Antigenic strain diversity predicts different biogeographic patterns of maintenance and decline of antimalarial drug resistance.

The establishment and spread of antimalarial drug resistance vary drastically across different biogeographic regions. Though most infections occur in sub-Saharan Africa, resistant strains often emerge in low-transmission regions. Existing models on resistance evolution lack consensus on the relationship between transmission intensity and drug resistance, possibly due to overlooking the feedback between antigenic diversity, host immunity, and selection for resistance. To address this, we developed a novel compartmental model that tracks sensitive and resistant parasite strains, as well as the host dynamics of generalized and antigen-specific immunity. Our results show a negative correlation between parasite prevalence and resistance frequency, regardless of resistance cost or efficacy. Validation using chloroquine-resistant marker data supports this trend. Post discontinuation of drugs, resistance remains high in low-diversity, low-transmission regions, while it steadily decreases in high-diversity, high-transmission regions. Our study underscores the critical role of malaria strain diversity in the biogeographic patterns of resistance evolution.

Drug resistance among strains of the parasites that cause malaria is a growing problem for people relying on antimalarial drugs to protect them from the disease. This phenomenon is global yet exactly how resistance emerges, spreads and persists in a population often differs greatly between regions, which can complicate malaria control projects. For example, discontinuing the use of antimalarials can lead to the frequency of resistant strains declining in an area, such as Africa, but persisting at high levels in others, including Asia and South America. Gaining resistance often leads to parasites becoming less transmissible than other strains. When antimalarials are not used, sensitive strains usually outcompete their resistant counterparts. However, prolonged use of antimalarial drugs tends to eliminate susceptible strains, allowing the previously outcompeted resistant strains to dominate. The local dynamics of antimalarial resistance are also shaped by multiple other factors such as transmission levels (how common the disease is in the region), the type of antimalarial measures used (such as drugs and mosquito nets), or previous immunity the population may have developed to specific strains. While many computational models have been developed to capture these dynamics, they usually fail to include strain diversity ­ a parameter reflecting the number of malaria strains the immune system is exposed to. This parameter is important as parasites need to escape both host immunity and drugs in order to be successful. To address this gap, He, Chaillet, and Labbé created a computational model to investigate how strain diversity, transmission levels and other related factors influence antimalarial resistance. The model was used to explore how the frequency of resistant and susceptible strains changes over time once antimalarial drugs are rolled out and then halted. These analyses show that in areas with both low strain diversity and low transmission levels, susceptible parasites are more likely to be wiped out from the population, leading to a high frequency of resistant strains that persist after drugs are discontinued. However, in high diversity and high transmission regions, susceptible strains can remain in the population. Therefore, when drug treatments are stopped, resistance levels are more likely to drop due to these parasites outcompeting the drug-resistant ones. Overall, this work demonstrates how modelling approaches that include strain diversity can help inform public health decisions aimed at reducing antimalarial resistance. In particular, they can provide important insights into the control strategies that are best suited for a specific region, suggesting that in low transmission areas intensive drug treatment may contribute to resistance. Instead, preventative strategies such as eliminating mosquitos and preventing bites with bed nets may prove more beneficial at reducing transmission rates in such areas.

Darwin review: the evolution of virulence in human pathogens.

By definition, all pathogens cause some level of harm to their hosts. If this harm occurs while the pathogen is transmitting, it can negatively affect the pathogen's fitness by shortening the duration over which transmission can occur. However, many of the factors that increase virulence (i.e. harm to host) also promote transmission, driving the pathogen population towards an optimal state of intermediate virulence. A wider spectrum of virulence may be maintained among pathogen populations which are structured into multiple discrete strains though direct resource and immune-mediated competition. These various evolutionary outcomes, and the effects of medical and public health interventions, are best understood within a framework that recognizes the complex relationship between transmission and virulence in the context of the antigenic diversity of the pathogen population.

Intra-serotypic antigenic diversity of dengue virus serotype 3 in Thailand during 2004-2015.

In addition to the well-known differences among the four dengue serotypes, intra-serotypic antigenic diversity has been proposed to play a role in viral evolution and epidemic fluctuation. A replacement of genotype II by genotype III of dengue virus serotype 3 (DENV3) occurred in Thailand during 2007-2014, raising questions about the role of intra-serotypic antigenic differences in this genotype shift. We characterized the antigenic difference of DENV3 of genotypes II and III in Thailand, utilizing a neutralizing antibody assay with DENV3 vaccine sera and monotypic DENV3 sera. Although there was significant antigenic diversity among the DENV3, it did not clearly associate with the genotype. Our data therefore do not support the role of intra-serotypic antigenic difference in the genotype replacement. Amino acid alignment showed that eight positions are potentially associated with diversity between distinct antigenic subgroups. Most of these amino acids were found in envelope domain II. Some positions (aa81, aa124, and aa172) were located on the surface of virus particles, probably involving the neutralization sensitivity. Notably, the strains of both genotypes II and III showed clear antigenic differences from the vaccine genotype I strain. Whether this differencewill affect vaccine efficacy requires further studies.

Effect of a Mismatched Vaccine against the Outbreak of a Novel FMD Strain in a Pig Population.

In December 2014, a novel foot and mouth disease (FMD) virus was introduced to a pig farm in South Korea, despite the animals being vaccinated. A marginal antigenic matching between the novel and vaccine strains potentially led to the infection of the vaccinated animals. To understand the impact of using an FMD vaccine on the transmission dynamics of an unmatched field strain, simulation models were employed using daily reported data on clinical cases from the farm. The results of this study indicated that immunisation with the FMD vaccine reduced the shedding of the novel FMD virus in pigs. However, there was no evidence to suggest that the immunisation had a significant effect in reducing the development of clinical signs. These findings highlight that the use of an unmatched FMD vaccine can confound the outbreak by altering the disease dynamics of the novel virus. Based on this study, we emphasise the importance of continuous testing to ensure antigenic matching between the circulating strains and the vaccine pool.

Identification of a second glycoform of the clinically prevalent O1 antigen from Klebsiella pneumoniae.

Carbapenemase and extended ß-lactamase-producing Klebsiella pneumoniae isolates represent a major health threat, stimulating increasing interest in immunotherapeutic approaches for combating Klebsiella infections. Lipopolysaccharide O antigen polysaccharides offer viable targets for immunotherapeutic development, and several studies have described protection with O-specific antibodies in animal models of infection. O1 antigen is produced by almost half of clinical Klebsiella isolates. The O1 polysaccharide backbone structure is known, but monoclonal antibodies raised against the O1 antigen showed varying reactivity against different isolates that could not be explained by the known structure. Reinvestigation of the structure by NMR spectroscopy revealed the presence of the reported polysaccharide backbone (glycoform O1a), as well as a previously unknown O1b glycoform composed of the O1a backbone modified with a terminal pyruvate group. The activity of the responsible pyruvyltransferase (WbbZ) was confirmed by western immunoblotting and in vitro chemoenzymatic synthesis of the O1b terminus. Bioinformatic data indicate that almost all O1 isolates possess genes required to produce both glycoforms. We describe the presence of O1ab-biosynthesis genes in other bacterial species and report a functional O1 locus on a bacteriophage genome. Homologs of wbbZ are widespread in genetic loci for the assembly of unrelated glycostructures in bacteria and yeast. In K. pneumoniae, simultaneous production of both O1 glycoforms is enabled by the lack of specificity of the ABC transporter that exports the nascent glycan, and the data reported here provide mechanistic understanding of the capacity for evolution of antigenic diversity within an important class of biomolecules produced by many bacteria.

The high identity of the Trypanosoma cruzi Group-I of trans-sialidases points them as promising vaccine immunogens.

Trans-sialidase (TS) superfamily of proteins comprises eight subgroups, being the proteins of Group-I (TS-GI) promising immunogens in vaccine approaches against Trypanosoma cruzi. Strikingly, TS-GI antigenic variability among parasite lineages and their influence on vaccine development has not been previously analyzed. Here, a search in GenBank detects 49 TS-GI indexed sequences, whereas the main infecting human different parasite discrete typing units (DTU) are represented. In silico comparison among these sequences indicate that they share an identity above 92%. Moreover, the antigenic regions (T-cell and B-cell epitopes) are conserved in most sequences or present amino acid substitutions that scarcely may alter the antigenicity. Additionally, since the generic term TS is usually used to refer to different immunogens of this broad family, a further in silico analysis of the TS-GI-derived fragments tested in preclinical vaccines was done to determine the coverage and identity among them, showing that overall amino acid identity of vaccine immunogens is high, but the segment coverage varies widely. Accordingly, strong H-2K, H-2I, and B-cell epitopes are dissimilarly represented among vaccine TS-derived fragments depending on the extension of the TG-GI sequence used. Moreover, bioinformatic analysis detected a set of 150 T-cell strong epitopes among the DTU-indexed sequences that strongly bind human HLA-I supertypes. In all currently reported experimental vaccines based on TS-GI fragments, mapping these 150 epitopes showed that they are moderately represented. However, despite vaccine epitopes do not present all the substitutions observed in the DTUs, these regions of the proteins are equally recognized by the same HLAs.  Interestingly, the predictions regarding global and South American population coverage estimated in these 150 epitopes are similar to the estimations in experimental vaccines when the complete sequence of TS-GI is used as an antigen. In silico prediction also shows that a number of these MHC-I restricted T-cell strong epitopes could be also cross-recognized by HLA-I supertypes and H-2Kb or H-2Kd backgrounds, indicating that these mice may be used to improve and facilitate the development of new TS-based vaccines and suggesting an immunogenic and protective potential in humans. Further molecular docking analyses were performed to strengthen these results. Taken together, different strategies that would cover more or eventually fully of these T-cell and also B-cell epitopes to reach a high level of coverage are considered.

Key Aspects of Coronavirus Avian Infectious Bronchitis Virus.

Infectious bronchitis virus (IBV) is an enveloped and positive-sense single-stranded RNA virus. IBV was the first coronavirus to be discovered and predominantly causes respiratory disease in commercial poultry worldwide. This review summarizes several important aspects of IBV, including epidemiology, genetic diversity, antigenic diversity, and multiple system disease caused by IBV as well as vaccination and antiviral strategies. Understanding these areas will provide insight into the mechanism of pathogenicity and immunoprotection of IBV and may improve prevention and control strategies for the disease.

Characterization of alternatively spliced transcript variants of glycophorin A and glycophorin B genes in Chinese blood donors.

BACKGROUND AND OBJECTIVES: The molecular basis of MNS blood group variants is not fully clear yet. In this study, we have characterized mRNA variants of GYPA and GYPB genes to reveal whether alternative RNA splicing may cause antigenic diversity of the MNS system. MATERIALS AND METHODS: Total RNA was extracted from peripheral blood of Chinese blood donors and full-length cDNA products were generated. A nested polymerase chain reaction (PCR)-based method was established for fragment amplification and Sanger sequencing. Resulted full-length mRNA sequences were aligned with GYPA or GYPB genomic sequences respectively for exon identification. Amino acid (AA) sequences of GPA and GPB proteins were extrapolated and GYPA-EGFP, GYPB-EGFP fusion genes were generated to monitor subcellular distribution of the encoded glycophorin (GP) proteins. RESULTS: Totally 10 blood samples were analysed. GYPB mRNAs of all the subjects demonstrated frequent exon insertion or deletion whereas this kind of variation was only observed in 3 of 10 GYPA mRNA samples. None of the reported Miltenberger hybrids was detected in any of the mRNA samples. The alternative splicing resulted in changes of AA sequences in N-terminal domains where the MNS antigenic motifs resided; however, subcellular localizations of GP-EGFP fusion proteins showed that the above-mentioned AA changes did not affect cell surface distribution of the encoded GP proteins. CONCLUSIONS: Alternative RNA splicing may influence the antigenic features of GP proteins but not their cell surface distribution. Therefore, GYPA and GYPB mRNA characterization might be an invaluable supplement to serological phenotyping and DNA-based genotyping in MNS blood grouping.

Panproteome Analysis of the Human Antibody Response to Bacterial Vaccines and Challenge.

High-density protein microarray is an established technology for characterizing host antibody profiles against entire pathogen proteomes. As one of the highest throughput technologies for antigen discovery, proteome microarrays are a translational research tool for identification of vaccine candidates and biomarkers of susceptibility or protection from microbial challenge. The application has been expanded in recent years due to increased availability of bacterial genomic sequences for a broader range of species and strain diversity. Panproteome microarrays now allow for fine characterization of antibody specificity and cross-reactivity that may be relevant to vaccine design and biomarker discovery, as well as a fuller understanding of factors underlying themes of bacterial evolution and host-pathogen interactions. In this chapter, we present a workflow for design of panproteome microarrays and demonstrate statistical analysis of panproteomic human antibody responses to bacterial vaccination and challenge. Focus is particularly drawn to the bioinformatics and statistical tools and providing nontrivial, real examples that may help foster hypotheses and rational design of panproteomic studies.

Evolution of the variant surface glycoprotein family in African trypanosomes.

An intriguing and remarkable feature of African trypanosomes is their antigenic variation system, mediated by the variant surface glycoprotein (VSG) family and fundamental to both immune evasion and disease epidemiology within host populations. Recent studies have revealed that the VSG repertoire has a complex evolutionary history. Sequence diversity, genomic organization, and expression patterns are species-specific, which may explain other variations in parasite virulence and disease pathology. Evidence also shows that we may be underestimating the extent to what VSGs are repurposed beyond their roles as variant antigens, establishing a need to examine VSG functionality more deeply. Here, we review sequence variation within the VSG gene family, and highlight the many opportunities to explore their likely diverse contributions to parasite survival.

Capsules and Extracellular Polysaccharides in Escherichia coli and Salmonella.

Escherichia coli and Salmonella isolates produce a range of different polysaccharide structures that play important roles in their biology. E. coli isolates often possess capsular polysaccharides (K antigens), which form a surface structural layer. These possess a wide range of repeat-unit structures. In contrast, only one capsular polymer (Vi antigen) is found in Salmonella, and it is confined to typhoidal serovars. In both genera, capsules are vital virulence determinants and are associated with the avoidance of host immune defenses. Some isolates of these species also produce a largely secreted exopolysaccharide called colanic acid as part of their complex Rcs-regulated phenotypes, but the precise function of this polysaccharide in microbial cell biology is not fully understood. E. coli isolates produce two additional secreted polysaccharides, bacterial cellulose and poly-N-acetylglucosamine, which play important roles in biofilm formation. Cellulose is also produced by Salmonella isolates, but the genes for poly-N-acetylglucosamine synthesis appear to have been lost during its evolution toward enhanced virulence. Here, we discuss the structures, functions, relationships, and sophisticated assembly mechanisms for these important biopolymers.

Antigenic Diversity of Human Norovirus Capsid Proteins Based on the Cross-Reactivities of Their Antisera.

Human norovirus (HuNoV), which is the major causative agent of acute gastroenteritis, has broad antigenic diversity; thus, the development of a broad-spectrum vaccine is challenging. To establish the relationship between viral genetic diversity and antigenic diversity, capsid P proteins and antisera of seven GI and 16 GII HuNoV genotypes were analyzed. Enzyme-linked immunosorbent assays showed that HuNoV antisera strongly reacted with the homologous capsid P proteins (with titers > 5 × 104). However, 17 (73.9%) antisera had weak or no cross-reactivity with heterologous genotypes. Interestingly, the GII.5 antiserum cross-reacted with seven (30.4%) capsid P proteins (including pandemic genotypes GII.4 and GII.17), indicating its potential use for HuNoV vaccine development. Moreover, GI.2 and GI.6 antigens reacted widely with heterologous antisera (n ≥ 5). Sequence alignment and phylogenetic analyses of the P proteins revealed conserved regions, which may be responsible for the immune crossover reactivity observed. These findings may be helpful in identifying broad-spectrum epitopes with clinical value for the development of a future vaccine.

Evaluation of Antigenic Comparisons Among BVDV Isolates as it Relates to Humoral and Cell Mediated Responses.

Antigenic differences between bovine viral diarrhea virus (BVDV) vaccine strains and field isolates can lead to reduced vaccine efficacy. Historically, antigenic differences among BVDV strains were evaluated using techniques based on polyclonal and monoclonal antibody activity. The most common method for antigenic comparison among BVDV isolates is determination of virus neutralization titer (VNT). BVDV antigenic comparisons using VNT only account for the humoral component of the adaptive immune response, and not cell mediated immunity (CMI) giving an incomplete picture of protective responses. Currently, little data is available regarding potential antigenic differences between BVDV vaccine strains and field isolates as measured by CMI responses. The goal of the current paper is to evaluate two groups of cattle that differed in the frequency they were vaccinated, to determine if similar trends in CMI responses exist within each respective group when stimulated with antigenically different BVDV strains. Data from the current study demonstrated variability in the CMI response is associated with the viral strain used for stimulation. Variability in IFN-γ mRNA expression was most pronounced in the CD4+ population, this was observed between the viruses within each respective BVDV subgenotype in the Group 1 calves. The increase in frequency of CD25+ cells and IFN-γ mRNA expression in the CD8+ and CD335+ populations were not as variable between BVDV strains used for stimulation in the Group 1 calves. Additionally, an inverse relationship between VNT and IFN-γ mRNA expression was observed, as the lowest VNT and highest IFN-γ mRNA expression was observed and vice versa, the highest VNT and lowest IFN-γ mRNA expression was observed. A similar trend regardless of vaccination status was observed between the two groups of calves, as the BVDV-1b strain had lower IFN-γ mRNA expression. Collectively, data from the current study and previous data support, conferring protection against BVDV as a method for control of BVDV in cattle populations is still a complex issue and requires a multifactorial approach to understand factors associated with vaccine efficacy or conversely vaccine failure. Although, there does appear to be an antigenic component associated with CMI responses as well as with humoral responses as determined by VNT.

Cross-reactivity of antibody responses to Borrelia afzelii OspC: Asymmetry and host heterogeneity.

The tick-transmitted bacterium Borrelia afzelii consists of a number of antigenically different strains - often defined by outer surface protein C (OspC) genotype - that coexist at stable frequencies in host populations. To investigate how host antibody responses affect strain coexistence, we measured antibody cross-reactivity to three different OspC types (OspC 2, 3 and 9) in three different strains of laboratory mice (BALB/c, C3H and C57BL/6). The extent of cross-reactivity differed between mouse strains, being higher in C3H than BALB/c and C57BL/6. In one of three pairwise comparisons of OspC types (OspC2 vs OspC9), there was evidence for asymmetry of cross-reactivity, with antibodies to OspC2 cross-reacting more strongly with OspC9 than vice versa. These results indicate that the extent of antibody-mediated competition between OspC types may depend on the composition of the host population, and that such competition may be asymmetric. We discuss the implications of these results for understanding the coexistence of OspC types.

Frequency-Dependent Competition Between Strains Imparts Persistence to Perturbations in a Model of Plasmodium falciparum Malaria Transmission.

In high-transmission endemic regions, local populations of Plasmodium falciparum exhibit vast diversity of the var genes encoding its major surface antigen, with each parasite comprising multiple copies from this diverse gene pool. This strategy to evade the immune system through large combinatorial antigenic diversity is common to other hyperdiverse pathogens. It underlies a series of fundamental epidemiological characteristics, including large reservoirs of transmission from high prevalence of asymptomatics and long-lasting infections. Previous theory has shown that negative frequency-dependent selection (NFDS) mediated by the acquisition of specific immunity by hosts structures the diversity of var gene repertoires, or strains, in a pattern of limiting similarity that is both non-random and non-neutral. A combination of stochastic agent-based models and network analyses has enabled the development and testing of theory in these complex adaptive systems, where assembly of local parasite diversity occurs under frequency-dependent selection and large pools of variation. We show here the application of these approaches to theory comparing the response of the malaria transmission system to intervention when strain diversity is assembled under (competition-based) selection vs. a form of neutrality, where immunity depends only on the number but not the genetic identity of previous infections. The transmission system is considerably more persistent under NFDS, exhibiting a lower extinction probability despite comparable prevalence during intervention. We explain this pattern on the basis of the structure of strain diversity, in particular the more pronounced fraction of highly dissimilar parasites. For simulations that survive intervention, prevalence under specific immunity is lower than under neutrality, because the recovery of diversity is considerably slower than that of prevalence and decreased var gene diversity reduces parasite transmission. A Principal Component Analysis of network features describing parasite similarity reveals that despite lower overall diversity, NFDS is quickly restored after intervention constraining strain structure and maintaining patterns of limiting similarity important to parasite persistence. Given the described enhanced persistence under perturbation, intervention efforts will likely require longer times than the usual practice to eliminate P. falciparum populations. We discuss implications of our findings and potential analogies for ecological communities with non-neutral assembly processes involving frequency-dependence.

About the necessity of including HoBi-like pestiviruses in bovine respiratory and reproductive viral vacines / Sobre a necessidade de incluir pestivírus HoBi-like em vacinas virais respiratórias e reprodutivas para bovinos

HoBi-like pestiviruses (HoBiPeV) constitute a novel group of bovine pestiviruses, genetically and antigenically related to bovine viral diarrhea virus 1 (BVDV-1) and BVDV-2. Recent data shows that HoBiPeV are endemic among Brazilian cattle, yet bovine reproductive/respiratory vaccines contain only BVDV-1 and BVDV-2 strains. The present study investigated the neutralizing antibody response against these pestiviruses induced by two commercial vaccines (VA = attenuated, VI = inactivated) and by three experimental, replicative, vaccine formulations (VAC1 = monovalent, BVDV-1; VAC2 = bivalent, BVDV-1 + BVDV-2; VAC3 = trivalent, BVDV-1 + BVDV-2 and HoBiPeV). Seronegative beef calves were immunized once (replicative vaccines) or twice (inactivated vaccine) and serum samples were tested by virus-neutralization (VN) 30 days after vaccination (dpv) (replicative vaccines) or 30 days after the second dose (VI). We considered a threshold VN titer of ≥60 indicative of protection against clinical disease. At 30 dpv, VA induced protective titers against BVDV-2 in 7/7 animals (GMT=289.8) and against BVDV-1 and HoBiPeV in 5/7 animals (GMTs=97.5 and 80, respectively). VI induced protective titers against BVDV-1 in 1/7 animal (GMT=16.4), 2/7 animals against BVDV-2 (GMT=53.8) and in none of the calves against HoBiPeV (GMT=12.2). When a pool of sera of each vaccine group was tested against individual Brazilian isolates, VA induced protective titers against 3/7 BVDV-1 isolates, to 9/10 (BVDV-2) and 1/8 (HoBiPeV); VI induced protective titers against 1/7 (BVDV-1), 1/10 (BVDV-2) and none (0/8) HoBiPeV isolates. The experimental vaccine VAC1 induced protective titers against BVDV-1 in 9/9 animals (GMT=320) but in no animal against BVDV-2 or HoBiPeV (GMT<10). VAC2 induced protective titers to BVDV-1 and BVDV-2 in 9/9 animals (GMTs=160 and 640, respectively), and against HoBiPeV in 7/9 animals (GMT=108.5). Finally, VAC3 induced protective titers in all animals against BVDV-1 (GMT=234.3), BVDV-2 (294.9) and HoBiPeV (201.1). Testing the pool of sera against pestivirus isolates, VAC1 induced titers ≥ 60 against 4/7 BVDV-1 but to none BVDV-2/HoBiPeV isolate; VAC2 induced protective titers against 4/7 BVDV-1; 10/10 BVDV-2 and 2/8 HoBiPeV; VAC3 induced protective titers against all BVDV-1, BVDV-2 and HoBiPeV isolates. These results indicate that vaccines composed by BVDV-1+BVDV-2, especially those containing inactivated virus, may not induce serological response against a variety of HoBiPeV isolates. Thus, the need of inclusion of HoBiPeV in vaccine formulations should be considered.(AU)

Os pestivírus HoBi-like (HoBiPeV) compõe um grupo novo de pestivírus de bovinos, genética e antigenicamente relacionados com os vírus da diarreia viral bovina 1 e 2 (BVDV-1, BVDV2). Dados recentes indicam que os HoBiPeV são endêmicos na população bovina do Brasil, mas as vacinas respiratórias e reprodutivas bovinas contêm apenas cepas de BVDV-1 e BVDV-2. O presente estudo investigou a atividade neutralizante contra estes pestivírus induzidas por duas vacinas comerciais (VA = atenuada, VI = inativada) e por três vacinas experimentais replicativas (VAC1 = monovalente, BVDV-1; VAC2 = bivalente, BVDV-1 + BVDV-2; VAC3 = trivalente, BVDV-1 + BVDV-2 e HoBiPeV). Bezerros soronegativos foram imunizados uma vez (vacinas replicativas) ou duas (vacina inativada) e amostras de soro foram testadas por vírus-neutralização (VN) 30 dias após a vacinação (dpv) (vacinas replicativas) ou 30 dias após a segunda dose (VI). Títulos neutralizantes ≥60 foram considerados indicativos de proteção contra doença clínica. Nesta data, a VA induziu títulos protetivos contra o BVDV-2 em 7/7 animais (GMT=289,8) e contra BVDV-1 e HoBiPeV em 5/7 animals (GMTs=97,5 e 80, respectivamente). VI induziu títulos protetores contra BVDV-1 em 1/7 animal (GMT=16,4), em 2/7 animais contra BVDV-2 (GMT=53,8) e em nenhum contra HoBiPeV (GMT=12,2). Quando um pool de soro de cada grupo vacinal foi testado frente a isolados Brasileiros, a VA induziu títulos protetores contra 3/7 isolados de BVDV-1, 9/10 (BVDV-2) e 1/8 (HoBiPeV); VI induziu títulos protetores em 1/7 contra BVDV-1, 1/10 (BVDV-2) e em nenhum (0/8) contra isolados de HoBiPeV. A VAC1 induziu títulos protetores contra BVDV-1 em 9/9 animais (GMT=320) mas em nenhum animal contra BVDV-2 ou HoBiPeV (GMT<10). VAC2 induziu títulos protetores contra BVDV-1e BVDV-2 em 9/9 animais (GMTs=160 e 640, respectivamente),e contra HoBiPeV em 7/9 animais (GMT=108,5). Finalmente, VAC3 induziu títulos protetores em todos os animais contra BVDV-1 (GMT=234,3), BVDV-2 (294,9) e HoBiPeV (201,1). No teste de pool de soro contra isolados de pestivírus, VAC1 induziu títulos ≥60 contra 4/7 BVDV-1 mas contra nenhum isolado de BVDV-2/HoBiPeV; VAC2 induziu títulos protetores contra 4/7 BVDV-1; 10/10 BVDV-2 e 2/8 HoBiPeV; VAC3 induziu títulos protetores contra todos BVDV-1, BVDV-2 e HoBiPeV. Esses resultados indicam que vacinas contendo apenas BVDV-1 BVDV-2, especialmente aquelas inativadas, podem não conferir resposta sorológica protetora contra vários isolados de HoBiPeV. Portanto, a necessidade de se incluir cepas de HoBiPeV nas vacinas deve ser considerada.(AU)

Avaliação da resposta de anticorpos IgG contra diferentes variantes alélicas do Antígeno 1 de Membrana Apical (AMA-1) de Plasmodium vivax em indivíduos de áreas endêmicas de malária / Evaluation of IgG antibody response against different variants of Plasmodium vivax apical membrane antigen 1 (AMA-1) in individuals from malaria endemic areas

O Plasmodium vivax é a espécie com maior distribuição geográfica no mundo e a que predomina nas Américas, incluindo o Brasil. Comparado ao Plasmodium falciparum, poucas vacinas contra o P. vivax encontram-se em fase de testes clínicos. Um dos antígenos de formas sanguíneas de P. vivax candidato a vacina é o Antígeno 1 de Membrana Apical (PvAMA-1). Entretanto, a diversidade antigênica do mesmo na natureza representa um grande desafio para seu uso no desenvolvimento de uma vacina de ampla cobertura. No presente estudo, avaliamos se os polimorfismos de sequências já descritos são capazes de influenciar na eficácia de uma vacina baseada em PvAMA-1. Para isso, geramos 9 proteínas recombinantes a partir da levedura Pichia pastoris, as quais são representativas de diferentes variantes alélicas do antígeno PvAMA-1, a saber: Belem, Chesson I, Sal-1, Indonesia XIX, SK0814, TC103, PNG_05_ESP, PNG_62_MU e PNG_68_MAS. Após expressão e purificação das proteínas selecionadas, avaliamos comparativamente por ELISA a resposta de anticorpos IgG naturalmente adquiridos em indivíduos expostos a malária, procedentes da Região Amazônica. Todas as proteínas foram obtidas com rendimento e pureza apropriados para os estudos propostos. A prevalência total de indivíduos expostos a malária com anticorpos contra PvAMA-1 Belem foi de 53,68%, em 611 amostras de soro testadas. Entre 100 das amostras sorologicamente positivas para PvAMA-1 Belem, os maiores valores de DO492 foram obtidos para as variantes Chesson I, SK0814 e Sal-1, sugerindo que epítopos comuns ou de reatividade cruzada estão sendo reconhecidos nessas variantes. Por outro lado, níveis mais baixos de DO492 foram obtidos para as variantes Indonesia XIX, TC103, PNG_05_ESP, PNG_62_MU e PNG_68_MAS, o que pode significar que essas variantes são menos prevalentes ou não circulam no Brasil. Soros policlonais de camundongos C57BL/6 previamente imunizados com PvAMA-1 Belem foram testados quanto ao reconhecimento das diferentes variantes por ELISA. Nossos resultados demonstraram que as variantes Chesson I, Indonesia XIX, SK0814, Sal-1 e a proteína homóloga foram predominantemente reconhecidas. Por fim, ensaios de competição baseados em ELISA revelaram que as proteínas Chesson I, Indonesia XIX, SK0814 e Sal-1, na fase solúvel, foram capazes de inibir a ligação de anticorpos à variante Belem aderida a placa, sugerindo a presença de epítopos comuns ou de reatividade cruzada entre as mesmas. Nossos dados sugerem que uma vacina baseada na variante PvAMA-1 Belem gera anticorpos variante-transcendentes. Entretanto, para gerar uma vacina universal baseada em PvAMA-1, uma formulação multi-alélica, incluindo variantes da Tailândia e Papua Nova Guiné, deverão ser testadas

Plasmodium vivax has the largest geographical distribution Plasmodium species in the world, and is predominant in the Americas, including Brazil. Fewer P. vivax vaccines than P. falciparum vaccines have successfully reached clinical trials. One of the candidate antigens for a blood-stage P. vivax vaccine is the apical membrane antigen 1 (PvAMA-1). However, the high natural variability found in this antigen presents a major challenge for its development into a wide-range vaccine. In the present study, we evaluated whether sequence polymorphisms would influence a vaccine based on PvAMA-1. To achieve this, we generated 9 recombinant proteins from the yeast Pichia pastoris, representative of different allelic variants of the PvAMA-1 antigen: Belem, Chesson I, Sal-1, Indonesia XIX, SK0814, TC103, PNG_05_ESP, PNG_62_MU, and PNG_68_MAS. After expression and purification of these proteins, we compared, by ELISA and IgG blocking, the natural acquired response from malaria-exposed individuals in the Amazon Region. All proteins selected had the appropriate yield and purity for the proposed studies. The total prevalence of malaria-exposed individuals with reactivity to PvAMA-1 Belem was 53,68%, from 611 serum samples tested. One hundred of these serologically positive samples were further tested against recombinant proteins representing the other allelic variants. The highest OD values resulted from Sal-1, Chesson I and SK0814 variants, suggesting that common epitopes or cross-reactivity exist across the variants. On the other hand, the lowest OD values resulted from the variants Indonesia XIX, TC103, PNG_05_ESP, PNG_62_MU, and PNG_68_MAS, which may mean these variants are less prevalent or do not circulate in Brazil. Polyclonal sera from C57BL/6 mice immunized with PvAMA-1 Belem were tested for recognition of different variants by ELISA. Our results showed that the variants Chesson I, Sal-1, Indonesia XIX, SK0814 and the homologous protein were predominantly recognized. Lastly, ELISA-based competition assays revealed that Chesson I, Sal-1, Indonesia XIX and SK0814 proteins were able to inhibit antibody binding to the Belem variant, suggesting the presence of common epitopes or cross-reactivity between these variants. Our data suggest that a vaccine based on the PvAMA-1 Belem variant displays strain-transcendent antibodies. However, to generate a universal vaccine based on PvAMA-1, a multiallelic formulation including variants from Thailand and Papua New Guinea must be tested

Infection Dynamics of Swine Influenza Virus in a Danish Pig Herd Reveals Recurrent Infections with Different Variants of the H1N2 Swine Influenza A Virus Subtype.

Influenza A virus (IAV) in swine, so-called swine influenza A virus (swIAV), causes respiratory illness in pigs around the globe. In Danish pig herds, a H1N2 subtype named H1N2dk is one of the main circulating swIAV. In this cohort study, the infection dynamic of swIAV was evaluated in a Danish pig herd by sampling and PCR testing of pigs from two weeks of age until slaughter at 22 weeks of age. In addition, next generation sequencing (NGS) was used to identify and characterize the complete genome of swIAV circulating in the herd, and to examine the antigenic variability in the antigenic sites of the virus hemagglutinin (HA) and neuraminidase (NA) proteins. Overall, 76.6% of the pigs became PCR positive for swIAV during the study, with the highest prevalence at four weeks of age. Detailed analysis of the virus sequences obtained showed that the majority of mutations occurred at antigenic sites in the HA and NA proteins of the virus. At least two different H1N2 variants were found to be circulating in the herd; one H1N2 variant was circulating at the sow and nursery sites, while another H1N2 variant was circulating at the finisher site. Furthermore, it was demonstrated that individual pigs had recurrent swIAV infections with the two different H1N2 variants, but re-infection with the same H1N2 variant was also observed. Better understandings of the epidemiology, genetic and antigenic diversity of swIAV may help to design better health interventions for the prevention and control of swIAV infections in the herds.

Genetic diversity and different cross-neutralization capability of porcine circovirus type 2 isolates recently circulating in South Korea.

BACKGROUND: Porcine circovirus type 2 (PCV2) is a small single-stranded DNA virus and a primary cause of PCV-associated diseases (PCVAD) that result insubstantial economic loss for swine farms. Between 2016 and 2018, PCV2 field viruses were isolated from PCVAD-affected swine farms in South Korea and investigated for genetic and antigenic heterogeneity. RESULTS: The genetic analysis of ORF2 showed that the genotype of the Korean PCV2 field isolates has been rapidly shifted from PCV2a or 2b to mutant PCV2b known as PCV2d with 82.6 to 100% amino acid sequence similarity. PCV2-specific monoclonal antibodies (mAbs) demonstrated variable antigen-binding activity to four representative Korean PCV2 field isolates [QIA215 (PCV2a), QIA418 (PCV2b), QIA169 (PCV2d), and QIA244 (PCV2d)] without genotype specificity, and one mAb showed neutralization activity to QIA215. In a cross-virus neutralization assay using anti-PCV2 sera of pigs and guinea pigs injected with a commercial vaccine and the Korean PCV2 field isolates, the anti-porcine sera of a commercial vaccine had high neutralization activity against QIA215 and QIA418 with statistically lower activity against PCV2d viruses. Anti-guinea pig sera of QIA215, QIA418, QIA169, and a commercial vaccine had high neutralization activity against all of the viruses with significantly lower activity against QIA244. Importantly, anti-guinea pig sera of QIA244 had high neutralization activity against all of the viruses. CONCLUSIONS: This study confirmed genetic and antigenic diversity among recent PCV2 field isolates in Korean swine farms, and the strain-based difference in virus neutralization capability should be considered for more effective control by vaccination.

Demographic and clinical features and subsectoral differences in occupational contact allergens in clothing manufacturing workers.

BACKGROUND: Epidemiologic data on the occurrence of contact dermatitis (CD) and the contact allergens involved in clothing manufacturing and its subsectors are scarce. This study aimed to determine the extent of occupational contact allergy and differences between work subsectors in clothing employees with CD. METHODS: A cross-sectional study was conducted with 272 clothing employees, who complained of CD and were diagnosed with occupational allergic contact dermatitis (OACD). Participants worked in accessory, dyeing, sewing, cutting, knitting, packing, cleaning, and ironing subsectors. Data on demographics, working-subsector, working-duration, and lesion-duration were collected, and participants were examined and patch tested. RESULTS: Participants included 173 females and 99 males. Dyeing workers were most frequently diagnosed with OACD, whereas cutting workers were least. Lesions were mostly located on the hands only. The most frequently detected allergens were nickel sulfate in accessory work; disperse blue-106 in dyeing, sewing, cutting, and knitting; cobalt chloride in packing; p-phenylenediamine in cleaning; and budesonide in ironing. CONCLUSIONS: Contact allergens show significant differences in frequency by work subsectors in clothing employees. Careful monitoring of workers for excessive exposures and for early signs of CD is warranted.