Getting on the right track: Interactions between viruses and the cytoskeletal motor proteins

Nuclear deformation by microtubule molecular motors

We present a model to calculate the displacement and extension of deformable cellular cargo pulled by molecular motors stepping along cytoskeletal filaments. We consider the case of a single type of molecular motor and cytoskeletal filaments oriented in one dimension in opposite directions on either side of a cargo. We model a deformable cargo as a simple elastic spring. We simulate this tug-of-war simple exclusion process model using a Monte Carlo Gillespie algorithm and calculate the displacement and extension of the cargo for different configurations of motors and filaments. We apply our model to kinesin-1 motors on microtubules to investigate whether they are strong enough to translocate and deform the largest cellular cargo, the nucleus. We show that the extension caused by motors on a single microtubule saturates for larger numbers of motors but that the extension and displacement scales linearly with the number of microtubules. We also show how the binding and unbinding behaviors of molecular motors on microtubule filaments affect the nuclear deformation. Our modelling results correspond to experiments on cells treated with the drug kinesore, which is thought to increase rescue events resulting in more stable microtubules and more active kinesin-1 molecular motors bound to them. Both the experiments and our simulations result in nuclear deformation.

Role of c-ABL in DENV-2 Infection and Actin Remodeling in Vero Cells

In this study, we address the role of c-ABL (cellular Abelson Tyr kinase) in the cytoskeletal rearrangements induced by DENV (Dengue virus) infection in mammalian cells. Using the specific inhibitor imatinib and targeted RNA interference, we show that c-ABL is necessary for viral entry and subsequent ENV (DENV envelope protein) accumulation in infected cells. In addition, c-ABL targeting attenuates F-actin reorganization induced by DENV infection. Together with the involvement of c-ABL in endothelial dysfunction induced by DENV and host secreted factors, our findings strongly suggest that c-ABL is a potential host-targeted antiviral that could control DENV infection and/or its evolution to more severe forms of the disease.

Classical swine fever virus recruits ALIX and ESCRT-III to facilitate viral budding

Classical swine fever virus (CSFV) incurs substantial economic losses in the global swine industry due to its persistent emergence and re-emergence across various countries. However, the precise mechanisms governing CSFV budding remain inadequately understood. Our study elucidates that the endosomal sorting complex required for transport (ESCRT)-associated protein ALIX, in conjunction with ESCRT-III, plays a pivotal role in orchestrating CSFV budding. Genomic sequence analysis identified a critical interaction between the YPXnL late domain on the E2 protein and ALIX. Through immunoprecipitation and structural domain deletion assays, we demonstrated that the ALIX Bro1 domain specifically recognized viral particles by binding to the YPXnL motif. Immunoelectron and transmission electron microscopy further confirmed that, upon infection, ALIX accumulated at the periphery of subcellular organelles, including COPII vesicles, endosomes, and the Golgi apparatus, thereby facilitating CSFV budding. Our findings also revealed that ESCRT-III subunits CHMP2B, CHMP4B, CHMP7, and VPS4A interacted with ALIX to expedite CSFV budding. Notably, Rab8 activated by Kif4A contributed to the release of CSFV particles by interacting with ALIX and directing ALIX-containing vesicles along microtubules toward the cytosol. Our study demonstrates that ALIX specifically recognizes E2 and orchestrates the recruitment of ESCRT-III and Rab8 to facilitate the vesicular budding of CSFV particles from the Golgi apparatus to the cytosol. Ultimately, virus-laden vesicles propelled by Kif4A are transported along microtubules to the plasma membrane for release. Our findings offer the first comprehensive elucidation of the CSFV budding process and contribute to the identification of antiviral targets, thereby advancing the development of antiviral therapeutics.IMPORTANCEThe endosomal sorting complex required for transport (ESCRT) machinery plays a pivotal role in the sorting of membrane proteins in eukaryotic cells and regulating various stages of infection for numerous viruses. Previous studies have underscored the indispensable role of ESCRT in the cellular entry and replication of classical swine fever virus (CSFV). However, the precise mechanisms by which ESCRT recognizes CSFV particles and initiates viral vesicle budding have remained elusive. This study reveals that the Bro1 domain of ALIX initiates viral budding proximal to the Golgi apparatus by specifically recognizing the YPXnL late domain on the CSFV E2 protein. Mechanistically, ALIX and ESCRT-III facilitate Rab8-regulated endosomal transport of CSFV particles from the Golgi apparatus to the plasma membrane. Subsequently, virions are propelled by the kinesin Kif4A along microtubules for egress into the extracellular space. In summary, these findings significantly advance our understanding of CSFV pathogenesis and offer valuable insights into the vesicular transport and budding mechanisms of CSFV particles.

Kinesin light chain 1 (KLC1) interacts with NS1 and is a susceptibility factor for dengue virus infection in mosquito cells

A hallmark of the dengue virus (DENV) infection is the manipulation of host cell membranes, lipid trafficking and lipid droplets (LDs), all cellular functions that depend on the cytoskeleton and the cytoplasmatic streaming system. We previously reported the interaction between DENV NS1 protein and members of the kinesin motor complex in the Aedes albopictus cell line C6/36. In this work, we present evidence indicating that the protein kinesin light chain 1 (KLC1) is indeed a susceptibility factor for DENV replicative cycle in mosquito cells. The interaction between NS1 and KLC1 was confirmed by proximity ligation and co-immunoprecipitation assays in cells harvested 24 hpi. In addition, transmission immunoelectron microscopy showed KLC1 decorating the surface of vacuoles in association with NS1. Increased levels of KLC1 were observed starting at 6 hpi, suggesting that virus infection stimulates KLC1 synthesis. Silencing KLC1 expression results in a reduction in viral genome synthesis, decreased secretion of NS1, and a reduction of virus progeny by nearly 1 log. In agreement, similar affectations were observed in infected cells transfected with a peptide that competes and interferes with the interaction between KLC1 and its cargo molecules. Of note, both silencing the expression or interfering with the function of KLC1 resulted in a disorganization of LDs, which decreased in number and increased in area, in mock or infected cells. These results, taken together, suggest that KLC1 is a host susceptibility factor for DENV in mosquito cells, necessary for the proper transport and homeostasis of LDs required for flavivirus replication. However, modest colocalization was observed between NS1 and LDs, and the significance of the KLC1 and NS1 interactions need to be further investigated.

Zika virus NS3 drives the assembly of a viroplasm-like structure

Zika virus (ZIKV) is a mosquito-transmitted flavivirus that caused an epidemic in 2015-2016 in the Americas and raised serious global health concerns due to its association with congenital brain developmental defects in infected pregnancies. Upon infection, ZIKV assembles virus particles in a virus-generated toroidal compartment next to the nucleus called the replication factory, or viroplasm, which forms by remodeling the host cell endoplasmic reticulum (ER). How the viral proteins control viroplasm assembly remains unknown. Here we show that the ZIKV non-structural protein 3 (NS3) is sufficient to drive the assembly of a viroplasm-like structure (VLS) in human cells. NS3 encodes a dual-function protease and RNA helicase. The VLS is similar to the ZIKV viroplasm in its assembly near centrosomes at the nuclear periphery, its deformation of the nuclear membrane, its recruitment of ER, Golgi, and dsRNA, and its association with microtubules at its surface. While sufficient to generate a VLS, NS3 is less efficient in several aspects compared to viroplasm formation upon ZIKV infection. We further show that the helicase domain and not the protease domain is required for optimal VLS assembly and dsRNA recruitment. Overall, this work advances our understanding of the mechanism of viroplasm assembly by ZIKV and likely will extend to other flaviviruses.

From Entry to the Nucleus: How Retroviruses Commute

Once inside host cells, retroviruses generate a double-stranded DNA copy of their RNA genomes via reverse transcription inside a viral core, and this viral DNA is subsequently integrated into the genome of the host cell. Before integration can occur, the core must cross the cell cortex, be transported through the cytoplasm, and enter the nucleus. Retroviruses have evolved different mechanisms to accomplish this journey. This review examines the various mechanisms retroviruses, especially HIV-1, have evolved to commute throughout the cell. Retroviruses cross the cell cortex while modulating actin dynamics and use microtubules as roads while connecting with microtubule-associated proteins and motors to reach the nucleus. Although a clearer picture exists for HIV-1 compared with other retroviruses, there is still much to learn about how retroviruses accomplish their commute.

The Transient Receptor Potential Vanilloid 2 (TRPV2) Channel Facilitates Virus Infection Through the Ca2+ -LRMDA Axis in Myeloid Cells

The transient receptor potential vanilloid 2 (TRPV2) channel is a nonselective cation channel that has been implicated in multiple sensory processes in the nervous system. Here, it is shown that TRPV2 in myeloid cells facilitates virus penetration by promoting the tension and mobility of cell membrane through the Ca²⁺ -LRMDA axis. Knockout of TRPV2 in myeloid cells or inhibition of TRPV2 channel activity suppresses viral infection and protects mice from herpes simplex virus 1 (HSV-1) and vesicular stomatitis virus (VSV) infection. Reconstitution of TRPV2 but not the Ca²⁺ -impermeable mutant TRPV2^E572Q into LyZ2-Cre;Trpv2^fl/fl bone marrow-derived dendritic cells (BMDCs) restores viral infection. Mechanistically, knockout of TRPV2 in myeloid cells inhibits the tension and mobility of cell membrane and the penetration of viruses, which is restored by reconstitution of TRPV2 but not TRPV2^E572Q . In addition, knockout of TRPV2 leads to downregulation of Lrmda in BMDCs and BMDMs, and knockdown of Lrmda significantly downregulates the mobility and tension of cell membrane and inhibits viral infections in Trpv2^fl/fl but not LyZ2-Cre;Trpv2^fl/fl BMDCs. Consistently, complement of LRMDA into LyZ2-Cre;Trpv2^fl/fl BMDCs partially restores the tension and mobility of cell membrane and promotes viral penetration and infection. These findings characterize a previously unknown function of myeloid TRPV2 in facilitating viral infection though the Ca2⁺ -LRMDA axis.

Dynamic Actin Filament Traps Mediate Active Diffusion of Vesicular Stomatitis Virus Ribonucleoproteins

A recently developed variational Bayesian analysis using pattern recognition and machine learning of single viral ribonucleoprotein (RNP) particle tracks in the cytoplasm of living cells provides a quantitative molecular explanation for active diffusion, a concept previously "explained" largely by hypothetical models based on indirect analyses such as continuum microrheology. Machine learning shows that vesicular stomatitis virus (VSV) RNP particles are temporarily confined to dynamic traps or pores made up of cytoskeletal elements. Active diffusion occurs when the particles escape from one trap to a nearby trap. In this paper, we demonstrate that actin filament disruption increased RNP mobility by increasing trap size. Inhibition of nonmuscle myosin II ATPase decreased mobility by decreasing trap size. Trap sizes were observed to fluctuate with time, dependent on nonmuscle myosin II activity. This model for active diffusion is likely to account for the dominant motion of other viral and cellular elements. IMPORTANCE RNA virus ribonucleoproteins (RNPs) are too large to freely diffuse in the host cytoplasm, yet their dominant motions consist of movements in random directions that resemble diffusion. We show that vesicular stomatitis virus (VSV) RNPs overcome limitations on diffusion in the host cytoplasm by hopping between traps formed in part by actin filaments and that these traps expand and contract by nonmuscle myosin II ATPase activity. ATP-dependent random motion of cellular particles has been termed "active diffusion." Thus, these mechanisms are applicable to active diffusion of other cellular and viral elements.