Your search keyword '"Sherer, Nathan M."' showing total 7 results

1. Long-distance relationships: do membrane nanotubes regulate cell-cell communication and disease progression?

Author

Sherer NM

Subjects

Actins ultrastructure, Animals, Biological Transport, Cell Surface Extensions ultrastructure, Cells, Cultured, Humans, Actins physiology, Cell Communication, Cell Surface Extensions physiology

Abstract

Metazoan cells rapidly exchange signals at tight cell-cell interfaces, including synapses and gap junctions. Advances in imaging recently exposed a third mode of intercellular cross-talk mediated by thin, actin-containing membrane extensions broadly known as "membrane" or "tunneling" nanotubes. An explosion of research suggests diverse functions for nanotubular superhighways, including cell-cell electrical coupling, calcium signaling, small-molecule exchange, and, remarkably, the transfer of bulky cargoes, including organelles or pathogenic agents. Despite great enthusiasm for all things nanotubular and their potential roles in cell signaling and pathogenesis, key questions remain regarding the mechanisms by which these structures regulate directional cell-cell exchange; how these linkages are formed and between which cells and, critically, whether nanotubes are as prevalent in vivo as they appear to be in the incubator.

Published

2013

2. Cytonemes and tunneling nanotubules in cell-cell communication and viral pathogenesis.

Author

Sherer NM and Mothes W

Subjects

Animals, Cell Surface Extensions ultrastructure, Gap Junctions ultrastructure, Humans, Intercellular Junctions ultrastructure, Pseudopodia physiology, Pseudopodia ultrastructure, Synapses physiology, Viruses metabolism, Cell Adhesion physiology, Cell Communication physiology, Cell Surface Extensions physiology, Gap Junctions physiology, Intercellular Junctions physiology

Abstract

Cells use a variety of intercellular structures, including gap junctions and synapses, for cell-cell communication. Here, we present recent advances in the understanding of thin membrane bridges that function in cell-cell signaling and intercellular transport. Cytonemes or filopodial bridges connect neighboring cells via mechanisms of adhesion, which enable ligand-receptor-mediated transfer of surface-associated cargoes from cell to cell. By contrast, tunneling nanotubes establish tubular conduits between cells that provide for the exchange of both cell-surface molecules and cytoplasmic content. We propose models for the biogenesis of both types of membrane bridges and describe how viruses use these structures for the purpose of cell-to-cell spread.

Published

2008

3. Retroviruses can establish filopodial bridges for efficient cell-to-cell transmission.

Author

Sherer NM, Lehmann MJ, Jimenez-Soto LF, Horensavitz C, Pypaert M, and Mothes W

Subjects

Animals, Avian Proteins genetics, Avian Proteins metabolism, CD4 Antigens genetics, CD4 Antigens metabolism, COS Cells, Cell Line, Cell Line, Tumor, Chlorocebus aethiops, Endocytosis physiology, Eukaryotic Cells metabolism, HIV-1 physiology, Humans, Luminescent Proteins genetics, Luminescent Proteins metabolism, Microscopy, Electron, Scanning, Microscopy, Fluorescence, Mutation, Pseudopodia ultrastructure, Receptors, CXCR4 genetics, Receptors, CXCR4 metabolism, Receptors, Virus genetics, Receptors, Virus metabolism, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, TRPV Cation Channels genetics, TRPV Cation Channels metabolism, Viral Envelope Proteins genetics, Viral Envelope Proteins metabolism, Cell Communication physiology, Eukaryotic Cells virology, Pseudopodia virology, Retroviridae physiology

Abstract

The spread of retroviruses between cells is estimated to be 2-3 orders of magnitude more efficient when cells can physically interact with each other. The underlying mechanism is largely unknown, but transfer is believed to occur through large-surface interfaces, called virological or infectious synapses. Here, we report the direct visualization of cell-to-cell transmission of retroviruses in living cells. Our results reveal a mechanism of virus transport from infected to non-infected cells, involving thin filopodial bridges. These filopodia originate from non-infected cells and interact, through their tips, with infected cells. A strong association of the viral envelope glycoprotein (Env) in an infected cell with the receptor molecules in a target cell generates a stable bridge. Viruses then move along the outer surface of the filopodial bridge toward the target cell. Our data suggest that retroviruses spread by exploiting an inherent ability of filopodia to transport ligands from cell to cell.

Published

2007

4. Virus Cell-to-Cell Transmission.

Author

Mothes, Walther, Sherer, Nathan M., Jing Jin, and Peng Zhong

Subjects

*VIRUS diseases, *INFECTION, *MICROORGANISMS, *CELL communication, *COMMUNICABLE diseases

Abstract

Viral infections spread based on the ability of viruses to overcome multiple barriers and move from cell to cell, tissue to tissue, and person to person and even across species. While there are fundamental differences between these types of transmissions, it has emerged that the ability of viruses to utilize and manipulate cell-cell contact contributes to the success of viral infections. Central to the excitement in the field of virus cell-to-cell transmission is the idea that cell-to-cell spread is more than the sum of the processes of virus release and entry. This implies that virus release and entry are efficiently coordinated to sites of cell-cell contact, resulting in a process that is distinct from its individual components. In this review, we will present support for this model, illustrate the ability of viruses to utilize and manipulate cell adhesion molecules, and discuss the mechanism and driving forces of directional spreading. An understanding of viral cell-to-cell spreading will enhance our ability to intervene in the efficient spreading of viral infections. [ABSTRACT FROM AUTHOR]

Published

2010

5. Directional Spread of Surface-Associated Retroviruses Regulated by Differential Virus-Cell Interactions.

Author

Sherer, Nathan M., Jing Jin, and Mothes, Walther

Subjects

*VIRUS disease transmission, *RETROVIRUSES, *CELL communication, *DISEASE progression, *CELL receptors, *CELL membranes, *HTLV, *VIRUSES

Abstract

The spread of viral infections involves the directional progression of virus particles from infected cells to uninfected target cells. Prior to entry, the binding of virus particles to specific cell surface receptors can trigger virus surfing, an actin-dependent lateral transport of viruses toward the cell body (M. J. Lehmann et al., J. Cell Biol. 170:317-325, 2005; M. Schelhaas, et al., PLoS Pathog. 4:e1000148, 2008; J. L. Smith, D. S. Lidke, and M. A. Ozbun, Virology 381:16-21, 2008). Here, we have used live-cell imaging to demonstrate that for cells chronically infected with the gammaretrovirus murine leukemia virus in which receptor has been downregulated, a significant portion of completely assembled virus particles are not immediately released into the supernatant but retain long-term association with the cell surface. Retention can be attributed, at least in part, to nonspecific particle attachment to cell surface glycosylaminoglycans. In contrast to virus surfing, viruses retained at the surface of infected cells undergo a lateral motility that is random and actin independent. This diffusive motility can be abruptly halted and converted into inward surfing after treatment with Polybrene, a soluble cation that increases virus-cell adsorption. In the absence of Polybrene, particle diffusion allows for an outward flow of viruses to the infected cell periphery. Peripheral particles are readily captured by and transmitted to neighboring uninfected target cells in a directional fashion. These data demonstrate a surface-based mechanism for the directional spread of viruses regulated by differential virus-cell interactions. [ABSTRACT FROM AUTHOR]

Published

2010

6. Assembly of the Murine Leukemia Virus Is Directed towards Sites of Cell-Cell Contact.

Author

Jin, Jing, Sherer, Nathan M., Heidecker, Gisela, Derse, David, and Mothes, Walther

Subjects

*MOUSE leukemia viruses, *CELL communication, *RETROVIRUSES, *CELL adhesion, *RNA viruses

Abstract

We have investigated the underlying mechanism by which direct cell-cell contact enhances the efficiency of cell-to-cell transmission of retroviruses. Applying 4D imaging to a model retrovirus, the murine leukemia virus, we directly monitor and quantify sequential assembly, release, and transmission events for individual viral particles as they happen in living cells. We demonstrate that de novo assembly is highly polarized towards zones of cell-cell contact. Viruses assembled approximately 10-fold more frequently at zones of cell contact with no change in assembly kinetics. Gag proteins were drawn to adhesive zones formed by viral Env glycoprotein and its cognate receptor to promote virus assembly at cell-cell contact. This process was dependent on the cytoplasmic tail of viral Env. Env lacking the cytoplasmic tail while still allowing for contact formation, failed to direct virus assembly towards contact sites. Our data describe a novel role for the viral Env glycoprotein in establishing cell-cell adhesion and polarization of assembly prior to becoming a fusion protein to allow virus entry into cells. [ABSTRACT FROM AUTHOR]

Published

2009

7. Murine Leukemia Virus Gag Localizes to the Uropod of Migrating Primary Lymphocytes.

Author

Fei Li, Sewald, Xaver, Jing Jin, Sherer, Nathan M., and Mothes, Walther

Subjects

*MOUSE leukemia viruses, *T cells, *CELL migration, *CELL morphology, *CELL membranes, *CELL communication

Abstract

B and CD4+ T lymphocytes are natural targets of murine leukemia virus (MLV). Migrating lymphocytes adopt a polarized morphology with a trailing edge designated the uropod. Here, we demonstrate that MLV Gag localizes to the uropod in polarized B cells and CD4+ T cells. The uropod localization of MLV Gag was dependent on plasma membrane (PM) association and multimerization of Gag but independent of the viral glycoprotein Env. Basic residues in MA that are required for MLV Gag recruitment to virological synapses between HEK293 and XC cells were dispensable for uropod localization in migrating B cells. Ultrastructural studies indicated that both wild-type and basic-residue mutant Gag localized to the outer surface of the PM at the uropod. Late-domain mutant virus particles were seen at the uropod in form of budding-arrested intermediates. Finally, uropods mediated contact between MLV-infected B cells and uninfected T cells to form virological synapses. Our results suggest that MLV, not unlike HIV, accumulates at the uropod of primary lymphocytes to facilitate viral spreading through the formation of uropodmediated cell-cell contacts. [ABSTRACT FROM AUTHOR]

Published

2014