One-Pot, Photocontrolled Enzymatic Assembly of the Structure-Defined Heterotypic Polyubiquitin Chain

Emerging tools and methods to study cell signalling mediated by branched ubiquitin chains

Branched ubiquitin chains are complex molecular structures in which two or more ubiquitin moieties are attached to distinct lysine residues of a single ubiquitin molecule within a polyubiquitin chain. These bifurcated architectures significantly expand the signalling capacity of the ubiquitin system. Although branched chains constitute a substantial fraction of cellular polyubiquitin, their biological functions largely remain enigmatic due to their complex nature and the associated technical challenges of studying them. Recent technological innovations have enabled the identification of key molecular players and revealed essential roles for branched chains in diverse cellular processes. In this review, we discuss the bespoke strategies that have driven these discoveries, as well as the technologies needed to advance this rapidly evolving field.

Convergent Assembly of Homo- and Heterotypic Ubiquitin Chains from Functionalized, Expressed Monomers via Thiol-Ene Chemistry

Nature constructs ubiquitin tags with high spatiotemporal precision to execute defined functions that critically rely on the exact molecular composition of the ubiquitin chain. Deciphering the complex ubiquitin code is of paramount interest in biology and requires flexible access to homogeneous ubiquitin tags. As enzymatic approaches suffer from inherent drawbacks such as hardly controllable chain length or connectivity and substrate-specificity, we apply a combination of expression and chemical tools to assemble ubiquitin chains. Our strategy includes expression of ubiquitin-intein fusion constructs to obtain large quantities of defined ubiquitin monomers with C-terminal modifications such as hydrazides and propargylamides. Linkages between ubiquitins are generated via photoinitiated thiol-ene click (TEC) chemistry, resulting in a nearly native isopeptide bond. We demonstrate the generation of homo- and heterotypic ubiquitin oligomers with K27, 29, 48, and 63 linkages up to a K48-linked tetramer. The presented toolbox allows selective installation of ubiquitin on target peptides and proteins with reactive cysteine residues as demonstrated for segments of the microtubule-associated protein tau. Such segments can be implemented into protein semisyntheses as shown here for ubiquitylated full-length Tau4. The presented work combines minimal synthetic effort with high fidelity linkage chemistry, paving the way toward homogeneously ubiquitylated proteins.

Chemical Diversification of Enzymatically Assembled Polyubiquitin Chains to Decipher the Ubiquitin Codes Programmed on the Branch Structure

The multimerization of ubiquitins at different positions of lysine residues to form heterotypic polyubiquitin chains is a post-translational modification that is essential for the precise regulation of protein functions and degradative fates in living cells. The understanding of structure-activity relationships underlying their diverse properties has been seriously impeded by difficulties in the preparation of a series of folded heterotypic chains appropriately functionalized with different chemical tags for the systematic evaluation of their multifaceted functions. Here, we report a chemical diversification of enzymatically assembled polyubiquitin chains that enables the facile preparation of folded heterotypic chains with different functionalities. By introducing an acyl hydrazide at the C terminus of the proximal ubiquitin, polyubiquitin chains were readily diversified from the same starting materials with a variety of molecules, ranging from small molecules to biopolymers, under nondenaturing conditions. This chemical diversification allowed the systematic study of the functional differences of K63/K48 heterotypic chains based on the position of the branch point during enzymatic deubiquitination and proteasomal proteolysis, thus demonstrating critical roles of the branch position in both the positive and negative control of ubiquitin-mediated reactions. The chemical diversification of the heterotypic chains provides a robust chemical platform to reframe the understanding of how the ubiquitin codes are regulated from the viewpoint of the branch structure for the precise control of cell functions, which has not been deciphered solely on the basis of the linkage types.

Decoding Chromatin Ubiquitylation: A Chemical Biology Perspective

Since Strahl and Allis proposed the "language of covalent histone modifications", a host of experimental studies have shed light on the different facets of chromatin regulation by epigenetic mechanisms. Initially proposed as a concept for controlling gene transcription, the regulation of deposition and removal of histone post-translational modifications (PTMs), such as acetylation, methylation, and phosphorylation, have been implicated in many chromatin regulation pathways. However, large PTMs such as ubiquitylation challenge research on many levels due to their chemical complexity. In recent years, chemical tools have been developed to generate chromatin in defined ubiquitylation states in vitro. Chemical biology approaches are now used to link specific histone ubiquitylation marks with downstream chromatin regulation events on the molecular level. Here, we want to highlight how chemical biology approaches have empowered the mechanistic study of chromatin ubiquitylation in the context of gene regulation and DNA repair with attention to future challenges.

Biocompatible Lysine Protecting Groups for the Chemoenzymatic Synthesis of K48/K63 Heterotypic and Branched Ubiquitin Chains

The elucidation of emerging biological functions of heterotypic and branched ubiquitin (Ub) chains requires new strategies for their preparation with defined lengths and connectivity. While in vitro enzymatic assembly using expressed E1-activating and E2-conjugating enzymes can deliver homotypic chains, the synthesis of branched chains typically requires extensive mutations of lysines or other sequence modifications. The combination of K48- and K63-biased E2-conjugating enzymes and two new carbamate protecting groups-pyridoxal 5'-phosphate (PLP)-cleavable aminobutanamide carbamate (Abac group) and periodate-cleavable aminobutanol carbamate (Aboc group)-provides a strategy for the synthesis of heterotypic and branched Ub trimers, tetramers, and pentamers. The Abac- and Aboc-protected lysines are readily prepared and incorporated into synthetic ubiquitin monomers. As these masking groups contain a basic amine, they preserve the overall charge and properties of the Ub structure, facilitating folding and enzymatic conjugations. These protecting groups can be chemoselectively removed from folded Ub chains and monomers by buffered solutions of PLP or NaIO4. Through the incorporation of a cleavable C-terminal His-tag on the Ub acceptor, the entire process of chain building, iterative Abac deprotections, and global Aboc cleavage can be conducted on a resin support, obviating the need for handling and purification of the intermediate oligomers. Simple modulation of the Ub monomers affords various K48/K63 branched chains, including tetramers and pentamers not previously accessible by synthetic or biochemical methods.