Your search keyword '"Carl C. Hayden"' showing total 3 results

1. Lateral compression of lipids drives transbilayer coupling of liquid-like protein condensates

Author

Yohan Lee, Sujin Park, Feng Yuan, Carl C. Hayden, Siyoung Q. Choi, and Jeanne C. Stachowiak

Abstract

Liquid-liquid phase separation of proteins has recently been observed on the surfaces of biological membranes, where it plays a role in diverse cellular processes, from assembly of focal adhesions and the immunological synapse, to biogenesis of trafficking vesicles. Interestingly in each of these cases, proteins on both surfaces of the membrane are thought to participate, suggesting that protein phase separation could be coupled across the membrane. To explore this possibility, we used an array of freestanding planar lipid membranes to observe protein phase separation simultaneously on both surfaces of lipid bilayers. When proteins known to engage in phase separation bound to the surfaces of these membranes, two-dimensional, protein-rich phases rapidly emerged. These phases displayed the hallmarks of a liquid, coarsening over time by fusing and re-rounding. Interestingly, we observed that protein-rich domains on one side of the membrane colocalized with those on the other side, resulting in transbilayer coupling. How do liquid-like protein phases communicate across the lipid bilayer? Our results, based on lipid probe partitioning and the differential mobility of proteins and lipids, collectively suggest an entropic coupling mechanism, which relies on the ability of protein phase separation to locally reduce the entropy of the underlying lipid membrane, most likely by increasing lipid packing. Regions of reduced entropy then colocalize across the bilayer to minimize the overall free energy of the membrane. These findings suggest a previously unknown mechanism by which cellular signals originating from one side of the membrane, triggered by protein phase separation, can be transferred to the opposite side.

Published

2022

2. Molecular Mechanisms of Steric Pressure Generation and Membrane Remodeling by Intrinsically Disordered Proteins

Author

Justin R. Houser, Hyun Woo Cho, Carl C. Hayden, Noel X. Yang, Liping Wang, Eileen M. Lafer, D. Thirumalai, and Jeanne C. Stachowiak

Abstract

Cellular membranes, which are densely crowded by proteins, take on an elaborate array of highly curved shapes. Steric pressure generated by protein crowding plays a significant role in shaping membrane surfaces. It is increasingly clear that many proteins involved in membrane remodeling contain substantial regions of intrinsic disorder. These domains have large hydrodynamic radii, suggesting that they may contribute significantly to steric congestion on membrane surfaces. However, it has been unclear to what extent they are capable of generating steric pressure, owing to their conformational flexibility. To address this gap, we use a recently developed sensor based on Förster resonance energy transfer to measure steric pressure generated at membrane surfaces by the intrinsically disordered domain of the endocytic protein, AP180. We find that disordered domains generate substantial steric pressure that arises from both entropic and electrostatic components. Interestingly, this steric pressure is largely invariant with the molecular weight of the disordered domain, provided that coverage of the membrane surface is held constant. Moreover, equivalent levels of steric pressure result in equivalent degrees of membrane remodeling, regardless of protein molecular weight. This result, which is consistent with classical polymer scaling relationships for semi-dilute solutions, helps to explain the molecular and physical origins of steric pressure generation by intrinsically disordered domains. From a physiological perspective, these findings suggest that a broad range of membrane-associated disordered domains are likely to play a significant and previously unknown role in controlling membrane shape.SignificanceWith nearly half their surfaces covered by proteins, biological membranes are highly crowded. Rapid diffusion and collision of membrane-bound proteins generates substantial steric pressure that is capable of shaping membrane surfaces. Many proteins involved in membrane remodeling, are intrinsically disordered. Having large hydrodynamic radii, disordered domains could contribute substantially to membrane crowding. However, it is unclear to what extent they are capable of generating steric pressure, owing to their conformational flexibility. Toward resolving this uncertainty, we have measured steric pressure at membrane surfaces during dynamic membrane remodeling events. Our data indicate that disordered domains generate significant steric pressure through entropic and electrostatic mechanisms, suggesting that they may constitute a critical, yet previously neglected class of membrane remodeling proteins.

Published

2022

3. Liquid-like protein interactions catalyze assembly of endocytic vesicles

Author

Liping Wang, Eileen M. Lafer, Kasey J. Day, Jeanne C. Stachowiak, J Blair Richter, Carl C. Hayden, and Grace Kago

Subjects

0303 health sciences, Vesicle budding, Budding, Chemistry, Vesicle, Endocytosis, Protein–protein interaction, 03 medical and health sciences, 0302 clinical medicine, Endocytic vesicle, Membrane, Biophysics, Membrane surface, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

During clathrin-mediated endocytosis, dozens of proteins assemble into an interconnected network at the plasma membrane. As early initiators of endocytosis, Eps15 and Fcho1 are responsible for locally concentrating downstream components on the membrane surface. However, they must also permit dynamic rearrangement of proteins within the budding vesicle. How do initiator proteins meet these competing demands? Here we show that Eps15 and Fcho1 rely on weak, liquid-like interactions to efficiently catalyze endocytosis. In reconstitution experiments, these weak interactions promote the assembly of protein droplets with liquid-like properties, including rapid coalescence and dynamic exchange of protein components. To probe the physiological role of liquid-like interactions among initiator proteins, we tuned the strength of initiator protein assembly in real time using light-inducible oligomerization of Eps15. Low light levels drove initiator proteins into liquid-like assemblies, restoring normal rates of endocytosis in mammalian Eps15 knockout cells. In contrast, initiator proteins formed solid-like assemblies upon exposure to higher light levels. Assembly of these structures stalled vesicle budding, likely owing to insufficient molecular rearrangement. These findings suggest that liquid-like assembly of early initiator proteins provides an optimal catalytic platform for endocytosis.

Published

2019