Fibrillation precursor of superoxide dismutase 1 revealed by gradual tuning of the protein-folding equilibrium

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123

A longstanding challenge in studies of neurodegenerative disease has been that the pathologic protein aggregates in live tissue are not amenable to structural and kinetic analysis by conventional methods. The situation is put in focus by the current progress in demarcating protein aggregation in vitro, exposing new mechanistic details that are now calling for quantitative in vivo comparison. In this study, we bridge this gap by presenting a direct comparison of the aggregation kinetics of the ALS-associated protein superoxide dismutase 1 (SOD1) in vitro and in transgenic mice. The results based on tissue sampling by quantitative antibody assays show that the SOD1 fibrillation kinetics in vitro mirror with remarkable accuracy the spinal cord aggregate buildup and disease progression in transgenic mice. This similarity between in vitro and in vivo data suggests that, despite the complexity of live tissue, SOD1 aggregation follows robust and simplistic rules, providing new mechanistic insights into the ALS pathology and organism-level manifestation of protein aggregation phenomena in general.superoxide dismutase 1 | aggregation | transgenic mice | aggregation kinetics

Section: Resultssupporting

confidence: 76%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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SOD1 aggregation in ALS mice shows simplistic test tube behavior

Lang

Zetterström

Brännström

et al. 2015

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123

“…This suggests that mutant and wild-type hSOD1 might confer disease by the same mechanism: Human SOD1 seems to be an oversaturated protein with an intrinsic propensity to aggregate (13), and this tendency can be critically augmented by mutation. Consistently, mutant and wild-type hSOD1 show indistinguishable fibrillation behavior in vitro with kinetics determined by structural stability and net charge (14,15). The in vitro fibrillation occurs moreover by the recruitment of globally unfolded hSOD1 monomers, following exponential time courses controlled by fibril fragmentation (15).…”

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confidence: 62%

Structural and kinetic analysis of protein-aggregate strains in vivo using binary epitope mapping

Bergh¹,

Zetterström²,

Andersen

et al. 2015

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108

Despite considerable progress in uncovering the molecular details of protein aggregation in vitro, the cause and mechanism of protein-aggregation disease remain poorly understood. One reason is that the amount of pathological aggregates in neural tissue is exceedingly low, precluding examination by conventional approaches. We present here a method for determination of the structure and quantity of aggregates in small tissue samples, circumventing the above problem. The method is based on binary epitope mapping using anti-peptide antibodies. We assessed the usefulness and versatility of the method in mice modeling the neurodegenerative disease amyotrophic lateral sclerosis, which accumulate intracellular aggregates of superoxide dismutase-1. Two strains of aggregates were identified with different structural architectures, molecular properties, and growth kinetics. Both were different from superoxide dismutase-1 aggregates generated in vitro under a variety of conditions. The strains, which seem kinetically under fragmentation control, are associated with different disease progressions, complying with and adding detail to the growing evidence that seeding, infectivity, and strain dependence are unifying principles of neurodegenerative disease.

“…In contrast to the high-energy intermediates of β2-microglobulin and lysozyme, however, we observe here that the high-energy state HS is not on the pathway to the unfolded state, but is more compact than the solution ground state (Table 1). Together with the finding that destabilization of the apo monomer with urea accelerates the fibrillation kinetics in vitro (37), this puts precise constraints on the aggregation mechanism: the fibrillation precursor needs to be more expanded than the folded ground state, which excludes the involvement of the high-energy state HS. Instead, the precursor for apoSOD fibrillation appears to be the globally denatured state (37), consistent with an observed maximum of the fibrillation kinetics above 5 M urea, at which the occupancy of D is nearly 1 and the occupancy of the high-energy state has decreased from 0.01 to less than 10 −4.7 (Table 1, SI Text, and Fig.…”

Section: Discussionmentioning

confidence: 99%

Global structural motions from the strain of a single hydrogen bond

Danielsson

Awad

Saraboji

et al. 2013

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The origin and biological role of dynamic motions of folded enzymes is not yet fully understood. In this study, we examine the molecular determinants for the dynamic motions within the β-barrel of superoxide dismutase 1 (SOD1), which previously were implicated in allosteric regulation of protein maturation and also pathological misfolding in the neurodegenerative disease amyotrophic lateral sclerosis. Relaxation-dispersion NMR, hydrogen/deuterium exchange, and crystallographic data show that the dynamic motions are induced by the buried H43 side chain, which connects the backbones of the Cu ligand H120 and T39 by a hydrogen-bond linkage through the hydrophobic core. The functional role of this highly conserved H120-H43-T39 linkage is to strain H120 into the correct geometry for Cu binding. Upon elimination of the strain by mutation H43F, the apo protein relaxes through hydrogen-bond swapping into a more stable structure and the dynamic motions freeze out completely. At the same time, the holo protein becomes energetically penalized because the twisting back of H120 into Cubound geometry leads to burial of an unmatched backbone carbonyl group. The question then is whether this coupling between metal binding and global structural motions in the SOD1 molecule is an adverse side effect of evolving viable Cu coordination or plays a key role in allosteric regulation of biological function, or both?D ynamic motions of folded proteins in several cases are found to be essential for allosteric control of ligand binding, adaptive orientation of active-site moieties, and communication between distant sites in protein structures and complexes (1-4). Despite this fundamental role of dynamic motions in biological function, the molecular factors that control structural fluctuations and conformational heterogeneity within folded proteins remain largely unexplored. Also, it is not yet known if there is any relation, or principal difference, between the functional motions of proteins and the supposedly adverse structural fluctuations implicated in protein misfolding and aggregation (5, 6). An interesting system for shedding more light on these questions is the enzyme superoxide dismutase 1 (SOD1) associated with pathological misfolding and aggregation in the neurodegenerative disease amyotrophic lateral sclerosis (ALS). Native SOD1 is a symmetric homodimer of two Ig-like β-barrels, each of which coordinates one catalytic Cu +/2+ ion and one structural Zn 2+ ion. The redox active Cu +/2+ ion is ligated directly to the side of the monomer β-barrel, whereas the Zn 2+ ties together the long loops IV and VII to a densely packed dome over the active site. The role of this dome is twofold. It composes a selectivity filter for substrates to the Cu +/2+ site (7) and also provides a critical part of the dimer interface (8). As a consequence, the dimerization of SOD1 becomes tightly controlled by metal binding via the structure of loops IV and VII, and the conserved C57-C146 disulfide linkage (9): if the metals and disulfide bond are lost, t...