Structural Biology: Parkin’s Serpentine Shape Revealed in the Year of the Snake

SummaryParkin is an E3 ubiquitin ligase, mutations in which are responsible for autosomal recessive juvenile parkinsonism. Recently, several structures of Parkin have been solved, revealing its serpentine shape and modes of auto-inhibition

RING-type E3 ligases: Master manipulators of E2 ubiquitin-conjugating enzymes and ubiquitination

AbstractRING finger domain and RING finger-like ubiquitin ligases (E3s), such as U-box proteins, constitute the vast majority of known E3s. RING-type E3s function together with ubiquitin-conjugating enzymes (E2s) to mediate ubiquitination and are implicated in numerous cellular processes. In part because of their importance in human physiology and disease, these proteins and their cellular functions represent an intense area of study. Here we review recent advances in RING-type E3 recognition of substrates, their cellular regulation, and their varied architecture. Additionally, recent structural insights into RING-type E3 function, with a focus on important interactions with E2s and ubiquitin, are reviewed. This article is part of a Special Issue entitled: Ubiquitin–Proteasome System. Guest Editors: Thomas Sommer and Dieter H. Wolf

Gcn4-Mediator Specificity Is Mediated by a Large and Dynamic Fuzzy Protein-Protein Complex.

Transcription activation domains (ADs) are inherently disordered proteins that often target multiple coactivator complexes, but the specificity of these interactions is not understood. Efficient transcription activation by yeast Gcn4 requires its tandem ADs and four activator-binding domains (ABDs) on its target, the Mediator subunit Med15. Multiple ABDs are a common feature of coactivator complexes. We find that the large Gcn4-Med15 complex is heterogeneous and contains nearly all possible AD-ABD interactions. Gcn4-Med15 forms via a dynamic fuzzy protein-protein interface, where ADs bind the ABDs in multiple orientations via hydrophobic regions that gain helicity. This combinatorial mechanism allows individual low-affinity and specificity interactions to generate a biologically functional, specific, and higher affinity complex despite lacking a defined protein-protein interface. This binding strategy is likely representative of many activators that target multiple coactivators, as it allows great flexibility in combinations of activators that can cooperate to regulate genes with variable coactivator requirements

Molecular insights into RBR E3 ligase ubiquitin transfer mechanisms

National Institute of General Medical Sciences R01 GM0880555T32 GM007270, Francis Crick Institute FCI01, Cancer Research UK, Medical Research Council U117565398, Wellcome Trus

Recognition of Antimicrobial Peptides by a Bacterial Sensor Kinase

SummaryPhoQ is a membrane bound sensor kinase important for the pathogenesis of a number of Gram-negative bacterial species. PhoQ and its cognate response regulator PhoP constitute a signal-transduction cascade that controls inducible resistance to host antimicrobial peptides. We show that enzymatic activity of Salmonella typhimurium PhoQ is directly activated by antimicrobial peptides. A highly acidic surface of the PhoQ sensor domain participates in both divalent-cation and antimicrobial-peptide binding as a first step in signal transduction across the bacterial membrane. Identification of PhoQ signaling mutants, binding studies with the PhoQ sensor domain, and structural analysis of this domain can be incorporated into a model in which antimicrobial peptides displace divalent cations from PhoQ metal binding sites to initiate signal transduction. Our findings reveal a molecular mechanism by which bacteria sense small innate immune molecules to initiate a transcriptional program that promotes bacterial virulence

Following Ariadne's thread: a new perspective on RBR ubiquitin ligases

Ubiquitin signaling pathways rely on E3 ligases for effecting the final transfer of ubiquitin from E2 ubiquitin conjugating enzymes to a protein target. Here we re-evaluate the hybrid RING/HECT mechanism used by the E3 family RING-between-RINGs (RBRs) to transfer ubiquitin to substrates. We place RBRs into the context of current knowledge of HECT and RING E3s. Although not as abundant as the other types of E3s (there are only slightly more than a dozen RBR E3s in the human genome), RBRs are conserved in all eukaryotes and play important roles in biology. Re-evaluation of RBR ligases as RING/HECT E3s provokes new questions and challenges the field

ADRla, a zinc finger peptide, exists in two folded conformations

Two-dimensional N MR (2DNMR) studies of several different zinc finger peptides have yielded a picture of the three-dimensional structure of this small DNA-binding motif. Details of the differences among fingers with different sequences may provide some insight into how these domains interact with DNA. Toward this end, we have reanalyzed the 2DNMR spectra of the C-terminal zinc finger sequence from the yeast transcriptional factor ADRl. Although this was the sequence on which our original report describing the overall fold of zinc fingers was based, complete spectral assignments (reported here) were needed to compare this sequence in detail with that of ADRlb, for which we have reported an atomic level structure. In the process of analyzing the spectra of ADRla and a mutant of ADRla, it was noted that the peptides give two sets of NMR lines, indicating that this sequence, unlike the other ADRl zinc finger sequence, exists in two slowly interconverting folded conformations in solution. Residues that exhibit peak doubling are located in the Cys loop, the a-helix, and the extreme C-terminus of the peptide. Differences in NOES observed for the two forms indicate that there are detectable conformational differences in the Zn^(2+) cluster and in the fingertip region. This conformational flexibility, which has not been observed for other zinc finger peptides, may stem from the presence of an additional residue between the histidine ligands (His-X_4-His versus His-X_3-His)