A. Carl scite author profile

ATP-hydrolysis-coupled actin polymerization is a fundamental mechanism of cellular force generation1–3. In turn, force4,5 and actin filament (F-actin) nucleotide state6 regulate actin dynamics by tuning F-actin’s engagement of actin-binding proteins through mechanisms that are unclear. Here we show that the nucleotide state of actin modulates F-actin structural transitions evoked by bending forces. Cryo-electron microscopy structures of ADP–F-actin and ADP-Pi–F-actin with sufficient resolution to visualize bound solvent reveal intersubunit interfaces bridged by water molecules that could mediate filament lattice flexibility. Despite extensive ordered solvent differences in the nucleotide cleft, these structures feature nearly identical lattices and essentially indistinguishable protein backbone conformations that are unlikely to be discriminable by actin-binding proteins. We next introduce a machine-learning-enabled pipeline for reconstructing bent filaments, enabling us to visualize both continuous structural variability and side-chain-level detail. Bent F-actin structures reveal rearrangements at intersubunit interfaces characterized by substantial alterations of helical twist and deformations in individual protomers, transitions that are distinct in ADP–F-actin and ADP-Pi–F-actin. This suggests that phosphate rigidifies actin subunits to alter the bending structural landscape of F-actin. As bending forces evoke nucleotide-state dependent conformational transitions of sufficient magnitude to be detected by actin-binding proteins, we propose that actin nucleotide state can serve as a co-regulator of F-actin mechanical regulation.

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Narrow-Spectrum Antibiotic Targeting of the Radical SAM Enzyme MqnE in Menaquinone Biosynthesis

Carl

Harris

Feng

et al. 2020

Biochemistry

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Antibiotic resistance continues to spread at an alarming rate, outpacing the introduction of new therapeutics and threatening to globally undermine health care. There is a crucial need for new strategies that selectively target specific pathogens while leaving the majority of the microbiome untouched, thus averting the debilitating and sometimes fatal occurrences of opportunistic infections. To address these challenges, we have adopted a unique strategy that focuses on oxygen-sensitive proteins, an untapped set of therapeutic targets. MqnE is a member of the radical S-adenosyl-l-methionine (RS) superfamily, all of which rely on an oxygen-sensitive [4Fe-4S] cluster for catalytic activity. MqnE catalyzes the conversion of didehydrochorismate to aminofutalosine in the essential menaquinone biosynthetic pathway present in a limited set of species, including the gut pathogen Helicobacter pylori (Hp), making it an attractive target for narrow-spectrum antibiotic development. Indeed, we show that MqnE is inhibited by the mechanism-derived 2-fluoro analogue of didehydrochorismate (2F-DHC) due to accumulation of a radical intermediate under turnover conditions. Structures of MqnE in the apo and product-bound states afford insight into its catalytic mechanism, and electron paramagnetic resonance approaches provide direct spectroscopic evidence consistent with the predicted structure of the radical intermediate. In addition, we demonstrate the essentiality of the menaquinone biosynthetic pathway and unambiguously validate 2F-DHC as a selective inhibitor of Hp growth that exclusively targets MqnE. These data provide the foundation for designing effective Hp therapies and demonstrate proof of principle that radical SAM proteins can be effectively leveraged as therapeutic targets.

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Crystal structure and mutational analysis of Mycobacterium smegmatis FenA highlight active site amino acids and three metal ions essential for flap endonuclease and 5′ exonuclease activities

Uson

Carl

Goldgur

et al. 2018

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Mycobacterium smegmatis FenA is a nucleic acid phosphodiesterase with flap endonuclease and 5′ exonuclease activities. The 1.8 Å crystal structure of FenA reported here highlights as its closest homologs bacterial FEN-family enzymes ExoIX, the Pol1 exonuclease domain and phage T5 Fen. Mycobacterial FenA assimilates three active site manganese ions (M1, M2, M3) that are coordinated, directly and via waters, to a constellation of eight carboxylate side chains. We find via mutagenesis that the carboxylate contacts to all three manganese ions are essential for FenA’s activities. Structures of nuclease-dead FenA mutants D125N, D148N and D208N reveal how they fail to bind one of the three active site Mn2+ ions, in a distinctive fashion for each Asn change. The structure of FenA D208N with a phosphate anion engaged by M1 and M2 in a state mimetic of a product complex suggests a mechanism for metal-catalyzed phosphodiester hydrolysis similar to that proposed for human Exo1. A distinctive feature of FenA is that it does not have the helical arch module found in many other FEN/FEN-like enzymes. Instead, this segment of FenA adopts a unique structure comprising a short 310 helix and surface β-loop that coordinates a fourth manganese ion (M4).

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Actin nucleotide state modulates the F-actin structural landscape evoked by bending forces

Reynolds

Hachicho

Carl

et al. 2022

Preprint

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ATP hydrolysis-coupled actin polymerization is a fundamental mechanism of cellular force generation. Force and actin filament (F-actin) nucleotide state in turn modulate the engagement of actin binding proteins (ABPs) to regulate actin dynamics through unknown mechanisms. Here, we show that bending forces evoke structural transitions in F-actin which are modulated by actin nucleotide state. Cryo-electron microscopy (cryo-EM) structures of ADP- and ADP-Pi-F-actin with sufficient resolution to visualize bound solvent reveal inter-subunit interactions primarily bridged by waters which could contribute to lattice flexibility. Despite substantial ordered solvent differences in the nucleotide binding cleft, these structures feature essentially indistinguishable protein backbone conformations which are unlikely to be discriminable by ABPs. We next introduce a machine-learning enabled pipeline for reconstructing bent filaments, enabling us to visualize both continuous structural variability and side-chain level detail. Bent F-actin structures reveal major rearrangements at inter-subunit interfaces characterized by striking alterations of helical twist and deformations of individual protomers which are distinct in ADP- and ADP-Pi-F-actin. This suggests phosphate rigidifies actin subunits to alter F-actin's bending structural landscape. We therefore propose actin nucleotide state serves as a co-regulator of F-actin mechanical regulation, as bending forces evoke nucleotide-state dependent conformational transitions that could be readily detected by ABPs.

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Mycobacterium smegmatis DNA flap endonuclease

Shuman¹,

Goldgur²,

Carl³

et al. 2018

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A. Carl

Bending forces and nucleotide state jointly regulate F-actin structure

Narrow-Spectrum Antibiotic Targeting of the Radical SAM Enzyme MqnE in Menaquinone Biosynthesis

Crystal structure and mutational analysis of Mycobacterium smegmatis FenA highlight active site amino acids and three metal ions essential for flap endonuclease and 5′ exonuclease activities

Actin nucleotide state modulates the F-actin structural landscape evoked by bending forces

Mycobacterium smegmatis DNA flap endonuclease

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