Research progress in optimization of therapeutic effect of antibodies against flavivirus / 中华微生物学和免疫学杂志

Flaviviruses are a class of positive-strand RNA viruses mainly transmitted by arthropods, which can cause high mortality and morbidity worldwide. At present, there is no specific therapy. Therapeutic antibodies bring hope for the treatment of flavivirus infection, but the antibody-dependent enhancement (ADE) effect induced by flavivirus infection can lead to disease progression. The ideal therapeutic antibodies against flaviviruses should not only treat flavivirus infection, but also avoid the harm caused by ADE. Therefore, researchers have optimized some of the antibodies to seek the best therapeutic antibodies. This review briefly described the research progress and mechanism of therapeutic antibodies against flaviviruses as well as some strategies to reduce the ADE effect induced by the therapeutic antibodies.

Implementación de un sistema de detección de flavivirus en mosquitos / Implementation of a flavivirus detection system in mosquitoes

Los Flavivirus constituyen virus transmitidos por artrópodos, principalmente mosquitos. Pueden producir enfermedades en humanos y animales, también incluyen virus específicos de insectos que solo infectan y se replican en los insectos, no así en vertebrados. En Paraguay los virus dengue, fiebre amarilla y Zika fueron detectados en infecciones humanas, pero los estudios de flavivirus en mosquitos son aún escasos. Por ello, el objetivo del presente estudio fue implementar un sistema de detección de flavivirus en mosquitos en el IICS-UNA. Primero, se organizaron capacitaciones en colecta, preparación de pools y procesamiento por técnicas de RT-PCRs convencionales realizadas por expertos internacionales a profesionales locales (bioquímicos y biólogos). Además, se implementaron planillas de registro de datos y de control de transporte de muestras de los lugares de colectas hasta el IICS-UNA. Se prepararon en total 201 pools de 1 a 35 mosquitos cada uno agrupados por especie, localidad, entre otros criterios. Para asegurar la integridad del RNA extraído se realizó la detección de un control interno (Actina-1), siendo todos los pools positivos para el mismo, 91/201 pools fueron positivos para flavivirus. Se realizó la secuenciación de 19/91 pools positivos para flavivirus identificándose flavivirus de insectos (detectándose principalmente Culex Flavivirus, cell fusing agents Flavivirus y Kamiti river virus), evidenciando la elevada distribución de estos virus. Estos resultados demuestran que fue factible implementar el sistema de detección de flavivirus en mosquitos, lo cual podría contribuir a fortalecer la vigilancia y control de estas virosis, así como el conocimiento sobre la importancia ecológica de flavivirus de insectos

Flaviviruses are viruses transmitted by arthropods, mainly mosquitoes. They can cause diseases in humans and animals, they also include specific insect viruses that only infect and replicate in insects, not in vertebrates. In Paraguay, dengue, yellow fever, and Zika viruses were detected in human infections, but studies of flaviviruses in mosquitoes are still scarce. Therefore, the objective of the present study was the implementation of a flavivirus detection system in mosquitoes at IICS-UNA. First, trainings on collection, pool preparation and processing by conventional RT-PCR techniques were organized by international experts for local professionals (biochemists and biologists). In addition, data log sheets and sample transport control forms from the collection sites to the IICS were implemented. A total of 201 pools of 1 to 35 mosquitoes were prepared, each grouped by species, locality, among others. To ensure the integrity of the extracted RNA, an internal control (Actin-1) detection was performed, all pools being positive for it; 91/201 pools were positive for flaviviruses. The sequencing of 19/91 pools positive for flavivirus was carried out, identifying flavivirus in all cases of insects (mainly detecting Culex Flavivirus, cell fusing agents Flavivirus and Kamiti river virus), evidencing the high distribution of these viruses. These results demonstrate that it was feasible to implement the flavivirus detection system in mosquitoes, which could contribute to strengthen the detection, surveillance and control of these viruses, as well as, the knowledge about the ecological importance of insect flaviviruses

Dengue, Yellow Fever, Zika and Chikungunya epidemic arboviruses in Brazil: ultrastructural aspects

BACKGROUND The impact of arbovirus cocirculation in Brazil is unknown. Dengue virus (DENV) reinfection may result in more intense viraemia or immunopathology, leading to more severe disease. The Zika virus (ZIKV) epidemic in the Americas provided pathogenicity evidence that had not been previously observed in flavivirus infections. In contrast to other flaviviruses, electron microscopy studies have shown that ZIKV may replicate in viroplasm-like structures. Flaviviruses produce an ensemble of structurally different virions, collectively contributing to tissue tropism and virus dissemination. OBJECTIVES AND METHODS In this work, the Aedes albopictus mosquito cell lineage (C6/36 cells) and kidney epithelial cells from African green monkeys (Vero cells) were infected with samples of the main circulating arboviruses in Brazil [DENV-1, DENV-2, DENV-3, DENV-4, ZIKV, Yellow Fever virus (YFV) and Chikungunya virus (CHIKV)], and ultrastructural studies by transmission electron microscopy were performed. FINDINGS We observed that ZIKV, the DENV serotypes, YFV and CHIKV particles are spherical. ZIKV, DENV-1, -2, -3 and -4 presented diameters of 40-50 nm, and CHIKV presented approximate diameters of 50-60 nm. Viroplasm-like structures was observed in ZIKV replication cycle. MAIN CONCLUSIONS The morphogenesis of these arboviruses is similar to what has been presented in previous studies. However, we understand that further studies are needed to investigate the relationship between viroplasm-like structures and ZIKV replication dynamics.

Zika virus serological diagnosis: commercial tests and monoclonal antibodies as tools

Zika virus (ZIKV), an emerging arthropod-borne virus (arbovirus) of the Flaviviridae family, is a current issue worldwide, particularly because of the congenital and neurological syndromes associated with infection by this virus. As the initial clinical symptoms of all diseases caused by this group are very similar, clinical diagnosis is difficult. Furthermore, laboratory diagnostic efforts have failed to identify specific and accurate tests for each virus of the Flaviviridae family due to the cross-reactivity of these viruses in serum samples. This situation has resulted in underreporting of the diseases caused by flaviviruses. However, many companies developed commercial diagnostic tests after the recent ZIKV outbreak. Moreover, health regulatory agencies have approved different commercial tests to extend the monitoring of ZIKV infections. Considering that a specific and sensitive diagnostic method for estimating risk and evaluating ZIKV propagation is still needed, this review aims to provide an update of the main commercially approved serological diagnostics test by the US Food and Drug Administration (FDA) and Brazilian National Health Surveillance Agency (ANVISA). Additionally, we present the technologies used for monoclonal antibody production as a tool for the development of diagnostic tests and applications of these antibodies in detecting ZIKV infections worldwide.(AU)

Entomopathogenic fungi and their potential for the management of Aedes aegypti (Diptera: Culicidae) in the Americas

Classical biological control has been used extensively for the management of exotic weeds and agricultural pests, but never for alien insect vectors of medical importance. This simple but elegant control strategy involves the introduction of coevolved natural enemies from the centre of origin of the target alien species. Aedes aegypti - the primary vector of the dengue, yellow fever and Zika flaviviruses - is just such an invasive alien in the Americas where it arrived accidentally from its West African home during the slave trade. Here, we introduce the concept of exploiting entomopathogenic fungi from Africa for the classical biological control of Ae. aegypti in the Americas. Fungal pathogens attacking arthropods are ubiquitous in tropical forests and are important components in the natural balance of arthropod populations. They can produce a range of specialised spore forms, as well as inducing a variety of bizarre behaviours in their hosts, in order to maximise infection. The fungal groups recorded as specialised pathogens of mosquito hosts worldwide are described and discussed. We opine that similar fungal pathogens will be found attacking and manipulating Ae. aegypti in African forests and that these could be employed for an economic, environmentally-safe and long-term solution to the flavivirus pandemics in the Americas.

Evaluation of Molecular Detection for Viral Hemorrhagic Infection Cases of Yellow Fever and Dengue Fever in Côte d’Ivoire 2010-2012, West Africa.

Background: Viral hemorrhagic fevers are emergent and endemic in Africa and in South America. In Côte d’Ivoire, Yellow fever cases were reported yearly and the distribution of mosquitoes in the country are the main factors for high incidence of Flaviviruses. The poorly reporting of viral hemorrhagic fever cases in some regions, the lack of international interest land and the underestimation of molecular surveillance method contribute to increase the risk for public health. Objectives: To evaluate the performance of molecular diagnostic methods in national surveillanceof two emergent Flaviviruses, Yellow fever virus and Dengue virus in Côte d’Ivoire. Study Design: 63 sera from suspected cases in 2010-2011 of viral hemorrhagic fevers were analyzed to detect viral RNA of Flaviviruses and to compare the results in three different methods. Results and Conclusion: The Flavivirus RT-PCR has showed the high molecular detection by12% and 6% for real time PCR. The methods are specific and high sensitive for the screening of tick and mosquito-borne Flaviviruses in clinical samples. This study confirms the high circulation of Flaviviruses and the introduction of Dengue virus in Côte d’Ivoire. The combination of real time PCR and the Flavivirus RT-PCR contribute to ameliorate the detection panel of molecular detection in Côte d’Ivoire and was a suitable method for the National Laboratory Reference.

Zoonotic encephalitides caused by arboviruses: transmission and epidemiology of alphaviruses and flaviviruses

In this review, we mainly focus on zoonotic encephalitides caused by arthropod-borne viruses (arboviruses) of the families Flaviviridae (genus Flavivirus) and Togaviridae (genus Alphavirus) that are important in both humans and domestic animals. Specifically, we will focus on alphaviruses (Eastern equine encephalitis virus, Western equine encephalitis virus, Venezuelan equine encephalitis virus) and flaviviruses (Japanese encephalitis virus and West Nile virus). Most of these viruses were originally found in tropical regions such as Africa and South America or in some regions in Asia. However, they have dispersed widely and currently cause diseases around the world. Global warming, increasing urbanization and population size in tropical regions, faster transportation and rapid spread of arthropod vectors contribute in continuous spreading of arboviruses into new geographic areas causing reemerging or resurging diseases. Most of the reemerging arboviruses also have emerged as zoonotic disease agents and created major public health issues and disease epidemics.

Potential Therapeutics Against Flaviviruses

Flaviviruses have been important human pathogens after emerging and resurging flavivirus diseases over the past decades. Although effective therapeutic agents are not yet commercially available for use in humans, significant progress has been made toward developing effective therapeutics and treatments. Several studies have shown that antibodies against the flaviviral E and NS1 proteins play a central role in prophylaxis and/or treatment of flavivirus infection through passive immunization. In addition, many anti-flavivirals, including interferons, oligonucleotide-based platforms, and small compounds, have been developed and evaluated for their antiviral effects. This review provides an overview of various approaches to the development of anti-flaviviral candidates and new insights that could improve our strategies for designing effective therapeutics against flaviviruses.

Concurrent dengue and malaria in the Amazon region / Co-infecção por dengue e malária na região Amazônica

INTRODUCTION: The Amazon region has extensive forested areas and natural ecosystems, providing favorable conditions for the existence of innumerous arboviruses. Over 200 arboviruses have been isolated in Brazil and about 40 are associated with human disease. Four out of 40 are considered to be of public health importance in Brazil: Dengue viruses (1-4), Oropouche, Mayaro and Yellow Fever. Along with these viruses, about 98 percent of the malaria cases are restricted to the Legal Amazon region. METHODS: This study aimed to investigate the presence of arboviruses in 111 clinical serum samples from patients living in Novo Repartimento (Pará), Plácido de Castro (Acre), Porto Velho (Rondônia) and Oiapoque (Amapá). The viral RNA was extracted and RT-PCR was performed followed by a Multiplex-Nested-PCR, using Flavivirus, Alphavirus and Orthobunyavirus generic and species-specific primers. RESULTS: Dengue virus serotype 2 was detected in two patients living in Novo Repartimento (Pará) that also presented active Plasmodium vivax infection. CONCLUSIONS: Despite scant data, this situation is likely to occur more frequently than detected in the Amazon region. Finally, it is important to remember that both diseases have similar clinical findings, thus the diagnosis could be made concomitantly for dengue and malaria in patients living or returning from areas where both diseases are endemic or during dengue outbreaks.

INTRODUÇÃO: A região Amazônica possui extensas áreas florestadas e ecossistemas naturais, provendo condições favoráveis para a existência de diversos arbovírus. Aproximadamente, 200 arbovírus foram isolados no Brasil, e 40 estão associados com doenças em humanos. Quatro destes 40 são considerados ser de importância para a saúde pública no Brasil: vírus da dengue (1-4), Oropouche, Mayaro e febre amarela. Juntamente com estes vírus, aproximadamente 98 por cento dos casos de malária estão restritos à região da Amazônia Legal. MÉTODOS: O objetivo deste estudo foi investigar a presença de arbovírus em 111 amostras clínicas de sangue de pacientes que residiam em Novo Repartimento (Pará), Plácido de Castro (Acre), Porto Velho (Rondônia) and Amapá (Macapá). O RNA viral foi extraído, RT-PCR foi realizada seguida de uma Multiplex-Nested-PCR, usando primers genéricos e espécie-específicos para Flavivirus, Alphavirus and Orthobunyavirus. RESULTADOS: Detectamos o vírus da dengue, sorotipo 2, em dois pacientes que residiam em Novo Repartimento (Pará), que também tinham infecção por Plasmodium vivax. CONCLUSÕES: Apesar de dados escassos, esta situação, provavelmente, ocorre mais frequência que a detectada na região Amazônica. Definitivamente, é importante lembrar que ambas as doenças possuem achados clínicos similares, assim o diagnóstico deveria ser feito concomitantemente para dengue e malária em pacientes que residem ou estão voltando de áreas onde ambas as doenças são endêmicas.

Expression of the Structural Proteins of Japanese Encephalitis Virus

Japanese encephalitis virus (JEV) is one of the most important human pathogens, which causes the permanent neuropsychiatric sequelae and even fatal diseases with high mortality and morbidity, especially among children. In this study, we expressed the structural proteins (C, prM, and E) of JEV using a Sindbis virus-based heterologous gene expression vector, the pSinRep5. We designed two expression vectors (pSinRep5/JEV C-E and pSinRep5/JEV C-NS1), which encode the precise coding sequence of JEV C-E and JEV C-NS1 proteins, respectively. These cloned JEV structural protein genes were designed to express under the Sindbis virus subgenomic promoter. Upon the transfection and expression of the pSinRep5/JEV C-E or pSinRep5/JEV C-NS1 plasmid, the transfected cells expressed approximately 55 kDa JEV E prtiens. As designed, the JEV NS1 proteins were expressed only in the SinRep5/JEV C-NS1 RNAtransfected cells. In addition, we found in the pSinRep5/JEV C-NS1-transfected cells that the viral proteins were predominantly localized around the perinuclear membranes. On the other hand, cytoplasmic staining was mainly observed in the pSinRep5/JEV C-E RNA-transfected cells in the absence of NS1 protein. Thus, our system will provide a useful tool to dissect intracellular membrane localization signals located in the JEV structural proteins without handling the infectious JEV viral particles and to characterize viral morphogenesis of this pathogen.