Zinc and the iron donor frataxin regulate oligomerization of the scaffold protein to form new Fe-S cluster assembly centers.

Early studies of the bacterial Fe-S cluster assembly system provided structural details for how the scaffold protein and the cysteine desulfurase interact. This work and additional work on the yeast and human systems elucidated a conserved mechanism for sulfur donation but did not provide any conclusive insights into the mechanism for iron delivery from the iron donor, frataxin, to the scaffold. We previously showed that oligomerization is a mechanism by which yeast frataxin (Yfh1) can promote assembly of the core machinery for Fe-S cluster synthesis both in vitro and in cells, in such a manner that the scaffold protein, Isu1, can bind to Yfh1 independent of the presence of the cysteine desulfurase, Nfs1. Here, in the absence of Yfh1, Isu1 was found to exist in two forms, one mostly monomeric with limited tendency to dimerize, and one with a strong propensity to oligomerize. Whereas the monomeric form is stabilized by zinc, the loss of zinc promotes formation of dimer and higher order oligomers. However, upon binding to oligomeric Yfh1, both forms take on a similar symmetrical trimeric configuration that places the Fe-S cluster coordinating residues of Isu1 in close proximity of iron-binding residues of Yfh1. This configuration is suitable for docking of Nfs1 in a manner that provides a structural context for coordinate iron and sulfur donation to the scaffold. Moreover, distinct structural features suggest that in physiological conditions the zinc-regulated abundance of monomeric vs. oligomeric Isu1 yields [Yfh1]·[Isu1] complexes with different Isu1 configurations that afford unique functional properties for Fe-S cluster assembly and delivery.

Mammalian pitrilysin: substrate specificity and mitochondrial targeting.

The substrate specificity of the mitochondrial metallopeptidase proteinase 1 (MP1) was investigated and its mitochondrial targeting signal identified. The substrate specificity of MP1 was examined with physiological peptides as substrates. Although the enzyme exhibits broad substrate specificity, there is a trend for peptides containing 13 or more residues to exhibit K(m) values of 2 muM or less. Three of four peptides containing 11 or fewer residues exhibited K(m) values above 10 muM. Similarly, peptides containing 13 or more residues exhibited k(cat) values below 10 min(-1), while three of four peptides containing 11 or fewer residues exhibited k(cat) values above 30 min(-1). Many of the peptide cleavage sites of MP1 resemble that of the mitochondrial processing protease (MPP); however, MP1 does not process the precursor form of citrate synthase. The enzyme, however, does cleave the released prepeptide from precitrate synthase. A mitochondria localization was shown in MP1 transfected NT2 and HepG2 cells. Deletion of the N-terminal 15 amino acids caused MP1 to be mislocalized to the cytoplasm and nucleus. Furthermore, when fused to green flourescent protein, this 15-amino acid N-terminal sequence directed the fusion protein to the mitochondria.

Functional studies of frataxin.

Mitochondria generate adenosine triphosphate (ATP) but also dangerous reactive oxygen species (ROS). One-electron reduction of dioxygen in the early stages of the electron transport chain yields a superoxide radical that is detoxified by mitochondrial superoxide dismutase to give hydrogen peroxide. The hydroxyl radical is derived from decomposition of hydrogen peroxide via the Fenton reaction, catalyzed by Fe2+ ions. Mitochondria require a constant supply of Fe2+ for heme and iron-sulfur cluster biosyntheses and therefore are particularly susceptible to ROS attack. Two main antioxidant defenses are known in mitochondria: enzymes that catalytically remove ROS, e.g. superoxide dismutase and glutathione peroxidase, and low molecular weight agents that scavenge ROS, including coenzyme Q, glutathione, and vitamins E and C. An effective defensive system, however, should also involve means to control the availability of pro-oxidants such as Fe2+ ions. There is increasing evidence that this function may be carried out by the mitochondrial protein frataxin. Frataxin deficiency is the primary cause of Friedreich's ataxia (FRDA), an autosomal recessive degenerative disease. Frataxin is a highly conserved mitochondrial protein that plays a critical role in iron homeostasis. Respiratory deficits, abnormal cellular iron distribution and increased oxidative damage are associated with frataxin defects in yeast and mouse models of FRDA. The mechanism by which frataxin regulates iron metabolism is unknown. The yeast frataxin homologue (mYfh1p) is activated by Fe(II) in the presence of oxygen and assembles stepwise into a 48-subunit multimer (alpha48) that sequesters >2000 atoms of iron in a ferrihydrite mineral core. Assembly of mYfhlp is driven by two sequential iron oxidation reactions: a fast ferroxidase reaction catalyzed by mYfh1p induces the first assembly step (alpha --> alpha3), followed by a slower autoxidation reaction that promotes the assembly of higher order oligomers yielding alpha48. Depending on the ionic environment, stepwise assembly is associated with the sequestration of < or = 50-75 Fe(II)/subunit. This Fe(II) is initially loosely bound to mYfh1p and can be readily mobilized by chelators or made available to the mitochondrial enzyme ferrochelatase to synthesize heme. However, as iron oxidation and mineralization proceed, Fe(III) becomes progressively inaccessible and a stable iron-protein complex is produced. In conclusion, by coupling iron oxidation with stepwise assembly, frataxin can successively function as an iron chaperon or an iron store. Reduced iron availability and solubility and increased oxidative damage may therefore explain the pathogenesis of FRDA.

Substrate binding changes conformation of the alpha-, but not the beta-subunit of mitochondrial processing peptidase.

Lifetime analysis of tryptophan fluorescence of the mitochondrial processing peptidase (MPP) from Saccharomyces cerevisiae clearly proved that substrate binding evoked a conformational change of the alpha-subunit while presence of substrate influenced neither the lifetime components nor the average lifetime of the tryptophan excited state of the beta-MPP subunit. Interestingly, lifetime analysis of tryptophan fluorescence decay of the alpha-MPP subunit revealed about 11% of steady-state fractional intensity due to the long-lived lifetime component, indicating that at least one tryptophan residue is partly buried at the hydrophobic microenvironment. Computer modeling, however, predicted none of three tryptophans, which the alpha-subunit contains, as deeply buried in the protein matrix. We conclude this as a consequence of a possible dimeric (oligomeric) structure.

Two-step processing of human frataxin by mitochondrial processing peptidase. Precursor and intermediate forms are cleaved at different rates.

We showed previously that maturation of the human frataxin precursor (p-fxn) involves two cleavages by the mitochondrial processing peptidase (MPP). This observation was not confirmed by another group, however, who reported only one cleavage. Here, we demonstrate conclusively that MPP cleaves p-fxn in two sequential steps, yielding a 18,826-Da intermediate (i-fxn) and a 17,255-Da mature (m-fxn) form, the latter corresponding to endogenous frataxin in human tissues. The two cleavages occur between residues 41-42 and 55-56, and both match the MPP consensus sequence RX downward arrow (X/S). Recombinant rat and yeast MPP catalyze the p --> i step 4 and 40 times faster, respectively, than the i --> m step. In isolated rat mitochondria, p-fxn undergoes a sequence of cleavages, p --> i --> m --> d(1) --> d(2), with d(1) and d(2) representing two C-terminal fragments of m-fxn produced by an unknown protease. The i --> m step is limiting, and the overall rate of p --> i --> m does not exceed the rate of m --> d(1) --> d(2), such that the levels of m-fxn do not change during incubations as long as 3 h. Inhibition of the i --> m step by a disease-causing frataxin mutation (W173G) leads to nonspecific degradation of i-fxn. Thus, the second of the two processing steps catalyzed by MPP limits the levels of mature frataxin within mitochondria.

Complementation between mitochondrial processing peptidase (MPP) subunits from different species.

Mitochondrial processing peptidase (MPP), a dimer of nonidentical subunits, is the primary peptidase responsible for the removal of leader peptides from nuclearly encoded mitochondrial proteins. Alignments of the alpha and beta subunits of MPP (alpha- and beta-MPP) from different species show strong protein sequence similarity in certain regions, including a highly negatively charged region as well as a domain containing a putative metal ion binding site. In this report, we describe experiments in which we combine the subunits of MPP from yeast, rat, and Neurospora crassa, both in vivo and in vitro and mesure the resultant processing activity. For in vivo complementation, we used the temperature sensitive mif1 and mif2 yeast mutants, which lack MPP activity at the nonpermissive temperature (37 degrees C). We found that the defective alpha-MPP of mif2 cannot be substituted for by the alpha-MPP from rat or Neurospora. On the other hand, the beta-MPP from rat and Neurospora can fully substitute for the defective beta-MPP in the mif1 mutant. These results were confirmed in in vitro experiments in which individually expressed subunits were combined. Only combinations of the alpha-MPP from yeast with the beta-MPP from rat or Neurospora produced active MPP.