James M. Gruschus

α-Synuclein Interacts with Glucocerebrosidase Providing a Molecular Link between Parkinson and Gaucher Diseases

The presynaptic protein α-synuclein (α-syn), particularly in its amyloid form, is widely recognized for its involvement in Parkinson disease (PD). Recent genetic studies reveal that mutations in the gene GBA are the most widespread genetic risk factor for parkinsonism identified to date. GBA encodes for glucocerebrosidase (GCase), the enzyme deficient in the lysosomal storage disorder, Gaucher disease (GD). In this work, we investigated the possibility of a physical linkage between α-syn and GCase, examining both wild type and the GD-related N370S mutant enzyme. Using fluorescence and nuclear magnetic resonance spectroscopy, we determined that α-syn and GCase interact selectively under lysosomal solution conditions (pH 5.5) and mapped the interaction site to the α-syn C-terminal residues, 118–137. This α-syn-GCase complex does not form at pH 7.4 and is stabilized by electrostatics, with dissociation constants ranging from 1.2 to 22 μm in the presence of 25 to 100 mm NaCl. Intriguingly, the N370S mutant form of GCase has a reduced affinity for α-syn, as does the inhibitor conduritol-β-epoxide-bound enzyme. Immunoprecipitation and immunofluorescence studies verified this interaction in human tissue and neuronal cell culture, respectively. Although our data do not preclude protein-protein interactions in other cellular milieux, we suggest that the α-syn-GCase association is favored in the lysosome, and that this noncovalent interaction provides the groundwork to explore molecular mechanisms linking PD with mutant GBA alleles.

Autoinhibition of Arf GTPase-activating Protein Activity by the BAR Domain in ASAP1

ASAP1 is an Arf GTPase-activating protein (GAP) that functions on membrane surfaces to catalyze the hydrolysis of GTP bound to Arf. ASAP1 contains a tandem of BAR, pleckstrin homology (PH), and Arf GAP domains and contributes to the formation of invadopodia and podosomes. The PH domain interacts with the catalytic domain influencing both the catalytic and Michaelis constants. Tandem BAR-PH domains have been found to fold into a functional unit. The results of sedimentation velocity studies were consistent with predictions from homology models in which the BAR and PH domains of ASAP1 fold together. We set out to test the hypothesis that the BAR domain of ASAP1 affects GAP activity by interacting with the PH and/or Arf GAP domains. Recombinant proteins composed of the BAR, PH, Arf GAP, and Ankyrin repeat domains (called BAR-PZA) and the PH, Arf GAP, and Ankyrin repeat domains (PZA) were compared. Catalytic power for the two proteins was determined using large unilamellar vesicles as a reaction surface. The catalytic power of PZA was greater than that of BAR-PZA. The effect of the BAR domain was dependent on the N-terminal loop of the BAR domain and was not the consequence of differential membrane association or changes in large unilamellar vesicle curvature. The Km for BAR-PZA was greater and the kcat was smaller than for PZA determined by saturation kinetics. Analysis of single turnover kinetics revealed a transition state intermediate that was affected by the BAR domain. We conclude that BAR domains can affect enzymatic activity through intraprotein interactions.

Modifications to the C-terminus of Arf1 alter cell functions and protein interactions.

Arf family proteins are ≈21‐kDa GTP‐binding proteins that are critical regulators of membrane traffic and the actin cytoskeleton. Studies examining the complex signaling pathways underlying Arf action have relied on recombinant proteins comprised of Arf fused to epitope tags or proteins, such as glutathione S‐transferase or green fluorescent protein, for both cell‐based mammalian cell studies and bacterially expressed recombinant proteins for biochemical assays. However, the effects of such protein fusions on the biochemical properties relevant to the cellular function have been only incompletely studied at best. Here, we have characterized the effect of C‐terminal tagging of Arf1 on (i) function in Saccharomyces cerevisiae, (ii) in vitro nucleotide exchange and (iii) interaction with guanine nucleotide exchange factors and GTPase‐activating proteins. We found that the tagged Arfs were substantially impaired or altered in each assay, compared with the wild‐type protein, and these changes are certain to alter actions in cells. We discuss the results related to the interpretation of experiments using these reagents and we propose that authors and editors consistently adopt a few simple rules for describing and discussing results obtained with Arf family members that can be readily applied to other proteins.

Site-directed Mutations in the vnd/NK-2 Homeodomain BASIS OF VARIATIONS IN STRUCTURE AND SEQUENCE-SPECIFIC DNA BINDING

Secondary structures, DNA binding properties, and thermal denaturation behavior of six site-directed mutant homeodomains encoded by the vnd/NK-2 gene from Drosophila melanogaster are described. Three single site H52R, Y54M, and T56W mutations, two double site H52R/T56W and Y54M/T56W mutations, and one triple site H52R/Y54M/T56W mutation were investigated. These positions were chosen based on their variability across homeodomains displaying differences in secondary structure and DNA binding specificity. Multidimensional NMR, electrophoretic mobility shift assays, and circular dichroism spectropolarimetry studies were carried out on recombinant 80-amino acid residue proteins containing the homeodomain. Position 56, but more importantly position 56 in combination with position 52, plays an important role in determining the length of the recognition helix. The H52R mutation alone does not affect the length of this helix but does increase the thermal stability. Introduction of site mutations at positions 52 and 56 in vnd/NK-2 does not modify their high affinity binding to the 18-base pair DNA fragment containing the vnd/NK-2 consensus binding sequence, CAAGTG. Site mutations involving position 54 (Y54M, Y54M/T56W, and H52R/Y54M/T56W) all show a decrease of 1 order of magnitude in their binding affinity. The roles in structure and sequence specificity of individual atom-atom interactions are described.

Characterization of the N-terminal Tail Domain of Histone H3 in Condensed Nucleosome Arrays by Hydrogen Exchange and NMR

The N-terminal tail domains (NTDs) of histones play important roles in the formation of higher-order structures of chromatin and the regulation of gene functions. Although the structure of the nucleosome core particle has been determined by X-ray crystallography at near-atomic resolution, the histone tails are not observed in this structure. Here, we demonstrate that large quantities of nucleosome arrays with well-defined DNA positioning can be reconstituted using specific DNA sequences and recombinant isotope-labeled histones, allowing for the investigation of NTD conformations by amide hydrogen exchange and multidimensional nuclear magnetic resonance (NMR) methods. We examined the NTD of Drosophila melanogaster histones H3 in condensed nucleosome arrays. The results reveal that the majority of the amide protons in the NTD of H3 are protected from exchange, consistent with the NTDs having formed folded structures. Our study demonstrates hydrogen exchange coupled with NMR can provide residue-by-residue characterization of NTDs of histones in condensed nucleosome arrays, a technique that may be used to study NTDs of other histones and those with post-translational modifications.

Histone H4 K16Q mutation, an acetylation mimic, causes structural disorder of its N-terminal basic patch in the nucleosome

Histone tails and their posttranslational modifications play important roles in regulating the structure and dynamics of chromatin. For histone H4, the basic patch K(16)R(17)H(18)R(19) in the N-terminal tail modulates chromatin compaction and nucleosome sliding catalyzed by ATP-dependent ISWI chromatin remodeling enzymes while acetylation of H4 K16 affects both functions. The structural basis for the effects of this acetylation is unknown. Here, we investigated the conformation of histone tails in the nucleosome by solution NMR. We found that backbone amides of the N-terminal tails of histones H2A, H2B, and H3 are largely observable due to their conformational disorder. However, only residues 1-15 in H4 can be detected, indicating that residues 16-22 in the tails of both H4 histones fold onto the nucleosome core. Surprisingly, we found that K16Q mutation in H4, a mimic of K16 acetylation, leads to a structural disorder of the basic patch. Thus, our study suggests that the folded structure of the H4 basic patch in the nucleosome is important for chromatin compaction and nucleosome remodeling by ISWI enzymes while K16 acetylation affects both functions by causing structural disorder of the basic patch K(16)R(17)H(18)R(19).

Mutations that affect the ability of the vnd/NK-2 homeoprotein to regulate gene expression: Transgenic alterations and tertiary structure

The importance in downstream target regulation of tertiary structure and DNA binding specificity of the protein encoded by the vnd/NK-2 homeobox gene is analyzed. The ectopic expression patterns of WT and four mutant vnd/NK-2 genes are analyzed together with expression of two downstream target genes, ind and msh, which are down-regulated by vnd/NK-2. Three mutants are deletions of conserved regions (i.e., tinman motif, acidic motif, and NK-2 box), and the fourth, Y54M vnd/NK-2, corresponds to a single amino acid residue replacement in the homeodomain. Of the four ectopically expressed mutant genes examined, only the Y54M mutation inactivates the ability of the vnd/NK-2 homeodomain protein to repress ind and msh. The acidic motif deletion mutant slightly reduced the ability of the protein to repress ind and msh. By contrast, both tinman and NK-2 box deletion mutants behaved as functional vnd/NK-2 genes in their ability to repress ind and msh. The NMR-determined tertiary structures of the Y54M vnd/NK-2 homeodomain, both free and bound to DNA, are compared with the WT analog. The only structural difference observed for the mutant homeodomain is in the complex with DNA and involved closer interaction of the methionine-54 with A2, rather than with C3 of the (−) strand of the DNA. This subtle change in the homeodomain–DNA complex resulted in modifications of binding affinities to DNA. These changes resulting from a single amino acid residue replacement constitute the molecular basis for the phenotypic alterations observed on ectopic expression of the Y54M vnd/NK-2 gene during embryogenesis.

The pleckstrin homology (PH) domain of the Arf exchange factor Brag2 is an allosteric binding site.

Background: Brag2 is a PH domain-containing Arf guanine nucleotide exchange factor (GEF) that regulates cell adhesion. Results: PIP2 association with the PH domain stimulated Brag2 activity. Regulation was dependent on the N terminus of Arf and independent of the N-terminal myristate. Conclusion: PIP2 binding to the PH domain allosterically modifies Brag2 activity. Significance: A novel regulatory mechanism for GEFs was identified. Brag2, a Sec7 domain (sec7d)-containing guanine nucleotide exchange factor, regulates cell adhesion and tumor cell invasion. Brag2 catalyzes nucleotide exchange, converting Arf·GDP to Arf·GTP. Brag2 contains a pleckstrin homology (PH) domain, and its nucleotide exchange activity is stimulated by phosphatidylinositol 4,5-bisphosphate (PIP2). Here we determined kinetic parameters for Brag2 and examined the basis for regulation by phosphoinositides. Using myristoylated Arf1·GDP as a substrate, the kcat was 1.8 ± 0.1/s as determined by single turnover kinetics, and the Km was 0.20 ± 0.07 μm as determined by substrate saturation kinetics. PIP2 decreased the Km and increased the kcat of the reaction. The effect of PIP2 required the PH domain of Brag2 and the N terminus of Arf and was largely independent of Arf myristoylation. Structural analysis indicated that the linker between the sec7d and the PH domain in Brag2 may directly contact Arf. In support, we found that a Brag2 fragment containing the sec7d and the linker was more active than sec7d alone. We conclude that Brag2 is allosterically regulated by PIP2 binding to the PH domain and that activity depends on the interdomain linker. Thus, the PH domain and the interdomain linker of Brag2 may be targets for selectively regulating the activity of Brag2.

A Low pKa Cysteine at the Active Site of Mouse Methionine Sulfoxide Reductase A

Background: The active site cysteine of methionine sulfoxide reductases has been reported to be 9.5. Results: The pKa of methionine sulfoxide reductase is 7.2. Conclusion: Methionine sulfoxide reductase has an active cysteine at its catalytic center. Significance: Methionine sulfoxide reductase is readily oxidized by low concentrations of hydrogen peroxide, supporting both antioxidant and redox signaling functions of the enzyme. Methionine sulfoxide reductase A is an essential enzyme in the antioxidant system which scavenges reactive oxygen species through cyclic oxidation and reduction of methionine and methionine sulfoxide. Recently it has also been shown to catalyze the reverse reaction, oxidizing methionine residues to methionine sulfoxide. A cysteine at the active site of the enzyme is essential for both reductase and oxidase activities. This cysteine has been reported to have a pKa of 9.5 in the absence of substrate, decreasing to 5.7 upon binding of substrate. Using three independent methods, we show that the pKa of the active site cysteine of mouse methionine sulfoxide reductase is 7.2 even in the absence of substrate. The primary mechanism by which the pKa is lowered is hydrogen bonding of the active site Cys-72 to protonated Glu-115. The low pKa renders the active site cysteine susceptible to oxidation to sulfenic acid by micromolar concentrations of hydrogen peroxide. This characteristic supports a role for methionine sulfoxide reductase in redox signaling.

NMR Structure of Calmodulin Complexed to an N-Terminally Acetylated α-Synuclein Peptide

Calmodulin (CaM) is a calcium binding protein that plays numerous roles in Ca-dependent cellular processes, including uptake and release of neurotransmitters in neurons. α-Synuclein (α-syn), one of the most abundant proteins in central nervous system neurons, helps maintain presynaptic vesicles containing neurotransmitters and moderates their Ca-dependent release into the synapse. Ca-Bound CaM interacts with α-syn most strongly at its N-terminus. The N-terminal region of α-syn is important for membrane binding; thus, CaM could modulate membrane association of α-syn in a Ca-dependent manner. In contrast, Ca-free CaM has negligible interaction. The interaction with CaM leads to significant signal broadening in both CaM and α-syn NMR spectra, most likely due to conformational exchange. The broadening is much reduced when binding a peptide consisting of the first 19 residues of α-syn. In neurons, most α-syn is acetylated at the N-terminus, and acetylation leads to a 10-fold increase in binding strength for the α-syn peptide (KD = 35 ± 10 μM). The N-terminally acetylated peptide adopts a helical structure at the N-terminus with the acetyl group contacting the N-terminal domain of CaM and with less ordered helical structure toward the C-terminus of the peptide contacting the CaM C-terminal domain. Comparison with known structures shows that the CaM/α-syn complex most closely resembles Ca-bound CaM in a complex with an IQ motif peptide. However, a search comparing the α-syn peptide sequence with known CaM targets, including IQ motifs, found no homologies; thus, the N-terminal α-syn CaM binding site appears to be a novel CaM target sequence.