Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disorder selectively affecting motor neurons; 90% of the total cases are sporadic, but 2% are associated with mutations in the gene coding for the antioxidant enzyme copper-zinc superoxide dismutase (SOD1). The causes of motor neuron death in ALS are poorly understood in general, but for SOD1-linked familial ALS, aberrant oligomerization of SOD1 mutant proteins has been strongly implicated. In this work, we show that wild-type human SOD1, when lacking both its metal ions, forms large, stable, soluble protein oligomers with an average molecular mass of Ϸ650 kDa under physiological conditions, i.e., 37°C, pH 7.0, and 100 M protein concentration. It further is shown here that intermolecular disulfide bonds are formed during oligomerization and that Cys-6 and Cys-111 are implicated in this bonding. The formation of the soluble oligomers was monitored by their ability to enhance the fluorescence of thioflavin T, a benzothiazole dye that increases in fluorescence intensity upon binding to amyloid fibers, and by disruption of this binding upon addition of the chaotropic agent guanidine hydrochloride. Our results suggest a general, unifying picture of SOD1 aggregation that could operate when wild-type or mutant SOD1 proteins lack their metal ions. Although we cannot exclude other mechanisms in SOD1-linked familial ALS, the one proposed here has the strength of explaining how a large and diverse set of SOD1 mutant proteins all could lead to disease through the same mechanism.amyloid ͉ neurodegeneration ͉ protein aggregation ͉ amyotrophic lateral sclerosis ͉ protein misfolding P rotein oligomerization, aggregation, and formation of insoluble amyloid deposits commonly are observed in neurodegenerative diseases, but the factors initiating and modulating the abnormal protein-protein interactions that lead to oligomerization remain elusive (1, 2). Metal ions frequently have been implicated in these phenomena, but how exactly they are involved remains unclear (3). Over 114 different variants of human copper-zinc superoxide dismutase (Cu 2 Zn 2 SOD1) have been linked to the neurodegenerative disease familial ALS (FALS) by a gain-of-function mechanism (4-6). Although the exact cellular sites and mechanisms of toxicity are unknown, aberrant SOD1 protein oligomerization has been strongly implicated in disease causation (7,8). Several recent publications have presented compelling evidence that abnormal disulfide cross-linking of ALS-mutant SOD1 plays a role in this oligomerization, and disulfide-linked SOD1 multimers have been detected in neural tissues of SOD1-ALS transgenic mice that are presumed to be components of higher-molecular-weight species or intermediates in their formation (7, 9-11).Wild-type (WT) human SOD1 is an exceptionally stable protein in its holo form and, although some of the ALS-mutant SOD1 proteins are severely destabilized by their mutations, others largely retain the stability of WT SOD1 (4). In the fully demetallated (apo) states, some ...
There are about 100 single point mutations of copper, zinc superoxide dismutase 1 (SOD1) which are reported (http://alsod.iop.kcl.ac.uk/Als/index.aspx) to be related to the familial form (fALS) of amyotrophic lateral sclerosis (ALS). These mutations are spread all over the protein. It is well documented that fALS produces protein aggregates in the motor neurons of fALS patients, which have been found to be associated to mitochondria. We selected eleven SOD1 mutants, most of them reported as pathological, and characterized them investigating their propensity to aggregation using different techniques, from circular dichroism spectra to ThT-binding fluorescence, size-exclusion chromatography and light scattering spectroscopy. We show here that these eleven SOD1 mutants, only when they are in the metal-free form, undergo the same general mechanism of oligomerization as found for the WT metal-free protein. The rates of oligomerization are different but eventually they give rise to the same type of soluble oligomeric species. These oligomers are formed through oxidation of the two free cysteines of SOD1 (6 and 111) and stabilized by hydrogen bonds, between beta strands, thus forming amyloid-like structures. SOD1 enters the mitochondria as demetallated and mitochondria are loci where oxidative stress may easily occur. The soluble oligomeric species, formed by the apo form of both WT SOD1 and its mutants through an oxidative process, might represent the precursor toxic species, whose existence would also suggest a common mechanism for ALS and fALS. The mechanism here proposed for SOD1 mutant oligomerization is absolutely general and it provides a common unique picture for the behaviors of the many SOD1 mutants, of different nature and distributed all over the protein.
Parkinson’s disease is a neurodegenerative disorder characterized by the death of dopaminergic neurons and by accumulation of alpha-synuclein (aS) aggregates in the surviving neurons. The dopamine catabolite 3,4-dihydroxyphenylacetaldehyde (DOPAL) is a highly reactive and toxic molecule that leads to aS oligomerization by covalent modifications to lysine residues. Here we show that DOPAL-induced aS oligomer formation in neurons is associated with damage of synaptic vesicles, and with alterations in the synaptic vesicles pools. To investigate the molecular mechanism that leads to synaptic impairment, we first aimed to characterize the biochemical and biophysical properties of the aS-DOPAL oligomers; heterogeneous ensembles of macromolecules able to permeabilise cholesterol-containing lipid membranes. aS-DOPAL oligomers can induce dopamine leak in an in vitro model of synaptic vesicles and in cellular models. The dopamine released, after conversion to DOPAL in the cytoplasm, could trigger a noxious cycle that further fuels the formation of aS-DOPAL oligomers, inducing neurodegeneration.
The structural and dynamical properties of the metal-free form of WT human superoxide dismutase 1 (SOD1) and its familial amyotrophic lateral sclerosis (fALS)-related mutants, T54R and I113T, were characterized both in solution, through NMR, and in the crystal, through X-ray diffraction. We found that all 3 X-ray structures show significant structural disorder in 2 loop regions that are, at variance, well defined in the fully-metalated structures. Interestingly, the apo state crystallizes only at low temperatures, whereas all 3 proteins in the metalated form crystallize at any temperature, suggesting that crystallization selects one of the most stable conformations among the manifold adopted by the apo form in solution. Indeed, NMR experiments show that the protein in solution is highly disordered, sampling a large range of conformations. The large conformational variability of the apo state allows the free reduced cysteine Cys-6 to become highly solvent accessible in solution, whereas it is essentially buried in the metalated state and the crystal structures. Such solvent accessibility, together with that of Cys-111, accounts for the tendency to oligomerization of the metal-free state. The present results suggest that the investigation of the solution state coupled with that of the crystal state can provide major insights into SOD1 pathway toward oligomerization in relation to fALS.amyotrophic lateral sclerosis ͉ NMR ͉ X-ray ͉ mobility ͉ H2O/D2O exchange M ore than 100 different variants of human copper-zinc superoxide dismutase (Cu 2 Zn 2 SOD) have been identified and linked to the neurodegenerative disease familial amyotrophic lateral sclerosis (fALS) by a gain-of-function mechanism (1, 2). Although the mechanism of the toxicity is unknown, aberrant SOD1 protein oligomerization has been strongly implicated in disease causation (3,4). Several recent publications (5, 6) have presented compelling evidence that in vivo abnormal disulfide cross-linking of ALS mutant SOD1 plays a role in this oligomerization, and disulfide-linked SOD1 multimers have been detected mainly in mitochondria of neuronal tissues of SOD1-linked fALS patients and transgenic mice (7-9).WT human SOD1 is an exceptionally stable, homodimeric 32-kDa protein, located mainly in the cytoplasm, but it is also present in the peroxisomes, the mitochondrial intermembrane space, and the nucleus of eukaryotic cells (10, 11). Each subunit of the dimer binds 1 copper and 1 zinc ion and folds as an 8-stranded Greek-key -barrel that is stabilized by an intrasubunit disulfide bond (Cys-57, Cys-146) near the active site (12). In vivo, in the highly reducing cytoplasm environment, the existence of this intrasubunit disulfide bond points to its very low reduction potential.In addition to the 2 cysteines involved in the formation of the intramolecular disulfide bond, 2 reduced cysteines, Cys-6 and Cys-111, are located on -strand 1 and loop VI of WT human SOD1, respectively. Among the loops connecting the 8 -strands, 2 have structural and functional roles. The ...
Catalase-peroxidase (KatG) from Mycobacterium tuberculosis is responsible for the activation of the antitubercular drug isonicotinic acid hydrazide (INH) and is important for survival of M. tuberculosis in macrophages. Characterization of the structure and catalytic mechanism of KatG is being pursued to provide insights into drug (INH) resistance in M. tuberculosis. Site-directed mutagenesis was used to prepare the INH-resistant mutant KatG[S315T], and the overexpressed enzyme was characterized and compared with wild-type KatG. KatG[S315T] exhibits a reduced tendency to form sixcoordinate heme, because of coordination of water to iron during purification and storage, and also forms a highly unstable Compound III (oxyferrous enzyme). Catalase activity and peroxidase activity measured using t-butylhydroperoxide and o-dianisidine were moderately reduced in the mutant compared with wild-type KatG. Stopped-flow spectrophotometric experiments revealed a rate of Compound I formation similar to wildtype KatG using peroxyacetic acid to initiate the catalytic cycle, but no Compound I was detected when bulkier peroxides (chloroperoxybenzoic acid, t-butylhydroperoxide) were used. The affinity of resting (ferric) KatG[S315T] for INH, measured using isothermal titration calorimetry, was greatly reduced compared with wild-type KatG, as were rates of reaction of Compound I with the drug. These observations reveal that although KatG[S315T] maintains reasonably good steady state catalytic rates, poor binding of the drug to the enzyme limits drug activation and brings about INH resistance.
The catalytic function of Mycobacterium tuberculosis catalase-peroxidase (KatG) and its role in activation of the anti-tuberculosis antibiotic isoniazid were investigated using rapid freeze-quench electron paramagnetic resonance (RFQ-EPR) experiments. The reaction of KatG with peroxyacetic acid was followed as a function of time using x-band EPR at 77 K. A doublet EPR signal appears within 6.4 ms after mixing and at time points through hundreds of milliseconds. Thereafter, a singlet signal develops and finally predominates after 1 s, with a total yield of radical ϳ0.5 spin/heme. Simulation of the spectra provided EPR parameters consistent with those for tyrosyl radicals. Changes in the hyperfine splitting and/or line width in spectra for L-3,3-[ 2 H 2 ]tyrosine-labeled, but not L-2,4,5,6,7-[ 2 H 5 ]tryptophan-labeled KatG confirmed this assignment. The initial rate of radical formation was unchanged using a 3-fold or 10-fold excess of peroxyacetic acid, consistent with a rate-determining step involving an intermediate. Although Compound I is likely to be the precursor of tyrosyl radical in KatG, neither its EPR signal nor its reduction to Compound II during formation of the radical(s) could be observed. The tyrosyl radical doublet signal was rapidly quenched by addition of isoniazid and benzoic hydrazide, but not by iproniazid, which binds poorly to KatG.
Elucidating the structure and biosynthesis of neuromelanin (NM) would be an important step towards understanding its putative role in the pathogenesis of Parkinson's disease. A useful complement to studies aimed at unraveling the origin and properties of this essentially insoluble natural substance is the preparation of synthetic derivatives that resemble NM. With this aim in mind, water-soluble conjugates between dopamine-derived melanin and bovine serum albumin (BSA) were synthesized. Melanin-BSA adducts were prepared with both eumelanic oligomers obtained through the oxidative polymerization of dopamine and pheomelanic oligomers obtained under the same conditions from dopamine and cysteine. Iron ions were added during the synthesis to understand the interaction between the pigment and this metal ion, as the NM in neurons in several human brain regions contains significant amounts of iron. The structures of the conjugates were analyzed by (1)H NMR spectroscopy and controlled proteolysis/MS experiments. The binding of iron(III) ions was evaluated by ICP analysis and EPR spectroscopy. The EPR signal from bound iron(III) indicated high-spin octahedral sites and, as also seen for NM, the signal is coupled to a signal from a radical associated with the melanic components of the conjugates. However, the intensity of the EPR signal from iron suggested a reduced fraction of the total iron, indicating that most of the iron is strongly coupled in clusters within the matrix. The amount of paramagnetic, mononuclear iron(III) was greater in the pheomelanin-BSA conjugates, suggesting that iron clustering is reduced in the sulfur-containing pigment. Thus, the melanin-BSA conjugates appear to be good models for the natural pigment.
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