A study of the MAYV replication cycle: Correlation between the kinetics of viral multiplication and viral morphogenesis.

Mayaro virus (MAYV) is mainly found in Central and South America and causes a febrile illness followed by debilitating arthritis and arthralgia similar to chikungunya virus (CHIKV). Infection leads to long-term sequelae with a direct impact on the patient's productive capacity, resulting in economic losses. Mayaro fever is a neglected disease due to the limited epidemiological data. In Brazil, it is considered a potential public health risk with the number of cases increasing every year. Most of our knowledge about MAYV biology is inferred from data obtained from other alphaviruses as well as more recent studies on MAYV. Here, we analyzed the kinetics of viral replication through standard growth curves, quantification of intracellular and extracellular particles, and RNA quantification. We compared transmission electron microscopy data during different stages of infection. This approach allowed us to establish a chronological order of events during MAYV replication and its respective timepoints including cell entry through clathrin-mediated endocytosis occurring at 15-30 min, genome replication at 2-3 h, morphogenesis at 4 hpi, and release at 4-6 hpi. We also present evidence of uncharacterized events such as ribosome reorganization as well as clusters of early viral precursors and release through exocytosis in giant forms. Our work sheds new and specific light on the MAYV replication cycle and may contribute to future studies on the field.

In-Depth Characterization of the Chikungunya Virus Replication Cycle.

The chikungunya virus has spread globally with a remarkably high attack rate. Infection causes arthralgic sequelae that can last for years. Nevertheless, there are no specific drugs or vaccines to contain the virus. Understanding the biology of the virus, such as its replication cycle, is a powerful tool to identify new drugs and comprehend virus-host interactions. Even though the chikungunya virus has been known for a long time (it was first described in 1952), many aspects of the replication cycle remain unclear. Furthermore, part of the cycle is based on observations of other alphaviruses. In this study, we used electron and scanning microscopy, as well as biological assays, to analyze and investigate the stages of the chikungunya virus replication cycle. Based on our data, we found infection cellular activities other than those usually described for the chikungunya virus replication cycle, i.e., we show particles enveloping intracellularly without budding in a membrane-delimited morphogenesis area, and we also observed virion release by membrane protrusions. Our work provides novel details regarding the biology of chikungunya virus and fills gaps in our knowledge of its replication cycle. These findings may contribute to a better understanding of virus-host interactions and support the development of antivirals. IMPORTANCE The understanding of virus biology is essential to containing virus dissemination, and exploring the virus replication cycle is a powerful tool to do this. There are many points in the biology of the chikungunya virus that need to be clarified, especially regarding its replication cycle. Our incomplete understanding of chikungunya virus infection stages is based on studies with other alphaviruses. We systematized the chikungunya virus replication cycle using microscopic imaging in the order of infection stages, as follows: entry, replication, protein synthesis, assembly/morphogenesis, and release. The imaging evidence shows novel points in the replication cycle of enveloping without budding, as well as particle release by cell membrane protrusion.

Dengue virus 3 genotype I shows natural changes in heparan sulphate binding sites, cell interactions, and neurovirulence in a mouse model.

Dengue virus (DENV) is the most prevalent pathogen of the Flaviviridae family. Due to the considerable increase in DENV incidence and spread, symptoms such as CNS involvement have increased. Heparan sulphate (HS) was the first molecule identified as an adhesion factor for DENV in mammalian cells. Viral phenotypes with different HS interactions are associated with various clinical symptoms, including neurological alterations. Here, using in silico analyses, in vitro studies, and the in vivo mouse model, we characterized two natural circulating DENV3 genotype I (GI) lineage 1 (L1) in Brazil-DENV3 MG-20 (from Minas Gerais) and DENV3 PV_BR (from Rondônia) that present divergent neurovirulent profiles and sensitivity to sulphated molecules. We identified substitutions at the viral envelope (E) in positions 62 and 123 as likely responsible for the differences in neurovirulence. The E62K and E123Q substitutions in DENV3 MG-20 and DENV3 PV_BR, respectively, greatly influenced in silico electrostatic density and heparin docking results. In vivo, mice inoculated with DENV3 MG-20 died, but not those infected with DENV3 PV_BR. The clinical symptoms, such as paralysis of the lower limbs and meningoencephalitis, and histopathology, also differed between the inoculated groups. In vitro heparin and heparinases assays further demonstrated the biological impact of these substitutions. Other characteristics that have been previously associated with alterations in cell tropism and neurovirulence, such as changes in the size of lysis plaques and differences in cytopathic effects in glioblastoma cells, were also observed.