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22 results on '"Mahapatra, Arijit"'

1. Interplay between cortical adhesion and membrane bending regulates microparticle formation

Author

Mahapatra, Arijit, Malingen, Sage A., and Rangamani, Padmini

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

The formation of microparticles requires the bending of the plasma membrane away from the cytosol. The capcity of the cell membrane to form a microparticle, and the rate of membrane deformation, are controlled by multiple factors, including loss of lipid asymmetry (primarily the exposure of phosphatidylserine on the outer leaflet), detachment of the membrane from the cortical cytoskeleton, and bleb expansion due to pressure. In this work, we develop a biophysical model that accounts for the interaction between these different factors. Our findings reveal that the linkage between the membrane and cortex is a key determinant of outward budding. Ultimately, the rates and mechanical parameters regulating cortical linkage interact with the kinetics of phosphatidylserine flipping, laying out a mechanical phase space for regulating the outward budding of the plasma membrane., Comment: 22 pages, 11 figures

Published
2024

2. Cristae formation is a mechanical buckling event controlled by the inner mitochondrial membrane lipidome

Author

Venkatraman, Kailash, Lee, Christopher T, Garcia, Guadalupe C, Mahapatra, Arijit, Milshteyn, Daniel, Perkins, Guy, Kim, Keun‐Young, Pasolli, H Amalia, Phan, Sebastien, Lippincott‐Schwartz, Jennifer, Ellisman, Mark H, Rangamani, Padmini, and Budin, Itay

Subjects
Biochemistry and Cell Biology, Biological Sciences, Bioengineering, cardiolipin, cristae, lipids, mechanics, mitochondria, Information and Computing Sciences, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences
Abstract

Cristae are high-curvature structures in the inner mitochondrial membrane (IMM) that are crucial for ATP production. While cristae-shaping proteins have been defined, analogous lipid-based mechanisms have yet to be elucidated. Here, we combine experimental lipidome dissection with multi-scale modeling to investigate how lipid interactions dictate IMM morphology and ATP generation. When modulating phospholipid (PL) saturation in engineered yeast strains, we observed a surprisingly abrupt breakpoint in IMM topology driven by a continuous loss of ATP synthase organization at cristae ridges. We found that cardiolipin (CL) specifically buffers the inner mitochondrial membrane against curvature loss, an effect that is independent of ATP synthase dimerization. To explain this interaction, we developed a continuum model for cristae tubule formation that integrates both lipid and protein-mediated curvatures. This model highlighted a snapthrough instability, which drives IMM collapse upon small changes in membrane properties. We also showed that cardiolipin is essential in low-oxygen conditions that promote PL saturation. These results demonstrate that the mechanical function of cardiolipin is dependent on the surrounding lipid and protein components of the IMM.

Published
2023

3. Formation of protein-mediated tubes is governed by a snapthrough transition

Author

Mahapatra, Arijit and Rangamani, Padmini

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Plasma membrane tubes are ubiquitous in cellular membranes and in the membranes of intracellular organelles. They play crucial roles in trafficking, ion transport, and cellular motility. The formation of plasma membrane tubes can be due to localized forces acting on the membrane or by curvature-induced by membrane-bound proteins. Here, we present a mathematical framework to model cylindrical tubular protrusions formed by proteins that induce anisotropic spontaneous curvature. Our analysis revealed that the tube radius depends on an effective tension that includes contributions from the bare membrane tension and the protein-induced curvature. We also found that the length of the tube undergoes an abrupt transition from a short, dome-shaped membrane to a long cylinder and this transition is characteristic of a snapthrough instability. Finally, we show that the snapthrough instability depends on the different parameters including coat area, bending modulus, and extent of protein-induced curvature. Our findings have implications for tube formation due to BAR-domain proteins in processes such as endocytosis, t-tubule formation in myocytes, and cristae formation in mitochondria., Comment: 20 pages, 10 figures

Published
2022

4. Curvature-driven feedback on aggregation-diffusion of proteins in lipid bilayers

Author

Mahapatra, Arijit, Saintillan, David, and Rangamani, Padmini

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Membrane bending is an extensively studied problem from both modeling and experimental perspectives because of the wide implications of curvature generation in cell biology. Many of the curvature generating aspects in membranes can be attributed to interactions between proteins and membranes. These interactions include protein diffusion and formation of aggregates due to protein-protein interactions in the plane of the membrane. Recently, we developed a model that couples the in-plane flow of lipids and diffusion of proteins with the out-of-plane bending of the membrane. Building on this work, here, we focus on the role of explicit aggregation of proteins on the surface of the membrane in the presence of membrane bending and diffusion. We develop a comprehensive framework that includes lipid flow, membrane bending, the entropy of protein distribution, along with an explicit aggregation potential and derive the governing equations for the coupled system. We compare this framework to the Cahn-Hillard formalism to predict the regimes in which the proteins form patterns on the membrane. We demonstrate the utility of this model using numerical simulations to predict how aggregation and diffusion, when coupled with curvature generation, can alter the landscape of membrane-protein interactions., Comment: 20 pages, 9 figures

Published
2021

5. The mechanics and thermodynamics of tubule formation in biological membranes

Author

Mahapatra, Arijit, Uysalel, Can, and Rangamani, Padmini

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics, Quantitative Biology - Subcellular Processes
Abstract

Membrane tubulation is a ubiquitous process that occurs both at the plasma membrane and on the membranes of intracellular organelles. These tubulation events are known to be mediated by forces applied on the membrane either due to motor proteins, by polymerization of the cytoskeleton, or due to the interactions between membrane proteins binding onto the membrane. The numerous experimental observations of tube formation have been amply supported by mathematical modeling of the associated membrane mechanics and have provided insights into the force-displacement relationships of membrane tubes. Recent advances in quantitative biophysical measurements of membrane-protein interactions and tubule formation have necessitated the need for advances in modeling that will account for the interplay of multiple aspects of physics that occur simultaneously. Here, we present a comprehensive review of experimental observations of tubule formation and provide context from the framework of continuum modeling. Finally, we explore the scope for future research in this area with an emphasis on iterative modeling and experimental measurements that will enable us to expand our mechanistic understanding of tubulation processes in cells., Comment: Arijit Mahapatra and Can Uysalel contributed equally, Padmini Rangamani is the corresponding author, 21 pages, 4 figures

Published
2020

6. Transport Phenomena in Fluid Films with Curvature Elasticity

Author

Mahapatra, Arijit, Saintillan, David, and Rangamani, Padmini

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics, Physics - Fluid Dynamics
Abstract

Cellular membranes are elastic lipid bilayers that contain a variety of proteins, including ion channels, receptors, and scaffolding proteins. These proteins are known to diffuse in the plane of the membrane and to influence the bending of the membrane. Experiments have shown that lipid flow in the plane of the membrane is closely coupled with the diffusion of proteins. Thus, there is a need for a comprehensive framework that accounts for the interplay between these processes. Here, we present a theory for the coupled in-plane viscous flow of lipids, diffusion of transmembrane proteins, and elastic deformation of lipid bilayers. The proteins in the membrane are modeled such that they influence membrane bending by inducing a spontaneous curvature. We formulate the free energy of the membrane with a Helfrich-like curvature elastic energy density function modified to account for the chemical potential energy of proteins. We derive the conservation laws and equations of motion for this system. Finally, we present results from dimensional analysis and numerical simulations and demonstrate the effect of coupled transport processes in governing the dynamics of membrane bending and protein diffusion., Comment: Added new Figures (11-16) and appendix

Published
2020
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7. The Mechanics and Thermodynamics of Tubule Formation in Biological Membranes

Author

Mahapatra, Arijit, Uysalel, Can, and Rangamani, Padmini

Subjects
Bioengineering, Cell Membrane, Cytoskeleton, Membrane Proteins, Microtubules, Thermodynamics, Membrane tubule formation, Membrane-protein interactions, Membrane mechanics, cond-mat.soft, physics.bio-ph, q-bio.SC, Biochemistry and Cell Biology, Microbiology, Medical Microbiology, Physiology
Abstract

Membrane tubulation is a ubiquitous process that occurs both at the plasma membrane and on the membranes of intracellular organelles. These tubulation events are known to be mediated by forces applied on the membrane either due to motor proteins, by polymerization of the cytoskeleton, or due to the interactions between membrane proteins binding onto the membrane. The numerous experimental observations of tube formation have been amply supported by mathematical modeling of the associated membrane mechanics and have provided insights into the force-displacement relationships of membrane tubes. Recent advances in quantitative biophysical measurements of membrane-protein interactions and tubule formation have necessitated the need for advances in modeling that will account for the interplay of multiple aspects of physics that occur simultaneously. Here, we present a comprehensive review of experimental observations of tubule formation and provide context from the framework of continuum modeling. Finally, we explore the scope for future research in this area with an emphasis on iterative modeling and experimental measurements that will enable us to expand our mechanistic understanding of tubulation processes in cells.

Published
2021

8. Transport Phenomena in Lipid Bilayers

Author

Mahapatra, Arijit

Subjects
Fluid mechanics, Aggregation, Membrane-protein interaction, Plasma membrane, Transport phenomena
Abstract

Lipid bilayers are formed from the self-assembly of two layers of amphiphilic lipid molecules. They are excellent model systems for studying the behavior of cellular membranes. The mechanics of lipid bilayers fascinates physicists and engineers because of their in-plane flow and out-of-plane bending. In cellular membranes, lipid bilayers contain a heterogeneous composition of integral and peripheral proteins that perform specific biophysical processes. These proteins are known to generate curvature on the membrane, and they also sense the curvature. Additionally, proteins undergo diffusion and aggregation in the membrane. Experiments have shown that the in-plane viscous flow of lipid influences the dynamics of protein distribution through advection. Therefore, the ability of the protein to deform the membrane, combined with the ability of the membrane curvature and flow to influence protein distribution, leads to a closed coupled problem. In the first part of the thesis, I present a comprehensive theory of the coupled problem of elastic bending of lipid bilayers, diffusion and aggregation of proteins, and in-plane viscous flow of lipids. The curvature generation of the proteins on the membranes is modeled with the help of a spontaneous curvature that emulates the asymmetry in the lipid leaflets. We formulate a Helfrich-like free energy of the membrane, which is modified to include the entropic contribution that leads to diffusion of the protein and the aggregation potential that mimics the forces of protein-protein interaction. The free energy is minimized to get the conservation equation of proteins and the equation of motion for the membrane shape. The mass conservation relation is further extended to account for the binding of proteins from the bulk volume. We perform a stability analysis to find the necessary condition to form an aggregate and compare our system with the Cahn-Hilliard-like formalism. We demonstrate the utility of the model by presenting numerical simulations in the limit of small deformation of the membrane and large deformation axisymmetric geometry. We rigorously investigate the effect of bending and curvature-induced feedback in protein distribution and related energy landscape. In the second part of the thesis, we model the formation and the shape transition in the membrane tubes generated by aggregated domains BAR-proteins that induce anisotropic curvatures. BAR-proteins are 1-dimensional rod-like proteins that bend the membrane because of their intrinsic shape and binding orientation. We first formulate a continuum bending energy due to anisotropic spontaneous curvatures. Then we include the effect of orientation by the values of spontaneous curvatures. The resultant shape equations that minimize the free energy are solved numerically in an axisymmetric geometry. We observe that the membrane undergoes a snap-through transition of its shape from a tent to a tube, and the transition is observed for all parameters. We further analyze the nature of the transition and report a hysteresis-like behavior that is commonly observed across snap-through transitions in elastic structures.

Published
2022

9. Cristae formation is a mechanical buckling event controlled by the inner mitochondrial membrane lipidome

Author

Venkatraman, Kailash, primary, Lee, Christopher T, additional, Garcia, Guadalupe C, additional, Mahapatra, Arijit, additional, Milshteyn, Daniel, additional, Perkins, Guy, additional, Kim, Keun‐Young, additional, Pasolli, H Amalia, additional, Phan, Sebastien, additional, Lippincott‐Schwartz, Jennifer, additional, Ellisman, Mark H, additional, Rangamani, Padmini, additional, and Budin, Itay, additional

Published
2023
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11. Cristae formation is a mechanical buckling event controlled by the inner membrane lipidome

Author

Venkatraman, Kailash, primary, Lee, Christopher T, additional, Garcia, Guadalupe C., additional, Mahapatra, Arijit, additional, Perkins, Guy, additional, Kim, Keun-Young, additional, Pasolli, Hilda Amalia, additional, Phan, Sebastien, additional, Lippincott-Schwartz, Jennifer, additional, Ellisman, Mark, additional, Rangamani, Padmini, additional, and Budin, Itay, additional

Published
2023
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21. Cristae formation is a mechanical buckling event controlled by the inner membrane lipidome.

Author

Venkatraman K, Lee CT, Garcia GC, Mahapatra A, Milshteyn D, Perkins G, Kim KY, Pasolli HA, Phan S, Lippincott-Schwartz J, Ellisman MH, Rangamani P, and Budin I

Abstract

Cristae are high curvature structures in the inner mitochondrial membrane (IMM) that are crucial for ATP production. While cristae-shaping proteins have been defined, analogous mechanisms for lipids have yet to be elucidated. Here we combine experimental lipidome dissection with multi-scale modeling to investigate how lipid interactions dictate IMM morphology and ATP generation. When modulating phospholipid (PL) saturation in engineered yeast strains, we observed a surprisingly abrupt breakpoint in IMM topology driven by a continuous loss of ATP synthase organization at cristae ridges. We found that cardiolipin (CL) specifically buffers the IMM against curvature loss, an effect that is independent of ATP synthase dimerization. To explain this interaction, we developed a continuum model for cristae tubule formation that integrates both lipid and protein-mediated curvatures. The model highlighted a snapthrough instability, which drives IMM collapse upon small changes in membrane properties. We also showed that CL is essential in low oxygen conditions that promote PL saturation. These results demonstrate that the mechanical function of CL is dependent on the surrounding lipid and protein components of the IMM., Competing Interests: Disclosure and Competing Interests Statement The authors declare that they have no conflict of interest.

Published
2023
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22. Curvature-driven feedback on aggregation-diffusion of proteins in lipid bilayers.

Author

Mahapatra A, Saintillan D, and Rangamani P

Subjects
Cell Membrane, Diffusion, Feedback, Lipid Bilayers, Proteins
Abstract

Membrane bending is an extensively studied problem from both modeling and experimental perspectives because of the wide implications of curvature generation in cell biology. Many of the curvature generating aspects in membranes can be attributed to interactions between proteins and membranes. These interactions include protein diffusion and formation of aggregates due to protein-protein interactions in the plane of the membrane. Recently, we developed a model that couples the in-plane flow of lipids and diffusion of proteins with the out-of-plane bending of the membrane. Building on this work, here, we focus on the role of explicit aggregation of proteins on the surface of the membrane in the presence of membrane bending and diffusion. We develop a comprehensive framework that includes lipid flow, membrane bending, the entropy of protein distribution, along with an explicit aggregation potential and derive the governing equations for the coupled system. We compare this framework to the Cahn-Hillard formalism to predict the regimes in which the proteins form patterns on the membrane. We demonstrate the utility of this model using numerical simulations to predict how aggregation and diffusion, when coupled with curvature generation, can alter the landscape of membrane-protein interactions.

Published
2021
Full Text
View/download PDF

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