Michael Nickells scite author profile

SummaryErythrocytes (E) lacking high incidence blood group antigens were screened by an antiglobulin test with a monoclonal antibody to human complement receptor type 1 (CR1 ; C3b/C4b receptor; CD35) . Some examples of E lacking Knops, McCoy, Swain-Langley, and York antigens, a serologically related group, were not agglutinated . Moreover, E of the null phenotype for these same antigens were nonreactive. To further explore this relationship, E expressing these antigens were surface labeled, solubilized, and incubated with the corresponding blood group-specific antisera. CR1 was immunoprecipitated, indicating that the epitopes recognized by each of these antisera are expressed on CR1 .

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Quasispecies Heterogeneity within the E1/E2 Region as a Pretreatment Variable during Pegylated Interferon Therapy of Chronic Hepatitis C Virus Infection

Chambers

Fan

Droll

et al. 2005

J Virol

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A series of 29 patients undergoing treatment for chronic hepatitis C virus (HCV) genotype 1 infection with pegylated alpha-2a interferon plus ribavirin were studied for patterns of response to antiviral therapy and viral quasispecies evolution. All patients were treatment naive and had chronic inflammation and fibrosis on biopsy. As part of an analysis of pretreatment variables that might affect the outcome of treatment, genetic heterogeneity within the viral E1-E2 glycoprotein region (nucleotides 851 to 2280) was assessed by sequencing 10 to 15 quasispecies clones per patient from serum-derived PCR products. Genetic parameters were examined with respect to response to therapy based on serum viral RNA loads at 12 weeks (early viral response) and at 24 weeks posttreatment (sustained viral response). Nucleotide and amino acid quasispecies complexities of the hypervariable region 1 (HVR-1) were less in the responder group in comparison to the nonresponder group at 12 weeks, and genetic diversity was also less both within and outside of the HVR-1, with the difference being most pronounced for the non-HVR-1 region of E2. However, these genetic parameters did not distinguish responders from nonresponders for sustained viral responses. Follow-up studies of genetic heterogeneity based on the HVR-1 in selected responders and nonresponders while on therapy revealed greater evolutionary drift in the responder subgroup. The pretreatment population sequences for the NS5A interferon sensitivity determinant region were also analyzed for all patients, but no correlations were found between treatment response and any distinct genetic markers. These findings support previous studies indicating a high level of genetic heterogeneity among chronically infected HCV patients. One interpretation of these data is that early viral responses are governed to some extent by viral factors, whereas sustained responses may be more influenced by host factors, in addition to effects of viral complexity and diversity.

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Neuroadapted Yellow Fever Virus 17D: Genetic and Biological Characterization of a Highly Mouse-Neurovirulent Virus and Its Infectious Molecular Clone

Chambers

Nickells

2001

J Virol

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A neuroadapted strain of yellow fever virus (YFV) 17D derived from a multiply mouse brain-passaged virus (Porterfield YF17D) was additionally passaged in SCID and normal mice. The virulence properties of this virus (SPYF) could be distinguished from nonneuroadapted virus (YF5.2iv, 17D infectious clone) by decreased average survival time in SCID mice after peripheral inoculation, decreased average survival time in normal adult mice after intracerebral inoculation, and occurrence of neuroinvasiveness in normal mice. SPYF exhibited more efficient growth in peripheral tissues of SCID mice than YF5.2iv, resulting in a more rapid accumulation of virus burden, but with low-titer viremia, at the time of fatal encephalitis. In cell culture, SPYF was less efficient in replication than YF5.2iv in all cell lines tested. The complete nucleotide sequence of SPYF revealed 29 nucleotide substitutions relative to YF5.2iv, and these were distributed throughout the genome. There were a total of 13 predicted amino acid substitutions, some of which correspond to known differences among the Asibi, French viscerotropic virus, French neurotropic vaccine, and YF17D vaccine strains. The envelope (E) protein contained five substitutions, within all three functional domains. Substitutions were also present in regions encoding the NS1, NS2A, NS4A, and NS5 proteins and in the 3 untranslated region (UTR). Construction of YFV harboring all of the identified coding nucleotide substitutions and those in the 3 UTR yielded a virus whose cell culture and pathogenic properties, particularly neurovirulence and neuroinvasiveness for SCID mice, generally resembled those of the original SPYF isolate. These findings implicate the E protein and possibly other regions of the genome as virulence determinants during pathogenesis of neuroadapted YF17D virus in mice. The determinants affect replication efficiency in both neural and extraneural tissues of the mouse and confer some limited host-range differences in cultured cells of nonmurine origin.Viruses within the Flavivirus genus of the family Flaviviridae are generally neurotropic, exhibiting various degrees of neurovirulence in rodent and primate hosts (41). Introduction of virus into the murine central nervous system (CNS) causes an acute encephalitis, the outcome of which can be influenced by the dose of virus and the age and strain of the mouse (15). Different strains of yellow fever virus (YFV) can be distinguished by their level of mouse neurovirulence (5,15,28,(52)(53)(54), and this property can be enhanced by serial passage of the virus in mouse brain (37,56,59). This neuroadaptation has also been observed with other flaviviruses (7,11,25). Genetic analyses of viruses which differ in their virulence properties have commonly focused on the envelope (E) protein, for which a variety of mutations have been shown to modulate neurovirulence (reviewed in reference 36). Regarding YFV, nucleotide sequence analysis of the partially attenuated French neurotropic virus (FNV) strain of YFV which was derived by ...

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Mapping epitopes for 20 monoclonal antibodies to CR1

Nickells

Hauhart

Krych

et al. 1998

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Complement receptor type one (CR1; CD35) binds and processes C3b and C4b opsonized immune complexes and regulates complement activation. We have characterized the epitopes of 13 previously reported and seven new MoAbs to human CR1. The MoAbs formed seven groups based on their reactivity with a panel of deletion forms of CR1. Seventeen of the MoAbs reacted with CR1 at more than one site, a consequence of its repetitive sequence. All five of the MoAbs recognizing epitopes in the nearly identical repeats 3, 10, and 17, as well as one MoAb which reacted with repeats 8 or 1/2 of 9 and 15 or 1/2 of 16, blocked cofactor activity for C3b. Knowledge of the repeats bearing the epitopes for these MoAbs should facilitate the further characterization of CR1.

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Yellow fever virus NS2B–NS3 protease: characterization of charged-to-alanine mutant and revertant viruses and analysis of polyprotein-cleavage activities

Chambers

Droll

Tang

et al. 2005

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A series of 46 charged-to-alanine mutations in the yellow fever virus NS2B-NS3 protease, previously characterized in cell-free and transient cellular expression systems, was tested for their effects on virus recovery. Four distinct plaque phenotypes were observed in cell culture: parental plaque-size (13 mutants), reduced plaque-size (17 mutants), small plaque-size (8 mutants) and no plaque-formation (8 mutants). No mutants displayed any temperature sensitivity based on recovery of virus after RNA transfection at 32 versus 37 6C. Most small plaque-mutants were defective in growth efficiency compared with parental virus. However not all small plaque-mutants had defective 2B/3 cleavage, with some showing selective defects at other non-structural protein cleavage sites. Revertant viruses were recovered for six mutations that caused reduced plaque sizes. Same-site and second-site mutations occurred in NS2B, and one second-site mutation occurred in the NS3 protease domain. Some reversion mutations ameliorated defects in cleavage activity and plaque size caused by the original mutation. These data indicate that certain mutations that reduce NS2B-NS3 protease cleavage activity cause growth restriction of yellow fever virus in cell culture. However, for at least two mutations, processing defects other than impaired cleavage activity at the 2B/3 site may account for the mutant phenotype. The existence of reversion mutations primarily in NS2B rather than NS3, suggests that the protease domain is less tolerant of structural perturbation compared with the NS2B protein.

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