Báo cáo Y học: Effect of ibuprofen and warfarin on the allosteric properties of haem– human serum albumin A spectroscopic study potx

Effect of ibuprofen and warfarin on the allosteric properties ofhaem– human serum albumin A spectroscopic study Simona Baroni1, Marco Mattu2, Alessandro Vannini2, Rita Cipollone2, Silvio

Effect of ibuprofen and warfarin on the allosteric properties of

haem– human serum albumin

A spectroscopic study

Simona Baroni1, Marco Mattu2, Alessandro Vannini2, Rita Cipollone2, Silvio Aime1, Paolo Ascenzi2and Mauro Fasano3

1 Department of Chemistry ‘IFM’, University of Torino, Italy;2Department of Biology, University ‘Roma Tre’, Rome, Italy;3Department of Structural and Functional Biology, University of Insubria, Italy

Haem binding to human serum albumin (HSA) endows the

protein with peculiar spectroscopic properties Here, the

effect of ibuprofen and warfarin on the spectroscopic

properties of ferric haem – human serum albumin (ferric

HSA – haem) and of ferrous nitrosylated haem – human

serum albumin (ferrous HSA – haem-NO) is reported Ferric

HSA – haem is hexa-coordinated, the haem-iron atom being

bonded to His105 and Tyr148 Upon drug binding to the

warfarin primary site, the displacement of water

molecu-les 2 buried in close proximity to the haem binding

pocket 2 induces perturbation of the electronic absorbance

properties of the chromophore without affecting the

coordination number or the spin state of the haem-iron,

and the quenching of the 1H-NMR relaxivity Values of

Kd for ibuprofen and warfarin binding to the warfarin

primary site of ferric HSA – haem, corresponding to the

ibuprofen secondary cleft, are 5.4 ^ 1.1  1024M and

2.1 ^ 0.4  1025M, respectively The affinity of ibuprofen

and warfarin for the warfarin primary cleft of ferric HSA – haem is lower than that reported for drug binding to haem-free HSA Accordingly, the Kdvalue for haem binding to HSA increases from 1.3 ^ 0.2  1028Min the absence of drugs to 1.5 ^ 0.2  1027Min the presence of ibuprofen and warfarin Ferrous HSA – haem-NO is a five-coordinated haem-iron system Drug binding to the warfarin primary site

of ferrous HSA – haem-NO induces the transition towards the six-coordinated haem-iron species, the haem-iron atom being bonded to His105 Remarkably, the ibuprofen primary cleft appears to be functionally and spectroscopically uncoupled from the haem site of HSA Present results represent a clear-cut evidence for the drug-induced shift of allosteric equilibrium(a) of HSA

Keywords: allostery; haem – human serum albumin; human serum albumin; ibuprofen; warfarin

Human serum albumin (HSA), the most prominent protein

in plasma, is best known for its exceptional ligand binding

capacity, the most strongly bound compounds being

hydrophobic organic anions of medium size, long-chain

fatty acids, haem and bilirubin Smaller and less

hydrophobic compounds (e.g tryptophan) are held less

strongly, but their binding can still be highly specific For

many compounds, HSA provides a depot so they will be

available in quantities well beyond their solubility in

plasma Moreover, HSA abundance (concentration of

45 mg:mL21 in the serum of human adults) makes it an

important determinant of the pharmacokinetic behaviour of

many drugs In other cases, HSA holds some ligands in a

strained orientation, allowing their metabolic modification,

and renders potential toxins harmless by transporting them

to disposal sites HSA also accounts for most of the antioxidant capacity of human serum, either directly or by binding and carrying radical scavengers, or by sequestering transition metal ions with pro-oxidant activity Finally, HSA acts as a nitric oxide depot and carrier, leading to covalent modification(s) of (macro)molecules [1 – 8]

The amino acid sequence of HSA shows the occurrence of three homologous domains, probably arising from divergent evolution of a degenerated ancestral gene followed by a fusion event However, the three domains deduced from the primary structure do not correspond to domains found in the three-dimensional model Rather, terminal regions of sequential domains contribute to the formation of inter-domain helices linking inter-domain I to II, and II to III, respectively On the other hand, each domain is known to consist of two separate sub-domains, connected by a random coil Therefore, HSA can be considered as an ensemble of four globular domains, namely IA, IB 1 IIA, IIB 1 IIIA, and IIIB, freely linked by extended random coils It is thus reasonable to hypothesize allosteric conformational tran-sition(s) occurring in HSA upon ligand binding Note that the flexibility of the HSA structure allows it to adapt readily to ligands and that its three-domain design provides

a variety of binding sites In particular, the conformational adaptability of HSA involves more than the immediate

Correspondence to M Fasano, Department of Structural and Functional

Biology, University of Insubria, Via Jean H Dunant 3, I-21100 Varese,

Italy Fax: 1 39 0332 421500, Tel : 1 39 0332 421523,

E-mail: mauro.fasano@uninsubria.it

Note: S Baroni and M Mattu contributed equally to this work.

(Received 2 July 2001, revised 27 September 2001, accepted 3 October

2001)

Abbreviations: HSA, human serum albumin; ferric HSA – haem, ferric

haem – human serum albumin; ferrous HSA – haem-NO, ferrous

nitrosylated haem – human serum albumin.

vicinity of the binding site(s), affecting both the structure

and the ligand binding properties of the whole HSA

molecule [1 – 11]

The interaction of ligands with HSA occurs mainly in two

regions According to the Sudlow’s nomenclature, bulky

heterocyclic anions bind to site I (located in subdomain IIA),

whereas site II (located in subdomain IIIA) is preferred by

aromatic carboxylates with an extended conformation

Remarkably, ibuprofen, a nonsteroidal anti-inflammatory

agent [12], and warfarin, an anticoagulant drug [12], are

considered as stereotypical ligands for Sudlow’s site II and

Sudlow’s site I, respectively [1,9,11,13,14] Ibuprofen binds

to Sudlow’s site II with Kd¼ 3.7  1027

M[1,15], whereas warfarin binds to Sudlow’s site I with Kd¼ 3.0  1026

M

[1,16 – 18] Secondary binding clefts have been found for

ibuprofen and warfarin to be located on domain I

Remarkably, the ibuprofen secondary site corresponds to

the warfarin primary cleft (i.e to Sudlow’s site I) [1,3,11]

Moreover, multiple recognition sites for binding of

anaesthetics, fatty acids, and triiodobenzoic acid to HSA

have also been identified [2,5,6,14,19]

Among hydrophobic molecules, haem binding to HSA is

of peculiar relevance for the haem iron reuptake following

hemolytic events [1,20] The haem binding site has been

located primarily at the interface between domains I and II

of HSA, while on domains II and III secondary binding

clefts have been found [3,7,10] The binding of this

spectroscopically active label to HSA makes it possible to

follow a number of events involving the holoprotein by

taking advantage of electronic absorption spectroscopy,

EPR spectroscopy and1H-NMR relaxometry [7,8,10,21,22]

Here, the effect of ibuprofen and warfarin on the electronic

absorption spectroscopic and1H-NMR-relaxometric

proper-ties of ferric haem – human serum albumin (ferric HSA –

haem) as well as on the EPR spectroscopic properties of

ferrous nitrosylated haem – human serum albumin (ferrous

HSA – haem-NO) is reported

M A T E R I A L S A N D M E T H O D S

HSA, haem chloride, ibuprofen (Fig 1), warfarin (see

Fig 1), and the NO-donor S-nitroso-N-acetylpenicillamine

were from Sigma Gaseous NO was purchased from Aldrich

Chemical Co All the other products were from Merck AG

All chemicals were of analytical or reagent grade and used

without further purification

Ferric HSA – haem was prepared by adding 0.83-Mdefect

of ferric haem, dissolved in 1.0  1021MKOH, to an HSA

solution, in 1.0  1021M phosphate buffer plus

1.0  1021M NaCl, pH 7.0 [8,21] Both in the absence

and presence of ibuprofen and warfarin, haem binds to

HSA mostly at the high affinity site and virtually no free

haem is present in solution (see [1,8,21], and present study)

Values of the apparent dissociation equilibrium constant

(Kd) for haem binding to the HSA primary site are

1.3 ^ 0.2  1028 M in the absence of drugs, and

1.5 ^ 0.2  1027M in the presence of ibuprofen and

warfarin (5.0  1022M) (see [1,22,23] and the present

study)

Ferrous HSA – haem-NO was obtained under anaerobic

conditions: (a) by sequential addition of a 10-M excess

of sodium dithionite or sodium ascorbate and a 4- excess of

KNO2 to ferric HSA – haem, in 1.0  1021M phosphate buffer plus 1.0  1021M NaCl, pH 7.0; (b) by blowing purified NO over the ferric HSA – haem solution (1.0  1021M phosphate buffer plus 1.0  1021M NaCl,

pH 7.0), in the absence and presence of a 5-M excess of sodium dithionite or sodium ascorbate; and (c) by sequential addition of a 10-Mexcess of dithiothreitol and a 4-Mexcess

of S-nitroso-N-acetylpenicillamine (which releases NO) to ferric HSA – haem, in 1.0  1021M phosphate buffer plus 1.0  1021MNaCl, pH 7.0 [8,21]

HSA solutions were prepared by dissolving the protein in 1.0  1021Mphosphate buffer plus 1.0  1021MNaCl, at

pH 7.0 and 25.0 8C Haem solutions were prepared in 1.0  1021M KOH Ibuprofen solutions were prepared by dissolving the drug in 1.0  1021M phosphate buffer plus 1.0  1021M NaCl, at pH 7.0 and 25.0 8C Warfarin solutions were prepared by stirring the drug in 1.0  1021M

phosphate buffer plus 1.0  1021M NaCl at pH 12.0 until it dissolved, then adjusting to pH 7.0 with HCl (at 25.0 8C)

Binding of ibuprofen and warfarin to ferric HSA – haem was followed by electronic absorption spectroscopy at

pH 7.0, in 1.0  1021M phosphate buffer plus 1.0  1021M NaCl, and 25.0 8C Electronic absorption spectra of ferric HSA – haem (5.0  1026 M to 2.0  1024M), in the absence and presence of ibuprofen and warfarin (1.0  1024M to 5.0  1022 M), were collected between 350 nm and 700 nm The electronic absorption spectra were recorded in 1-mm to 1-cm path length cuvettes The ibuprofen- and warfarin-induced electronic absorption spectroscopic transition of ferric HSA – haem was complete within the time to achieve the sample preparation (, 10 min) Test measurements performed after 2 h excluded slow kinetic effects

Fig 1 Chemical structures of ibuprofen and warfarin.

Binding of ibuprofen and warfarin to ferric HSA – haem

was also followed by 1H-NMR relaxometry at pH 7.0

(1.0  1021M phosphate buffer plus 1.0  1021M NaCl)

and 25.0 8C 1H-NMR relaxometry of ferric HSA – haem

(1.0  1023M) in the absence and presence of ibuprofen

and warfarin (1.0  1024M to 1.0  1021M) was

investi-gated on a Stelar SpinMaster Spectrometer (Stelar S.n.c.,

Mede, PV, Italy) Water proton relaxation rate (R1)

measurements were obtained at 0.47 T (i.e at 20 MHz

proton Larmor frequency) by means of the

Inversion-Recovery technique (16 experiments, four scans)

Magneti-zation values were obtained by averaging the first 128 data

points of the Free Induction Decay A phase cycle (1x, – x,

– x, 1x) was applied on the 908 observation pulse to cut

off the y-scale receiver offset A typical 908 pulse width

was 3.5 ms The t-values were increased linearly from a

starting value corresponding to one-seventh of the estimated

null-point (0.693/R1), so that the null-point occurs on

the middle of the inversion-recovery curve (seventh

experiment) In the 16th experiment the Free Induction

Decay is acquired after a single 908 pulse, to obtain the M1

value [24] The reproducibility in R1 measurements was

^ 0.5% The temperature was controlled by a Stelar

VTC-91 airflow heater (Stelar S.n.c.), equipped with a

copper-constantan thermocouple; the actual temperature in the

probe head was measured with a Fluke 52k/j digital

thermometer (Fluke AG, Zu¨rich, Switzerland), with an

uncertainty of ^ 0.3 8C Values of the paramagnetic

contribution to the overall water solvent relaxation rate

(R1p) were determined by subtracting from the observed

relaxation rate (Robs

1 ) the blank relaxation rate value (Rdia

1 ) measured for solutions containing HSA at the same

concentration without the paramagnetic prosthetic group

Test measurements performed after 2 h excluded slow

kinetic effects [7]

Haem binding to HSA in the absence and presence of

ibuprofen and warfarin was followed by electronic

absorption spectroscopy (between 350 nm and 450 nm) at

pH 7.0 (1.0  1021M phosphate buffer plus 1.0  1021M

NaCl) and 25.0 8C [22] The HSA concentration ranged

between 3.0  1028 M and 2.0  1026 M, the haem

concentration was 1.0  1027M, and the ibuprofen and

warfarin concentrations were 5.0  1022M The electronic

absorption spectra were recorded in a 10-cm path length

cuvette The haem-induced electronic absorption

spectro-scopic transition of HSA was complete within the time

to achieve the sample preparation (, 10 min) Test

measurements performed after 2 h excluded slow kinetic

effects

Binding of ibuprofen and warfarin to ferrous HSA –

haem-NO was followed by X-band EPR spectroscopy at pH 7.0 in

1.0  1021M phosphate buffer plus 1.0  1021M NaCl,

and 2173 8C X-band EPR spectra of ferrous HSA –

haem-NO (3.0  1024M) in the absence and presence of

ibuprofen and warfarin (5.0  1022M) were collected on

a Bruker ESP 300 spectrometer, operating at 9.42 GHz

microwave frequency, 100 kHz field modulation, 20 mW

microwave power, and 0.10 mT modulation amplitude The

ibuprofen- and warfarin-induced EPR-spectroscopic

tran-sition of ferrous HSA – haem-NO was complete within the

time to achieve the sample preparation (, 10 min) Test

measurements performed after 2 h excluded slow kinetic

effects [8]

R E S U L T S A N D D I S C U S S I O N

Fig 2 shows the electronic absorption spectra of ferric HSA – haem in the absence and presence of ibuprofen and warfarin at pH 7.0 and 25.0 8C Electronic absorbance spectroscopy and 1H-NMR relaxometry indicate that the haem iron atom of ferric HSA – haem is hexa-coordinated, possibly being bonded to His105 and Tyr148 as suggested

by docking simulations [7] Upon drug binding, neither a change in the haem-iron atom coordination number, nor in the spin state of the metal centre, is observed Spectra shown

in Fig 2 are indicative of a high-spin state of the haem-iron Actually, even the minor low-spin component [22] seems to diminish in the presence of either drug In fact, the Soret band is blue-shifted, the charge transfer band is red-shifted and the a band is decreased in intensity with respect to the

b band The spectral features shown in Fig 2 are indicative

of a drug-dependent conformational transition(s) that does not affect the inner coordination sphere of the haem iron atom

Fig 2 Effect of ibuprofen and warfarin on the electronic absorption spectroscopic properties of ferric HSA – haem Elec-tronic absorption spectra of ferric HSA – haem were obtained in the absence (spectrum a) and in the presence of 5.0  1022M ibuprofen (spectrum b, continuous line) and 5.0  10 22

M warfarin (spectrum b, filled circles) at pH 7.0 and 25.0 8C The electronic absorption spectra

of ferric HSA – haem in the presence of ibuprofen and warfarin are superimposable The ferric HSA – haem concentration was 8.4  1026M The electronic absorption spectra were recorded in a 1-cm path length cuvette.

Fig 3 shows the binding isotherms of ibuprofen and

warfarin to ferric HSA Ờ haem, at pH 7.0 and 25.0 8C Data

obtained by different techniques (i.e electronic absorption

spectroscopy and 1H-NMR relaxometry) are in good

agreement By applying the minimum model accounting

for multiple binding sites per monomeric protein, a

relationship between the apparent equilibrium dissociation

constant (Kd) for ibuprofen and warfarin binding to ferric

HSA Ờ haem and the molar fraction of the ligand-bound

ferric HSA Ờ haem (a) may be expressed according to

Eqn (1) [25]:

a Ử đơLŠT2 ơLŠbỡn/ Kf d1 đơLŠT2 ơLŠbỡng đ1ỡ

where n is the Hill coefficient, and [L] is the ligand (i.e

drug, HSA, HSA : ibuprofen, or HSA : warfarin)

concen-tration in the forms indicated by subscripts T (total) and b

(bound), respectively [L]b was calculated according to Eqn (2) [25]:

ơLŠbỬ K d1 n:ơQŠT1 ơLŠT2pđKd1 n:ơQŠT1 ơLŠTỡ2

where [Q]T is the total ferric HSA Ờ haem or haem concentration

The analysis of data given in Fig 3 according to Eqn (1) allowed the determination of values of Kd (Ử 5.4 ^ 1.1  1024M) and n (Ử 1.9 ^ 0.1) for ibuprofen binding

to ferric HSA Ờ haem, and of Kd (Ử 2.1 ^ 0.4  1025M) and n (Ử 2.7 ^ 0.1) for ferric HSA Ờ haem : warfarin complex formation at pH 7.0 and 25.0 8C The Kd value for ibuprofen binding to ferric HSA Ờ haem is higher than those reported for drug binding to the ibuprofen primary site (KdỬ 3.7  1027

M, at pH 7.4 and 37.0 8C) [1,15] and to the ibuprofen secondary cleft (Kd< 4  1025

Mat pH 7.4 and 37.0 8C) [1,15] of haem-free HSA Also the Kdvalue for warfarin binding to ferric HSA Ờ haem is higher than that reported for drug binding to the warfarin primary site (KdỬ 3.0  1026

M at pH 7.4 and 25.0 8C) [1,16 Ờ 18] of haem-free HSA

Fig 4 shows the binding isotherms of ferric haem to HSA

in the absence and presence of ibuprofen and warfarin, as obtained by electronic absorption spectroscopy at pH 7.0 and 25.0 8C Data analysis according to Eqn (1) allowed the determination of values of the apparent dissociation equilibrium constant (Kd) and of the Hill coefficient (n ) for haem binding to HSA, in the absence and presence of ibuprofen and warfarin The Kd value for ferric haem binding to HSA, in the absence of drugs, is 1.3 ^ 0.2  1028M at pH 7.0 and 25.0 8C Remarkably, the Kd value for ferric haem binding to HSA determined here (see Fig 4) is in excellent agreement with that reported

in the literature (K Ử 1  1028

Mat pH 7.0 and 24.0 8C)

Fig 3 Ibuprofen and warfarin binding to ferric HSA Ờ haem.

Electronic absorption spectroscopic and 1 H-NMR relaxometric binding

isotherms of ibuprofen and warfarin to ferric HSA Ờ haem were obtained

at pH 7.0 and 25.0 8C Circles and squares indicate data obtained by

electronic absorption spectroscopy and 1 H-NMR relaxometry,

respectively The continuous lines were obtained by using Eqn (1).

Best fitting parameters are K d Ử 5.4 ^ 1.1  10 24

M and

n Ử 1.9 ^ 0.1 for ibuprofen binding, and K d Ử 2.1 ^ 0.4  10 25

M and n Ử 2.7 ^ 0.1 for warfarin binding The ferric HSA Ờ haem

concentration was 1.5  1024M and 1.0  1023M for electronic

absorption spectroscopic and 1 H-NMR relaxometric experiments,

respectively The electronic absorption spectra were recorded in a

1-mm path length cuvette.

Fig 4 Haem binding to HSA Electronic absorption spectroscopic binding isotherms of haem to HSA were obtained in the absence (A) and presence of 5.0  1022M ibuprofen (K) and 5.0  1022M warfarin (W) at pH 7.0 and 25.0 8C The continuous lines were obtained by using Eqn (1) Best fitting parameters for ferric HSA Ờ haem formation are

K d Ử 1.3 ^ 0.2  10 28

M and n Ử 1.0 ^ 0.1, in the absence of drugs, and K d Ử 1.5 ^ 0.2  10 27

M and n Ử 1.0 ^ 0.1, in the presence of ibuprofen and warfarin The haem concentration was 1.0  1027M The electronic absorption spectra were recorded in a 10-cm path length cuvette For further details, see text.

[23] In the presence of saturating amounts of ibuprofen and

warfarin (5.0  1022M) the affinity of haem for HSA

decreases by about one order of magnitude, the

drug-independent Kdvalue being 1.5 ^ 0.2  1027Mat pH 7.0

and 25.0 8C In the absence and presence of drugs, the value

of n for haem binding to HSA is 1.0 ^ 0.1 at pH 7.0 and

25.0 8C (see Fig 4)

Data reported in Figs 3 and 4 indicate that haem binding

to HSA inhibits ibuprofen and warfarin association to the

warfarin primary cleft (i.e Sudlow’s site I), corresponding

to the ibuprofen secondary site [1,3,11] Then, ibuprofen

and warfarin impair ferric HSA – haem formation

Remark-ably, the ibuprofen primary cleft (i.e Sudlow’s site II)

appears to be functionally and spectroscopically uncoupled

to the haem site of HSA

Ferric HSA – haem has been widely investigated by

1H-NMR relaxometry [7] The high value of the paramagnetic

contribution to the water relaxation rate (R1p) of

hexacoordinated ferric HSA – haem (¼ 4.8 mM21:s21 at

20 MHz, pH 7.2 and 25 8C) has been ascribed to the

occurrence of slowly exchanging water molecules in the

surroundings of the paramagnetic ferric haem center [7] In

the presence of saturating amounts of ibuprofen and

warfarin, the R1p value of hexacoordinated ferric HSA –

haem decreases to 0.4 mM21:s21 at 20 MHz, pH 7.0 and

25 8C (data not shown) The decrease of the R1pvalue upon

drug binding may reflect a conformational transition(s)

towards a ferric HSA – haem state where slowly exchanging

water molecules are far apart from the paramagnetic centre

On the other hand, the lifetime of the ferric haem centre

hydration shell could be shortened to approach the diffusion

mean time [26 – 28]

Fig 5 shows a ribbon diagram of HSA (PDB code 1E78)

[5] Remarkably, a cavity hosting three water molecules can

be located at the interface between the haem cleft and the

warfarin primary site (i.e Sudlow’s site I) These water

Fig 5 Sudlow’s site I and haem cleft location

in HSA Buried water molecules (blue spheres) are located at the interface between the warfarin primary site (i.e Sudlow’s site I; highlighted

in green) and the haem cleft (traced in red) The HSA backbone is rendered as a ribbon model HSA atomic coordinates were recovered from the Protein Data Bank (PDB ID: 1E78) [19] For details, see [5,7,10,14] and text.

Fig 6 Effect of ibuprofen and warfarin on the EPR spectroscopic properties of ferrous HSA – haem-NO X-band EPR spectra of ferrous HSA – haem-NO were obtained in the absence (spectrum a) and in the presence of 5.0  1022M ibuprofen (spectrum b, continuous line) and 5.0  1022M warfarin (spectrum b, filled circles) at pH 7.0 and

2173 8C The X-band EPR spectra of ferrous HSA – haem-NO in the presence of ibuprofen and warfarin are superimposable The ferrous HSA – haem-NO concentration was 3.0  1024M

Table 1 X-band EPR parameters and the haem-iron coordination state of HSA – haem-NO Values listed are for 14 N systems Experimental conditions were pH 7.0 and 2173 8C US, unresolved signal.

molecules are able to exchange with the bulk solvent

typically on the submicrosecond timescale, which is

sufficient to promote relaxation of the observed water

protons [27] Therefore, upon drug binding, these water

molecules are displaced or, alternatively, their residence

lifetime is reduced In either case, a quenching of the

paramagnetic contribution to the observed relaxation rate is

expected [7,24,26]

Fig 6 shows the X-band EPR spectra of ferrous HSA –

haem-NO in the absence and presence of ibuprofen and

warfarin Ferrous HSA – haem-NO samples obtained by

different methods give identical X-band EPR spectra In the

absence of any allosteric effector, the X-band EPR spectrum

of ferrous HSA – haem-NO displays a three-line splitting

(A3¼ 1.65 mT) in the high magnetic field region

(g3¼ 2.010) (see Fig 6, spectrum a, and Table 1) This

X-band EPR spectrum has been associated with the

five-coordinate haem-iron state of ferrous HSA – haem-NO [8],

in agreement with data reported for several ferrous

nitrosylated haemoglobin systems [8,29 – 34] Addition of

either ibuprofen or warfarin to ferrous HSA – haem-NO

induces the transition towards a species characterized by an

X-band EPR spectrum with a rhombic shape and a weak

superhyperfine pattern in the gzregion (see Fig 6, spectrum

b, and Table 1) Such behaviour is similar to that observed in

the presence of bezafibrate and clofibrate, which has been

attributed to the shift of the conformational equilibrium

towards the six-coordinated haem-iron state of ferrous

HSA – haem-NO [8] The His242 residue has been

postulated to be a likely candidate for the sixth axial ligand

of the haem iron in ferrous HSA – haem-NO in the presence

of bezafibrate and clofibrate [8] However, more recent

results are consistent with the suggestion that His105 might

be responsible for the sixth axial bonding of the haem iron

[7,10,11] Remarkably, His242 has been shown to be

hydrogen-bonded to warfarin [14] As the binding of

warfarin to Sudlow’s site I does not affect the coordination

state of haem iron (see Fig 2), His242 does not appear to be

a likely candidate for the axial haem bonding

C O N C L U S I O N S

The effect of ibuprofen and warfarin on the electronic

absorption spectroscopic, 1H-NMR relaxometric and

X-band EPR spectroscopic properties of ferric HSA – haem

and ferrous HSA – haem-NO is in keeping with the allosteric

conformational transition(s) induced by these therapeutic

drugs in HSA Note that the Sudlow’s site I and the

Sudlow’s site II ligands induce the N (normal) to B (basic)

conformer transition in HSA Accordingly, the affinity of

therapeutic drugs for the B-form of HSA is higher than that

observed for the N-form [1,3,4,14,35,36] Haem inhibits

drug binding, possibly stabilizing the N-species of HSA

(present study) Accordingly, binding of ibuprofen and

warfarin to Sudlow’s site I impairs ferric HSA – haem

formation (present study) Finally, drug-dependent

spectro-scopic properties of ferric HSA – haem and ferrous HSA –

haem-NO may be helpful in investigating ligand binding

and allosteric properties of HSA, as already reported for

haemoglobin (see [37,38]) Therefore, the therapeutic use of

warfarin and ibuprofen may affect haem transfer to

hemopexin and consequently its plasma level In parallel,

haem may affect pharmacokinetics of drugs carried out by HSA

A C K N O W L E D G E M E N T S

The authors thank M Coletta and A Desideri for helpful discussions and F Tiberi for technical assistance This work was partially supported

by grants from the Ministry for University, Scientific Research and Technology of Italy (MURST ‘Fondi per lo Sviluppo, Universita` Roma Tre 2001’ to P A., and MURST ‘Projects of Relevant National Interest’

to S A.), as well as from the National Research Council of Italy (CNR, Target oriented project ‘Biotecnologie’ to P A and M F.) S B wishes

to thank Consorzio Interuniversitario di Ricerca in Chimica dei Metalli nei Sistemi Biologici (CIRCMSB) for a doctoral studentship.

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