Mayaro virus (MAYV) is an emergent arbovirus first described in forest regions of the American continent, with recent and increasing notification of urban area circulation. Similar to Chikungunya (CHIKV) and other arthritogenic Alphavirus, MAYV-induced disease shows a high prevalence of persistent arthralgia, and myalgia. Despite this, knowledge regarding pathogenesis and characteristics of host immune response of MAYV infections are still limited. Here, using different ages of wild-type (WT), adult Type I Interferon receptor deficient (IFNAR–/–), and adult recombination activation gene-1 deficient (RAG–/–) mice, we have investigated the dependence of age, innate and adaptive immunity for the control of MAYV replication, tissue damage, and inflammation in mice. We have found that MAYV induces clinical signal and replicates in young WT mice, which gain the ability to restrict MAYV replication with aging. In addition, we observed that mice age and type I interferon response are related to restriction of MAYV infection and muscular inflammation in mice. Moreover, MAYV continues to replicate persistently in RAG–/– mice, being detected at blood and tissues 40 days post infection, indicating that adaptive immunity is essential to MAYV clearance. Despite chronic replication, infected adult RAG–/– mice did not develop an apparent signal of muscle damage in early and late infection. On the other hand, MAYV infection in young WT and adult IFNAR-/- mice triggers an increase in the expression of pro-inflammatory mediators, such as TNF, IL-6, KC, IL-1β, MCP-1, and RANTES, in muscle tissue, and decreases TGF-β expression, that were not significantly modulated in adult WT and RAG–/– mice. Taken together, our data demonstrated that age, innate and adaptive immunity are important to restrict MAYV replication and that adaptive immunity is also involved in MAYV-induced tissue damage. These results contribute to the comprehension of MAYV pathogenesis, and describe translational mice models for further studies of MAYV infection, vaccine tests, and therapeutic strategies against this virus.
Zika virus (ZIKV) infection became a worldwide concern due to its correlation with the development of microcephaly and other neurological disorders. ZIKV neurotropism is well characterized, but the role of peripheral viral amplification to brain infection remains unknown. Here we found that ZIKV replicates in human primary skeletal muscle myoblasts, impairing its differentiation into myotubes but not interfering with the integrity of the already formed muscle fibers. Using mouse models, we showed ZIKV tropism to muscle tissue either during embryogenesis after maternal transmission or when infection occurred after birth. Interestingly, ZIKV replication in the mouse skeletal muscle started immediately after ZIKV inoculation, preceding viral RNA detection in the brain and causing no disruption to the integrity of the blood brain barrier, and remained active for more than two weeks, while replication in spleen and liver were not sustained over time. In addition, ZIKV infection of the skeletal muscle induces necrotic lesions, inflammation and fiber atrophy. We also found a reduction in the expression of regulatory myogenic factors that are essential for muscle repair after injury. Taken together our results indicate that the skeletal muscle is an early site of viral amplification and lesion that may result in late consequences in muscle development after ZIKV infection. Importance Zika Virus (ZIKV) neurotropism and its deleterious effects on central nervous system have been well characterized. But, investigations of the initial replication sites for the establishment of infection and viral spread to neural tissues remain under explored. The complete description of the range of ZIKV induced lesions and others factors that can influence the severity of the disease are necessary to prevent ZIKV deleterious effects. ZIKV has been shown to access the central nervous system without significantly affecting blood-brain barrier permeability. Here we demonstrated that skeletal muscle is an earlier site of ZIKV replication, contributing to the increase of peripheral ZIKV load. ZIKV replication in muscle promotes necrotic lesions, inflammation and also impairs myogenesis. Overall, our findings showed that skeletal muscle is involved in pathogenesis and opens new fields in the investigation of the long-term consequence of early infection.
Zika virus (ZIKV) infection causes severe neurological consequences in both gestationally-exposed infants and adults. Sensorial gating deficits strongly correlate to the motor, sensorial and cognitive impairments observed in ZIKV-infected patients. However, to date, no startle response or prepulse inhibition (PPI) assessment has been made in patients or animal models. In this study, we identified different outcomes for the age of infection and sex in wild-type mice: neonatally infected animals presented an increase in PPI and startle latency in both sexes, while adult infected males presented lower startle amplitude but preserved PPI. Our data further the understanding of the functional impacts of ZIKV on the developing and mature nervous system, which could help explain other behavioral and cognitive alterations caused by the virus. With this study, we support the use of startle reflex testing in ZIKV exposed patients, especially infants, allowing for early detection of functional neuromotor damage and early intervention.
Zika virus (ZIKV) infections are still a worldwide concern due to the severity of neurological outcomes. ZIKV neurotropism is well characterized, but peripheral tissue could be sites of viral amplification, contributing to endothelial-barrier crossing and access to peripheral nerves. During acute and late phases of infection, ZIKV can be detected in several body fluids, eyes, testis and vagina. However, the importance of initial replication sites for the establishment of infection and viral spread remain unknown. Here we demonstrated that ZIKV replicates primarily in human muscle precursor cells, resulting in cell death and inhibition of myogenesis. ZIKV also replicates in fetal muscle after maternal transmission and in infected neonate mice, inducing lesions and inflammation. Muscle was an important site of viral amplification, sustaining higher peripheral viral loads than liver and spleen. In addition, ZIKV showed rapid and sustained replication kinetics in muscle even before replication in the neural tissues, persisting until 16 days post infection. Our results highlight the importance of muscle in ZIKV pathogenesis as a peripheral site of viral amplification which may contribute to ZIKV reaching neural structures.Author SummaryZika Virus (ZIKV) neurotropism and its deleterious effects on central nervous system have been well characterized. But, investigations of the initial replication sites for the establishment of infection and viral spread to neural tissues remain under explored. Here we demonstrated that ZIKV replicates primarily in human skeletal muscle precursor cells, resulting in cell death and disrupted myogenesis. ZIKV also replicates in muscle of fetus and neonate mice inducing muscle damage and inflammation. Muscle replication occurs before amplification in peripheral nerves and brain, contributing to the increase of peripheral ZIKV load and dissemination. In addition, ZIKV RNA still been detected in skeletal muscle at late stages of infection. Overall, our findings showed that skeletal muscle is involved in ZIKV pathogenesis, contributing to a broader understanding of ZIKV infection. Thus, opens new aspects in the investigation of the long-term consequence of early infection.
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