The Proteasomal ATPases Use a Slow but Highly Processive Strategy to Unfold Proteins

Snoberger, Aaron; Anderson, Raymond T.; Smith, David M.

doi:10.3389/fmolb.2017.00018

Cited by 18 publications

(15 citation statements)

References 40 publications

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“…This study uncovered several surprising properties of the structure and function of the PAN proteasomal ATPase: (1) PAN’s CCs are not conformationally symmetric, (2) global conformation of the CCs does not appear to cycle around the ring, and (3) local changes in two of the CC conformations (C2 and C3) can regulate PAN’s activity. Previous biochemical studies suggest that PAN adopts asymmetrical conformations 48 , 50 , 51 , but the present study provides direct structural evidence of this, at least for the CC domains. This finding is critical, because up until this point it has been assumed based on crystal structures of PAN’s N-terminus that it is symmetric.…”

Section: Discussioncontrasting

confidence: 41%

“…Since crosslinking C1 has no effect on activity, and since crosslinking C1+C3 lowers PAN’s activity, these data indicate that stabilizing C3 by crosslinking stabilizes a functional but low activity state of PAN. This suggests that crosslinking the C3 state results in the slowing of some step in the ATP hydrolysis cycle (ATP binding, ATP hydrolysis/phosphate leaving, or ADP off rate) but does not have an effect on the mechanochemical coupling of ATP hydrolysis to substrate unfolding previously observed for proteasomal ATPases 50 . While PAN 87+73C alone in the reduced state had a slightly lower Vmax (42 ± 1 ATP/PAN/min), it had a similar Km as WT-PAN (556 ± 29 mM) (Supplementary Table 1 , Supplementary Fig.…”

Section: Resultsmentioning

confidence: 66%

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Conformational switching in the coiled-coil domains of a proteasomal ATPase regulates substrate processing

2018

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Protein degradation in all domains of life requires ATPases that unfold and inject proteins into compartmentalized proteolytic chambers. Proteasomal ATPases in eukaryotes and archaea contain poorly understood N-terminally conserved coiled-coil domains. In this study, we engineer disulfide crosslinks in the coiled-coils of the archaeal proteasomal ATPase (PAN) and report that its three identical coiled-coil domains can adopt three different conformations: (1) in-register and zipped, (2) in-register and partially unzipped, and (3) out-of-register. This conformational heterogeneity conflicts with PAN’s symmetrical OB-coiled-coil crystal structure but resembles the conformational heterogeneity of the 26S proteasomal ATPases’ coiled-coils. Furthermore, we find that one coiled-coil can be conformationally constrained even while unfolding substrates, and conformational changes in two of the coiled-coils regulate PAN switching between resting and active states. This switching functionally mimics similar states proposed for the 26S proteasome from cryo-EM. These findings thus build a mechanistic framework to understand regulation of proteasome activity.

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Section: Discussioncontrasting

confidence: 41%

Section: Resultsmentioning

confidence: 66%

Conformational switching in the coiled-coil domains of a proteasomal ATPase regulates substrate processing

2018

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“…Martin and colleagues recently used single-molecule analysis to analyze the unfolding of a GFP-fusion protein by ClpXP and showed that unfolding depends of the power generated by the pore loops and thus requires frequent and forceful pulling on the substrate (Rodriguez-Aliaga et al, 2016). However, Smith an coworkers showed that translocation by the 26S or PAN is more processive than by ClpXP and depends predominantly on the force generated by the pore loops rather than the frequency with which these loops pull on the substrate (Snoberger et al, 2017). …”

Section: Translocation Of the Polypeptide Through The Atpase Ringmentioning

confidence: 99%

The Logic of the 26S Proteasome

Collins

Goldberg

2017

Cell

676

626

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“…Processive enzymes play the important roles in various biological activities such as DNA/RNA synthesis (13,14), cargo transport (15,16), and protein (17,18) and polysaccharide (19 -21) degradations. Once processive enzymes bind to their substrates, they can repeat multiple cycles of catalysis without dissociation (22,23).…”

mentioning

confidence: 99%

Single-molecule imaging analysis reveals the mechanism of a high-catalytic-activity mutant of chitinase A from Serratia marcescens

Visootsat

Nakamura

Vignon

et al. 2020

Journal of Biological Chemistry

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Chitin degradation is important for biomass conversion and has potential applications for agriculture, biotechnology, and the pharmaceutical industry. Chitinase A from the Gram-negative bacterium Serratia marcescens (SmChiA) is a processive enzyme that hydrolyzes crystalline chitin as it moves linearly along the substrate surface. In a previous study, the catalytic activity of SmChiA against crystalline chitin was found to increase after the tryptophan substitution of two phenylalanine residues (F232W and F396W), located at the entrance and exit of the substrate binding cleft of the catalytic domain, respectively. However, the mechanism underlying this high catalytic activity remains elusive. In this study, single-molecule fluorescence imaging and high-speed atomic force microscopy were applied to understand the mechanism of this high-catalytic-activity mutant. A reaction scheme including processive catalysis was used to reproduce the properties of SmChiA WT and F232W/F396W, in which all of the kinetic parameters were experimentally determined. High activity of F232W/F396W mutant was caused by a high processivity and a low dissociation rate constant after productive binding. The turnover numbers for both WT and F232W/F396W, determined by the biochemical analysis, were well-replicated using the kinetic parameters obtained from single-molecule imaging analysis, indicating the validity of the reaction scheme. Furthermore, alignment of amino acid sequences of 258 SmChiA-like proteins revealed that tryptophan, not phenylalanine, is the predominant amino acid at the corresponding positions (Phe-232 and Phe-396 for SmChiA). Our study will be helpful for understanding the kinetic mechanisms and further improvement of crystalline chitin hydrolytic activity of SmChiA mutants.

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The Proteasomal ATPases Use a Slow but Highly Processive Strategy to Unfold Proteins

Cited by 18 publications

References 40 publications

Conformational switching in the coiled-coil domains of a proteasomal ATPase regulates substrate processing

Conformational switching in the coiled-coil domains of a proteasomal ATPase regulates substrate processing

The Logic of the 26S Proteasome

Single-molecule imaging analysis reveals the mechanism of a high-catalytic-activity mutant of chitinase A from Serratia marcescens

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