Attenuation and efficacy of human parainfluenza virus type 1 (HPIV1) vaccine candidates containing stabilized mutations in the P/C and L genes

<p>Abstract</p> <p>Background</p> <p>Two recombinant, live attenuated human parainfluenza virus type 1 (rHPIV1) mutant viruses have been developed, using a reverse genetics system, for evaluation as potential intranasal vaccine candidates. These rHPIV1 vaccine candidates have two non-temperature sensitive (non-<it>ts</it>) attenuating (<it>att</it>) mutations primarily in the P/C gene, namely C^R84GHN^T553A(two point mutations used together as a set) and C^Δ170(a short deletion mutation), and two <it>ts att </it>mutations in the L gene, namely L^Y942A(a point mutation), and L^Δ1710–11(a short deletion), the last of which has not been previously described. The latter three mutations were specifically designed for increased genetic and phenotypic stability. These mutations were evaluated on the HPIV1 backbone, both individually and in combination, for attenuation, immunogenicity, and protective efficacy in African green monkeys (AGMs).</p> <p>Results</p> <p>The rHPIV1 mutant bearing the novel L^Δ1710–11mutation was highly <it>ts </it>and attenuated in AGMs and was immunogenic and efficacious against HPIV1 wt challenge. The rHPIV1-C^R84G/Δ170HN^T553AL^Y942Aand rHPIV1-C^R84G/Δ170HN^T553AL^Δ1710–11vaccine candidates were highly <it>ts</it>, with shut-off temperatures of 38°C and 35°C, respectively, and were highly attenuated in AGMs. Immunization with rHPIV1-C^R84G/Δ170HN^T553AL^Y942Aprotected against HPIV1 wt challenge in both the upper and lower respiratory tracts. In contrast, rHPIV1-C^R84G/Δ170HN^T553AL^Δ1710–11was not protective in AGMs due to over-attenuation, but it is expected to replicate more efficiently and be more immunogenic in the natural human host.</p> <p>Conclusion</p> <p>The rHPIV1-C^R84G/Δ170HN^T553AL^Y942Aand rHPIV1-C^R84G/Δ170HN^T553AL^Δ1710–11vaccine candidates are clearly highly attenuated in AGMs and clinical trials are planned to address safety and immunogenicity in humans.</p

Chimeric Recombinant Human Metapneumoviruses with the Nucleoprotein or Phosphoprotein Open Reading Frame Replaced by That of Avian Metapneumovirus Exhibit Improved Growth In Vitro and Attenuation In Vivo

Chimeric versions of recombinant human metapneumovirus (HMPV) were generated by replacing the nucleoprotein (N) or phosphoprotein (P) open reading frame with its counterpart from the closely related avian metapneumovirus (AMPV) subgroup C. In Vero cells, AMPV replicated to an approximately 100-fold-higher titer than HMPV. Surprisingly, the N and P chimeric viruses replicated to a peak titer that was 11- and 25-fold higher, respectively, than that of parental HMPV. The basis for this effect is not known but was not due to obvious changes in the efficiency of gene expression. AMPV and the N and P chimeras were evaluated for replication, immunogenicity, and protective efficacy in hamsters. AMPV was attenuated compared to HMPV in this mammalian host on day 5 postinfection, but not on day 3, and only in the nasal turbinates. In contrast, the N and P chimeras were reduced approximately 100-fold in both the upper and lower respiratory tract on day 3 postinfection, although there was little difference by day 5. The N and P chimeras induced a high level of neutralizing serum antibodies and protective efficacy against HMPV; AMPV was only weakly immunogenic and protective against HMPV challenge, reflecting antigenic differences. In African green monkeys immunized intranasally and intratracheally, the mean peak titer of the P chimera was reduced 100- and 1,000-fold in the upper and lower respiratory tracts, whereas the N chimera was reduced only 10-fold in the lower respiratory tract. Both chimeras were comparable to wild-type HMPV in immunogenicity and protective efficacy. Thus, the P chimera is a promising live HMPV vaccine candidate that paradoxically combines improved growth in vitro with attenuation in vivo

The Genome Length of Human Parainfluenza Virus Type 2 Follows the Rule of Six, and Recombinant Viruses Recovered from Non-Polyhexameric-Length Antigenomic cDNAs Contain a Biased Distribution of Correcting Mutations

Members of the Paramyxovirinae subfamily of the Paramyxoviridae family of viruses have the unusual requirement that the nucleotide length of the viral genome must be an even multiple of six in order for efficient RNA replication, and hence virus replication, to occur. Human parainfluenza virus type 2 (HPIV2) is the only member of the genus that has been reported to have a genome length that is not an even multiple of six, and it has also been recovered from a full-length antigenomic-sense cDNA that did not conform to the “rule of six.” To reexamine the issue of nucleotide length in natural isolates of HPIV2, a complete consensus genomic sequence was determined for three HPIV2 strains: Greer, Vanderbilt/1994 (V94), and Vanderbilt/1998. Each of these strains was found to have a genome length of 15,654 nucleotides (nt), thus conforming in each case to the rule of six. To directly examine the requirement that the genomic length of HPIV2 be an even multiple of six, we constructed six full-length antigenomic HPIV2/V94 cDNAs that deviated from a polyhexameric length by 0 to 5 nt. Recombinant HPIV2s were readily recovered from all of the cDNAs, including those that did not conform to the rule of six. One recombinant HPIV2 isolate was completely sequenced for each of the nonpolyhexameric antigenomic cDNAs. These were found to contain small nucleotide insertions or deletions that conferred polyhexameric length to the recovered genome. Interestingly, almost all of the length corrections occurred within the hemagglutinin-neuraminidase and large polymerase genes or the intervening intergenic region and thus were proximal to the insert that caused the deviation from the rule of six. These results demonstrate, in the context of complete infectious virus, that HPIV2 has a strong and seemingly absolute requirement for a polyhexameric genome

Infection of Nonhuman Primates with Recombinant Human Metapneumovirus Lacking the SH, G, or M2-2 Protein Categorizes Each as a Nonessential Accessory Protein and Identifies Vaccine Candidates

Recombinant human metapneumovirus (HMPV) in which the SH, G, or M2 gene or open reading frame was deleted by reverse genetics was evaluated for replication and vaccine efficacy following topical administration to the respiratory tract of African green monkeys, a permissive primate host. Replication of the ΔSH virus was only marginally less efficient than that of wild-type HMPV, whereas the ΔG and ΔM2-2 viruses were reduced sixfold and 160-fold in the upper respiratory tract and 3,200-fold and 4,000-fold in the lower respiratory tract, respectively. Even with the highly attenuated mutants, there was unequivocal HMPV replication at each anatomical site in each animal. Thus, none of these three proteins is essential for HMPV replication in a primate host, although G and M2-2 increased the efficiency of replication. Each gene-deletion virus was highly immunogenic and protective against wild-type HMPV challenge. The ΔG and ΔM2-2 viruses are promising vaccine candidates that are based on independent mechanisms of attenuation and are appropriate for clinical evaluation

Modification of the Trypsin-Dependent Cleavage Activation Site of the Human Metapneumovirus Fusion Protein To Be Trypsin Independent Does Not Increase Replication or Spread in Rodents or Nonhuman Primates

The contribution of cleavage activation of the fusion F protein of human metapneumovirus (HMPV) to replication and pathogenicity in rodents and nonhuman primates was investigated. Recombinant HMPVs were generated in which the naturally occurring trypsin-dependent cleavage sequence (R-Q-S-R↓) was replaced by each of three sequences whose cleavage in vitro does not depend upon added trypsin. Two of these were multibasic sequences derived from avian metapneumovirus type A (R-R-R-R) or type C (R-K-A-R), with the former containing the consensus furin protease cleavage motif (R-X-R/K-R↓). The third one (R-Q-P-R) was derived from a recently described trypsin independent HMPV isolate (J. H. Schickli, J. Kaur, N. Ulbrandt, R. R. Spaete, and R. S. Tang, J. Virol. 79:10678-10689, 2005). To preclude the possibility of conferring even greater virulence to this significant human pathogen, the modifications were done in an HMPV variant that was attenuated by the deletion of two of the three envelope glycoproteins, SH and G. Each of the introduced cleavage sequences conferred trypsin independent F cleavage and growth to HMPV in vitro. However, they differed in the efficiency of trypsin independent growth and plaque formation in vitro: R-R-R-R > R-K-A-R > R-Q-P-R > R-Q-S-R. The R-R-R-R mutant was the only one whose growth in vitro was not augmented by added trypsin, indicative of highly efficient trypsin independent cleavage. When inoculated intranasally into hamsters, there was essentially no difference in the magnitude of replication in the upper or lower respiratory tract between the mutants, and virus was not detected in organs outside of the respiratory tract. Evaluation of the most cleavage-efficient mutant, R-R-R-R, in African green monkeys showed that there was no detectable change in the magnitude of replication in the upper and lower respiratory tract or in immunogenicity and protective efficacy against HMPV challenge. These results suggest that cleavage activation is not a major determinant of HMPV virulence