Date: November 21, 2024
Time: 9:00am PST, 12:00pm EST, 6:00pm CET
Exploring membrane proteins: Strategies for successful research and applications
Suzanne Smith, M.S.
Membrane proteins are essential for fundamental biological processes, and are important for drug discovery, understanding disease mechanisms, and advancing structural biology. Their intricate roles in cellular signaling and transport make them a critical area of research with broad implications in human health and life sciences.
Studying membrane proteins can be particularly challenging due to their complex structure, dynamic nature, and the difficulties with isolating and manipulating them outside of their native environment. There are many considerations to consider when designing experiments that directly impact sample yield, integrity, and downstream compatibility. An overview of strategies for membrane protein expression, extraction, and stabilization will be discussed, touching on the advantages and disadvantages associated with the different methods. Taking these factors into account will help ensure optimal results while saving precious time.
The presentation will then be handed over to Dr. Kallol Gupta, an Assistant Professor at Yale University, to discuss how different polymers, such as SMALPS (styrene malaic acid lipid particles), can be enriched for specific membrane protein solubilization based on their surrounding lipid bilayer. Dr. Gupta’s lab focuses on gaining a comprehensive understanding of how the spatiotemporal arrangement of membrane proteins and lipids influences and regulates various aspects of cellular physiology. By attending this presentation, you will gain the foundational knowledge needed to help maximize your membrane protein studies.
Capturing membrane proteins in their native membrane nanodomain contexts
Kallol Gupta, Ph.D.
The intricate molecular environment of the native membrane profoundly influences every aspect of membrane protein (MP) biology. Despite this, the most prevalent method of studying MPs uses detergent-like molecules that disrupt and remove this vital local membrane context. This severely impedes our ability to quantitatively decipher the local molecular context and comprehend its regulatory role in the structure, function, and biogenesis of MPs. Using a library of membrane-active polymers (MAP) we have developed a platform for the high-throughput analysis of the membrane proteome. The platform enables near-complete spatially resolved extraction of target MPs directly from their endogenous membranes into native nanodiscs that maintain the local membrane context. We accompany this advancement with an open-access database that quantifies the polymer-specific extraction variability for 2065 unique mammalian MPs and provide an exceptional optimized condition for each of them. Our method enables rapid and near-complete extraction and purification of target MPs directly from their endogenous organellar membranes at physiological expression levels while maintaining the nanoscale local membrane environment. Going beyond the plasma membrane proteome, our platform enables extraction from any target organellar membrane including the endoplasmic reticulum, mitochondria, lysosome, Golgi, and even transient organelles such as the autophagosome. We expect these publicly available resources to help empower researchers across disciplines to efficiently capture membrane ‘nano-scoops’ containing a target MP and interface with structural, functional, and other bioanalytical approaches.
For Research Use Only. Not for use in diagnostic procedures.
Webinars will be available for unlimited on-demand viewing after live event.