PER.C6(®) cells as a serum-free suspension cell platform for the production of high titer poliovirus: a potential low cost of goods option for world supply of inactivated poliovirus vaccine.

There are two highly efficacious poliovirus vaccines: Sabin's live-attenuated oral polio vaccine (OPV) and Salk's inactivated polio vaccine (IPV). OPV can be made at low costs per dose and is easily administrated. However, the major drawback is the frequent reversion of the OPV vaccine strains to virulent poliovirus strains which can result in Vaccine Associated Paralytic Poliomyelitis (VAPP) in vaccinees. Furthermore, some OPV revertants with high transmissibility can circulate in the population as circulating Vaccine Derived Polioviruses (cVDPVs). IPV does not convey VAPP and cVDPVs but the high costs per dose and insufficient supply have rendered IPV an unfavorable option for low and middle-income countries. Here, we explored whether the human PER.C6(®) cell-line, which has the unique capability to grow at high density in suspension, under serum-free conditions, could be used as a platform for high yield production of poliovirus. PER.C6(®) cells supported replication of all three poliovirus serotypes with virus titers ranging from 9.4 log(10) to 11.1 log(10)TCID(50)/ml irrespective of the volume scale (10 ml in shaker flasks to 2 L in bioreactors). This production yield was 10-30 fold higher than in Vero cell cultures performed here, and even 100-fold higher than what has been reported for Vero cell cultures in literature [38]. In agreement, the D-antigen content per volume PER.C6(®)-derived poliovirus was on average 30-fold higher than Vero-derived poliovirus. Interestingly, PER.C6(®) cells produced on average 2.5-fold more D-antigen units per cell than Vero cells. Based on our findings, we are exploring PER.C6(®) as an interesting platform for large-scale production of poliovirus at low costs, potentially providing the basis for global supply of an affordable IPV.

Antibody and T-cell responses to a virosomal adjuvanted H9N2 avian influenza vaccine: impact of distinct additional adjuvants.

A highly efficacious vaccine is required to counteract a threat of an avian influenza pandemic. Increasing the potency of vaccines by adjuvation is essential not only to overcome generally low immunogenicity of pandemic strains, but also to allow dose sparing and as such to make it feasible to satisfy huge global production demands. In this study we evaluated the ability of four distinct adjuvants to further increase immune responses to a virosomal adjuvanted avian H9N2 influenza vaccine in mice. Currently registered adjuvants aluminium phosphate, aluminium hydroxide and MF59, as well as a novel promising adjuvant MATRIX-M were included in the study. Our results demonstrate that all adjuvants significantly increased the H9N2 haemagglutinin (HA) inhibition and ELISA antibody titers induced with the virosomal adjuvanted vaccine. The adjuvants exhibited different effect on the isotype of virus specific antibodies, with MATRIX-M inducing the most pronounced skewing to IgG2a, i.e. towards Th1 type of response. While the virosomal adjuvanted pandemic influenza vaccine efficiently induced CD4(+) T-cell response, with no further increase upon adjuvation, the CD8(+) T-cell responses induced with virosomal adjuvanted vaccine could be significantly improved upon additional adjuvation with MATRIX-M or MF59. All adjuvants demonstrated a dose sparing effect, i.e. in combination with the virosomal adjuvanted pandemic influenza vaccine they increased immune responses to comparable level independent of the tested vaccine dose. In conclusion, our results demonstrate that immune responses to a virosomal adjuvanted pandemic influenza vaccine can be further enhanced by add-on adjuvants, with MATRIX-M being overall the most potent adjuvant in combination with virosomes, followed by MF59 and finally aluminium-based adjuvants.

Safety and efficacy in geese of a PER.C6-based inactivated West Nile virus vaccine.

Studies were performed with an inactivated vaccine against the mosquito-borne flavivirus, West Nile virus (WNV). The mammalian cell line, PER.C6, was selected as the platform for WNV growth since both the neurovirulent strains NY99 and ISR98 that cause epidemics in humans and high mortality in geese, respectively, could be propagated to high titers (10(9) to 10(10)TCID(50)/ml) on these cells. Based on the high DNA homology of the WNV envelope (E) protein and non-structural protein 5 (NS5), and identical neurovirulence in mice and geese, we concluded that NY99 and ISR98 viruses are closely related and therefore vaccine studies were performed with ISR98 as a model for NY99. A robust challenge model in domestic geese was set up resulting in 100% mortality within 7 days of intracranial challenge with 500 TCID(50) WNV. Geese were used to assess the efficacy and safety of an inactivated WNV vaccine produced on PER.C6 cells. Efficacy studies demonstrated 91.4% (53/58) protection of geese compared to no protection (0/13) in geese receiving a sham vaccine. A follow-up study in 1800 geese showed that the vaccine was safe with a survival rate of 96.6% (95% lower CL 95.7%). Initial studies on the correlates of protection induced by the vaccine indicate an important role for antibodies since geese were protected when injected intra-cranial with a mixture of serum from vaccinated, non-challenged geese and WNV. In all, these results provide a scientific basis for the development of an inactivated WNV vaccine based on NY99 produced on PER.C6 cells for human and equine use.

Antiviral treatment with alpha interferon up-regulates CD14 on liver macrophages and its soluble form in patients with chronic hepatitis B.

To investigate whether therapy with alpha interferon (IFN-alpha) induces changes in intrahepatic antigen-presenting cells (APCs), we obtained liver biopsy specimens before, during, and after therapy with IFN-alpha from chronic hepatitis B patients whose viral load had already been reduced by at least 8 weeks of treatment with lamivudine. HLA-DR, CD1a, and CD83 were not modified by the therapy. The intralobular expression of CD68 on Kupffer cells remained stable, denoting no changes in the number of resident macrophages during IFN-alpha treatment. In contrast, CD14 was weakly expressed in the absence of IFN-alpha and was significantly up-regulated during therapy. At the same time, the levels of soluble CD14 and interleukin-10 in plasma increased significantly. In vitro, monocytes maintained in the presence of IFN-alpha differentiated into macrophages or dendritic cells with higher levels of expression of CD14 than that for the control cultures. During therapy with IFN-alpha, T-cell infiltration in the portal spaces was reduced, mainly due to a significant decrease in the number of CD8(+) T cells. These findings show that IFN-alpha is biologically active on APCs in vivo and in vitro and suggest that this newly described regulatory function, together with the already known inhibitory effects on lymphocytes, may cooperate to reduce inflammation and consequent tissue damage in patients with chronic viral hepatitis.

Hepatitis B virus-specific T cell response in chronic hepatitis B patients treated with lamivudine and interferon-alpha.

AIMS: The goal of the present study was to assess the impact combination antiviral therapy has on immune responses in chronic hepatitis B. MATERIALS AND METHODS: T cell responses were studied in 16 chronically hepatitis B virus (HBV)-infected patients treated with sequential, partially overlapping, lamivudine-interferon (IFN)-alpha combination therapy. RESULTS: HBcAg-specific lymphoproliferative response (LPR) was transiently detected in four of five patients who achieved virus suppression (HBV DNA < 10(4) genome equivalents/ml) at end of dual therapy, and then reverted to pre-treatment viral load after therapy discontinuation. In contrast, no significant HBcAg-specific LPR was detected in 8 patients who did not attain profound HBV suppression, as well as in three patients who experienced no HBV DNA rebound after therapy discontinuation. CONCLUSIONS: This pilot study suggests that restored viral replication after pharmacological suppression drives the immune response to HBV in chronically infected patients. Further characterization of the adaptive immunity and its regulatory mechanisms at time of therapy discontinuation appears therefore necessary in controlled trials.