Sequestration of Free Tubulin Molecules by the Viral Protein NSP2 Induces Microtubule Depolymerization during Rotavirus Infection

Microtubules, components of the cell cytoskeleton, play a central role in cellular trafficking. Here we show that rotavirus infection leads to a remodeling of the microtubule network together with the formation of tubulin granules. While most microtubules surrounding the nucleus depolymerize, others appear packed at the cell periphery. In microtubule depolymerization areas, tubulin granules are observed; they colocalize with viroplasms, viral compartments formed by interactions between rotavirus proteins NSP2 and NSP5. With purified proteins, we show that tubulin directly interacts in vitro with NSP2 but not with NSP5. The binding of NSP2 to tubulin is independent of its phosphatase activity. The comparison of three-dimensional (3-D) reconstructions of NSP2 octamers alone or associated with tubulin reveals electron densities in the positively charged grooves of NSP2 that we attribute to tubulin. Site-directed mutagenesis of NSP2 and competition assays between RNA and tubulin for NSP2 binding confirm that tubulin binds to these charged grooves of NSP2. Although the tubulin position within NSP2 grooves cannot be precisely determined, the tubulin C-terminal H12 α-helix could be involved in the interaction. NSP2 overexpression and rotavirus infection produce similar effects on the microtubule network. NSP2 depolymerizes microtubules and leads to tubulin granule formation. Our results demonstrate that tubulin is a viroplasm component and reveal an original mechanism. Tubulin sequestration by NSP2 induces microtubule depolymerization. This depolymerization probably reroutes the cell machinery by inhibiting trafficking and functions potentially involved in defenses to viral infections.Microtubules (MTs) are components of the cell cytoskeleton and play a major role in cellular trafficking. Molecular motors (dynein and kinesins) use MTs as tracks to address organelles to precise loci. Viruses are irreplaceable tools to study cellular processes; for example, many of them hijack cellular transport to reach the perinuclear region (for reviews, see references 27, 35, 39, and 40). Some viruses also modify the cell compartmentation and create viral inclusions where viral replication and virion assembly are performed (for a review, see reference 30). Both aspects are sometimes related; electron and fluorescence microscopy observations of reovirus-infected cells have shown that viral inclusions form an electron-dense coat surrounding the MTs (15, 32, 41). In the case of rotavirus, another member of the Reoviridae family, interactions between viral proteins and MTs remain unclear; some studies report an interaction between MTs and either NSP4 or VP4, whereas others did not detect these interactions (4, 19, 29, 51). Rotavirus is the leading agent of gastroenteritis in young children worldwide (31); studying its interactions with its host cell is thus of particular interest to identify new potential therapeutical targets.The rotavirus genome is composed of 11 double-stranded RNAs (dsRNA) surrounded by a triple-layer capsid. During rotavirus infection, punctuate cytoplasmic structures, named “viroplasms,” are formed; they are the sites of viral genome replication and virion assembly. These structures are made of several viral proteins and of viral mRNAs that serve as templates for genome replication. Two viral nonstructural proteins, NSP2 and NSP5, are crucial for viroplasm formation (10, 24, 38). Their coexpression in uninfected cells leads to the formation of punctuate cytoplasmic structures termed viroplasm-like structures (VLS) (18). NSP2 forms a doughnut-shaped octamer by tail-to-tail interaction of two tetramers; four positively charged grooves crossing the two tetramers have been identified (21). Structural and biochemical studies have revealed a histidine-triad (HIT)-like motif responsible for the nucleoside triphosphatase (NTPase), RNA triphosphatase (RTPase), and nucleoside diphosphate (NDP) kinase-like activities of NSP2 (21, 23, 42, 46). These catalytic activities are required for dsRNA synthesis but not for viroplasm formation (11, 43). NSP2 binds single-stranded RNA nonspecifically, has helix destabilizing activity (44), and undertakes conformational changes upon nucleotide binding (37). NSP2 might thus function as a molecular motor involved in genome replication and packaging. NSP5 is a dimeric O-linked glyco- and phosphoprotein, which exists as variously phosphorylated isoforms (1, 36, 48). A cryoelectron microscopy study pointed out that RNA and NSP5 compete for binding to the grooves of the NSP2 octamer (22). The function of NSP5 in rotavirus replication and the role of its phosphorylation remain unknown. No cellular partner of these two nonstructural proteins was known, until a possible association of both proteins with tubulin was reported (9).In the present report, we studied the interaction of rotavirus with tubulin and MTs. We focused on the cellular effects and the structural characterization of the interaction between tubulin and NSP2. Our results highlight that infection by the rotavirus RF strain disorganizes and depolymerizes the MT network of MA104 cells and that viroplasms colocalize with tubulin granules. Electron microscopy and biochemical experiments demonstrate that tubulin directly binds to the positively charged grooves of NSP2. Moreover, NSP2 overexpression induces MT depolymerization and tubulin granule formation. We thus propose that NSP2 sequesters tubulin in viroplasms during rotavirus infection. This sequestration induces the MT depolymerization observed during rotavirus infection and most probably modifies cellular trafficking.