Immunological relationships between parainfluenza virus type 4 and other paramyxoviruses studied by use of monoclonal antibodies

The Role of Nucleoprotein in Immunity to Human Negative-Stranded RNA Viruses—Not Just Another Brick in the Viral Nucleocapsid

Negative-stranded RNA viruses (NSVs) are important human pathogens, including emerging and reemerging viruses that cause respiratory, hemorrhagic and other severe illnesses. Vaccine design traditionally relies on the viral surface glycoproteins. However, surface glycoproteins rarely elicit effective long-term immunity due to high variability. Therefore, an alternative approach is to include conserved structural proteins such as nucleoprotein (NP). NP is engaged in myriad processes in the viral life cycle: coating and protection of viral RNA, regulation of transcription/replication processes and induction of immunosuppression of the host. A broad heterosubtypic T-cellular protection was ascribed very early to this protein. In contrast, the understanding of the humoral immunity to NP is very limited in spite of the high titer of non-neutralizing NP-specific antibodies raised upon natural infection or immunization. In this review, the data with important implications for the understanding of the role of NP in the immune response to human NSVs are revisited. Major implications of the elicited T-cell immune responses to NP are evaluated, and the possible multiple mechanisms of the neglected humoral response to NP are discussed. The intention of this review is to remind that NP is a very promising target for the development of future vaccines.

Differential durability of immune responses to measles and mumps following MMR vaccination

The development and wide-spread use of mumps vaccine resulted in a dramatic and sustained decrease in the incidence of mumps disease; however, since 2000, an increase in the size and number of mumps outbreaks in the United States and other countries has sparked renewed interest in the durability of mumps-specific immunity elicited by mumps vaccination. The most likely explanation for mumps cases in previously immunized persons may be secondary vaccine failure, or waning immunity. In the current study, we examined changes in markers of measles and mumps immunity at two timepoints, approximately 7 and 17 years after two-dose MMR-II® vaccination, in a cohort of 98 healthy adults. Our results indicate that mumps IgG titers exhibited a large and significant decline during this time period, while mumps neutralizing Ab titers were relatively stable. There was a similar discrepancy with measles-specific immune responses. For both pathogens, neutralizing antibody titers were fairly low and, given the length of time since vaccination, may have already declined. These data suggest that specific immune outcomes may wane at different rates and highlight our currently incomplete understanding of protective immune responses to mumps and measles.

Evaluating a parainfluenza virus 5-based vaccine in a host with pre-existing immunity against parainfluenza virus 5

Parainfluenza virus 5 (PIV5), formerly known as simian virus 5 (SV5), is a paramyxovirus often referred to as canine parainfluenza virus (CPI) in the veterinary field. PIV5 is thought to be a contributing factor to kennel cough. Kennel cough vaccines containing live PIV5 have been used in dogs for many decades. PIV5 is not known to cause any diseases in humans or other animals. PIV5 has been used as a vector for vaccine development for humans and animals. One critical question concerning the use of PIV5 as a vector is whether prior exposure to PIV5 would prevent the use of PIV5-based vaccines. In this work, we have examined immunogenicity of a recombinant PIV5 expressing hemagglutinin (HA) of influenza A virus subtype 3 (rPIV5-H3) in dogs that were immunized against PIV5. We found that vaccination of the dogs containing neutralizing antibodies against PIV5 with rPIV5-H3 generated immunity against influenza A virus, indicting that PIV5-based vaccine is immunogenic in dogs with prior exposure. Furthermore, we have examined exposure of PIV5 in human populations. We have detected neutralizing antibody (nAb) against PIV5 in 13 out of 45 human serum samples (about 29 percent). The nAb titers in humans were lower than that in vaccinated dogs, suggesting that nAb in humans is unlikely to prevent PIV5 from being an efficacious vector in humans.

Recombinant parainfluenza virus 5 (PIV5) expressing the influenza A virus hemagglutinin provides immunity in mice to influenza A virus challenge

Parainfluenza virus type 5 (PIV5), formerly known as simian virus 5 (SV5), is a non-segmented negative strand RNA virus that offers several advantages as a vaccine vector. PIV5 infects many cell types causing little cytopathic effect, it replicates in the cytoplasm of infected cells, and does not have a DNA phase in its life cycle thus avoiding the possibility of introducing foreign genes into the host DNA genome. Importantly, PIV5 can infect humans but it is not associated with any known human illness. PIV5 grows well in tissue culture cells, including Vero cells, which have been approved for vaccine production, and the virus can be obtained easily from the media. To test the feasibility of using PIV5 as a live vaccine vector, the hemagglutinin (HA) gene from influenza A virus strain A/Udorn/72 (H3N2) was inserted into the PIV5 genome as an extra gene between the hemagglutinin-neuraminidase (HN) gene and the large (L) polymerase gene. Recombinant PIV5 containing the HA gene of Udorn (rPIV5-H3) was recovered and it replicated similarly to wild type PIV5, both in vitro and in vivo. The HA protein expressed by rPIV5-H3-infected cells was incorporated into the virions and addition of the HA gene did not increase virus virulence in mice. The efficacy of rPIV5-H3 as a live vaccine was examined in 6-week-old BALB/c mice. The results show that a single dose inoculation provides broad and considerable immunity against influenza A virus infection.

Methods for subtyping and molecular comparison of human viral genomes

The development over the past two decades of molecular methods for manipulation of RNA and DNA has afforded molecular virologists the ability to study viral genomes in detail that has heretofore not been possible. There are many molecular techniques now available for typing and subtyping of viruses. The available methods include restriction fragment length polymorphism analysis, Southern blot analysis, oligonucleotide fingerprint analysis, reverse hybridization, DNA enzyme immunoassay, RNase protection analysis, single-strand conformation polymorphism analysis, heteroduplex mobility assay, nucleotide sequencing, and genome segment length polymorphism analysis. The methods have certain advantages and disadvantages which should be considered in their application to specific viruses or for specific purposes. These techniques are likely to become more widely used in the future for epidemiologic studies and for investigations into the pathophysiology of virus infections.

Multiple amino acid substitutions in the HN protein of the paramyxovirus, SV5, are selected for in monoclonal antibody resistant mutants

Monoclonal antibody resistant (MAR) mutants (which escaped antibody-mediated neutralization) were selected from simian (W 3) and human (LN) isolates of simian virus 5 (SV 5), using monoclonal antibodies (MAbs) specific for antigenic sites 4 and 5 on the HN glycoprotein. Resistance correlated with an inability of the selecting antibody to bind with the respective MAR mutants. Sequence comparisons between parental and mutant HN proteins revealed multiple non-adjacent amino acid substitutions in the majority of MAR mutants. The same multiple substitutions were identified in mutants selected from both the LN and W 3 isolates of SV 5. Furthermore, different mutations on the primary sequence of the HN protein conferred resistance to the same MAb.