Christopher E. Berndsen scite author profile

E3 ligases carry out the final step in the ubiquitination cascade, catalyzing transfer of ubiquitin from an E2 enzyme to form a covalent bond with a substrate lysine. Three distinct classes of E3 ligases have been identified that stimulate transfer of ubiquitin and ubiquitin-like proteins through either a direct or an indirect mechanism. Only recently have the catalytic mechanisms of E3 ligases begun to be elucidated.

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Histone H3-K56 Acetylation Is Catalyzed by Histone Chaperone-Dependent Complexes

Tsubota

et al. 2007

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Acetylation of histone H3 on lysine 56 occurs during mitotic and meiotic S phase in fungal species. This acetylation blocks a direct electrostatic interaction between histone H3 and nucleosomal DNA, and the absence of this modification is associated with extreme sensitivity to genotoxic agents. We show here that H3-K56 acetylation is catalyzed when Rtt109, a protein that lacks significant homology to known acetyltransferases, forms an active complex with either of two histone binding proteins, Asf1 or Vps75. Rtt109 binds to both these cofactors, but not to histones alone, forming enzyme complexes with kinetic parameters similar to those of known histone acetyltransferase (HAT) enzymes. Therefore, H3-K56 acetylation is catalyzed by a previously unknown mechanism that requires a complex of two proteins: Rtt109 and a histone chaperone. Additionally, these complexes are functionally distinct, with the Rtt109/Asf1 complex, but not the Rtt109/Vps75 complex, being critical for resistance to genotoxic agents.

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Structural Insights into the Assembly and Function of the SAGA Deubiquitinating Module

Samara

Datta

Berndsen

et al. 2010

Science

200

256

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SAGA is a transcriptional coactivator complex that is conserved across eukaryotes and performs multiple functions during transcriptional activation and elongation. One role is deubiquitination of histone H2B, and this activity resides in a distinct subcomplex called the deubiquitinating module (DUBm), which contains the ubiquitin-specific protease, Ubp8, bound to Sgf11, Sus1 and Sgf73. The deubiquitinating activity depends upon the presence of all four DUBm proteins. We report here the 1.90 Å resolution crystal structure of the DUB module bound to ubiquitin aldehyde, as well as the 2.45 Å resolution structure of the uncomplexed DUB module. The structure reveals an arrangement of protein domains that gives rise to a highly interconnected complex, which is stabilized by eight structural zinc atoms that are critical for enzymatic activity. The structure suggests a model for how interactions with the other DUBm proteins activate Ubp8, and allows us to speculate about how the DUB module binds to monoubiquitinated histone H2B in nucleosomes.

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Catalysis and substrate selection by histone/protein lysine acetyltransferases

Berndsen

Denu

2008

Current Opinion in Structural Biology

196

173

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Reversible protein acetylation is controlled by the opposing actions of protein lysine acetyltransferases and deacetylations. Recent developments on the structure and biochemical mechanisms of histone acetyltransfers (HATs) have provided new insight into catalysis and substrate selection. Diverse families of HATs appear to perform a conserved mechanism of acetyl-transfer, where the lysine-containing substrate directly attacks enzyme-bound acetyl-CoA. The ability of HATs to form distinct multi-subunit complexes provide a means to regulate HAT activity by altering substrate specificity, targeting to specific loci, enhancing acetyltransferase activity, restricting access of non-target proteins, and coordinating the multiple enzyme activities of the complex. In the case of newly discovered Rtt109 HAT, association with distinct histone chaperones directs substrate selection between N-terminal lysines (H3K9, H3K23) and those (H3K56) within the histone fold domain. Moreover, the ability of some HATs to utilize longer chain acyl-CoA (i.e. propionyl-CoA) as alternative substrates suggests a potential direct link between the metabolic state of the cell and transcriptional regulation.

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RNF4-Dependent Hybrid SUMO-Ubiquitin Chains Are Signals for RAP80 and Thereby Mediate the Recruitment of BRCA1 to Sites of DNA Damage

et al. 2012

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The DNA repair function of the breast cancer susceptibility protein BRCA1 depends in part on its interaction with RAP80, which targets BRCA1 to DNA double strand breaks (DSBs) through recognition of K63-linked polyubiquitin chains. The localization of BRCA1 to DSBs also requires sumoylation. Here, we demonstrated that, in addition to having ubiquitin-interacting motifs, RAP80 also contains a SUMO-interacting motif (SIM) that is critical for recruitment to DSBs. In combination with the ubiquitin-binding activity of RAP80, this SIM enabled RAP80 to bind with nanomolar affinity to hybrid chains consisting of ubiquitin conjugated to SUMO. Furthermore, RNF4, a SUMO-targeted ubiquitin E3 ligase that synthesizes hybrid SUMO-ubiquitin chains, localized to DSBs and was critical for the recruitment of RAP80 and BRCA1 to sites of DNA damage. Our findings, therefore, connect ubiquitin-dependent and SUMO-dependent DSB recognition, revealing that RNF4 synthesized hybrid SUMO-ubiquitin chains are recognized by RAP80 to promote BRCA1 recruitment and DNA repair.

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Molecular functions of the histone acetyltransferase chaperone complex Rtt109–Vps75

Berndsen

Tsubota

Lindner

et al. 2008

Nat Struct Mol Biol

108

152

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Histone acetylation and nucleosome remodeling regulate DNA damage repair, replication and transcription. Rtt109, a recently discovered histone acetyltransferase (HAT) from Saccharomyces cerevisiae, functions with the histone chaperone Asf1 to acetylate lysine K56 on histone H3 (H3K56), a modification associated with newly synthesized histones. In vitro analysis of Rtt109 revealed that Vps75, a Nap1 family histone chaperone, could also stimulate Rtt109-dependent acetylation of H3K56. However, the molecular function of the Rtt109-Vps75 complex remains elusive. Here we have probed the molecular functions of Vps75 and the Rtt109-Vps75 complex through biochemical, structural and genetic means. We find that Vps75 stimulates the kcat of histone acetylation by ∼100-fold relative to Rtt109 alone and enhances acetylation of K9 in the H3 histone tail. Consistent with the In vitro evidence, cells lacking Vps75 showed a substantial reduction (60%) in H3K9 acetylation during S phase. X-ray structural, biochemical and genetic analyses of Vps75 indicate a unique, structurally dynamic Nap1-like fold that suggests a potential mechanism of Vps75-dependent activation of Rtt109. Together, these data provide evidence for a multifunctional HAT-chaperone complex that acetylates histone H3 and deposits H3-H4 onto DNA, linking histone modification and nucleosome assembly.

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Architectural Organization of the Metabolic Regulatory Enzyme Ghrelin O-Acyltransferase

Taylor

Ruch²,

Hsiao

et al. 2013

Journal of Biological Chemistry

120

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Background:Ghrelin O-acyltransferase (GOAT) is a membrane protein that is responsible for octanoylating the metabolism-regulating peptide hormone ghrelin. Results: We have used a combination of approaches to determine the topology of GOAT. Conclusion:We have shown that GOAT has 11 transmembrane-spanning domains and one reentrant loop. Significance: These findings serve as a reference for other membrane-bound O-acyltransferase family members.

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Trans -Binding Mechanism of Ubiquitin-like Protein Activation Revealed by a UBA5-UFM1 Complex

Oweis¹,

Padala²,

Hassouna³

et al. 2016

Cell Reports

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Modification of proteins by ubiquitin or ubiquitin-like proteins (UBLs) is a critical cellular process implicated in a variety of cellular states and outcomes. A prerequisite for target protein modification by a UBL is the activation of the latter by activating enzymes (E1s). Here, we present the crystal structure of the non-canonical homodimeric E1, UBA5, in complex with its cognate UBL, UFM1, and supporting biochemical experiments. We find that UBA5 binds to UFM1 via a trans-binding mechanism in which UFM1 interacts with distinct sites in both subunits of the UBA5 dimer. This binding mechanism requires a region C-terminal to the adenylation domain that brings UFM1 to the active site of the adjacent UBA5 subunit. We also find that transfer of UFM1 from UBA5 to the E2, UFC1, occurs via a trans mechanism, thereby requiring a homodimer of UBA5. These findings explicitly elucidate the role of UBA5 dimerization in UFM1 activation.

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