Produção de citocinas e óxido nítrico por macrófagos de camundongos infectados com flavivírus brasileiros

The Flaviviridae family, Flavivirus genus includes viruses that are transmitted to vertebrates by infected mosquitoes or ticks. The genus Flavivirus includes a variety of viruses that cause diseases such as acute febrile illness, encephalitis, and hemorrhagic fever. Flaviviruses primarily infect blood monocytes and tissue macrophages, which have been shown to be permissive, supporting viral replication and serving as virus reservoirs. On the other hand, these cells may have an important antiviral activity related to modulation by cytokine production and by the capacity of these cells to synthesize reactive free radicals such as nitric oxide (NO) which can have a microbicidal effect. The present study was performed in order to determine the production of cytokines interleukin-1beta (IL-1β), tumor necrosis factor -alpha (TNF-α), transforming growth factor- beta (TGF-β) and interferon -alpha (IFN-α) and NO by macrophages infected with one of four Brazilian flaviviruses, Bussuquara virus (BUSV), Yellow Fever virus (YFV), Rocio virus (ROCV) and Encephalitis Saint Louis virus (SLEV), and to verify the possible antiviral effect of NO during macrophage infection with ROCV. Moreover, we asked if the different viruses were able to regulate bacterial lipopolysaccharide (LPS) induced cytokine production. Our results showed that YFV and SLEV reduced the production of IL-1β and TGF-β by LPS-stimulated macrophages, while ROCV only diminished LPS-stimulated TGF-β synthesis. On the other hand, BUSV more likely favored an enhancement of the LPS-induced production of IL-1β by macrophages. Additionally, while most of the viruses stimulated the production of IFN-α, none of them altered the production of TNF-α by murine macrophages. Interestingly, all viruses induced synthesis of NO that was not correlated with antiviral activity for ROCV.A família Flaviviridae, gênero flavivírus inclui vírus que são transmitidos para os vertebrados por mosquitos e carrapatos. O gênero flavivirus inclui uma variedade de vírus que causa doenças como febres, encefalites e febres hemorrágicas. Primeiramente, as flaviviroses infectam monócitos do sangue e macrófagos do tecido, o qual tem mostrado ser permissivo, suportando a replicação viral e servindo como reservatório de vírus. Por outro lado, essas células podem ter uma importante atividade antiviral relacionada à modulação pela produção de citocinas e pela capacidade destas células sintetizar reativos de radicais livres como óxido nítrico (NO) o qual tem efeito microbicida. O presente estudo foi realizado a fim de determinar a produção de citocinas interleucina -1 beta (IL-1β), fator de necrose tumoral-alfa (TNF-α), fator de crescimento transformador-beta (TGF-β), interferon - alfa (IFN-α) e NO pelos macrófagos infectados com os quatros flavivírus como vírus Bussuquara (BUSV), vírus da febre amarela (YFV), vírus Rocio (ROCV) e vírus da Encefalite de Saint Louis (SLEV), e verificar o possível efeito antiviral de NO durante a infecção dos macrófagos com ROCV. Além disso, com os diferentes vírus foram capazes de regular o lipopolissacarídeo bacteriano (LPS) indutor da produção de citocinas. Nossos resultados mostraram que YFV e SLEV reduziram a produção de IL-1β e TGF-β quando macrófagos foram estimulados pelo LPS, enquanto ROCV somente diminuiu a síntese de TGF-β estimulada pelo LPS. Entretanto, BUSV favoreceu uma acentuada produção de IL-1β pelos macrófagos estimulados pelo LPS, enquanto os vírus estimularam a produção de IFN-α, nenhum deles alterou a produção de TNF-α pelos macrófagos murinos. Interessantemente, todos os vírus induziram a síntese de NO que não esteve correlacionada com a atividade antiviral pelo ROCV

Reactive oxygen and nitrogen species during viral infections

Abstract Oxygen and nitrogen radicals are frequently produced during viral infections. These radicals are not only a physiological mechanism for pathogen clearance but also result in many pathological consequences. Low concentrations of radicals can promote viral replication; however high concentrations of radicals can also inhibit viral replication and are detrimental to the cell due to their mitogenic activity. We reviewed the detailed mechanisms behind oxygen and nitrogen radical production and focused on how viruses induce radical production. In addition, we examined the effects of oxygen and nitrogen radicals on both the virus and host. We also reviewed enzymatic and chemical detoxification mechanisms and recent advances in therapeutic antioxidant applications. Many molecules that modulate the redox balance have yielded promising results in cell and animal models of infection. This encourages their use in clinical practice either alone or with existing therapies. However, since the redox balance also plays an important role in host defence against pathogens, carefully designed clinical trials are needed to assess the therapeutic benefits and secondary effects of these molecules and whether these effects differ between different types of viral infections

Dengue viruses – an overview

Dengue viruses (DENVs) cause the most common arthropod-borne viral disease in man with 50–100 million infections per year. Because of the lack of a vaccine and antiviral drugs, the sole measure of control is limiting the Aedes mosquito vectors. DENV infection can be asymptomatic or a self-limited, acute febrile disease ranging in severity. The classical form of dengue fever (DF) is characterized by high fever, headache, stomach ache, rash, myalgia, and arthralgia. Severe dengue, dengue hemorrhagic fever (DHF), and dengue shock syndrome (DSS) are accompanied by thrombocytopenia, vascular leakage, and hypotension. DSS, which can be fatal, is characterized by systemic shock. Despite intensive research, the underlying mechanisms causing severe dengue is still not well understood partly due to the lack of appropriate animal models of infection and disease. However, even though it is clear that both viral and host factors play important roles in the course of infection, a fundamental knowledge gap still remains to be filled regarding host cell tropism, crucial host immune response mechanisms, and viral markers for virulence