- Email: [email protected]
Extraction and partial purification of two histone-specific transacetylases from rat liver nuclei
Vol. 40, No. 1, 1970
BIOCHEMICAL
AND BIOPHYSICAL
EXTRACTION AND PARTIAL HISTONE-SPECIFIC
RESEARCH COMMUNICATIONS
PURIFICATION
OF TWO
TRANSACETYLASES FROM RAT LIVER NUCLEI. Dieter
Gallwitz
Physiological Chemical Institute University of Marburg (Lahn), Germany
Received
June 5, 1970
SUMMARY Two histone-specific transacetylases with an approximate molecular weight between 80,000 and 90,000 were solubilized from rat liver nuclei by sonication in the presence of 1 M ammonium sulfate and 20% glycerol followed by precipitation with 3.5 M ammonium sulfate. A SO-fold purification was achieved by DEAEcellulose and Sephadex G-200 chromatography. The acetate transfered by the enzymes from acetyl coenzyme A to histones is N-linked. The pH-optimum of the enzymatic acetylation is approximately 8.6. The occurence histones
has been
E-N-acetyllysine incubation acetate that
of
isolated
(3).
From the
in the
arginine-rich
acetylated
in
a specific
lysine
and takes Methylation other
of histone the
known
histone
for
place
recent
nuclei
on already
of
occuring
IV and may have
presence it from is
This
--in vitro of labelled
is evident calf
thymus
partially
modification
of
be an intranuclear
to
completed
and phosphorylation
2al)
residue
(Q,5,6). seems
after
studies
IV (f
lysine
the S-N-position residue
in the
sequencing
in
In addition,
in histones
histone
a specific
residues
(1,2).
identified
thymus
modifications
acetylserine
some time
has been
and pea seedlings
are
of NH2-terminal
protein
molecules
specific
in the
amino
highly
some influence
process
acid
basic
on the
(7,8). residues portion
binding
of
to DNA.
To establish
a basis
for
an understanding
236
of the
biological
Vol. 40, No. 1, 1970
meanins
of
involved
BIOCHEMICAL AND BIOPHYSICAL
these
modification
should
prove
acetone
fractionation
proteins
catalyzing;
to histones
more
helpful, of the
of
some properties
It
the
study
has already
of
been
the
enzymes
shown that
pieeon
(9)
and rat
liver
(10)
transfer
of
acetate
from
acetyl
or less
The extraction
reactions
RESEARCH COMMUNICATIONS
yields coenzyme
A
unspecifically,
two histone-specific
of the
partially
transacetylases
purified
enzymes
are
and reported
here. EXPERIMENTAL Liver rats
nuclei
initially
(10,111,
the
X 100
(Tris-ECl,
(12).
5 mll,
viscous
125 !Jatt)
3.5
with
suspended
EDTA, 0.25 glycerol,
90 min in
v/v) the
and
x gav for
medium
B or passed
in
solution
equilibrated
at
with
the
in
ZDTA,
over
0.25
2'
in
the
x S,,.
for
2 hrs. a final
cold
medium
concentration
the
extract
onto
B, Proteins
To remove
pellets
237
MgC12,
the
1 mM,
ammonium
centrifugation for
extracted
DEAR-cellulose were
was
5 m?l, 20%
G-25 equilibrated the
the
Crystalline
The protein
dialyzed
20% of
v/v),
15 mV, pH 7.6,
60 min.
Sephadex
adsorbed
mY, 2-mercapto-
20 kHz,
1 hr
after
A
sonifier,
B (Tris-HCl,
about
medium
(Branson
yield
obtained
detergent
in
to
for
al
was sonicated
added
10 min was either
and were
by use of
"i istar
bath
at
120,000
stirred
procedure
et -2
10 mM, 2-mercaptoethanol,
supernatant
40,000
this
stirred
medium
mM, NH4C1,
an ice
bursts
for
Chauveau
homogenized
1 mll,
g bR II
1 ?!, 20% qlycerol,
in
25 2 set
120-18(!
of
study
cjere
sulfate,
stirring
for
the
NgC12,
was slowly
I?. After
sulfate
of
immersed
sulfate
centrifuged
After
state
ammonium
ma le
procedure
and subsequently
ammonium
from
The nuclei
homoqenate
40 ml aliquots
were
later
75 mM, p:i 7.6,
ethanol,
of
prepared
by a modified
in
Triton
were
eluted
at 40 hrs with
against medium
proteins
remained
previously from
B.
the
column
Vol. 40, No. 1, 1970
with
a linear
enzymatic 3.5
0.01-0.3
activity
medium
sulfate
activity
C-acetate
acetyl
0.35
NH,+Cl,
25 @moles
of
glycerol
(v/v),
0.025
56.6
mC/mM),
total
volume
were
discs
KCl,
of
0.5
37')
1 mg of
the
incubation ice
Sephadex
were
with
G-200
equilibrated
Protein
hot
0.1 ymole of
contained EDTA,
act.
protein
in
incubation
time
was added
as carrier
and
as described
precipitated
ml
filter
The filters
(10).
purified with
was estimated
a
0.2
onto
acid.
rat
0.14
or thymus Extraction
precipitation
according 56.6
act.
liver
M NaCl.
N HCl and subsequent
Nuclear
A (spec.
the
were
of
15%
25 ,ug enzyme
25% trichloroacetic
A (spec.
15 @moles
3.5 ,umoles
coenzyme
end of
from
acid
2-mercaptoethanol,
and 2 to the
of
trichloroacetic
of
l4 C-1-acetyl
washing
coenzyme
New England
incorporation
medium
mixture
prepared
by 0.25
14 C-1-acetyl
A into
albumin
and counted
was achieved
from
At
cold
extensive
acetone.
,uC of
ml.
after
of
having
precipitated
as the
2 flumoles
50 pug substrate
treated
nuclei
proteins
over
coenzyme
flumole of MgC12,
in
Histones
The fractions
The incubation
Tris-HCl,
paper
and passed
material.
of
the
was determined
from
precipitable
aliquots
pooled,
RESEARCH COMMUNICATIONS
B.
Enzyme
(20 min at
AND BIOPHYSICAL
M NH&Cl gradient.
were
M ammonium
with
14
BIOCHEMICAL
to
Lowry
et -2
in
10 vol
al
(13).
mC/mM) was purchased
Corporation.
RESULTS AND DISCUSSION The DEAE-cellulose preparation one major about
0.09
from peak
of activity
G-200
liver
of activity
M NH4C1.
The enzyme Sephadex
rat
elution
could
nuclei
is
with
be further in
may point
Fig. to
of
the
shown
an intimate
The purification
as seen
which
profile
in purified 2. There
the 238
in
soluble Fig.
enzyme 1. There
shoulder
this
step
eluting
existence
two distinct of
at
was 6- to
by chromatography are
is
at
least
8-fold. on
peaks two
of
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 40, No. 1, 1970
Fig. 1. DEAE-cellulose chromatography of soluble nuclear histone transacetylase. 150 mg protein were adsorbed to a 2 x 9 cm DEAE column and eluted with a linear 350 ml 0.01 - 0.3 M NH4C1 gradient at a flow rate of 40 ml/hr.
Fip. 2. Sephadex G-ZOO chromatography of nuclear histone transacetylase. 25 me protein previously chromatographed on DEAEcellulose (fractions pooled as indicated by arrows in Fig. 1) were chromatocraphed on a 1.8 x 90 cm Sephadex G-200 column at flow rate of 5 ml/hr. different the
histone
molecular
acetylating
weight
of the
enzymes. two
enzymes 239
According is
to
gel
approximately
filtration 80,000
a
Vol. 40, No. 1, 1970
to
90,000.
BIOCHEMICAL
The final
adsorbed
to
coenzyme
not
for
Other
basic (Table
1).
of
the
acetate
from
Under two
the
to
conditions
has yet
of nuclear histone transacetylase. on Senhadex G-200 were incubated protein as described in Methods, wmoles
(rat (rat (bovine)
Cytochrome Lysozyme
C (horse
been
at
acetate
5 ~g of ?,I1 8.6
incorporated
acceptor
liver) thymus)
Hemoglobin
the
proteins
test
enzymes
acetyl
fraction.
protein
histone histone
extract
as nonbasic
50 fig Total Total
the
and predominantly
as well
histone
Table 1. Specificity the enzyme purified with 50 pg acceptor
Acceptor
G-ZOO transfer
specificity
one specific
with
50-fold.
to histones
acetylated
no absolute
found
Sephadex
ones.
were
used
from
compared
was about
A specifically
aroinine-rich tested
purification
DEAE-cellulose
The enzymes
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
protein
22 25
heart)
RNase Albumin
(bovine)
In from
earlier
studies
neutral
by acetyl
to
alkaline
coenzyme
these
acetylating In
test
concentrations
enzymes (14,151 acetylases.
histones
by KC1 at
acid,
of
a final
by raising
acetylated
the
10m3 to
obviously
a chemical
concentration
was optimal
to
10e8
activate
of
for
any effect
240
M adenosine histone on the
pH
spontaneously
the
reaction 50 mM. histone
3).
known
was without
is
pH 8.6
(Fig.
that
were
This
conditions
enzymes
monophosphoric
was observed
A (8,101.
and can be prevented Under
it
3',5'-cyclic phosphorylating
histone
trans-
BIOCHEMICAL
Vol. 40, No. 1, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
9.0 PH
Pip,. 3. @I-dependence of nuclear buffer (O--C ) and glycine-XaOII The stability in
hot
incorporated
acid
acetate
shows that
The identification
of
the
the
amino
to
the
acetyl
treatment
groups
acid(s)
are
acetylated
is
progress. This
ally
work
has clearly
acetylate
histone is
the
trichloroacetic
?i-linked. in
of
histone transacetylase. Tris-IiCl buffer (A) were used.
histones
synthesis
probably
likely
not
the
internally nuclear
in
are
takes
initiated
established
N-terminal the
located
place with
histone
that
in
in the
enzymes
the
cell
cytoplasm
N-acetyl-seryl-tRNA amino
acid
molecule
but which
which
nucleus.
Since
(16,17,18)
and
(19) an amino is
specific.
it acid
acetylated
is
very
positioned by the
enzymes.
ACKNOWLEDGEMENTS I wish work
to
and Dr.
thank C.E.
Prof.Dr. Sekeris
P. Karlson for
stimulating 241
for
his
interest
discussions.
in Thanks
this are
Vol. 40, No. 1, 1970
due to
Mrs.
Ch.
BIOCHEMICAL
Pfeiffer
for
AND BIOPHYSICAL
helping
to
RESEARCH COMMUNICATIONS
prepare
the
manuscript.
REFERENCES 1. Phillips, D.M.P., Biochem. J. 87, 258 (1963). 2. Phillips, D.M.P., Biochem. J. 107, 135 (1968). 3. Gershey, E.L., Vidali, G. and Allfrey, V.G., J. Biol. Chem. 5018 (1968). 243, 4. DeLange, R.J., Fambrough, D.M., Smith, E.L. and Bonner, J., J.Biol. Chem. 244, 319 (1969). 5. Ogawa, Y., QuaFarotti, G., Jordan, J., Taylor, C.W., Starbuck, C.W. and Busch,,H., J. Biol. Chem. 244, 4387 (1969) 6. DeLange, R.J., Fambrough, D.M., Smith, E.L. and Bonner, J., J. Biol. Chem. E, 5669 (1969). I. Allfrey, V.G., Faulkner, R. and Mirsky, A.E., Proc. Nat. Acad. Sci. U.S. 5l, 786 (1964). 8. Gallwitz, D. and Sekeris, C.E., 2. Physiol. Chem. 2, 150 (1969). 9. Nohara, H., Takahashi, T. and Ogata, K., Biochim. Biophys. Acta 154, 529 (1968). 10. Gallwx, D., Biochem. Biophys. Res. Commun. 32, 117 (1968). 11. Chauveau, J., Moule, Y. and Rouiller, C., Exptl. Cell Res. 11, 317 (1956). 12. Beato, M., Homoki, J. and Sekeris, C.E., Exptl. Cell Res. 55, 107 (1969). 13. Lowry, O.H., Rosebrough, J.N., Farr, A.L., and Randall, R.J., J. Biol. Chem. 193, 265 (1951). 14. Langan, T.A., Science 162, 579 (1968). B. and Dixon, G.H., J. Biol. Chem. E, 425 (1970). 15. Jergil, C. and Borun, T.W., Proc. Nat. Acad. Sci. U.S. 16. Robbins, 57, 409 (1967). 17. Gallwitz, D. and Mueller, G.C., Science 163, 1351 (1969). 18. Gallwitz, D. and Mueller, G.C., J. Biol. Chem. 244, 5947 (1969). 19. Liew, C.C., Haselett, G.W. and Allfrey, V.G., Nature 225, 414 (1970).
242
BIOCHEMICAL
AND BIOPHYSICAL
EXTRACTION AND PARTIAL HISTONE-SPECIFIC
RESEARCH COMMUNICATIONS
PURIFICATION
OF TWO
TRANSACETYLASES FROM RAT LIVER NUCLEI. Dieter
Gallwitz
Physiological Chemical Institute University of Marburg (Lahn), Germany
Received
June 5, 1970
SUMMARY Two histone-specific transacetylases with an approximate molecular weight between 80,000 and 90,000 were solubilized from rat liver nuclei by sonication in the presence of 1 M ammonium sulfate and 20% glycerol followed by precipitation with 3.5 M ammonium sulfate. A SO-fold purification was achieved by DEAEcellulose and Sephadex G-200 chromatography. The acetate transfered by the enzymes from acetyl coenzyme A to histones is N-linked. The pH-optimum of the enzymatic acetylation is approximately 8.6. The occurence histones
has been
E-N-acetyllysine incubation acetate that
of
isolated
(3).
From the
in the
arginine-rich
acetylated
in
a specific
lysine
and takes Methylation other
of histone the
known
histone
for
place
recent
nuclei
on already
of
occuring
IV and may have
presence it from is
This
--in vitro of labelled
is evident calf
thymus
partially
modification
of
be an intranuclear
to
completed
and phosphorylation
2al)
residue
(Q,5,6). seems
after
studies
IV (f
lysine
the S-N-position residue
in the
sequencing
in
In addition,
in histones
histone
a specific
residues
(1,2).
identified
thymus
modifications
acetylserine
some time
has been
and pea seedlings
are
of NH2-terminal
protein
molecules
specific
in the
amino
highly
some influence
process
acid
basic
on the
(7,8). residues portion
binding
of
to DNA.
To establish
a basis
for
an understanding
236
of the
biological
Vol. 40, No. 1, 1970
meanins
of
involved
BIOCHEMICAL AND BIOPHYSICAL
these
modification
should
prove
acetone
fractionation
proteins
catalyzing;
to histones
more
helpful, of the
of
some properties
It
the
study
has already
of
been
the
enzymes
shown that
pieeon
(9)
and rat
liver
(10)
transfer
of
acetate
from
acetyl
or less
The extraction
reactions
RESEARCH COMMUNICATIONS
yields coenzyme
A
unspecifically,
two histone-specific
of the
partially
transacetylases
purified
enzymes
are
and reported
here. EXPERIMENTAL Liver rats
nuclei
initially
(10,111,
the
X 100
(Tris-ECl,
(12).
5 mll,
viscous
125 !Jatt)
3.5
with
suspended
EDTA, 0.25 glycerol,
90 min in
v/v) the
and
x gav for
medium
B or passed
in
solution
equilibrated
at
with
the
in
ZDTA,
over
0.25
2'
in
the
x S,,.
for
2 hrs. a final
cold
medium
concentration
the
extract
onto
B, Proteins
To remove
pellets
237
MgC12,
the
1 mM,
ammonium
centrifugation for
extracted
DEAR-cellulose were
was
5 m?l, 20%
G-25 equilibrated the
the
Crystalline
The protein
dialyzed
20% of
v/v),
15 mV, pH 7.6,
60 min.
Sephadex
adsorbed
mY, 2-mercapto-
20 kHz,
1 hr
after
A
sonifier,
B (Tris-HCl,
about
medium
(Branson
yield
obtained
detergent
in
to
for
al
was sonicated
added
10 min was either
and were
by use of
"i istar
bath
at
120,000
stirred
procedure
et -2
10 mM, 2-mercaptoethanol,
supernatant
40,000
this
stirred
medium
mM, NH4C1,
an ice
bursts
for
Chauveau
homogenized
1 mll,
g bR II
1 ?!, 20% qlycerol,
in
25 2 set
120-18(!
of
study
cjere
sulfate,
stirring
for
the
NgC12,
was slowly
I?. After
sulfate
of
immersed
sulfate
centrifuged
After
state
ammonium
ma le
procedure
and subsequently
ammonium
from
The nuclei
homoqenate
40 ml aliquots
were
later
75 mM, p:i 7.6,
ethanol,
of
prepared
by a modified
in
Triton
were
eluted
at 40 hrs with
against medium
proteins
remained
previously from
B.
the
column
Vol. 40, No. 1, 1970
with
a linear
enzymatic 3.5
0.01-0.3
activity
medium
sulfate
activity
C-acetate
acetyl
0.35
NH,+Cl,
25 @moles
of
glycerol
(v/v),
0.025
56.6
mC/mM),
total
volume
were
discs
KCl,
of
0.5
37')
1 mg of
the
incubation ice
Sephadex
were
with
G-200
equilibrated
Protein
hot
0.1 ymole of
contained EDTA,
act.
protein
in
incubation
time
was added
as carrier
and
as described
precipitated
ml
filter
The filters
(10).
purified with
was estimated
a
0.2
onto
acid.
rat
0.14
or thymus Extraction
precipitation
according 56.6
act.
liver
M NaCl.
N HCl and subsequent
Nuclear
A (spec.
the
were
of
15%
25 ,ug enzyme
25% trichloroacetic
A (spec.
15 @moles
3.5 ,umoles
coenzyme
end of
from
acid
2-mercaptoethanol,
and 2 to the
of
trichloroacetic
of
l4 C-1-acetyl
washing
coenzyme
New England
incorporation
medium
mixture
prepared
by 0.25
14 C-1-acetyl
A into
albumin
and counted
was achieved
from
At
cold
extensive
acetone.
,uC of
ml.
after
of
having
precipitated
as the
2 flumoles
50 pug substrate
treated
nuclei
proteins
over
coenzyme
flumole of MgC12,
in
Histones
The fractions
The incubation
Tris-HCl,
paper
and passed
material.
of
the
was determined
from
precipitable
aliquots
pooled,
RESEARCH COMMUNICATIONS
B.
Enzyme
(20 min at
AND BIOPHYSICAL
M NH&Cl gradient.
were
M ammonium
with
14
BIOCHEMICAL
to
Lowry
et -2
in
10 vol
al
(13).
mC/mM) was purchased
Corporation.
RESULTS AND DISCUSSION The DEAE-cellulose preparation one major about
0.09
from peak
of activity
G-200
liver
of activity
M NH4C1.
The enzyme Sephadex
rat
elution
could
nuclei
is
with
be further in
may point
Fig. to
of
the
shown
an intimate
The purification
as seen
which
profile
in purified 2. There
the 238
in
soluble Fig.
enzyme 1. There
shoulder
this
step
eluting
existence
two distinct of
at
was 6- to
by chromatography are
is
at
least
8-fold. on
peaks two
of
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 40, No. 1, 1970
Fig. 1. DEAE-cellulose chromatography of soluble nuclear histone transacetylase. 150 mg protein were adsorbed to a 2 x 9 cm DEAE column and eluted with a linear 350 ml 0.01 - 0.3 M NH4C1 gradient at a flow rate of 40 ml/hr.
Fip. 2. Sephadex G-ZOO chromatography of nuclear histone transacetylase. 25 me protein previously chromatographed on DEAEcellulose (fractions pooled as indicated by arrows in Fig. 1) were chromatocraphed on a 1.8 x 90 cm Sephadex G-200 column at flow rate of 5 ml/hr. different the
histone
molecular
acetylating
weight
of the
enzymes. two
enzymes 239
According is
to
gel
approximately
filtration 80,000
a
Vol. 40, No. 1, 1970
to
90,000.
BIOCHEMICAL
The final
adsorbed
to
coenzyme
not
for
Other
basic (Table
1).
of
the
acetate
from
Under two
the
to
conditions
has yet
of nuclear histone transacetylase. on Senhadex G-200 were incubated protein as described in Methods, wmoles
(rat (rat (bovine)
Cytochrome Lysozyme
C (horse
been
at
acetate
5 ~g of ?,I1 8.6
incorporated
acceptor
liver) thymus)
Hemoglobin
the
proteins
test
enzymes
acetyl
fraction.
protein
histone histone
extract
as nonbasic
50 fig Total Total
the
and predominantly
as well
histone
Table 1. Specificity the enzyme purified with 50 pg acceptor
Acceptor
G-ZOO transfer
specificity
one specific
with
50-fold.
to histones
acetylated
no absolute
found
Sephadex
ones.
were
used
from
compared
was about
A specifically
aroinine-rich tested
purification
DEAE-cellulose
The enzymes
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
protein
22 25
heart)
RNase Albumin
(bovine)
In from
earlier
studies
neutral
by acetyl
to
alkaline
coenzyme
these
acetylating In
test
concentrations
enzymes (14,151 acetylases.
histones
by KC1 at
acid,
of
a final
by raising
acetylated
the
10m3 to
obviously
a chemical
concentration
was optimal
to
10e8
activate
of
for
any effect
240
M adenosine histone on the
pH
spontaneously
the
reaction 50 mM. histone
3).
known
was without
is
pH 8.6
(Fig.
that
were
This
conditions
enzymes
monophosphoric
was observed
A (8,101.
and can be prevented Under
it
3',5'-cyclic phosphorylating
histone
trans-
BIOCHEMICAL
Vol. 40, No. 1, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
9.0 PH
Pip,. 3. @I-dependence of nuclear buffer (O--C ) and glycine-XaOII The stability in
hot
incorporated
acid
acetate
shows that
The identification
of
the
the
amino
to
the
acetyl
treatment
groups
acid(s)
are
acetylated
is
progress. This
ally
work
has clearly
acetylate
histone is
the
trichloroacetic
?i-linked. in
of
histone transacetylase. Tris-IiCl buffer (A) were used.
histones
synthesis
probably
likely
not
the
internally nuclear
in
are
takes
initiated
established
N-terminal the
located
place with
histone
that
in
in the
enzymes
the
cell
cytoplasm
N-acetyl-seryl-tRNA amino
acid
molecule
but which
which
nucleus.
Since
(16,17,18)
and
(19) an amino is
specific.
it acid
acetylated
is
very
positioned by the
enzymes.
ACKNOWLEDGEMENTS I wish work
to
and Dr.
thank C.E.
Prof.Dr. Sekeris
P. Karlson for
stimulating 241
for
his
interest
discussions.
in Thanks
this are
Vol. 40, No. 1, 1970
due to
Mrs.
Ch.
BIOCHEMICAL
Pfeiffer
for
AND BIOPHYSICAL
helping
to
RESEARCH COMMUNICATIONS
prepare
the
manuscript.
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