evolutionary divergence between species.

Detection and quantitation of Solenopsis invicta virus-2 genomic and intermediary replicating viral RNA in fire ant workers and larvae

Quantitative real-time PCR (QPCR) was used to quantify the genome of Solenopsis invicta virus-2 (SINV-2) from infected individual ants of S. invicta. Strand-specific cDNA synthesis oligonucleotide primers and RNase digestion after cDNA synthesis allowed quantification of plus (genomic) and minus (replicative) strands of the SINV-2 genome. Both strands were detected in adult workers and larval fire ants indicating that the virus was replicating within the ant. The differences between the genomic to replicative strand ranged from 199-fold in larvae to 479-fold in workers with an average ratio of 339:1.

Analysis of foot-and-mouth disease virus replication using strand-specific quantitative RT-PCR

Foot-and-mouth disease virus (FMDV) is a positive-sense, single stranded RNA virus and its replication involves the synthesis of a negative strand intermediate. In the present study, a strand-specific quantitative RT-PCR assay was developed for analysis of FMDV replication. Strand-specific detection of viral positive and negative strand RNA was achieved using a high reverse transcription (RT) temperature (62 degrees C) and a tagged RT primer. In both the positive and negative strand assays, the lowest reliably detectable concentration was 1 x 10(2) copies/microl. The assays developed were successfully used to analyse viral replication in tissues collected from experimentally infected sheep during both acute and persistent infection. The results showed that while replication was observed in all tissues examined during acute infection, active viral replication during persistent infection was only detected in the tonsil. These results are consistent with the current opinion that the tonsil in sheep is the main predilection site for virus persistence. This assay will be used in the future to look further at replication in experimentally infected animals, including the study of individual cell types, and will improve our understanding of FMDV pathogenesis.

Plus- and minus-stranded foot-and-mouth disease virus RNA quantified simultaneously using a novel real-time RT-PCR

Even though tagged RT-PCR and rTth RT-PCR have been developed to improve strand-specific detection of RNA virus, these assays are not quantitative. In this study, a novel real-time RT-PCR assay, which combines the benefits of both the tagged and rTth RT-PCR has been developed to quantify the strand-specific RNA of foot-and-mouth disease virus (FMDV). The tagged-primers plus a TaqMan probe located within the highly conserved viral 3D region were used. The in vitro synthesized minus-and plus-stranded RNA templates were used as a dual control along with the copy number of viral RNA molecules, which is more reliable than reported RT-PCR employing a DNA-based standard. This assay was used to quantify FMDV RNA from 10(9) to 10(1) copies with a maximum sensitivity of between ten and five copies and was shown to be highly reproducible with low intra-and inter-assay variation. Coefficients of variation (CV) values were 0.70-1.39% and 0.98-2.1%, respectively. Importantly, the method was applied to simultaneously quantify both plus-stranded and minus-stranded FMDV RNA using tagged-RT and tagged-FP primer during a high-temperature reverse transcription. Highly sensitive and strand-specific real-time RT-PCR assay has been established. We tested the ratio of viral plus-stranded to minus-stranded RNA in acutely infected and persistently infected BHK-21 cells, for which the values ranged from 22/1 to 143/1 and from 287/1 to 334/1, respectively, suggesting different replication patterns of plus-and minus-stranded RNA in acutely infected and persistently infected cells. This value ranged from 83/1 to 93/1 in enriched FMDV virions, indicating that FMDV encapsidation is highly specific for plus-stranded RNAs. In addition, the method was applied to surveille the FMDV replication at animal level.

RNA viral community in human feces: prevalence of plant pathogenic viruses

The human gut is known to be a reservoir of a wide variety of microbes, including viruses. Many RNA viruses are known to be associated with gastroenteritis; however, the enteric RNA viral community present in healthy humans has not been described. Here, we present a comparative metagenomic analysis of the RNA viruses found in three fecal samples from two healthy human individuals. For this study, uncultured viruses were concentrated by tangential flow filtration, and viral RNA was extracted and cloned into shotgun viral cDNA libraries for sequencing analysis. The vast majority of the 36,769 viral sequences obtained were similar to plant pathogenic RNA viruses. The most abundant fecal virus in this study was pepper mild mottle virus (PMMV), which was found in high concentrations--up to 10(9) virions per gram of dry weight fecal matter. PMMV was also detected in 12 (66.7%) of 18 fecal samples collected from healthy individuals on two continents, indicating that this plant virus is prevalent in the human population. A number of pepper-based foods tested positive for PMMV, suggesting dietary origins for this virus. Intriguingly, the fecal PMMV was infectious to host plants, suggesting that humans might act as a vehicle for the dissemination of certain plant viruses.

A stem-loop-mediated reverse transcription real-time PCR for the selective detection and quantification of the replicative strand of an RNA virus

A stem-loop-based method to quantify the replicative strand of a model system, dengue virus, with high specificity and sensitivity is described. The high specificity of this approach is achieved at two levels: the use of a reverse transcription primer folded into a stem-loop structure with optimal energetics and the use of specific PCR primers to the loop structure. This approach has exceptional specificity to the replicative RNA as compared with the genomic sequence (>10(5)-fold difference), with a detection sensitivity of 10 copies. The high correlation to the biological "gold standard" plaque assay, used to quantify infectious virus, renders this method a useful quantitative tool that can replace the time-consuming, labor-intensive, and low-throughput plaque-based assays. The method has been extended to the detection of replicative strands of other RNA viruses (West Nile virus and human respiratory syncytial virus) with similar results. This real-time PCR method is reliable, simple to perform, and easily adaptable to different targets. The ability to detect and rapidly quantify replicating viruses is an important step in the elucidation of pathogenesis and is also useful for the evaluation of drugs designed to inhibit viral replication.

RT-PCR analysis of Deformed wing virus in honeybees (Apis mellifera) and mites (Varroa destructor)

Deformed wing virus (DWV) is a honeybee viral pathogen either persisting as an inapparent infection or resulting in wing deformity. The occurrence of deformity is associated with the transmission of DWV through Varroa destructor during pupal stages. Such infections with DWV add to the pathology of V. destructor and play a major role in colony collapse in the course of varroosis. Using a recently developed RT-PCR protocol for the detection of DWV, individual bees and mites originating from hives differing in Varroa infestation levels and the occurrence of crippled bees were analysed. It was found that 100 % of both crippled and asymptomatic bees were positive for DWV. However, a significant difference in the spatial distribution of DWV between asymptomatic and crippled bees could be demonstrated: when analysing head, thorax and abdomen of crippled bees, all body parts were always strongly positive for viral sequences. In contrast, for asymptomatic bees viral sequences could be detected in RNA extracted from the thorax and/or abdomen but never in RNA extracted from the head. DWV replication was demonstrated in almost all DWV-positive body parts of infected bees. Analysing individual mites for the presence of DWV revealed that the percentage of DWV-positive mites differed between mite populations. In addition, it was demonstrated that DWV was able to replicate in some but not all mites. Interestingly, virus replication in mites was correlated with wing deformity. DWV was also detected in the larval food, implicating that in addition to transmission by V. destructor DWV is also transmitted by feeding.

Establishment of stable HeLa cell lines expressing enzymatically active hepatitis C virus RNA polymerase

The hepatitis C virus RNA polymerase (NS5B) is strictly required for viral replication and thus represents an attractive target for antiviral drug development. In this study, stable HeLa cell lines with an integrated NS5B gene were selected by G418 and then confirmed by genome PCR. Subsequently, transcription and expression of the integrated NS5B genes were demonstrated by RT-PCR and Western blot analysis. Further analysis demonstrated enzymatic activity of the expressed NS5B polymerase. The stable HeLa cell lines should be useful for the identification of NS5B inhibitors and for studying the mechanisms of HCV replication.

Strand-specific, real-time RT-PCR assays for quantification of genomic and positive-sense RNAs of the fish rhabdovirus, Infectious hematopoietic necrosis virus

The fish rhabdovirus, Infectious hematopoietic necrosis virus (IHNV), is an important pathogen of salmonids. Cell culture assays have traditionally been used to quantify levels of IHNV in samples; however, real-time or quantitative RT-PCR assays have been proposed as a rapid alternative. For viruses having a single-stranded, negative-sense RNA genome, standard qRT-PCR assays do not distinguish between the negative-sense genome and positive-sense RNA species including mRNA and anti-genome. Thus, these methods do not determine viral genome copy number. This study reports development of strand-specific, qRT-PCR assays that use tagged primers for enhancing strand specificity during cDNA synthesis and quantitative PCR. Protocols were developed for positive-strand specific (pss-qRT-PCR) and negative-strand specific (nss-qRT-PCR) assays for IHNV glycoprotein (G) gene sequences. Validation with synthetic RNA transcripts demonstrated the assays could discriminate the correct strand with greater than 1000-fold fidelity. The number of genome copies in livers of IHNV-infected fish determined by nss-qRT-PCR was, on average, 8000-fold greater than the number of infectious units as determined by plaque assay. We also compared the number of genome copies with the quantity of positive-sense RNA and determined that the ratio of positive-sense molecules to negative-sense genome copies was, on average, 2.7:1. Potential future applications of these IHNV strand-specific qRT-PCR assays are discussed.

Transcriptional analysis of the conserved ftsZ gene cluster in Mycoplasma genitalium and Mycoplasma pneumoniae

Several experimental approaches were used to construct a detailed transcriptional profile of the phylogenetically conserved ftsZ cell division gene cluster in both Mycoplasma genitalium and its closest relative, Mycoplasma pneumoniae. We determined initiation and termination points for the cluster, as well as an absolute steady-state RNA level for each gene. Transcription of this cluster in both these organisms was shown to be highly strand specific. While the four genes in this cluster are cotranscribed, their transcription unit also includes two genes of close proximity yet disparate function. A transcription initiation point immediately upstream of these two genes was detected in M. genitalium but not M. pneumoniae. In M. pneumoniae, transcription of the six genes terminates at a poly(U)-tailed hairpin. In M. genitalium, this transcription terminates at two closely spaced points by an unknown mechanism. Real-time reverse transcription-PCR analysis of this cluster in M. pneumoniae shows that mRNA levels for all six genes vary at most fivefold and form a gradient of decreasing quantity with increasing distance from the promoter at the beginning of the cluster. mRNA from coding regions was approximately 20- to 100-fold more abundant than that from intergenic regions. We estimated the most abundant mRNA we detected at 0.6 copy per cell. We conclude that groups of functionally related genes in M. genitalium and M. pneumoniae are often preceded by promoters but rarely followed by terminators. This causes functionally unrelated genes to be commonly cotranscribed in these organisms.

Detection of infectious hepatitis A virus by integrated cell culture/strand-specific reverse transcriptase-polymerase chain reaction

AIMS

A novel integrated cell culture/strand-specific reverse transcriptase-polymerase chain reaction (RT-PCR) assay was established for detection of infectious hepatitis A virus (HAV).

METHODS AND RESULTS

The specificity of tagged RT-PCR was assessed using HAV genomic positive-strand RNA extracted from HAV virions as reference. Water samples artificially contaminated with infectious or formalin-inactivated HAV were subjected to integrated cell culture (ICC)/RT-PCR and ICC/strand-specific RT-PCR assays respectively. The tagged RT-PCR had high specificity for HAV negative-strand RNA. By demonstrating the formation of negative-strand RNA replicative intermediate, ICC/strand-specific RT-PCR can distinguish between infectious and non-infectious HAV. The described method detected infectious HAV at inoculation level of 10(0) TCID50 per flask within 4 days.

CONCLUSIONS

The ICC/strand-specific RT-PCR is a novel, rapid, sensitive and reliable method for detection of infectious HAV.

SIGNIFICANCE AND IMPACT OF THE STUDY

Coupled with a suitable virus concentration and purification system, ICC/strand-specific RT-PCR will provide a novel and rapid method for detection of infectious HAV in clinical, environmental and food samples. This assay may be used as an alternative method to test the effective inactivation of inactivated virus vaccines. It may also be adapted to assess the efficacy of disinfection of HAV and enteric viruses in foods and water.

Strand specific quantitative real-time PCR to study replication of hepatitis C virus genome

Qualitative detection of negative hepatitis C virus (HCV) RNA has been used widely to demonstrate HCV replication. However, relative quantitation of both positive and negative HCV RNA strands has never been reported for studying viral genome replication. A strand specific real-time PCR carried out in the highly conserved 5'-non-coding region of HCV genome and monitored either by the DNA binding dye SYBR Green I or by molecular beacons is described. Using these techniques, it was found that negative HCV RNA strand was a 100-1000 times less abundant than the positive strand in the liver of HCV infected patients.

Evidence for in vitro falsely-primed cDNAs that prevent specific detection of virus negative strand RNAs in dengue-infected cells: improvement by tagged RT-PCR

The identification of cell types replicating dengue viruses is an important step towards the understanding of the pathophysiology of dengue severe forms. Since the detection of negative strand viral RNAs is the more reliable marker of active replication for single-strand positive sense RNA viruses, we reassessed the specificity of RT-PCR assays already developed to detect dengue negative strand RNAs. Studying mammalian Vero cells infected by a dengue-2 strain, it was shown that falsely-primed cDNAs are generated in vitro during the reverse transcription step and are amplified subsequently by PCR. Since this may compromise the specificity of existing RT-PCR systems, we developed a tagged RT-PCR assay and addressed the role of some critical factors in such a system. Optimization of the negative strand-specific tagged RT-PCR allowed to resolve the problems due to the PCR amplification of falsely-primed cDNAs. Using this assay it was possible to detect specifically negative strand RNAs as soon as 3h after Vero cells have been exposed to the dengue-2 strain and we showed that this system is highly specific. Thus, the present dengue negative strand-specific tagged RT-PCR assay may help to reassess viral replication in the context of dengue pathophysiology.

An oligonucleotide complementary to the SL-B1 domain in the 3'-end of the minus-strand RNA of the hepatitis C virus inhibits in vitro initiation of RNA synthesis by the viral polymerase

We describe oligonucleotides (ODNs) that inhibit hepatitis C virus (HCV) RNA synthesis in vitro. From a series of 13 ODNs complementary to the 3'-end of the minus-strand HCV RNA, only 4 inhibited RNA synthesis with IC(50) values lower than 1 microM. The inhibition was sequence-specific, since no effect was observed when the ODNs were used with a noncomplementary template. The introduction of a 2'-O-methyl modification increased the inhibitor activity 11-fold (IC(50) = 50 nM) in just 1 (ODN7) of the 4 inhibitory ODNs. ODNs did not inhibit RNA synthesis by interfering with the elongation process as no short RNAs products were detected. We also show that ODN7 did not prevent binding of NS5B to the template or cause polymerase trapping by the duplex RNA/ODN. Our data demonstrate that ODN7 inhibits the initiation process, most probably by modifying structural features present at the 3'-end of the minus-strand RNA.

Replication studies using genotype 1a subgenomic hepatitis C virus replicons

Recently, cell-based replicon systems for hepatitis C virus (HCV), in which the nonstructural proteins stably replicate subgenomic viral RNA in Huh7 cells, were developed. To date, one limitation of using these replicon systems to advance drug discovery is the inability of other genotypic derivatives, beyond those of two distinct strains of genotype 1b (HCV-N and Con1), to stably replicate in Huh7 cells. In this report, we evaluated a series of replicon genotype 1a-1b chimeras, as well as a complete genotype 1a replicon clone. A subgenomic replicon construct containing only type 1a sequences failed to generate stable colonies in Huh7 cells even after repeated attempts. Furthermore, addition of an NS5A adaptive mutation (S2204I) which enhances type 1b replicon efficiency was insufficient to confer replication to the wild-type 1a replicon. This subgenomic replicon was subsequently found to be inefficiently translated in Huh7 cells compared to a type 1b replicon, and the attenuation of translation mapped to the N-terminal region of NS3. Therefore, to ensure efficient translation and thereby support replication of the 1a genome, the coding sequence for first 75 residues from type 1a were replaced with the type 1b (strain Con 1) NS3 coding sequence. Although nonstructural proteins were expressed at lower levels with this replicon than with type 1b and although the amount of viral RNA was also severalfold lower (150 copies of positive-strand RNA per cell), the replicon stably replicated in Huh7 cells. Notwithstanding this difference, the ratio of positive- to negative-strand RNA of 26 was similar to that found with the type 1b replicon. Similar results were found for a 1b replicon expressing the type 1a RNA-dependent RNA polymerase. These 1a hybrid replicons maintained sensitivity to alpha interferon (IFN-alpha), albeit with an eightfold-higher 50% inhibitory concentration than type 1b replicons. Evidence is provided herein to confirm that this differential response to IFN-alpha may be attributed directly to the type 1a polymerase.

Identification and biological characterization of heterocyclic inhibitors of the hepatitis C virus RNA-dependent RNA polymerase

The hepatitis C virus (HCV) NS5B protein encodes an RNA-dependent RNA polymerase (RdRp), the primary catalytic enzyme of the HCV replicase complex. We established a biochemical RNA synthesis assay, using purified recombinant NS5B lacking the C-terminal 21 amino acid residues, to identify potential polymerase inhibitors from a high throughput screen of the GlaxoSmithKline proprietary compound collection. The benzo-1,2,4-thiadiazine compound 1 was found to be a potent, highly specific inhibitor of NS5B. This agent interacts directly with the viral polymerase and inhibits RNA synthesis in a manner noncompetitive with respect to GTP. Furthermore, in the absence of an in vitro-reconstituted HCV replicase assay employing viral and host proteins, the ability of compound 1 to inhibit NS5B-directed viral RNA replication was determined using the Huh7 cell-based HCV replicon system. Compound 1 reduced viral RNA in replicon cells with an IC(50) of approximately 0.5 microm, suggesting that the inhibitor was able to access the perinuclear membrane and inhibit the polymerase activity in the context of a replicase complex. Preliminary structure-activity studies on compound 1 led to the identification of a modified inhibitor, compound 4, showing an improvement in both biochemical and cell-based potency. Lastly, data are presented suggesting that these compounds interfere with the formation of negative and positive strand progeny RNA by a similar mode of action. Investigations are ongoing to assess the potential utility of such agents in the treatment of chronic HCV disease.

A novel strand-specific RT-PCR for detection of hepatitis C virus negative-strand RNA (replicative intermediate): evidence of absence or very low level of HCV replication in peripheral blood mononuclear cells

Hepatitis C virus (HCV) is reported to be lymphotropic under certain circumstances. In order to evaluate viral replication in peripheral blood mononuclear cells (PBMCs), a novel strand-specific RT-PCR was developed for the determination of HCV negative-strand RNA. The detection limit of this strand-specific RT-PCR was 100 copies of HCV negative-strand RNA in the presence of 1 microg liver RNA and 10(7)-10(8) copies of positive-strand RNA. False positive PCR signals occurred only when HCV positive-strand RNA exceeded 10(9) copies. With this RT-PCR, the replicative-intermediates could be detected specifically in eight of ten liver tissues, but not in any samples of serum or plasma (0/65) of patients with chronic hepatitis C. When examining the PBMCs of 46 hepatitis C patients, including 12 patients who had undergone orthotopic liver transplantation, HCV negative-strand RNA was detected in only one patient (1/46). In addition, HCV replicative intermediates were not detected in PBMCs of patients using immunosuppressive agents. It is concluded that the replication of HCV in PBMCs is very unusual.