Filling Knowledge Gaps for Mimivirus Entry, Uncoating, and Morphogenesis.

Since the discovery of mimivirus, its unusual structural and genomic features have raised great interest in the study of its biology; however, many aspects concerning its replication cycle remain uncertain. In this study, extensive analyses of electron microscope images, as well as biological assay results, shed light on unclear points concerning the mimivirus replication cycle. We found that treatment with cytochalasin, a phagocytosis inhibitor, negatively impacted the incorporation of mimivirus particles by Acanthamoeba castellanii, causing a negative effect on viral growth in amoeba monolayers. Treatment of amoebas with bafilomicin significantly impacted mimivirus uncoating and replication. In conjunction with microscopic analyses, these data suggest that mimiviruses indeed depend on phagocytosis for entry into amoebas, and particle uncoating (and stargate opening) appears to be dependent on phagosome acidification. In-depth analyses of particle morphogenesis suggest that the mimivirus capsids are assembled from growing lamellar structures. Despite proposals from previous studies that genome acquisition occurs before the acquisition of fibrils, our results clearly demonstrate that the genome and fibrils can be acquired simultaneously. Our data suggest the existence of a specific area surrounding the core of the viral factory where particles acquire the surface fibrils. Furthermore, we reinforce the concept that defective particles can be formed even in the absence of virophages. Our work provides new information about unexplored steps in the life cycle of mimivirus.IMPORTANCE Investigating the viral life cycle is essential to a better understanding of virus biology. The combination of biological assays and microscopic images allows a clear view of the biological features of viruses. Since the discovery of mimivirus, many studies have been conducted to characterize its replication cycle, but many knowledge gaps remain to be filled. In this study, we conducted a new examination of the replication cycle of mimivirus and provide new evidence concerning some stages of the cycle which were previously unclear, mainly entry, uncoating, and morphogenesis. Furthermore, we demonstrate that atypical virion morphologies can occur even in the absence of virophages. Our results, along with previous data, allow us to present an ultimate model for the mimivirus replication cycle.

High positivity of mimivirus in inanimate surfaces of a hospital respiratory-isolation facility, Brazil.

BACKGROUND: Mimiviruses have been considered putative emerging pneumonia agents. Pneumonia is a leading cause of death related to infection throughout the world, with approximately 40% of cases presenting unknown etiology. Therefore, identifying new causative agents of community and nosocomial pneumonia is of major public health concern. OBJECTIVE: We evaluated the distribution of these viruses in samples collected from different environments of one of the largest hospitals in Brazilian Southeast. STUDY DESIGN: We analyzed, by molecular and virological approaches, the distribution of mimivirus in 242 samples collected from inanimate surfaces in different hospital facilities. RESULTS: A significant positivity of mimivirus in respiratory-isolation-facilities was observed (p<0.001). CONCLUSION: Although the role of mimivirus as etiological agents of pneumonia is still under investigation, our results demonstrates interesting correlations that strengthens the need for control over the occurrence of these viruses in hospital facilities.

Virucidal activity of chemical biocides against mimivirus, a putative pneumonia agent.

BACKGROUND: Acanthamoeba polyphaga mimivirus (APMV), the largest known virus, has been studied as a putative pneumonia agent, especially in hospital environments. Despite the repercussions of the discovery of APMV, there has been no study related to the control of APMV and the susceptibility of this virus to disinfectants. OBJECTIVES: This work investigated the virucidal activity against mimivirus of chemical biocides commonly used in clinical practice for the disinfection of hospital equipment and rooms. STUDY DESIGN: APMV was dried on sterilized steel coupons, exposed to different concentrations of alcohols (ethanol, 1-propanol and 2-propanol) and commercial disinfectants (active chlorine, glutaraldehyde and benzalkonium chloride) and titrated in amoebas using the TCID50 value. The stability of APMV on an inanimate surface was also tested in the presence and absence of organic matter for 30 days. RESULTS: APMV showed a high level of resistance to chemical biocides, especially alcohols. Only active chlorine and glutaraldehyde were able to decrease the APMV titers to undetectable levels. Dried APMV showed long-lasting stability on an inanimate surface (30 days), even in the absence of organic matter. CONCLUSIONS: The data presented herein may help health and laboratory workers plan the best strategy to control this putative pneumonia agent from surfaces and devices.