Cell-mediated immune response to mumps virus infection in man.

The antibody and cell-mediated immune response to mumps virus infection was studied in groups of subjects after natrually acquired mumps virus infection, after parenteral immunization with live attenuated mumps vaccine, and in a population of mumps seronegative subjects. The technique of neutralization of tissue culture infectivity was utilized to study mumps specific antibody. The cell-mediated immunity (CMI) was detected by specific immune release (SIR) of radioactivity by purified lymphocytes after they were reacted with radioactive chromium (51Cr) labeled human conjunctival cell cultures chronically infected with mumps virus. No SIR activity was observed in lymphocytes obtained from cord blood and young individuals seronegative for antibody to mumps virus. Detectable SIR activity was observed in a few older seronegative subjects; however, immunization with mumps vaccine in such antibody negative subjects failed to result in the development of any antibody response in the serum. High SIR activity was observed in the lymphocytes of naturally infected and vaccinated subjects. Although all naturally infected or immunized subjects had varying levels of mumps specific antibody activity in the serum, no correlation existed between the levels of antibody and SIR activity. These observations suggest the development of mumps specific in vitro correlates of CMI after naturally acquired or vaccine-induced mumps virus infection.     

Polypeptides of mumps virus.

Mumps virus was propagated in the extra-embryonic fluids of embryonated chicken eggs and was labeled by cionjection of radioactively labeled amino acids. The virus was purified by density gradient centrifugation, and its polypeptides were analyzed by polyarylamide gel electrophoresis. The virus was found to be composed of six polypeptides, ranging in size from 40,000 to 64,000 daltons. Viral proteins 1 and 3 were the glycoproteins of the virons. When the virus particle was treated with noniontic detergents, a small fraction of these glycoproteins could be released into the supernatant. After treatment with nonionic detergents in high salt and alkaline conditions, more of the surface glycoproteins were removed. This treatment also released the smallest viral polypeptide from the virion. The glycoproteins were separated using an affinity chromatographic column of agarose-fetuin. The heavier glycoprotein, viral protein 1, was found to contain both the neuraminidase and hemagglutinating activity. The two glycoproteins were tested for their ability to react in complement-fixing tests with mumps antisera. Only the heavier glycoprotein reacted with antisera possessing both anti-S and anti-V activity. Neither glycoprotein reacted with antisera specific for the S antigen. Thus, it was concluded that this glycoprotein corresponds to the classical V antigen of mumps virus.     

Neurovirulence of mumps virus: intraspinal inoculation test in marmosets.

An intraspinal inoculation test of mumps virus using marmosets was performed in order to develop a neurovirulence test of mumps vaccines. In the group inoculated with non-neurovirulent Jeryl Lynn vaccine strain at 10(2.0) pfu/dose, there were only minimal histopathological changes in 3 of the 5 marmosets. In contrast, all marmosets inoculated with neurovirulent Urabe and NK-M46 vaccine strains developed extensive encephalitis and meningitis. Thus, this marmoset model, which can distinguish between non-neurovirulent and neurovirulent vaccine strains, is useful for evaluating neurovirulence of vaccine strains and elucidating the molecular pathogenesis of mumps.     

Analysis of mumps virus defectiveness in vitro

The efficiency of mumps virus replication (EOR) was determined by comparing the multiplicity of infectious input (MOI) with the multiplicity of viral production (MOP). The replication kinetics of low passage wild, high passage laboratory and attenuated vaccine virus were evaluated using regular stock and cloned pools of virus (Table). The EOR of stock wild virus was 2.8, 4-fold greater than stock vaccine virus (0.7), and 300-fold greater than stock laboratory virus (0.009). The EOR of vaccine and laboratory virus was increased strikingly by double cloning, 0.7 to 2.0 and 0.009 to 3.7, respectively, while such limiting dilution hemadsorption plaquing techniques, employed to eliminate defective virions, reduced the EOR of wild virus (2.8 to 0.6).