Báo cáo khoa học: Neptunium uptake by serum transferrin potx

Combined extended X-ray absorption fine structure spectrometry EXAFS and absorption spectrometry are ideal complementary probes to characterize the Np coordination site in the metalloprot

Isabelle Llorens1, Christophe Den Auwer1, Philippe Moisy1, Eric Ansoborlo1, Claude Vidaud1and Harld Funke2

1 CEA Marcoule, Bagnols sur Ce`ze Cedex, France

2 Rossendorf beamline, Grenoble, France

Metallobiomolecules are considered as elaborated

inor-ganic complexes with well designed metal active sites

Although the various interaction processes between

essential metallic cations and proteins have been widely

studied, focus on the actinide family is more seldom

[1,1a,2] In particular, the interaction of these cations in

the biologically active sites is only partially understood

Sequestration and transport of iron in vertebrates are

carried out by transferrin (Tf), a monomeric

glyco-protein of
80 kDa Crystal structures of transferrins

reveal that these proteins consist of a polypeptide chain

folded in two similar but not identical lobes Each of

them contains one metal binding centre [3,4] Serum Tf

is reported to bind a wide variety of d-block transition

metals, as well as actinides and lanthanides [3,5–7]

Furthermore, Taylor et al have suggested that the

protein is able to stabilize the tetravalent state and

forms stable (M4+)2–Tf complexes [8] This is why Tf

contamination by actinide cations is a critical issue of

nuclear human toxicology The oxidation state IV of

neptunium (Np) has been of particular concern for its

relative stability in physiological conditions and

reacti-vity similarities with both Pu(IV), Th(IV) and Fe(III) Pu(IV) as well as most of the transition metal cations reported to be complexed by Tf are assumed to be located in the iron sites [9] In the case of Fe the donor atoms are provided by two tyrosyl phenolates, one hist-idyl imidazole and one aspartate carboxyl The require-ment of a synergistic bidentate carbonate anion has been confirmed [10] Other synergistic anions have also been reported as the nitrilotriacetic anion (NTA) in the crystallographically characterized structure of Fe(III)(NTA)(Tf) [11] Aspartate has a dual role: it provides an oxygen ligand to the metal and allows the formation of a hydrogen bond, helping stabilization of the lobes in a closed configuration Other residues not directly coordinated to iron also play important roles through hydrogen bonding as described by the crystal structure of MacGillivray et al [12] in which arginine stabilizes the synergistic carbonate

Combined extended X-ray absorption fine structure spectrometry (EXAFS) and absorption spectrometry are ideal complementary probes to characterize the Np coordination site in the metalloprotein On the one hand

Keywords

neptunium; serum transferrin; XAS

Correspondence

C Den Auwer, CEA Marcoule,

DEN ⁄ DRCP ⁄ SCPS, 30207 Bagnols sur Ce`ze

Cedex, France

Fax: +33 4 66 79 63 25

Tel: +33 4 66 79 62 89

E-mail: christophe.denauwer@cea.fr

(Received 26 November 2004, revised 19

January 2005, accepted 8 February 2005)

doi:10.1111/j.1742-4658.2005.04603.x

Although of major impact in terms of biological and environmental haz-ards, interactions of actinide cations with biological molecules are only par-tially understood Human serum transferrin (Tf) is one of the major iron carriers in charge of iron regulation in the cell cycle and consequently con-tamination by actinide cations is a critical issue of nuclear toxicology Combined X-ray absorption spectroscopy (XAS) and near infrared absorp-tion spectrometry were used to characterize a new complex between Tf and

Np (IV) with the synergistic nitrilotriacetic acid (NTA) anion Description

of the neptunium polyhedron within the iron coordination site is given

Abbreviations

EXAFS, extended X-ray absorption fine structure spectrometry; NIR, near infrared; NTA, nitrilotriacetic acid; Tf, transferrin; XAS, X-ray absorption spectroscopy.

spectrometric data provide a fingerprint of the specific

complexation mechanism and on the other hand, in

the EXAFS regime of X-ray absorption spectrometry

(XAS), a quantitative description of the cation

coordi-nation sphere can be achieved

Results and Discussion

To avoid hydrolysis at physiological pH, Np(IV) in

initial stock solution was complexed by NTA Among

the Tf synergistic anions as carbonate, oxalate

or citrate, nitrilotriacetic acid is a well known

chelat-ing agent that can be used for actinide(IV) [13,14]

Fig 1 shows the spectrometric near infrared (NIR)

spectra exhibiting the characteristic absorption band

of Np(IV)aq, Np(IV)(NTA) and Np(IV)(NTA)2

com-plexes at 960, 973 and 980 nm, respectively [14] The

band at 960 nm for Np(IV)aq is spectroscopically

described as an internal 5f)5f transition and is very

sensitive to coordination modification [15] In the

visible range, the spectra also exhibit characteristic

bands at 724, 732 and 740 nm, respectively The

presence of a band at 724 nm and the absence of

any band at 610 nm confirm that the spectral

evolu-tion cannot be attributed to the oxidaevolu-tion of Np(IV)

to Np(V) but is characteristic of the Np(IV)–NTA

complex

To identify the formation of a complex between

apoTf and Np(IV) with the NTA synergistic anion (a)

the titration of Np(IV) with 2.8 equivalents of NTA

by apoTf (Fig 2A) and (b) the titration of apoTf by Np(IV) with 2.8 equivalents of NTA (Fig 2B) has been followed by spectrometry in the NIR and visible regions Fig 2A shows the evolution of the absorption band at 980 nm of Np(IV) in the Np(IV)(NTA)2 com-plex upon apoTf titration The band at 980 nm decrea-ses and a new band appears at 995 nm from [Tf]⁄ [Np] ¼ 0 to [Tf] ⁄ [Np] ¼ 1.27 In the visible region (data not shown) the band at 740 nm decreases and new bands at 747, 732 and 727 nm appear Again, the absence of any band at 610 nm precludes the presence

of Np(V) The LIII edge XANES spectrum of Np in Tf(Np(IV)NTA)2 (data not shown) also confirms the oxidation state (IV) of Np in the complex [absence of any shoulder at around 15 eV above the edge charac-teristic of the transdioxo form in which Np is at oxida-tion state (V) or (VI)]

This result and particularly the isobestic point at

987 nm is a characteristic fingerprint of the formation

of a new Np(IV) complex with Tf and NTA as synergis-tic anion Moreover, the total disappearance of the absorption band that is characteristic of Np(IV)(NTA)2 for two equivalents of apoTf suggests the stoechiometry

1 : 2 for the new complex, as observed for Fe(III) Accordingly, the reaction between apoTf, Np(IV) and NTA can be written as shown in Eqn (1)

2NpðIVÞ þ 2NTA þ apoTf () Tf ðNpðIVÞNTAÞ2 ð1Þ Fig 2B presents the spectrometric evolution of the titration of apoTf by a mixture of Np(IV) with 2.8 equivalents of NTA from [Tf]⁄ [Np] ¼0.68–0.26 At the beginning of the titration process, the two complexes Np(IV)(NTA)2 and Tf(Np(IV)NTA)2 are in equilib-rium according to Eqn (1), as characterized by the two absorption bands at 980 and 995 nm Upon titration and decrease of [Tf]⁄ [Np], disappearance of the charac-teristic absorption band of the Tf(Np(IV)NTA)2 com-plex at 995 nm, the isobestic point at 987 nm and the concomitant increase of the band at 980 nm indicates the formation of Np(IV)(NTA)2 because of the large excess of NTA in the solution This confirms the equi-librium described by Eqn (1) The Np LIII edge EXAFS spectrum and corresponding Fourier transform

of Tf(Np(IV)NTA)2 are presented in Fig 3A and B From the pseudo radial distribution function (R +F), backscattering contributions from the first Np neigh-bours (I) and from second shell contributors (II) are clearly observed In the adjustment of the EXAFS spectrum, the typical coordination number of eight was set for Np(IV) Two oxygen shells with 5.2 atoms

at 2.34 A˚ (r2 ¼ 0.007 A˚2) and 2.8 atoms at 2.56 A˚ (r2¼ 0.025 A˚2) and one carbon shell of 7.4 atoms

at 3.37 A˚ (r2 ¼ 0.009 A˚2) were necessary to obtain a

Fig 1 NIR spectrometry of Np(IV)aq, Np(IV)(NTA) and Np(IV)(NTA)2.

Experimental conditions are as described in Experimental

proce-dures.

satisfactory adjustment (R factor¼ 0.06) The fit

qual-ity is very poor above 3 A˚ because of the high

signal-to-noise ratio and the short data range (only EXAFS

data up to 8.5 A˚)1 were considered because of the

presence of a glitch at 9 A˚)1) These results will be

compared to the structure of the coordinating lobe in

TfFe(III)(NTA) [11] for which iron is coordinated to

two tyrosines at a mean distance of 1.83 A˚ and a

tetradentate NTA (three O at 1.99 A˚ and one N at 2.76 A˚) in a highly distorted octahedral symmetry From a steric point of view, the global increase of the size of the Np coordination sphere vs that of iron(III) can be explained by the increase in ionic radii although the coordination symmetry is radically different between the two cations

A putative model based on the crystal structure of TfFe(III)(NTA) [11] with Np in the Tf iron binding site with two tyrosines, one tetradentate NTA and two additional water molecules was tested Note that it is

Fig 2 NIR spectrometry of Np(IV) (A) Titration of Np(IV) in the

presence of 2.8 equivalents of NTA per Np by apoTf from

[Tf] ⁄ [Np] ¼ 0–1.27 (B) Titration of apoTf by Np(IV) in the presence

of 2.8 equivalents of NTA per Np from [Tf] ⁄ [Np] ¼ 0.68–0.26.

Experimental conditions are as described Experimental procedures.

Fig 3 k3-Weighted EXAFS spectrum (A) and corresponding Fourier transform (B) of Np(IV) in the Tf(Np(IV)NTA)2complex (straight line, experimental data; dots, fit).

impossible to achieve distinction between each

coordi-nation site of each lobe with EXAFS because of their

structural similarity Thus, the two Np cations in the

Tf complex were considered equivalent The

localiza-tion of Np in the iron binding site is in agreement with

previous studies, as referenced above [3] Because the

data resolution is equal to 0.2 A˚ and the technique

averages the signal over all the contributors of similar

backscattering factor (i.e O, N, C), the data fitting is

only indicative of the validity of the putative model

coordination site According to this model, a

satistory agreement with an experimental spectrum (R

fac-tor¼ 0.07) was achieved with single scattering

contributions from the coordination of a tetradentate

NTA molecule as in the Nd(III)(NTA)2(H2O) complex

[16], two tyrosines and two water molecules (no

signifi-cant multiple scattering contributions were needed)

The three carboxylate oxygen atoms of NTA were

refined at 2.35 A˚ (r2¼ 0.009 A˚2) and the

correspond-ing nitrogen atom at 2.63 A˚ (r2¼ 0.001 A˚2), the two

distances being linked together according to the

struc-ture of Nd(NTA)2H2O The two tyrosines were refined

at 2.34 A˚ (r2¼ 0.005 A˚2) and the two additional

water molecules at 2.47 A˚ (r2¼ 0.014 A˚2) In the

sec-ond sphere, the eight carbon atoms were linked to the

corresponding first coordination sphere atoms (three

plus three adjacent to O and N of NTA, plus two

adjacent to O of the tyrosine) and only one Debye

Waller factor was used for all the carbon scattering

paths (r2 ¼ 0.001 A˚2) The average of these distances

compares satisfactorily with the two-shell fit described

previously: five oxygen atoms at 2.35 A˚ (2.34 A˚ in the

two-shell fit) and three oxygen⁄ nitrogen atoms at

2.52 A˚ (2.56 A˚ in the two-shell fit)

From the bond distance point of view, the

Np(IV)–Tf interaction may be compared on the one

hand to that of Nd(III)–NTA in the crystal structure

of Nd(NTA)2(H2O) (2.42 for Nd–O and 2.67 A˚ for

Nd–N) [16] and on the other hand to that of

Ce(IV)–Tf in the crystal structure of TfCe(IV)2 [7]

The shortening of the Np(IV)–Tf distances in the Tf

lobe compared to neodymium is in agreement with

(a) the shortening of the ionic radii at CN¼ 8 from

Nd3+(R(Nd3+)¼ 1.107 A˚ [17]) to Np4+(R(Np4+)¼

0.980 A˚ [17]), and (b) the increase of the ionic charge

from three to four if mainly electrostatic interactions

are considered According to the crystal structure of

TfFe(III)(NTA), the two tyrosine residues are the only

side chain functions available because NTA forces the

Tf lobe to be locked in the open form Thus, the

aspartate and histidine residues are unavailable [11]

The short Np-O(Tyr) distance (2.34 A˚) is in agreement

with the strong basicity of the phenolate group and

agrees with the average value of 2.3 A˚ in the crystal structure of TfCe(IV)2 [7] The overall average Np(IV)–Tf bond distance is equal to 2.42 A˚ and com-pares well with the Ce(IV)–Tf average distance of 2.46 A˚ although the comparison must be taken with care given the difference in coordination numbers [six for Ce(IV)] and the differences in coordination pattern (there is no NTA in the case of Ce) More generally speaking, it compares satisfactorily with other actin-ide(IV) coordination complexes as neptunium oxalate (CN¼ 8, 2.45 A˚ [18] or plutonium-siderophore com-plex (CN ¼ 9, 2.38 A˚ [19] See also reference [1])

We have shown here that the interaction of apoTf with Np at formal oxidation state (IV) leads to the uptake of the cation by the protein A putative model that places the Np cation in the iron binding site with concomitant binding of NTA synergistic anion has been tested by EXAFS and further spectroscopic and theoretical investigations are needed to support this model The average Np–ligand distances are in agree-ment with comparable crystallographic structures in the literature The protein conformation may also be affected by the size of the synergistic anion as in the open form of the coordinating lobe in TfFe(III)(NTA)

In that case, binding to the Tf receptor is impossible and cation transfer inside the cell is disabled Conse-quently, comparison between the lobe conformation in the holo and Np form is also essential

Experimental procedures

Np(IV) stock solution preparation

The stock solution of Np(IV) (24 mm) was prepared by hydroxylamine (310 mm) reduction (60
C) of Np(V) obtained by dissolution of Np(V)O2OHxH2O in hydro-chloric acidic solution nitrilotriacetic acid complexation was achieved with 2.8 equivalents of ligand at pH¼ 4 For protein samples, the buffering solution was Hepes Note that Np (237Np, CEA stock) is a radioactive nucleus and must be manipulated with specific radiological shielding Human serum Tf was provided by Sigma-Aldrich (Paris, France), 97% purity (Aldrich ref T2252)

NIR absorption spectrometry

Data acquisition was carried out at room temperature with

a Shimadzu 3101 spectrophotometer with a 10-mm path length

In Fig 1, the spectra of the Np–nitrilotriacetic acid complexes have been obtained by variation of the solution acidity in the presence of 20 mm NTA from an initial solution of aqueous Np(IV) [Np(IV)]¼ 1.5 mm; HCl, 1 m;

Np(IV)(NTA)1 [HCl, 1 m; NTA, 20 mm]; Np(IV)(NTA)2

[HCl, 0.8 m; NTA, 20 mm]

Fig 2A presents the titration of Np(IV) in the presence of

2.8 equivalents of NTA per Np by apoTf [Hepes, 0.4 m

(pH¼ 7.5); Np(IV), 1.79 mm; NTA, 5.0 mm] The

succes-sive addition of apoTf (powder form) was carried out from

[Tf]⁄ [Np] ¼ 0 to 1.27 Fig 2B presents the titration of apoTf

by Np(IV) in the presence of 2.8 equivalents of NTA per Np

[Hepes, 0.4 m, (pH¼ 7.5); apoTf, 2.35 mm] The volumetric

successive addition of Np(IV)(NTA)2was carried out from

[Tf]⁄ [Np] ¼ 0.68 to 0.26 The composition of the titrating

solution was: Np(IV), 24.4 mm; NTA, 68.3 mm (pH¼ 5.5)

EXAFS

Data acquisition

Np LIII-edge EXAFS spectra were recorded at the ROBL

beamline (BM20) of the European Synchrotron Radiation

Facility (Grenoble, France) The ring was operated at 6 GeV

with a nominal current of 200 mA The beamline is equipped

with a water-cooled double crystal Si(111) monochromator

Higher harmonics were rejected by two Pt coated mirrors A

Ge solid state detector was used for data collection in the

fluorescence mode Dead time corrections were not necessary

because of the low sample concentration Monochromator

energy calibration was carried out with yttrium K-edge at

17052 eV All measurements were recorded at room

tempera-ture, 298 k The composition of the solution is [Np(IV)]¼

0.28 mm; NTA, 0.77 mm; apoTf, 0.14 mm (pH¼ 6.5)

Data analysis and fitting

Data treatment was carried out using EXAFS98 code [20]

Background removal was performed using a pre-edge linear

function Atomic absorption was simulated with a cubic

spline function The extracted EXAFS signal was fitted in

k3CHI(k) without any additional filtering using ARTEMIS

code [21] Due to the low signal to noise ratio above

10 A˚)1 and a glitch at 9 A˚)1, Fourier transform (Kaiser

window) was done between 2.0 and 8.5 A˚)1 Fitting was

carried out in R space between 1.0 and 3.5 A˚ Theoretical

phases, amplitudes and electron mean free path were

calcu-lated with FEFF82 code [22] based on the crystallographic

structures of TfFe(III)(NTA) (PDB code 1NFT) and

Nd(NTA)2(H2O) Oxygen and nitrogen atom contributions

from the first coordination sphere and carbon atoms from

the second coordination sphere were included in the fit

Carbon atom distances were constrained to the

correspond-ing oxygen⁄ nitrogen atoms

Acknowledgement

We thank for financial support the French

Nuclear-Toxicology program, CEA⁄ DEN ⁄ MRTRA

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