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![Page 1: Overlapping recognition determinants within the ssrA degradation tag allow modulation of proteolysis Flynn, Levchenko, Seidl, Wickner, Sauer, Baker Presented.](https://reader035.fdocuments.in/reader035/viewer/2022062516/56649dc65503460f94ababef/html5/thumbnails/1.jpg)
Overlapping recognition determinants within the ssrA degradation tag allow modulation of
proteolysis
Flynn, Levchenko, Seidl, Wickner, Sauer, Baker
Presented by Alice Crane and Lindsey Wu
![Page 2: Overlapping recognition determinants within the ssrA degradation tag allow modulation of proteolysis Flynn, Levchenko, Seidl, Wickner, Sauer, Baker Presented.](https://reader035.fdocuments.in/reader035/viewer/2022062516/56649dc65503460f94ababef/html5/thumbnails/2.jpg)
How do ClpX and ClpA interact differently with SspB?
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Definitions
ssrApeptide sequence added to proteins targeted for degradation
ClpX and ClpAProteins that promote ATP dependant degradation, aid in unfolding of protein
ClpPProtease that contains active site for degradation of damaged proteins
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Definitions continued
ClpXP and ClpAPComplexes formed by these proteins that carry out degradation
SspBRegulator of substrate recognition
- enhances ClpX recognition- inhibits ClpA recognition
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Proteolytic chamber of ClpP
Binding to ssrA tag
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Goal of Experiment
To determine the sequence information in the 11 a.a ssrA degradation tag required for recognition by ClpX, ClpA, and SspB
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Mutant Derivation
Non alanine residues Alanine (A)Alanine residues Aspartic Acid (D)
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GFP Mutants
GFP cloned into a vector and mutant ssrA tags ligated into vector.
Allows for loss of fluorescence to be measured – basis for for degradation assays.
Loss in fluorescence = Increase in degradation
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SsrA Tag ClpX Recognition
Goal: To determine which residues are critical for ClpX recognition by testing 12 GFP-ssrA mutants.
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Only those with substitutions at tag positions 9, 10 and 11 caused significant increase in Km for ClpXP degradation, though 9 was less critical.
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Formed 2 mutants
Mutant 11-8 mutated to generate GFP – D2A5DLAA
Mutant 21-8 mutated to glycines – GFP – G8LAA
Is L-A-A sequence enough for ClpX recognition?
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Mutant 1 caused slight Km increase due to cumulative minor effects.
Glycine-rich Mutant 2 inhibited ClpX recognition due to flexibility.
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The tri-peptide LAA sequence is sufficient in most cases (but not all) for ClpX recognition.
Conclusion
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SsrA Tag ClpA Recognition
Goal: To determine which residues are critical for ClpA recognition by using 12 GFP-ssrA mutants
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ClpA relies on a different set of residues than ClpX.
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ClpA recognizes sequences at N terminus and C terminus
Mutation of C terminal Alanine had no effect on degradation.
So, is the free -carboxyl group necessary for recognition?
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Compared normal - carboxyl group to mutant terminal carboxamide (ssrA -CONH2) group.
Testing for -carboxyl group recognition
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Conclusions
ClpA recognizes ssrA-like signals in any exposed region of a protein.
(Previous studies show that -carboxyl group is important for ClpX recognition of ssrA)
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SsrA Tag SspB Recognition
Goal: To determine which residues are critical for SspB recognition
Created peptide library
Each residue mutated to each other 19 aa’s, while keeping other 10 residues unchanged.
(Total of 220 mutants)
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Each spot corresponds to 1 mutant sequence.
Bound SspB was detected with anti-SspB antibodies.
SspB recognition is dependent on residues 1,2,3,4, and 7.
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SspB and ClpX are recognition dependent on different positions on ssrA tag.
SspB and ClpA interact with some of the same residues.
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Conclusion
SspB enhances ClpX recognition, but inhibits ClpA.
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Dual Recognition by SspB and ClpX
Goal
To determine if binding of SspB to ssrA tag is enough for ClpX recognition or is independent recognition of ClpX required.
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Monitored degradation with SspB of 3 mutants (L9A, A10D, A11D).
All are ClpX recognition defective.
Mutants A10D and A11D were not degraded by ClpX.
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Mutant L9A with SspB was degraded, but not as efficiently as wild type with SspB.
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Conclusions
SspB binding cannot bypass requirement of ClpX recognition for residues 10 and 11.
SspB can compensate for decreased interaction with ClpX and a mutation at residue 9.
SspB regulated degradation requires sets of binding determinants for both ClpX and SspB.
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SspB Inhibition of ClpA
GoalTo test the assumption that ClpA and SspB binding is mutually exclusive.
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Compared wild type to mutant (N3A) defective in SspB recognition.
Wild type ClpA recognition completely inhibited
Mutant ClpA recognition not inhibited SspB presence.
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Conclusions
Binding is mutually exclusive.
Specific interaction of SspB to ssrA tag required to inhibit ClpA recognition.
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C-terminal tripeptide of ssrA tag is highly conserved across many bacterial species.
N-terminal portions of ssrA also highly conserved
Conservation of Clpx and SspB
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Conclusion
Suggests that these bacteria also have a SspB-like regulator or that these are regions mediate interactions with other proteases.
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What is the biological explanation for the inhibition of ClpA?
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Possible Explanations
ClpAP, but not ClpXP, degrades unfolded proteins without target signals.
- important during heat shock or environmental stress
In times of stress, up-regulation of SspB can direct ssrA tagged substrates to ClpXP, leaving ClpAP free to degraded unfolded substrates.
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Works Cited
Clark, Adrien K. “ATP-dependent Clp Proteases in Photosynthetic OrganismsÐA Cut Above the Rest!” (1999) Annals of Botany 83: 593±599
Hersch, Greg L. et al. “SspB delivery of substrates for ClpXP proteolysisprobed by the design of improved degradation tags.” (2004) Proc. Natl. Acad. Sci. 101: 12136–12141