Human Norovirus belongs to a family Calciviridae, and was identified in the outbreak of gastroenteritis in Norwalk, due to its seasonal prevalence known as "winter vomiting disease." Treatment of Norovirus infection is still mysterious because there is no effective antiviral drugs or vaccine developed to protect against the infection, to eradicate the infection an effective vaccine should be developed. In this study, capsid protein (A7YK10), small protein (A7YK11), and polyprotein (A7YK09) were utilized. These proteins were subjected to B and T cell epitopes prediction by using reliable immunoinformatics tools. The antigenic and non-allergenic epitopes were selected for the subunit vaccine, which can activate cellular and humoral immune responses. Linkers joined these epitopes together. The vaccine structure was modelled and validated by using Errat, ProSA, and rampage servers. The modelled vaccine was docked with TLR-7. The stability of the docked complex was evaluated by MD simulation. To apply the concept in a wet lab, the reverse translated vaccine sequence was cloned in pET28a (+). The vaccine developed in this study requires experimental validation to ensure its effectiveness against the disease.Communicated by Ramaswamy H. Sarma.

Genetic diversity of Plasmodium parasite has significantly related to malaria control and vaccine development. The P. falciparum merozoite surface protein 1 (Pfmsp1) gene is a commonly used molecular marker to differentiate genetic diversity. This study is aimed at developing a nested PCR-Heteroduplex Mobility Assay (nPCR-HMA) for determination of the block 2 of the Pfmsp1 gene. The MAD20 family allele of P. falciparum was used as a control for optimization of the annealing and polyacrylamide gel electrophoresis conditions. In order to evaluate the developed nPCR-HMA, 8 clinical P. falciparum isolates were examined for allelic variants. The results revealed 9 allelic variants. Our study indicated that the successful nPCR-HMA with good precision and accuracy offers a more rapid, efficient, and cheap method for large-scale molecular epidemiological studies as compared to nucleotide sequencing.

An oligonucleotide microarray hybridization method for identification of most known measles virus (MV) genotypes was developed. Like the conventional genotyping method, the microarray relied on detecting sequence differences in the 450-nucleotide region coding for the COOH-terminal 150 amino acids of the nucleoprotein (N). This region was amplified using PCR primers binding to all known MV genotypes. The microarray included 71 pairs of oligonucleotide probes (oligoprobes) immobilized on glass slides. Each pair consisted of a genotype-specific oligoprobe, which matched the sequence of only one target genotype, and a control oligoprobe, which contained mismatches at the nucleotide positions unique to this genotype. A pattern recognition algorithm based on cluster analysis of the ratios of hybridization signals from specific and control oligoprobes was used to identify the specific MV genotype. Following the initial validation, the method was used for rapid genotyping of two panels of coded samples. The results of this study showed good sensitivity (90.7%), specificity (100%), and genotype agreement (91.8%) for the new method compared to the results of genotyping conducted using phylogenetic analysis of viral sequences of the C terminus of the N gene. In addition, the microarray demonstrated the ability to identify potential new genotypes of MV based on the similarity of their hybridization patterns with those of known MV genotypes.

To investigate the evaluation of hepatitis C virus (HCV) quasispecies in the envelope region and its relationship with the outcome of acute hepatitis C.

HCV quasispecies were characterized in specimens collected every 2-6 mo from a cohort of acutely HCV-infected subjects. We evaluated two individuals who spontaneously cleared viremia and three individuals with persistent viremia by cloning 33 1-kb amplicons that spanned E1 and the 5' half of E2, including hypervariable region 1 (HVR1). To assess the quasispecies complexity and to detect variants for sequencing, 33 cloned cDNAs representing each specimen were assessed by a combined method of analysis of a single-stranded conformational polymorphism and heteroduplex analysis. The rates of both synonymous and nonsynonymous substitutions for the E1, HVR1 and E2 regions outside HVR1 were analyzed.

Serum samples collected from chronic phase of infection had higher quasispecies complexity than those collected from acute phase of infection in all individuals examined. The genetic diversity (genetic distance) within HVR1 was consistently higher than that in the complete E1 (0.0322+/-0.0068 vs -0.0020+/-0.0014, P<0.05) and E2 regions outside HVR1 (0.0322+/-0.0068 vs 0.0017+/-0.0011, P<0.05) in individuals with persistent viremia, but did not change markedly over time in those with clearance of viremia. For individuals with persistent viremia, the rate of nonsynonymous substitutions within the HVR1 region (2.76X10(-3)+/-1.51X10(-3)) predominated and gradually increased, as compared with that in the E1 and E2 regions outside HVR1 (0.23X10(-3)+/-0.15X10(-3), 0.50X10(-3)+/-0.10X10(-3)). By contrast, the rates of both nonsynonymous and synonymous substitutions for the E1 and E2 regions including HVR1 were consistently lower in individuals with clearance of viremia.

HCV persistence is associated with a complexity quasispecies and positive selection of HVR1 by the host immune system.

A heteroduplex mobility assay (HMA) was developed to genotype infectious bursal disease virus (IBDV). This method analyzed 390-base pair (bp) polymerase chain reaction (PCR) products, encompassing the hypervariable region of the VP2 gene. IBDV strains from the United States and other countries were analyzed. The HMA was able to differentiate standard, antigenic variants and very virulent strains of IBDV. Minor differences between different strains from the same subtype were also detected. Close relationships between field IBDV with vaccines prepared with Delaware E strain were determined by HMA. The results obtained by HMA were confirmed by restriction fragment length polymorphism (RFLP) and phylogenetic analysis of nucleotide sequences. The HMA proved to be a useful technique to rapidly genotype different field strains of IBDV and should prove to be a useful tool in epidemiologic studies.

Recent studies have demonstrated the widespread contamination of river and seawater with noroviruses (NV), often with more than one strain. The heteroduplex mobility assay (HMA) in which amplicons from study samples are hybridised (by denaturing and reannealing) to amplicons from reference strains and resolved by electrophoresis, has the potential to provide a simple and rapid means to identify samples containing multiple NV strains and to establish the diversity of strains within that sample. PCR amplicons from environmental samples that were tested directly in the HMA assay were shown to contain more than one strain. In order to evaluate HMA for investigations of NV diversity in environmental samples, amplicons from three representative samples were cloned and, for each, 20 amplicons derived from individual clones were analysed by HMA. Between two and six different HMA profiles were demonstrated among clones from a single sample indicating the extent of NV diversity in the sample. Sequence analysis confirmed the relationship of HMA profile and NV 'genotype'. Far greater diversity was seen among Genogroup (G) II (Ni/E3) amplicons than Genogroup (G) I (Ando/E3) amplicons (generated from the RNA dependent RNA polymerase region of the ORF1 of noroviruses), which often contained only a single strain, which is reflective of the greater prevalence of GII NVs over GI NVs. Overall, four GII and four GI strains were identified in these environmental water/sewage samples.

Drug-resistant viruses may be present as minority variants during early treatment failures or following discontinuation of failed antiretroviral regimens. A limitation of the traditional direct PCR population sequencing method is its inability to detect human immunodeficiency virus type 1 (HIV-1) variants present at frequencies lower than 20%. A drug resistance genotyping assay based on the isolation and DNA sequencing of minority HIV protease variants is presented here. A multiple-codon-specific heteroduplex generator probe was constructed to improve the separation of HIV protease genes varying in sequence at 12 codons associated with resistance to protease inhibitors. Using an RNA molecule as probe allowed the simple sequencing of protease variants isolated as RNA/DNA heteroduplexes with different electrophoretic mobilities. The protease gene RNA heteroduplex generator-tracking assay (RNA-HTA) was tested on plasma quasispecies from 21 HIV-1-infected persons in whom one or more protease resistance mutations emerged during therapy or following initiation of salvage regimens. In 11 of 21 cases, RNA-HTA testing of virus from the first episode of virologic failure identified protease resistance mutations not seen by population-based PCR sequencing. In 8 of these 11 cases, all of the low-frequency drug resistance mutations detected exclusively by RNA-HTA during the first episode became detectable by population-based PCR sequencing at the later time point. Distinct sets of protease mutations could be linked on different genomes in patients with high-frequency protease gene lineages. The enhanced detection of minority drug resistance variants using a sequencing-based assay may improve the efficacy of genotype-assisted salvage therapies.

This article describes the methods used to investigate 407 outbreaks of acute non-bacterial gastroenteritis occurring in the North-West of England between January 2000 and July 2001 and suspected to be caused by noroviruses (NV) [Mayo (2002) Arch Virol 147:1655-1663]. These included 319 outbreaks in hospitals and nursing homes and 88 other settings. Eight hundred and seventy-one faecal samples from 407 outbreaks were tested using electron microscopy (EM), an enzyme-linked immunosorbent assay (ELISA) specific for Grimsby virus (GRV) capsid antigen and/or by reverse transcriptase-polymerase chain reaction (RT-PCR) for NV, allowing the utility of each assay for routine diagnosis to be assessed. Preliminary genomic characterisation of detected strains was performed using the heteroduplex mobility assay (HMA) and DNA sequencing. The results demonstrate the continuing predominance of GII-4 GRV strain of NV as a cause of outbreaks, particularly in hospital and nursing home settings. Overall, NV were detected in 223/407 (55%) of outbreaks tested. However, a wide range of apparently diverse strains was identified, including several not previously reported. Genomic characterisation revealed clusters of linked outbreaks not recognised previously.

Porcine reproductive and respiratory syndrome has been devastating the swine industry since the late 1980s. The disease has been controlled, to some extent, through the use of modified live-attenuated (MLV) vaccines once available. However, such a practice periodically resulted in isolation or detection of vaccine-like viruses from pigs as determined by a partial genomic sequencing. In this study, we developed a heteroduplex mobility assay (HMA) for quickly identifying porcine reproductive and respiratory syndrome virus (PRRSV) isolates with significant nucleotide sequence identities (>/=98%) with the modified live-attenuated vaccines. The major envelope gene (ORF5) of 51 PRRSV field isolates recovered before and after the introduction of the vaccines was amplified, denatured, and reannealed with the HMA reference vaccine strains Ingelvac PRRS MLV and Ingelvac PRRS ATP, respectively. Nine of the 51 field isolates and the VR2332 parent virus of Ingelvac PRRS MLV, which were all highly related to Ingelvac PRRS MLV with Collapse

A simple method, based on a modification of the amplification refractory mutation system (ARMS), for genotyping outbreak strains of measles and mumps viruses and detecting these in a simple enzyme immunoassay (EIA) is described. Fifty-three measles strains circulating at the time of an outbreak in London in 2000 and 26 strains circulating at the time of a mumps outbreak in Accrington, UK, in 1999 were investigated. All strains were genotyped by direct sequencing. ARMS primers were then designed to amplify the outbreak strain. The ARMS-EIA for measles and mumps detected all 36 measles outbreak strains as genotype D6, and all 15 mumps outbreak strains as genotype F, respectively. The sensitivity and specificity of both the measles D6 and Mumps F genotype ARMS EIA was 100% compared with direct sequencing. The results show that ARMS-EIA can be used as a rapid alternative to genotyping by direct sequence analysis in outbreak situations.

Phylogenetic analysis based on a 168 base segment encompassing the putative VP1/2A junction of the hepatitis A virus (HAV) genome has enabled the classification of HAV isolates into seven genotypes (I-VII). Genotype I, which includes the vast majority of the human HAV isolates, has been divided further into subgenotypes IA and IB. An heteroduplex mobility assay was designed with amplification products from the VP1/2A junction region, and used as a genotyping method able to discriminate HAV isolates belonging to IA, IB and non-I genotypes. The method was used to successfully genotype 48 samples (16 IA and 32 IB). However, one HAV RNA positive serum sample (AUX-23), collected from a 15 year old female employed at a child care center located in Rio de Janeiro, Brazil, showed an unusual pattern. PCR products from sample AUX-23 gave rise to heteroduplex bands when mixed with IA products as well as with IB products, suggesting the presence of HAV isolates from both subgenotypes in the serum. PCR products from sample AUX-23 were then cloned and 20 clones were analyzed by heteroduplex mobility assay. Eleven were subgenotype IA and 9 were IB. Three clones of each subgenotype were then sequenced to confirm the results. These data constitute the first report of mixed infection of a single individual with different HAV isolates.

Highly pathogenic avian influenza (HPAI) in poultry causes high morbidity and mortality, and it is a List A disease of the Office International des Epizooties. An outbreak of HPAI in commercial poultry not only causes direct disease losses but often results in trade restrictions for the affected country. Because HPAI viruses can mutate from H5 and H7 low pathogenic avian influenza viruses, it is necessary to monitor and control even the low pathogenic form of the virus. We report a practical approach for screening large numbers of isolates that uses amplification by reverse transcriptase-polymerase chain reaction of a segment of the hemagglutinin (HA) gene (536-560 bp) of H7 avian influenza viruses followed by the heteroduplex mobility assay (HMA). The HMA test compares the amplified polymerase chain reaction product from unknown samples with reference isolates, which allows the identification of new variants. The HMA test results were compared with sequence analysis of the isolates used in the study. On the basis of the HMA, we could identify several new variant viruses present in the live bird markets in the northeastern United States. New strains gave a distinct pattern of bands in the gels in accordance with the different heteroduplexes formed when their HA region amplification products were incubated together with the same amplification product of a reference strain. These differences correlate with phylogenetic analysis from sequence data.

Recombinant plasmids carrying 199 base pairs (bp) inserts from the non coding region (nucleotides (nt) 6-204) of the TT virus (TTV) genome were used to standardize an heteroduplex mobility assay able to detect mixed infections of a single individual with several TTV isolates. In this simplified heteroduplex mobility assay, polymerase chain reaction (PCR) products were analyzed directly by polyacrylamide gel electrophoresis, without requirement for post-PCR denaturation and annealing steps of the amplicons. The assay was used to test TTV positive serum samples collected from healthy 1-7 years old children, 11-17 years old adolescents, and 24-39 years old blood donors living in Rio de Janeiro, Brazil, as well as TTV positive samples from Amazonian Indians. The results showed a very high frequency of multiple infection in all groups, with 20/30 (67%), 31/33 (94%), 35/38 (92%), and 34/37 (92%) of the samples collected from children, adolescents, blood donors, and Amazonian Indians, respectively, containing more than one TTV genotype.

Transfer of influenza A viruses from animal hosts to man may lead to the emergence of new human pandemic strains. The early detection and identification of such events are therefore paramount in the surveillance of influenza viruses. To detect and partially characterize influenza A viruses from different animal species, a combined reverse transcription (RT)-PCR heteroduplex mobility assay (HMA) was designed. This M gene RT-PCR was shown to be sensitive and specific for the detection of human, avian, and swine influenza A viruses. PCR amplicons from human, avian, and swine viruses of 15 different subtypes, with between 1.9 and 21.4% nucleotide divergence, were differentiated by HMA. Sequencing of the amplicons showed that the heteroduplex mobility patterns correlated with the sequence divergence between test and reference DNA. The application of the RT-PCR HMA method for rapid screening of samples was assessed with a reference panel of viruses of human, avian, and swine origin. The avian H9N2 virus A/HongKong/1073/99, which crossed the species barrier to humans, was screened against the reference panel. It was found to be most closely related to the avian A/Quail/HongKong/G1/97 H9N2 reference PCR product. Sequence analysis showed a nucleotide divergence of 1.1% between the A/Quail/HongKong/G1/97 and A/HongKong/1073/99 amplicons. From the results of our work, we consider the RT-PCR HMA method described to offer a rapid and sensitive means for screening for novel or unusual influenza viruses.

Phage-displayed peptide libraries represent an efficient tool to isolate peptides that bind a given target molecule. After several selection rounds, generally a large pool of target binding phages is obtained. Conventional analysis of the selected phage population involves extensive sequencing of many clones, most of which can be identical. We have adapted the Heteroduplex Mobility Assay (HMA) for pre-screening of phage inserts that were amplified by direct colony PCR of ELISA-positive clones. This strategy allowed for the rapid and reproducible assignment of insert sequences to different 'heteroduplex migration groups'. Sequence analysis of only one representative of each HMA migration group then completes the characterisation of the binding phage population. In our model experiments, only 16% of HMA pre-screened clones required further sequence analysis.

In many parts of Asia measles virus (MV) continues to be endemic. However, little is known about the genetic characteristics of viruses circulating on this continent. This study reports the molecular epidemiological analysis based on the entire nucleocapsid (N) and hemagglutinin (H) genes of the first isolates from Nepal and Taiwan, as well as of recent MV strains from India, Indonesia, and China. Four isolates collected in various regions in Nepal during 1999 belonged to a new genotype, tentatively called D8. Another Nepalese isolate and one from India belonged to genotype D4. The diversity of the Nepalese strains indicated that measles continues to be endemic in this country. The isolate from Taiwan grouped with D3 viruses and one Chinese strain isolated in The Netherlands was assigned to the previously described clade H, known to be endemic in Mainland China. Molecular characterization emerges as an important tool for monitoring virus endemicity and vaccination efforts.

For genetic identification of Aspergillus Section Flavi isolates and detection of intraspecific variation, we developed a novel method for heteroduplex panel analysis (HPA) utilizing fragments of the internal transcribed spacer (ITS) regions (ITS1-5.8S-ITS2) of the rRNA gene that was PCR amplified with universal primers. The method involves formation of heteroduplexes with a set of reference fragments amplified from Aspergillus flavus, A. parasiticus, A. tamarii, and A. nomius and subsequent minislab vinyl polymer gel electrophoresis. The test panel is compared with species-specific standard panels (F-1, P-1, T-1, and N-1) generated by pairwise reannealing among four reference fragments. Of 90 test panels, 89 succeeded in identifying the species and 74 were identical to one of the four standard panels. Of the 16 new panels, 11 A. flavus/A. oryzae panels were identical and typed as F-2 and 4 of 5 A. nomius panels were typed as N-2 or N-3. The other strain, A. nomius IMI 358749, was unable to identify the species because no single bands were formed with any of the four reference strains. DNA sequencing revealed that our HPA method has the highest sensitivity available and is able to detect as little as one nucleotide of diversity within the species. When Penicillium or non-Section Flavi Aspergillus was subjected to HPA, the resulting bands of heteroduplexes showed apparently lower mobility and poor heteroduplex formation. This indicates that HPA is a useful identification method without morphological observation and is suitable for rapid and inexpensive screening of large numbers of isolates. The HPA typing coincided with the taxonomy of Section Flavi and is therefore applicable as an alternative to the conventional methods (Samson, R. A., E. S. Hoekstra, J. C. Frisvad, and O. Filtenborg, p. 64-97, in Introduction to Food- and Airborne Fungi, 6th ed., 2000).

Newcastle disease virus (NDV) is an economically important pathogen of poultry that may cause clinical disease that ranges from a mild respiratory syndrome to a virulent form with high mortality, depending on an isolate's pathotype. Infections with virulent NDV strains are required to be reported by member nations to the Office of International Epizootes (OIE). The primary determinant for virulence among NDV isolates is the presence or absence of dibasic amino acids in the fusion (F) protein cleavage activation site. Along with biological virulence determinations as the definitive tests, OIE accepts reporting of the F protein cleavage site sequence of NDV isolates as a virulence criterion. Nucleotide sequence data for many NDV isolates recently isolated from infected chickens and other avian species worldwide have been deposited in GenBank. Consequently, viral genomic information surrounding the F protein cleavage site coding sequence was used to develop a heteroduplex mobility assay (HMA) to aid in further identification of molecular markers as predictors of NDV virulence. Using common vaccine strains as a reference, we were able to distinguish virulent viruses among NDV isolates that correlated with phylogenetic analysis of the nucleotide sequence. This technique was also used to examine NDV isolates not previously characterized. We were able to distinguish vaccine-like viruses from other isolates potentially virulent for chickens. This technique will help improve international harmonization of veterinary biologics as set forth by the OIE and the Veterinary International Cooperation on Harmonization of Technical Requirements of Veterinary Medicinal Products. Ultimately, the HMA could be used for initial screening among a large number of isolates and rapid identification of potentially virulent NDV that continue to threaten commercial poultry worldwide.

Cassava mosaic disease is an enormous problem affecting the viability and productivity of cassava in all the developing regions in Africa. The disease is now known to be caused by a number of cassava-infecting begomoviruses. New viruses and viral strains continue to be discovered and due to the lack of cloning and sequencing facilities in many African laboratories, a simple, rapid and sensitive technique is needed for screening of cassava plantations. Here we report on the development of a heteroduplex mobility assay (HMA) which could be used for the testing of viral-infected cassava. The assay involves amplifying the highly conserved core region of the coat protein gene of field isolates followed by denaturing and annealing with a number of reference strains. The HMA profiles in this study were able to differentiate four different viral species and 11 different virus strains, and showed a good correlation with sequencing results and phylogenetic comparisons with other sequenced cassava viruses. This technique is sensitive and rapid and has the added advantage of being able to detect mixtures of viruses in field-grown cassava.

The different measles virus genotypes are confined to more or less distinct geographic regions. Molecular characterization of virus isolates has been successfully used to determine epidemiological links between cases and the geographic origin of imported viruses. In Europe, indigenous measles has been eliminated in some countries, but in others the disease is still endemic. Intra-outbreak variability can be used to differentiate between sporadic endemic cases and a 'pseudo-outbreak' of unrelated imported cases. The interruption of virus circulation by mass vaccination campaigns could be demonstrated by comparing the variability of pre-campaign viruses with post-campaign isolates. Simplified tools are being developed that could bring genotyping within reach of laboratories that do not have the possibility of sequencing.

The heteroduplex mobility assay (HMA) is a means of comparing two PCR amplicons or, in the variation known as the heteroduplex tracking assay (HTA), a means of estimating the quasispecies diversity of a viral genome. Heteroduplex assays have many applications including subtyping viral genomes, screening for low frequency variants in a population, scanning the relative genetic diversity across a genome and screening for recombinant clones. They can be used to detect dual infections, superinfections, contaminated blood products and laboratory contaminations. PCR amplicons of about 65% sequence similarity or greater will form heteroduplexes under appropriate conditions, and phylogenetic trees can be drawn from heteroduplex mobility data. While homoduplexes indicate more than 98% similarity between two DNA sequences, heteroduplexes indicate at least seven mismatches in a 500-bp amplicon, or a three-base pair gap in 1000-bp. Minority variants comprising 1% to 5% of the genome population can be detected and quantified by HTA. Thus far, heteroduplex assays have been described for HIV and other lentiviruses, hepatitis C and G viruses, Norwalk-like viruses, influenza, measles and poliovirus. They could be applied to a wide range of other viral species.

Heteroduplex mobility assay (HMA) is a fast and inexpensive method for determining relatedness between DNA sequences. Rapidly evolving viruses such as HIV-1 develop marked sequence differences in their genomes over the course of the epidemic and infection in a single individual. HMA can be used to monitor both processes. Here, we systematically evaluated the influence of single base mismatches on heteroduplex mobility. The impact of mismatches at nine different positions in 559 bp double-stranded DNA molecules, within a background of overall sequence divergence ranging from 1.97 to 9.65%, was evaluated in both non-denaturing and partially-denaturing acrylamide gels. We found that the electrophoretic mobility of heteroduplexes was proportional to the level of mismatch when that level exceeded 4.5%. Overall, mismatches near the center of the fragment and clustered mismatches tended to have an exaggerated influence on the mobility of heteroduplexes. Thus, the use of HMA for quantitative inference of genetic distances under the conditions we describe is of greatest utility at levels of mismatch >5%.

ABSTRACT A heteroduplex mobility assay (HMA) was used to analyze the variability among five isolates of Zucchini yellow mosaic virus (ZYMV; TW-TC1, TW-CY2, TW-TN3, TW-TNML1, and TW-NT1) collected from cucurbit fields in different areas of Taiwan. A cDNA fragment of 760 bp covering the variable region of the N terminal half of the coat protein (CP) gene was amplified by reverse transcription-polymerase chain reaction (RT-PCR) and subsequently subjected to HMA analysis for sequence variation. When TW-NT1 combined with any of the other Taiwan isolates, the heteroduplexes obtained migrated much more slowly than did the heteroduplexes obtained in combinations among the other four Taiwan isolates, indicating that TW-TC1, TW-CY2, TW-TN3, and TW-TNML1 share a high degree of sequence homology, while the TW-NT1 isolate is more distinct. The complete nucleotide sequences of the CP genes and the 3' noncoding regions of the five isolates were determined from RT-PCR-derived cDNA clones. A phylogenetic tree derived from the actual sequences of the 760-bp fragments of the five Taiwan and another six ZYMV isolates from different geographic areas revealed four genotypes. TW-TNML1, TW-TC1, TWC-Y2, and TW-TN3 were in genotype I, while TW-NT1 and U.S. isolates were in genotype II. The Singapore and Reunion Island isolates were separated into genotypes III and IV, respectively. Comparison of the CP genes of the five Taiwan isolates indicated that they share 92.8 to 98.7% nucleotide identities and 96.4 to 99.3% amino acid identities. The amino acid positions 73, 102, 109, and 149 of the CP gene, where lysine, serine, arginine, and aspartic acid reside, respectively, were uniquely conserved for genotype I Taiwan isolates. Thus, results of HMA agreed well with those of phylogenetic analysis based on the sequence data of the five Taiwan ZYMV isolates. These five ZYMV isolates of known sequence can be used as reference strains for HMA to analyze the variability of ZYMV in Taiwan.

GB virus C/hepatitis G virus (GBV-C/HGV) is a positive-sense RNA virus belonging to the Flaviviridae family identified recently. Reverse transcription polymerase chain reaction (RT-PCR) was used to detect GBV-C/HGV RNA using nested primers designed to amplify 245 bp of the 5'-untranslated region (UTR). GBV-C/HGV RNA was detected in 20.7% of 101 HCV-RNA positive and 6.8% of 44 HCV-RNA negative specimens. Sequencing of the PCR products demonstrated they had between 84.3 and 100% nucleotide identity. Most of the diversity corresponded to two variable regions identified within the 5'-UTR. Phylogenetic analysis indicated that GBV-C/HGV subtypes present in Australia belonged to group 2 and were closest in evolutionary terms to isolates from the USA and Europe. All isolates were analysed using single-strand conformation polymorphism (SSCP) and heteroduplex mobility analysis (HMA) on 8% non-denaturing polyacrylamide gels. SSCP of the isolates identified a number of distinct conformation polymorphisms that corresponded with sequence-determined genetic diversity. HMA was developed to assess the amount of genetic diversity between isolates without the need for sequencing. The average difference between the predicted divergence of two isolates calculated from the mobility of the heteroduplex and the actual value (based on nucleotide sequence) was 2.3% in this sample of isolates, where the mean sequence divergence was 8.52%.

To assess genetic variation in hepatitis C virus (HCV) sequences accurately, we optimized a method for identifying distinct viral clones without determining the nucleotide sequence of each clone. Twelve serum samples were obtained from seven individuals soon after they acquired HCV during a prospective study, and a 452-bp fragment from the E2 region was amplified by reverse transcriptase PCR and cloned. Thirty-three cloned cDNAs representing each specimen were assessed by a method that combined heteroduplex analysis (HDA) and a single-stranded conformational polymorphism (SSCP) method to determine the number of clonotypes (electrophoretically indistinguishable cloned cDNAs) as a measure of genetic complexity (this combined method is referred to herein as the HDA+SSCP method). We calculated Shannon entropy, incorporating the number and distribution of clonotypes into a single quantifier of complexity. These measures were evaluated for their correlation with nucleotide sequence diversity. Blinded analysis revealed that the sensitivity (ability to detect variants) and specificity (avoidance of false detection) of the HDA+SSCP method were very high. The genetic distance (mean +/- standard deviation) between indistinguishable cloned cDNAs (intraclonotype diversity) was 0.6% +/- 0.9%, and 98.7% of cDNAs differed by <2%, while the mean distance between cloned cDNAs with different patterns was 4.0% +/- 3.2%. The sensitivity of the HDA+SSCP method compared favorably with either HDA or the SSCP method alone, which resulted in intraclonotype diversities of 1.6% +/- 1.8% and 3.5% +/- 3.4%, respectively. The number of clonotypes correlated strongly with genetic diversity (R2, 0.93), but this correlation fell off sharply when fewer clones were assessed. This HDA+SSCP method accurately reflected nucleotide sequence diversity among a large number of viral cDNA clones, which should enhance analyses to determine the effects of viral diversity on HCV-associated disease. If sequence diversity becomes recognized as an important parameter for staging or monitoring of HCV infection, this method should be practical enough for use in laboratories that perform nucleic acid testing.

Rapid and efficient procedures for the detection of sequence polymorphisms are essential for chromosomal walking and mutation detection analyses. While DNA chip technology and denaturing high-performance liquid chromatography (DHPLC) are the methods of choice for large scale facilities, small laboratories are dependent on simple ready-to-use techniques. We show that heteroduplex analysis on high resolution gel matrices efficiently detects sequence polymorphism differing as little as a single base pair (e.g. single-nucleotide polymorphism, SNP) with standard laboratory equipment. Furthermore, the matrices also discerned differences between homoduplexes, a prerequisite for co-dominant markers. The markers thus generated are referred to as duplex analysis markers. We designed PCR primers for 36 Arabidopsis thaliana loci ranging in length from 230 bp to 1000 bp. Among three ecotypes, more than half (n = 19) of the loci examined were polymorphic; five of which contained three different alleles. This simple, high resolution technique can be used to rapidly convert sequence tagged sites into co-dominant PCR-based molecular markers for fine-scale mapping studies and chromosomal walking strategies as well as for the detection of mutations in particular genes.

Analysis of the 16S rRNA genes retrieved directly from different environments has proven to be a powerful tool that has greatly expanded our knowledge of microbial diversity and phylogeny. It is shown here that sequence similarity between 80 and 100% among 16S rDNAs can be estimated by the electrophoretic migration of their heteroduplexes. This was measured by hybridization and electrophoresis in polyacrylamide gels of the product obtained after PCR amplification of almost the entire 16S rRNA gene from different bacterial species. These heteroduplexes were also observed after amplification of samples containing DNA from two or more bacterial species and a procedure was applied to identify reliably heteroduplexes among the amplification products. The electrophoretic migration of the heteroduplexes observed after PCR was used to detect the presence of 16S rDNAs with different sequences in DNA extracted from both a mixture of two bacterial species and samples containing a natural bacterial community.

Genetic and antigenic characterization of 14 wild-type measles viruses isolated from four provinces in the People's Republic of China during 1993 and 1994 was conducted. Sequence analyses of the hemagglutinin (H) and nucleoprotein (N) genes indicated that 13 of the 14 Chinese viruses comprised a previously undescribed genetic group. Viruses from this unique group were the most genetically diverse measles viruses described, so far. The Chinese viruses differed from other wild-type viruses by as much as 6.9% in the H gene and 7.0% in the N gene at the nucleotide level. One of the 14 viruses was a member of the same genetic group that contains the Edmonston strain. Antigenic analysis using monoclonal antibodies to the H protein did not detect significant differences in binding patterns between the Chinese viruses and other wild-type measles viruses. In addition, representative viruses from the unique Chinese group were neutralized by both human post-vaccination antiserum and mouse antiserum against the H protein of the Edmonston vaccine virus. Viruses closely related to these Chinese viruses were also associated with importations of measles into the United States during 1997 from Vietnam and Hong Kong suggesting that viruses from this new genetic group continue to circulate in China and possibly other parts of Asia.

Wild-type measles viruses have been divided into distinct genetic groups according to the nucleotide sequences of their hemagglutinin and nucleoprotein genes. Most genetic groups have worldwide distribution; however, at least two of the groups appear to have a more limited circulation. To monitor the transmission pathways of measles virus, we observed the geographic distribution of genetic groups, as well as changes in them in a particular region over time. We found evidence of interruption of indigenous transmission of measles in the United States after 1993 and identified the sources of imported virus associated with cases and outbreaks after 1993. The pattern of measles genetic groups provided a means to describe measles outbreaks and assess the extent of virus circulation in a given area. We expect that molecular epidemiologic studies will become a powerful tool for evaluating strategies to control, eliminate, and eventually eradicate measles.