Crosstalk between Lys63- and Lys11-polyubiquitin signaling at DNA damage sites is driven by Cezanne.

The establishment of polyubiquitin conjugates with distinct linkages play important roles in the DNA damage response. Much remains unknown about the regulation of linkage-specific ubiquitin signaling at sites of DNA damage. Here we reveal that Cezanne (also known as Otud7B) deubiquitinating enzyme promotes the recruitment of Rap80/BRCA1-A complex by binding to Lys63-polyubiquitin and targeting Lys11-polyubiquitin. Using a ubiquitin binding domain protein array screen, we identify that the UBA domains of Cezanne and Cezanne2 (also known as Otud7A) selectively bind to Lys63-linked polyubiquitin. Increased Lys11-linkage ubiquitination due to lack of Cezanne DUB activity compromises the recruitment of Rap80/BRCA1-A. Cezanne2 interacts with Cezanne, facilitating Cezanne in the recruitment of Rap80/BRCA1-A, Rad18, and 53BP1, in cellular resistance to ionizing radiation and DNA repair. Our work presents a model that Cezanne serves as a "reader" of the Lys63-linkage polyubiquitin at DNA damage sites and an "eraser" of the Lys11-linkage ubiquitination, indicating a crosstalk between linkage-specific ubiquitination at DNA damage sites.

Nonenzymatic assembly of branched polyubiquitin chains for structural and biochemical studies.

Polymeric chains of a small protein ubiquitin are involved in regulation of nearly all vital processes in eukaryotic cells. Elucidating the signaling properties of polyubiquitin requires the ability to make these chains in vitro. In recent years, chemical and chemical-biology tools have been developed that produce fully natural isopeptide-linked polyUb chains with no need for linkage-specific ubiquitin-conjugating enzymes. These methods produced unbranched chains (in which no more than one lysine per ubiquitin is conjugated to another ubiquitin). Here we report a nonenzymatic method for the assembly of fully natural isopeptide-linked branched polyubiquitin chains. This method is based on the use of mutually orthogonal removable protecting groups (e.g., Boc- and Alloc-) on lysines combined with an Ag-catalyzed condensation reaction between a C-terminal thioester on one ubiquitin and a specific ε-amine on another ubiquitin, and involves genetic incorporation of more than one Lys(Boc) at the desired linkage positions in the ubiquitin sequence. We demonstrate our method by making a fully natural branched tri-ubiquitin containing isopeptide linkages via Lys11 and Lys33, and a (15)N-enriched proximal ubiquitin, which enabled monomer-specific structural and dynamical studies by NMR. Furthermore, we assayed disassembly of branched and unbranched tri-ubiquitins as well as control di-ubiquitins by the yeast proteasome-associated deubiquitinase Ubp6. Our results show that Ubp6 can recognize and disassemble a branched polyubiquitin, wherein cleavage preferences for individual linkages are retained. Our spectroscopic and functional data suggest that, at least for the chains studied here, the isopeptide linkages are effectively independent of each other. Together with our method for nonenzymatic assembly of unbranched polyubiquitin, these developments now provide tools for making fully natural polyubiquitin chains of essentially any type of linkage and length.

Preparing to read the ubiquitin code: characterization of ubiquitin trimers by top-down mass spectrometry.

The profound effects of ubiquitination on the movement and processing of cellular proteins depend exquisitely on the structures of monoubiquitin and polyubiquitin modifications. Unconjugated polyubiquitins also have a variety of intracellular functions. Structures and functions are not well correlated yet, because the structures of polyubiquitins and polyubiquitin modifications of proteins are difficult to decipher. We are moving towards a robust strategy to provide that structural information. In this report electron transfer dissociation mass spectra of six synthetic ubiquitin trimers (multiply branched proteins with molecular masses exceeding 25,600 Da) are examined using an Orbitrap Fusion Lumos instrument to determine how top-down mass spectrometry can characterize the chain topology and linkage sites in a single, facile workflow. The efficacy of this method relies on the formation, detection, and interpretation of extensive fragmentation.

Unique structural, dynamical, and functional properties of k11-linked polyubiquitin chains.

K11-linked polyubiquitin chains play important signaling and regulatory roles in both degradative and nonproteolytic 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 diubiquitin (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 nonproteasomal pathways but with intermediate affinity and different binding modes than either K48-linked or K63-linked diubiquitin. 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.

Controlled enzymatic synthesis of natural-linkage, defined-length polyubiquitin chains using lysines with removable protecting groups.

E2 enzymes catalyze the ATP-dependent polymerization of polyubiquitin chains which function as molecular signals in the regulation of numerous cellular processes. Here we present a method that uses genetically encoded unnatural amino acids to halt and re-start ubiquitin polymerization providing access to natural-linkage, precision-length ubiquitin chains that can be used for biochemical, structural, and dynamics studies.