Mutations in the park2 gene, encoding the RING-inBetweenRING-RING E3 ubiquitin ligase parkin, cause 50% of autosomal recessive juvenile Parkinsonism cases. More than 70 known pathogenic mutations occur throughout parkin, many of which cluster in the inhibitory amino-terminal ubiquitin-like domain, and the carboxy-terminal RING2 domain that is indispensable for ubiquitin transfer. A structural rationale showing how autosomal recessive juvenile Parkinsonism mutations alter parkin function is still lacking. Here we show that the structure of parkin RING2 is distinct from canonical RING E3 ligases and lacks key elements required for E2-conjugating enzyme recruitment. Several pathogenic mutations in RING2 alter the environment of a single surface-exposed catalytic cysteine to inhibit ubiquitination. Native parkin adopts a globular inhibited conformation in solution facilitated by the association of the ubiquitin-like domain with the RING-inBetweenRING-RING C-terminus. Autosomal recessive juvenile Parkinsonism mutations disrupt this conformation. Finally, parkin autoubiquitinates only in cis, providing a molecular explanation for the recessive nature of autosomal recessive juvenile Parkinsonism. Mutations in the E3 ubiquitin ligase parkin are associated with juvenile Parkinson’s disease. Here the authors report the solution structure of the Parkin RING2 domain, revealing how disease-associated mutations affect its function and providing a molecular explanation for the recessive nature of the disease.
Abstract The PARK 2 gene is mutated in 50% of autosomal recessive juvenile parkinsonism ( ARJP ) cases. It encodes parkin, an E3 ubiquitin ligase of the RBR family. Parkin exists in an autoinhibited state that is activated by phosphorylation of its N‐terminal ubiquitin‐like (Ubl) domain and binding of phosphoubiquitin. We describe the 1.8 Å crystal structure of human parkin in its fully inhibited state and identify the key interfaces to maintain parkin inhibition. We identify the phosphoubiquitin‐binding interface, provide a model for the phosphoubiquitin–parkin complex and show how phosphorylation of the Ubl domain primes parkin for optimal phosphoubiquitin binding. Furthermore, we demonstrate that the addition of phosphoubiquitin leads to displacement of the Ubl domain through loss of structure, unveiling a ubiquitin‐binding site used by the E2~Ub conjugate, thus leading to active parkin. We find the role of the Ubl domain is to prevent parkin activity in the absence of the phosphorylation signals, and propose a model for parkin inhibition, optimization for phosphoubiquitin recruitment, release of inhibition by the Ubl domain and engagement with an E2~Ub conjugate. Taken together, this model provides a mechanistic framework for activating parkin.
SUMMARY The mechanisms by which Parkinson disease-linked parkin confers neuroprotection of human dopamine cells remain elusive. We hypothesized that its cysteines mediate multiple anti-oxidant effects in the midbrain. By studying >60 control specimens, we found that in adult human brain - but not in skeletal muscle- parkin is mostly aggregated and insoluble due to oxidative modifications, such as at C253. In vitro , parkin’s oxidation directly reduces hydrogen peroxide (H 2 O 2 ) to water. In parkin-deficient human brain, H 2 O 2 concentrations are elevated. In dopamine toxicity studies, wild-type parkin -but not disease-associated mutants-prevents neural death by lowering H 2 O 2 and sequestering radicals within insoluble aggregates. Parkin conjugates dopamine metabolites at the human-specific residue C95 and augments melanin formation in vitro . Using epitope-mapped antibodies, we found that in adult Substantia nigra neurons parkin localizes to neuromelanin within LAMP-3/CD63-positive lysosomes. We conclude that parkin’s own oxidation, previously considered a loss-of-function event, underlies three neuroprotective effects in adult midbrain: its cysteines participate in H 2 O 2 reduction, dopamine radical conjugation and the formation of neuromelanin.
The first wide-line 2H NMR investigation of a receptor tyrosine kinase is reported. Selectively deuterated peptides from the membrane-associated portion of the human epidermal growth factor (EGF) receptor were synthesized for examination in lipid bilayers mimicking certain natural membrane features. The peptide sequence included the 23-amino acid hydrophobic stretch thought to span the membrane (Ile622−Met644 of the EGF receptor), plus the first 10 amino acids of the receptor's cytoplasmic domain (Arg645−Thr654). Dispersion of the peptide with lipid in the lipomimetic solvent, trifluoroethanol (TFE), was found to be a very useful initial step for sample preparation. TFE readily dissolved all components and was then easily removed in vacuo to yield thin films which could be subsequently hydrated to produce bilayers incorporating homogeneously dispersed peptide. Samples extensively studied consisted of 6 mol % peptide in multilamellar liposomes of 1-palmitoyl-2-oleoylphosphatidylcholine and similar liposomes containing cholesterol. 2H NMR spectra of the resulting unsonicated model membranes indicated the existence of peptide monomers undergoing rapid axially symmetric diffusion. It was possible to examine structural and behavioral effects of events often suggested as pivotal in signaling mechanisms and to consider by wide-line NMR for the first time the effect of cholesterol on hydrophobic peptides. When it was incorporated into bilayers by an alternative method involving dialysis of aqueous solutions prepared using a cationic detergent, spectra suggested that the peptide existed primarily as irreversibly aggregated oligomers which were relatively immobile on a time scale of 10-3−10-4 s. For liposomes prepared by hydration of thin films, deuterated methyl groups on the peptide at locations corresponding to Ala623, Met644, and Val650 of the human EGF receptor were individually distinguishable. In highly fluid matrices, spectra suggested the presence of peptide monomers, diffusing symmetrically about axes perpendicular to the membrane. Studied as a function of temperature, 2H NMR spectra of such samples permitted independent consideration of membrane/peptide relationships at separate locations in the receptor tyrosine kinase. None of the locations probed demonstrated significant conformational sensitivity to temperature over a wide range. Effects seen at Ala623 and Met644, at opposite ends of the putative membrane-spanning domain, suggested slight increases in motional order with decreasing temperature. Addition of 33% cholesterol to the membrane caused little apparent conformational change at Val650 or Met644. However, in the presence of the sterol, Met644 and Ala623 exhibited nonaxially symmetric motion at low temperatures, perhaps as a result of peptide oligomerization. Moreover, the presence of cholesterol led to considerable change in spatial arrangement or order at Ala623. There was little evidence to support transmission of conformational changes along the peptide segment probed.
The dimeric calcium-binding protein S100b is proposed to undergo a calcium-induced structural change allowing it to interact, via a hydrophobic surface, with other proteins. Previously it has been suggested that calcium binding to S100b leads to the exposure of at least one phenylalanine residue (Mani et al., 1982, 1983). This effect appears to be “reversed” at higher ionic strength, leading to a possible reburying of phenylalanine residues (Mani et al., 1982, 1983). To study these effects, we monitored calcium binding to recombinant human S100b by NMR spectroscopy under different salt (KCl) conditions. 15N-Labeled glycine residues in S100b showed calcium-induced chemical shift changes similar to those reported for the related monomeric protein calbindin D9k, suggesting similar conformational changes are occurring in the calcium-binding loops of these two proteins. Calcium binding to S100b also resulted in a shifting and broadening of several 1H resonances from the Ca-S100b form only including those from the side chains of residues F14, F70, and F73 but not those of residue Y17. This broadening was enhanced with increased ionic strength (KCl). However, small additions (<15% v/v) of the hydrophobic solvent trifluoroethanol relieved this phenomenon, leading to narrower line widths. These observations are consistent with the calcium-induced exposure of at least one of these hydrophobic residues, resulting in self-association of the S100b dimer. Trifluoroethanol serves to dissociate these complexes back to the dimeric calcium species. We propose that this cluster of hydrophobic residues which include F14, F73, and F88 may be important for interactions with a target protein.
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