2010
DOI: 10.1021/ja1057136
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Folding Catalysis by Transient Coordination of Zn2+ to the Cu Ligands of the ALS-Associated Enzyme Cu/Zn Superoxide Dismutase 1

Abstract: How coordination of metal ions modulates protein structures is not only important for elucidating biological function but has also emerged as a key determinant in protein turnover and protein-misfolding diseases. In this study, we show that the coordination of Zn(2+) to the ALS-associated enzyme Cu/Zn superoxide dismutase (SOD1) is directly controlled by the protein's folding pathway. Zn(2+) first catalyzes the folding reaction by coordinating transiently to the Cu ligands of SOD1, which are all contained with… Show more

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Cited by 81 publications
(79 citation statements)
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“…5, Folding Analysis, and Table S5). Consistent with previous studies (20), holoSOD1 pwt displays elevated k u values in the presence of EDTA, exposing the apparent rate constant of metal loss, k off (Fig. 5).…”
Section: H43fsupporting
confidence: 91%
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“…5, Folding Analysis, and Table S5). Consistent with previous studies (20), holoSOD1 pwt displays elevated k u values in the presence of EDTA, exposing the apparent rate constant of metal loss, k off (Fig. 5).…”
Section: H43fsupporting
confidence: 91%
“…An example of such long-range modulation is the observation that the common ALS-associated SOD1 mutation G93A affects the metal-binding ligands more than 18 Å away (38). For an enzyme whose stability, maturation, and cellular lifetimes are intimately coupled to the metal-binding equilibria (20), such global effects might be critical, shedding light not only on why the ALSprovoking mutations are so broadly distributed in the SOD1 structure, but also on why the SOD1 sequence is so highly conserved across divergent species (39). To this end, our data show that the evolutionary pathway to such complex functional dynamics may be very short: in this case, the change of a ubiquitous tyrosine corner into a cross-core histidine link is just one mutation away.…”
Section: Discussionmentioning
confidence: 99%
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“…Non-amyloid aggregates can also be promoted without agitation in physiological buffer by simply increasing the protein concentration to 95-950 μM and extending the incubation times (10). More detailed insight into the SOD1 aggregation mechanism has so far been precluded by difficulty to identify at structural level the monomeric precursor material: Native SOD1 is a metallated dimer with a complex maturation and degradation pathway, including a plethora of intermediate states (11,12). As observed for β 2 -microglobulin (13) and TTR (14); however, it is often assumed that the precursor for SOD1 aggregation is a ruptured apo species, which either exposes sticky material through local unfolding of the central β-barrel (15, 16) cross-links oxidatively via C6/C111 (9), polymerizes via the long active site loops (17), or promotes aggregation by a mixture of mechanisms (10).…”
mentioning
confidence: 99%