Quantification of antibody responses against multiple antigens of the two infectious forms of Vaccinia virus provides a benchmark for smallpox vaccination

Smallpox was eradicated without an adequate understanding of how vaccination induced protection. In response to possible bioterrorism with smallpox, the UK government vaccinated approximately 300 health care workers with vaccinia virus (VACV) strain Lister. Antibody responses were analyzed using ELISA for multiple surface antigens of the extracellular enveloped virus (EEV) and the intracellular mature virus (IMV), plaque reduction neutralization and a fluorescence-based flow cytometric neutralization assay. Antibody depletion experiments showed that the EEV surface protein B5 is the only target responsible for EEV neutralization in vaccinated humans, whereas multiple IMV surface proteins, including A27 and H3, are targets for IMV-neutralizing antibodies. These data suggest that it would be unwise to exclude the B5 protein from a future smallpox vaccine. Repeated vaccination provided significantly higher B5-specific and thus EEV-neutralizing antibody responses. These data provide a benchmark against which new, safer smallpox vaccines and residual immunity can be compared.     

Activity of vaccinia virus-neutralizing antibody in the sera of smallpox vaccinees

Individuals vaccinated against smallpox maintain substantial antiviral antibody responses for many years after vaccination. In this study, we examined the ability of antiviral antibodies from 104 unique serum samples to neutralize the two infectious forms of vaccinia virus, intracellular mature virus (IMV) and extracellular enveloped virus (EEV). While we found direct correlations between antiviral antibody titers and the ability to neutralize IMV and EEV, correlation with EEV neutralization was weaker. To determine factors that may influence more varied EEV neutralization within a vaccinated population, we asked the following questions. (1) Does vaccinia virus-neutralizing ability remain constant over time? (2) Do multiple vaccinations boost IMV and EEV neutralization activity? We found that serum from vaccinated individuals retained ability to neutralize EEV for a relatively long time, but there was a significant drop in EEV neutralization ability in the third decade after vaccination. While all vaccinees maintained some ability to neutralize IMV, a number of individuals lost the capacity to neutralize EEV. Interestingly, the ability to neutralize either virus form was not altered by the number of vaccinations received. Since it is likely that neutralizing antibodies against both IMV and EEV are required for maximal protective immunity, a loss of anti-EEV-neutralizing ability may warrant the revaccination of individuals who have been vaccinated >20 years ago, should widespread pre-event smallpox vaccination be instituted.     

Development of smallpox vaccine candidates with integrated interleukin-15 that demonstrate superior immunogenicity, efficacy, and safety in mice

The potential use of variola virus, the etiological agent of smallpox, as a bioterror agent has heightened the interest in the reinitiation of smallpox vaccination. However, the currently licensed Dryvax vaccine, despite its documented efficacy in eradicating smallpox, is not optimal for the vaccination of contemporary populations with large numbers of individuals with immunodeficiencies because of severe adverse effects that can occur in such individuals. Therefore, the development of safer smallpox vaccines that can match the immunogenicity and efficacy of Dryvax for the vaccination of contemporary populations remains a priority. Using the Wyeth strain of vaccinia virus derived from the Dryvax vaccine, we generated a recombinant Wyeth interleukin-15 (IL-15) with integrated IL-15, a cytokine with potent immunostimulatory functions. The integration of IL-15 into the Wyeth strain resulted in a >1,000-fold reduction in lethality of vaccinated athymic nude mice and induced severalfold-higher cellular and humoral immune responses in wild-type mice that persisted longer than those induced by the parental Wyeth strain. The superior efficacy of Wyeth IL-15 was further demonstrated by the ability of vaccinated mice to fully survive a lethal intranasal challenge of virulent vaccinia virus even 10 months after vaccination, whereas all mice vaccinated with parental Wyeth strain succumbed. By integrating IL-15 into modified vaccinia virus Ankara (MVA), a virus currently under consideration as a substitute for the Dryvax vaccine, we developed a second vaccine candidate (MVA IL-15) with greater immunogenicity and efficacy than Dryvax. Thus, Wyeth IL-15 and MVA IL-15 viruses hold promise as more-efficacious and safe alternatives to the Dryvax vaccine.     

Duration of antiviral immunity after smallpox vaccination

Although naturally occurring smallpox was eliminated through the efforts of the World Health Organization Global Eradication Program, it remains possible that smallpox could be intentionally released. Here we examine the magnitude and duration of antiviral immunity induced by one or more smallpox vaccinations. We found that more than 90% of volunteers vaccinated 25-75 years ago still maintain substantial humoral or cellular immunity (or both) against vaccinia, the virus used to vaccinate against smallpox. Antiviral antibody responses remained stable between 1-75 years after vaccination, whereas antiviral T-cell responses declined slowly, with a half-life of 8-15 years. If these levels of immunity are considered to be at least partially protective, then the morbidity and mortality associated with an intentional smallpox outbreak would be substantially reduced because of pre-existing immunity in a large number of previously vaccinated individuals.     

Vaccinia virus persistence in a child against the background of immune deficiency

A young girl, vaccinated against smallpox 6 years before suffered from a persistent vaccinia virus infection and a congenital skin disease, i.e. epidermolysis bullosa. The virus was isolated from skin lesions at the vaccination site and remote sites and repeatedly from the blood; it was not isolated from bone-marrow specimen, saliva, pharynx or urine. The titre of virus-neutralizing antibodies was low (1:10), immunoglobulins A, M and G were within age-related limits; antibodies against measles and tetanus were at protective levels, skin tests were positive. Staphylococcal antitoxin titre was extremely high. The child's mother, not vaccinated against smallpox, possessed vaccinia--virus-neutralizing antibodies at high titre (over 1:320). Examination of the child did not show any quantitative immune deficiency. Immune deviations were found in the lymphocyte blast-transformation reaction on stimulation with PHA and specific antigen, as well as in the nonspecific-suppression test. The possible genesis of the virus persistence and the role of the virus in the clinical course of the disease are discussed.     

Assessment of the Protective Effect of Imvamune and Acam2000 Vaccines against Aerosolized Monkeypox Virus in Cynomolgus Macaques

To support the licensure of a new and safer vaccine to protect people against smallpox, a monkeypox model of infection in cynomolgus macaques, which simulates smallpox in humans, was used to evaluate two vaccines, Acam2000 and Imvamune, for protection against disease. Animals vaccinated with a single immunization of Imvamune were not protected completely from severe and/or lethal infection, whereas those receiving either a prime and boost of Imvamune or a single immunization with Acam2000 were protected completely. Additional parameters, including clinical observations, radiographs, viral load in blood, throat swabs, and selected tissues, vaccinia virus-specific antibody responses, immunophenotyping, extracellular cytokine levels, and histopathology were assessed. There was no significant difference (P > 0.05) between the levels of neutralizing antibody in animals vaccinated with a single immunization of Acam2000 (132 U/ml) and the prime-boost Imvamune regime (69 U/ml) prior to challenge with monkeypox virus. After challenge, there was evidence of viral excretion from the throats of 2 of 6 animals in the prime-boost Imvamune group, whereas there was no confirmation of excreted live virus in the Acam2000 group. This evaluation of different human smallpox vaccines in cynomolgus macaques helps to provide information about optimal vaccine strategies in the absence of human challenge studies.     

Smallpox DNA vaccine protects nonhuman primates against lethal monkeypox

Two decades after a worldwide vaccination campaign was used to successfully eradicate naturally occurring smallpox, the threat of bioterrorism has led to renewed vaccination programs. In addition, sporadic outbreaks of human monkeypox in Africa and a recent outbreak of human monkeypox in the U.S. have made it clear that naturally occurring zoonotic orthopoxvirus diseases remain a public health concern. Much of the threat posed by orthopoxviruses could be eliminated by vaccination; however, because the smallpox vaccine is a live orthopoxvirus vaccine (vaccinia virus) administered to the skin, the vaccine itself can pose a serious health risk. Here, we demonstrate that rhesus macaques vaccinated with a DNA vaccine consisting of four vaccinia virus genes (L1R, A27L, A33R, and B5R) were protected from severe disease after an otherwise lethal challenge with monkeypox virus. Animals vaccinated with a single gene (L1R) which encodes a target of neutralizing antibodies developed severe disease but survived. This is the first demonstration that a subunit vaccine approach to smallpox-monkeypox immunization is feasible.     

Redundancy and plasticity of neutralizing antibody responses are cornerstone attributes of the human immune response to the smallpox vaccine

The smallpox vaccine is widely considered the gold standard for human vaccines, yet the key antibody targets in humans remain unclear. We endeavored to identify a stereotypic, dominant, mature virion (MV) neutralizing antibody target in humans which could be used as a diagnostic serological marker of protective humoral immunity induced by the smallpox vaccine (vaccinia virus [VACV]). We have instead found that diversity is a defining characteristic of the human antibody response to the smallpox vaccine. We show that H3 is the most immunodominant VACV neutralizing antibody target, as determined by correlation analysis of immunoglobulin G (IgG) specificities to MV neutralizing antibody titers. It was determined that purified human anti-H3 IgG is sufficient for neutralization of VACV; however, depletion or blockade of anti-H3 antibodies revealed no significant reduction in neutralization activity, showing anti-H3 IgG is not required in vaccinated humans (or mice) for neutralization of MV. Comparable results were obtained for human (and mouse) anti-L1 IgG and even for anti-H3 and anti-L1 IgG in combination. In addition to H3 and L1, human antibody responses to D8, A27, D13, and A14 exhibited statistically significant correlations with virus neutralization. Altogether, these data indicate the smallpox vaccine succeeds in generating strong neutralizing antibody responses not by eliciting a stereotypic response to a single key antigen but instead by driving development of neutralizing antibodies to multiple viral proteins, resulting in a "safety net" of highly redundant neutralizing antibody responses, the specificities of which can vary from individual to individual. We propose that this is a fundamental attribute of the smallpox vaccine.     

An attenuated LC16m8 smallpox vaccine: analysis of full-genome sequence and induction of immune protection

The potential threat of smallpox bioterrorism has made urgent the development of lower-virulence vaccinia virus vaccines. An attenuated LC16m8 (m8) vaccine was developed in 1975 from the Lister strain used in the World Health Organization smallpox eradication program but was not used against endemic smallpox. Today, no vaccines can be tested with variola virus for efficacy in humans, and the mechanisms of immune protection against the major intracellular mature virion (IMV) and minor extracellular enveloped virion (EEV) populations of poxviruses are poorly understood. Here, we determined the full-genome sequences of the m8, parental LC16mO (mO), and grandparental Lister (LO) strains and analyzed their evolutionary relationships. Sequence data and PCR analysis indicated that m8 was a progeny of LO and that m8 preserved almost all of the open reading frames of vaccinia virus except for the disrupted EEV envelope gene B5R. In accordance with this genomic background, m8 induced 100% protection against a highly pathogenic vaccinia WR virus in mice by a single vaccination, despite the lack of anti-B5R and anti-EEV antibodies. The immunogenicity and priming efficacy with the m8 vaccine consisting mainly of IMV were as high as those with the intact-EEV parental mO and grandparental LO vaccines. Thus, mice vaccinated with 10(7) PFU of m8 produced low levels of anti-B5R antibodies after WR challenge, probably because of quick clearance of B5R-expressing WR EEV by strong immunity induced by the vaccination. These results suggest that priming with m8 IMV provides efficient protection despite undetectable levels of immunity against EEV.     

Contagiousness of monkey pox for humans: results of an investigation of 2 outbreaks of the infection in Zaire

The results of the investigation of two outbreaks of group monkeypox infection among humans (altogether 8 cases) in the zone of Bumba, Equatorial Province, Zaire, are presented. The primary source of infection in both outbreaks was not established, the outbreaks were supposedly caused by sick wild animals. Almost all persons affected by this infection were children aged 7 months to 7 years, never vaccinated against smallpox; the only exception was a 29-year old female patient, formerly vaccinated and revaccinated against smallpox. During one of the outbreaks the laboratory-confirmed transmission of infection from man to man was established in two generations. During the other outbreak there were grounds to suspect the transmission of infection in three generations, though the possibility of contacting infection from animals could not be completely ruled out. The existence of the inapparent form of monkeypox in humans was revealed.     

Development of a High-Content Orthopoxvirus Infectivity and Neutralization Assays

Currently, a number of assays measure Orthopoxvirus neutralization with serum from individuals, vaccinated against smallpox. In addition to the traditional plaque reduction neutralization test (PRNT), newer higher throughput assays are based on neutralization of recombinant vaccinia virus, expressing reporter genes such as β-galactosidase or green fluorescent protein. These methods could not be used to evaluate neutralization of variola virus, since genetic manipulations of this virus are prohibited by international agreements. Currently, PRNT is the assay of choice to measure neutralization of variola virus. However, PRNT assays are time consuming, labor intensive, and require considerable volume of serum sample for testing. Here, we describe the development of a high-throughput, cell-based imaging assay that can be used to measure neutralization, and characterize replication kinetics of various Orthopoxviruses, including variola, vaccinia, monkeypox, and cowpox.     

Participation of vaccinia virus in the pathogenesis of different clinical forms of postvaccinal complications. I. Frequency of vaccinia virus detection in the vaccinted who have usual and complicated reactions to vaccination]

The virological examination of 1365 samples taken from 469 children vaccinated against smallpox revealed considerable differences in the frequency and the time of vaccinia virus detection in different clinical forms of postvaccinal pathology as compared with uncomplicated vaccinal process. During the postvaccinal period taking its normal course vaccinia virus was isolated from 7.3% of children only from the pharynx till day 8 following vaccination. In generalized and creeping vaccinia the virus was isolated from 71.4% of children, in postvaccinal encephalitis from 57.1% of children, in vaccinal angina frove-mentioned complications vaccinia virus was detected in the samples obtained from the patients till days 24, 35, 15 and 24 respectively. The etiopathogenetic role of vaccinia virus in a number of postvaccinal complications is discussed.     

Protective effect of inactivated virus vaccine on Sendai virus infection in rats

Rats which had received two doses of inactivated Sendai virus vaccine were resistant to intranasal virus challenge. Vaccination was equally effective when administered by intravenous, intraperitoneal, intramuscular, or subcutaneous routes but not the intranasal route. Rats vaccinated intraperitoneally with inactivated Sendai virus vaccine were protected from contact infection. Suckling rats born to vaccinated dams were resistant to challenge infection at 3 weeks of age, but the resistance was not demonstrated after weaning at 4 weeks of age.     

Stimulation of cynomolgus peripheral blood lymphocytes with tetanus toxoid and smallpox vaccine

The cynomolgus monkey was studied as an animal model to investigate the cell-mediated immunity induced by vaccines. Optimal conditions are described to isolate peripheral blood lymphocytes. Lymphocyte transformation tests were performed with tetanus toxoid and smallpox vaccine. Antigen-specific lymphocyte transformations with smallpox vaccine could only be demonstrated when lymphocytes were obtained from vaccinated monkeys. Tetanus toxoid appeared to be a weak antigen. However, after adsorption of the toxoid to aluminum phosphate, a significant antigen-specific lymphocyte transformation was observed.     

Frequency of acrocentric chromosomal associations in children immunized with smallpox vaccine]

The frequency of associations of acrocentric chromosomes (AAC) diminished on the 7th day after vaccination in children primary vaccinated, primary revaccinated and secondary revaccinated against smallpox. This decrease reached its maximum by the 30th day and returned to its starting point after 6th months after vaccination. The degree of reduction of the frequency of AAC in every immunized children group correlated with the degree of increasing of antihemagglutinin titre. The relation of the number of group D chromosomes involved in AAC to the number of group G chromosomes varied in various individuals, these variations remaining after immunization. It was supposed that in PHA-stimulated lymphocyte cultures the degree of reduction of AAC frequency after vaccination against smallpox is a cytochemical marker of proliferation intensity of T-lymphocytes induced for immunopoiesis.     

Proteomic basis of the antibody response to monkeypox virus infection examined in cynomolgus macaques and a comparison to human smallpox vaccination

Monkeypox is a zoonotic viral disease that occurs primarily in Central and West Africa. A recent outbreak in the United States heightened public health concerns for susceptible human populations. Vaccinating with vaccinia virus to prevent smallpox is also effective for monkeypox due to a high degree of sequence conservation. Yet, the identity of antigens within the monkeypox virus proteome contributing to immune responses has not been described in detail. We compared antibody responses to monkeypox virus infection and human smallpox vaccination by using a protein microarray covering 92-95% (166-192 proteins) of representative proteomes from monkeypox viral clades of Central and West Africa, including 92% coverage (250 proteins) of the vaccinia virus proteome as a reference orthopox vaccine. All viral gene clones were verified by sequencing and purified recombinant proteins were used to construct the microarray. Serum IgG of cynomolgus macaques that recovered from monkeypox recognized at least 23 separate proteins within the orthopox proteome, while only 14 of these proteins were recognized by IgG from vaccinated humans. There were 12 of 14 antigens detected by sera of human vaccinees that were also recognized by IgG from convalescent macaques. The greatest level of IgG binding for macaques occurred with the structural proteins F13L and A33R, and the membrane scaffold protein D13L. Significant IgM responses directed towards A44R, F13L and A33R of monkeypox virus were detected before onset of clinical symptoms in macaques. Thus, antibodies from vaccination recognized a small number of proteins shared with pathogenic virus strains, while recovery from infection also involved humoral responses to antigens uniquely recognized within the monkeypox virus proteome.     

The threat of smallpox

Smallpox is a highly contagious disease mainly transmitted by aerosols with a high case-fatality. The smallpox virus has evolved from a long adaptation to humans during Evolution, explaining that the virus is highly specific for humans and nonpathogenic for animals. Smallpox was eradicated in 1977 and vaccination was abandoned in the 1980's. This virus is a dreadful potential biological weapon since the reemergence of smallpox on the planet might be expected to be devastating, due to its high 'contagiosity', which would rapidly spread in naive populations, especially those living in urban areas, and worldwide through air travels. There is no anti-viral treatment and vaccine is active in the first four days post-exposure. Today, the stocks of smallpox virus constitute one of the most dangerous threats for humanity. There is a need for improving the safety of the vaccine and to reconsider the preventive strategy to face a possible attack by smallpox virus.     

Evaluation of preterm births and birth defects in liveborn infants of US military women who received smallpox vaccine

BACKGROUND: Women serving in the US military have some unique occupational exposures, including exposure to vaccinations that are rarely required in civilian professions. When vaccinations are inadvertently given during pregnancy, such exposures raise special concerns. These analyses address health outcomes, particularly preterm births and birth defects, among infants who appear to have been exposed to maternal smallpox vaccination in pregnancy. METHODS: This retrospective cohort study included 31,420 infants born to active‐duty military women during 2003–2004. We used Department of Defense databases to define maternal vaccination and infant health outcomes. Multivariable regression models were developed to describe associations between maternal smallpox vaccination and preterm births and birth defects in liveborn infants. RESULTS: There were 7,735 infants identified as born to women ever vaccinated against smallpox, and 672 infants born to women vaccinated in the first trimester of pregnancy. In multivariable modeling, maternal smallpox vaccination in pregnancy was not associated with preterm or extreme preterm delivery. Maternal smallpox vaccination in the first trimester of pregnancy was not significantly associated with overall birth defects (OR 1.40; 95% CI: 0.94, 2.07), or any of seven specific defects individually modeled. CONCLUSIONS: Results may be reassuring that smallpox vaccine, when inadvertently administered to pregnant women, is not associated with preterm delivery or birth defects in liveborn infants. Birth Defects Research (Part A) 2008. © 2008 Wiley‐Liss, Inc.     

The Future of Smallpox Vaccination: is MVA the key?

Eradication of the smallpox virus through extensive global vaccination efforts has resulted in one of the most important breakthroughs in medical history, saving countless lives from the severe morbidity and mortality that is associated with this disease. Although smallpox is now extinct in nature, laboratory stocks of this virus still remain and the subject of smallpox vaccination has gained renewed attention due to the potential risk that smallpox may be used as a biological weapon by terrorists or rogue states. Despite having the longest history of any modern vaccine, there is still much to be learned about smallpox vaccination and the correlates of protection remain to be formally defined. This Commentary will discuss the strengths and weaknesses of traditional smallpox vaccination in comparison with immunization using modified vaccinia virus Ankura (MVA), a non-replicating virus with a strong safety record but weakened immunogenicity.