Evaluation of the thermal stability of a novel strain of live-attenuated mumps vaccine (RS-12 strain) lyophilized in different stabilizers.

The stability of live-attenuated viral vaccines is important for immunization efficacy. Here, the thermostabilities of lyophilized live-attenuated mumps vaccine formulations in two different stabilizers, a trehalose dihydrate-based stabilizer and a stabilizer containing sucrose, human serum albumin and sorbitol were investigated using accelerated stability tests at 4°C, 25°C and 37°C at time points between 4h (every 4h for the first 24h) and 1 week. Even under the harshest storage conditions of 37°C for 1 week, the 50% cell culture infective dose (CCID50) determined from titrations in Vero cells dropped by less than 10-fold using each stabilizer formulation and thus complied with the World Health Organization's requirements for the potency of live-attenuated mumps vaccines. However, as the half-life of the RS-12 strain mumps virus infectivity was lengthened substantially at elevated temperatures using the trehalose dihydrate (TD)-based stabilizer, this stabilizer is recommended for vaccine use.

In vitro secondary generation of cytotoxic T lymphocytes in mice with mumps virus and their mumps-specific cytotoxicity among paramyxoviruses.

Murine cells (L929, MC57G, and P815 mastocytoma) defectively infected with the egg-adapted vaccine strain of mumps virus were found to be susceptible to cytotoxic T-lymphocyte (CTL)-mediated lysis. In vitro secondary, but not in vivo primary, generated CTL caused cytolysis of these targets in an H-2-restricted manner. UV-inactivated-mumps virus-coated murine cells were also found to be susceptible to CTL-mediated lysis. Comparisons of murine CTL-mediated lysis by three paramyxoviruses (mumps, Sendai, and Newcastle disease viruses) indicated that no cross-reactivity occurred. The CTL response with mumps virus exhibited specific unresponsiveness patterns, as influenced by the H-2 K/D regions of the mouse strains, that were partially different from those of Sendai virus and Newcastle disease virus.

Mumps virus-induced enhancement of the in vitro cytotoxicity of cord blood lymphocytes.

Purified lymphocytes from the umbilical cord of healthy donors (CBL) displayed lower natural cytotoxicity (NK) and antibody-dependent cellular cytotoxicity (ADCC) than peripheral blood (PBL) from adult donors. In contrast, CBL treated with small amounts of UV-inactivated or live mumps virions expressed the same level of enhanced cytotoxicity (virus-dependent cytotoxicity (VDCC)) against non-infected target cells as PBL. For individual CBL donors there was no correlation between the level of NK and VDCC, indicating involvement of partly distinct effector cell populations. The heterogeneity of the effector cells active in VDCC was confirmed by cell fractionation experiments. The major CBL effector cells in NK and ADCC were found in 'non-T' lymphocyte fractions and/or in fractions containing cells with high-avidity receptors for IgG. In contrast, CBL fractions consisting of about 100% lymphocytes bearing T-cell markers and depleted of Fc gamma R+ cells were strongly cytotoxic in VDCC when T24 cells (human bladder carcinoma) were the targets. With two other target cell types of similar susceptibility to VDCC, the cytotoxic activity of T-cell-containing fractions was less pronounced, indicating that the target cells play an active role in effector cell selection. The surface marker profiles of the VDCC effector cells were the same for CBL and adult PBL. Incubation of CBL with UV-inactivated virions usually gave no significant stimulation of DNA synthesis above that seen in virus-free controls. Taken together, our results suggest that neither specific recognition of viral antigen by T cells nor mitogenic effects of viral material are involved in VDCC generation.

Inhibition of host cellular ribonucleic acid synthesis by glycoprotein of mumps virus.

After infection with mumps virus, cellular ribonucleic acid synthesis of a murine lymphoma cell line, EL4, was appreciably depressed. The inactivation of viral infectivity by ultraviolet irradiation or the treatment of cells with mouse interferon did not abolish the inhibiting effect, suggesting that virus replication is not required for the depressed RNA synthesis. Envelope glycoproteins isolated from disrupted mumps virus caused inhibition of cellular RNA synthesis. The addition of low concentrations of specific antibody enhanced the inhibitory effect, probably through the formation of aggregates of glycoproteins. On the contrary, the glycoproteins showed no effect on RNA synthesis in the presence of cytochalasin D.