Summary Research on ubiquitin (Ub) signaling has focused primarily on homogeneously-linked polyUb. Although polyUb containing different linkages within the same chain exist, their structures and signaling properties are unknown. These mixed-linkage chains could be unbranched (i.e., no more than one lysine- or methionine-linkage per Ub) or branched. Here we examined the structure, dynamics, receptor selectivity, and disasssembly of branched and unbranched tri-Ub containing both K48 and K63-linkages. Each linkage was virtually indistinguishable from its counterpart in homogeneously-linked polyUb. Linkage-selective receptors from hHR23A and Rap80 preferentially bound to the K48- or K63-linkages in the branched trimer. Linkage-selective deubiquitinases specifically cleaved their cognate Ub-Ub linkages in mixed-linkage chains, and the 26S proteasome recognized and processed branched tri-Ub. We conclude that mixed-linkage chains retain the distinctive signaling properties of their K48- and K63-components, and that these multiple signals can be recognized by multiple linkage-specific receptors. Finally, we propose a new, comprehensive notation for Ub and Ub-like polymers.
Cellular cross-talk between ubiquitination and other posttranslational modifications contributes to the regulation of numerous processes. One example is ADP-ribosylation of the carboxyl terminus of ubiquitin by the E3 DTX3L/ADP-ribosyltransferase PARP9 heterodimer, but the mechanism remains elusive. Here, we show that independently of PARP9, the conserved carboxyl-terminal RING and DTC (Deltex carboxyl-terminal) domains of DTX3L and other human Deltex proteins (DTX1 to DTX4) catalyze ADP-ribosylation of ubiquitin’s Gly76. Structural studies reveal a hitherto unknown function of the DTC domain in binding NAD+. Deltex RING domain recruits E2 thioesterified with ubiquitin and juxtaposes it with NAD+ bound to the DTC domain to facilitate ADP-ribosylation of ubiquitin. This ubiquitin modification prevents its activation but is reversed by the linkage nonspecific deubiquitinases. Our study provides mechanistic insights into ADP-ribosylation of ubiquitin by Deltex E3s and will enable future studies directed at understanding the increasingly complex network of ubiquitin cross-talk.
Summary K11-linked polyubiquitin chains play important signaling and regulatory roles in both degradative and non-proteolytic pathways in eukaryotes. To understand the structural basis of how these chains are recognized and distinguished from other polyubiquitins, we determined solution structures of K11-linked di-ubiquitin (K11-Ub2) in the absence and presence of salt. These structures reveal that K11-Ub2 adopts conformations distinct from those of K48-linked or K63-linked chains. Importantly, our solution NMR and SANS data are inconsistent with published crystal structures of K11-Ub2. We found that increasing salt concentration compacts K11-Ub2 and strengthens interactions between the two Ub units. Binding studies indicate that K11-Ub2 interacts with ubiquitin-receptor proteins from both proteasomal and non-proteasomal pathways, but with intermediate affinity and different binding modes than either K48-linked or K63-linked di-ubiquitin. Our data support the hypothesis that polyubiquitin chains of different linkages possess unique conformational and dynamical properties allowing them to be recognized differently by downstream receptor proteins.
SummaryRING and U-box E3 ubiquitin ligases regulate diverse eukaryotic processes and have been implicated in numerous diseases, but targeting these enzymes remains a major challenge. We report the development of three ubiquitin variants (UbVs), each binding selectively to the RING or U-box domain of a distinct E3 ligase: monomeric UBE4B, phosphorylated active CBL, or dimeric XIAP. Structural and biochemical analyses revealed that UbVs specifically inhibited the activity of UBE4B or phosphorylated CBL by blocking the E2∼Ub binding site. Surprisingly, the UbV selective for dimeric XIAP formed a dimer to stimulate E3 activity by stabilizing the closed E2∼Ub conformation. We further verified the inhibitory and stimulatory functions of UbVs in cells. Our work provides a general strategy to inhibit or activate RING/U-box E3 ligases and provides a resource for the research community to modulate these enzymes.
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