Dr. Alamgir Karim
Stabilized Coacervate Microdroplets and Vesicles as Model Protocells
Abstract:
Coacervate microdroplets have been widely studied as protocell models due to their ability to grow, divide, and selectively concentrate biomolecules such as RNA. However, their rapid fusion and unrestricted molecular exchange pose a significant challenge to maintaining distinct genetic identities over time, making sustained evolutionary processes unfeasible. The rapid spread of parasitic RNA within coacervate populations could further hinder their potential role in prebiotic evolution. In this study, we demonstrate that exposure to distilled water, mimicking freshwater environments, induces the formation of electrostatic crosslinks at the droplet interface. These crosslinks effectively prevent droplet fusion indefinitely while also modulating the diffusion and compartmentalization of RNA. The retention timescales of RNA within individual droplets vary based on RNA length and structure, extending over several days. This prolonged molecular retention provides a potential mechanism for maintaining distinct RNA populations within separate coacervate compartments. Our findings suggest that nonfusing, membraneless coacervates could serve as primitive protocells capable of sustaining compartmentalized ribozyme activity in early Earth conditions. By stabilizing coacervate structures, environmental factors such as freshwater influx may have played a key role in shaping early molecular evolution, offering new insights into the origin of functional RNA systems. Beyond their implications for early life, these stabilized coacervates exhibit intrinsic polarizability due to their charged nature and diffuse counterion clouds, making them highly responsive to electric fields. We show that individual droplets and their larger assemblies can be precisely manipulated using low-voltage fields comparable in magnitude to a standard 9-volt battery. This controllability opens new possibilities for using coacervates as tunable materials for encapsulating, transporting, and delivering cargos in applications spanning biomedicine and manufacturing. Additionally, these systems serve as a model for dynamically evolving coacervate vesicles for understanding electrodynamic behaviors in biological materials, shedding light on how living systems may harness electrostatic interactions for organization, function and evolution as active matter.
Speaker: Alamgir Karim, University of Houston
Alamgir Karim is presently Dow and Welch Chair Professor in the Department of Chemical and Biomolecular Engineering at the University of Houston. He received his PhD degree in Physics from Northwestern University and did a post-doc at the Chemical Engineering at University of Minnesota. He was led multiple Groups at NIST's Polymers Division with deep NCNR affiliation, before becoming Associate Dean of Research of College of Polymers Science and Engineering at University of Akron. He has a h-index of 74 and is Fellows of the American Physical Society, American Association of Advancement of Science and Neutron Scattering Society of America. His area of research is in polymers for energy, sustainability, functional materials and soft matter applications.
Host: Srini Raghavan
Seminars start at 4:00 pm, and refreshments will be served at 3:45 pm. All seminars are held in the 2136 Physical Sciences Complex (#415) unless otherwise noted.