Impact of the presequence of a mitochondrium-targeted precursor, preadrenodoxin, on folding, catalytic activity, and stability of the protein in vitro.

Bovine preadrenodoxin, an adrenocortical precursor protein destined for mitochondrial import, was expressed in Escherichia coli as an [2Fe-2S] cluster-containing protein. It was found in inclusion bodies, purified from there, and finally reconstituted to obtain soluble holo-protein. The impact of the presequence on folding of the protein using biochemical and biophysical approaches has been investigated. Upon unfolding the preprotein reveals a decrease in the denaturational enthalpy and heat capacity compared with mature adrenodoxin, indicating an incomplete unfolding of the preprotein with remaining residual structure. Moreover, the data obtained show that the presequence is solvent exposed in aqueous solution with no preference for secondary structure elements and that it does not disturb the accurate folding of the mature part of the protein. The latter conclusion is also based on the finding that the precursor in vitro exhibits electron transfer function comparable to the mature protein, adrenodoxin. While the reduction of cytochrome c, reflecting the interaction between adrenodoxin and its reductase, and the interaction with CYP11B1 have not been significantly affected by the presence of the presequence, the binding affinity of preadrenodoxin to CYP11A1 is 5.5-fold lower than that of the mature form.

Cluster-iron substitution is related to structural and functional features of adrenodoxin mutants and to their redox states.

Site-directed mutants of adrenodoxin were studied for their ability to undergo cluster-iron substitution when reacted with zinc or cadmium salts under non-denaturing conditions in the presence or absence of reductants. Equilibrium and kinetic data for metal substitution were correlated with data on the stability to thermal unfolding and with the redox potential of the protein. Similarly to the wild-type protein, all mutants were able to stabilize a substituted form of the protein containing two metal (Zn or Cd) atoms and two sulfide ions/mol protein and a substituted form of the protein containing two sulfide ions and five Cd atoms/mol protein. However, the distribution of these two metal-substituted forms was different among the investigated proteins. [Ser95]Adrenodoxin stabilized either metal-substituted forms, confirming that Cys95 is not involved in metal coordination, even when five Cd atoms are bound to the protein. Removal of the extremely conserved hydroxy function at position 54 resulted in complete apoprotein formation upon reaction with Cd (75 % with Zn) under reducing conditions, indicating a cluster-harboring role for this function, which is conserved in all known 2Fe-2S proteins. Mutants at His56, which represents a residue unique to most vertebrate-type ferredoxins, were much more reactive than the wild-type protein with either metal, indicating that His56 plays a prominent role in the stabilization of the protein structure in the immediate vicinity of the cluster in this class of proteins. The nature of the metal-substitution products was dependent on cluster accessibility. For the reduced proteins, apoprotein formation depended on protein stability, while the velocity of metal substitution depended on the ease of cluster reduction.

Specific aspects of electron transfer from adrenodoxin to cytochromes p450scc and p45011beta.

An analysis of the electron transfer kinetics from the reduced [2Fe-2S] center of bovine adrenodoxin and its mutants to the natural electron acceptors, cytochromes P450scc and P45011beta, is the primary focus of this paper. A series of mutant proteins with distinctive structural parameters such as redox potential, microenvironment of the iron-sulfur cluster, electrostatic properties, and conformational stability was used to provide more detailed insight into the contribution of the electronic and conformational states of adrenodoxin to the driving forces of the complex formation of reduced adrenodoxin with cytochromes P450scc and P45011beta and electron transfer. The apparent rate constants of P450scc reduction were generally proportional to the adrenodoxin redox potential under conditions in which the protein-protein interactions were not affected. However, the effect of redox potential differences was shown to be masked by structural and electrostatic effects. In contrast, no correlation of the reduction rates of P45011beta with the redox potential of adrenodoxin mutants was found. Compared with the interaction with P450scc, however, the hydrophobic protein region between the iron-sulfur cluster and the acidic site on the surface of adrenodoxin seems to play an important role for precise complementarity in the tightly associated complex with P45011beta.

Conformational stability of adrenodoxin mutant proteins.

Adrenodoxin and the mutants at the positions T54, H56, D76, Y82, and C95, as well as the deletion mutants 4-114 and 4-108, were studied by high-sensitivity scanning microcalorimetry, limited proteolysis, and absorption spectroscopy. The mutants show thermal transition temperatures ranging from 46 to 56 degrees C, enthalpy changes from 250 to 370 kJ/mol, and heat capacity change delta Cp = 7.28 +/- 0.67 kJ/mol/K, except H56R. The amino acid replacement H56R produces substantial local changes in the region around positions 56 and Y82, as indicated by reduced heat capacity change (delta Cp = 4.29 +/- 0.37 kJ/mol/K) and enhanced fluorescence. Deletion mutant 4-108 is apparently more stable than the wild type, as judged by higher specific denaturation enthalpy and resistance toward proteolytic degradation. No simple correlation between conformational stability and functional properties could be found.

Mutational effects on the spectroscopic properties and biological activities of oxidized bovine adrenodoxin, and their structural implications.

Of the aromatic 1H-NMR signals of oxidized bovine adrenodoxin only those of His56 showed intrinsic chemical shift changes upon replacement of Tyr82 by Ser or Leu, that must arise from a loss of a through-space ring-current effect of the tyrosine ring in these mutants. Thus, of the three His residues contained in adrenodoxin, His56 is closest to Tyr82, and hence to the highly acidic determinant region of adrenodoxin that is the interaction site for adrenodoxin reductase and P-450. The strong dependence of the fluorescence intensity of Tyr82 on the residue in position 56 supported this observation. As a consequence of this, the effects of replacement of His56 by Gln or Thr on cytochrome c reduction and cytochromes P-450(11 beta) (CYP11B1)-dependent and P-450scc (CYP11A1)-dependent substrate conversions were studied. No influence on Vmax values was observed for all reactions mediated by the mutants, implying His56 does not play a decisive role in the intramolecular or intermolecular electron transfer. In contrast, the Km values were increased, as was the Ks value for binding of CYP11A1 to the [H56T]adrenodoxin. The secondary structure deduced from further NMR data of adrenodoxin was compared with that of other ferredoxins. Tyr82 is in a region of the molecule containing no secondary-structure elements. The data for Tyr82 are in keeping with the biological activities and suggests it is in a flexible, solvent-exposed region of the molecule.

Immunocytochemical localization of heterologously expressed adrenodoxin and its electron acceptor cytochrome P45011B1 in Escherichia coli.

Adrenal steroid hydroxylase P45011B1 and its electron donor adrenodoxin were localized in the cortex of bovine adrenals by immunogold-silver staining. In order to test recently developed heterologous expression systems for both enzymes to enable structure-function studies, immunocytochemical marker methods were applied. Adrenodoxin, the ferredoxin of the adrenal gland, was successfully expressed and for the first time localized in Escherichia coli. By use of ultrathin cryosections and the protein A-gold technique, adrenodoxin was detectable in large amounts in the cytoplasm of the bacterial cells, and, following the insertion of the outer membrane protein A leader sequence of E. coli, also in the periplasmic space. A fusion protein between mature adrenodoxin and human P45011B1 was constructed and clearly localized in E. coli by antibodies against both proteins.

Mutations of tyrosine 82 in bovine adrenodoxin that affect binding to cytochromes P45011A1 and P45011B1 but not electron transfer.

To understand the function of the unique tyrosine in position 82 of bovine adrenodoxin (Adx), which had been proposed to be involved in electron transfer from NADPH-dependent adrenodoxin reductase (AdR) to cytochrome P-450 enzymes and/or AdR binding by chemical modification studies (Taniguchi, T., and Kimura, T. (1975) Biochemistry 14, 5573-5578), the residue was replaced by phenylalanine, leucine, or serine. Unchanged absorption, CD, and electron spin resonance spectra as well as redox potentials indicate that the environment of the [2Fe-2S] cluster was not affected by the mutations. The Vmax values in cytochrome c reduction, P45011A1- and P45011B1-dependent activities were also not changed when using Y82F, Y82S, and Y82L Adx mutants as electron donor, demonstrating that tyrosine 82 is not involved in the intra- or intermolecular electron transfer. Replacement of tyrosine 82 did not affect AdR binding as shown by unchanged cytochrome c activity. There are, however, changes in Km values up to 4-fold when measuring the enzymatic activities of mutant Adx with P45011A1 and P45011B1. These changes differ in dependence on the P-450 (P45011A1 or P45011B1) used. The results suggest that mutation of tyrosine 82 either directly or indirectly (by inducing small conformational changes of the binding domain) affects the binding of cytochromes P-450.

Expression of bovine adrenodoxin in E. coli and site-directed mutagenesis of /2 Fe-2S/ cluster ligands.

Expression systems for adrenodoxin into the periplasm and the cytoplasm of E. coli have been developed as a prerequisite for site-directed mutagenesis studies. In both systems the /2Fe-2S/ cluster of the protein was correctly assembled, the cytoplasmic one gives, however, a tenfold higher expression level. To determine which of the five cysteines at positions 46, 52, 55, 92, and 95 coordinate the /2Fe-2S/ center, they have been individually mutated into serines. From these mutants, only C95S forms a functionally active holoprotein. Thus, residues 46, 52, 55, and 92 are the cysteines that coordinate the /2Fe-2S/ cluster in adrenodoxin.