Your search keyword '"Shnyrova AV"' showing total 23 results

1. Fission of double-membrane tubes under tension.

Author

Spencer RKW, Santos-Pérez I, Shnyrova AV, and Müller M

Subjects

Cell Membrane metabolism, Cell Membrane chemistry, Stress, Mechanical, Nanotubes chemistry

Abstract

The division of a cellular compartment culminates with the scission of a highly constricted membrane neck. Scission requires lipid rearrangements, topology changes, and transient formation of nonbilayer intermediate structures driven by curvature stress. Often, a side effect of this stress is pore-formation, which may lead to content leakage and thus breaching of the membrane barrier function. In single-membrane systems, leakage is avoided through the formation of a hemifusion (HF) intermediate, whose structure is still a subject of debate. The consequences of curvature stress have not been explored in double-membrane systems, such as the mitochondrion. Here, we combine experimental and theoretical approaches to study neck constriction and scission driven by tension in biomimetic lipid systems, namely single- and double-membrane nanotubes (sNTs and dNTs), respectively. In sNTs, constriction by high tension gives rise to a metastable HF intermediate (seen as stalk or worm-like micelle), whereas poration is universally slower in a simple neck. In dNTs, high membrane tension causes sequential rupture of each membrane. In contrast, low tension leads to the HF of both membranes, which may lead to a leaky fusion pathway, or may progress to further fusion of the two membranes along a number of transformation pathways. These findings provide a new mechanistic basis for fundamental cellular processes., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

2. Membrane fission via transmembrane contact.

Author

Spencer RKW, Santos-Pérez I, Rodríguez-Renovales I, Martinez Galvez JM, Shnyrova AV, and Müller M

Subjects

Cryoelectron Microscopy, Proteome metabolism, Mitochondrial Membranes metabolism, Endoplasmic Reticulum metabolism

Abstract

Division of intracellular organelles often correlates with additional membrane wrapping, e.g., by the endoplasmic reticulum or the outer mitochondrial membrane. Such wrapping plays a vital role in proteome and lipidome organization. However, how an extra membrane impacts the mechanics of the division has not been investigated. Here we combine fluorescence and cryo-electron microscopy experiments with self-consistent field theory to explore the stress-induced instabilities imposed by membrane wrapping in a simple double-membrane tubular system. We find that, at physiologically relevant conditions, the outer membrane facilitates an alternative pathway for the inner-tube fission through the formation of a transient contact (hemi-fusion) between both membranes. A detailed molecular theory of the fission pathways in the double membrane system reveals the topological complexity of the process, resulting both in leaky and leakless intermediates, with energies and topologies predicting physiological events., (© 2024. The Author(s).)

Published

2024

3. Allosteric control of dynamin-related protein 1 through a disordered C-terminal Short Linear Motif.

Author

Pérez-Jover I, Rochon K, Hu D, Mahajan M, Madan Mohan P, Santos-Pérez I, Ormaetxea Gisasola J, Martinez Galvez JM, Agirre J, Qi X, Mears JA, Shnyrova AV, and Ramachandran R

Subjects

Mitochondria metabolism, Hydrolysis, Membrane Fusion, Mitochondrial Dynamics, Mitochondrial Proteins metabolism, Dynamins metabolism, GTP Phosphohydrolases metabolism

Abstract

The mechanochemical GTPase dynamin-related protein 1 (Drp1) catalyzes mitochondrial and peroxisomal fission, but the regulatory mechanisms remain ambiguous. Here we find that a conserved, intrinsically disordered, six-residue Short Linear Motif at the extreme Drp1 C-terminus, named CT-SLiM, constitutes a critical allosteric site that controls Drp1 structure and function in vitro and in vivo. Extension of the CT-SLiM by non-native residues, or its interaction with the protein partner GIPC-1, constrains Drp1 subunit conformational dynamics, alters self-assembly properties, and limits cooperative GTP hydrolysis, surprisingly leading to the fission of model membranes in vitro. In vivo, the involvement of the native CT-SLiM is critical for productive mitochondrial and peroxisomal fission, as both deletion and non-native extension of the CT-SLiM severely impair their progression. Thus, contrary to prevailing models, Drp1-catalyzed membrane fission relies on allosteric communication mediated by the CT-SLiM, deceleration of GTPase activity, and coupled changes in subunit architecture and assembly-disassembly dynamics., (© 2024. The Author(s).)

Published

2024

4. Allosteric control of dynamin-related protein 1-catalyzed mitochondrial fission through a conserved disordered C-terminal Short Linear Motif.

Author

Pérez-Jover I, Rochon K, Hu D, Mohan PM, Santos-Perez I, Gisasola JO, Galvez JMM, Agirre J, Qi X, Mears JA, Shnyrova AV, and Ramachandran R

Abstract

The mechanochemical GTPase dynamin-related protein 1 (Drp1) catalyzes mitochondrial fission, but the regulatory mechanisms remain ambiguous. Here we found that a conserved, intrinsically disordered, six-residue S hort Li near M otif at the extreme Drp1 C-terminus, named CT-SLiM, constitutes a critical allosteric site that controls Drp1 structure and function in vitro and in vivo . Extension of the CT-SLiM by non-native residues, or its interaction with the protein partner GIPC-1, constrains Drp1 subunit conformational dynamics, alters self-assembly properties, and limits cooperative GTP hydrolysis, leading to the fission of model membranes in vitro . In vivo , the availability of the native CT-SLiM is a requirement for productive mitochondrial fission, as both non-native extension and deletion of the CT-SLiM severely impair its progression. Thus, contrary to prevailing models, Drp1-catalyzed mitochondrial fission relies on allosteric communication mediated by the CT-SLiM, deceleration of GTPase activity, and coupled changes in subunit architecture and assembly-disassembly dynamics., Competing Interests: Additional Declarations: Competing interests: The authors declare no competing interests.

Published

2023

5. Reply to Roy and Pucadyil: A gain of function by a GTPase-impaired Drp1.

Author

Pérez-Jover I, Madan Mohan P, Ramachandran R, and Shnyrova AV

Subjects

Mitochondrial Proteins genetics, Dynamins genetics, GTP Phosphohydrolases genetics, Gain of Function Mutation, Mitochondrial Dynamics genetics

Published

2022

6. Nonlinear material and ionic transport through membrane nanotubes.

Author

Ivchenkov DV, Kuzmin PI, Galimzyanov TR, Shnyrova AV, Bashkirov PV, and Frolov VA

Subjects

Cell Membrane metabolism, Ion Transport, Microscopy, Fluorescence, Nonlinear Dynamics, Surface Tension, Nanotubes

Abstract

Membrane nanotubes (NTs) and their networks play an important role in intracellular membrane transport and intercellular communications. The transport characteristics of the NT lumen resemble those of conventional solid-state nanopores. However, unlike the rigid pores, the soft membrane wall of the NT can be deformed by forces driving the transport through the NT lumen. This intrinsic coupling between the NT geometry and transport properties remains poorly explored. Using synchronized fluorescence microscopy and conductance measurements, we revealed that the NT shape was changed by both electric and hydrostatic forces driving the ionic and solute fluxes through the NT lumen. Far from the shape instability, the strength of the force effect is determined by the lateral membrane tension and is scaled with membrane elasticity so that the NT can be operated as a linear elastic sensor. Near shape instabilities, the transport forces triggered large-scale shape transformations, both stochastic and periodic. The periodic oscillations were coupled to a vesicle passage along the NT axis, resembling peristaltic transport. The oscillations were parametrically controlled by the electric field, making NT a highly nonlinear nanofluidic circuitry element with biological and technological implications., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

7. NMR identification of a conserved Drp1 cardiolipin-binding motif essential for stress-induced mitochondrial fission.

Author

Mahajan M, Bharambe N, Shang Y, Lu B, Mandal A, Madan Mohan P, Wang R, Boatz JC, Manuel Martinez Galvez J, Shnyrova AV, Qi X, Buck M, van der Wel PCA, and Ramachandran R

Subjects

Amino Acid Motifs, Binding Sites, Dynamins genetics, Humans, Intrinsically Disordered Proteins chemistry, Intrinsically Disordered Proteins genetics, Intrinsically Disordered Proteins metabolism, Magnetic Resonance Spectroscopy, Mitochondria metabolism, Mitochondrial Membranes metabolism, Mitochondrial Membranes pathology, Mitophagy, Mutation, Protein Binding, Protein Conformation, Cardiolipins metabolism, Dynamins chemistry, Dynamins metabolism, Mitochondrial Dynamics physiology

Abstract

Mitochondria form tubular networks that undergo coordinated cycles of fission and fusion. Emerging evidence suggests that a direct yet unresolved interaction of the mechanoenzymatic GTPase dynamin-related protein 1 (Drp1) with mitochondrial outer membrane-localized cardiolipin (CL), externalized under stress conditions including mitophagy, catalyzes essential mitochondrial hyperfragmentation. Here, using a comprehensive set of structural, biophysical, and cell biological tools, we have uncovered a CL-binding motif (CBM) conserved between the Drp1 variable domain (VD) and the unrelated ADP/ATP carrier (AAC/ANT) that intercalates into the membrane core to effect specific CL interactions. CBM mutations that weaken VD-CL interactions manifestly impair Drp1-dependent fission under stress conditions and induce "donut" mitochondria formation. Importantly, VD membrane insertion and GTP-dependent conformational rearrangements mediate only transient CL nonbilayer topological forays and high local membrane constriction, indicating that Drp1-CL interactions alone are insufficient for fission. Our studies establish the structural and mechanistic bases of Drp1-CL interactions in stress-induced mitochondrial fission., Competing Interests: The authors declare no competing interest.

Published

2021

8. Microfluidic chip with pillar arrays for controlled production and observation of lipid membrane nanotubes.

Author

Martinez Galvez JM, Garcia-Hernando M, Benito-Lopez F, Basabe-Desmonts L, and Shnyrova AV

Subjects

Lipids, Oligonucleotide Array Sequence Analysis, Lab-On-A-Chip Devices, Microfluidics, Nanotubes

Abstract

Lipid membrane nanotubes (NTs) are a widespread template for in vitro studies of cellular processes happening at high membrane curvature. Traditionally NTs are manufactured one by one, using sophisticated membrane micromanipulations, while simplified methods for controlled batch production of NTs are in growing demand. Here we propose a lab-on-a-chip (LOC) approach to the simultaneous formation of multiple NTs with length and radius controlled by the chip design. The NTs form upon rolling silica microbeads covered by lipid lamellas over the pillars of a polymer micropillar array. The array's design and surface chemistry set the geometry of the resulting free-standing NTs. The integration of the array inside a microfluidic chamber further enables fast and turbulence-free addition of components, such as proteins, to multiple preformed NTs. This LOC approach to NT production is compatible with the use of high power objectives of a fluorescence microscope, making real-time quantification of the different modes of the protein activity in a single experiment possible.

Published

2020

9. Reconstitution and real-time quantification of membrane remodeling by single proteins and protein complexes.

Author

Bashkirov PV, Kuzmin PI, Chekashkina K, Arrasate P, Vera Lillo J, Shnyrova AV, and Frolov VA

Subjects

Cell Membrane chemistry, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Nanotubes chemistry, Cell Membrane metabolism, Membrane Proteins metabolism, Nanotechnology methods

Abstract

Cellular membrane processes, from signal transduction to membrane fusion and fission, depend on acute membrane deformations produced by small and short-lived protein complexes working in conditions far from equilibrium. Real-time monitoring and quantitative assessment of such deformations are challenging; hence, mechanistic analyses of the protein action are commonly based on ensemble averaging, which masks important mechanistic details of the action. In this protocol, we describe how to reconstruct and quantify membrane remodeling by individual proteins and small protein complexes in vitro, using an ultra-short (80- to 400-nm) lipid nanotube (usNT) template. We use the luminal conductance of the usNT as the real-time reporter of the protein interaction(s) with the usNT. We explain how to make and calibrate the usNT template to achieve subnanometer precision in the geometrical assessment of the molecular footprints on the nanotube membrane. We next demonstrate how membrane deformations driven by purified proteins implicated in cellular membrane remodeling can be analyzed at a single-molecule level. The preparation of one usNT takes ~1 h, and the shortest procedure yielding the basic geometrical parameters of a small protein complex takes 10 h.

Published

2020

10. Electrophysiological Methods for Detection of Membrane Leakage and Hemifission by Dynamin 1.

Author

Bashkirov PV, Chekashkina KV, Shnyrova AV, and Frolov VA

Subjects

Algorithms, Cell Membrane chemistry, Electrodes, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Models, Biological, Nanotubes chemistry, Patch-Clamp Techniques, Permeability, Cell Membrane metabolism, Dynamin I metabolism, Electrophysiological Phenomena

Abstract

Membrane fusion and fission are indispensable parts of intracellular membrane recycling and transport. Electrophysiological techniques have been instrumental in discovering and studying fusion and fission pores, the key intermediates shared by both processes. In cells, electrical admittance measurements are used to assess in real time the dynamics of the pore conductance, reflecting the nanoscale transformations of the pore, simultaneously with membrane leakage. Here, we described how this technique is adapted to in vitro mechanistic analyses of membrane fission by dynamin 1 (Dyn1), the protein orchestrating membrane fission in endocytosis. We reconstitute the fission reaction using purified Dyn1 and biomimetic lipid membrane nanotubes of defined geometry. We provide a comprehensive protocol describing simultaneous measurements of the ionic conductance through the nanotube lumen and across the nanotube wall, enabling spatiotemporal correlation between the nanotube constriction by Dyn1, leading to fission and membrane leakage. We present examples of "leaky" and "tight" fission reactions, specify the resolution limits of our method, and discuss how our results support the hemi-fission conjecture.

Published

2020

11. Dynamic constriction and fission of endoplasmic reticulum membranes by reticulon.

Author

Espadas J, Pendin D, Bocanegra R, Escalada A, Misticoni G, Trevisan T, Velasco Del Olmo A, Montagna A, Bova S, Ibarra B, Kuzmin PI, Bashkirov PV, Shnyrova AV, Frolov VA, and Daga A

Subjects

Animals, COS Cells, Cell Membrane, Chlorocebus aethiops, Drosophila, Drosophila Proteins genetics, GTP Phosphohydrolases genetics, Membrane Fusion, Nanotubes, Nuclear Envelope, Drosophila Proteins metabolism, Endoplasmic Reticulum metabolism, GTP Phosphohydrolases metabolism

Abstract

The endoplasmic reticulum (ER) is a continuous cell-wide membrane network. Network formation has been associated with proteins producing membrane curvature and fusion, such as reticulons and atlastin. Regulated network fragmentation, occurring in different physiological contexts, is less understood. Here we find that the ER has an embedded fragmentation mechanism based upon the ability of reticulon to produce fission of elongating network branches. In Drosophila, Rtnl1-facilitated fission is counterbalanced by atlastin-driven fusion, with the prevalence of Rtnl1 leading to ER fragmentation. Ectopic expression of Drosophila reticulon in COS-7 cells reveals individual fission events in dynamic ER tubules. Consistently, in vitro analyses show that reticulon produces velocity-dependent constriction of lipid nanotubes leading to stochastic fission via a hemifission mechanism. Fission occurs at elongation rates and pulling force ranges intrinsic to the ER, thus suggesting a principle whereby the dynamic balance between fusion and fission controlling organelle morphology depends on membrane motility.

Published

2019

12. Combining patch-clamping and fluorescence microscopy for quantitative reconstitution of cellular membrane processes with Giant Suspended Bilayers.

Author

Velasco-Olmo A, Ormaetxea Gisasola J, Martinez Galvez JM, Vera Lillo J, and Shnyrova AV

Subjects

Biological Transport physiology, Constriction, Microscopy, Fluorescence methods, Unilamellar Liposomes metabolism, Cell Membrane metabolism, Lipid Bilayers metabolism

Abstract

In vitro reconstitution and microscopic visualization of membrane processes is an indispensable source of information about a cellular function. Here we describe a conceptionally novel free-standing membrane template that facilitates such quantitative reconstitution of membrane remodelling at different scales. The Giant Suspended Bilayers (GSBs) spontaneously swell from lipid lamella reservoir deposited on microspheres. GSBs attached to the reservoir can be prepared from virtually any lipid composition following a fast procedure. Giant unilamellar vesicles can be further obtained by GSB detachment from the microspheres. The reservoir stabilizes GSB during deformations, mechanical micromanipulations, and fluorescence microscopy observations, while GSB-reservoir boundary enables the exchange of small solutes with GSB interior. These unique properties allow studying macro- and nano-scale membrane deformations, adding membrane-active compounds to both sides of GSB membrane and applying patch-clamp based approaches, thus making GSB a versatile tool for reconstitution and quantification of cellular membrane trafficking events.

Published

2019

13. Human ATG3 binding to lipid bilayers: role of lipid geometry, and electric charge.

Author

Hervás JH, Landajuela A, Antón Z, Shnyrova AV, Goñi FM, and Alonso A

Subjects

Adaptor Proteins, Signal Transducing chemistry, Apoptosis Regulatory Proteins, Autophagosomes chemistry, Autophagy genetics, Autophagy-Related Proteins chemistry, Biophysical Phenomena genetics, Cardiolipins chemistry, Cardiolipins genetics, Cell Membrane chemistry, Cell Membrane genetics, Humans, Lipids genetics, Microtubule-Associated Proteins chemistry, Protein Binding, Ubiquitin-Conjugating Enzymes chemistry, Adaptor Proteins, Signal Transducing genetics, Autophagy-Related Proteins genetics, Lipid Bilayers chemistry, Lipids chemistry, Microtubule-Associated Proteins genetics, Ubiquitin-Conjugating Enzymes genetics

Abstract

Specific protein-lipid interactions lead to a gradual recruitment of AuTophaGy-related (ATG) proteins to the nascent membrane during autophagosome (AP) formation. ATG3, a key protein in the movement of LC3 towards the isolation membrane, has been proposed to facilitate LC3/GABARAP lipidation in highly curved membranes. In this work we have performed a biophysical study of human ATG3 interaction with membranes containing phosphatidylethanolamine, phosphatidylcholine and anionic phospholipids. We have found that ATG3 interacts more strongly with negatively-charged phospholipid vesicles or nanotubes than with electrically neutral model membranes, cone-shaped anionic phospholipids (cardiolipin and phosphatidic acid) being particularly active in promoting binding. Moreover, an increase in membrane curvature facilitates ATG3 recruitment to membranes although addition of anionic lipid molecules makes the curvature factor relatively less important. The predicted N-terminus amphipathic α-helix of ATG3 would be responsible for membrane curvature detection, the positive residues Lys 9 and 11 being essential in the recognition of phospholipid negative moieties. We have also observed membrane aggregation induced by ATG3 in vitro, which could point to a more complex function of this protein in AP biogenesis. Moreover, in vitro GABARAP lipidation assays suggest that ATG3-membrane interaction could facilitate the lipidation of ATG8 homologues.

Published

2017

14. A hemi-fission intermediate links two mechanistically distinct stages of membrane fission.

Author

Mattila JP, Shnyrova AV, Sundborger AC, Hortelano ER, Fuhrmans M, Neumann S, Müller M, Hinshaw JE, Schmid SL, and Frolov VA

Subjects

Biocatalysis, Blood Proteins chemistry, Dynamin I chemistry, Guanosine Diphosphate metabolism, Guanosine Triphosphate metabolism, Humans, Hydrolysis, Membrane Fusion, Models, Molecular, Phosphoproteins chemistry, Protein Conformation, Cell Membrane metabolism, Cytoplasmic Vesicles metabolism, Dynamin I metabolism

Abstract

Fusion and fission drive all vesicular transport. Although topologically opposite, these reactions pass through the same hemi-fusion/fission intermediate, characterized by a 'stalk' in which only the outer membrane monolayers of the two compartments have merged to form a localized non-bilayer connection. Formation of the hemi-fission intermediate requires energy input from proteins catalysing membrane remodelling; however, the relationship between protein conformational rearrangements and hemi-fusion/fission remains obscure. Here we analysed how the GTPase cycle of human dynamin 1, the prototypical membrane fission catalyst, is directly coupled to membrane remodelling. We used intramolecular chemical crosslinking to stabilize dynamin in its GDP·AlF4(-)-bound transition state. In the absence of GTP this conformer produced stable hemi-fission, but failed to progress to complete fission, even in the presence of GTP. Further analysis revealed that the pleckstrin homology domain (PHD) locked in its membrane-inserted state facilitated hemi-fission. A second mode of dynamin activity, fuelled by GTP hydrolysis, couples dynamin disassembly with cooperative diminishing of the PHD wedging, thus destabilizing the hemi-fission intermediate to complete fission. Molecular simulations corroborate the bimodal character of dynamin action and indicate radial and axial forces as dominant, although not independent, drivers of hemi-fission and fission transformations, respectively. Mirrored in the fusion reaction, the force bimodality might constitute a general paradigm for leakage-free membrane remodelling.

Published

2015

15. Geometry of membrane fission.

Author

Frolov VA, Escalada A, Akimov SA, and Shnyrova AV

Subjects

Cell Membrane chemistry, Membrane Microdomains chemistry, Membrane Microdomains metabolism, Thermodynamics, Cell Membrane metabolism

Abstract

Cellular membranes define the functional geometry of intracellular space. Formation of new membrane compartments and maintenance of complex organelles require division and disconnection of cellular membranes, a process termed membrane fission. Peripheral membrane proteins generally control membrane remodeling during fission. Local membrane stresses, reflecting molecular geometry of membrane-interacting parts of these proteins, sum up to produce the key membrane geometries of fission: the saddle-shaped neck and hour-glass hemifission intermediate. Here, we review the fundamental principles behind the translation of molecular geometry into membrane shape and topology during fission. We emphasize the central role the membrane insertion of specialized protein domains plays in orchestrating fission in vitro and in cells. We further compare individual to synergistic action of the membrane insertion during fission mediated by individual protein species, proteins complexes or membrane domains. Finally, we describe how local geometry of fission intermediates defines the functional design of the protein complexes catalyzing fission of cellular membranes., (Copyright © 2014 Elsevier Ireland Ltd. All rights reserved.)

Published

2015

16. Stochastic transport through carbon nanotubes in lipid bilayers and live cell membranes.

Author

Geng J, Kim K, Zhang J, Escalada A, Tunuguntla R, Comolli LR, Allen FI, Shnyrova AV, Cho KR, Munoz D, Wang YM, Grigoropoulos CP, Ajo-Franklin CM, Frolov VA, and Noy A

Subjects

Animals, Biological Transport, CHO Cells, Cell Survival, Cricetulus, DNA metabolism, HEK293 Cells, Humans, Ion Channels metabolism, Liposomes, Porins chemistry, Cell Membrane chemistry, Cell Membrane metabolism, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Nanotubes, Carbon ultrastructure, Porins metabolism, Stochastic Processes

Abstract

There is much interest in developing synthetic analogues of biological membrane channels with high efficiency and exquisite selectivity for transporting ions and molecules. Bottom-up and top-down methods can produce nanopores of a size comparable to that of endogenous protein channels, but replicating their affinity and transport properties remains challenging. In principle, carbon nanotubes (CNTs) should be an ideal membrane channel platform: they exhibit excellent transport properties and their narrow hydrophobic inner pores mimic structural motifs typical of biological channels. Moreover, simulations predict that CNTs with a length comparable to the thickness of a lipid bilayer membrane can self-insert into the membrane. Functionalized CNTs have indeed been found to penetrate lipid membranes and cell walls, and short tubes have been forced into membranes to create sensors, yet membrane transport applications of short CNTs remain underexplored. Here we show that short CNTs spontaneously insert into lipid bilayers and live cell membranes to form channels that exhibit a unitary conductance of 70-100 picosiemens under physiological conditions. Despite their structural simplicity, these 'CNT porins' transport water, protons, small ions and DNA, stochastically switch between metastable conductance substates, and display characteristic macromolecule-induced ionic current blockades. We also show that local channel and membrane charges can control the conductance and ion selectivity of the CNT porins, thereby establishing these nanopores as a promising biomimetic platform for developing cell interfaces, studying transport in biological channels, and creating stochastic sensors.

Published

2014

17. Geometric catalysis of membrane fission driven by flexible dynamin rings.

Author

Shnyrova AV, Bashkirov PV, Akimov SA, Pucadyil TJ, Zimmerberg J, Schmid SL, and Frolov VA

Subjects

Biocatalysis, Guanosine Triphosphate metabolism, Hydrolysis, Lipid Bilayers chemistry, Models, Biological, Nanotubes, Protein Conformation, Protein Multimerization, Protein Structure, Tertiary, Thermodynamics, Dynamin I chemistry, Dynamin I metabolism, Lipid Bilayers metabolism

Abstract

Biological membrane fission requires protein-driven stress. The guanosine triphosphatase (GTPase) dynamin builds up membrane stress by polymerizing into a helical collar that constricts the neck of budding vesicles. How this curvature stress mediates nonleaky membrane remodeling is actively debated. Using lipid nanotubes as substrates to directly measure geometric intermediates of the fission pathway, we found that GTP hydrolysis limits dynamin polymerization into short, metastable collars that are optimal for fission. Collars as short as two rungs translated radial constriction to reversible hemifission via membrane wedging of the pleckstrin homology domains (PHDs) of dynamin. Modeling revealed that tilting of the PHDs to conform with membrane deformations creates the low-energy pathway for hemifission. This local coordination of dynamin and lipids suggests how membranes can be remodeled in cells.

Published

2013

18. Lipid polymorphisms and membrane shape.

Author

Frolov VA, Shnyrova AV, and Zimmerberg J

Subjects

Cell Shape, Lipid Bilayers chemistry, Membrane Lipids chemistry, Membrane Lipids metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism, Cell Membrane ultrastructure, Lipid Bilayers metabolism, Membrane Lipids physiology

Abstract

Morphological plasticity of biological membrane is critical for cellular life, as cells need to quickly rearrange their membranes. Yet, these rearrangements are constrained in two ways. First, membrane transformations may not lead to undesirable mixing of, or leakage from, the participating cellular compartments. Second, membrane systems should be metastable at large length scales, ensuring the correct function of the particular organelle and its turnover during cellular division. Lipids, through their ability to exist with many shapes (polymorphism), provide an adequate construction material for cellular membranes. They can self-assemble into shells that are very flexible, albeit hardly stretchable, which allows for their far-reaching morphological and topological behaviors. In this article, we will discuss the importance of lipid polymorphisms in the shaping of membranes and its role in controlling cellular membrane morphology.

Published

2011

19. Domain-driven morphogenesis of cellular membranes.

Author

Shnyrova AV, Frolov VA, and Zimmerberg J

Subjects

Cell Membrane metabolism, Cell Membrane Structures physiology, Cell Membrane Structures ultrastructure, Cell Shape, Lipid Bilayers metabolism, Membrane Proteins metabolism, Membrane Proteins physiology, Cell Membrane physiology, Cell Membrane ultrastructure

Abstract

Cellular membrane systems delimit and organize the intracellular space. Most of the morphological rearrangements in cells involve the coordinated remodeling of the lipid bilayer, the core of the membranes. This process is generally thought to be initiated and coordinated by specialized protein machineries. Nevertheless, it has become increasingly evident that the most essential part of the geometric information and energy required for membrane remodeling is supplied via the cooperative and synergistic action of proteins and lipids, as cellular shapes are constructed using the intrinsic dynamics, plasticity and self-organizing capabilities provided by the lipid bilayer. Here, we analyze the essential role of proteo-lipid membrane domains in conducting and coordinating morphological remodeling in cells.

Published

2009

20. Chapter 4 - Reconstitution of membrane budding with unilamellar vesicles.

Author

Shnyrova AV and Zimmerberg J

Subjects

Membrane Microdomains chemistry, Membrane Microdomains metabolism, Membrane Proteins metabolism, Newcastle disease virus chemistry, Newcastle disease virus metabolism, Newcastle disease virus physiology, Protein Binding, Unilamellar Liposomes chemistry, Viral Matrix Proteins analysis, Viral Matrix Proteins chemistry, Virus Replication, Biological Assay methods, Unilamellar Liposomes metabolism, Viral Matrix Proteins metabolism

Abstract

Enveloped virus particles select their lipid-protein components and egress by budding from the host cell membranes. The matrix protein of many enveloped viruses has been proposed as a crucial element for viral budding; however, molecular mechanisms behind membrane remodeling by the matrix protein are yet to be unraveled. Here, we describe a set of in vitro functional reconstitution assays that allow quantitative evaluation of both, membrane binding and creation of membrane curvature by the matrix protein isolated from Newcastle Disease Virus. Individual budding events orchestrated by the matrix protein can be resolved in real time. The assays may be applied for direct reconstitution of the on-membrane action of cellular proteins involved in membrane curvature induction upon binding in vivo.

Published

2009

21. Vesicle formation by self-assembly of membrane-bound matrix proteins into a fluidlike budding domain.

Author

Shnyrova AV, Ayllon J, Mikhalyov II, Villar E, Zimmerberg J, and Frolov VA

Subjects

Cholesterol chemistry, Ethanolamines chemistry, Fluorescent Dyes, Glycoproteins chemistry, Glycoproteins ultrastructure, Lipid Bilayers chemistry, Microscopy, Electron, Newcastle disease virus chemistry, Newcastle disease virus physiology, Patch-Clamp Techniques, Phospholipids chemistry, Phospholipids metabolism, Phosphorylcholine chemistry, Protein Structure, Tertiary, Spectrometry, Fluorescence, Temperature, Thermodynamics, Viral Envelope Proteins metabolism, Viral Matrix Proteins chemistry, Glycoproteins metabolism, Unilamellar Liposomes metabolism, Viral Matrix Proteins biosynthesis

Abstract

The shape of enveloped viruses depends critically on an internal protein matrix, yet it remains unclear how the matrix proteins control the geometry of the envelope membrane. We found that matrix proteins purified from Newcastle disease virus adsorb on a phospholipid bilayer and condense into fluidlike domains that cause membrane deformation and budding of spherical vesicles, as seen by fluorescent and electron microscopy. Measurements of the electrical admittance of the membrane resolved the gradual growth and rapid closure of a bud followed by its separation to form a free vesicle. The vesicle size distribution, confined by intrinsic curvature of budding domains, but broadened by their merger, matched the virus size distribution. Thus, matrix proteins implement domain-driven mechanism of budding, which suffices to control the shape of these proteolipid vesicles.

Published

2007

22. Effect of acetonitrile on Cynara cardunculus L. cardosin A stability.

Author

Shnyrova AV, Oliveira CS, Sarmento AC, Barros MT, Zhadan GG, Roig MG, and Shnyrov VL

Subjects

Aspartic Acid Endopeptidases metabolism, Calorimetry, Differential Scanning, Circular Dichroism, Enzyme Stability drug effects, Kinetics, Plant Proteins metabolism, Protein Conformation drug effects, Protein Denaturation drug effects, Spectrometry, Fluorescence, Thermodynamics, Tryptophan chemistry, Acetonitriles pharmacology, Aspartic Acid Endopeptidases chemistry, Cynara enzymology, Plant Proteins chemistry

Abstract

The kinetics of the structural changes affecting cardosin A, a plant aspartic proteinase (AP) from Cynara cardunculus L., in the presence of a mixture of acetonitrile (AN) in water (W) was studied. Incubation of cardosin A with 10% (v/v) AN resulted in a gradual increase in protein helicity, accompanied by changes in the tertiary structure, seen by changes in the intrinsic fluorescence of tryptophan. Differential scanning calorimetry (DSC) revealed that the temperature of denaturation of cardosin A decreased upon the addition of AN. With longer incubation times, the small chain of cardosin A denatured completely, consequent exposure of the single tryptophan residue accounting well for the observed spectral shift intrinsic fluorescence of the protein. Enzymatic activity assays demonstrated that the kinetically determined unfolding of the small chain of cardosin A does not result in loss of the activity of this enzyme.

Published

2006

23. Thermally induced conformational changes in horseradish peroxidase.

Author

Pina DG, Shnyrova AV, Gavilanes F, Rodríguez A, Leal F, Roig MG, Sakharov IY, Zhadan GG, Villar E, and Shnyrov VL

Subjects

Calorimetry, Circular Dichroism, Hydrogen-Ion Concentration, Protein Conformation, Protein Denaturation, Spectrometry, Fluorescence, Temperature, Horseradish Peroxidase chemistry

Abstract

Detailed differential scanning calorimetry (DSC), steady-state tryptophan fluorescence and far-UV and visible CD studies, together with enzymatic assays, were carried out to monitor the thermal denaturation of horseradish peroxidase isoenzyme c (HRPc) at pH 3.0. The spectral parameters were complementary to the highly sensitive but integral method of DSC. Thus, changes in far-UV CD corresponded to changes in the overall secondary structure of the enzyme, while that in the Soret region, as well as changes in intrinsic tryptophan fluorescence emission, corresponded to changes in the tertiary structure of the enzyme. The results, supported by data about changes in enzymatic activity with temperature, show that thermally induced transitions for peroxidase are irreversible and strongly dependent upon the scan rate, suggesting that denaturation is under kinetic control. It is shown that the process of HRPc denaturation can be interpreted with sufficient accuracy in terms of the simple kinetic scheme N -->k D where k is a first-order kinetic constant that changes with temperature, as given by the Arrhenius equation; N is the native state, and D is the denatured state. On the basis of this model, the parameters of the Arrhenius equation were calculated.

Published

2001