Two models have been proposed to explain the interaction of cytochrome c with cardiolipin (CL) vesicles. In one case, an acyl chain of the phospholipid accommodates into a hydrophobic channel of the protein located close the Asn52 residue, whereas the alternative model considers the insertion of the acyl chain in the region of the Met80-containing loop. In an attempt to clarify which proposal offers a more appropriate explanation of cytochrome c-CL binding, we have undertaken a spectroscopic and kinetic study of the wild type and the Asn52Ile mutant of iso-1-cytochrome c from yeast to investigate the interaction of cytochrome c with CL vesicles, considered here a model for the CL-containing mitochondrial membrane. Replacement of Asn52, an invariant residue located in a small helix segment of the protein, may provide data useful to gain novel information on which region of cytochrome c is involved in the binding reaction with CL vesicles. In agreement with our recent results revealing that two distinct transitions take place in the cytochrome c-CL binding reaction, data obtained here support a model in which two (instead of one, as considered so far) adjacent acyl chains of the liposome are inserted, one at each of the hydrophobic sites, into the same cytochrome c molecule to form the cytochrome c-CL complex.
Dehaloperoxidase (DHP) from the annelid Amphitrite ornata is a catalytically active hemoglobin-peroxidase that possesses a unique internal binding cavity in the distal pocket above the heme. The previously published crystal structure of DHP shows 4-iodophenol bound internally. This led to the proposal that the internal binding site is the active site for phenol oxidation. However, the native substrate for DHP is 2,4,6-tribromophenol, and all attempts to bind 2,4,6-tribromophenol in the internal site under physiological conditions have failed. Herein, we show that the binding of 4-halophenols in the internal pocket inhibits enzymatic function. Furthermore, we demonstrate that DHP has a unique two-site competitive binding mechanism in which the internal and external binding sites communicate through two conformations of the distal histidine of the enzyme, resulting in nonclassical competitive inhibition. The same distal histidine conformations involved in DHP function regulate oxygen binding and release during transport and storage by hemoglobins and myoglobins. This work provides further support for the hypothesis that DHP possesses an external binding site for substrate oxidation, as is typical for the peroxidase family of enzymes.
Cytochrome c undergoes structural variations during the apoptotic process; such changes have been related to modifications occurring in the protein when it forms a complex with cardiolipin, one of the phospholipids constituting the mitochondrial membrane. Although several studies have been performed to identify the site(s) of the protein involved in the cytochrome c−cardiolipin interaction, to date the location of this hosting region(s) remains unidentified and is a matter of debate. To gain deeper insight into the reaction mechanism, we investigate the role that the Lys72, Lys73, and Lys79 residues play in the cytochrome c−cardiolipin interaction, as these side chains appear to be critical for cytochrome c−cardiolipin recognition. The Lys72Asn, Lys73Asn, Lys79Asn, Lys72/73Asn, and Lys72/73/79Asn mutants of horse heart cytochrome c were produced and characterized by circular dichroism, ultraviolet−visible, and resonance Raman spectroscopies, and the effects of the mutations on the interaction of the variants with cardiolipin have been investigated. The mutants are characterized by a subpopulation with non-native axial coordination and are less stable than the wild-type protein. Furthermore, the mutants lacking Lys72 and/or Lys79 do not bind cardiolipin, and those lacking Lys73, although they form a complex with the phospholipid, do not show any peroxidase activity. These observations indicate that the Lys72, Lys73, and Lys79 residues stabilize the native axial Met80−Fe(III) coordination as well as the tertiary structure of cytochrome c. Moreover, while Lys72 and Lys79 are critical for cytochrome c−cardiolipin recognition, the simultaneous presence of Lys72, Lys73, and Lys79 is necessary for the peroxidase activity of cardiolipin-bound cytochrome c.
Electronic absorption and resonance Raman (RR) spectra of the ferric form of barley grain peroxidase (BP 1) at various pH values, at both room temperature and 20 K, are reported, together with electron paramagnetic resonance spectra at 10 K. The ferrous forms and the ferric complex with fluoride have also been studied. A quantum mechanically mixed-spin (QS) state has been identified. The QS heme species coexists with 6- and 5-cHS hemes; the relative populations of these three spin states are found to be dependent on pH and temperature. However, the QS species remains in all cases the dominant heme spin species. Barley peroxidase appears to be further characterized by a splitting of the two vinyl stretching modes, indicating that the vinyl groups are differently conjugated with the porphyrin. An analysis of the currently available spectroscopic data for proteins from all three peroxidase classes suggests that the simultaneous occurrence of the QS heme state as well as the splitting of the two vinyl stretching modes is confined to class III enzymes. The former point is discussed in terms of the possible influences of heme deformations on heme spin state. It is found that moderate saddling alone is probably not enough to cause the QS state, although some saddling may be necessary for the QS state.
Mutation of Distal Residues of Horseradish Peroxidase: Influence on Substrate Binding and Cavity Properties
The manner in which the distal heme pocket residues of peroxidases control the reaction mechanism and ligand binding has been investigated further by analysis of the electronic absorption and resonance Raman (RR) spectra of distal site mutants of recombinant horseradish peroxidase (HRP-C*). The roles of the conserved distal histidine and arginine residues, particularly in the context of the catalytic mechanism originally proposed for cytochrome c peroxidase (CCP), have been evaluated by studying the His42 --> Leu, His42 --> Arg, Arg38 --> Gly, and Arg38 --> Leu variants of HRP-C*. Spectra of the ferric forms, their complexes with benzohydroxamic acid (BHA), and the ferrous forms have been recorded at neutral pH. In addition, the ferric forms have been studied at alkaline pH. The relative populations of the three heme spin states characteristic of HRP-C* and its mutants were found to vary markedly from mutant to mutant. This diversity of heme spin state populations among the various mutants has allowed a well-defined set of RR frequencies to be compiled for the three heme spin states. These frequencies support the analysis of wild-type HRP-C* in terms of two heme states, five- (5cHS#) and six-coordinate high-spin (6cHS#), which exhibit anomalous RR frequencies compared to those of model heme systems. The third heme spin state is identified as being six-coordinate high-spin, displaying typical RR frequencies (6cHS). The 6cHS# and the 6cHS heme states are characterized by H bonding between the iron-bound water molecule and the Arg38 residue or the His42 residue, respectively. The proportion of six-coordinate high-spin heme states is at a minimum in the Arg38Leu mutant, indicating that the occupancy of the distal water molecule site is reduced in this mutant. The His42Arg mutant is distinguished from the other mutants by the unexpected presence of an iron-bound hydroxyl group at neutral pH. The spectral changes induced upon complexation with BHA indicate that both the distal histidine and arginine are involved in BHA binding; however, the arginine residue appears to play a more critical role. Measurements at pH 12 suggest there is a concerted involvement of both distal residues in mediating the alkaline transition of HRP-C*. Arg38 appears to be essential for stabilization of the OH- ligand, while His42 acts as a H bond acceptor. A striking similarity between the roles of these residues in the reaction of H2O2 with the enzyme and the alkaline transition is noted. By comparison with the results from corresponding mutants of CCP, it appears that although the hydrogen-bonding network linking the distal and proximal sides of the heme is conserved the distal cavity in HRP-C differs significantly from that of CCP. However, some similarities in the local environment of the distal arginine are suggested.
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