(Received for publication, August 14, 1996, and in revised form, September 27, 1996)
From the Department of Biology, Graduate School of
Science, Osaka University, Toyonaka, Osaka 560, Japan,
§ School of Medicine, Kumamoto University, Kumamoto,
Kumamoto 860, Japan, ¶ Faculty of Science, Japan Women's
University, Bunkyo-ku, Tokyo 112, Japan, and
Faculty of
Industrial Science and Technology, Science University of Tokyo,
Noda, Chiba 278, Japan
The site and characteristics of iodide binding to Arthromyces ramosus peroxidase were examined by x-ray crystallographic analysis, 1H and 127I NMR, and kinetic studies. X-ray analysis of an A. ramosus peroxidase crystal soaked in a KI solution at pH 5.5 showed that a single iodide ion is located at the entrance of the access channel to the distal side of the heme and lies between the two peptide segments, Phe90-Pro91-Ala92 and Ser151-Leu152-Ile153, 12.8 Å from the heme iron. The distances between the iodide ion and heme peripheral methyl groups were all more than 10 Å. The findings agree with the results obtained with 1H NMR in which the chemical shift and intensity of the methyl groups in the hyperfine shift region of A. ramosus peroxidase were hardly affected by the addition of iodide, unlike the case of horseradish peroxidase. Moreover, 127I NMR and steady-state kinetics showed that the binding of iodide depends on protonation of an amino acid residue with a pKa of about 5.3, which presumably is the distal histidine (His56), 7.8 Å away from the iodide ion. The mechanism of electron transfer from the iodide ion to the heme iron is discussed on the basis of these findings.
Peroxidases (EC 1.11.1.7; donor, H2O2 oxidoreductase) are a family of heme-containing enzymes which catalyze the oxidation of a number of organic and inorganic substrates with hydrogen peroxide (1, 2). The oxidation reaction for organic substrates generally occurs by two sequential one-electron transfer reactions through the formation of intermediate compounds (compound I and compound II). In contrast, the oxidation of inorganic compounds (such as iodide or thiocyanide) is mediated by one two-electron transfer to compound I (3-6). The mechanisms of these electron transfer reactions has yet to be determined. Investigation of the mechanism is necessary in relation to the roles of peroxidases such as thyroid peroxidase, lactoperoxidase, chloroperoxidase, myeloperoxidase, and eosinophil peroxidase that function in hormone synthesis, bactericidal activity, and phagocytosis (1, 2).
Although kinetic studies of the reactions between compound I and halides showed characteristics of second order reactions, various evidence suggested that before the process of electron transfer, halide ions bind to the protein portion of compound I at a particular site in the vicinity of the prosthetic group. Because it is very difficult to study the binding to compound I that causes the reaction, the binding of these ions to peroxidases in the resting state was examined by spectrophotometric (4, 7, 8), kinetic (9, 10), fluorometric (11), 127I NMR (12, 13), 15N NMR (14-17), 13C NMR (17), 1H NMR (13-19), and optical difference spectroscopy (20-22) techniques. The actual site of the binding of these ions to the enzymes and the mechanism of electron transfer from these ions to the heme irons have yet to be clarified. This is partly due to lack of knowledge about the fine three-dimensional structures of enzymes such as HRP1 and lactoperoxidase that are used in studies on the binding of halide ions.
Recently, in addition to the peroxidases of plants and animals, many peroxidases have been isolated from fungi and bacteria, and their physicochemical properties are characterized (23). ARP, one such enzyme, is secreted from the hypomycete Arthromyces ramosus (Fungi Imperfecti). Its three-dimensional structure was determined recently by Kunishima et al. (24). It is almost identical in amino acid sequence to the Coprinus cinereus peroxidase which has been characterized by kinetic, chemical, spectroscopic, and NMR methods (25-29). These findings prompted us to attempt to determine the iodide-binding site by x-ray crystallographic analysis. In addition, the binding of iodide ions to ARP was examined by 1H NMR, 127I NMR, and kinetic techniques to compare with those obtained previously for HRP and lactoperoxidase.
ARP that had been purified by the method of
Morita et al. (27) was provided by Dr. T. Amachi. The
Reinheit Zahl (A403/A280) was 2.63. The concentration of the enzyme was determined
spectrophotometrically from the molar extinction coefficient at 405 nm,
1.09 × 105 cm1 M
1
(30). KI and H2O2 were purchased from Wako
(Osaka, Japan). Deuterium oxide (>99.85%) was purchased from the
Commissariat a l'Energie Atomique, France.
The iodide-bound form of
the ARP crystal was prepared by soaking the parent ARP crystal, which
had been prepared as described previously (24), for 12 h in 20 mM ammonium acetate buffer adjusted to pH 5.5 and
containing 33% saturated ammonium sulfate and 30 mM
potassium iodide. Diffraction data for the iodide derivative were
collected to 2.06 Å resolution at room temperature on an R-AXIS IIc
imaging plate area detector. X-rays, generated with a Rigaku rotating
anode at 40 kV and 100 mA, were monochromatized ( = 1.5418 Å) with
graphite. The diffraction data recorded on each imaging plate were read
out at 100-µm intervals then processed with PROCESS (32). Intensities
of the partial reflections recorded on adjacent two imaging plates were
summed to obtain the integrated intensities. The conditions and results
of the data collection are summarized in Table I.
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Two kinds of difference Fourier syntheses were calculated in order to
locate the iodide ion. One was an (Fo Fc) synthesis at 2.06 Å resolution, where
Fo is the observed structure factor of the
iodide derivative and Fc the calculated
structure factor derived from the atomic parameters of the native
crystal. The other was anomalous difference synthesis at 4.0 Å resolution. The phase angles were calculated using the atomic
parameters of ARP at pH 4.5 refined at 1.8 Å resolution (33).
The model of the iodide derivative was refined by simulated annealing
using the program XPLOR (34). Rearrangement of water molecules and
conformational change in the model were checked with the FRODO (35, 36)
and IRIS 4D/35GT computer graphics system. When the temperature factors
of all the atoms were refined with the occupancy of iodide fixed at
0.3, the temperature factor of the iodide converged to the value of
21.9 Å2. The final model contains one iodide ion and 250 water molecules in addition to the protein. The crystallographic
R factor was 16.2% for 19,513 reflections with
F > 2F in the 7.0-2.06 Å resolution range.
Proton NMR measurements were made with a Brüker AMX-400WB NMR spectrometer at 298 K. Samples dissolved in a deuterated phosphate buffer (100 mM) were measured in an NMR microtube (0.2 ml) with symmetric geometry along the Bo field (37). Typical spectra were obtained by accumulation of 20,000 transients at 32,000 data points over an 80-kHz bandwidth (18). Proton chemical shifts were referred to the proton signal of trace HDO at 4.82 ppm. The pH was measured in a Horiba model F-23 pH meter equipped with a Fuji Keisoku model SF-1600GC or home-made long and thin (3.2 × 180 mm) combination glass electrodes. The pH was calibrated using standard aqueous (H20) buffer and the isotope effect was disregarded for the deuterated solutions.
127I NMR was recorded at 80 MHz on the same spectrometer at 298 K equipped with an inverse HX probe. Typical spectra were obtained by 200,000-800,000 transients using 5-degree pulse at 32,000 data points over a 41.6-kHz bandwidth and applied 100-Hz line broadening to the free induction decay prior to the Fourier transform.
Peroxidase KineticsThe rate of oxidation of iodide ion by
H2O2 was measured at 295 K by following
I3 at 350 nm as described previously (39),
except that the total volume of the reaction mixture was reduced to 2.4 ml and the H2O2 concentration was 270 µM. The pH range of the medium was 4.0-6.0 in 33 mM acetate buffer. The spectrophotometer used was a Hitachi model UV-3000 spectrophotometer equipped with a thermoregulator made of
Peltier units, and the time course was recorded on a floppy disk to
instantly obtain the initial rate.
The ARP crystal
soaked in KI solution was isomorphous with the native crystal and
showed no significant change in conformation on the binding of iodide.
The (Fo Fc) and
anomalous difference maps are shown in Fig. 1, and the
peak heights that appear in these maps are listed in Table
II. The (Fo
Fc) map showed only one significant peak per
asymmetric unit. Its height was greater than 15
, whereas the second
largest peak was less than 6
. The anomalous difference map of the
derivative crystal showed four significant peaks per asymmetric unit.
The highest peak appeared at the iron site in the heme group, and the
second highest peak appeared at exactly the same site as in the
(Fo
Fc) map. The third
and fourth largest peaks were at the sites of the two presumed calcium
sites (24). These findings strongly suggest that the iodide binds to
ARP at a single site.2 The occupancy of the
present iodide derivatives is estimated to be about 30% based on the
peak height at this site in the anomalous difference map. The anomalous
difference map also confirmed the two calcium sites proposed from
circumstantial evidence.
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A close-up view of the environment of the iodide-binding site is shown
in Fig. 2. The binding site is between the two peptide segments, Phe90-Pro91-Ala92 and
Ser151-Leu152-Ile153, which
respectively continue to helices C and E (24) and form the upper rim of
the access channel to the heme distal side. The site is near the
surface side of Ile153 and, at its opposite side (inside of
ARP), there is the imidazole ring of the distal histidine
(His56). The coordinate of the bound iodine atom and the
distances from the iodine atom to a few adjacent amino acid residues
are listed in Table III.
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Typical 127I NMR spectra are shown
in Fig. 3A. An aqueous KI solution (100 mM, pH 6.25) had a very broad 127I NMR signal
with a 1/2 value of approximately 2.0 kHz
(upper panel). The addition of ARP to the KI solution
further broadened the signal (lower panel). The
1/2 values of the I
/enzyme solution
varied linearly with the enzyme concentration but leveled off at about
300 µM (Fig. 3B). pH had a slight effect on
the
1/2 of I
in the absence of the
enzyme (Fig. 3C, open circles), a distinct increase in the
line width of the I
/ARP occurring with a decrease in pH
(Fig. 3C, solid circles). This suggests that protonation of
an ionizable group with pKa of <5.5 has a role in
iodide binding, but the exact pKa value could not be
obtained because the enzyme tended to become insoluble in the acidic
region.
The proton NMR of native ARP at pH 5.5 is shown in Fig.
4A. The hyperfine-shifted spectrum in the
region of 60-90 ppm is characterized by three peaks (a,
b, and c), the size of the last peak being about
twice of that of peaks a and b. The spectral
pattern is similar to that of C. cinereus peroxidase whose
amino acid sequence is almost identical to that of ARP (28, 40, 41).
Therefore, it is most likely that peaks a, b, and
c arise from protons of heme peripheral methyls at 3, 8, and
1 plus 5, respectively. We showed previously that an iodide ion induces
marked changes in both chemical shift and line width of 1- and
8-methyl protons of HRP (18). In the case of ARP, however, these
changes were small compared with those of HRP. The
Kd value for the binding of iodide is estimated to
be 50 mM at pH 5.5 based on the chemical shift and
intensity changes (Fig. 4, B and C).
Effect of pH on the Rate of the Oxidation of Iodide
Previous
studies on the rate of oxidation of iodide with HRP compound I showed
that protonation of an ionizable group with a pKa
value of 4.0 (18) or 4.6 (4) is necessary for the reaction. For
comparison, the rate of the iodide oxidation catalyzed by ARP was
examined in the acidic region. The Lineweaver-Burk plots in Fig.
5 indicate that the apparent Km
values at pH 4.5, 5.0, 5.5, 5.75, and 6.0, respectively, are 13, 16, 23, 34, and 62 mM and that the pKa of
the ionizable group involved in iodide oxidation is estimated to be
5.3, although slight deviations were found in the low and high
concentration regions at pH 6.0 and 4.5.
The x-ray crystallographic analysis reported here shows that the ARP-iodide complex contains only one iodine atom, which is located at the entrance of the access channel to the distal side of the heme, 12.8 Å away from the heme iron (Fig. 1, Fig. 2, and Table III). To our knowledge, this is the first report on the binding site of the electron donor molecule to peroxidase determined by x-ray crystallographic analysis.
When the ARP crystal was soaked in 2 mM KI3 solution containing about 15 mM KI, two triiodide ions bound to one ARP molecule, but no iodide ion was found on the enzyme (45). One of the two triiodide-binding sites, the external one, is close to the iodide-binding site, 4.8 Å from the end iodine atom of the triiodide ion of the external site. Because the distance is slightly larger than the sum of the van der Waals radii of the two iodine atoms (4.3 Å), the fact that no iodine atom was found on the surface of ARP molecule in previous experiments is explained not by simple steric hindrance but by the repulsive force produced by two negative ions and by lower affinity of the iodide ion than the triiodide ion.
It is noteworthy that no iodide ion was found in the heme pocket of ARP in either the present or previous (45) experiments. The absence of iodide ion in the latter case is explained by assuming that iodide, even though once bound, was released by the triiodide, which has a higher affinity for the distal side of the heme. The reason for the absence of iodide ion in the heme pocket of ARP, which is large enough to accommodate even the triiodide ion and involves positively charged groups, however, is not clear.
The binding of iodide to ARP in solution was examined by 127I NMR and 1H NMR. 127I NMR findings showed reversible binding of iodide to ARP with a very fast (less than a millisecond) exchange rate, facilitated by protonation of amino acid residues with a pKa value of <5.5. In contrast, 1H NMR showed that the hyperfine-shifted methyl resonance is scarcely affected by the addition of iodide ion. This agrees with the long (>10 Å) distances between the iodide and the heme periphery methyl group found by x-ray analysis. The 1H NMR results indicate that the iodide-binding affinity is fairly low (Kd = 50 mM at pH 5.5).
Participation of an ionizable group with a pKa value of about 5.3 was suggested from the steady-state kinetics (Fig. 5). Although the residue was not identified, it is likely to be the distal histidine (His56) in view of amino acid residues in the vicinity of the iodide-binding site. It must be noted that chemical modification of the distal histidine (His42 corresponding to the His56 of ARP) in HRP abolished iodide oxidation activity without loss of compound I formation (10, 46). Moreover, we earlier found that, with respect to lactoperoxidase, protonation of an ionizable group with a pKa value of 6.0-6.8, probably the distal histidyl residue, is essential for iodide oxidation (13).
The location of the iodide ion described here is for ARP at the resting state, not for ARP compound I. However, it is unlikely that the binding sites differ, because the surface structure of ARP may not be influenced by the formation of the oxyferryl group, as seen from the ligation of cyanide in ARP (45) and the formation of compound I in cytochrome c peroxidase (47) and catalase (48). The first step of iodide oxidation therefore would be electron transfer from the iodide-binding site reported here to the imidazolium group of the distal histidine. As shown in Fig. 2, direct binding of iodide to the imidazolium of His56 is prevented by several amino acid residues, the distance being about 8 Å. Long range electron transport from the iodide to the imidazole therefore would occur, as in the cytochrome c peroxidase and cytochrome c system (49, 50).
The next step would be electron transfer from the imidazole to the
oxyferryl group of compound I. The accumulated evidence indicates that
a hydrogen bond is formed between the imidazole of the distal histidine
(His42) and the oxyferryl group of HRP compound II
(51-57). This also may be the case for ARP, because a hydrogen bond
between FeCN and the imidazole of His56 is
expected (45). The hydrogen bond may play an important role in the
proton tunneling mechanism in the electron transfer from the imidazole
to the oxyferryl group (58, 59). Further theoretical treatment of
electron transfer will be made on the basis of the information on the
spatial relationship reported here.
The atomic coordinates of the iodide-bound form of ARP (code 1GZA) have been deposited in the Protein Data Bank, Brookhaven National Laboratory, Upton, NY.
We thank Drs. Teruo Amachi, Hideo Tsujimura, and Shunichi Nakamura of Suntory Co. for providing the sample of ARP, Fumiko Amada for assistance with x-ray analysis, and the staff of the Research Center for Protein Engineering, Institute for Protein Research, Osaka University, for the use of R-AXIS IIc. We also are grateful to Dr. Kikuo Tsukamoto of Nagoya City University for helpful discussions of protein structure and to Shoko Kikuchi for assistance with NMR.