Ataxin-3 is a multivalent ligand for the parkin Ubl domain.

The ubiquitin signaling pathway consists of hundreds of enzymes that are tightly regulated for the maintenance of cell homeostasis. Parkin is an E3 ubiquitin ligase responsible for conjugating ubiquitin onto a substrate protein, which itself can be ubiquitinated. Ataxin-3 performs the opposing function as a deubiquitinating enzyme that can remove ubiquitin from parkin. In this work, we have identified the mechanism of interaction between the ubiquitin-like (Ubl) domain from parkin and three C-terminal ubiquitin-interacting motifs (UIMs) in ataxin-3. (1)H-(15)N heteronuclear single-quantum coherence titration experiments revealed that there are weak direct interactions between all three individual UIM regions of ataxin-3 and the Ubl domain. Each UIM utilizes the exposed ß-grasp surface of the Ubl domain centered around the I44 patch that did not vary in the residues involved or the surface size as a function of the number of ataxin-3 UIMs involved. Further, the apparent dissociation constant for ataxin-3 decreased as a function of the number of UIM regions used in experiments. A global multisite fit of the nuclear magnetic resonance titration data, based on three identical binding ligands, resulted in a KD of 669 ± 62 µM for each site. Our observations support a multivalent ligand binding mechanism employed by the parkin Ubl domain to recruit multiple UIM regions in ataxin-3 and provide insight into how these two proteins function together in ubiquitination-deubiquitination pathways.

Structural insights into the anti-methicillin-resistant Staphylococcus aureus (MRSA) activity of ceftobiprole.

Methicillin-resistant Staphylococcus aureus (MRSA) is an antibiotic-resistant strain of S. aureus afflicting hospitals and communities worldwide. Of greatest concern is its development of resistance to current last-line-of-defense antibiotics; new therapeutics are urgently needed to combat this pathogen. Ceftobiprole is a recently developed, latest generation cephalosporin and has been the first to show activity against MRSA by inhibiting essential peptidoglycan transpeptidases, including the ß-lactam resistance determinant PBP2a, from MRSA. Here we present the structure of the complex of ceftobiprole bound to PBP2a. This structure provides the first look at the molecular details of an effective ß-lactam-resistant PBP interaction, leading to new insights into the mechanism of ceftobiprole efficacy against MRSA.

Structural perspective of peptidoglycan biosynthesis and assembly.

The peptidoglycan biosynthetic pathway is a critical process in the bacterial cell and is exploited as a target for the design of antibiotics. This pathway culminates in the production of the peptidoglycan layer, which is composed of polymerized glycan chains with cross-linked peptide substituents. This layer forms the major structural component of the protective barrier known as the cell wall. Disruption in the assembly of the peptidoglycan layer causes a weakened cell wall and subsequent bacterial lysis. With bacteria responsible for both properly functioning human health (probiotic strains) and potentially serious illness (pathogenic strains), a delicate balance is necessary during clinical intervention. Recent research has furthered our understanding of the precise molecular structures, mechanisms of action, and functional interactions involved in peptidoglycan biosynthesis. This research is helping guide our understanding of how to capitalize on peptidoglycan-based therapeutics and, at a more fundamental level, of the complex machinery that creates this critical barrier for bacterial survival.

Solution structure of the E3 ligase HOIL-1 Ubl domain.

The E3 ligases HOIL-1 and parkin are each comprised of an N-terminal ubiquitin-like (Ubl) domain followed by a zinc-binding region and C-terminal RING-In-between-RING-RING domains. These two proteins, involved in the ubiquitin-mediated degradation pathway, are the only two known E3 ligases to share this type of multidomain architecture. Further, the Ubl domain of both HOIL-1 and parkin has been shown to interact with the S5a subunit of the 26S proteasome. The solution structure of the HOIL-1 Ubl domain was solved using NMR spectroscopy to compare it with that of parkin to determine the structural elements responsible for S5a intermolecular interactions. The final ensemble of 20 structures had a ß-grasp Ubl-fold with an overall backbone RMSD of 0.59 ± 0.10 Å in the structured regions between I55 and L131. HOIL-1 had a unique extension of both ß1 and ß2 sheets compared to parkin and other Ubl domains, a result of a four-residue insertion in this region. A similar 15-residue hydrophobic core in the HOIL-1 Ubl domain resulted in a comparable stability to the parkin Ubl, but significantly lower than that observed for ubiquitin. A comparison with parkin and other Ubl domains indicates that HOIL-1 likely uses a conserved hydrophobic patch (W58, V102, Y127, Y129) found on the ß1 face, the ß3-ß4 loop and ß5, as well as a C-terminal basic residue (R134) to recruit the S5a subunit as part of the ubiquitin-mediated proteolysis pathway.

Impact of autosomal recessive juvenile Parkinson's disease mutations on the structure and interactions of the parkin ubiquitin-like domain.

Autosomal recessive juvenile parkinsonism (ARJP) is an early onset familial form of Parkinson's disease. Approximately 50% of all ARJP cases are attributed to mutations in the gene park2, coding for the protein parkin. Parkin is a multidomain E3 ubiquitin ligase with six distinct domains including an N-terminal ubiquitin-like (Ubl) domain. In this work we examined the structure, stability, and interactions of the parkin Ubl domain containing most ARJP causative mutations. Using NMR spectroscopy we show that the Ubl domain proteins containing the ARJP substitutions G12R, D18N, K32T, R33Q, P37L, and K48A retained a similar three-dimensional fold as the Ubl domain, while at least one other (V15M) had altered packing. Four substitutions (A31D, R42P, A46P, and V56E) result in poor folding of the domain, while one protein (T55I) showed evidence of heterogeneity and aggregation. Further, of the substitutions that maintained their three-dimensional fold, we found that four of these (V15M, K32T, R33Q, and P37L) lead to impaired function due to decreased ability to interact with the 19S regulatory subunit S5a. Three substitutions (G12R, D18N, and Q34R) with an uncertain role in the disease did not alter the three-dimensional fold or S5a interaction. This work provides the first extensive characterization of the structural effects of causative mutations within the ubiquitin-like domain in ARJP.

Differential interaction of the E3 ligase parkin with the proteasomal subunit S5a and the endocytic protein Eps15.

Parkin is a multidomain E3 ligase associated with autosomal recessive Parkinson disease. The N-terminal ubiquitin-like domain (Ubld) of parkin functions with the S5a proteasomal subunit, positioning substrate proteins for degradation. In addition the parkin Ubld recruits the endocytotic protein Eps15, allowing the E3 ligase to ubiquinate Eps15 distal from its parkin-interacting site. The recognition sequences in the S5a subunit and Eps15 for the parkin Ubld are ubiquitin-interacting motifs (UIM). Each protein has two UIM sequences separated by a 50-residue spacer in S5a, but only approximately 5 residues in Eps15. In this work we used NMR spectroscopy to determine how the parkin Ubld recognizes the proteasomal subunit S5a compared with Eps15, a substrate for ubiquitination. We show that Eps15 contains two flexible alpha-helices each encompassing a UIM sequence. The alpha-helix surrounding UIM II is longer than that for UIM I, a situation that is reversed from S5a. Furthermore, we show the parkin Ubld preferentially binds to UIM I in the S5a subunit. This interaction is strongly diminished in a K48A substitution, found near the center of the S5a interacting surface on the parkin Ubld. In contrast to S5a, parkin recruits Eps15 using both its UIM sequences resulting in a larger interaction surface that includes residues from beta1 and beta2, not typically known to interact with UIM sequences. These results show that the parkin Ubld uses differential surfaces to recruit UIM regions from the S5a proteasomal subunit compared with Eps15 involved in cell signaling.

A disease state mutation unfolds the parkin ubiquitin-like domain.

E3 ubiquitin ligases are essential enzymes in the ubiquitination pathway responsible for the recognition of specific E2 conjugating enzymes and for transferring ubiquitin to a substrate targeted for degradation. In autosomal recessive juvenile Parkinson's disease, an early onset form of Parkinson's disease, point mutations in the E3 ligase parkin are one of the most commonly observed traits. Parkin is a multidomain E3 ligase that contains an N-terminal ubiquitin-like domain that interacts with, and effects the ubiquitination of, substrates such as cyclin E, p38 and synphilin. In this work we have examined the folding and structure of the parkin ubiquitin-like domain (Ubld) and of the protein with two causative disease mutations (K48A and R42P). Parallel experiments with the protein ubiquitin were done in order to determine if the same mutations were detrimental to the ubiquitin structure and stability. Despite similar folds between the parkin Ubld and ubiquitin, urea unfolding experiments show that the parkin Ubld is surprisingly approximately 10.6 kJ/mol less stable than ubiquitin. The K48A mutation had little effect on the stability of the parkin Ubld or ubiquitin indicating that this mutation contributes to defective protein-protein interactions. In contrast, the single point mutation R42P in parkin's Ubld caused poor expression and degradation of the protein. To avoid these problems, a GB1-Ubld fusion protein was characterized by NMR spectroscopy to show that the R42P mutation causes the complete unfolding of the parkin Ubld. This observation provides a rationale for the more rapid degradation of parkin carrying the R42P mutation in vivo, and its inability to interact with some substrate proteins. Our work provides the first structural and folding insight into the effects of causative mutations within the ubiquitin-like domain in autosomal recessive juvenile Parkinson's disease.