Summary: | ABSTRACT Filoviruses depend on the nucleoprotein (NP) to accomplish multiple functions during the viral life cycle. NP is the most abundantly expressed viral protein in infected cells and the main component of the viral nucleocapsid. It can be structurally divided into amino- and carboxy- terminal domains (NTD and CTD). The NTD can homo-oligomerize to interact and protect the (−) ssRNA genome, forming long helical structures. The flexible CTD is responsible for the binding of other nucleocapsid proteins and is involved in the formation of inclusion bodies (IBs)—the cytoplasmic sites of nucleocapsid formation and genome replication. The CTD ends in a ~100-residue globular tail. Měnglà virus (MLAV) is the only member of the new Dianlovirus genus within the Filoviridae family. Their differential characteristics and the possibility of becoming a threat for human health justify the interest in better understanding of its structure and function. In this work, we present the structure of the globular tail of the MLAV NP CTD, showing an overall conformation closely related to that previously reported for the equivalent NP region in MARV. Moreover, analyses of the CTD-CTD interactions in the crystal asymmetric unit revealed a higher-order helicoidal structure. Mutational studies underscore the crucial role of a number of residues, located at the CTD-CTD contact interface, for IB formation. Site-directed mutagenesis of amino acids L653 and F687, involved in the formation of these helicoidal assemblies, abrogate the growth of IBs when the full-length MLAV NP was ectopically expressed in cells. Our findings confirm the role of NP CTD in IB formation, also for MLAV, and focus the attention on particular residues as starting point for further analysis. IMPORTANCE Filoviruses are the causative agents of severe and often fatal hemorrhagic disease in humans. Měnglà virus (MLAV) is a recently reported filovirus, isolated from fruit bats that is capable to replicate in human cells, representing a potential risk for human health. An in-depth structural and functional knowledge of MLAV proteins is an essential step for antiviral research on this virus that can also be extended to other emerging filoviruses. In this study, we determined the first crystal structures of the C-terminal domain (CTD) of the MLAV nucleoprotein (NP), showing important similarities to the equivalent domain in MARV. The structural data also show that the NP CTD has the ability to form large helical oligomers that may participate in the control of cytoplasmic inclusion body formation during viral replication.
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