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J Biol Chem, Vol. 274, Issue 44, 31291-31296, October 29, 1999
From the For deoxyribonucleotide synthesis during
anaerobic growth, Escherichia coli cells depend on an
oxygen-sensitive class III ribonucleotide reductase. The enzyme system
consists of two proteins: protein Ribonucleotide reductases
(RNRs)1 catalyze the
reduction of ribonucleotides into deoxyribonucleotides and thus provide
the cell with a balanced supply of the DNA precursors (1-3).
Escherichia coli uses different ribonucleotide reductases
during aerobic and anaerobic growth. The active form of the anaerobic
enzyme (class III RNR) is characterized by the presence of a
catalytically essential glycyl radical and an iron-sulfur center as
well as the requirement for formate as the hydrogen donor (4-6). It is
found in other anaerobically growing microorganisms among bacteria,
phages, and methanogens (7).
The anaerobic RNR was originally isolated as a dimeric The small Second, whereas the presence of an iron-sulfur center was suggested
early from the light absorption properties of the enzyme and from iron
and sulfide analysis (15), very little iron could be retained during
purification of the protein. However, treatment of the Third, EPR and Mössbauer spectroscopies of the protein after
reduction with photoreduced deazaflavin or dithionite showed that the
reduced centers were almost exclusively [4Fe-4S] cubane clusters (5,
16). The reductive [2Fe-2S] to [4Fe-4S] conversion is a remarkable
reaction, even though it has been recently also observed with other
iron-sulfur proteins, such as the transcription factor FNR, the
activating enzyme of the pyruvate formate-lyase and biotin synthase
(17-19). Whether the [4Fe-4S] center, in the reduced anaerobic
ribonucleotide reductase, was at the interface of two Fourth, formation of the glycyl radical was shown to depend on the
one-electron reduction of S-adenosylmethionine by the
reduced [4Fe-4S]1+ center (20). It was proposed that
reduced AdoMet can undergo homolysis of the S Here we report evidence that previous models for the iron center of RNR
need to be revised. As a matter of fact, we show, by stricter adherence
to high quality anaerobic conditions probably not achieved in previous
studies, that each Materials
Enzymes and other components of the anaerobic ribonucleotide
reductase system have been obtained as described previously (5, 8-10,
20, 21) 57Fe2O3 was converted into
its chloride form by dissolving it in hot, concentrated (35%)
hydrochloric acid of analytical grade (Carlo Erba) and repetitively
concentrated in water.
Fe(NH4)2(SO4)2 was from
Aldrich. AdoMet was from Roche Molecular Biochemicals. 5-Deaza-7,8-demethyl-10-methyl-isoalloxazine (5-DAF) was available in
our laboratory. Ferredoxin IV from Rhodobacter capsulatus
and pyruvate:ferredoxin oxidoreductase from Clostridium
pasteurianum were provided by Dr. Y. Jouanneau and Dr. J. M. Moulis, respectively (CEA, Grenoble, France).
Analysis
Protein concentration was determined by the method of Bradford
(22), standardized by amino acid analysis of each different protein.
Protein-bound iron was determined under reducing conditions with
bathophenantroline disulfonate after acid denaturation of the protein
(23) and labile sulfide by Beinert's method (24).
Methods
Reconstitution of the Iron-Sulfur Center of the RNR Activity--
Activity assays were performed under anaerobic
conditions inside a glove box. The assay comprised two steps, the
activation step, which leads to the formation of the glycyl radical,
and the reduction step, in which CTP is reduced to dCTP. In the first step, 4 µg of the large
In the second step, 15 µl of a substrate mixture (giving a final
concentration of 1.4 mM [3H]CTP (20-30
cpm/pmol), 1 mM ATP, 10 mM MgCl2)
were added to initiate the reduction of the substrate. The reaction was
stopped after 20 min by moving the reaction solution outside of the
glove box (exposing it to air) and adding to it 0.5 ml of 1 M HClO4. The solution was then worked up as
described earlier (8). One unit of enzyme activity is defined as the
formation of 1 nmol of dCTP/min.
UV-visible Absorption Spectroscopy--
UV-visible spectra of
aerobic samples were recorded with a Cary 1 Bio (Varian)
spectrophotometer. Spectra could be also recorded inside the glove box
using a Hewlett-Packard 8453 diode array spectrophotometer equipped
with optical fibers connected to a cell holder inside the box.
EPR Spectroscopy--
EPR first derivative spectra were recorded
on a Bruker EMX (9.5 GHz) EPR spectrometer equipped with an ESR 900 helium flow cryostat (Oxford Instruments). Double integrals of the EPR
signals were evaluated by using a computer on-line with the
spectrometer. Spin concentrations in the protein samples were
determined by calibrating double integrations of the EPR spectra with a
standard sample of a [2Fe-2S]1+ protein (62 µM
ferredoxin IV of R. capsulatus).
Reduction of Iron-Sulfur Centers--
Reduction of iron-sulfur
centers were performed inside the anaerobic glove box. 5-DAF was
dissolved in Me2SO, diluted with water to 500 µM, and stored inside the box in the dark. Protein Mössbauer Spectroscopy--
57Fe
Mössbauer spectra were recorded on 200-µl cups containing the
protein (0.25 mM) with a conventional constant acceleration spectrometer using a 57Co source in a Rh matrix (254 Mbq).
Measurements at 4.2 and 77 K were performed using a bath cryostat
(Oxford Instruments) with an electromagnet mounted outside the
cryostat, producing a field of 20 mT perpendicular to the Anaerobic Reconstitution of the Apoprotein
The apoprotein form of protein Iron and Sulfide Content--
Sample A contained 3-4 iron and
3-4 sulfur atoms/protein Light Absorption Spectroscopy--
Samples A and B displayed
significantly different UV-visible spectra (Fig.
1). The time course for conversion of
sample A to B, under exposure to air, could be monitored by light
absorption spectroscopy (data not shown). The reaction is a rather slow
process (t1/2 = 25 min at 11 °C) for which sample
B is the true final product, not further transformed in a time scale of
hours. Spectrum B was like that of sample C, with a band at 420 nm
together with a broad band at 590 nm. Spectrum A was twice as intense
at 420 nm and had no band at 590 nm. In the anaerobic box, sample A was
stable for days.
EPR Spectroscopy--
Sample C was EPR-silent as were previously
published comparable preparations. Even though most of the B
preparations were also EPR-silent, in some cases a small EPR signal
could be detected, which was characteristic of a
[3Fe-4S]+ center and accounted for less than 10% of
total iron (data not shown). Sample A was also most often EPR-silent,
but in some cases a small EPR signal could be observed, accounting for
about 0.1 spin/
Anaerobic reduction of samples A and B with photoreduced deazaflavin or
dithionite generated an EPR signal (shown in Fig. 2 for sample A) characteristic for a
S = 1/2 species, with g values at 2.03 and 1.93. The
temperature dependence and the microwave power saturation properties
are consistent with a [4Fe-4S]+ center (Fig. 2,
inset). A and B spectra were very similar in shape and
properties to that of the anaerobically reduced sample C, as prepared
for this work or previously reported (5, 20). However, quantitation of
the EPR signal of sample A demonstrated that the amount of spins
accounted for approximately 0.7-0.8 S = 1/2 species per
polypeptide. This was the first time that such a large amount of signal
could be obtained, because previous work could not show more than
0.3-0.45 S = 1/2 species per polypeptide (5, 16), amount
also found here for samples B and C.
Mössbauer Spectroscopy--
In Fig.
3A, the Mössbauer
spectrum of an EPR-silent sample A is shown, measured at 77 K in an
external field of 20 mT perpendicular to the
From Fig. 4A, it is clear that
the signal corresponding to the [4Fe-4S]2+ center has
greatly decreased in sample B and now accounts only for 24%. From one
experiment to another, this amount varied from 15 to 25%. The second
doublet (76%) in sample B shows parameters ( Enzyme Activity--
The enzyme reaction consists of two steps. In
the first one, the enzyme is activated by introducing the glycyl
radical into protein
As shown in Fig. 5, sample A, with
[4Fe-4S] centers, and sample B, derived from sample A by oxidation,
were assayed for CTP reduction and compared. The addition of increasing
amounts of protein
This model was further supported by the data shown in Fig.
5B, in which the specific activity of protein The ribonucleotide reductase from anaerobically grown E. coli is an enzyme that is extremely sensitive to oxygen, which
makes it particularly difficult to handle. We previously showed that the glycyl radical reacted instantaneously during exposure to air,
resulting in fragmentation of protein The reactivity of the iron center explains why various forms can be
obtained during reconstitution of the apoprotein, depending on the
quality of the anaerobiosis. Previous preparations of reconstituted protein During exposure to air, the cluster is oxidized and loses two iron
atoms, which can be removed during filtration of the protein. That it
is converted mainly into a [2Fe-2S]2+ cluster is shown by
a decreased intensity of the light absorption band at 420 nm and by
characteristic Mössbauer parameters. The spectroscopic properties
and the enzyme activity of this oxidized form are identical to those of
the previously reported reconstituted forms, containing [2Fe-2S]
centers (16).
It is thus now clear that the protein This [4Fe-4S] to [2Fe-2S] conversion is unlikely to have functional
relevance. As a matter of fact, inside anaerobically growing cells, the
reducing conditions are strong enough to maintain a [4Fe-4S] center,
which probably shuttles between the two redox states,
[4Fe-4S]2+ and [4Fe-4S]+. However, we
cannot exclude the possibility that during transient exposure to air,
the enzyme experiences a 4Fe to 2Fe conversion. This conversion could
be beneficial for the cell because it would switch off the formation of
the glycyl radical and prevent oxygen-dependent cleavage of
the polypeptide at the glycine site (27). Furthermore, by limiting the
loss of protein-bound iron, it would allow faster reconstitution of the
cluster after restoring anaerobic conditions.
The present data now also rule out the previous suggestion that the
[4Fe-4S] clusters, generated during reduction of the [2Fe-2S] forms
of the protein The anaerobic ribonucleotide reductase presents a number of
similarities with another enzymatic system of the anaerobic metabolism, the pyruvate formate-lyase (PFL). As a matter of fact, the PFL activating enzyme contains an iron center that is involved in the
reduction of AdoMet by reduced flavodoxin and the generation of a
glycyl radical on PFL (29, 30). Recently it was shown that this iron
center was a [4Fe-4S] center that can be interconverted to a
[2Fe-2S] center depending on the redox conditions (18, 31). The
results reported here thus further extend the similarity between the
PFL and the anaerobic RNR systems. Protein The improved anaerobic conditions and the higher amount of iron present
in the preparations of protein Thus, whereas a tight association between radical-free protein *
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
To whom correspondence should be addressed. Tel:
33-4-76-88-91-03; Fax: 33-4-76-88-91-24; E-mail:
fontecav@cbcrb.ceng.cea.fr.
The abbreviations used are:
RNR, ribonucleotide
reductases;
AdoMet, S-adenosylmethionine;
5-DAF, 5-deaza-7,8-demethyl-10-methyl-isoalloxazine;
mT, millitesla;
PFL, pyruvate formate-lyase.
The Anaerobic Ribonucleotide Reductase from Escherichia
coli
THE SMALL PROTEIN IS AN ACTIVATING ENZYME CONTAINING A
[4Fe-4S]2+ CENTER*
,,¶
Laboratoire de Chimie et Biochimie des
Centres Rédox Biologiques, Commissariat à l'Energie
Atomique (CEA)/Département de Biologie Moléculaire et
Structurale/Chimie et Biochimie 1087 CNRS, Université Joseph
Fourier, 17 rue des Martyrs, 38054 Grenoble, Cédex 9, France and
§ Institut für Physik, Medizinische
Universität, D-23538 Lübeck, Germany
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
, on which ribonucleotides bind
and are reduced, and protein 
, of which the function is to introduce
a catalytically essential glycyl radical on protein . Protein can assemble one [4Fe-4S] center per polypeptide enjoying both the
[4Fe-4S]2+ and [4Fe-4S]1+ redox state, as
shown by iron and sulfide analysis, Mössbauer spectroscopy
(
= 0.43 mm·s
1, 
EQ = 1.0 mm·s1, [4Fe-4S]2+), and EPR
spectroscopy (g = 2.03 and 1.93, [4Fe-4S]1+). This
iron center is sensitive to oxygen and can decompose into stable
[2Fe-2S]2+ centers during exposure to air. This degraded
form is nevertheless active, albeit to a lesser extent because of the
conversion of the cluster into [4Fe-4S] forms during the strongly
reductive conditions of the assay. Furthermore, protein has the
potential to activate several molecules of protein , suggesting that
protein is an activating enzyme rather than a component of an
22 complex as previously claimed.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
2
(160 kDa) inactive form that could be activated by anaerobic incubation with a complex activating system consisting of
S-adenosylmethionine (AdoMet), a reducing system (NADPH,
flavodoxin reductase, and flavodoxin), and an additional 17-kDa protein, provisionally called activase (8, 9). During the reaction, a
radical is introduced at a specific glycine residue (Gly-681) of
protein . The activated protein , encoded by the nrdD
gene, thus contains the glycyl radical, the substrate site, and two
additional sites where allosteric effectors (deoxyribonucleotides) bind
and regulate the activity (4, 10-12). The recently determined
three-dimensional structure of a mutant form of the enzyme from
bacteriophage T4, in which the essential glycine has been changed to an
alanine, suggests that the function of the radical is to abstract a
hydrogen atom from an adjacent cysteine close to the substrate (13). The resulting thiyl radical is then supposed to initiate the reaction by removing the 3'-hydrogen atom of the ribose (14). How reduction by
formate and formation of the deoxyribonucleotide proceed from the sugar
radical remains to be established.
protein, encoded by the nrdG gene, proved to
be an unusual enzyme. First, in solution in the absence of the large protein, it occurred in a monomer-polymer equilibrium, with and
2 being the major species. The addition of protein
2 shifts the equilibrium to the 2 form
and results in a very tight 1:1 complex between dimers of the two
proteins, as shown from sucrose gradient centrifugation (5) and from
the impossibility of separating them during gel filtration or by
affinity chromatography on dATP-Sepharose gel, on which only protein
can bind because of its affinity for dATP (5, 10). It was thus
concluded that 2 was not an activating enzyme but rather
a component of the system and that the anaerobic ribonucleotide
reductase had an 22 structure (5).
protein with
ferrous iron and sulfide generated a well defined
[2Fe-2S]2+ cluster, as shown from Mössbauer and
Raman resonance spectroscopy (16).
polypeptide
chains was first suggested as a likely possibility but not firmly
established experimentally (5).
C(5'-deoxyadenosyl) bond
to generate methionine and the 5'-deoxyadenosyl radical, presumably
responsible for abstraction of the hydrogen atom of the glycine residue.
polypeptide has the ability to chelate 4 iron
and 4 sulfur atoms per polypeptide chain, and we conclude that is a
[4Fe-4S]2+ and not, as previously reported, a
[2Fe-2S]2+ enzyme. The [2Fe-2S]2+ center is
in fact an air-degraded form of the cluster, which is convertible back
to the [4Fe-4S] form under strong reducing conditions. The previous
hypothesis that such a reduced cluster sits at the interface of the
dimer has to be rejected. Furthermore, experiments are shown that
demonstrate that , with its [4Fe-4S] center, appears to function
more like an activase for protein 2 than as a component
of an 22 complex.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
Protein--
All of the steps of the reconstitution procedure were
done anaerobically inside a glove box (Jacomex BS531 NMT) in an
N2 atmosphere containing less than 2 ppm O2.
The apoenzyme was incubated with a 6-fold molar excess of
Na2S and either
Fe(NH4)2(SO4)2 or
57FeCl3 in 0.1 M Tris-HCl, pH 8.0, in the presence of 5 mM dithiothreitol for 2 h at
18 °C followed by incubation with 2 mM EDTA for 30 min.
After chromatography through a Sephadex G-25 column equilibrated with
the same buffer, the colored fractions (sample A) were collected and
concentrated over a YM10 Diaflo membrane (Amicon). Alternatively, protein was reconstituted outside the box as described previously (16), within tubes connected to a manifold under a constant flux of
moist N2, and then gel-filtrated on a Sephadex G-25 column equilibrated with N2-bubbled buffer. In this case, the
protein was concentrated under aerobic conditions (sample C).
protein in a final volume of 35 µl were incubated during 45 min with different amounts of the protein in
the presence of 10 mM sodium formate, 30 mM
KCl, 500 µM AdoMet, 20 µg/ml flavodoxin, 40 µg/ml
flavodoxin reductase, 1.25 mM NADPH, and 10 mM
dithiothreitol in 30 mM Tris-HCl buffer, pH 8.0.
(100 µM) was prepared in 100 mM Tris-HCl, pH
8.0, and irradiated in the presence of 5-DAF (20-50 µM)
for 60 min. Reduction could be monitored by light absorption directly
inside the box. To avoid exposure to oxygen, EPR tubes were frozen
directly inside the box in a well filled with isopentane cooled from
outside the box by liquid nitrogen.
-ray.
High-field measurements were performed with a cryostat equipped with a
superconducting magnet (Oxford Instruments). The spectra were analyzed
assuming Lorentzian line shape, and the isomer shift is quoted relative
to -Fe at room temperature.
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
--
The basis of
this work was the suspicion that previous preparations of the small
component of the anaerobic ribonucleotide reductase suffered from
insufficient anaerobiosis. This led us to use a high quality anaerobic
glove box and to carry out all experiments within the box. To avoid any
contamination of protein samples with oxygen, also during light
absorption spectroscopic analysis, the glove box was equipped with
optical fibers, which allowed samples to be monitored
spectrophotometrically directly inside the box.
was obtained in large quantities by
purification from overexpressing E. coli cells (5). It was
incubated in the box in the presence of a 6-fold excess of sodium
sulfide and ferrous sulfate, with respect to , and dithiothreitol.
After a 2-h reaction at 18 °C, the sample was desalted by
chromatography on a Sephadex G-25 column inside the box. This
preparation was called sample A. A portion of this preparation was
opened to air outside the box for 1 h at 4 °C and then
desalted, to give sample B. A third sample, C, prepared under the
previously reported conditions and characterized as a [2Fe-2S]
protein, with one [2Fe-2S] center per polypeptide chain, was used for
comparison (16). All three samples were assayed for iron and sulfur
content, light absorption, EPR and Mössbauer spectroscopic
properties, and ribonucleotide reduction activity. Spectra of sample C
were found to be identical to earlier published preparations of the same type (16), showing the reproducibilty of the reconstitution procedure and thus are not shown here.
, with slight variations from one
preparation to another. Under these conditions, we never obtained
1.8-2 iron and sulfur atoms/chain, as previously reported (16) and as
for sample C. Sample B contained only 1.7-2 iron and 1.8-2 sulfur
atoms/chain, showing that about half of the iron and sulfide content
was lost during the exposure of sample A to air.
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Fig. 1.
UV-visible light absorption spectra of
the protein (40 µM) in 50 mM Tris-HCl, pH 8, after reconstitution inside the glove box (solid line,
sample A) and after exposure to oxygen (dashed line,
sample B).
polypeptide and similar to that obtained during
reduction of samples A, B, and C (see below).
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Fig. 2.
X-band EPR spectrum of the reduced
protein (100 µM) in 50 mM
Tris-HCl, pH 8. Sample A was incubated for
1 h with 30 µM photoreduced 5-DAF. The spectrum was
recorded under the following conditions: temperature, 10 K; microwave
power, 0.16 milliwatts; modulation amplitude, 1 mT. Inset,
microwave power (P) saturation curve of the EPR signal of
the reduced protein (
). The EPR signal amplitudes (h)
were normalized to the maximum value (h0). Standard
samples were ferredoxin IV [2Fe-2S]+ from R. capsulatus (
) and pyruvate:ferredoxin oxidoreductase
[4Fe-4S]+ from C. pasteurianum (
).
-ray. The spectrum
consists of two doublets. One doublet ( = 0.43 mm·s1, EQ = 1.0 mm·s1, 82%) is typical for tetrahedrally
sulfur-coordinated Fe2.5+ as in [4Fe-4S]2+
centers. The diamagnetic nature of the major component is confirmed from the Mössbauer spectrum taken at 4.2 K with an applied field of 7 T parallel to the -ray (Fig. 3B). Actually, this
component could be simulated using the nuclear Hamiltonian only. The
other doublet shows parameters ( = 0.86 mm·s1, EQ = 2.07 mm·s1, 18%) for partially sulfur-coordinated
Fe2+ and most probably corresponds to a monomeric species
(simulated with parameters for reduced Rubredoxin (26) with slightly
changed hyperfine coupling tensor, i.e.
Axx = 
13 T,
Ayy = 6 T,
Azz = 32 T). The presence
of small amounts of ferrous iron is not surprising because sample A is
obtained by incubating ferrous sulfide with apoprotein under
anaerobiosis.
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Fig. 3.
Mössbauer spectra of sample A taken at
77 K in an external field of 20 mT perpendicular to the
-ray (A) and at 4.2 K in an
external field of 7 T parallel to the -ray
(B). Dotted line,
[4Fe-4S]2+ (82%); dashed line,
mononuclear Fe2+ (18%).
= 0.3 mm·S1, EQ = 0.56 mm·s1) typical for tetrahedrally
sulfur-coordinated high spin Fe3+ as in
[2Fe-2S]2+ centers. These parameters are comparable with
those previously reported for a C-type sample (16). Again, that these
two components were diamagnetic, thus excluding the presence of
[3Fe-4S] centers, was demonstrated from the Mössbauer spectrum
taken at 4.2 K with an applied field of 7 T parallel to the -ray
(Fig. 4B). Note that this B preparation was EPR-silent.
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Fig. 4.
Mössbauer spectra of sample B taken at
77 K in an external field of 20 mT perpendicular to the
-ray (A) and at 4.2 K in an
external field of 7 T parallel to the -ray
(B). Dotted line,
[4Fe-4S]2+ (24%); dashed-dotted line,
[2Fe-2S]2+ (76%).
, during anaerobic incubation of a mixture of
protein and protein , with enzymatically reduced flavodoxin and
AdoMet. In the second step, CTP is added in the same anaerobic tube,
and the active enzyme catalyzes the reduction of CTP to dCTP by
formate. The assay measures the amount of dCTP formed in the second step.
to a fixed amount of protein (4 µg), with
an activation period fixed at 45 min, generated the results shown in
Fig. 5A. The system became saturated with respect to protein
, in both cases with the same maximal specific activity. When the
same experiment was done with sample C, containing [2Fe-2S] centers,
the results obtained were superimposable on those obtained with sample
B (data not shown). However, saturation in the case of samples B and C occurred at significantly larger amounts of protein than in the case of
sample A (Fig. 5). For example, whereas saturation was obtained for a
: ratio of 0.1 for sample A, a : ratio of 0.4 was required
for samples B and C. These data now suggest that is an activating
enzyme capable of generating a glycyl radical in several molecules of
protein rather than a component of an 22 holoenzyme.
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Fig. 5.
Enzyme activity as a function of the
to ratio
(A) and a function of the activation time
(B). A, protein (4 µg) was
activated during 45 min with increasing amounts of the protein
(samples A () and B (
)) and assayed for CTP reduction.
B, protein was activated during increasing times with
sample A in a / molar ratio of 0.03 (), 0.06 (), and 0.20 (
). Specific activity is given in units/mg of protein.
is
reported as a function of the activation time for three different
amounts of protein (sample A), substoichiometric with regard to
protein . In fact, with a : ratio of 0.2, full activity was
obtained for an activation period of less than 5 min. When this ratio
was decreased to 0.06, full activity could also be obtained but only because of an extended activation time (about 40 min). With a :
ratio of 0.03, as much as 75% of the activity was obtained after a
50-min activation time.
DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and irreversible inactivation
of the enzyme (8, 27). More recently we showed that the fully reduced
iron cluster, identified as a [4Fe-4S]+ center and
responsible for AdoMet reduction and glycyl radical formation, was also
sensitive to oxygen and degraded into 3Fe and 2Fe clusters during
exposure to air (28).
contained [2Fe-2S] centers exclusively, as shown by a
combination of different spectroscopies (16). Now, by improving the
anaerobic conditions and working exclusively within an anaerobic glove
box, we show that the reconstituted protein can assemble a
[4Fe-4S]2+ center with two ferric and two ferrous ions
per polypeptide chain. Iron and sulfur analysis and UV-visible and
Mössbauer spectroscopies unambiguously support such a conclusion.
In particular, the Mössbauer parameters ( = 0.43 mm·s1, EQ = 1.04 mm·s1) of the major iron species (80-90% of the total
iron) are typical for Fe2.5+ centers, present in
[4Fe-4S]2+ clusters. A significant amount of mononuclear
sulfur-coordinated Fe2+ was also observed. In some cases,
probably because of optimal anaerobic conditions, a small amount of
reduced [4Fe-4S]+ center can be retained during
reconstitution, as shown by EPR spectroscopy of the reconstituted
protein . In any case, reduction with photoreduced deazaflavin
afforded large amount of S = 1/2 [4Fe-4S]1+ cluster.
of the anaerobic
ribonucleotide reductase is a [4Fe-4S] protein and that imperfect anaerobiosis was responsible for iron oxidation and labilization during
reconstitution of the iron center and the preparation of a [2Fe-2S]
protein. However, that previous preparations contained degraded forms
of the cluster could not be easily concluded from enzyme activity
because, as previously shown, the [2Fe-2S] centers of the protein
have the potential, during the reductive conditions of the enzyme
assay, to generate an active [4Fe-4S] center (15).
, are localized at the interface of two polypeptides (5). Instead, it is likely that during reduction iron is
mobilized to generate (4Fe-4S) centers in half of the polypeptides
(16).
and the PFL activase
also share some sequence homology, with a common CXXXCXXC motif, which presumably provides the
cysteines for binding iron (18). This sequence is also found in the
case of biotin synthase, which catalyzes the conversion of dethiobiotin
to biotin. Biotin synthase is a homodimer containing one [2Fe-2S]
center per monomer, which under reduction generate a [4Fe-4S] center (19). It is tempting to suggest that also in that case the enzyme is
designed to assemble [4Fe-4S] centers and that the reported preparations are oxidized forms of the enzyme.
of the anaerobic RNR now available
also explain another unexpected observation reported here. The
holoenzyme was previously characterized as a tight
22 complex, in agreement with sucrose
gradient centrifugation studies and behavior on the affinity
dATP-Sepharose column (5). In contrast, we now report that full
activity of protein is obtained with a catalytic amount of protein
, showing that one molecule of protein is able to create a
glycyl radical in several molecules of protein . Therefore protein
cannot be considered any longer as a component of an
22 holoenzyme, as previously stated, but
rather as an activating enzyme ("activase") associated with protein
, the proper ribonucleotide reductase. This property again
strengthens the similarity between the PFL and the anaerobic RNR systems.
and
oxidized protein undoubtedly occurs (5), this does not appear to be
the case during enzyme activation. Several parameters, by themselves or
in combination, might therefore affect this interaction: (i) the
binding of flavodoxin to protein ; (ii) the reduction of the
iron-sulfur cluster of protein ; (iii) the introduction of the
glycyl radical in protein . This important aspect of the activation
reaction deserves further investigation.
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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