Ricardo Galler

Serious adverse events associated with yellow fever 17DD vaccine in Brazil: a report of two cases.

BACKGROUND The yellow fever vaccine is regarded as one of the safest attenuated virus vaccines, with few side-effects or adverse events. We report the occurrence of two fatal cases of haemorrhagic fever associated with yellow fever 17DD substrain vaccine in Brazil. METHODS We obtained epidemiological, serological, virological, pathological, immunocytochemical, and molecular biological data on the two cases to determine the cause of the illnesses. FINDINGS The first case, in a 5-year-old white girl, was characterised by sudden onset of fever accompanied by headache, malaise, and vomiting 3 days after receiving yellow fever and measles-mumps-rubella vaccines. Afterwards she decompensated with icterus and haemorrhagic signs and died after a 5-day illness. The second patient-a 22-year-old black woman-developed a sore throat and fever accompanied by headache, myalgia, nausea, and vomiting 4 days after yellow fever vaccination. She then developed icterus, renal failure, and haemorrhagic diathesis, and died after 6 days of illness. Yellow fever virus was recovered in suckling mice and C6/36 cells from blood in both cases, as well as from fragments of liver, spleen, skin, and heart from the first case and from these and other viscera fragments in case 2. RNA of yellow fever virus was identical to that previously described for 17D genomic sequences. IgM ELISA tests for yellow fever virus were negative in case 1 and positive in case 2; similar tests for dengue, hantaviruses, arenaviruses, Leptospira, and hepatitis viruses A-D were negative. Tissue injuries from both patients were typical of wild-type yellow fever. INTERPRETATION These serious and hitherto unknown complications of yellow fever vaccination are extremely rare, but the safety of yellow fever 17DD vaccine needs to be reviewed. Host factors, probably idiosyncratic reactions, might have had a substantial contributed to the unexpected outcome.

Vaccine-induced CD8+ T cells control AIDS virus replication

Developing a vaccine for human immunodeficiency virus (HIV) may be aided by a complete understanding of those rare cases in which some HIV-infected individuals control replication of the virus. Most of these elite controllers express the histocompatibility alleles HLA-B*57 or HLA-B*27 (ref. 3). These alleles remain by far the most robust associations with low concentrations of plasma virus, yet the mechanism of control in these individuals is not entirely clear. Here we vaccinate Indian rhesus macaques that express Mamu-B*08, an animal model for HLA-B*27-mediated elite control, with three Mamu-B*08-restricted CD8+ T-cell epitopes, and demonstrate that these vaccinated animals control replication of the highly pathogenic clonal simian immunodeficiency virus (SIV) mac239 virus. High frequencies of CD8+ T cells against these Vif and Nef epitopes in the blood, lymph nodes and colon were associated with viral control. Moreover, the frequency of the CD8+ T-cell response against the Nef RL10 epitope (Nef amino acids 137–146) correlated significantly with reduced acute phase viraemia. Finally, two of the eight vaccinees lost control of viral replication in the chronic phase, concomitant with escape in all three targeted epitopes, further implicating these three CD8+ T-cell responses in the control of viral replication. Our findings indicate that narrowly targeted vaccine-induced virus-specific CD8+ T-cell responses can control replication of the AIDS virus.

Complete nucleotide sequence of yellow fever virus vaccine strains 17DD and 17D-213.

The complete nucleotide sequence of the genome from two yellow fever (YF) virus vaccine strains, 17DD and 17D-213, has been determined. Comparison of these sequences with those of other YF viruses including the parental virulent Asibi strain allowed the identification of 48 nucleotide sequence differences which are common to all 17D substrains. This is a significant reduction from the 67 nucleotide changes originally reported as being 17D-specific and potentially related to viral attenuation. The 48 changes are scattered throughout the genome, 26 of which are silent and 22 led to amino acid substitutions. These 22 changes are bona fide candidates to test by mutating the infectious YF cDNA to investigate their role in viral attenuation.

Construction, characterization and immunogenicity of recombinant yellow fever 17D-dengue type 2 viruses

Chimeric yellow fever (YF)-dengue type 2 (Den 2) viruses were constructed by replacing the premembrane (prM) and envelope (E) genes of YF 17D virus with those from Den 2 virus strains of south-east Asian genotype. Whereas viable chimeric viruses were successfully recovered when the YF 17D C gene and the Den 2 prM gene were fused at the signalase cleavage site, no virus could be rescued from the constructions fused at the viral protease cleavage site. Unlike YF virus that replicated in all the cell lines tested and similar to the Den 2 virus, the recombinant viruses did not replicate in vaccine-production certified CEF and MRC5 cells. Besides, chimeric 17D/Den 2 viruses and their parental viruses reached similar growth titers in Vero and C6/36 cell cultures. Analysis of mouse neurovirulence, performed by intracerebral inoculation, demonstrated that the 17D/Den 2 chimera is more attenuated in this system than the YF 17DD virus. Immunization of mice with this chimera induced a neutralizing antibody response associated with a partial protection against an otherwise lethal dose of mouse neurovirulent Den 2 NGC virus. Overall, these results provide further support for the use of chimeric viruses as an attractive methodology for the development of new live flavivirus vaccines.

Cytokine Signatures of Innate and Adaptive Immunity in 17DD Yellow Fever Vaccinated Children and Its Association With the Level of Neutralizing Antibody

BACKGROUND The live attenuated yellow fever (YF) vaccines have been available for decades and are considered highly effective and one of the safest vaccines worldwide. METHODS The impact of YF-17DD-antigens recall on cytokine profiles of YF-17DD-vaccinated children were characterized using short-term cultures of whole blood samples and single-cell flow cytometry. This study enrolled seroconverters and nonseroconverters after primovaccination (PV-PRNT⁺ and PV-PRNT⁻), seroconverters after revaccination (RV-PRNT⁺), and unvaccinated volunteers (UV-PRNT⁻). RESULTS The analysis demonstrated in the PV-PRNT⁺ group a balanced involvement of pro-inflammatory/regulatory adaptive immunity with a prominent participation of innate immunity pro-inflammatory events (IL-12⁺ and TNF-α⁺ NEU and MON). Using the PV-PRNT⁺ cytokine signature as a reference profile, PV-PRNT⁻ presented a striking lack of innate immunity proinflammatory response along with an increased adaptive regulatory profile (IL-4⁺CD4⁺ T cells and IL-10⁺ and IL-5⁺CD8⁺ T cells). Conversely, the RV-PRNT⁺ shifted the overall cytokine signatures toward an innate immunity pro-inflammatory profile and restored the adaptive regulatory response. CONCLUSIONS The data demonstrated that the overall cytokine signature was associated with the levels of PRNT antibodies with a balanced innate/adaptive immunity with proinflammatory/regulatory profile as the hallmark of PV-PRNT(MEDIUM⁺), whereas a polarized regulatory response was observed in PV-PRNT⁻ and a prominent proinflammatory signature was the characteristic of PV-PRNT(HIGH⁺).

Recombinant Yellow Fever Vaccine Virus 17D Expressing Simian Immunodeficiency Virus SIVmac239 Gag Induces SIV-Specific CD8+ T-Cell Responses in Rhesus Macaques

ABSTRACT Here we describe a novel vaccine vector for expressing human immunodeficiency virus (HIV) antigens. We show that recombinant attenuated yellow fever vaccine virus 17D expressing simian immunodeficiency virus SIVmac239 Gag sequences can be used as a vector to generate SIV-specific CD8+ T-cell responses in the rhesus macaque. Priming with recombinant BCG expressing SIV antigens increased the frequency of these SIV-specific CD8+ T-cell responses after recombinant YF17D boosting. These recombinant YF17D-induced SIV-specific CD8+ T cells secreted several cytokines, were largely effector memory T cells, and suppressed viral replication in CD4+ T cells.

Construction and characterization of recombinant flaviviruses bearing insertions between E and NS1 genes

BackgroundThe yellow fever virus, a member of the genus Flavivirus, is an arthropod-borne pathogen causing severe disease in humans. The attenuated yellow fever 17D virus strain has been used for human vaccination for 70 years and has several characteristics that are desirable for the development of new, live attenuated vaccines. We described here a methodology to construct a viable, and immunogenic recombinant yellow fever 17D virus expressing a green fluorescent protein variant (EGFP). This approach took into account the presence of functional motifs and amino acid sequence conservation flanking the E and NS1 intergenic region to duplicate and fuse them to the exogenous gene and thereby allow the correct processing of the viral polyprotein precursor.ResultsYF 17D EGFP recombinant virus was grew in Vero cells and reached a peak titer of approximately 6.45 ± 0.4 log10 PFU/mL at 96 hours post-infection. Immunoprecipitation and confocal laser scanning microscopy demonstrated the expression of the EGFP, which was retained in the endoplasmic reticulum and not secreted from infected cells. The association with the ER compartment did not interfere with YF assembly, since the recombinant virus was fully competent to replicate and exit the cell. This virus was genetically stable up to the tenth serial passage in Vero cells. The recombinant virus was capable to elicit a neutralizing antibody response to YF and antibodies to EGFP as evidenced by an ELISA test. The applicability of this cloning strategy to clone gene foreign sequences in other flavivirus genomes was demonstrated by the construction of a chimeric recombinant YF 17D/DEN4 virus.ConclusionThis system is likely to be useful for a broader live attenuated YF 17D virus-based vaccine development for human diseases. Moreover, insertion of foreign genes into the flavivirus genome may also allow in vivo studies on flavivirus cell and tissue tropism as well as cellular processes related to flavivirus infection.

Genetic variability among yellow fever virus 17D substrains

The complete nucleotide sequence of the genome from two yellow fever (YF) virus strains, 17DD and 17D-213 was determined. Comparison of these sequences with those of other YF viruses, including the parental virulent Asibi strain, allowed the identification of 48 nucleotide sequence differences which are 17D strain-specific and potentially related to viral attenuation. Another 43 nucleotide sequence differences were not common to all 17D substrains and are therefore substrain specific. Of the 21 changes between 17DD and Asibi 15 only five led to amino acid substitutions whereas 13 substrain differences common to all 17D-204 substrains produced six amino acid substitutions. Since the exact passage histories of these viruses is known it was possible to calculate, for each strain, the number of accumulated changes per passage. Based on these data the 17DD strain was the most genetically stable virus.

Pressure-inactivated yellow fever 17DD virus: implications for vaccine development.

The successful Yellow Fever (YF) vaccine consists of the live attenuated 17D-204 or 17DD viruses. Despite its excellent record of efficacy and safety, serious adverse events have been recorded and influenced extensive vaccination in endemic areas. Therefore, alternative strategies should be considered, which may include inactivated whole virus. High hydrostatic pressure has been described as a method for viral inactivation and vaccine development. The present study evaluated whether high hydrostatic pressure would inactivate the YF 17DD virus. YF 17DD virus was grown in Vero cells in roller bottle cultures and subjected to 310MPa for 3h at 4 degrees C. This treatment abolished YF infectivity and eliminated the ability of the virus to cause disease in mice. Pressure-inactivated virus elicited low level of neutralizing antibody titers although exhibited complete protection against an otherwise lethal challenge with 17DD virus in the murine model. The data warrant further development of pressure-inactivated vaccine against YF.

Heterogeneity in envelope protein sequence and N-linked glycosylation among yellow fever virus vaccine strains.

We have compared the deduced envelope (E) protein sequences of two biologically well-characterized yellow fever (YF) virus vaccine strains. The 17DD strain has been produced in Brazil for more than 50 years and used to successfully vaccinate millions of people worldwide. The 17D-213 is a candidate vaccine strain produced in tissue culture which has previously passed the monkey neurovirulence assay for testing human YF vaccines. Nucleotide sequence analysis of polymerase chain reaction-amplified cDNA revealed a number of mutations which were strain- and substrain-specific. A major difference of 17DD and 17D-213 as compared to 17D-204 and Asibi was the existence of a potential N-linked glycosylation site located at amino acid residues 153 and 151 of 17DD and 17D-213, respectively. These acceptor sites are apparently utilized for the addition of high-mannose carbohydrate chains as shown by endoglycosidase analyses of immunoprecipitated E proteins. Glycosylated E protein is also used to assemble YF vaccine virions. This work and eventual complete nucleotide sequence analysis of both vaccine strains should help to define possible changes involved in YF virus attenuation and allow their biological importance to be determined using a recently developed system for generating YF virus from cDNA. In addition, these data provide an estimate on the extent of genetic variability among YF 17D seeds and vaccines.