63PETACCI ET AL. Biol Res 43, 2010, 63-74
Biol Res 43: 63-74, 2010 BR
Inhibition of peroxidase activity and scavenging of
reactive oxygen species by astilbin isolated from
Dimorphandra mollis (Fabaceae, Caesalpinioideae)

1FERNANDO PETACCI, 1SILVIA S FREITAS, 2IGUATEMY L BRUNETTI
and 3NAJEH M KHALIL*

1 Chemistry Department, CAC-UFG, Catalão, Goiás, Brazil.
2 Clinical Analysis Department, School of Pharmaceutical Sciences, Araraquara - UNESP - São Paulo State
University, São Paulo, Brazil.
3 Pharmacy Department, Guararapuava - UNICENTRO - Paraná, Brazil.

ABSTRACT

Astilbin (5,7,3’,4’-tetrahydroxy-2,3-dihydroflavonol-3-ß-o-rhamnoside), a flavonoid with a large range of
biological activities, was isolated from Dimorphandra mollis, a shrub common to the Brazilian Cerrado. The
purpose of this study is to verify the effects of astilbin on myeloperoxidase (MPO) and horseradish peroxidase
(HRP), and its antioxidant activity against hypochlorous acid (HOCl) and total antioxidant activity (TAC) by
the 2,2’-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) radical cation (ABTS•+). Astilbin inhibited MPO
and HRP activities in a concentration-dependent relationship and effectively scavenged HOCl. The TAC by
ABTS•+ of astilbin (IC50 ~ 20 mM) was higher than that of uric acid, which was used as a positive control.
These data demonstrate that astilbin is a potent antioxidant and that it inhibits MPO and HRP activities
efficiently.

Key terms: Astilbin, Myeloperoxidase, Horseradish peroxidase, Reactive Oxygen Species, Hypochlorous
acid.

* Corresponding Author: Prof. Dr. Najeh Maissar Khalil, Departamento de Farmácia, Setor de Ciências da Saúde,
Universidade Estadual do Centro-Oeste – UNICENTRO, Rua Simeão Camargo Varela de Sá n. 03, Guarapuava – PR,
Brazil 85040080, Phone: 55 42 3629 8137, FAX: 55 42 3629 8102. E-mail: najeh@unicentro.com Najeh Maissar Khalil3,
Fernando Petacci1*, Silvia de Sousa Freitas1, Iguatemy Lourenço Brunetti2

Received: 04-05-2009. In revised form: 23-08-2009. Accepted: 01-09-2009

INTRODUCTION

Dimorphandra mollis Benth. (Fabaceae,
Caesalpinioideae) (Lorenzi, 1992) is a
very common tree that  thrives from
southern to western Brazil. There is no
evidence that this species lives elsewhere
in the world. Some species are popularly
known as “barbatimão”. Stryphnodendron
adstringens ,  S.  polyphyllum ,  and S.
obovatum are known as “true barbatimão”,
and Dimorphandra moll is ,  as  “false
barbatimão”. Although they belong to
different  genera,  some species are
sympatric (similar blooming period) and
are commonly confused.  Barbatimão
(Stryphnodendron  sp or D. mollis) is

extensively used in folk medicine for the
treatment of  diarrhea,  gynecological
problems,  and for  heal ing wounds.
Previous studies showed signif icant
cicatrizing properties (Panizza et al., 1988;
Jorge Neto et al., 1996, Landrault et al.
2002,  Lopes et  al . ,  2005),  ant i-
inflammatory activity (Lima et al., 1998),
and gastric anti-ulcerogenic properties
(Audi et al., 1999) of the crude extract of
the stem bark. Use of barbatimão species
as an antioxidant has not been reported.
The production of reactive oxygen species
(ROS) by active neutrophils and the
release of oxidants may be a contributing
factor  in the progressive decl ine of
immune system activity in patients with



PETACCI ET AL. Biol Res 43, 2010, 63-7464

diabetes, emphysema, atherosclerosis, and
cancer (Clark, 2002; Giordano, 2005). The
generation of ROS by neutrophils involves
the enzymes NADPH oxidase and
myeloperoxidase (MPO). The NADPH
oxidase system generates a superoxide
radical (O2

• -) ,  and after dismutation
catalyzed by superoxide dismutase, H2O2
is generated. MPO utilizes H2O2

 to oxidize
chloride, resulting in the formation of the
pro-inflammatory oxidant, hypochlorous
acid (HOCl), a microbiocidal responsible
for the oxidation of several biological
substrates resulting in tissue damage. The
anti-inflammatory activity of many drugs
and natural compounds has been attributed
to the inhibi t ion of  MPO. Evidence
suggests the association between MPO
levels and the risk of coronary diseases,
pointing to MPO as an inflammatory
marker (Zhang et  al . ,  2001).
Epidemiological studies indicate that
increased consumption of  frui t  is
associated with a decreased r isk of
degenerative cancer (Beecher, 1999) and
that secondary metabolites present in
natural food sources are responsible for
this (Liu, 2003). The protective action of
some foods, such as fruit and vegetables,
against degenerative diseases has been
attributed to their antioxidants, particularly
those rich in phenolic compounds.

Astilbin (5,7,3’,4’-tetrahydroxy-2,3-
dihydroflavonol-3-β-O-rhamnoside) (Figure
1) has been associated with a large range of
biological activities, such as lowering total
cholesterol in the liver (Igarashi et al.,
1996), protection against oxidative damage
to the mitochondria and erythrocyte
hemolysis in the liver (Haraguchi et al.,
1996a), inhibition of aldose reductase
(Haraguchi et al., 1996b), enhancement of
the vanadate-stimulated release of
lipoprotein lipase (Motoyashiki et al.,
1998), hepatoprotecting effects in rats
(Closa et al., 1997) and mice (Xu et al.,
1999), antinociceptive and anti-
oedematogenic effects (Cechinel-Filho et
al, 2000), induction of apoptosis (Yan and
Xu, 2001), and suppression of lymphocyte
functions (Cai et al., 2003). Recently, our
group reported that astilbin is toxic to
various insects (Cintra et al., 2002; Pereira
et al., 2002; Cintra et al., 2005a, 2005b).

This paper reports the inhibitory effects
of astilbin on MPO and horseradish
peroxidase (HRP) activities, as well as its
antioxidant properties. Based on reports on
the redox properties and antioxidative
activities of flavonoids, as well as on the
fact that peroxidases have been shown to
oxidize those compounds, we studied the
interaction of astibin with HRP and MPO
and its major reaction product, HOCl.

Figure 1: Structure of astilbin (5, 7, 3’, 4’- tetrahydroxy -2, 3- dihydroflavonol- 3- β- O-
rhamnoside)



65PETACCI ET AL. Biol Res 43, 2010, 63-74

MATERIALS AND METHODS

Reagents and chemicals

Human MPO was purchased from Planta
Natural Products (Austria). HRP, guaoacol,
H2O2, 5,5’-dithio-2-nitrobenzoic acid, sodium
borohydride, NaOCl, and ABTS were
purchased from Sigma (St. Louis, MO, USA).
All the other chemicals were of analytical
grade and of the highest commercially
available purity. The concentration of HRP
was determined as described in the literature
(Gazaryan et al., 1996). HOCl was obtained
by diluting NaOCl in 5 mM NaOH. The
dilute concentration was determined
spectrophotometrically (e292 = 350 M-1 cm-1).

Plant material

Flowers of Dimorphandra mollis Benth.
were collected in São Carlos, São Paulo
State, Brazil in January 2004 and dried in
an air circulation oven (40 oC) and later
milled.

The extraction, purification, and
characterization of astilbin were previously
described (Pereira et al., 2002). Flowers
(450 g) were extracted three times with
dichloromethane, followed by two
extractions with methanol, yielding 7.5 g
and 34.1 g, respectively. The methanol
extract yielded astilbin after HPLC
separation on a polymer-packed column
(Shimadzu, Asahipak GS-310 P, 21.5 cm
ID x 50.0 cm L) eluted with methanol (flow
rate: 7 mL min-1, UV detection at 290 nm),
yielding whitish yellow crystals (7.6% w/w
of the dry starting material), m.p. 190-191
°C; APCI/MS m/z = 451 [M + H]+; NMR
data were compared with literature data (De
Brito et al., 1995).

Peroxidase activity inhibition

The activities of MPO and HRP were
spectrophotometrically determined using
guaiacol as a substrate (Khalil et al, 2008).
The reaction mixture contained either 2.5
nM of MPO or 0.35 nM of HRP, 5 mM of
guaiacol, and 0.5 mM of H2O2 in 1.0 mL of
50 mM sodium phosphate buffer (pH 7.4),
and micromolar concentrations of astilbin

(range 0 from to 22.5 μM). The mixtures
were incubated at 37 °C, and the reactions
were initiated by the addition of H2O2,
followed by recording the increase in
absorption at 470 nm for 3 min. MPO and
HRP activities were calculated from the
initial rate of the reaction (in seconds).

Direct interaction between astilbin and the
HRP-H2O2 system

The transition of native HRP (403 nm) to
compound I was followed at the Soret
maximum of compound I (408 nm), and
that of compound I to compound II was
followed at the Soret maximum of
compound II (420 nm). In a typical
experiment, HRP (2 mM heme) in a 50 mM
buffer (pH 7.4) was premixed with 0.1 mM
of H2O2. After a 5-s delay, compound I was
reacted with astilbin (45 mM) and was
monitored for 3600 s.

Synthesis of 5-thio-2-nitrobenzoic acid
(TNB)

The synthesis of 5-thio-2-nitrobenzoic acid
was carried out according to Ching et al.
(1994). Briefly, a 1-mM solution of 5,5’-
dithio-2-nitrobenzoic acid (DTNB) in 50
mM potassium phosphate buffer (pH 6.6)
containing 50 mM sodium EDTA was
added to a 20 mM solution of sodium
borohydride. The solution was incubated in
the dark at 37 ºC for 30 min. The
concentration of TNB was measured at 412
nm (ε = 13.600 M-1.cm-1).

Hypochlorous acid scavenging assay

HOCl (35 mM) was incubated either with
or without astilbin (0 to 25 mM). After 5
min, TNB (70 mM) was added and the
concentration of the remaining HOCl was
determined spectrophotometrically (l = 412
nm).

ABTS decolorization assay

Solutions of ABTS (7 mM) and potassium
persulfate (2.45 mM) were mixed and
incubated in the dark at room temperature
for 12-16 h (Re et al., 1999). The product,



PETACCI ET AL. Biol Res 43, 2010, 63-7466

ABTS•+, was diluted in ethanol for optimal
absorption ± 0.7 at 734 nm. The reduction
between ABTS•+ and astilbin was
monitored by a decrease in absorption at
734 nm after 30 minutes. This decolorizing
assay was also applied for uric acid as a
standard.

The antioxidant activity was calculated
as the percentage of inhibition ABTS•+
according to the formula:

ABTS•+ inhibition % =[(Ab-Aa)/
Ab]×100; where: Ab: absorption of the
control, and Aa: absorption of the sample
(astilbin or uric acid).

RESULTS

Inhibition of peroxidase activity

Peroxidases are heme-containing enzymes
that oxidize a variety of xenobiotics and
biomolecules in the presence of hydrogen
peroxide. The following reaction cycle is
involved in the oxidation of xenobiotics and
biomolecules by peroxidases (Saunders,
1973):

Peroxidase + ROOH → Compound I + ROH
Compound I + XOH → Compound II + XO•

Compound II + XOH → Peroxidase + XO• + H2O

As shown in Figure 2,  ast i lbin
decreases the rate of oxidation of guaiacol,
indicating that it acts as an MPO substrate.
In this system, either MPO or HRP (an
enzyme used as a model for peroxidases)
is converted into compound I in the
presence of  H2O2,  fol lowed by the
oxidation of guaiacol and the formation of
compound II. Compound II promotes the
oxidation of another guaiacol equivalent
and returns to i ts  nat ive state.
Alternat ively,  MPO I catalyzes the
oxidation of halides, generating their
respective hypohalous acids (Figure 3).
The interaction between flavonoids and
peroxidases (HRP) has been well studied.
Kostyuk et al. (2003) and Awad et al.
(2000) reported that flavonoids can act as
MPO and HRP substrates. According to
our results, astilbin may interact with
oxidized intermediates MPO I and/or MPO
II, leading to decreased oxidation of
guaiacol. It is interesting to point out that

Figure 2: A) Time course of the oxidation of guaiacol (5 mM) by MPO system (2.5 nM) / H2O2

(0.5 mM) in 50 mM sodium phosphate buffer pH 7.4 at 37 oC in either the absence or the presence
of astilbin.



67PETACCI ET AL. Biol Res 43, 2010, 63-74

(FeIV=O). Compound II also catalyzes the
oxidation of substrates while converting
itself into its native form, completing the
peroxidase cycle. The native enzyme is
monitored at λmax= 403 nm, Compound I at
λmax= 408, and Compound II at λmax= 420
nm. The kinetic data for the reaction of
HRP-H2O2 in the presence of astilbin are
shown in Figure 7. Compound II is formed
in the HRP-H2O2-astilbin system, which
indicates that astilbin is not an efficient
substrate for Compound II; thus, the
peroxidase cycle (native return) cannot be
completed. Simultaneously, the astilbin
spectra presented absorption changes
despite the accumulation of Compound II in
this step. The reaction between HRP-H2O2
and catechin resulted in dimeric products
(Hosny and Rosazza, 2002). The literature
reports that peroxidase transfers one-
electron oxidation of flavonoids, leading to
the formation of several products (Awad et
al., 2000), which may be attributed to the
presence of multiple hydroxyl groups.

Figure 3: Catalytic cycle of MPO. SH: reducing substrate and S•: radical substrate.

the concentrations of astilbin (11 and 22
μM) used in this assay was much smaller
than those used with guaiacol (5 mM),
showing its significant effect on the
inactivation of MPO. Figure 4 shows the
effect of astilbin on the oxidation of
guaiacol by HRP. Astilbin presented a low
inhibitory effect on HRP (% inhibition:
from 25.5 to 10 μM and from 40 to 20 μM)
in comparison with MPO (% inhibition:
from 37 to 10 μM and from 69.3 to 20 μM).

Direct interaction between astilbin and the
HRP-H2O2 system

The conventional peroxidase cycle is
known to oxidize various substrates with
the consumption of H2O2. In the presence
of H2O2, the native form of the enzyme
(FeIII) is converted into Compound I (heme
with FeIV=O plus porphyrin radicals),
which catalyzes the oxidation of substrates
by converting itself into Compound II



PETACCI ET AL. Biol Res 43, 2010, 63-7468

HOCl scavenger assay

Figure 5 presents the results of the HOCl
scavenger assay. In this assay, HOCl
scavengers compete with TNB for HOCl
and are monitored by a decrease in the
absorption at 412 nm. Incubation of astilbin
with HOCl reduced TNB oxidation,
indicating that a low concentration range of
astilbin acts as a HOCl scavenger. A similar
effect was reported using quercetin
(Binsack et al. ,  2001). An astilbin
concentration of 5 μM resulted in a
decrease of approximately 94% of HOCl
(35 μM) (seven times as high as the
concentration of astilbin), demonstrating its
effective antioxidant effect on HOCl. The
interaction between HOCl and quercetin
generated stable mono- and dechlorinated
derivatives that exhibited enhanced
antioxidant potential (Binsack et al., 2001).
To elucidate the scavenging reaction
mechanism of astilbin with HOCl, the
interaction between the two compounds was
evaluated based on spectral changes.
Astilbin (pH 7.4) presents a peak at λmax =

Figure 4: Oxidation of guaiacol (5 mM) by HRP system (0.1 nM) / H2O2 (0.1 mM) in 50 mM
sodium phosphate buffer pH 7.4 at 37 °C in either the absence  or the presence of astilbin.

280 nm. We observed a hyperchromic
effect at λ = 260 nm and λ = 430 nm,
followed by a hypochromic effect at λ =
328 nm, and an isosbestic point at 290 nm
(Figure 6A) when HOCl (30-240 μM) was
added to the astilbin solution (20 μg/mL). A
similar experiment at pH 6.0 showed a peak
at λmax = 290 nm, and after HOCl was
added, there was an increase in the
absorption at 255, 342 and 430 nm, a
decrease at 290 nm, and isosbestic points
appeared at 270 and 312 nm (Figure 6B).

Total antioxidant activity

Figure 8 shows the results of the ABTS•+
assay. The degree of discoloration indicates
that the scavenger has antioxidant activity.
In comparison to uric acid, an endogenous
antioxidant present in extra cellular fluids
(Stinefelt et al., 2005), astilbin presented a
higher antioxidant capacity (IC50 ~ 20 μM).
Uric acid is the final product of the
metabolism of purine (Machin et al., 2004)
and it is a relevant indicator of the total
antioxidant capacity of human plasma.



69PETACCI ET AL. Biol Res 43, 2010, 63-74

DISCUSSION

Flavonoids are probably the most studied
and the best-known natural substances
present in vegetables that have antioxidant
and anti-inflammatory properties.

Recently, attention has been focused on
the use of flavonoid-based drugs in the
prevention and therapy of free radical-
mediated human diseases. Flavonoids are
excellent radical scavengers, a property that
is related to their oxidation/reduction
potential and activation energy of electron
transfer (Havsteen, 2002).

The release of ROS by phagocytic
leukocytes depends on the activation of
NADPH oxidase and MPO. MPO is an
abundant component stored in azurophilic
granules of neutrophils that catalyzes the
generation of HOCl, a reactive chlorinated
intermediate that is also involved in
oxidative complications.

The formation of ROS serves as a host
defense mechanism, but it is also clear that
ROS are related to the development of
diseases. The oxidation of low-density
lipoprotein (LDL) by MPO and HOCl has
been implicated in the development of

Figure 5: Effect of astilbin on HOCl (35 mM). HOCl was incubated with astilbin (0 to 25 μM) for
5 min. The remaining HOCl was determined by adding TNB (70 μM).

atherosclerotic lesions (Kostyuk et al.,
2003; Mertens and Holvoet, 2001).

Several studies have been aimed at
elucidating the interactions between
peroxidases and flavonoids, but few have
dealt with MPO. It was demonstrated that
flavonoids with either the catechol moiety
or α,β−unsaturated carbonyl with the free
hydroxyl group at C-3 have shown the best
MPO inhibitory properties (Regasini et al.
2008). HRP catalyzes the oxidation of
flavonoids to free phenoxyl or semiquinone
radicals (Awad et al., 2000). Quercetin
radicals were detected during the
interaction of quercetin with HRP-H2O2,
indicating oxidation by one electron
transfer (Miura et al., 2003).

Astilbin demonstrated an inhibitory
effect on the activity of MPO (IC50 ~15
μM). In our experiment, we used a high
concentration of guaiacol (5 mM) in
relation to astilbin (μM). This shows that
astilbin is an efficient inhibitor under
peroxidase activity. The direct interaction
between astilbin and intermediate
peroxidase products at different absorbance
peaks may be due to the presence of several
hydroxyl groups (Kostyuk et al., 2003).



PETACCI ET AL. Biol Res 43, 2010, 63-7470

Figure 6: Changes in the absorbance of astilbin by HOCl. Astilbin (22 μM) was incubated at 37 ºC
either without (curve 1) or with HOCl (curves 2-5) in 50 mM phosphate buffer at either pH 7.4 (A)
or pH 6.0 (B).  HOCl concentrations (μM) were as follows: curve 2, 15; curve 3, 60; curve 4, 120;
curve 5, 240.



71PETACCI ET AL. Biol Res 43, 2010, 63-74

Figure 7: Accumulation of Compound II of HRP in the presence of astilbin. The reaction was
performed in phosphate buffer 50 mM, pH 6.0 at 37 °C. HRP (2 μM) was mixed with H2O2 (0.1M)
plus astibin (5 μg/ml). The arrows show the direction of change of absorption with time. The first
scan was taken at 0 s, the second at 100 s, and after that, every 400 s up to 3600 s.

Figure 8: Concentration-dependent decrease of ABTS•+ radical cation as a function of increasing
concentrations of either astilbin or uric acid. Experiments performed in 10 mM phosphate buffer pH 7.4.



PETACCI ET AL. Biol Res 43, 2010, 63-7472

Phenolic compounds from grapes and in
wines can protect against oxidative damage
and may prevent the development of
atherosclerosis. The proposed mechanism
for this correlation involves the antioxidant
properties of flavonoids. The intake of
polyphenols in the diet has been associated
with a low risk of coronary diseases
(Hertog et al., 1995).

The literature supports the association of
the beneficial effects of a diet rich in fruits,
vegetables, tea, and red wine with the
presence of polyphenol antioxidants
(Urquiaga and Leighton, 2000; Yao et al.,
2004). Flavonoids scavenge free radicals by
donating hydrogen atoms to radicals
(Rajendran et al., 2004). Pharmacokinetic
studies in animals have demonstrated that
pure astilbin presents a rapid oral
absorption profile and longer t1/2 (Guo et
al. 2004, Liang et al. 2009). This means that
astilbin in the diet can provide interesting
benefits.  These pharmacokinetic
characteristics might be helpful for
exploring the effective mechanisms of
astilbin and its related compounds in vivo.

The substitution patterns in flavonoid rings
either increase or decrease antioxidant activity.
The 3’,4’-orthodihydroxy configuration in ring
B and the 4-carbonyl group in ring C has
radical scavenging activity (van Acker et al.,
1996). The presence of a sugar moiety
increases antioxidant activity more than the
hydroxyl group in carbon 7 (Rajendran et al.,
2004). Therefore, several features of the
astilbin structure (Figure 1) make it a strong
antioxidant agent, as confirmed by our results.

Our results suggest that astilbin
possesses a high antioxidant effect, as seen
by its action on ROS (HOCl and·O2

-), TAC
activity, and dose-dependent inhibition of
the activities of MPO and HRP, which
could exert beneficial effects in several
pathologies. The straightforward extraction
and purification of astilbin from D. mollis
flowers shows that they could be a good
source of this compound.

ACKNOWLEDGEMENTS

The authors would like to thank
Coordenação de Aperfeiçoamento de

Pessoal de Nível Superior (CAPES) and
Conselho Nacional de Desenvolvimento
Científico e Tecnológico (CNPq, Process
475879/2008-2.

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