Oropouche Virus Disease Among U.S. Travelers - United States, 2024.

Beginning in late 2023, Oropouche virus was identified as the cause of large outbreaks in Amazon regions with known endemic transmission and in new areas in South America and the Caribbean. The virus is spread to humans by infected biting midges and some mosquito species. Although infection typically causes a self-limited febrile illness, reports of two deaths in patients with Oropouche virus infection and vertical transmission associated with adverse pregnancy outcomes have raised concerns about the threat of this virus to human health. In addition to approximately 8,000 locally acquired cases in the Americas, travel-associated Oropouche virus disease cases have recently been identified in European travelers returning from Cuba and Brazil. As of August 16, 2024, a total of 21 Oropouche virus disease cases were identified among U.S. travelers returning from Cuba. Most patients initially experienced fever, myalgia, and headache, often with other symptoms including arthralgia, diarrhea, nausea or vomiting, and rash. At least three patients had recurrent symptoms after the initial illness, a common characteristic of Oropouche virus disease. Clinicians and public health jurisdictions should be aware of the occurrence of Oropouche virus disease in U.S. travelers and request testing for suspected cases. Travelers should prevent insect bites when traveling, and pregnant persons should consider deferring travel to areas experiencing outbreaks of Oropouche virus disease.

Oropouche Fever, Cuba, May 2024.

Phylogenetic analyses showed that the virus responsible for a May 2024 Oropouche fever outbreak in Cuba was closely related to viruses from Brazil in 2023. Pools of Ceratopogonidae spp. biting midges and Culex quinquefasciatus mosquitoes were positive for Oropouche viral RNA. No cases were severe. Virus extension to new areas may increase case numbers and severity.

Diretrizes para a Detecção e Vigilância de Oropouche em possíveis casos de infecção vertical, malformação congênita ou morte fetal/Directrices para la Detección y Vigilancia de Oropouche en posibles casos de infección vertical, malformación congénita o muerte fetal

Orientaciones sobre el diagnóstico y vigilancia por laboratorio de arbovirus emergentes, incluyendo OROV, se detallan en las “Directrices para la Detección y Vigilancia de Arbovirus Emergentes en el Contexto de la Circulación de Otros Arbovirus”

Febre oropouche

O site atua como uma plataforma central para conectar cidadãos, profissionais de saúde, pesquisadores e gestores públicos, facilitando o acesso a informações e serviços essenciais para a saúde no Brasil. informações atualizadas sobre políticas, programas e ações de saúde pública, além de dados epidemiológicos e estatísticas de saúde. Campanhas de conscientização sobre prevenção de doenças, saúde da mulher, saúde infantil, saúde do idoso, entre outras áreas. Legislação e Regulamentação: Publicar e atualizar normas, portarias, resoluções e diretrizes relacionadas ao sistema de saúde e à prática médica no Brasil, etc

Fiocruz Amazônia identifica primeiro caso de oropouche na tríplice fronteira

O site da FIOCRUZ (Fundação Oswaldo Cruz) oferece uma ampla gama de conteúdos e funcionalidades relacionadas à saúde pública, pesquisa científica, educação e desenvolvimento tecnológico.

Perguntas e respostas sobre o vírus Oropouche/Preguntas y respuestas sobre el virus Oropouche/ Q&A – Oropouche fever

Washington D.C., 24 de julho de 2024 (OPAS) [Atualizado em 26 de julho de 2024] – Em julho deste ano, a Organização Pan-Americana da Saúde (OPAS) emitiu alerta epidemiológico sobre um aumento nos casos notificados do vírus Oropouche (OROV) em cinco países (Brasil, Bolívia, Peru, Cuba e Colômbia) na Região das Américas. Washington D.C., 24 de julio de 2024 (OPS) [Actualizado el 26 de julio de 2024] – En julio de este año, la Organización Panamericana de la Salud (OPS) emitió una alerta epidemiológica sobre un aumento de casos reportados del virus Oropouche (OROV) en cinco países (Brasil, Bolivia, Perú, Cuba y Colombia) de la Región de las Américas. Washington D.C., 24 July 2024 (PAHO) [Updated 26 July 2024] – In July this year, the Pan American Health Organization (PAHO) issued an epidemiological alert on an increase in reported cases of Oropouche virus (OROV) in five countries (Brazil, Bolivia, Peru, Cuba and Colombia) in the Region of the Americas.

Spatiotemporal Epidemiology of Oropouche Fever, Brazil, 2015-2024.

We assessed the spatiotemporal dynamics of Oropouche fever in Brazil during 2015-2024. We found the number of cases substantially increased during that period, particularly in the Amazon region. Our findings underscore the need for improved surveillance and public health measures in response to the disease's potential spread beyond endemic areas.

A reporter Oropouche virus expressing ZsGreen from the M segment enables pathogenesis studies in mice.

Oropouche fever caused by Oropouche virus (OROV) is a significant zoonosis in Central and South America. Despite its public health significance, we lack high-throughput diagnostics, therapeutics, and a comprehensive knowledge of OROV biology. Reporter viruses are valuable tools to rapidly study virus dynamics and develop neutralization and antiviral screening assays. OROV is a tri-segmented bunyavirus, which makes generating a reporter virus challenging, as introducing foreign elements into the viral genome typically affects fitness. We previously demonstrated that the non-structural gene NSm on the OROV medium (M) segment is non-essential for replication in vitro. Taking advantage of this, we have now generated a recombinant OROV expressing fluorescent protein ZsGreen in place of NSm. This reporter OROV is both stable and pathogenic in IFNAR-/- mice and provides a powerful tool for OROV pathogenesis studies and assay development.IMPORTANCEEmerging and reemerging infectious agents such as zoonotic bunyaviruses are of global health concern. Oropouche virus (OROV) causes recurring outbreaks of acute febrile illness in the Central and South American human populations. Biting midges are the primary transmission vectors, whereas sloths and non-human primates are their reservoir hosts. As global temperatures increase, we will likely see an expansion in arthropod-borne pathogens such as OROV. Therefore, developing reagents to study pathogen biology to aid in identifying druggable targets is essential. Here, we demonstrate the feasibility and use of a fluorescent OROV reporter in mice to study viral dynamics and pathogenesis. We show that this reporter OROV maintains characteristics such as growth and pathogenicity similar to the wild-type virus. Using this reporter virus, we can now develop methods to assist OROV studies and establish various high-throughput assays.

Rab27a GTPase and its effector Myosin Va are host factors required for efficient Oropouche virus cell egress.

Oropouche fever, a debilitating illness common in South America, is caused by Oropouche virus (OROV), an arbovirus. OROV belongs to the Peribunyaviridae family, a large group of RNA viruses. Little is known about the biology of Peribunyaviridae in host cells, especially assembly and egress processes. Our research reveals that the small GTPase Rab27a mediates intracellular transport of OROV induced compartments and viral release from infected cells. We show that Rab27a interacts with OROV glycoproteins and colocalizes with OROV during late phases of the infection cycle. Moreover, Rab27a activity is required for OROV trafficking to the cell periphery and efficient release of infectious particles. Consistently, depleting Rab27a's downstream effector, Myosin Va, or inhibiting actin polymerization also hinders OROV compartments targeting to the cell periphery and infectious viral particle egress. These data indicate that OROV hijacks Rab27a activity for intracellular transport and cell externalization. Understanding these crucial mechanisms of OROV's replication cycle may offer potential targets for therapeutic interventions and aid in controlling the spread of Oropouche fever.

Imaging Bunyavirus Infections by Transmission Electron Microscopy: Conventional Sample Preparation vs High-Pressure Freezing and Freeze-Substitution.

Transmission electron microscopy significantly contributed to unveil the course of virus entry, replication, morphogenesis, and egress. For these studies, the most widely used approach is imaging ultrathin sections of virus-infected cells embedded in a plastic resin that is transparent to electrons. Before infiltration in a resin, cells must be processed to stabilize their components under the observation conditions in an electron microscope, such as high vacuum and irradiation with electrons. For conventional sample preparation, chemical fixation and dehydration are followed by infiltration in the resin and polymerization to produce a hard block that can be sectioned with an ultramicrotome. Another method that provides a superior preservation of cell components is high-pressure freezing (HPF) followed by freeze substitution (FS) before resin infiltration and polymerization. This chapter describes both procedures with cells infected with Bunyamwera virus (BUNV), a well characterized member of the Bunyavirales, and compares the morphological details of different viral structures imaged in the two types of samples. Advantages, disadvantages, and applications of conventional processing and HPF/FS are also presented and discussed.

Single-Molecule Visualization of Bunyavirus Genome Segments Using Fluorescence In Situ Hybridization.

The genome of most bunyaviruses is divided over three (S, M, and L) single-stranded RNA segments of negative polarity. The three viral RNA segments are essential to establish a productive infection. RNA fluorescence in situ hybridization (FISH) enables the detection, localization, and quantification of RNA molecules at single-molecule resolution. This chapter describes an RNA FISH method to directly visualize individual segment-specific bunyavirus RNAs in fixed infected cells and in mature virus particles, using Rift Valley fever virus as an example. Imaging of bunyavirus RNA segments is a valuable experimental tool to investigate fundamental aspects of the bunyavirus life cycle, such as virus replication, genome packaging, and virion assembly, among others.

N-glycosylation of viral glycoprotein is a novel determinant for the tropism and virulence of highly pathogenic tick-borne bunyaviruses.

Severe fever with thrombocytopenia syndrome (SFTS) virus, a tick-borne bunyavirus, causes a severe/fatal disease termed SFTS; however, the viral virulence is not fully understood. The viral non-structural protein, NSs, is the sole known virulence factor. NSs disturbs host innate immune responses and an NSs-mutant SFTS virus causes no disease in an SFTS animal model. The present study reports a novel determinant of viral tropism as well as virulence in animal models, within the glycoprotein (GP) of SFTS virus and an SFTS-related tick-borne bunyavirus. Infection with mutant SFTS viruses lacking the N-linked glycosylation of GP resulted in negligible usage of calcium-dependent lectins in cells, less efficient infection, high susceptibility to a neutralizing antibody, low cytokine production in macrophage-like cells, and reduced virulence in Ifnar-/- mice, when compared with wildtype virus. Three SFTS virus-related bunyaviruses had N-glycosylation motifs at similar positions within their GP and a glycan-deficient mutant of Heartland virus showed in vitro and in vivo phenotypes like those of the SFTS virus. Thus, N-linked glycosylation of viral GP is a novel determinant for the tropism and virulence of SFTS virus and of a related virus. These findings will help us understand the process of severe/fatal diseases caused by tick-borne bunyaviruses.

Little-known virus surging in Latin America may harm fetuses.

Oropouche virus could be linked to brain malformation and stillbirths, Brazilian health officials say.