Gregory R. Reyes scite author profile

We have recently described the cloning of a portion of the hepatitis E virus (HEV) and confirmed its etiologic association with enterically transmitted (waterborne, epidemic) non-A, non-B hepatitis. The virus consists of a single-stranded, positive-sense RNA genome of approximately 7.5 kb, with a polyadenylated 3' end. We now report on the cloning and nucleotide sequencing of an overlapping, contiguous set of cDNA clones representing the entire genome of the HEV Burma strain [HEV(B)]. The largest open reading frame extends approximately 5 kb from the 5' end and contains the RNA-directed RNA polymerase and nucleoside triphosphate binding motifs. The second major open reading frame (ORF2) begins 37 bp downstream of the first and extends approximately 2 kb to the termination codon present 65 bp from the 3' terminal stretch of poly(A) residues. ORF2 contains a consensus signal peptide sequence at its amino terminus and a capsid-like region with a high content of basic amino acids similar to that seen with other virus capsid proteins. A third open reading frame partially overlaps the first and second and encompasses only 369 bp. In addition to the 7.5-kb full-length genomic transcript, two subgenomic polyadenylated messages of approximately 3.7 and 2.0 kb were detected in infected liver using a probe from the 3' third of the genome. The genomic organization of the virus is consistent with the 5' end encoding nonstructural and the 3' end encoding the viral structural gene(s). The expression strategy of the virus involves the use of three different open reading frames and at least three different transcripts. HEV was previously determined to be a nonenveloped particle with a diameter of 27-34 nm. These findings on the genetic organization and expression strategy of HEV suggest that it is the prototype human pathogen for a new class of RNA virus or perhaps a separate genus within the Caliciviridae family. o tsst Academic PWSS, IIX.

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Computer-assisted assignment of functional domains in the nonstructural polyprotein of hepatitis E virus: delineation of an additional group of positive-strand RNA plant and animal viruses.

Koonin¹,

Gorbalenya²,

Purdy³

et al. 1992

Proc. Natl. Acad. Sci. U.S.A.

468

520

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Computer-assisted comparison of the nonstructural polyprotein of hepatitis E virus (HEV) with proteins of other positive-strand RNA viruses allowed the identification of the following putative functional domains: (i) RNAdependent RNA polymerase, (ii) RNA helicase, (iii) methyltransferase, (iv) a domain of unknown function ("X" domain) flanking the papain-like protease domains in the polyproteins of animal positive-strand RNA viruses, and (v) papain-like cysteine protease domain distantly related to the putative papain-like protease of rubella virus (RubV). Comparative analysis of the polymerase and helicase sequences of positivestrand RNA viruses belonging to the so-called "alpha-like" supergroup revealed grouping between 1EV, RubV, and beet necrotic yellow vein virus (BNYVV), a plant furovirus. Two additional domains have been identified: one showed significant conservation between HEV, RubV, and BNYVV, and the other showed conservation specifically between HEV and RubV. The large nonstructural proteins of HEV, RubV, and BNYVV retained similar domain organization, with the exceptions of relocation of the putative protease domain in 11EV as compared to RubV and the absence of the protease and X domains in BNYVV. These observations show that HEV, RubV, and BNYVV encompass partially conserved arrays of distinctive putative functional domains, suggesting that these viruses constitute a distinct monophyletic group within the alpha-like supergroup of positive-strand RNA viruses.Hepatitis E virus (HEV) is the causative agent of the enterically transmitted form of non-A, non-B hepatitis, a disease of significant epidemiologic importance (1, 2). HEV has been found in stools from hepatitis patients as naked isometric virus-like particles of about 32-34 nm in diameter (3, 4). It has been shown that the HEV genome is a single-stranded polyadenylylated RNA of about 7.5 kilobases (5). Recently the HEV genome has been cloned as cDNA (5, 6), and its complete nucleotide sequence has been determined (7,8). The positive-sense RNA of HEV encompasses three large open reading frames (ORFs): the largest ORF (5' end) consists of 1693 codons, the second ORF (3' end) is composed of 660 codons, and the third ORF consists of 123 codons that overlap the first and the second ORFs. By analogy with other positive-strand RNA animal viruses, such as alphaviruses (9), rubella virus (RubV), (10) and caliciviruses (11), it was tempting to speculate that the 660-codon ORF encodes the capsid protein(s) of HEV, whereas the product of the largest 5' ORF should be the nonstructural polyprotein, which is probably cleaved to yield functional viral proteins (7,8). The function of the smallest ORF is not known, but there are indications that it is expressed in infected humans (12).Comparative analyses of the sequences of nonstructural proteins encoded by positive-strand RNA viruses have yielded a considerable collection of functional domains with varying degrees of conservation. Various subsets of this "pool" are combined in polyproteins (or large ...

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Endoproteolytic cleavage of gp160 is required for the activation of human immunodeficiency virus

McCune

Rabin²,

Feinberg

et al. 1988

Cell

593

406

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Isolation of a cDNA from the Virus Responsible for Enterically Transmitted Non-A, Non-B Hepatitis

Reyes¹,

Purdy

Kim³

et al. 1990

Science

792

393

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Major epidemic outbreaks of viral hepatitis in underdeveloped countries result from a type of non-A, non-B hepatitis distinct from the parenterally transmitted form. The viral agent responsible for this form of epidemic, or enterically transmitted non-A, non-B hepatitis (ET-NANBH), has been serially transmitted in cynomolgus macaques (cynos) and has resulted in typical elevation in liver enzymes and the detection of characteristic virus-like particles (VLPs) in both feces and bile. Infectious bile was used for the construction of recombinant complementary DNA libraries. One clone, ET1.1, was exogenous to uninfected human and cyno genomic liver DNA, as well as to genomic DNA from infected cyno liver. ET1.1 did however, hybridize to an approximately 7.6-kilobase RNA species present only in infected cyno liver. The translated nucleic acid sequence of a portion of ET1.1 had a consensus amino acid motif consistent with an RNA-directed RNA polymerase; this enzyme is present in all positive strand RNA viruses. Furthermore, ET1.1 specifically identified similar sequences in complementary DNA prepared from infected human fecal samples collected from five geographically distinct ET-NANBH outbreaks. Therefore, ET1.1 represents a portion of the genome of the principal viral agent, to be named hepatitis E virus, which is responsible for epidemic outbreaks of ET-NANBH.

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HIV-1 escape from a small molecule, CCR5-specific entry inhibitor does not involve CXCR4 use

Trkola

Kuhmann

Strizki

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

294

300

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To study HIV-1 escape from a coreceptor antagonist, the R5 primary isolate CC1͞85 was passaged in peripheral blood mononuclear cells with increasing concentrations of the CCR5-specific small molecule inhibitor, AD101. By 19 passages, an escape mutant emerged with a >20,000-fold resistance to AD101. This virus was cross-resistant to a related inhibitor, SCH-C, and partially resistant to RANTES but still sensitive to CCR5-specific mAbs. The resistant phenotype was stable; the mutant virus retained AD101 resistance during nine additional passages of culture in the absence of inhibitor. Replication of the escape mutant in peripheral blood mononuclear cells completely depended on CCR5 expression and did not occur in cells from CCR5-⌬32 homozygous individuals. The escape mutant was unable to use CXCR4 or any other tested coreceptor to enter transfected cells. Acquisition of CXCR4 use is not the dominant in vitro escape pathway for a small molecule CCR5 entry inhibitor. Instead, HIV-1 acquires the ability to use CCR5 despite the inhibitor, first by requiring lower levels of CCR5 for entry and then probably by using the drug-bound form of the receptor.

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Gregory R. Reyes

Hepatitis E virus (HEV): Molecular cloning and sequencing of the full-length viral genome

Computer-assisted assignment of functional domains in the nonstructural polyprotein of hepatitis E virus: delineation of an additional group of positive-strand RNA plant and animal viruses.

Endoproteolytic cleavage of gp160 is required for the activation of human immunodeficiency virus

Isolation of a cDNA from the Virus Responsible for Enterically Transmitted Non-A, Non-B Hepatitis

HIV-1 escape from a small molecule, CCR5-specific entry inhibitor does not involve CXCR4 use

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