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Nuclease-sensitivity of methylated DNA as a probe for chromatin reconstitution by genotoxicants
Vol. 107, No. 2, 1982 July 30, 19812
BIOCHEMICAL
AND BIOPHYSICAL
NUCLEASE-SENSITIVITY
OF METHYLATED DNA AS A PROBE
FOR CHROMATIN RECONSTITUTION Akira Department 39th Received
June
Nishio*
of Pharmacology, St. and Rainbow 11,
RESEARCH COMMUNICATIONS Pages 485-491
and
BY GENOTOXICANTS+
Edwin
M. Uyeki*
The University of Kansas Blvd., Kansas City, Kansas
Medical 66103,
Center, USA.
1982
DNA iln Chinese hamster ovary cells was labeled with [W]thymidine and [methylsH]-1-methionine in culture, and their nuclei were digested with nuclease. Not until 10 percent of bulk DNA was digested did micrococcal acid-soluble fraction. methylated DNA appear in the When these cells were exposed to UV-radiation, alkylating agents and intercalating agents in culture, the resistance of methylated DNA to digestion by the nuclease was largely or completely eliminated. The change in the sensitivity of methylated DNA to the induced by the nuclease indicates a conformational change in chromatin genotoxicants.
INTRODUCTION The bulk 200-base
pair
base pairs
of il
units,
DNA
(1,2).
replication.
inf'..uence repair however,
is
nucleosome. around
The
"phasing"
(
nucleosome
in genes
the
eukaryotes
There is
is
generally
the
be
consensus
that (3).
of
linker of
of
such
core
into
the
because
the
can also
are
been
subject
and
of nucleosomes significantly
by physical/chemical have
DNA
location
gene expression
structure
146
60 base
to the
specific
distribution
studies studies
of about relative
a means of regulating
Nucleosome
of about
each of histones
consisting
nucleosome
a non-random
approximately
consists
two molecules
region
of DNA damage induced
Nuclease-digestion results
A nucleosome
much interest
gene may
obtained
the distribution processes.
arrangement
) has received
in a
known to be packed
an octamer
H3 and H4, and a nucleosome
of
seqt..ence
DNA in
of DNA winding
H2a, H2b, pairs
of
agents
invaluable to
and
probes;
contradictory
reorganization of nucleosome structure interpretations because of the possible -~ * : supported by NIEHS Grant No. ES-02046, and to whom all correspondence should be addressed. **: present address: 2nd Department of Medicine, Kyoto Prefectural University of Medicine, Kajii-cho, Kawaramachi Hirokoji, Kamikyoku, Kyoto 602, Japan.
0006-291X/82/140485-07$01.00/0 485
Copyright 0 1982 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 107, No. 2, 1982
BIOCHEMICAL
by damage
processes
the
and repair
detection
sequences
are
for
2 to
nucleosome
structure
9),
portions
(10,
differential in nucleosome
7
has (7);
times
up
to 75
11).
(MeCyt)
percent
MeCyt
several and
changes
5-methylcytosine
of
(8,
Further
RESEARCH COMMUNICATIONS
development
in
of
chromatin
with
the only
minor
the methods respect
for
to
DNA
required.
distribution
of DNA is
(4,5).
conformational
of
In mammals, accounts
AND BIOPHYSICAL
In
been the
higher
this
total
cytosine
reported
abundance than
percent
nuclease-sensitivity reconstitution
of
is
of study, of
induced
with
respect
of MeCyt
in highly
in moderately total
residues
MeCyt
to
DNA sequences
repetitive
is
in
the and bulk
possibility DNA to
and
sequences
or unique
located
in DNA and Non-random
(6).
repetitive
we investigated methylated
base
sequences
nucleosome
core
of using detect
a
changes
by genotoxicants.
MATERIALS AND METHODS Chemicals: Doxorubicin was supplied by The Drug Synthesis and Chemical Branch, National Cancer Institute (Bethesda, MD). Dichlorvos was supplied by Analytical Chemistry, U.S. Environmental Protection Agency (Research Triangle Louis, Park, NC). Ethyl methanesulfonate (EMS) was obtained from Sigma ( St. [methylsH]-1-methionine (specific activity: 12 Ci/mmole) was obtained MO). from New England Nuclear (Boston, MS). [2-l%] thymidine (54 mCi/mmole) and [methylsH]thymidine (48 Ci/mmole) were from Schwarz/Mann (Orangeburg, NY). Micrococcal nuclease was obtained from Worthington ( Freehold, NJ). Cell culture: Chinese hamster ovary (CHO) cells were grown as a monolayer in RPM1 1640 medium supplemented with 10 percent fetal calf serum, an additional 10 rig/ml insulin and penicillin/streptomycin at 37'C in a water2 gm/L glucose, Radio-labeling of DNA was done overnight by adding jacketed CO2 incubator. [methyl-sH]methionine, ['4C]thymidine or [aH]thymidine at concentrations of 5, 0.05 and 1 uCi/ml, respectively. For the treatment with genotoxicants the medium containing radioactivity was discarded, and cells were washed once with phosphate buffered saline (PBS), chased with fresh medium for 2 hr, and then exposed to chemicals for 3 hr or W-light (predominantly 254 nm) in PBS. of CHO cell nuclei followed Digestion by nuclease: Preparation the method Nuclei were suspended in a buffer consisting reported by Muramatsu et al (12). of 0.25 M sucrose, 0.1 mM CaC12, 1 mM Tris-HCl (pH 7.8) at a concentration of 108 nuclei/ml. Micrococcal nuclease was added at a concentration of 50 U/10* nuclei. Digestion was continued in a 37X water bath and terminated by adding of 10 percent perchloric acid (PCA) or 10 mM EDTA and chilling an equal volume in ice. Digestion of bulk DNA was determined by measuring the radioactivity of [ 14C]thymidine in the cold PCA-soluble and -insoluble fractions of nuclease-treated nuclei, after solubilization of DNA with 5 percent PCA by heating at 90 'C for 20 min.
rig/ml),
Extraction pronase
of DNA: The EDTA-added nuclei (0.5 mg/ml) and sodium dodecyl 486
were treated with (1 percent) sulfate
RNase A (0.5 in a buffer
Vol. 107, No. 2, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
containing 0.2 M NaCl, 5 mM EDTA and 10 mM Tris-HCl (pH 7.8) at 37'C for 1, 4 and 2 hr, respectively. DNA was extracted twice with phenol: chloroform: isoamyl alcohol (24: 24: 1) and precipitated overnight with 3 volumes of ethanol with 5 pg calf thymus DNA as carrier at -20 'C. For measurement of radioactivity, DNA was solubilized in 5 percent PCA by heating at 90°C for 20 min and ad.ded to a xylene-based scintillation counting fluid. Radioactivity of [methyl-sH] methionine in the ethanol-precipitated DNA was rendered completely acid-soluble by DNase I, but not by RNase A or pronase. The possibility that radioactivity resides in the methyl group of thymine and purine rings can not be excluded (1.1, 13, 14), since the radioactivity among the DNA bases was not determined. RESULTS kinetics
of
methylated
shown in
Fig
1 A.
Digestion nuclease acid
are
soluble
using
did
the
mouse L cells
Met-)NA
is
digested
Met-DNA
initiated,
a
accord is
reports
compared
with
digested
in
parallel
with
of
total
of bulk
and this
bulk
DNA by micrococcal DNA was rendered
We obtained
of others
manner
( 40 percent
remained
occur.
observations), the
and bulk
10 percent
of Met-DNA
with
plateau
of Met-DNA
Not until
(unpublished
proceeded
DNA reached percent
in
digestion
DNA (Met-DNA)
nuclease-
(10,111.
DNA. bulk
similar
In
Digestion
DNA.
resistance Fig.
undigested
of
1 B, the
of Met-DNA,
When digestion
DNA remained
results,
once
of bulk 1, 50 - 60
undigested.
fl40 0
3 : 30 I
o$
a 2o iFI 1 10
,OOk
15
/ I" 9'
;c 0L 0
TIMECMIN)
A
/
d""
10 20 -1. DIGESTED
30 40 BULK DNA
50
of methylated DNA and bulk DNA in nuclei by micrococcal --Fig. 1. Digestion nuclease. A: kinetics of digestion. CHO cells were labeled overnight with [methyl-aH]-1-mzthionine and ['4C]thymidine, 5 and 0.05 pCi/ml, respectively. Isolated nuclei were digested with micrococcal nuclease ( 50 U enzyme/108 nuclei 1 at 37 'C for the indicated periods. Undigested DNA was purified, and the radioactivity was determined by scintillation counting. o: methylated DNA ([sH]). .: bulk DNA ([WI). B: Digestion of methylated DNA as a function of bulk DNA. Digestion of methylated DNA was plotted against bulk DNA. 0, a, 0 represent
three
different
experiments.
487
BIOCHEMICAL
Vol. 107, No. 2, 1982 The resistance were
with
treated
hr.
of
2
Fig.
A shows
digestion
of
the
digestion
as
is
a
investigated;
a
known
and
protein similar
J/m')
curve of
on did
in the
the
the nuclease not
abolish
abolition
chemicals
0
5 10 TIMECMIN)
DNA
on
in
cells
bulk
protein
(16).
preferentially
treated
% DIGESTED
BULK
with
EMS is
methylates
and
genotoxicants although
completely,
a
(Fig.
3).
DNA was
also
the
drugs
15 DNA
Fig. 2. A: Digestion kinetics of methylated and bulk DNA in nuclei treated with dichlorvos. The radiolabeled cells were treated for 3 hr with 10 mM dichlorvos in culture, and isolated nuclei +re subjected to digestion by micrococcal nuclease under similar conditions to Fig. 1. o: methylated DNA. .: bulk DNA. B. Effects of dichlorvos, EMS and doxorubicin on the nuclease sensitivity of methylated DNA. This figure is represented in a similar way to Fig. 1 B. 0: control. ., A, . : cells were treated with 10 mM dichlorvos ( . ), 20 mM EMS ( A ) and 20 uM doxorubicin ( u ) for 3 hr in culture.
488
a an
was observed bulk
and
Dichlorvos,
of Met-DNA
were
the
Met-DNA.
(15).
chemical
of
with
and
of chromatin;
kinetics
B shows
disappeared,
agent
resistance
3
DNA in
2
treated
both
The three
bulk
Fig.
to digestion
the resistance
digestion
EMS.
in nuclei
sensitivity
of this
cells
by the nuclease.
anticancer
pesticide,
[sH]thymidine-labeled
50’
and
and
digested
fashion
DNA (17).
Met-DNA
and
of Met-DNA
DNA
than
rather
of
equally
intercalating
when
(10 mM) and EMS (20 mM) for
of bulk
parallel
alkylates
effect
(100
dose response Effect
in
were
was abolished
doxorubicin
organophosphate
phosphorylates
W-radiation
with
resistance
well
anti-cholinesterase
a
DNAs
RESEARCH COMMUNICATIONS
digestion
kinetics
a function
initial
mutagen
showed
both
proceeded
Doxorubicin strong
digestion
obtained
Met-DNA
genotoxicants; the
the
were
nuclease
(20 JIM), dichlorvos
nuclei;
results
to
doxorubicin
dichlorvos-treated Similar
Met-DNA
AND BIOPHYSICAL
in
BIOCHEMICAL
Vol. 107, No. 2, 1982
60’.
03
' ' 3 5 TIME(MIN)
0 1
Fig. DNA. -&n an additional bulk DNA. (0 ).
3.
AND BIOPHYSICAL
04 50. 0
4 10
' 7
RESEARCH COMMUNICATIONS
of W-radiation Effects were exposed to W-radiation 3 hr. The condition 0, A, q : methylated DNA,
5 TIME
10 (MINI
15
on
the digestion kinetics of methylated at 8, 20 and 100 J/msand cultured for .: for digestion was similar to Fig. 1. irradiated 8 ( a ), 20 ( o ) and 100 J/m2
Fig’ 4 Digestion kinetics of bulk DNA in nuclei treated with Llchlorvos. -c ('HO cellls were labeled with overnight L3Hl- or [ ‘4C] thymidine conditlonH ['HI-labeled cells were treated with dichlorvoa under similar to Fig. 1. Isolated [sH]- and ['4C]-labeled nuclei were mixed and subjected to digestion by micrococcal nuclease. o: dichlorvos-treated DNA. .: control DNA.
culture,
and
controls.
digestion
Fig. 4 shows
betws?en with
the
was compared that
there
dichlorvos-treated
doxorubicin
and
and EMS ( data
are
that
of
no differences
control not
with
cells.
shown
['4C]thymidine-labeled in nuclease-sensitivity
Similar
results
were
obtained
1.
DISCUSSION An explanation earl,?
of
course
distributed reports
in on
the
preferentially whether
for
(Fig. cores
distribution
of
distributed
or not nuclease-sensitivity
nucleosome
core
requires
Many studies re
digestion
nucleosome
(19)
lationship
between
further
are
nuclease-resistance
the micrococcal
currently
methylated
1)
is
11).
(IO, MeCyt in the
that
Met-DNA
There
are,
in chromatin: linker
of Met-DNA
of Met-DNA
portion will
is
preferentially
however, it
is
in the
conflicting
randomly
(18)
of nucleosome.
be a useful
"marker"
or
Hence, for
the
investigation. under DNA and gene 489
investigation activity
dealing (20).
There
with
the
i s agreement
Vol. 107, No. 2, 1982
BIOCHEMICAL
that
of a
hypomethylation
active
transcription different
hypersensitive
to pancreatic
possibility,
higher
rendering
their
order
(doxorubicin), abolished
change
previously
was
show
a more observed
not
in the
abrupt
and steeper
higher
order
is
the
and
Genotoxicant
effects
conformational
presence
on these
changes
genotoxicants
nuclease-hypersensitivity
and,
these
occurred as of
either
DNA >,
The
effects
completely
is
that
nuclease
that
2 B),
is
that
a DNA
are now
in the
early
Met-DNA
curves
steeper
slope
this
and that
of an all-or-none
We
there
action,
of Met-DNA
or
3).
such a manner
fact
(Fig.
agent
2 and
DV-radiation
response,
is a toxicant-induced
Fig.
is
mobility is
3 )
between
presently proteins
our
study,
the hypomethylated,
in progress. 490
in the
loss
normally
of nuclease-
dependent
on histone
(HMG) of proteins
these in
change
chromatin,
somewhat
group not
topological
"active" resulting
proteins
observed
as
possibility.
there
high
in bulk
(Fig.
to
of transcriptionally
of
genes.
as well
toxicant-treated
Nuclease-hypersensitivity
acetylation
(25).
an intercalating
Met-DNA
further, slope.
first
is
"active"
occurring
resistance
and nuclease-hypersensitive,
hypersensitivity.
those
opaque
( instead
that
structure
and,
chromatin
configurations
and DNA in
Met-DNA
of this
possibility
hypomethylated
of
be lost
curve
the feasibility
one for
hence,
should
response
lessens
of
then
is
nuclease
with
(EMS and dichlorvos),
the case,
drug-treated
a dose
A second
were
chromatin
hydrolysis.
the nucleosome
in
showed
with
with
nuclease-hypersensitive,
UV-radiation,
the first
and,
to micrococcal
nucleosome
to acid
agents
between
this
of digestion
would
different
correlated
"active"
may correlate
( compared
"covered"
If
susceptible. course
studies
genotoxicants,
two possibilities;
(24);
micrococcal
nuclease-resistance
the
conformational sites,
with
alkylating
and
considered
our
in
the
is
"active"
and possibly
that
structures
the
with
sequences
chromatin
DNA more susceptible
Treatment
almost
bulk
exists
Such genes may be associated different
neighboring
DNase I,
DNA observed
RESEARCH COMMUNICATIONS
Transcriptionally
from
thus,
hypomethylated
gene and
(21-23).
topologically
The
AND BIOPHYSICAL
known.
(25,
26).
We believe
that
and DNA with resulted
"active"
DNA.
in
the
addition
abolition
Further
work
of is
BIOCHEMICAL
Vol. 107, No. 2, 1982 Using digestion
radio-labeled kinetics
genocoxicants.
Met-DNA of
association
with
rearrangement
digestion
showed
no
differences;
conformational
changes
be
detected
chromatin general
by DNA.
utility
by
of bulk we
nuclease
increase
We believe
that
study
the change the
by Met-DNA in the
It
of genotoxic
is
to
mean are
in
dependent a
on its
structural
noteworthy cells that
not
nuclease-digestible DNA and Met-DNA
the
large
that
assays
a
(Fig.
4)
putative
enough
fraction
the
several
by
indicates
and control
labeling
the use of bulk
a change
DNA is
probably
toxicants.
this
that
was induced
of nuclear
interpreted
suggested
RESEARCH COMMUNICATIONS showed
DNA in drug-treated
a gross
in the
we
micrococcal
proteins,
chromatin
comparative
probe,
nuclease-sensitivity
chromatin of
as a
DNA by
Because
AND BIOPHYSICAL
as to
of whole will
have
agents.
REFERENCES 1. 2. 3. 4. 5. 6. 7. a. 9. 10. 11. 12. 13. 14. 15. 16. 17. ia. 19. 20. 21. 22. 23. 24. 25. 26.
Kornberg, R.D. (1977) Ann. Rev. Biochem. 46, 931-954. McGhee, J.D. and Felsenfeld, G. (1980) Ann. Rev. Biochem. 49, 1115-1156. Zachau, H.G. and Igo-Kemenes, T. (1981) Cell 24, 597-598. Hanawalt, P.C., Cooper, P.K., Ganesan, A.K. and Smith, C.A. (1979) Ann. Rev. Biochem. 48, 783-836. Lehmann, A.R. and Karran, P. (1981) Int. Rev. Cytol. 72, 101-146. Vanyushin, B.F., Tkacheva, S.G. and Belozersky, A.N. (1970) Nature 225, 948-949. Razin, A. and Friedman, .J. (1981) Prog. Nucl. Acid Res. Mol. Biol. 25, 33-52. Salom'on, R., Kaye, A.M. and Herzberg, M. (1969) J. Mol. Biol. 43, 581-592. Romanov, G.A. and Vanyushin, B.F. (1981) Biochim. Biophys. Acta 653, 204-218. Razin, A and Cedar, H. (1977) Proc. Natl. Acad. Sci. USA. 74, 2725-2728. Solage, A. and Cedar, H. (1978) Biochemistry 17, 2934-2938. Muramatsu, M., Hayashi, Y., Onishi, T., Sakai, M., Takai, K. and Kashiyama, T. (1974) Exp. Cell Res. 88, 345-351. Winocour, E., Kaye, A.M. and Stollar, V. (1965) Virology 27, 156-169. R.L. (1970) J. Mol. Biol. 53, 251Razin, A., Sedat, J.W. and Sinsheimer, 259. Waring, M.J. (1981) Ann. Rev. Biochem. 50, 159-192. Krieg, D.R. (1963) Prog. Nucl. Acid Res. 2, 125-169. Lawley, P.D., Shah, S.A. and Orr, D.J. (1974) Chem.-Biol. Interactions 8, 171-182. Adams, R.L.P., Mckay, E.L., Douglas, J.T. and Burdon, R.H. (1977) Nucl. Acid Res. 4, 3097-3108. Khodarev, N.N., Votrin, I.I., Sokolov, N.N. and Basnak'an, A.G. (1979) Biokhimiia 44, 1058-1067. Razin, A. and Riggs, A.D. (1980) Science 210, 604-610. Christman, J.K., Price, P., Perdrinan, L. and Acs, G. (1977) Eur. J. Biochem. 81, 53-61. Bird, A.P. and Southern, E.M. (1978) J. Mol. Biol. 118, 27-47. Mandel, J.L. and Chambon, P. (1979) Nucl. Acid Res. 7, 2081-2103. Weintraub, H and Groudine, M. (1976) Science 193, 848-856. Mathis, D., Oudet, P. and Chambon, P. (1980) Prog. Nucl. Acid Res. Mol. Biol. 24, l-55. Weisbrod, S. (1982) Nature 297, 289-295. 491
BIOCHEMICAL
AND BIOPHYSICAL
NUCLEASE-SENSITIVITY
OF METHYLATED DNA AS A PROBE
FOR CHROMATIN RECONSTITUTION Akira Department 39th Received
June
Nishio*
of Pharmacology, St. and Rainbow 11,
RESEARCH COMMUNICATIONS Pages 485-491
and
BY GENOTOXICANTS+
Edwin
M. Uyeki*
The University of Kansas Blvd., Kansas City, Kansas
Medical 66103,
Center, USA.
1982
DNA iln Chinese hamster ovary cells was labeled with [W]thymidine and [methylsH]-1-methionine in culture, and their nuclei were digested with nuclease. Not until 10 percent of bulk DNA was digested did micrococcal acid-soluble fraction. methylated DNA appear in the When these cells were exposed to UV-radiation, alkylating agents and intercalating agents in culture, the resistance of methylated DNA to digestion by the nuclease was largely or completely eliminated. The change in the sensitivity of methylated DNA to the induced by the nuclease indicates a conformational change in chromatin genotoxicants.
INTRODUCTION The bulk 200-base
pair
base pairs
of il
units,
DNA
(1,2).
replication.
inf'..uence repair however,
is
nucleosome. around
The
"phasing"
(
nucleosome
in genes
the
eukaryotes
There is
is
generally
the
be
consensus
that (3).
of
linker of
of
such
core
into
the
because
the
can also
are
been
subject
and
of nucleosomes significantly
by physical/chemical have
DNA
location
gene expression
structure
146
60 base
to the
specific
distribution
studies studies
of about relative
a means of regulating
Nucleosome
of about
each of histones
consisting
nucleosome
a non-random
approximately
consists
two molecules
region
of DNA damage induced
Nuclease-digestion results
A nucleosome
much interest
gene may
obtained
the distribution processes.
arrangement
) has received
in a
known to be packed
an octamer
H3 and H4, and a nucleosome
of
seqt..ence
DNA in
of DNA winding
H2a, H2b, pairs
of
agents
invaluable to
and
probes;
contradictory
reorganization of nucleosome structure interpretations because of the possible -~ * : supported by NIEHS Grant No. ES-02046, and to whom all correspondence should be addressed. **: present address: 2nd Department of Medicine, Kyoto Prefectural University of Medicine, Kajii-cho, Kawaramachi Hirokoji, Kamikyoku, Kyoto 602, Japan.
0006-291X/82/140485-07$01.00/0 485
Copyright 0 1982 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 107, No. 2, 1982
BIOCHEMICAL
by damage
processes
the
and repair
detection
sequences
are
for
2 to
nucleosome
structure
9),
portions
(10,
differential in nucleosome
7
has (7);
times
up
to 75
11).
(MeCyt)
percent
MeCyt
several and
changes
5-methylcytosine
of
(8,
Further
RESEARCH COMMUNICATIONS
development
in
of
chromatin
with
the only
minor
the methods respect
for
to
DNA
required.
distribution
of DNA is
(4,5).
conformational
of
In mammals, accounts
AND BIOPHYSICAL
In
been the
higher
this
total
cytosine
reported
abundance than
percent
nuclease-sensitivity reconstitution
of
is
of study, of
induced
with
respect
of MeCyt
in highly
in moderately total
residues
MeCyt
to
DNA sequences
repetitive
is
in
the and bulk
possibility DNA to
and
sequences
or unique
located
in DNA and Non-random
(6).
repetitive
we investigated methylated
base
sequences
nucleosome
core
of using detect
a
changes
by genotoxicants.
MATERIALS AND METHODS Chemicals: Doxorubicin was supplied by The Drug Synthesis and Chemical Branch, National Cancer Institute (Bethesda, MD). Dichlorvos was supplied by Analytical Chemistry, U.S. Environmental Protection Agency (Research Triangle Louis, Park, NC). Ethyl methanesulfonate (EMS) was obtained from Sigma ( St. [methylsH]-1-methionine (specific activity: 12 Ci/mmole) was obtained MO). from New England Nuclear (Boston, MS). [2-l%] thymidine (54 mCi/mmole) and [methylsH]thymidine (48 Ci/mmole) were from Schwarz/Mann (Orangeburg, NY). Micrococcal nuclease was obtained from Worthington ( Freehold, NJ). Cell culture: Chinese hamster ovary (CHO) cells were grown as a monolayer in RPM1 1640 medium supplemented with 10 percent fetal calf serum, an additional 10 rig/ml insulin and penicillin/streptomycin at 37'C in a water2 gm/L glucose, Radio-labeling of DNA was done overnight by adding jacketed CO2 incubator. [methyl-sH]methionine, ['4C]thymidine or [aH]thymidine at concentrations of 5, 0.05 and 1 uCi/ml, respectively. For the treatment with genotoxicants the medium containing radioactivity was discarded, and cells were washed once with phosphate buffered saline (PBS), chased with fresh medium for 2 hr, and then exposed to chemicals for 3 hr or W-light (predominantly 254 nm) in PBS. of CHO cell nuclei followed Digestion by nuclease: Preparation the method Nuclei were suspended in a buffer consisting reported by Muramatsu et al (12). of 0.25 M sucrose, 0.1 mM CaC12, 1 mM Tris-HCl (pH 7.8) at a concentration of 108 nuclei/ml. Micrococcal nuclease was added at a concentration of 50 U/10* nuclei. Digestion was continued in a 37X water bath and terminated by adding of 10 percent perchloric acid (PCA) or 10 mM EDTA and chilling an equal volume in ice. Digestion of bulk DNA was determined by measuring the radioactivity of [ 14C]thymidine in the cold PCA-soluble and -insoluble fractions of nuclease-treated nuclei, after solubilization of DNA with 5 percent PCA by heating at 90 'C for 20 min.
rig/ml),
Extraction pronase
of DNA: The EDTA-added nuclei (0.5 mg/ml) and sodium dodecyl 486
were treated with (1 percent) sulfate
RNase A (0.5 in a buffer
Vol. 107, No. 2, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
containing 0.2 M NaCl, 5 mM EDTA and 10 mM Tris-HCl (pH 7.8) at 37'C for 1, 4 and 2 hr, respectively. DNA was extracted twice with phenol: chloroform: isoamyl alcohol (24: 24: 1) and precipitated overnight with 3 volumes of ethanol with 5 pg calf thymus DNA as carrier at -20 'C. For measurement of radioactivity, DNA was solubilized in 5 percent PCA by heating at 90°C for 20 min and ad.ded to a xylene-based scintillation counting fluid. Radioactivity of [methyl-sH] methionine in the ethanol-precipitated DNA was rendered completely acid-soluble by DNase I, but not by RNase A or pronase. The possibility that radioactivity resides in the methyl group of thymine and purine rings can not be excluded (1.1, 13, 14), since the radioactivity among the DNA bases was not determined. RESULTS kinetics
of
methylated
shown in
Fig
1 A.
Digestion nuclease acid
are
soluble
using
did
the
mouse L cells
Met-)NA
is
digested
Met-DNA
initiated,
a
accord is
reports
compared
with
digested
in
parallel
with
of
total
of bulk
and this
bulk
DNA by micrococcal DNA was rendered
We obtained
of others
manner
( 40 percent
remained
occur.
observations), the
and bulk
10 percent
of Met-DNA
with
plateau
of Met-DNA
Not until
(unpublished
proceeded
DNA reached percent
in
digestion
DNA (Met-DNA)
nuclease-
(10,111.
DNA. bulk
similar
In
Digestion
DNA.
resistance Fig.
undigested
of
1 B, the
of Met-DNA,
When digestion
DNA remained
results,
once
of bulk 1, 50 - 60
undigested.
fl40 0
3 : 30 I
o$
a 2o iFI 1 10
,OOk
15
/ I" 9'
;c 0L 0
TIMECMIN)
A
/
d""
10 20 -1. DIGESTED
30 40 BULK DNA
50
of methylated DNA and bulk DNA in nuclei by micrococcal --Fig. 1. Digestion nuclease. A: kinetics of digestion. CHO cells were labeled overnight with [methyl-aH]-1-mzthionine and ['4C]thymidine, 5 and 0.05 pCi/ml, respectively. Isolated nuclei were digested with micrococcal nuclease ( 50 U enzyme/108 nuclei 1 at 37 'C for the indicated periods. Undigested DNA was purified, and the radioactivity was determined by scintillation counting. o: methylated DNA ([sH]). .: bulk DNA ([WI). B: Digestion of methylated DNA as a function of bulk DNA. Digestion of methylated DNA was plotted against bulk DNA. 0, a, 0 represent
three
different
experiments.
487
BIOCHEMICAL
Vol. 107, No. 2, 1982 The resistance were
with
treated
hr.
of
2
Fig.
A shows
digestion
of
the
digestion
as
is
a
investigated;
a
known
and
protein similar
J/m')
curve of
on did
in the
the
the nuclease not
abolish
abolition
chemicals
0
5 10 TIMECMIN)
DNA
on
in
cells
bulk
protein
(16).
preferentially
treated
% DIGESTED
BULK
with
EMS is
methylates
and
genotoxicants although
completely,
a
(Fig.
3).
DNA was
also
the
drugs
15 DNA
Fig. 2. A: Digestion kinetics of methylated and bulk DNA in nuclei treated with dichlorvos. The radiolabeled cells were treated for 3 hr with 10 mM dichlorvos in culture, and isolated nuclei +re subjected to digestion by micrococcal nuclease under similar conditions to Fig. 1. o: methylated DNA. .: bulk DNA. B. Effects of dichlorvos, EMS and doxorubicin on the nuclease sensitivity of methylated DNA. This figure is represented in a similar way to Fig. 1 B. 0: control. ., A, . : cells were treated with 10 mM dichlorvos ( . ), 20 mM EMS ( A ) and 20 uM doxorubicin ( u ) for 3 hr in culture.
488
a an
was observed bulk
and
Dichlorvos,
of Met-DNA
were
the
Met-DNA.
(15).
chemical
of
with
and
of chromatin;
kinetics
B shows
disappeared,
agent
resistance
3
DNA in
2
treated
both
The three
bulk
Fig.
to digestion
the resistance
digestion
EMS.
in nuclei
sensitivity
of this
cells
by the nuclease.
anticancer
pesticide,
[sH]thymidine-labeled
50’
and
and
digested
fashion
DNA (17).
Met-DNA
and
of Met-DNA
DNA
than
rather
of
equally
intercalating
when
(10 mM) and EMS (20 mM) for
of bulk
parallel
alkylates
effect
(100
dose response Effect
in
were
was abolished
doxorubicin
organophosphate
phosphorylates
W-radiation
with
resistance
well
anti-cholinesterase
a
DNAs
RESEARCH COMMUNICATIONS
digestion
kinetics
a function
initial
mutagen
showed
both
proceeded
Doxorubicin strong
digestion
obtained
Met-DNA
genotoxicants; the
the
were
nuclease
(20 JIM), dichlorvos
nuclei;
results
to
doxorubicin
dichlorvos-treated Similar
Met-DNA
AND BIOPHYSICAL
in
BIOCHEMICAL
Vol. 107, No. 2, 1982
60’.
03
' ' 3 5 TIME(MIN)
0 1
Fig. DNA. -&n an additional bulk DNA. (0 ).
3.
AND BIOPHYSICAL
04 50. 0
4 10
' 7
RESEARCH COMMUNICATIONS
of W-radiation Effects were exposed to W-radiation 3 hr. The condition 0, A, q : methylated DNA,
5 TIME
10 (MINI
15
on
the digestion kinetics of methylated at 8, 20 and 100 J/msand cultured for .: for digestion was similar to Fig. 1. irradiated 8 ( a ), 20 ( o ) and 100 J/m2
Fig’ 4 Digestion kinetics of bulk DNA in nuclei treated with Llchlorvos. -c ('HO cellls were labeled with overnight L3Hl- or [ ‘4C] thymidine conditlonH ['HI-labeled cells were treated with dichlorvoa under similar to Fig. 1. Isolated [sH]- and ['4C]-labeled nuclei were mixed and subjected to digestion by micrococcal nuclease. o: dichlorvos-treated DNA. .: control DNA.
culture,
and
controls.
digestion
Fig. 4 shows
betws?en with
the
was compared that
there
dichlorvos-treated
doxorubicin
and
and EMS ( data
are
that
of
no differences
control not
with
cells.
shown
['4C]thymidine-labeled in nuclease-sensitivity
Similar
results
were
obtained
1.
DISCUSSION An explanation earl,?
of
course
distributed reports
in on
the
preferentially whether
for
(Fig. cores
distribution
of
distributed
or not nuclease-sensitivity
nucleosome
core
requires
Many studies re
digestion
nucleosome
(19)
lationship
between
further
are
nuclease-resistance
the micrococcal
currently
methylated
1)
is
11).
(IO, MeCyt in the
that
Met-DNA
There
are,
in chromatin: linker
of Met-DNA
of Met-DNA
portion will
is
preferentially
however, it
is
in the
conflicting
randomly
(18)
of nucleosome.
be a useful
"marker"
or
Hence, for
the
investigation. under DNA and gene 489
investigation activity
dealing (20).
There
with
the
i s agreement
Vol. 107, No. 2, 1982
BIOCHEMICAL
that
of a
hypomethylation
active
transcription different
hypersensitive
to pancreatic
possibility,
higher
rendering
their
order
(doxorubicin), abolished
change
previously
was
show
a more observed
not
in the
abrupt
and steeper
higher
order
is
the
and
Genotoxicant
effects
conformational
presence
on these
changes
genotoxicants
nuclease-hypersensitivity
and,
these
occurred as of
either
DNA >,
The
effects
completely
is
that
nuclease
that
2 B),
is
that
a DNA
are now
in the
early
Met-DNA
curves
steeper
slope
this
and that
of an all-or-none
We
there
action,
of Met-DNA
or
3).
such a manner
fact
(Fig.
agent
2 and
DV-radiation
response,
is a toxicant-induced
Fig.
is
mobility is
3 )
between
presently proteins
our
study,
the hypomethylated,
in progress. 490
in the
loss
normally
of nuclease-
dependent
on histone
(HMG) of proteins
these in
change
chromatin,
somewhat
group not
topological
"active" resulting
proteins
observed
as
possibility.
there
high
in bulk
(Fig.
to
of transcriptionally
of
genes.
as well
toxicant-treated
Nuclease-hypersensitivity
acetylation
(25).
an intercalating
Met-DNA
further, slope.
first
is
"active"
occurring
resistance
and nuclease-hypersensitive,
hypersensitivity.
those
opaque
( instead
that
structure
and,
chromatin
configurations
and DNA in
Met-DNA
of this
possibility
hypomethylated
of
be lost
curve
the feasibility
one for
hence,
should
response
lessens
of
then
is
nuclease
with
(EMS and dichlorvos),
the case,
drug-treated
a dose
A second
were
chromatin
hydrolysis.
the nucleosome
in
showed
with
with
nuclease-hypersensitive,
UV-radiation,
the first
and,
to micrococcal
nucleosome
to acid
agents
between
this
of digestion
would
different
correlated
"active"
may correlate
( compared
"covered"
If
susceptible. course
studies
genotoxicants,
two possibilities;
(24);
micrococcal
nuclease-resistance
the
conformational sites,
with
alkylating
and
considered
our
in
the
is
"active"
and possibly
that
structures
the
with
sequences
chromatin
DNA more susceptible
Treatment
almost
bulk
exists
Such genes may be associated different
neighboring
DNase I,
DNA observed
RESEARCH COMMUNICATIONS
Transcriptionally
from
thus,
hypomethylated
gene and
(21-23).
topologically
The
AND BIOPHYSICAL
known.
(25,
26).
We believe
that
and DNA with resulted
"active"
DNA.
in
the
addition
abolition
Further
work
of is
BIOCHEMICAL
Vol. 107, No. 2, 1982 Using digestion
radio-labeled kinetics
genocoxicants.
Met-DNA of
association
with
rearrangement
digestion
showed
no
differences;
conformational
changes
be
detected
chromatin general
by DNA.
utility
by
of bulk we
nuclease
increase
We believe
that
study
the change the
by Met-DNA in the
It
of genotoxic
is
to
mean are
in
dependent a
on its
structural
noteworthy cells that
not
nuclease-digestible DNA and Met-DNA
the
large
that
assays
a
(Fig.
4)
putative
enough
fraction
the
several
by
indicates
and control
labeling
the use of bulk
a change
DNA is
probably
toxicants.
this
that
was induced
of nuclear
interpreted
suggested
RESEARCH COMMUNICATIONS showed
DNA in drug-treated
a gross
in the
we
micrococcal
proteins,
chromatin
comparative
probe,
nuclease-sensitivity
chromatin of
as a
DNA by
Because
AND BIOPHYSICAL
as to
of whole will
have
agents.
REFERENCES 1. 2. 3. 4. 5. 6. 7. a. 9. 10. 11. 12. 13. 14. 15. 16. 17. ia. 19. 20. 21. 22. 23. 24. 25. 26.
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