Sebastian Kenny scite author profile

Sebastian Kenny

5Publications

58Citation Statements Received

303Citation Statements Given

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Purdue University West Lafayette

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Legionella effector MavC targets the Ube2N~Ub conjugate for noncanonical ubiquitination

Puvar

Iyer

et al. 2020

Nat Commun

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The bacterial effector MavC modulates the host immune response by blocking Ube2N activity employing an E1-independent ubiquitin ligation, catalyzing formation of a γ-glutamylε-Lys (Gln40 Ub-Lys92 Ube2N) isopeptide crosslink using a transglutaminase mechanism. Here we provide biochemical evidence in support of MavC targeting the activated, thioester-linked Ube2N~ubiquitin conjugate, catalyzing an intramolecular transglutamination reaction, covalently crosslinking the Ube2N and Ub subunits effectively inactivating the E2~Ub conjugate. Ubiquitin exhibits weak binding to MavC alone, but shows an increase in affinity when tethered to Ube2N in a disulfide-linked substrate that mimics the charged E2~Ub conjugate. Crystal structures of MavC in complex with the substrate mimic and crosslinked product provide insights into the reaction mechanism and underlying protein dynamics that favor transamidation over deamidation, while revealing a crucial role for the structurally unique insertion domain in substrate recognition. This work provides a structural basis of ubiquitination by transglutamination and identifies this enzyme's true physiological substrate.

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The Two Deubiquitinating Enzymes from Chlamydia trachomatis Have Distinct Ubiquitin Recognition Properties

et al. 2020

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Chlamydia trachomatis is the cause of several diseases such as sexually transmitted urogenital disease and ocular trachoma. The pathogen contains a small genome yet, upon infection, expresses two enzymes with deubiquitinating activity, termed ChlaDUB1 and ChlaDUB2, presumed to have redundant deubiquitinase (DUB) function because of the similarity of the primary structure of their catalytic domain. Previous studies have led to structural characterization of the enzymatic properties of ChlaDUB1; however, ChlaDUB2 has yet to be investigated thoroughly. In this study, we investigated the deubiquitinase properties of ChlaDUB2 and compared them to those of ChlaDUB1. This revealed a distinct difference in hydrolytic activity with regard to di-and polyubiquitin chains while showing similar ability to cleave a monoubiquitin-based substrate, ubiquitin aminomethylcoumarin (Ub-AMC). ChlaDUB2 was unable to cleave a diubiquitin substrate efficiently, whereas ChlaDUB1 could rapidly hydrolyze this substrate like a prototypical prokaryotic DUB, SdeA. With polyubiquitinated green fluorescent protein substrate (GFP-Ub n ), whereas ChlaDUB1 efficiently disassembled the polyubiquitin chains into the monoubiquitin product, the deubiquitination activity of ChlaDUB2, while showing depletion of the substrate, did not produce appreciable levels of the monoubiquitin product. We report the structures of a catalytic construct of ChlaDUB2 and its complex with ubiquitin propargyl amide. These structures revealed differences in residues involved in substrate recognition between the two Chlamydia DUBs. On the basis of the structures, we conclude that the distal ubiquitin binding is equivalent between the two DUBs, consistent with the Ub-AMC activity result. Therefore, the difference in activity with longer ubiquitinated substrates may be due to the differential recognition of these substrates involving additional ubiquitin binding sites.

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Insights into Ubiquitin Product Release in Hydrolysis Catalyzed by the Bacterial Deubiquitinase SdeA

et al. 2021

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We report the co-crystal structure of the (catalytic Cys)-to-Ala mutant of the deubiquitinase domain of the Legionella pneumophila effector SdeA (SdeADUB) with its ubiquitin (Ub) product. Most of the intermolecular interactions are preserved in this product-bound structure compared to that of the previously characterized complex of SdeADUB with the suicide inhibitor ubiquitin vinylmethyl ester (Ub-VME), whose structure models the acyl-enzyme thioester intermediate. Nuclear magnetic resonance (NMR) titration studies show a chemical shift perturbation pattern that suggests that the same interactions also exist in solution. Isothermal titration calorimetry and NMR titration data reveal that the affinity of wild-type (WT) SdeADUB for Ub is significantly lower than that of the Cys-to-Ala mutant. This is potentially due to repulsive interaction between the thiolate ion of the catalytic Cys residue in WT SdeADUB and the carboxylate group of the C-terminal Gly76 residue in Ub. In the context of SdeADUB catalysis, this electrostatic repulsion arises after the hydrolysis of the scissile isopeptide bond in the acyl-enzyme intermediate and the consequent formation of the C-terminal carboxylic group in the Ub fragment. We hypothesize that this electrostatic repulsion may expedite the release of the Ub product by SdeADUB. We note that similar repulsive interactions may also occur in other deubiquitinases and hydrolases of ubiquitin-like protein modifiers and may constitute a fairly general mechanism of product release within this family. This is a potentially important feature for a family of enzymes that form extensive protein–protein interactions during enzyme–substrate engagement.

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The Two Deubiquitinating Enzymes from Chlamydia trachomatis have Distinct Ubiquitin Recognition Properties

Hausman

Kenny

Das

2021

Biophysical Journal

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effective concentration. We find that phosphorylation kinetics scale with the length of the intrinsically disordered linkers that join the enzyme and substrate, but that the scaling differs between substrates. Steady-state kinetics only partially predict rates of tethered reactions as product release may obscure the rate of phospho-transfer. Our results suggest that changes in signalling complex architecture not only enhance the rates of phosphorylation reactions, but may also alter the relative substrate usage. This suggests a mechanism for how anchoring proteins can allosterically modify the output from a signalling pathway.

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SdeA DUB Domain in complex with Ubiquitin

Kenny¹,

Sheedlo²,

Das³

2021

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Sebastian Kenny

Legionella effector MavC targets the Ube2N~Ub conjugate for noncanonical ubiquitination

The Two Deubiquitinating Enzymes from Chlamydia trachomatis Have Distinct Ubiquitin Recognition Properties

Insights into Ubiquitin Product Release in Hydrolysis Catalyzed by the Bacterial Deubiquitinase SdeA

The Two Deubiquitinating Enzymes from Chlamydia trachomatis have Distinct Ubiquitin Recognition Properties

SdeA DUB Domain in complex with Ubiquitin

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