Your search keyword '"Ghose, Aurnab"' showing total 5 results

1. The role of mechanics in axonal stability and development.

Author

Ghose A and Pullarkat P

Subjects

Microtubules metabolism, Neurons, Stress, Mechanical, Axons metabolism, Cytoskeleton metabolism

Abstract

Much of the focus of neuronal cell biology has been devoted to growth cone guidance, synaptogenesis, synaptic activity, plasticity, etc. The axonal shaft too has received much attention, mainly for its astounding ability to transmit action potentials and the transport of material over long distances. For these functions, the axonal cytoskeleton and membrane have been often assumed to play static structural roles. Recent experiments have changed this view by revealing an ultrastructure much richer in features than previously perceived and one that seems to be maintained at a dynamic steady state. The role of mechanics in this is only beginning to be broadly appreciated and appears to involve passive and active modes of coupling different biopolymer filaments, filament turnover dynamics and membrane biophysics. Axons, being unique cellular processes in terms of high aspect ratios and often extreme lengths, also exhibit unique passive mechanical properties that might have evolved to stabilize them under mechanical stress. In this review, we summarize the experiments that have exposed some of these features. It is our view that axonal mechanics deserves much more attention not only due to its significance in the development and maintenance of the nervous system but also due to the susceptibility of axons to injury and neurodegeneration., Competing Interests: Conflict of interest Authors declare no conflict of interest., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2023

2. The axonal actin-spectrin lattice acts as a tension buffering shock absorber.

Author

Dubey S, Bhembre N, Bodas S, Veer S, Ghose A, Callan-Jones A, and Pullarkat P

Subjects

Animals, Biomechanical Phenomena, Cells, Cultured, Chickens, Microtubules physiology, Protein Folding, Spectrin chemistry, Stress, Mechanical, Actins physiology, Axons physiology, Spectrin physiology

Abstract

Axons span extreme distances and are subject to significant stretch deformations during limb movements or sudden head movements, especially during impacts. Yet, axon biomechanics, and its relation to the ultrastructure that allows axons to withstand mechanical stress, is poorly understood. Using a custom developed force apparatus, we demonstrate that chick dorsal root ganglion axons exhibit a tension buffering or strain-softening response, where its steady state elastic modulus decreases with increasing strain. We then explore the contributions from the various cytoskeletal components of the axon to show that the recently discovered membrane-associated actin-spectrin scaffold plays a prominent mechanical role. Finally, using a theoretical model, we argue that the actin-spectrin skeleton acts as an axonal tension buffer by reversibly unfolding repeat domains of the spectrin tetramers to release excess mechanical stress. Our results revise the current viewpoint that microtubules and their associated proteins are the only significant load-bearing elements in axons., Competing Interests: SD, NB, SB, SV, AG, AC, PP No competing interests declared, (© 2020, Dubey et al.)

Published

2020

3. Cytoskeletal Mechanisms of Axonal Contractility.

Author

Mutalik SP, Joseph J, Pullarkat PA, and Ghose A

Subjects

Actomyosin metabolism, Animals, Cell Adhesion, Chickens, Microtubules metabolism, Trypsin metabolism, Axons metabolism, Cytoskeleton metabolism, Mechanotransduction, Cellular

Abstract

Mechanotransduction is likely to be an important mechanism of signaling in thin, elongated cells such as neurons. Maintenance of prestress or rest tension may facilitate mechanotransduction in these cells. In recent years, functional roles for mechanical tension in neuronal development and physiology are beginning to emerge, but the cellular mechanisms regulating neurite tension remain poorly understood. Active contraction of neurites is a potential mechanism of tension regulation. In this study, we have explored cytoskeletal mechanisms mediating active contractility of neuronal axons. We have developed a simple assay in which we evaluate contraction of curved axons upon trypsin-mediated detachment. We show that curved axons undergo contraction and straighten upon deadhesion. Axonal straightening was found to be actively driven by actomyosin contractility, whereas microtubules may subserve a secondary role. We find that although axons show a monotonous decrease in length upon contraction, subcellularly, the cytoskeleton shows a heterogeneous contractile response. Further, using an assay for spontaneous development of tension without trypsin-induced deadhesion, we show that axons are intrinsically contractile. These experiments, using novel experimental approaches, implicate the axonal cytoskeleton in tension homeostasis. Our data suggest that although globally, the axon behaves as a mechanical continuum, locally, the cytoskeleton is remodeled heterogeneously., (Copyright © 2018 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2018

4. Axonal heparan sulfate proteoglycans regulate the distribution and efficiency of the repellent slit during midline axon guidance.

Author

Johnson KG, Ghose A, Epstein E, Lincecum J, O'Connor MB, and Van Vactor D

Subjects

Animals, Axons metabolism, Drosophila, Drosophila Proteins metabolism, Heparitin Sulfate metabolism, Immunohistochemistry, Membrane Glycoproteins genetics, Models, Neurological, Mutation genetics, Precipitin Tests, Proteoglycans genetics, Syndecans, Axons physiology, Central Nervous System embryology, Membrane Glycoproteins metabolism, Nerve Tissue Proteins metabolism, Proteoglycans metabolism, Signal Transduction

Abstract

The presentation of secreted axon guidance factors plays a major role in shaping central nervous system (CNS) connectivity. Recent work suggests that heparan sulfate (HS) regulates guidance factor activity; however, the in vivo axon guidance roles of its carrier proteins (heparan sulfate proteoglycans, or HSPGs) are largely unknown. Here we demonstrate through genetic analysis in vivo that the HSPG Syndecan (Sdc) is critical for the fidelity of Slit repellent signaling at the midline of the Drosophila CNS, consistent with the localization of Sdc to CNS axons. sdc mutants exhibit consistent defects in midline axon guidance, plus potent and specific genetic interactions supporting a model in which HSPGs improve the efficiency of Slit localization and/or signaling. To test this hypothesis, we show that Slit distribution is altered in sdc mutants and that Slit and its receptor bind to Sdc. However, when we compare the function of the transmembrane Sdc to a different class of HSPG that localizes to CNS axons (Dallylike), we find functional redundancy, suggesting that these proteoglycans act as spatially specific carriers of common HS structures that enable growth cones to interact with and perceive Slit as it diffuses away from its source at the CNS midline.

Published

2004

5. Complex interactions amongst N-cadherin, DLAR, and Liprin-α regulate Drosophila photoreceptor axon targeting

Author

Prakash, Saurabh, McLendon, Helen M., Dubreuil, Catherine I., Ghose, Aurnab, Hwa, Jennifer, Dennehy, Kelly A., Tomalty, Katharine M.H., Clark, Kelsey L., Van Vactor, David, and Clandinin, Thomas R.

Subjects

*CELL communication, *CADHERINS, *PHOTORECEPTORS, *DROSOPHILA, *AXONS, *CELL adhesion, *SYNAPSES

Abstract

Abstract: The formation of stable adhesive contacts between pre- and post-synaptic neurons represents the initial step in synapse assembly. The cell adhesion molecule N-cadherin, the receptor tyrosine phosphatase DLAR, and the scaffolding molecule Liprin-α play critical, evolutionarily conserved roles in this process. However, how these proteins signal to the growth cone and are themselves regulated remains poorly understood. Using Drosophila photoreceptors (R cells) as a model, we evaluate genetic and physical interactions among these three proteins. We demonstrate that DLAR function in this context is independent of phosphatase activity but requires interactions mediated by its intracellular domain. Genetic studies reveal both positive and, surprisingly, inhibitory interactions amongst all three genes. These observations are corroborated by biochemical studies demonstrating that DLAR physically associates via its phosphatase domain with N-cadherin in Drosophila embryos. Together, these data demonstrate that N-cadherin, DLAR, and Liprin-α function in a complex to regulate adhesive interactions between pre- and post-synaptic cells and provide a novel mechanism for controlling the activity of Liprin-α in the developing growth cone. [Copyright &y& Elsevier]

Published

2009