Abstract
Ligation of polyubiquitin chains to proteins is a fundamental post-translational modification, often resulting in targeted degradation of conjugated proteins. Attachment of polyubiquitin chains requires the activities of an E1 activating enzyme, an E2 carrier protein, and an E3 ligase. The mechanism by which polyubiquitin chains are formed remains largely speculative, especially for RING-based ligases. The tripartite motif (TRIM) superfamily of ligases functions in many cellular processes including innate immunity, cellular localization, development and differentiation, signaling, and cancer progression. The present results show that TRIM ligases catalyze polyubiquitin chain formation in the absence of substrate, the rates of which can be used as a functional readout of enzyme function. Initial rate studies under biochemically defined conditions show that TRIM32 and TRIM25 are specific for the Ubc5 family of E2-conjugating proteins and, along with TRIM5α, exhibit cooperative kinetics with respect to Ubc5 concentration, with submicromolar [S]0.5 and Hill coefficients of 3-5, suggesting they possess multiple binding sites for their cognate E2-ubiquitin thioester. Mutation studies reveal a second, non-canonical binding site encompassing the C-terminal Ubc5α-helix. Polyubiquitin chain formation requires TRIM subunit oligomerization through the conserved coiled-coil domain, but can be partially replaced by fusing the catalytic domain to GST to promote dimerization. Other results suggest that TRIM32 assembles polyubiquitin chains as a Ubc5-linked thioester intermediate. These results represent the first detailed mechanistic study of TRIM ligase activity and provide a functional context for oligomerization observed in the superfamily.
Highlights
Targeted degradation by tripartite motif (TRIM) ligase-catalyzed polyubiquitin chain formation is critical for cell regulation and innate immunity
Target protein specificity among these posttranslational modifications is defined by a diverse subset of ubiquitin ligases (58) of which the TRIM superfamily constitutes more than 100 paralogs that serve important functions in cellular homeostasis and, more critically, in the innate immune response of cells to viral and bacterial pathogens (13, 14)
The current study is the first to investigate the mechanism of polyubiquitin chain formation by TRIM32 and related paralogs, using initial rates for formation of this degradation signal as a functional readout
Summary
Targeted degradation by tripartite motif (TRIM) ligase-catalyzed polyubiquitin chain formation is critical for cell regulation and innate immunity. Results: TRIM32-catalyzed chain formation requires oligomerization and uses a cooperative allosteric mechanism. Conclusion: Kinetics suggest TRIM32 assembles polyubiquitin chains as E2-linked thioesters prior to en bloc target protein transfer. The present results show that TRIM ligases catalyze polyubiquitin chain formation in the absence of substrate, the rates of which can be used as a functional readout of enzyme function. Other results suggest that TRIM32 assembles polyubiquitin chains as a Ubc5-linked thioester intermediate. These results represent the first detailed mechanistic study of TRIM ligase activity and provide a functional context for oligomerization observed in the superfamily
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