Florian Küllmer scite author profile

The function of actin is coupled to the nucleotide bound to its active site. ATP hydrolysis is activated during polymerization; a delay between hydrolysis and inorganic phosphate (P) release results in a gradient of ATP, ADP-P and ADP along actin filaments (F-actin). Actin-binding proteins can recognize F-actin's nucleotide state, using it as a local 'age' tag. The underlying mechanism is complex and poorly understood. Here we report six high-resolution cryo-EM structures of F-actin from rabbit skeletal muscle in different nucleotide states. The structures reveal that actin polymerization repositions the proposed catalytic base, His161, closer to the γ-phosphate. Nucleotide hydrolysis and P release modulate the conformational ensemble at the periphery of the filament, thus resulting in open and closed states, which can be sensed by coronin-1B. The drug-like toxin jasplakinolide locks F-actin in an open state. Our results demonstrate in detail how ATP hydrolysis links to F-actin's conformational dynamics and protein interaction.

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Optical Manipulation of F-Actin with Photoswitchable Small Molecules

Borowiak

Küllmer

Gegenfurtner

et al. 2020

J. Am. Chem. Soc.

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Cell-permeable photoswitchable small molecules, termed optojasps, are introduced to optically control the dynamics of the actin cytoskeleton and cellular functions that depend on it. These light-dependent effectors were designed from the F-actinstabilizing marine depsipeptide jasplakinolide by functionalizing them with azobenzene photoswitches. As demonstrated, optojasps can be employed to control cell viability, cell motility, and cytoskeletal signaling with the high spatial and temporal resolution that light affords. Optojasps can be expected to find applications in diverse areas of cell biological research. They may also provide a template for photopharmacology targeting the ubiquitous actin cytoskeleton with precision control in the micrometer range.

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Cryo‐EM Resolves Molecular Recognition Of An Optojasp Photoswitch Bound To Actin Filaments In Both Switch States

et al. 2021

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Actin is essential for key processes in all eukaryotic cells. Cellpermeable optojasps provide spatiotemporal control of the actin cytoskeleton, confining toxicity and potentially rendering F-actin druggable by photopharmacology. Here, we report cryo electron microscopy (cryo-EM) structures of both isomeric states of one optojasp bound to actin filaments. The high-resolution structures reveal for the first time the pronounced effects of photoswitching a functionalized azobenzene. By characterizing the optojasp binding site and identifying conformational changes within F-actin that depend on the optojasp isomeric state, we refine determinants for the design of functional F-actin photoswitches. Actin is a key player in eukaryotic cell biology and involved in cellular motility, cytokinesis, intra-cellular cargo transport and endocytosis. [1] The 42 kDa globular protein (G-actin) assembles into polar filaments (F-actin) that form complex and dynamic networks. To fulfill its diverse functions, the conformation and dynamics of actin filaments are clocked by ATP hydrolysis and the subsequent release of phosphate. [2, 3] Furthermore, actin polymerization and the assembly of higher order structures is tightly controlled in space and time by a plethora of actin binding proteins (ABPs). [4] While actin may serve as a potential entry for drug design due to its involvement in many cellular processes, it is also

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Systematic modifications of substitution patterns for property tuning of photoswitchable asymmetric azobenzenes

2022

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Next Generation Opto-Jasplakinolides Enable Local Remodeling of Actin Networks

Küllmer

Vepřek

Borowiak

et al. 2022

Preprint

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The natural product jasplakinolide is a widely used tool compound to stabilize F-actin and influence actin dynamics. We have previously introduced photoswitchable jasplakinolides (optojasps) that are activated with violet light and deactivated with blue light. Based on insights from cryo-electron microscopy and structure-activity relationship (SAR) studies, we now developed a new generation of functionally superior optojasps that are better suited for biological investigations. These compounds are procured through chemical total synthesis and feature rationally designed red-shifted azobenzene photoswitches. Our new optojasps can be activated with longer wavelengths in the visible range (e.g. 440-477 nm) and rapidly return to their inactive state through thermal relaxation. This has enabled the reversible control of F-actin dynamics, as shown through live-cell imaging and cell migration, as well as cell proliferation assays. Brief sub-cellular activation with blue-green light resulted in highly localized F-actin clusters that gradually dissolved in the dark. Our light-responsive tools can be useful in diverse fields to study actin dynamics with outstanding spatiotemporal precision.

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