Cell-mediated immune responses to smallpox vaccination

Smallpox vaccine, ACAM2000: Sites and duration of viral shedding and effect of povidone iodine on scarification site shedding and immune response

The U.S. Department of Defense vaccinates personnel deployed to high-risk areas with the vaccinia virus (VACV)-based smallpox vaccine. Autoinoculations and secondary and tertiary transmissions due to VACV shedding from the vaccination site continue to occur despite education of vaccinees on the risks of such infections. The objectives of this study were to investigate, in naïve smallpox vaccinees, (a) whether the vaccination site can remain contagious after the scab separates and (b) whether the application of povidone iodine ointment (PIO) to the vaccination site inactivates VACV without affecting the immune response. These objectives were tested in 60 individuals scheduled to receive smallpox vaccine. Thirty individuals (control) did not receive PIO; 30 subjects (treatment) received PIO starting on post-vaccination day 7. Counter to current dogma, this study showed that VACV continues to shed from the vaccination site after the scab separates. Overall viral shedding levels in the PIO group were significantly lower than those in the control group (p=0.0045), and PIO significantly reduced the duration of viral shedding (median duration 14.5 days and 21 days in the PIO and control groups, respectively; p=0.0444). At least 10% of control subjects continued to shed VACV at day 28, and 3.4% continued to shed the virus at day 42. PIO reduced the proportion of subjects shedding virus from the vaccination site from day 8 until days 21-23 compared with control subjects. Groups did not differ significantly in the proportion of subjects mounting an immune response, as measured by neutralizing antibodies, IgM, IgG, and interferon-gamma enzyme-linked immunospot assay. When applied to the vaccination site starting on day 7, PIO reduced viral shedding without altering the immune response. The use of PIO in addition to a semipermeable dressing may reduce the rates of autoinoculation and contact transmission originating from the vaccination site in smallpox-vaccinated individuals.

Detection of vaccinia virus-specific IFNγ and IL-10 secretion from human PBMCs and CD8⁺ T cells by ELISPOT

High-throughput in vitro assays, which rapidly and succinctly assess the immune status of large cohorts of individuals, are essential tools for conducting population-based studies, including vaccine research. The enzyme-linked immunospot (ELISPOT) assay has emerged as a sensitive, reliable high-throughput tool to measure functional recall immunity by assessing the frequency of antigen-specific cytokine-secreting lymphocytes present in peripheral blood mononuclear cells (PBMCs). For the past 10 years, ELISPOT method has been the dominant platform and a standard for the cell-mediated immune (CMI) assays. ELISPOT assays are used extensively as a measure of CMI response to vaccines, including smallpox (vaccinia), following primary or secondary vaccination. Here, we present detailed methodology for using ELISPOT assays to detect the frequency of cytokine secreting vaccinia-specific lymphocytes including optimized protocols for growing, titrating, and inactivating vaccinia virus; isolating, cryopreserving, and thawing human PBMCs; and finally, detecting vaccinia-specific IL-10 and IFNγ secreting lymphocytes, as well as CD8(+) IFNγ T cells following in vitro stimulation of PBMCs with vaccinia virus. The methods presented below, although optimized for vaccinia virus, emphasize principles that can be generally applied to create ELISPOT assays capable of assessing the immune status as well as antiviral CD8(+) T cell response of individuals following primary or secondary vaccination with other licensed or novel vaccines.

Third-generation smallpox vaccines: challenges in the absence of clinical smallpox

Smallpox, a disease caused by variola virus, is estimated to have killed hundreds of millions to billions of people before it was certified as eradicated in 1980. However, there has been renewed interest in smallpox vaccine development due in part to zoonotic poxvirus infections and the possibility of a re-emergence of smallpox, as well as the fact that first-generation smallpox vaccines are associated with relatively rare, but severe, adverse reactions in some vaccinees. An understanding of the immune mechanisms of vaccine protection and the use of suitable animal models for vaccine efficacy assessment are paramount to the development of safer and effective smallpox vaccines. This article focuses on studies aimed at understanding the immune responses elicited by vaccinia virus and the various animal models that can be used to evaluate smallpox vaccine efficacy. Harnessing this information is necessary to assess the effectiveness and potential usefulness of new-generation smallpox vaccines.

A randomized, double-blind, controlled clinical trial to evaluate the efficacy and safety of CJ-50300, a newly developed cell culture-derived smallpox vaccine, in healthy volunteers

A randomized, double-blind, controlled clinical trial was conducted to evaluate the efficacy and safety of CJ-50300, a newly developed cell culture-derived smallpox vaccine, and to determine its minimum effective dose. The overall rates of cutaneous "take" reaction and humoral and cellular immunogenicity in CJ-50300 vaccinees were 100% (123/123), 99.2% (122/123), and 90.8% (109/120), respectively, and these rates did not differ significantly between the conventional-dose and the low-dose CJ-50300 (1.0x10(8) and 1.0x10(7) plaque-forming units/mL, respectively) (P>0.05 for each). No serious adverse reaction was observed. However, one case of possible generalized vaccinia occurred in the conventionally dosed group [ClinicalTrials.gov Identifier: NCT00607243].

Real time PCR for the assessment of CD8+ T cellular immune response after prophylactic vaccinia vaccination

BACKGROUND

The magnitude of specific CD8+ T cell reactivity responsible for vaccine-induced protection against smallpox infection has not yet been fully elucidated. Among other techniques, RT-PCR for the monitoring of cytokine release in effector T cells against tumor and viral antigens has demonstrated a novel promising method.

OBJECTIVE

To determine the functional status of antigen specific CD8+ T cells in healthy participants before and 4 weeks after prophylactic vaccination (Lister strain) against smallpox using quantitative real-time PCR (qRT-PCR).

STUDY DESIGN

Changes of interferon-gamma (IFNgamma) mRNA expression levels on short term ex vivo peptide antigen stimulation were measured. The corresponding specific CD8+ T cell reactivity was then displayed as CD8-normalized IFN-gamma levels (IFN-gamma/CD8 ratio).

RESULTS

We found a 5-9 fold increase of CD8+ T cell reactivity in three out of four vaccinated individuals. The kinetics and strength determined in responders reveal a virus specific T cell effector repertoire pre-vaccination and a corresponding functional state after immunization comparable also to data obtained from tetramer- and ELISPOT analysis.

CONCLUSIONS

Apart from protective vaccinia-specific neutralizing antibodies, the presence of antigen-specific CD8+ T-cells has been demonstrated after vaccinia vaccination. In concordance with others, results from this PCR-based study indicate that this smallpox vaccine induces strong vaccinia virus-specific CD8+ and IFN-gamma producing T cell responses.

Detailed kinetics of immune responses to a new cell culture-derived smallpox vaccine in vaccinia-naïve adults

The aim of the present study was to investigate the kinetics of humoral and cell-mediated immune responses to a new cell culture-derived smallpox vaccine (CJ-50300, CJ Corporation, South Korea) in 18 vaccinia-naïve volunteers. All subjects achieved positive humoral immune responses (plaque reduction neutralizing antibody assay) 28 days after vaccination, and cell-mediated immune responses (ELISPOT assay) 14 days after vaccination. Humoral immune responses increased up to 28 days after vaccination and were maintained up to 56 days after vaccination. In contrast, cell-mediated immune responses increased up to 14 days after vaccination and steadily decreased to 56 days after vaccination [Clinical Trial No. NCT 00336635].

Adaptive immunity to vaccinia virus: revisiting an old friend

The study of immunity to vaccinia virus has had a renaissance in recent years, largely owing to a desire to produce a safe and efficacious vaccine against smallpox in the context of biodefense concerns. This review focuses on three areas that have seen recent advances: the mapping of epitopes, data from the clinic (including efforts to determine the longevity of responses in humans and recent smallpox vaccine trials) and the use of animal models to determine the requisites for successful immunity and the effect of vaccinia virus immunomodulators on adaptive immune responses. This is intended to be a snapshot of areas generating current interest rather than a comprehensive review, and each area is discussed in terms of current achievements and challenges for the future.