Membrane lipids drive formation of KRAS4b-RAF1 RBDCRD nanoclusters on the membrane

Shrestha, Rebika; Carpenter, Timothy S.; Van, Que N.; Agamasu, Constance; Tonelli, Marco; Aydin, Fikret; Chen, De; Gulten, Gulcin; Glosli, James N.; López, Cesar A.; Oppelstrup, Tomas; Neale, Chris; Gnanakaran, Sandrasegaram; Gillette, William K.; Ingólfsson, Helgi I.; Lightstone, Felice C.; Stephen, Andrew G.; Streitz, Frederick H.; Nissley, Dwight V.; Turbyville, Thomas J.

doi:10.1038/s42003-024-05916-0

Commun Biol

2024

DOI: 10.1038/s42003-024-05916-0

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Membrane lipids drive formation of KRAS4b-RAF1 RBDCRD nanoclusters on the membrane

Rebika Shrestha,

Timothy S. Carpenter,

Que N. Van

et al.

Abstract: The oncogene RAS, extensively studied for decades, presents persistent gaps in understanding, hindering the development of effective therapeutic strategies due to a lack of precise details on how RAS initiates MAPK signaling with RAF effector proteins at the plasma membrane. Recent advances in X-ray crystallography, cryo-EM, and super-resolution fluorescence microscopy offer structural and spatial insights, yet the molecular mechanisms involving protein-protein and protein-lipid interactions in RAS-mediated si… Show more

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Cited by 3 publications

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Two hearts beat as one: the debate over RAS dimers continues

Stephen

2024

Trends in Biochemical Sciences

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Two hearts beat as one: the debate over RAS dimers continues

Stephen

2024

Trends in Biochemical Sciences

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Generating Protein Structures for Pathway Discovery Using Deep Learning

Georgouli,

Stephany,

Tempkin

et al. 2024

J. Chem. Theory Comput.

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Resolving the intricate details of biological phenomena at the molecular level is fundamentally limited by both length- and time scales that can be probed experimentally. Molecular dynamics (MD) simulations at various scales are powerful tools frequently employed to offer valuable biological insights beyond experimental resolution. However, while it is relatively simple to observe long-lived, stable configurations of, for example, proteins, at the required spatial resolution, simulating the more interesting rare transitions between such states often takes orders of magnitude longer than what is feasible even on the largest supercomputers available today. One common aspect of this challenge is pathway discovery, where the start and end states of a scientific phenomenon are known or can be approximated, but the mechanistic details in between are unknown. Here, we propose a representation-learning-based solution that uses interpolation and extrapolation in an abstract representation space to synthesize potential transition states, which are automatically validated using MD simulations. The new simulations of the synthesized transition states are subsequently incorporated into the representation learning, leading to an iterative framework for targeted path sampling. Our approach is demonstrated by recovering the transition of a RAS-RAF protein domain (CRD) from membrane-free to interacting with the membrane using coarse-grain MD simulations.

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Producing recombinant proteins in Vibrio natriegens

Smith,

Hernández,

Messing

et al. 2024

Microb Cell Fact

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The diversity of chemical and structural attributes of proteins makes it inherently difficult to produce a wide range of proteins in a single recombinant protein production system. The nature of the target proteins themselves, along with cost, ease of use, and speed, are typically cited as major factors to consider in production. Despite a wide variety of alternative expression systems, most recombinant proteins for research and therapeutics are produced in a limited number of systems: Escherichia coli, yeast, insect cells, and the mammalian cell lines HEK293 and CHO. Recent interest in Vibrio natriegens as a new bacterial recombinant protein expression host is due in part to its short doubling time of ≤ 10 min but also stems from the promise of compatibility with techniques and genetic systems developed for E. coli. We successfully incorporated V. natriegens as an additional bacterial expression system for recombinant protein production and report improvements to published protocols as well as new protocols that expand the versatility of the system. While not all proteins benefit from production in V. natriegens, we successfully produced several proteins that were difficult or impossible to produce in E. coli. We also show that in some cases, the increased yield is due to higher levels of properly folded protein. Additionally, we were able to adapt our enhanced isotope incorporation methods for use with V. natriegens. Taken together, these observations and improvements allowed production of proteins for structural biology, biochemistry, assay development, and structure-based drug design in V. natriegens that were impossible and/or unaffordable to produce in E. coli.

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Membrane lipids drive formation of KRAS4b-RAF1 RBDCRD nanoclusters on the membrane

Cited by 3 publications

References 65 publications

Two hearts beat as one: the debate over RAS dimers continues

Two hearts beat as one: the debate over RAS dimers continues

Generating Protein Structures for Pathway Discovery Using Deep Learning

Producing recombinant proteins in Vibrio natriegens

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