Naturally occurring human parainfluenza type 3 viruses exhibit divergence in amino acid sequence of their fusion protein neutralization epitopes and cleavage sites.

Many human parainfluenza type 3 virus (PIV3) strains isolated from children with respiratory illness are resistant to neutralization by monoclonal antibodies (MAbs) which recognize epitopes in antigenic site A or B of the fusion (F) protein of the prototype 1957 PIV3 strain. The F protein genes of seven PIV3 clinical isolates were sequenced to determine whether their neutralization-resistant phenotypes were associated with specific differences in amino acids which are recognized by neutralizing MAbs. Several clinical strains which were resistant to neutralization by site A or B MAbs had amino acid differences at residues 398 or 73, respectively. These specific changes undoubtedly account for the neutralization-resistant phenotype of these isolates, since identical substitutions at residues 398 or 73 in MAb-selected escape mutants confer resistance to neutralization by site A or B MAbs. The existence of identical changes in naturally occurring and MAb-selected neutralization-resistant PIV3 strains raises the possibility that antigenically different strains may arise by immune selection during replication in partially immune children. Three of the seven clinical strains examined had differences in their F protein cleavage site sequence. Whereas the prototype PIV3 strain has the cleavage site sequence Arg-Thr-Lys-Arg, one clinical isolate had the sequence Arg-Thr-Arg-Arg and two isolates had the sequence Arg-Thr-Glu-Arg. The different cleavage site sequences of these viruses did not affect their level of replication in either continuous simian or bovine kidney cell monolayers (in the presence or absence of exogenous trypsin or plasmin) or in the upper or lower respiratory tract of rhesus monkeys. We conclude that two nonconsecutive basic residues within the F protein cleavage site are sufficient for efficient replication of human PIV3 in primates.

Identification of amino acids recognized by syncytium-inhibiting and neutralizing monoclonal antibodies to the human parainfluenza type 3 virus fusion protein.

Neutralizing monoclonal antibodies specific for the fusion (F) glycoprotein of human parainfluenza type 3 virus (PIV3) were used to select neutralization-resistant antigenic variants. Sequence analysis of the F genes of the variants indicated that their resistance to antibody binding, antibody-mediated neutralization or to both was a result of specific amino acid substitutions within the neutralization epitopes of the F1 and F2 subunits. Comparison of the locations of PIV3 neutralization epitopes with those of Newcastle disease and Sendai viruses indicated that the antigenic organization of the fusion proteins of paramyxoviruses is similar. Furthermore, some of the PIV3 epitopes recognized by syncytium-inhibiting monoclonal antibodies are located in an F1 cysteine cluster region which corresponds to an area of the measles virus F protein involved in fusion activity.

Live viral vaccines for respiratory and enteric tract diseases.

In its programme for accelerated development of vaccines for viral respiratory and enteric tract diseases the WHO has assigned a very high priority to respiratory syncytial virus (RSV), parainfluenza viruses and rotaviruses. There is also some interest in alternative approaches to immunization against influenza viruses because of the failure of inactivated vaccines to provide complete and reasonably durable immunity. Current attempts to develop satisfactorily attenuated viruses for use in prevention of disease caused by the above viral pathogens are described.

Nucleotide sequences for the gene junctions of human respiratory syncytial virus reveal distinctive features of intergenic structure and gene order.

Complete sequences for the intergenic regions of the genome of human respiratory syncytial virus were obtained by dideoxynucleotide sequencing using synthetic oligonucleotides. These experiments established that the 10 respiratory syncytial viral genes are arranged, without additional intervening genes, in the order 3' 1C-1B-N-P-M-1A-G-F-22K-L 5'. For the first nine genes, the exact gene boundaries were identified by comparison of the genomic sequences with previously determined mRNA sequences. The intergenic regions varied in length from 1 to 52 nucleotides and lacked any obvious conserved features of primary or secondary structure except that each sequence ended (3' to 5') with an adenosine residue. The exact start site of the 10th gene, the L gene, was not determined. However, RNA blot hybridization using a synthetic oligonucleotide designed from the genomic sequence mapped the L gene to within 54 nucleotides of the end of the penultimate 22K gene. The lack of conservation of chain length and nucleotide sequence for the respiratory syncytial viral intergenic regions, together with the complexity of the genetic map, contrasts with previous observations for other nonsegmented negative-strand viruses.

Electroelution for purification of influenza A matrix protein for use in immunoassay.

A new preparative method for isolation of matrix protein from type A influenza virus was developed. Commercially available whole virus or split virus vaccines were lysed, and the soluble proteins separated by electrophoresis on polyacrylamide gel. The matrix protein was located on the gel by precipitation with KCl, and recovered by electroelution. The method was technically simple and required little direct supervision during the two-step recovery process. Yields of A matrix were consistently high, averaging 68.1% in five trials with A/Brazil/X-71. The method was also successful with other A viruses, although not with influenza B virus. Isolated A matrix had less than 0.5% contamination by hemagglutinin or nucleoprotein, as determined by immunoblotting and ELISA. Matrix protein was immunoreactive in Western blots and was detectable in concentrations as low as 1 ng/ml with ELISA. The isolated matrix provided a suitable standard for detection of matrix protein in nasal washes from patients with influenza A virus infection, and could also be used to detect anti-matrix antibodies, including monoclonal antibodies in tissue culture supernatants. The advantages of electroelution for separation of matrix protein compared to other methods were its technical simplicity, applicability to formalin-fixed influenza virus in commercially available vaccines, its consistently high yield, and its very high level of purification.