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Covalent binding of benzo[a]pyrene to DNA in fish liver
Vol. 103, No. 2,19Bl
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
30,1981
November
pages
COVALENT
Usha
BINUiNG DNA IN
Varanasi,
trF BENZUlajPYRENE FISH LIVER
John
E.
Stein
Received
October
TO
and
Northwest and Alaska Fisheries Environmental Conservation 2725 Montlake Boulevard Seattle, Washington
780-787
Tom Horn
Center, Uivision East
NMFS
98112
21,1981
SUMMARY: BenzoLaApyrene became bound to the hepatic DNA in juvenile English sole (Paro hr s vetulus) force fed tritiated benzolajpyrene. No statistical +- y slgniflmchange was observed in the level of the binding from 16 h to 2 wk after the single exposure. Specific activities of binding were similar for both DNA and protein. Moreover, a binding index was calculated to represent the nurnber of benzo[a]pyrene molecules bound per 106 nucleotides after administration of a theoretical dose of 1 mmole of hydrocarbon per kg body weight. The value for English sole liver DNA was of the same order of magnitude as the values reported for mouse skin and mammary glanu in which benzo[ajpyrene is carcinogenic. INTHUDUCTIUN:
Bottom-dwelling
pleuronectid
family,
can
(1).
English
sole,
areas
exhibit
a high
possible
accumulate
them
extensively
mutagens
(5)
liver
of
whether
of
BaP-exposed
(e.g.,
liver
BaP)
half-life
levels
of
from
diet
of
sole of to
belonging PAHs
(3-4).
(2)
interact
their
The in
polluted
cellular
a
(1). and
English metabolize
characterized (6)
important fish
the environment
indicating
sediment
mammals
with
in
development and
formed
to
chemically
BaP metabolites in
UaP
from
tumor
carcinogens
English
those
neoplasms
with
A number
proximate
as
sampled of
metabolites long
high
pollutants
(3-4).
reactive
sufficiently
encounter
frequency
PAHs
and
such
a pleuronectid,
association
sole
fish,
are
as
formed
in
question liver
have
was a
macromolecules,
Abbrevidtions used: PAH, polynuclear aromatic hydrocarbon; BaP, benzo[aJpyrene; DMBA, 7,12-dimethylbenzlajanthracene; SDS, sodium dodecylsulfate; IxSSC, 0.15 2 sodium chloride, U.Ulb M sodium citrate, pH 7.4; CBI, covalent binding index; BPDE, (t)-78 , 8-(x -dihydroxy-9 10a -epoxy-7,8,Y,l&tetrahydroxybenzoLajpyreTie.
does
Uisclaimer: not constitute
Mention of endorsement
trade by
names is the U.S.
0006-291X/81/220780-08$01.00/0 Copyright 0 1981 by Academic Press, Inc. All rights of reproduciion in any form reserved.
780
for information Uepartment of
only and Commerce.
,
Vol. 103, No. 2,Wl
especially cancer that
BIOCHEMICAL
DNA, because through
with
binding
comparative
data
to that In this
BIOPHYSICAL
believed
with
of binding
the
of --in vivo
similar
is
interaction
the magnitude
roughly
it
AND
DNA.
that
chemical
carcinogens
induce
Studies
with
mammals (6-11)
show
of carcinogens
carcinogenic
potential
whether
the extent
paper
we provide
information to hepatic
expose;
to orally
BaP.
the chemical least
administered
of BaP to DNA in fish
mammalian
provide
correlates Determination
valuable
of binding
in fish
is
in mammals.
of BaP intermediate(s)
for
vivo
of the compound.
binding
of binding
to DNA --in
of PAHs, such as BaP, should to assess
RESEARCH COMMUNICATIONS
tissues
susceptible
modification
2 wk after
a single
of the exposure
on the extent DNA and protein
The results
liver
show that
was comparable
to PA&induced hepatic
of covalent in
English
the extent
to values
neoplasms
DNA was observed
sole
reported
and that for
at
to BaP.
MATERIALS AND METHODS: Sodium p-aminosalicylate, deproteinized salmon speml DNA, SDS, ribonuclease-A type l-A, and protease type V were purchased from Sigma Chemical Co., St. Louis, Missouri. The ribonuclease was dissolved in water (1 my/ml) and heated at 80-85°C for 15 min to inactivate any contaminating deoxyribonucleases; the protease was also dissolved in water (1 mg/ml), self-digested for 1 h at 37"C, heated for 2 min at 80°C then quenched in ice. The ribonuclease and protease solutions were stored at -2U'C. Generally labeled [3H]-BaP was purchased from Amersham-Searle, Arlington Heights, Illinois. The [3H]-BaP was purified as described previously (12). The m-cresol was distilled under reduced pressure. All other chemicals were of reagent or analytical grade and used without further purification. Animals: English sole (118+19g), obtained by trawling from Puget Sound, were kept in flowing seawater at 11°C and fed a diet of minced clams for three weeks. The feeding was stopped two days prior to starting the experiment and resumed 48 h after initiation of exposure, with the fish being fed every other day. The fish were force-fed gelatin capsules (no. 3) containing 0.69 mCi of L3H]-BaP (sp act 17.4 Ci/mmole) dissolved in 50 vl of corn oil. The average dose of BaP was 88t12 Pg/kg body weight. Fish were sacrificed by a blow to the head at-16, 24, 96, 168 and 336 h after being fed BaP; the liver was removed and stored at -65'C. The concentration of radioactivity in liver Radioactivity in Liver: was determined from a sample (O.lg) of liver solubilized in 1 ml of Soluene-350 (Packard Instrument Co.) and decolorized with 200 1~1 of both isopropanol and 30% hydrogen peroxide; 15 ml of Dimilume-30 (Packard Instrument Co.) was added and the radioactivity measured using a Packard The distribution of radioactivity 300C liquid scintillation spectrometer.
781
Vol. 103, No. 2.1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
in liver as unconverted BaP, organic solvent-soluble BaP metabolites, and water-soluble BaP metabolites was determined by homogenization of liver and ethyl acetate extraction, followed by thin-layer chromatography A 200 !~l aliquot of the liver homogenate was of the organic phase (4). diluted to 1 ml with water, and an aliquot removed for measurement of The remaining aqueous solution was mixed with 1 volume radioactivity. of N2-saturated acetone, then extracted twice with 1 volume N2-saturated ethyl acetate. The organic extract waS dried over Na2S04, an aliquot removed and radioactivity measured. The remaining extract was removed by suction, evaporated to dryness under a stream of nitrogen, then dissolved in 50-100 Ul of ethyl acetate containing BaP and its oxygenated standards. The organic extract with added standards was spotted on the pre-adsorbent layer of a channeled thin-layer chromatographic plate (Whatman No. LKSU, Whatman Inc., Clitton, N.J.) and developed with hexane: ether (Y5:5, v/v). The adsorbent from the thin-layer chromatoyraphic plate was removed in three fractions. The first fraction contained BaP metabolites (Rf = 0.1) and the pre-adsorbent pad; the second fraction was the adsorbent between Rf of 0.1 and 0.5. The third fraction of adsorbent contained unmetabolized BaP (Rf = 0.5). The radioactivity was measured in each fraction. All of these operations were performed under red light to minimize photooxidation.
Isolation of Liver DNA: Liver DNA was isolated according to parts of the methods by Kirby (13), Kirby and Cook (14) and Marmur (15): Liver tissue (l-29) was minced in 5 volumes of sodium p-aminosalicylate, set-butanol, tetrasodium EDTA dihydrate, water (1:1:0.35:143 w/w/w/v) adjusted to pH 8 with hydrochloric acid. SDS was added to a final concentration of 1% just prior to homogenization in a loose-fitting Teflon-glass homogenizer. The homogenization was performed at 0°C. The homogenate was gently shaken with an equal volume of phenol reagent (phenol, m-cresol, &hydroxyquinoline, water lOU:l4:U.l:11 w/w/w/w) After centrifugation for 40 min at 4'C and 10,OOOxg for 45 min at 40°C. the aqueous phase was removed by suction. The phenol reagent fraction was re-extracted with 0.5 volume of the sodium p-aminosalicylate mixture. NaCl was added to the combined aqueous phases to a final concentration of 3% (w/v) and shaken with 0.5 volume of phenol reagent for 10 min and centrifuged as described above. The phenol reagent fractions were combined and stored at -20% for later protein isolation. The viscous aqueous phase was shaken for 5 min with 1 volume of chloroform-isoamyl alcohol (24:l v/v) and centrifuged at 3UUOxg for 5 min. Crude DNA was precipitated by addition of 2 volumes of 2-ethoxyethanol (-2O'C) and spooled onto a glass rod. The nucleic acids were dissolved overnight at 4'C in 5-10 ml of O.lxSSC, and after dissolution the solution was were degraded adjusted to 1xSSC by adding 1OxSSC. RNA contaminants by a 1 h incubation at 37°C with ribonuclease solution (0.1 ml, 1 my/ml). Protein contaminants were rernoved by addition of protease (0.1 ml, 1 mg/ml) and 0.25 volumes of 20% SDS to bring the solution to 0.5% SOS, followed by overnight incubation at 37°C. SDS was added to a final concentration of l%, and the DNA solution was extracted with 1 volume of chloroform-isoamyl alcohol; the DNA was precipitated with 2 volumes of ethanol (-2VC). The DNA was washed twice with ethanol, once with ether and dryed under a stream of N2. The concentration of DNA, dissolved in 2 ml of deionized distilled water, was estimated from the absorbance at 260 nm using an extinction coefficient of 22.Y ml/mg-cm, which was determined for salmon sperm DNA. DNA isolated by this procedure had A260:&0 and A26O:A230 values of 1.82tU.03 and 2.2+0.2, (10). Prior to liquid scintillation countTng the DNA . respectively solution was made U.5N in perchloric acid using concentrated perchloric
782
Vol. 103, No. 2,198l
TABLE
1.
Exposure, h
Distribution metabolites 3H-BaP.
BIOCHEMICAL
of BaP as parent to DNA and protein
% Administered Dose
hydrocarbon in liver
(n=4)e 0.6+o.lf
24
BIOPHYSICAL
or of
Organic Soluble Metabolites
Unconverted BaP
% of Total
16
AND
metabolites English sole
Water Soluble Metabolites
RESEARCH COMMUNICATIONS
and after
extent of exposure
Specifica Activity (Protein)
51+31 -
45226
16210
56+39
42t15
46218
135
95 92
14t - 2
25+18
22216
86 95
31518
50232
46228
1.1 0.3
9.5 12
89 88
90224
96
U.4zD.l
0.2 0.7
96 93
168
u.2+0.1
0.4 0.7
4.8 7.6
0.7 0.4
11 4.3
fmole BaP equivalents/mg DNA or protein. pm administered/kg fish)j/3.24x10-g=(lle CBIPM 7 L(dpm/mgDNA)/(d nut eotides)/(mmole BP administered/kg fish); using 3099 nrole BaP equivalents/mole nucleotides. Since only two fish were analyzed, individual values are Number of fish analyzed at each time point. Mean + standard error.
DNA=1
mole
BP equivalents/ of nucleotides.
mole
given.
and heated for 20 min at 1UU"C. Insta-gel (Packard was added and the radioactivity was measured.
Instrument
Isolation of Liver Protein: The phenol reagent phases were treated essentially according to method (b) of Poland and tilover (161, except the protein was precipitated by the addition of two volum& bf acetone followed by the use of 10% SUS in both dissolution-precipitation steps. The final precipitate was washed, in centrifuge tubes, twice with acetone, once with ether and dryed under a stream of nitrogen. An aliquot (20 mg) was first dissolved in 1 ml of Soluene-350 then 15 ml of Uimilume-30 was added and the radioactivity measured. All data were analyzed by one-way analysis of Statistical Analysis: variance. The averase of all time periods for specific activities for protein and DNA were tested for'difference uiing Students t-test and the Mann-Nhitney test, at a significance level of 0.05. RESULTS:
Kadioactivity
in liver
rePresented
dose at 16 h (Table
1).
The concentration
in
sole
did
liver
of English
336 h after
the
total
radioactivity
oral
not
administration in liver
Bindingc Values
(n=3) 165 9f
o.eo.2
acid Co.)
CBIb
(n=3) 412251
83 a4
c d 'f
Specifica Activity
DNA
16 15
i
binding of administered
Radioactivityd
0.8 1.2
336
covalent to orally
change
0.6% of the of BaP-derived
significantly
of BaP; greater
was in the
783
administered
form
radioactivity
from than
of the organic
16 h through
98% of the solvent-
5
85 6 16+10
Vol. 103, No. 2,198l
BIOCHEMICAL
and water-soluble the
organic
because
metabolites
or aqueous
detailed
metabolites
data
expressed
to DNA in liver
for
extent
of binding the
different
the
(Table for
lesions
The results
DNA in English
since
these
PAHs (l-10 liver
did
BaP
(pmole
body weight), the
to
data
are
of BaP intermediates BaP-exposure.
1).
As with
not
change
DNA, the
significantly of all
the
was not significantly
DNA, 44239;
individual
In
in the binding
the average
58251,
for
for
to hepatic
of activated
sole
the
the
values
values
for
first
time
are
15 fish
expressed analyzed
findings
exposed
the --in vivo
macromolecules,
carcinogens
implicated
do encounter
ppm) in their
neoplasia
indices
was observed
Moreover,
protein,
(nmole
mammals where
(Table
protein
demonstrate
The present
liver
fish
change
from
DNA, is strongly (6-11).
binding
activities
experiment.
Interaction
especially
or sediment
values
16 to 336 h after
value
of BaP intermediate(s)
in fish.
from
1).
as the mean + SD calculated
binding
diet
as specific
binding
2 wk exposure
from the average
DISCUSSION:
study
modes.
detectable
of BaP to liver
the entire
for
three
significant
values
both
binding
data
1 show that
activity
in
and conjugated
DNA are given
and covalent
in one of these
2 wk period
specific
during
1) for
published
DNA during
in this
BaP administered/kg
was observed
values
to BaP via
macromolecule),
no statistically
metabolites
not characterized
exposed
(Table
with
Data in Table
Individual
of nonconjugated
of nucleotides)/(mmole
usually
fact,
were
of nucleotide)
comparison
1).
RESEARCH COMMUNICATIONS
(3-4).
BaP equivalents/mg
permit
over
sole
earlier
The binding
BaP/mole
(Table
phases
in English
equivalent/mole
BIOPHYSICAL
characterization
has been published
(fmole
AND
with
macromolecules,
in initiation showing
DNA and protein,
of malignant
chemical
modification
to BaP is of considerable
high
levels
environment
(1)
(2).
784
of BaP and other and they
are
of
importance carcinogenic
susceptible
to
Vol.103.No.2,1981
BIOCHEMICAL
In a separate simultaneously
experiment
to L14C]
injection.
indicating
tritiated
that
of labeled
BaP fragments
of a single
for
per
body weight
mammalian
mammals,
Lutz
and 4 for
liver
of rats
gland
a Cl31 of 24 for
are susceptible
a greater
extent
rats
than
(20)
susceptible
at any time
In the during
tissues
susceptible
between
covalent
tissue
tissue
the
binding
carcinogen
(19).
range
valid,
then
English
785
a CBI of 56
were
Both
sole
feeding
obtained
when
and mammary DMBA binds
of partially liver
while
liver
for
of values Thus,
results liver.
rapidly
rodents
intact
value
to
hepatectomized
(CBI=4);
DNA and the our
a single
skin
(7-11).
neoplasms.
of a PAH with
of our data
the dose of PAH
hepatectomized (21)
administration
comparison
liver
the average
2 wk was in the
for
deoxyadenosine
after
at 16 h after
adult
neoplasms
is
a rat
incorporation
calculated
(CBI=37)
intact
study
(10)
neoplasia
to PAH-induced
to the carcinogen
is a potential
route
of partially
present
performed
Based on a compilation
and 7 for
liver
DNA from
to DMBA-induced
is not.
skin oral
to DNA from
liver
studies.
to PAH-induced
to the
proliferating
rat
to BaP via
and
shows how many molecules
although
with
exposed
unaltered
allows
tissues
studies
mice were
with
(17)
DNA from
106 DNA nucleotides
of data
of DMBA (18);
et al. liver
as Cl31 which
in various
mammary gland
[I4C]
DNA using
no biosynthetic
is different
for
both with
Viviani
associated
administered from
for
of UNA by l3aP intermediates
digested
expressed
covalently
reported
exposed
DNA.
dose of 1 mmole/kg
those
DNA.
were
an intraperitoneal
associated
practically into
potency
of a PAH are bound
with
fish
similar
modification
no tritium
indicating
The binding
DNA were
of enzymatically
and found
or deoxyguanosine
BaP via
radioactivity
exchange
analysis
[3H]-BaP,
with
the
RESEARCH COMMUNICATIONS
to be published)
for
BaP was due to chemical
a nucleoside fed
(data
values
and not due to tritium
BIOPHYSICAL
and C3H]-labeled
The binding
L3H]-BaP
AND
of
CBI (Table for
if
is
1)
mammalian
a correlation
susceptibility suggest
of a that
BaP
Vol.103,No.2,1981
BIOCHEMICAL
For at least liver
remained
studies
with
binding,
the
tissues
also
2 wk after
chemically
the
persistence
in
regenerating
liver
of DMBA, while
observed
liver.
within
constant the
rat
level
PAH.
its
binding, a long
is
ACKNOWLEDGEMENTS: Protection
Agency
by increased cells This
that
DMBA-DNA at a relatively
administration
slow
lipid
this
release
(27),
(30)
observed of sister
BaP-exposed
was supported
in part
of PAH or with of
modified
for
may adversely
et al. frequency
might
persistence
remained
interaction
of
coupled
of the
such as replication
from
was not
of a PAN-DNA complex
liver
DMBA-DNA
4 wk after
was maintained
or the
to
that
binding
events
isolated work
at least
of the cause
because
Stromberg
reported
intragastric
DNA in sole
of critical
(29).
in kidney
that
(25)
observed
cells
intracellular
Regardless
important,
a number
indicated
(26)
mechanism
from
activation.
transcription
rates,
repair
the observation
influence
damage,
a slow
of the tissue
for
or maintenance
metabolites
period
et al.
3 to 14 days after
The persistence
primary
subsequent
Janss
of
of DNA in target
such persistent
mammary parenchymal
from
be due to either
et al.
persists
from
to the magnitude
on susceptibility
the administration
complex
Evidence
modification
Marguardt rat
to BaP, DNA in sole
level.
in addition
information
RESEARCH COMMUNICATIONS
exposure
at a high
that
(Z-25).
in intact
single
of chemical
provides lesions
BIOPHYSICAL
modified
mammals suggests
neoplastic complex
AND
(28)
significant chromatid
English by the
and chromosomal exchange
sole. Environmental
(EPA 79-D-X0514).
HEFERENCES 1. 2. 3. 4.
Malins, D.C., McCain, B.B., Brown, D.W., Sparks, A.K. and Hodgins, H.O. (1980) NOAA Tech. Memo. OMPA-2, pp l-295. Pierce, K.V., McCain, B.B. and Wellings, S.R. (1978) J. Natl. Cancer Inst., 6J, 1445-1453. Varanasi, U. and (;mur, D.J. (1981) Chemical Analysis and Biological Fate: Polynuclear Aromatic Hydrocarbons (Cooke, M. and Dennis, A.J. eds), pp 367-376, Battelle Press, Columbus. Varanasi, U. and Gmur, D.J. (1981) Aquatic Toxicol., -,1 49-67.
786
Vol. 103, No. 2,198l
5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27.
28. 29. 30.
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
T. (1978) Polycyclic Hydrocarbons and Cancer, Nagao, M., and Sugimara, Vol. 2 (tielboin, H.V., and Ts'lJ, P.O.P., eds), pp. 99-121, Academic Press, New York. Kapitulnik, J., Levin, W., Conney, A.H., Yagi, H. and Jerina, D.M. (1977) Nature, 266, 378-380. Brooks, P. and Lxey, P.D. (lY64) Nature, 202, 781-784. Miller, E.C. and Miller, J.A. (lY74) The Molecular Biology of Cancer ('Busch H, ed.), pp. 377-402, Academic Press, London. Huberman, E. and Sachs, L. (1977) Int. J. Cancer, 19, 122-127. Lutz, W.K. (1979) Mutation Res., 65, 289-356. Phillips, U.H., Grover, P.L., and gms, P. (1979) Int. J. Cancer, g, ml-208. Varanasi, IJ. and Gmur, D.J. (1980) Biochem. Pharniacol., 2, 753-761. Kirby, K.S. (1965) Biochem. J., yd, 266-269. Kirby, K.S. and Cook, E.A. (1967) Biochem. J., 104, 254-257. Marmur, J. (1961) J. Mol. Biol., 3, 208-218. Poland, A. and Glover, E. (lY7q Cancer Res., 3y, 3341-3344. Viviani, A., von Daniken, A., Schlatter, Ch. and Lutz, W.K. (1980) J. Cancer Res. Clin. Oncol., 98, 139-152. Janss, D.H. and Ben, T.L. (19n) J. Natl. Cancer Inst., so, 173-177. Suss, K. and Maurer, H.R. (1968) Nature, 217, /52-753. Marquardt. H.A., Bendick, A., Philips,F.S. and Hoffmann (1971) Chem.-Viol. Interact., 3, l-11. Marquardt, H., Sternberg, S.S. and Philips, F.S. (1970) Chem.-Biol. Interact., -,2 4Dl-4U3. Lo, K. and Kakunaga, T. (1981) Biochem. Biophys. Res. Commun., ,U, 820-829. Margison, G.P. and Kleihaus, P. (1975) Biochem J., 148, 521-525. Kleihaus, P. and Margison, G.P. (lY74) J. Natl. Cancer Inst., 53, 183Y-1841. Marquardt, H.A., Bendick, A. and Philips, F.S. (1971) Proc. Am. Assoc. Cancer Kes., lZ-, 15. Janss, D.H., Moon K.C. and Irving, C.C. (1972) Cancer Res., 32, 254-258. Wills, E.U. (1980) Microsomes, Drug Oxidations, and Chemical Carcinogenesis(Coon, M.J ., Conney, A.H., Estabrook, K.W., J.R. and O'Brien, P.J. eds), pp 545-548, tielboin, H.V., Gillette, Academic Press, New York. Lin, E.J. and Weiss, S.B. (1977) Proc. Natl. HSU, W.T., Harvey, K.ti., Acad. Sci. U.S.A., 74, 1378-1382. Leffler, S., PulkraEk, P., Grunberger, D. and Weinstein, I.B. (lY77) Biochemistry, 2, 3133-3136. Stromberg, P.T., Landolt, M.L. dnd Kocan, K.M. (1981) NOAA Tech Memo. DMPA-10, pp l-43.
787
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
30,1981
November
pages
COVALENT
Usha
BINUiNG DNA IN
Varanasi,
trF BENZUlajPYRENE FISH LIVER
John
E.
Stein
Received
October
TO
and
Northwest and Alaska Fisheries Environmental Conservation 2725 Montlake Boulevard Seattle, Washington
780-787
Tom Horn
Center, Uivision East
NMFS
98112
21,1981
SUMMARY: BenzoLaApyrene became bound to the hepatic DNA in juvenile English sole (Paro hr s vetulus) force fed tritiated benzolajpyrene. No statistical +- y slgniflmchange was observed in the level of the binding from 16 h to 2 wk after the single exposure. Specific activities of binding were similar for both DNA and protein. Moreover, a binding index was calculated to represent the nurnber of benzo[a]pyrene molecules bound per 106 nucleotides after administration of a theoretical dose of 1 mmole of hydrocarbon per kg body weight. The value for English sole liver DNA was of the same order of magnitude as the values reported for mouse skin and mammary glanu in which benzo[ajpyrene is carcinogenic. INTHUDUCTIUN:
Bottom-dwelling
pleuronectid
family,
can
(1).
English
sole,
areas
exhibit
a high
possible
accumulate
them
extensively
mutagens
(5)
liver
of
whether
of
BaP-exposed
(e.g.,
liver
BaP)
half-life
levels
of
from
diet
of
sole of to
belonging PAHs
(3-4).
(2)
interact
their
The in
polluted
cellular
a
(1). and
English metabolize
characterized (6)
important fish
the environment
indicating
sediment
mammals
with
in
development and
formed
to
chemically
BaP metabolites in
UaP
from
tumor
carcinogens
English
those
neoplasms
with
A number
proximate
as
sampled of
metabolites long
high
pollutants
(3-4).
reactive
sufficiently
encounter
frequency
PAHs
and
such
a pleuronectid,
association
sole
fish,
are
as
formed
in
question liver
have
was a
macromolecules,
Abbrevidtions used: PAH, polynuclear aromatic hydrocarbon; BaP, benzo[aJpyrene; DMBA, 7,12-dimethylbenzlajanthracene; SDS, sodium dodecylsulfate; IxSSC, 0.15 2 sodium chloride, U.Ulb M sodium citrate, pH 7.4; CBI, covalent binding index; BPDE, (t)-78 , 8-(x -dihydroxy-9 10a -epoxy-7,8,Y,l&tetrahydroxybenzoLajpyreTie.
does
Uisclaimer: not constitute
Mention of endorsement
trade by
names is the U.S.
0006-291X/81/220780-08$01.00/0 Copyright 0 1981 by Academic Press, Inc. All rights of reproduciion in any form reserved.
780
for information Uepartment of
only and Commerce.
,
Vol. 103, No. 2,Wl
especially cancer that
BIOCHEMICAL
DNA, because through
with
binding
comparative
data
to that In this
BIOPHYSICAL
believed
with
of binding
the
of --in vivo
similar
is
interaction
the magnitude
roughly
it
AND
DNA.
that
chemical
carcinogens
induce
Studies
with
mammals (6-11)
show
of carcinogens
carcinogenic
potential
whether
the extent
paper
we provide
information to hepatic
expose;
to orally
BaP.
the chemical least
administered
of BaP to DNA in fish
mammalian
provide
correlates Determination
valuable
of binding
in fish
is
in mammals.
of BaP intermediate(s)
for
vivo
of the compound.
binding
of binding
to DNA --in
of PAHs, such as BaP, should to assess
RESEARCH COMMUNICATIONS
tissues
susceptible
modification
2 wk after
a single
of the exposure
on the extent DNA and protein
The results
liver
show that
was comparable
to PA&induced hepatic
of covalent in
English
the extent
to values
neoplasms
DNA was observed
sole
reported
and that for
at
to BaP.
MATERIALS AND METHODS: Sodium p-aminosalicylate, deproteinized salmon speml DNA, SDS, ribonuclease-A type l-A, and protease type V were purchased from Sigma Chemical Co., St. Louis, Missouri. The ribonuclease was dissolved in water (1 my/ml) and heated at 80-85°C for 15 min to inactivate any contaminating deoxyribonucleases; the protease was also dissolved in water (1 mg/ml), self-digested for 1 h at 37"C, heated for 2 min at 80°C then quenched in ice. The ribonuclease and protease solutions were stored at -2U'C. Generally labeled [3H]-BaP was purchased from Amersham-Searle, Arlington Heights, Illinois. The [3H]-BaP was purified as described previously (12). The m-cresol was distilled under reduced pressure. All other chemicals were of reagent or analytical grade and used without further purification. Animals: English sole (118+19g), obtained by trawling from Puget Sound, were kept in flowing seawater at 11°C and fed a diet of minced clams for three weeks. The feeding was stopped two days prior to starting the experiment and resumed 48 h after initiation of exposure, with the fish being fed every other day. The fish were force-fed gelatin capsules (no. 3) containing 0.69 mCi of L3H]-BaP (sp act 17.4 Ci/mmole) dissolved in 50 vl of corn oil. The average dose of BaP was 88t12 Pg/kg body weight. Fish were sacrificed by a blow to the head at-16, 24, 96, 168 and 336 h after being fed BaP; the liver was removed and stored at -65'C. The concentration of radioactivity in liver Radioactivity in Liver: was determined from a sample (O.lg) of liver solubilized in 1 ml of Soluene-350 (Packard Instrument Co.) and decolorized with 200 1~1 of both isopropanol and 30% hydrogen peroxide; 15 ml of Dimilume-30 (Packard Instrument Co.) was added and the radioactivity measured using a Packard The distribution of radioactivity 300C liquid scintillation spectrometer.
781
Vol. 103, No. 2.1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
in liver as unconverted BaP, organic solvent-soluble BaP metabolites, and water-soluble BaP metabolites was determined by homogenization of liver and ethyl acetate extraction, followed by thin-layer chromatography A 200 !~l aliquot of the liver homogenate was of the organic phase (4). diluted to 1 ml with water, and an aliquot removed for measurement of The remaining aqueous solution was mixed with 1 volume radioactivity. of N2-saturated acetone, then extracted twice with 1 volume N2-saturated ethyl acetate. The organic extract waS dried over Na2S04, an aliquot removed and radioactivity measured. The remaining extract was removed by suction, evaporated to dryness under a stream of nitrogen, then dissolved in 50-100 Ul of ethyl acetate containing BaP and its oxygenated standards. The organic extract with added standards was spotted on the pre-adsorbent layer of a channeled thin-layer chromatographic plate (Whatman No. LKSU, Whatman Inc., Clitton, N.J.) and developed with hexane: ether (Y5:5, v/v). The adsorbent from the thin-layer chromatoyraphic plate was removed in three fractions. The first fraction contained BaP metabolites (Rf = 0.1) and the pre-adsorbent pad; the second fraction was the adsorbent between Rf of 0.1 and 0.5. The third fraction of adsorbent contained unmetabolized BaP (Rf = 0.5). The radioactivity was measured in each fraction. All of these operations were performed under red light to minimize photooxidation.
Isolation of Liver DNA: Liver DNA was isolated according to parts of the methods by Kirby (13), Kirby and Cook (14) and Marmur (15): Liver tissue (l-29) was minced in 5 volumes of sodium p-aminosalicylate, set-butanol, tetrasodium EDTA dihydrate, water (1:1:0.35:143 w/w/w/v) adjusted to pH 8 with hydrochloric acid. SDS was added to a final concentration of 1% just prior to homogenization in a loose-fitting Teflon-glass homogenizer. The homogenization was performed at 0°C. The homogenate was gently shaken with an equal volume of phenol reagent (phenol, m-cresol, &hydroxyquinoline, water lOU:l4:U.l:11 w/w/w/w) After centrifugation for 40 min at 4'C and 10,OOOxg for 45 min at 40°C. the aqueous phase was removed by suction. The phenol reagent fraction was re-extracted with 0.5 volume of the sodium p-aminosalicylate mixture. NaCl was added to the combined aqueous phases to a final concentration of 3% (w/v) and shaken with 0.5 volume of phenol reagent for 10 min and centrifuged as described above. The phenol reagent fractions were combined and stored at -20% for later protein isolation. The viscous aqueous phase was shaken for 5 min with 1 volume of chloroform-isoamyl alcohol (24:l v/v) and centrifuged at 3UUOxg for 5 min. Crude DNA was precipitated by addition of 2 volumes of 2-ethoxyethanol (-2O'C) and spooled onto a glass rod. The nucleic acids were dissolved overnight at 4'C in 5-10 ml of O.lxSSC, and after dissolution the solution was were degraded adjusted to 1xSSC by adding 1OxSSC. RNA contaminants by a 1 h incubation at 37°C with ribonuclease solution (0.1 ml, 1 my/ml). Protein contaminants were rernoved by addition of protease (0.1 ml, 1 mg/ml) and 0.25 volumes of 20% SDS to bring the solution to 0.5% SOS, followed by overnight incubation at 37°C. SDS was added to a final concentration of l%, and the DNA solution was extracted with 1 volume of chloroform-isoamyl alcohol; the DNA was precipitated with 2 volumes of ethanol (-2VC). The DNA was washed twice with ethanol, once with ether and dryed under a stream of N2. The concentration of DNA, dissolved in 2 ml of deionized distilled water, was estimated from the absorbance at 260 nm using an extinction coefficient of 22.Y ml/mg-cm, which was determined for salmon sperm DNA. DNA isolated by this procedure had A260:&0 and A26O:A230 values of 1.82tU.03 and 2.2+0.2, (10). Prior to liquid scintillation countTng the DNA . respectively solution was made U.5N in perchloric acid using concentrated perchloric
782
Vol. 103, No. 2,198l
TABLE
1.
Exposure, h
Distribution metabolites 3H-BaP.
BIOCHEMICAL
of BaP as parent to DNA and protein
% Administered Dose
hydrocarbon in liver
(n=4)e 0.6+o.lf
24
BIOPHYSICAL
or of
Organic Soluble Metabolites
Unconverted BaP
% of Total
16
AND
metabolites English sole
Water Soluble Metabolites
RESEARCH COMMUNICATIONS
and after
extent of exposure
Specifica Activity (Protein)
51+31 -
45226
16210
56+39
42t15
46218
135
95 92
14t - 2
25+18
22216
86 95
31518
50232
46228
1.1 0.3
9.5 12
89 88
90224
96
U.4zD.l
0.2 0.7
96 93
168
u.2+0.1
0.4 0.7
4.8 7.6
0.7 0.4
11 4.3
fmole BaP equivalents/mg DNA or protein. pm administered/kg fish)j/3.24x10-g=(lle CBIPM 7 L(dpm/mgDNA)/(d nut eotides)/(mmole BP administered/kg fish); using 3099 nrole BaP equivalents/mole nucleotides. Since only two fish were analyzed, individual values are Number of fish analyzed at each time point. Mean + standard error.
DNA=1
mole
BP equivalents/ of nucleotides.
mole
given.
and heated for 20 min at 1UU"C. Insta-gel (Packard was added and the radioactivity was measured.
Instrument
Isolation of Liver Protein: The phenol reagent phases were treated essentially according to method (b) of Poland and tilover (161, except the protein was precipitated by the addition of two volum& bf acetone followed by the use of 10% SUS in both dissolution-precipitation steps. The final precipitate was washed, in centrifuge tubes, twice with acetone, once with ether and dryed under a stream of nitrogen. An aliquot (20 mg) was first dissolved in 1 ml of Soluene-350 then 15 ml of Uimilume-30 was added and the radioactivity measured. All data were analyzed by one-way analysis of Statistical Analysis: variance. The averase of all time periods for specific activities for protein and DNA were tested for'difference uiing Students t-test and the Mann-Nhitney test, at a significance level of 0.05. RESULTS:
Kadioactivity
in liver
rePresented
dose at 16 h (Table
1).
The concentration
in
sole
did
liver
of English
336 h after
the
total
radioactivity
oral
not
administration in liver
Bindingc Values
(n=3) 165 9f
o.eo.2
acid Co.)
CBIb
(n=3) 412251
83 a4
c d 'f
Specifica Activity
DNA
16 15
i
binding of administered
Radioactivityd
0.8 1.2
336
covalent to orally
change
0.6% of the of BaP-derived
significantly
of BaP; greater
was in the
783
administered
form
radioactivity
from than
of the organic
16 h through
98% of the solvent-
5
85 6 16+10
Vol. 103, No. 2,198l
BIOCHEMICAL
and water-soluble the
organic
because
metabolites
or aqueous
detailed
metabolites
data
expressed
to DNA in liver
for
extent
of binding the
different
the
(Table for
lesions
The results
DNA in English
since
these
PAHs (l-10 liver
did
BaP
(pmole
body weight), the
to
data
are
of BaP intermediates BaP-exposure.
1).
As with
not
change
DNA, the
significantly of all
the
was not significantly
DNA, 44239;
individual
In
in the binding
the average
58251,
for
for
to hepatic
of activated
sole
the
the
values
values
for
first
time
are
15 fish
expressed analyzed
findings
exposed
the --in vivo
macromolecules,
carcinogens
implicated
do encounter
ppm) in their
neoplasia
indices
was observed
Moreover,
protein,
(nmole
mammals where
(Table
protein
demonstrate
The present
liver
fish
change
from
DNA, is strongly (6-11).
binding
activities
experiment.
Interaction
especially
or sediment
values
16 to 336 h after
value
of BaP intermediate(s)
in fish.
from
1).
as the mean + SD calculated
binding
diet
as specific
binding
2 wk exposure
from the average
DISCUSSION:
study
modes.
detectable
of BaP to liver
the entire
for
three
significant
values
both
binding
data
1 show that
activity
in
and conjugated
DNA are given
and covalent
in one of these
2 wk period
specific
during
1) for
published
DNA during
in this
BaP administered/kg
was observed
values
to BaP via
macromolecule),
no statistically
metabolites
not characterized
exposed
(Table
with
Data in Table
Individual
of nonconjugated
of nucleotides)/(mmole
usually
fact,
were
of nucleotide)
comparison
1).
RESEARCH COMMUNICATIONS
(3-4).
BaP equivalents/mg
permit
over
sole
earlier
The binding
BaP/mole
(Table
phases
in English
equivalent/mole
BIOPHYSICAL
characterization
has been published
(fmole
AND
with
macromolecules,
in initiation showing
DNA and protein,
of malignant
chemical
modification
to BaP is of considerable
high
levels
environment
(1)
(2).
784
of BaP and other and they
are
of
importance carcinogenic
susceptible
to
Vol.103.No.2,1981
BIOCHEMICAL
In a separate simultaneously
experiment
to L14C]
injection.
indicating
tritiated
that
of labeled
BaP fragments
of a single
for
per
body weight
mammalian
mammals,
Lutz
and 4 for
liver
of rats
gland
a Cl31 of 24 for
are susceptible
a greater
extent
rats
than
(20)
susceptible
at any time
In the during
tissues
susceptible
between
covalent
tissue
tissue
the
binding
carcinogen
(19).
range
valid,
then
English
785
a CBI of 56
were
Both
sole
feeding
obtained
when
and mammary DMBA binds
of partially liver
while
liver
for
of values Thus,
results liver.
rapidly
rodents
intact
value
to
hepatectomized
(CBI=4);
DNA and the our
a single
skin
(7-11).
neoplasms.
of a PAH with
of our data
the dose of PAH
hepatectomized (21)
administration
comparison
liver
the average
2 wk was in the
for
deoxyadenosine
after
at 16 h after
adult
neoplasms
is
a rat
incorporation
calculated
(CBI=37)
intact
study
(10)
neoplasia
to PAH-induced
to the carcinogen
is a potential
route
of partially
present
performed
Based on a compilation
and 7 for
liver
DNA from
to DMBA-induced
is not.
skin oral
to DNA from
liver
studies.
to PAH-induced
to the
proliferating
rat
to BaP via
and
shows how many molecules
although
with
exposed
unaltered
allows
tissues
studies
mice were
with
(17)
DNA from
106 DNA nucleotides
of data
of DMBA (18);
et al. liver
as Cl31 which
in various
mammary gland
[I4C]
DNA using
no biosynthetic
is different
for
both with
Viviani
associated
administered from
for
of UNA by l3aP intermediates
digested
expressed
covalently
reported
exposed
DNA.
dose of 1 mmole/kg
those
DNA.
were
an intraperitoneal
associated
practically into
potency
of a PAH are bound
with
fish
similar
modification
no tritium
indicating
The binding
DNA were
of enzymatically
and found
or deoxyguanosine
BaP via
radioactivity
exchange
analysis
[3H]-BaP,
with
the
RESEARCH COMMUNICATIONS
to be published)
for
BaP was due to chemical
a nucleoside fed
(data
values
and not due to tritium
BIOPHYSICAL
and C3H]-labeled
The binding
L3H]-BaP
AND
of
CBI (Table for
if
is
1)
mammalian
a correlation
susceptibility suggest
of a that
BaP
Vol.103,No.2,1981
BIOCHEMICAL
For at least liver
remained
studies
with
binding,
the
tissues
also
2 wk after
chemically
the
persistence
in
regenerating
liver
of DMBA, while
observed
liver.
within
constant the
rat
level
PAH.
its
binding, a long
is
ACKNOWLEDGEMENTS: Protection
Agency
by increased cells This
that
DMBA-DNA at a relatively
administration
slow
lipid
this
release
(27),
(30)
observed of sister
BaP-exposed
was supported
in part
of PAH or with of
modified
for
may adversely
et al. frequency
might
persistence
remained
interaction
of
coupled
of the
such as replication
from
was not
of a PAN-DNA complex
liver
DMBA-DNA
4 wk after
was maintained
or the
to
that
binding
events
isolated work
at least
of the cause
because
Stromberg
reported
intragastric
DNA in sole
of critical
(29).
in kidney
that
(25)
observed
cells
intracellular
Regardless
important,
a number
indicated
(26)
mechanism
from
activation.
transcription
rates,
repair
the observation
influence
damage,
a slow
of the tissue
for
or maintenance
metabolites
period
et al.
3 to 14 days after
The persistence
primary
subsequent
Janss
of
of DNA in target
such persistent
mammary parenchymal
from
be due to either
et al.
persists
from
to the magnitude
on susceptibility
the administration
complex
Evidence
modification
Marguardt rat
to BaP, DNA in sole
level.
in addition
information
RESEARCH COMMUNICATIONS
exposure
at a high
that
(Z-25).
in intact
single
of chemical
provides lesions
BIOPHYSICAL
modified
mammals suggests
neoplastic complex
AND
(28)
significant chromatid
English by the
and chromosomal exchange
sole. Environmental
(EPA 79-D-X0514).
HEFERENCES 1. 2. 3. 4.
Malins, D.C., McCain, B.B., Brown, D.W., Sparks, A.K. and Hodgins, H.O. (1980) NOAA Tech. Memo. OMPA-2, pp l-295. Pierce, K.V., McCain, B.B. and Wellings, S.R. (1978) J. Natl. Cancer Inst., 6J, 1445-1453. Varanasi, U. and (;mur, D.J. (1981) Chemical Analysis and Biological Fate: Polynuclear Aromatic Hydrocarbons (Cooke, M. and Dennis, A.J. eds), pp 367-376, Battelle Press, Columbus. Varanasi, U. and Gmur, D.J. (1981) Aquatic Toxicol., -,1 49-67.
786
Vol. 103, No. 2,198l
5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27.
28. 29. 30.
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
T. (1978) Polycyclic Hydrocarbons and Cancer, Nagao, M., and Sugimara, Vol. 2 (tielboin, H.V., and Ts'lJ, P.O.P., eds), pp. 99-121, Academic Press, New York. Kapitulnik, J., Levin, W., Conney, A.H., Yagi, H. and Jerina, D.M. (1977) Nature, 266, 378-380. Brooks, P. and Lxey, P.D. (lY64) Nature, 202, 781-784. Miller, E.C. and Miller, J.A. (lY74) The Molecular Biology of Cancer ('Busch H, ed.), pp. 377-402, Academic Press, London. Huberman, E. and Sachs, L. (1977) Int. J. Cancer, 19, 122-127. Lutz, W.K. (1979) Mutation Res., 65, 289-356. Phillips, U.H., Grover, P.L., and gms, P. (1979) Int. J. Cancer, g, ml-208. Varanasi, IJ. and Gmur, D.J. (1980) Biochem. Pharniacol., 2, 753-761. Kirby, K.S. (1965) Biochem. J., yd, 266-269. Kirby, K.S. and Cook, E.A. (1967) Biochem. J., 104, 254-257. Marmur, J. (1961) J. Mol. Biol., 3, 208-218. Poland, A. and Glover, E. (lY7q Cancer Res., 3y, 3341-3344. Viviani, A., von Daniken, A., Schlatter, Ch. and Lutz, W.K. (1980) J. Cancer Res. Clin. Oncol., 98, 139-152. Janss, D.H. and Ben, T.L. (19n) J. Natl. Cancer Inst., so, 173-177. Suss, K. and Maurer, H.R. (1968) Nature, 217, /52-753. Marquardt. H.A., Bendick, A., Philips,F.S. and Hoffmann (1971) Chem.-Viol. Interact., 3, l-11. Marquardt, H., Sternberg, S.S. and Philips, F.S. (1970) Chem.-Biol. Interact., -,2 4Dl-4U3. Lo, K. and Kakunaga, T. (1981) Biochem. Biophys. Res. Commun., ,U, 820-829. Margison, G.P. and Kleihaus, P. (1975) Biochem J., 148, 521-525. Kleihaus, P. and Margison, G.P. (lY74) J. Natl. Cancer Inst., 53, 183Y-1841. Marquardt, H.A., Bendick, A. and Philips, F.S. (1971) Proc. Am. Assoc. Cancer Kes., lZ-, 15. Janss, D.H., Moon K.C. and Irving, C.C. (1972) Cancer Res., 32, 254-258. Wills, E.U. (1980) Microsomes, Drug Oxidations, and Chemical Carcinogenesis(Coon, M.J ., Conney, A.H., Estabrook, K.W., J.R. and O'Brien, P.J. eds), pp 545-548, tielboin, H.V., Gillette, Academic Press, New York. Lin, E.J. and Weiss, S.B. (1977) Proc. Natl. HSU, W.T., Harvey, K.ti., Acad. Sci. U.S.A., 74, 1378-1382. Leffler, S., PulkraEk, P., Grunberger, D. and Weinstein, I.B. (lY77) Biochemistry, 2, 3133-3136. Stromberg, P.T., Landolt, M.L. dnd Kocan, K.M. (1981) NOAA Tech Memo. DMPA-10, pp l-43.
787