- Email: [email protected]
Effect of specific inhibitors on mitochondrial DNA replication in HeLa cells
Vol. 60, No. 3,1974
BIOCHEMICAL
L. Laboratory
of
Received
Cell
July
Pica
Mattoccia
Biology,
22,
AND BIOPHYSICAL
C. N.
and
R.,
Via
S.
RESEARCH COMMUNICATIONS
Roberti
Rornagnosi
18
A,
Rome,
synthesis
on
the
bromide
densit)-
Ital>-
1974 SUMMARY
The
effect
of
tochondrial
different
DNA,
sedimentation xyadenosine
velocity, excess,
of mitochondrial difference clear DNA
of 22%) synthesis,
analogy
what
as
to
inhibitors
isolated
by
of
has been hydroxyurea
studied in HeLa and fluorodeoxyuridine
DNA less than while cytosine has a very
happens
expected,only
in
DNA
CsCl-ethidium
cells.
labeling
Thymidine inhibit
that
of the n.uclear DNA (with arabinoside, which strongly limited action on mitochondrial
the
bacterial
mitochondrial
system.
DNA
of
gradient
Ethidium
miand
and deolabeling
the
a maximum inhibits DNA, bromide
nuin
inhibits:
replication.
INTRODUCTICN
study-
The drial
of
replicative
and
cytoplasmic
and
alcohol
xic
The
(m.
Borst
All rights
only
replication
Irorri
lack
of thymiciine
in
to
HeLa
drugs
of
understand
of
cells,
the
the
in
to
isolated
nuclear
extent
into
acid
to
a limited
that
thymidine been
and of
the
bromide;
HU Thy
=.
@ 1974 by Academic Press, Inc. of reproduction in any form resetvd
by
mirochonacton
“1:
of
by
by
An UN-4
= hydroxyurea; thymidine;
882
DNA
not
Pica
block Mattoccia
synthesis
alternative synthesis CA FIJdR
not
after
by of
also
= cy-tosine :? fl-orodeox)-crilir.e
nalidi-
mitochondrial and the
hypothesis but
that
inhibited
concentrations
does
suggested
circular
found
is
high
of
hydroxyurea;
mitochondria,
excess
rn.
labeling
material
extent
block.
indeedblock
the
inhibition
insoluble
of m.
thymidine
that
chick-liver
synchronization
might
found
resistant
has
a double
Eth. br = ethidium d. Ade = deoxjradenosine:
Copyright
dATF
possibility
the
cells
(2))
and
DNA)
interpret
excess
help
relatively
of
phenethyl acid.
(1)
is
incorporation
HeLa
can
Penman DNA
Tershegget
DNA
to different
biogenesis.
Vesco
the
sensiti-Jity
systems
rritochondrial
to
the
Attardi release
was cause arabinoside;
(3) of
that anarrest
the of
BIOCHEMICAL
Vol. 60, No. 3, 1974
AND BIOPHYSICAL
mitochondria
development
at different
stages
cpon
of the
thymidine,
mitochondria
removal
development
and reach
In the
present
of HeLa sine,
excess
cells
the
paper
grown
stage
we investigated
in the presence
fluorodeoxyuridine,
bromide.
That
of DNA
compared
HeLa
(S,
clonal
(Joklik,
strain)
Grand
Island)
ranging
b) Drug
and labeling
treatment
if Samples
C/ml; B one hour
as DNA xyadenosine
ii)
at the
and
ethidium
labeling.
incubated
thymidine
for
(0, 1 PC/ml; and mixed
and
5. 1 OS/ml.
were
two
serum
at 37°C
in the
The
(Merck),
resus-
[methyl-
3H.]
H-G deoxyadenoP I. of the specific inhibitor
presence
isotope.
and
to 4. lO’im1.
with with
following
drugs
hydroxyurea
fluorodeoxyuridine,
were
(Sigma),
cytosine
used deo-
arabinoside
HCI,
HeLa
cells
the
recovery
Sigma) ethidium bromide (Sigma). 7 (1 or 2.10 cells in 50 ml), to be used as of m.DNA,
50, 5 mC/mM,New with
modified
centrifuged
hours
Amersham)or
thymidine
arabino-furanosyl
control
5% calf
of 5. 105,/ml
for
radioactive
inhibitors:
Drug-untreated
in Eagle’s
with
cultures
8 C/mM,
the
in suspension
concentration
(Schwar’zfMann),
an internal
the tritium
were
England
labeled
labeled
with
Nuclear
samples
Corp.)
at the
[2-l*C] for
end of the
about incuba-
period. iii)
and
before
1-p-D
24 hours
DNA
deoxyadeno-
conditions.
7, 5 C/mM,Amersham)
synthesis
(cytosine
of m. DNA
METHODS
4. 1 04/ml
growing
10 pC/ml;
(10
added
tion
medium
(5 or
grown
between
of 10 to 25 ml were
thymidine sine
AND
their
excess
arabinoside
on total
supplemented
of exponentially
in fresh
Aliquots
of labeling
effect
were
at a concentration
pended
resume
the.inhibition thymidine,
so that
cultures.
cells
medium
cycle,
wouid
cytosine
to the
life
asinchronously.
of excess
MATERIALS a) Cells
of their
replication
hydroxyurea,
was
RESEARCH COMMUNICATIONS
The
[2-‘“Cl
radioactivity trichloacetic (matman
incorporation thymidine
into
in samples acid GF/C).
3
of [methyltotal
of the
H] thymidine
cellular total
(TCA).in
the
cold
Samples
labeled
DNA
was
cell
homogenate
and
collected
with 883
tritiated
or
PH-GI
analyzed
deox)-adeno
sine
by- measuring
the
precipitated on glass
fiber
deoxyadenosine
with
5%
filters were
treated
Vol. 60, No. 3,1974
with
NaCH
lize
the
BlOCHEMlCAL
0. 5 N for
15 min
Cytosine-arabinoside
measured
in cell
[5 -3S] c)*osine m. DNA
was
m. DNA
samples
then
first
fraction
was
bromide
gradient
method,
was
The
m. DNA
two
hours
I and RNase
centrifuged
, to ‘a:.-dro-
was
then
tions.
mitochondrial
The
sulfate
(SDS),
digested
for
pellet
30 min
hours
samples
were
(Merck)
chilled
for
recentrifuged
under
the
added
in order
alcohol
were
hours
at -20°C
the
at 14. 000 rev/min
for
in 1 ml
0. 01 M Tris
a two-step
CsCI-ethidium in
bromide)
0. 01
M in
same
was
for
the
buffer Spinco
pH
The
SW
50.
and
gradient
CsCl,
1 rotor
(1 ml
884
M at
buffer
(pH condi-
dodee)-!
and pronase
EGTA. 33,
000
(self-
of 75 rg/ml. concentration
of
at 12.000
rev/min
fraction of cold
acids.
acids
0. 01 M EDTA
0. 01
10 min,
was
93’
After
were
sedimrnted
rev/min
rotor
resuspended throl?gh
g=l.70, with
eth?-1 at least
in the SS 34 Sorvall nucleic
for
for
same
supernatant
the nucleic
centrifuged
7. 2,
7.2)
to a final
and the pelleted
bromide
the
of 1% sodium (pH
digested
fraction
at 4°C
and two volumes
to precipitate
pH 7. 2,
and
0. 01 M Tris
and centrifuged
15 min.
were
cells)
to a concentration added
conditions
samples
buffer
added
0. 05 Xl
rcitochondrial
under
buffer
2,
respectively-)
SS 34 rotor
in 3 ml
30 min
at 4°C
20 min
Tris
lysed
was
CsCl
SS 34 rotor
the
M sucrose,
0. 01 M Tris
in the Sorvall
packed 100 rg/ml
and
as in the first
M MgCl
and recentrifuged was
at 37°C)
at 37”C,
and
of the Storrie
obtained
buffer/ml
in the Sorvall
cells)
mitochondrial
in a CsCl-etbidium
0.0015
treatment
in 0.25
packed
of the
is a modification
100 pg/ml
enzimatic
lysate
fraction,
(4 ml
7.2)
rev/mm
methods.
below,
(pH
0. 01 M EDTA, two
with
(3).
mitochondrial
resuspended
buffer/ml
-Gas
Amersham):
to equilibrium
M sucrose,
the
at 9600
for
14 C/mM,
sulfate
centrifuged
A (10 or
After
labeled
dodecyl
in 0.25
buffer
7. 2) (4 ml
dium
and
nuclear
different
described
(4).
at 37°C.
@ = 1.40
TCA
below.
described
method,
resuspended
DNase
1 M,the
a sodium
as previously
0. 005 M Tris
the pellet
two
into
5 rC/ml,
to two
and then
procedure
After
with
DNA.
method
second
or
as described
according
prepared
The
Attardi’s
was
precipitation
1.1 06/m1)
(2.5
isolated
isolated
i) In the
15 min
(70 ml,
of mitochondrial was
NaCl,
before
incorporation
#j-D-arabinoside
c) Isolation
with
at 37°C
RESEARCH COMMUNICATIONS
RNA.
iiii)
ii)
AND BIOPHYSICAL
3ml
200
CsCl,
yg/ml for
ethi5 hours
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Table 1 Effect of llffmmt DNA synth,,ls Inblbitors on the lrbella6 tf total cdl DNA an1 n.DIA lrolrtrd by CsCI-stbldlum bromide density pradisnt ,
Expt
Ethidlun btoaida
IPlhl
0
: INHIBITIOI m. ONA 100
2 3 4
Hydroxyurer * .
lwSP . 5*10-‘M
95 94 70
02 59 53
5 6
:ytarlne rrbiaosld~ Ho-’ M * *
96 07
0 6
7 0 9
Oetxyrdtntsinc . .
2WM t *
96 67 76
04 71 79
IO I1 12
lkymidine * .
2*lbJP .
65 69 77
67 63 63
I3 I4 I5
Fluorodatxyuridinr * *
Ir#/ml . *
47 77 75
74 54 70
INHIBITOR
no r
l
Table 1 Effect of different DNA synthesis inhi.bitors on the labeling =ell DNA and m. DNA isolated by CsCl-ethidium bromide equilibrium gradient.
of total
density
m. DNA was isolated from HeLa cells labeled with tritiated thymidine (expts. l-9) or deoxyadenosine (expts. 10-15) in th-e presence of specific inhibitors as explained in Materials and Methods section ,b fi) and in the legend of Fig. 1. The labeling of total cell DNA was ca?culateci as 3H ctslmin present in the samples of the cell homogenate precipitated with TCA3(Materials and Methods associated b_ (iii)) while the labeling of m. DNA was calculated as H cts/min with the heavier band of the gradient (pertaining to closed circular DS,Q, The percentages of inhibition of radioactivity incorporation in total cell DNA and m. DNA were calculated relatively to the incorporation in controls.
at 20°C. bottom
After of the
and counted
the tube,
before
were TCA
fractions
precipitated
in a liquid
deoxyadenosine lized
run,
with
scintillation treated
of about
with
120 ~1 were
TCA.
collected
counter. NaOH
precipitation.
885
0.5
Samples N (15 min
collected
from
the
on glass
fiber
filters
labeled
with
[‘H-G]
at 37°C)
and,neutra-
Vol. 60, No. 3,1974
BIOCHEMICAL
RESULTS Effect
of different
a) IX. DNA Table
1 shows
to the
method
cedure
only
seen
that
inhibitors reported the
(2. 1 Oe3M)
of inhibitors, 20%
arabinoside, is very
I of m. DNA
it doesn’t
affect
5. 10W4M),
m. DNA
finally, poorly
equilibrium
of these
inhibitors
corresponds
the
density
circular
or open
circular
strong
labeling.
in Fig.
that
of the 1.
m. DNA DNA
Ml,
For
labeling
of total
cell
by
m. DNA
labeled
pattern
molecules molecules
total
with
analysis
the
and the (mostly
DNA.
thymidine
among
on total
each
inhibits cell
as expected,
effect
The
It can be
of total -3
Hydroxycrea,
verus
pro-
completel>-
(2.10
on m. DNA
expected
B>- this
labeling
inhibit,
labeling.
gradients
is shown
the
expo-
according
can be quantitated.
at all
active
were
isolated
sectionS(
deoxyadenosine
of this
on m. DNA
to closed to linear
inhibition shows
active
less
cells
of 1 pg/ml,
(1 pg/mI)
extent
in the
bromide
pertains
and Methods,
at a concentration
is consistently
difference
m. DNA
labeling.
gradient.
was
labeled
and fluorodeoxyuridine
and to a lesser
densit)-
and the
form
(1.1 Oq3M,
on m-DNA
bromide
in Materials
while
synthesis
in which
bromide
labeling,
Hydroxyurea
of DNA
of a set of experiments
supercoiled
ethidium
m-DNA
DNA
results
RESEARCH COMMUNICATIONS
DISCUSSION
by CsCl-ethidium
the
sed to different
AND
inhibitors
isolated
AND BIOPHYSICAL
cell
this
group
an average
DNA. cell
Cytosine DNA
but it
CsCl-ethidium in the heavier major
presence band
lighter
nuclear
band
contami-
nant s) .
Fig. 1 Analysis m. DNA labeled
b>- CsCl-ethidium in the presence.
bromide
of different
equilibrium inhibitors.
density
gradient
of
HeLa cells were labeled with tritiated thymidine (a- cl) or deoxyadenosine (e, f) as explained in Materials and Methods section b(i). DNA extraction from the mitochondrial fraction and banding in CsCl-ethidium bromide density gradients were carried out as previously described (3). Gradients were centrifuged for 48 hours at 35. K rpm in the SW41 Spinco rotor at 2O”C, fractions of about 70 ~1 were collected from the bottom of the tube and aliquots of 20 VI with TCA, collected on glass (a), 30 pl (b, c ) or 50 ~1 (d, e,f) were precipited fibre filters (Whatman GF/C) and counted in a scintillation counter. Aliquots from gradients e and f were treated with NaOH (0.5 N, 15 min at 37’C) and neutralized before being TCA precipitated., -3 arabinoside a: ethidium bromide 1 pi/ml; b: hydroxyurea 1. 10 M; c;3cytosine 1. 10W5M; d: deoxyadenosine 2. 10W3M; e: thymidine 2.10 M; f: fluorodeoxyuridine 1 pi/ml. . ---. ---. control; . -. inhibitor.
886
BIOCHEMICAL
Vol. 60, No. 3,1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
v (bl
HU
:i =F ,
(I)
7 :
Ethbr.
dAda
Fraction
b)
m.
de
two-step
It
DNA
cannot
isolated
by
sedimentation
velocity
no
through
a CsCl-ethidi?lm
m.
determinations
bromi-
gradient. be
significantly small
Thv. (eJ ,
ignored
that
the
precision
by
the
isolation
procedure
(relative
to
affected proportion
of
m.
DNA
of
the
total
887
DNA used,
DNA)
in
in
view
the
cell,
be
ma)-
not but
only also
of of
the its
(d)
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
Table Effect
of different
DNA
RESEARCH COMMUNICATIONS
2
synthesis
inhibitors
on the
Iabelinl
of total
cell DNA and m.011 isolated by sedimentation throughaCsCI-ethidium bromide two step-gradient.
cBIc
Expt. lWHlBlTOR no 1 Et hidh brtrtde
*
PERCENTAGE OF INHIBITION TOTAL DNA m. DNA 0 100
2 3
Hydroxyurca
82
65
98
5
96
89 75
83
47
96 95
34 24
iytotine
arabinosik
7 II 9
94
28
10 11
96 97
20 15
12 13
97 96
35 37
14
36
ta
90
60
15
Oeoxyrderosine
16
89
75
11
91
82
70
57
Thymidine
I8 Table
2
Effect
of
and m. two-step
different
the
DNA
DNA isolated gradient.
Cells were labeled (expt.18’) as explained isolated as specified The labeling of total while
100
4
6
cell DNA bromide
20
synthesis
by
inhibitors
sedimentation
on
velocit)-
the
labeling
through
of
total
a CsCl-ethidium
with
tr itiated thymidine (expt s. 1 - 1’7) or deoxyadeno sane s section _b (i) and rr,.DZaq was Materials and Method in section s(ii). cell DNA was calculated as described in legend Table 1 3 H cts/min incorporated into m. DNA was caiculated as in
radioactivity
associated with m. DNA form I (a and b) and form II as separa.ted b>- sedimentation velocity (Fig. 2-4). Normalization for differences in recovery of 14C cts/min present in the same bands. m. DNA was done on the basis of the The percentages of inhibition of incorporation in total cell DNA and m. DSA were calculated relatively to control samples. Each value of inhibition of m. DNA labeling DNA form I and
represents II.
presence
in
accurate
assessment
which
appeared
multiple
the
forms of
to
vary
average
with the over
of
the
different
values
physico-chemical
differential a broad
separate
effect range
888
of of
the
activities,
found
ior
m.
properties. inhibitors
used required
An here, then
to
be
Vol.
60,
No.
BIOCHEMICAL
3,1974
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1500.
100O-
5010. 2 c
v) ',
d
I"
150nl-
100IO
50IO
8
Fraction
Fig. 2 gradient
no
Fraction
Analysis by sedimentation velocity of m. DNA labeled in the presence
HeLa cells (5 pi/ml, 8 1 pi/ml (b). standard for of m. DNA, are described to in the text. .-.-.
no
in CsCl-ethidium bromide of ethidium bromide.
two-step
(8. lo7 cells in 20 ml) were labeled with [methyl-3Hj thymidine C! mM) in the absence (a) or in the presence of etfidium bromide Long-term labeled cells were used as in internal k-l4 C 1 thymidine the recovery of m. DNA (Materials and Methods g (ii)).Isolation conditions of the run and collection of fraction from the gradient in Materials and Methods c(ii). The numbered bands are referred 3H
cts/min;
. -----.
Fig. 3 Analysis by sedimentation gradient of m. DNA labeled in the
14
-----. velocity presence
C cts/min in CsCl-ethidium bromide of different inhibitors.
two,-step
HeLa cells (2: 4. 10’ cells in 20 ml)were labeled with’[methyl-3H] thymidine in the absence (a) and in the presence of: hydroxyurea (5 pi/ml, 8 C/mM) 1. 10-3M (b), cytosine arabinoside 1.1 OW5M (cl, deoxyadenosine 2.1 Oe3M (d) See also legend Fig. 2. 14 .-.3H cts/min . -----. -----. C cts/min
889
Vol. 60, No. 3,1974
verified
BIOCHEMICAL
by another
than
the
method,
classical
Materials
employed
and Methods contaminant
riments
we also
obtained
by mixing
-term
[2-14C]
E (ii), band
introduced the
should
which
the
analytical
obtained
the
bromide
gradient,
with
a band
a faster
merit
forms
lar
m. DNA.
The
From
comparison
effects de,
the
on nuclear
In the
The
effect
possibility
still
that
the labeling
results
of Table
1 and
values
of rr. DNA
form
rence.
In addition, analytical
found
labeling
appeared
derably
smaller
that
artefacts
extraction,
since
that
could
procedure
used,
but not
presence this
source
into
of error,
with
account,
of an internal
was
of m. DNA
form
could
since
widely
(although
such perhaps the
where
second,
b) variable standard
the
c) contamination
with
resolved for
the
in the first difference
of the
any
of the
inhibition
significant
carried
diffe-
OUT b>- the
remaining
in all
consi-
variations
results
cases
could
of closed
not be easily
circles
obtainedwith
nicked
a different bands
during the
molecules
of materials,
of m. DNA
890
of experiments.
on m. DNA
recovery
labeled
type
dif-
arabinosidc
as: a) nicking alter
reproduced.
of cytosine
These
DNA).
bromi-
a considerable
first
show
circu-
differential
well
used,
of experiments
2) the effect
open
to ethidium
calculation
didn’t
m. DNA
DNA.
the
fairly
II (not
of
of oligo-
nuclear
in the
the
bottom
circular
to the
be responsible
a series
on total
to obvious
are
two-step
consists
that
1 (except
illustrate
the
closed
by exposure
than
discarded
to fluctuate than
caused
smaller
(Table
attributed
and taken
but
within
procedure
from
it appears
I and II individually
even
starting
presumably
arabinoside
of m. DNA) 2 was
througha
and thymidine
cytosine
was
of separation
ted
labeling
of such
2-4
m. DNA
to degraded
of long-
in Table
(II) corresponding
tables
of m. DNA
results
Figures
the
,of expe-
amount
reported ).
see,
corresponds
of the two
where
method
same
band
deoxyadenosine
experiments
ferential
band
and m. DNA
hydroxyurea,
data
(lb) which
a second
siowes:
to the
II from
recovery
the
to monomeric
shoulder
of m.. DNA;
2 shows
by sedimenting
corresponding
sedimenting
Table
can
the
in
series
a constant
re-examined
One
I and form
for
samples
sensitive
described
In this
standard
was not
gradient. (Ia)
form
velocity.
cells.
more
procedure,
m. DNA
be compared
fluorodeoxyuridine
RESEARCH COhW&INlCATlONS
and actually
This
experimental
for
CsCl-ethidium
separates
labeled
patterns
above.
and internal
with
which
from,
by sedimentation
thymidine
experiments
independent
method
nuclear
AND BIOPHYSICAL
are
first separa-
because
isotope by nuclear
the
eliminates DSX:
be-
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
Fraction
RESEARCH COMMUNICATIONS
II’
Fig. 4 Analysis by sedimentation velocity gradient of m. DNA labeled in the presence
in CsCl-ethidium of thymidine.
bromide
HeLa celis (2, 2. lo7 cells in 15 ml) were labeled withfH-G] in the absence (a) and in the presence (10 @/ml, 7, 5 C/mM) 2. 10m3M. See also legend Fig. 2 14 3H cts/min, . -----. -----. C cts/min . -.-.
cause (one
all
the
experiments
of which
is illustrated
-resistant
radioactivity
a ten-fold
increase
did
not
might drug
whese
cells,
results.
the
inhibition
used
at very
cells
were
incubated
r(iiii)), effect
DNA
high
of cytosine
arabinoside
of ethidium-
employed,
then
that
depends
on mitochondrial
derivative
(ara-CTP),
replication
is also
found
into
on m. DNA
891
tha:
mitochondria these
variations of the
of m. DN.‘A s:.-ntheinabilit>in analog)not
(6). Indeed,
was
found
of action
insensitivity
cytosine
also
to purify
relative
radioactive
no incorporation
absence
characteristics
concentrations
with
bromide
It was
We believe
on the
that
(5) where
bands.
deoxyadenosine (b) of thymidine
of ethidium
a complete
of DNase
dependent
unless
the
2)show
it to its triphosphate
in bacteria
and Methods
the
likely
in the presence
mitochondrial
amount
arabinoside
phosphorylate happens
in part
It is quite
sis to cytosine
bitor,
in the change
be at least
out
in Fig. in the
significantly
itself.
carried
two-step
to what
affected
b:- the
in two
ewgeriments
arabinoside m. DNA does
to
not
inhi-
(Xaterials (Fig, seem
5). in HeLa to depend
on
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Fig. 5 Analysis by sedimentation velocity in CsCl -ethidium bromide two- step gradient of m. DNA isolated from HeLa cells (7. 1 07ceils in 70 ml) labeled for two ho,urs with [5-31-1] cytosine /j-D-arabinosi.de (2, 5 rC/ml, 14 C/m&:) See also legend Fig. 2.
the
concentration
occur,
(Table
we believe
uncontrolled caused
that
factors
by variable
meabilized
by toluene
concept
cells
is supported
mouse ted
Pica
nuclear
of two
only
into
Our
results,
since
play
a role
cultures):
into
the mitochondria
system.
It has
distinct
can
systems
by the results Kinase
cell
the
effect
shown
that
suppress
in E. coli
by Robberson
s where
radioactive
and
be phs s -
cells,
synthesis
phosphorylation
on
then
arabinoside
DNA
obtained
does
in turn would
of cytosine
of nucleoside
inhibition
(depending
inhibitory
been
in fact
a variable
per-
(7 1. in animal
Cla>-ton
th:-midine
(8) in
is incorpora-
m. DNA.
Mattocia
synthesis
hand,
might
, ara-CTP
L Thymidine
other
dell
leaking
by the
on the
permeability
in the
phorylated
The
i!),
finally
are
and Attardi’to
after
release
in favour interpret
of HeLa
cells
of the
second
the lack from
hypothesis
made
of synchronization
double
tly;-midine
b: of
m. DNA
block.
ACKNOWLEDGEMENTS We are manuscript
grateful to Dr. C. Vesco for advise in the preparation and Mrs. F. Sarracino for her excellent assistance.
of the
REFERENCES 1. 2.
Vesco, C. and Penman, S. Terschegget, J. and Borst,.
Biochem. Biophys. Res. Comn., 2, 249 (1969) P. Biochem. Biophys.Acta, 246, 239 (1971)
892
Vol. 60, No. 3,1974
3. 4.
Pica Storrie,
5. 6.
KarlstrlJm, Lark,
C.
7.
Staub, corr.nl. Robbersor
M., Warner, , 46, 1824 D. L.
8.
3810
Mattoccia, B.
BIOCHEMICAL
and
and
L. and Attardi,
H.O., Lark,
Attardi, G.,
Eur. J. K.G.,
J.
AND BIOPHYSICAL
G., Mol.
Biochem., J. Mol.
H. R. and (1972) and Clayton,
J. Mol. Biol. 17, Bier,
Reichard, D.A.
(1972)
893
RESEARCH COAWJNtCATfONS
Biol., ?I, 177 68(1970) 10, 120 F.,
Biocherr,.
Proc.Nat.Acad.Sci.
64, 465 (1972)
(1972)
(1964) Biophys. U.S.A.,
Res. B
BIOCHEMICAL
L. Laboratory
of
Received
Cell
July
Pica
Mattoccia
Biology,
22,
AND BIOPHYSICAL
C. N.
and
R.,
Via
S.
RESEARCH COMMUNICATIONS
Roberti
Rornagnosi
18
A,
Rome,
synthesis
on
the
bromide
densit)-
Ital>-
1974 SUMMARY
The
effect
of
tochondrial
different
DNA,
sedimentation xyadenosine
velocity, excess,
of mitochondrial difference clear DNA
of 22%) synthesis,
analogy
what
as
to
inhibitors
isolated
by
of
has been hydroxyurea
studied in HeLa and fluorodeoxyuridine
DNA less than while cytosine has a very
happens
expected,only
in
DNA
CsCl-ethidium
cells.
labeling
Thymidine inhibit
that
of the n.uclear DNA (with arabinoside, which strongly limited action on mitochondrial
the
bacterial
mitochondrial
system.
DNA
of
gradient
Ethidium
miand
and deolabeling
the
a maximum inhibits DNA, bromide
nuin
inhibits:
replication.
INTRODUCTICN
study-
The drial
of
replicative
and
cytoplasmic
and
alcohol
xic
The
(m.
Borst
All rights
only
replication
Irorri
lack
of thymiciine
in
to
HeLa
drugs
of
understand
of
cells,
the
the
in
to
isolated
nuclear
extent
into
acid
to
a limited
that
thymidine been
and of
the
bromide;
HU Thy
=.
@ 1974 by Academic Press, Inc. of reproduction in any form resetvd
by
mirochonacton
“1:
of
by
by
An UN-4
= hydroxyurea; thymidine;
882
DNA
not
Pica
block Mattoccia
synthesis
alternative synthesis CA FIJdR
not
after
by of
also
= cy-tosine :? fl-orodeox)-crilir.e
nalidi-
mitochondrial and the
hypothesis but
that
inhibited
concentrations
does
suggested
circular
found
is
high
of
hydroxyurea;
mitochondria,
excess
rn.
labeling
material
extent
block.
indeedblock
the
inhibition
insoluble
of m.
thymidine
that
chick-liver
synchronization
might
found
resistant
has
a double
Eth. br = ethidium d. Ade = deoxjradenosine:
Copyright
dATF
possibility
the
cells
(2))
and
DNA)
interpret
excess
help
relatively
of
phenethyl acid.
(1)
is
incorporation
HeLa
can
Penman DNA
Tershegget
DNA
to different
biogenesis.
Vesco
the
sensiti-Jity
systems
rritochondrial
to
the
Attardi release
was cause arabinoside;
(3) of
that anarrest
the of
BIOCHEMICAL
Vol. 60, No. 3, 1974
AND BIOPHYSICAL
mitochondria
development
at different
stages
cpon
of the
thymidine,
mitochondria
removal
development
and reach
In the
present
of HeLa sine,
excess
cells
the
paper
grown
stage
we investigated
in the presence
fluorodeoxyuridine,
bromide.
That
of DNA
compared
HeLa
(S,
clonal
(Joklik,
strain)
Grand
Island)
ranging
b) Drug
and labeling
treatment
if Samples
C/ml; B one hour
as DNA xyadenosine
ii)
at the
and
ethidium
labeling.
incubated
thymidine
for
(0, 1 PC/ml; and mixed
and
5. 1 OS/ml.
were
two
serum
at 37°C
in the
The
(Merck),
resus-
[methyl-
3H.]
H-G deoxyadenoP I. of the specific inhibitor
presence
isotope.
and
to 4. lO’im1.
with with
following
drugs
hydroxyurea
fluorodeoxyuridine,
were
(Sigma),
cytosine
used deo-
arabinoside
HCI,
HeLa
cells
the
recovery
Sigma) ethidium bromide (Sigma). 7 (1 or 2.10 cells in 50 ml), to be used as of m.DNA,
50, 5 mC/mM,New with
modified
centrifuged
hours
Amersham)or
thymidine
arabino-furanosyl
control
5% calf
of 5. 105,/ml
for
radioactive
inhibitors:
Drug-untreated
in Eagle’s
with
cultures
8 C/mM,
the
in suspension
concentration
(Schwar’zfMann),
an internal
the tritium
were
England
labeled
labeled
with
Nuclear
samples
Corp.)
at the
[2-l*C] for
end of the
about incuba-
period. iii)
and
before
1-p-D
24 hours
DNA
deoxyadeno-
conditions.
7, 5 C/mM,Amersham)
synthesis
(cytosine
of m. DNA
METHODS
4. 1 04/ml
growing
10 pC/ml;
(10
added
tion
medium
(5 or
grown
between
of 10 to 25 ml were
thymidine sine
AND
their
excess
arabinoside
on total
supplemented
of exponentially
in fresh
Aliquots
of labeling
effect
were
at a concentration
pended
resume
the.inhibition thymidine,
so that
cultures.
cells
medium
cycle,
wouid
cytosine
to the
life
asinchronously.
of excess
MATERIALS a) Cells
of their
replication
hydroxyurea,
was
RESEARCH COMMUNICATIONS
The
[2-‘“Cl
radioactivity trichloacetic (matman
incorporation thymidine
into
in samples acid GF/C).
3
of [methyltotal
of the
H] thymidine
cellular total
(TCA).in
the
cold
Samples
labeled
DNA
was
cell
homogenate
and
collected
with 883
tritiated
or
PH-GI
analyzed
deox)-adeno
sine
by- measuring
the
precipitated on glass
fiber
deoxyadenosine
with
5%
filters were
treated
Vol. 60, No. 3,1974
with
NaCH
lize
the
BlOCHEMlCAL
0. 5 N for
15 min
Cytosine-arabinoside
measured
in cell
[5 -3S] c)*osine m. DNA
was
m. DNA
samples
then
first
fraction
was
bromide
gradient
method,
was
The
m. DNA
two
hours
I and RNase
centrifuged
, to ‘a:.-dro-
was
then
tions.
mitochondrial
The
sulfate
(SDS),
digested
for
pellet
30 min
hours
samples
were
(Merck)
chilled
for
recentrifuged
under
the
added
in order
alcohol
were
hours
at -20°C
the
at 14. 000 rev/min
for
in 1 ml
0. 01 M Tris
a two-step
CsCI-ethidium in
bromide)
0. 01
M in
same
was
for
the
buffer Spinco
pH
The
SW
50.
and
gradient
CsCl,
1 rotor
(1 ml
884
M at
buffer
(pH condi-
dodee)-!
and pronase
EGTA. 33,
000
(self-
of 75 rg/ml. concentration
of
at 12.000
rev/min
fraction of cold
acids.
acids
0. 01 M EDTA
0. 01
10 min,
was
93’
After
were
sedimrnted
rev/min
rotor
resuspended throl?gh
g=l.70, with
eth?-1 at least
in the SS 34 Sorvall nucleic
for
for
same
supernatant
the nucleic
centrifuged
7. 2,
7.2)
to a final
and the pelleted
bromide
the
of 1% sodium (pH
digested
fraction
at 4°C
and two volumes
to precipitate
pH 7. 2,
and
0. 01 M Tris
and centrifuged
15 min.
were
cells)
to a concentration added
conditions
samples
buffer
added
0. 05 Xl
rcitochondrial
under
buffer
2,
respectively-)
SS 34 rotor
in 3 ml
30 min
at 4°C
20 min
Tris
lysed
was
CsCl
SS 34 rotor
the
M sucrose,
0. 01 M Tris
in the Sorvall
packed 100 rg/ml
and
as in the first
M MgCl
and recentrifuged was
at 37°C)
at 37”C,
and
of the Storrie
obtained
buffer/ml
in the Sorvall
cells)
mitochondrial
in a CsCl-etbidium
0.0015
treatment
in 0.25
packed
of the
is a modification
100 pg/ml
enzimatic
lysate
fraction,
(4 ml
7.2)
rev/mm
methods.
below,
(pH
0. 01 M EDTA, two
with
(3).
mitochondrial
resuspended
buffer/ml
-Gas
Amersham):
to equilibrium
M sucrose,
the
at 9600
for
14 C/mM,
sulfate
centrifuged
A (10 or
After
labeled
dodecyl
in 0.25
buffer
7. 2) (4 ml
dium
and
nuclear
different
described
(4).
at 37°C.
@ = 1.40
TCA
below.
described
method,
resuspended
DNase
1 M,the
a sodium
as previously
0. 005 M Tris
the pellet
two
into
5 rC/ml,
to two
and then
procedure
After
with
DNA.
method
second
or
as described
according
prepared
The
Attardi’s
was
precipitation
1.1 06/m1)
(2.5
isolated
isolated
i) In the
15 min
(70 ml,
of mitochondrial was
NaCl,
before
incorporation
#j-D-arabinoside
c) Isolation
with
at 37°C
RESEARCH COMMUNICATIONS
RNA.
iiii)
ii)
AND BIOPHYSICAL
3ml
200
CsCl,
yg/ml for
ethi5 hours
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Table 1 Effect of llffmmt DNA synth,,ls Inblbitors on the lrbella6 tf total cdl DNA an1 n.DIA lrolrtrd by CsCI-stbldlum bromide density pradisnt ,
Expt
Ethidlun btoaida
IPlhl
0
: INHIBITIOI m. ONA 100
2 3 4
Hydroxyurer * .
lwSP . 5*10-‘M
95 94 70
02 59 53
5 6
:ytarlne rrbiaosld~ Ho-’ M * *
96 07
0 6
7 0 9
Oetxyrdtntsinc . .
2WM t *
96 67 76
04 71 79
IO I1 12
lkymidine * .
2*lbJP .
65 69 77
67 63 63
I3 I4 I5
Fluorodatxyuridinr * *
Ir#/ml . *
47 77 75
74 54 70
INHIBITOR
no r
l
Table 1 Effect of different DNA synthesis inhi.bitors on the labeling =ell DNA and m. DNA isolated by CsCl-ethidium bromide equilibrium gradient.
of total
density
m. DNA was isolated from HeLa cells labeled with tritiated thymidine (expts. l-9) or deoxyadenosine (expts. 10-15) in th-e presence of specific inhibitors as explained in Materials and Methods section ,b fi) and in the legend of Fig. 1. The labeling of total cell DNA was ca?culateci as 3H ctslmin present in the samples of the cell homogenate precipitated with TCA3(Materials and Methods associated b_ (iii)) while the labeling of m. DNA was calculated as H cts/min with the heavier band of the gradient (pertaining to closed circular DS,Q, The percentages of inhibition of radioactivity incorporation in total cell DNA and m. DNA were calculated relatively to the incorporation in controls.
at 20°C. bottom
After of the
and counted
the tube,
before
were TCA
fractions
precipitated
in a liquid
deoxyadenosine lized
run,
with
scintillation treated
of about
with
120 ~1 were
TCA.
collected
counter. NaOH
precipitation.
885
0.5
Samples N (15 min
collected
from
the
on glass
fiber
filters
labeled
with
[‘H-G]
at 37°C)
and,neutra-
Vol. 60, No. 3,1974
BIOCHEMICAL
RESULTS Effect
of different
a) IX. DNA Table
1 shows
to the
method
cedure
only
seen
that
inhibitors reported the
(2. 1 Oe3M)
of inhibitors, 20%
arabinoside, is very
I of m. DNA
it doesn’t
affect
5. 10W4M),
m. DNA
finally, poorly
equilibrium
of these
inhibitors
corresponds
the
density
circular
or open
circular
strong
labeling.
in Fig.
that
of the 1.
m. DNA DNA
Ml,
For
labeling
of total
cell
by
m. DNA
labeled
pattern
molecules molecules
total
with
analysis
the
and the (mostly
DNA.
thymidine
among
on total
each
inhibits cell
as expected,
effect
The
It can be
of total -3
Hydroxycrea,
verus
pro-
completel>-
(2.10
on m. DNA
expected
B>- this
labeling
inhibit,
labeling.
gradients
is shown
the
expo-
according
can be quantitated.
at all
active
were
isolated
sectionS(
deoxyadenosine
of this
on m. DNA
to closed to linear
inhibition shows
active
less
cells
of 1 pg/ml,
(1 pg/mI)
extent
in the
bromide
pertains
and Methods,
at a concentration
is consistently
difference
m. DNA
labeling.
gradient.
was
labeled
and fluorodeoxyuridine
and to a lesser
densit)-
and the
form
(1.1 Oq3M,
on m-DNA
bromide
in Materials
while
synthesis
in which
bromide
labeling,
Hydroxyurea
of DNA
of a set of experiments
supercoiled
ethidium
m-DNA
DNA
results
RESEARCH COMMUNICATIONS
DISCUSSION
by CsCl-ethidium
the
sed to different
AND
inhibitors
isolated
AND BIOPHYSICAL
cell
this
group
an average
DNA. cell
Cytosine DNA
but it
CsCl-ethidium in the heavier major
presence band
lighter
nuclear
band
contami-
nant s) .
Fig. 1 Analysis m. DNA labeled
b>- CsCl-ethidium in the presence.
bromide
of different
equilibrium inhibitors.
density
gradient
of
HeLa cells were labeled with tritiated thymidine (a- cl) or deoxyadenosine (e, f) as explained in Materials and Methods section b(i). DNA extraction from the mitochondrial fraction and banding in CsCl-ethidium bromide density gradients were carried out as previously described (3). Gradients were centrifuged for 48 hours at 35. K rpm in the SW41 Spinco rotor at 2O”C, fractions of about 70 ~1 were collected from the bottom of the tube and aliquots of 20 VI with TCA, collected on glass (a), 30 pl (b, c ) or 50 ~1 (d, e,f) were precipited fibre filters (Whatman GF/C) and counted in a scintillation counter. Aliquots from gradients e and f were treated with NaOH (0.5 N, 15 min at 37’C) and neutralized before being TCA precipitated., -3 arabinoside a: ethidium bromide 1 pi/ml; b: hydroxyurea 1. 10 M; c;3cytosine 1. 10W5M; d: deoxyadenosine 2. 10W3M; e: thymidine 2.10 M; f: fluorodeoxyuridine 1 pi/ml. . ---. ---. control; . -. inhibitor.
886
BIOCHEMICAL
Vol. 60, No. 3,1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
v (bl
HU
:i =F ,
(I)
7 :
Ethbr.
dAda
Fraction
b)
m.
de
two-step
It
DNA
cannot
isolated
by
sedimentation
velocity
no
through
a CsCl-ethidi?lm
m.
determinations
bromi-
gradient. be
significantly small
Thv. (eJ ,
ignored
that
the
precision
by
the
isolation
procedure
(relative
to
affected proportion
of
m.
DNA
of
the
total
887
DNA used,
DNA)
in
in
view
the
cell,
be
ma)-
not but
only also
of of
the its
(d)
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
Table Effect
of different
DNA
RESEARCH COMMUNICATIONS
2
synthesis
inhibitors
on the
Iabelinl
of total
cell DNA and m.011 isolated by sedimentation throughaCsCI-ethidium bromide two step-gradient.
cBIc
Expt. lWHlBlTOR no 1 Et hidh brtrtde
*
PERCENTAGE OF INHIBITION TOTAL DNA m. DNA 0 100
2 3
Hydroxyurca
82
65
98
5
96
89 75
83
47
96 95
34 24
iytotine
arabinosik
7 II 9
94
28
10 11
96 97
20 15
12 13
97 96
35 37
14
36
ta
90
60
15
Oeoxyrderosine
16
89
75
11
91
82
70
57
Thymidine
I8 Table
2
Effect
of
and m. two-step
different
the
DNA
DNA isolated gradient.
Cells were labeled (expt.18’) as explained isolated as specified The labeling of total while
100
4
6
cell DNA bromide
20
synthesis
by
inhibitors
sedimentation
on
velocit)-
the
labeling
through
of
total
a CsCl-ethidium
with
tr itiated thymidine (expt s. 1 - 1’7) or deoxyadeno sane s section _b (i) and rr,.DZaq was Materials and Method in section s(ii). cell DNA was calculated as described in legend Table 1 3 H cts/min incorporated into m. DNA was caiculated as in
radioactivity
associated with m. DNA form I (a and b) and form II as separa.ted b>- sedimentation velocity (Fig. 2-4). Normalization for differences in recovery of 14C cts/min present in the same bands. m. DNA was done on the basis of the The percentages of inhibition of incorporation in total cell DNA and m. DSA were calculated relatively to control samples. Each value of inhibition of m. DNA labeling DNA form I and
represents II.
presence
in
accurate
assessment
which
appeared
multiple
the
forms of
to
vary
average
with the over
of
the
different
values
physico-chemical
differential a broad
separate
effect range
888
of of
the
activities,
found
ior
m.
properties. inhibitors
used required
An here, then
to
be
Vol.
60,
No.
BIOCHEMICAL
3,1974
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
1500.
100O-
5010. 2 c
v) ',
d
I"
150nl-
100IO
50IO
8
Fraction
Fig. 2 gradient
no
Fraction
Analysis by sedimentation velocity of m. DNA labeled in the presence
HeLa cells (5 pi/ml, 8 1 pi/ml (b). standard for of m. DNA, are described to in the text. .-.-.
no
in CsCl-ethidium bromide of ethidium bromide.
two-step
(8. lo7 cells in 20 ml) were labeled with [methyl-3Hj thymidine C! mM) in the absence (a) or in the presence of etfidium bromide Long-term labeled cells were used as in internal k-l4 C 1 thymidine the recovery of m. DNA (Materials and Methods g (ii)).Isolation conditions of the run and collection of fraction from the gradient in Materials and Methods c(ii). The numbered bands are referred 3H
cts/min;
. -----.
Fig. 3 Analysis by sedimentation gradient of m. DNA labeled in the
14
-----. velocity presence
C cts/min in CsCl-ethidium bromide of different inhibitors.
two,-step
HeLa cells (2: 4. 10’ cells in 20 ml)were labeled with’[methyl-3H] thymidine in the absence (a) and in the presence of: hydroxyurea (5 pi/ml, 8 C/mM) 1. 10-3M (b), cytosine arabinoside 1.1 OW5M (cl, deoxyadenosine 2.1 Oe3M (d) See also legend Fig. 2. 14 .-.3H cts/min . -----. -----. C cts/min
889
Vol. 60, No. 3,1974
verified
BIOCHEMICAL
by another
than
the
method,
classical
Materials
employed
and Methods contaminant
riments
we also
obtained
by mixing
-term
[2-14C]
E (ii), band
introduced the
should
which
the
analytical
obtained
the
bromide
gradient,
with
a band
a faster
merit
forms
lar
m. DNA.
The
From
comparison
effects de,
the
on nuclear
In the
The
effect
possibility
still
that
the labeling
results
of Table
1 and
values
of rr. DNA
form
rence.
In addition, analytical
found
labeling
appeared
derably
smaller
that
artefacts
extraction,
since
that
could
procedure
used,
but not
presence this
source
into
of error,
with
account,
of an internal
was
of m. DNA
form
could
since
widely
(although
such perhaps the
where
second,
b) variable standard
the
c) contamination
with
resolved for
the
in the first difference
of the
any
of the
inhibition
significant
carried
diffe-
OUT b>- the
remaining
in all
consi-
variations
results
cases
could
of closed
not be easily
circles
obtainedwith
nicked
a different bands
during the
molecules
of materials,
of m. DNA
890
of experiments.
on m. DNA
recovery
labeled
type
dif-
arabinosidc
as: a) nicking alter
reproduced.
of cytosine
These
DNA).
bromi-
a considerable
first
show
circu-
differential
well
used,
of experiments
2) the effect
open
to ethidium
calculation
didn’t
m. DNA
DNA.
the
fairly
II (not
of
of oligo-
nuclear
in the
the
bottom
circular
to the
be responsible
a series
on total
to obvious
are
two-step
consists
that
1 (except
illustrate
the
closed
by exposure
than
discarded
to fluctuate than
caused
smaller
(Table
attributed
and taken
but
within
procedure
from
it appears
I and II individually
even
starting
presumably
arabinoside
of m. DNA) 2 was
througha
and thymidine
cytosine
was
of separation
ted
labeling
of such
2-4
m. DNA
to degraded
of long-
in Table
(II) corresponding
tables
of m. DNA
results
Figures
the
,of expe-
amount
reported ).
see,
corresponds
of the two
where
method
same
band
deoxyadenosine
experiments
ferential
band
and m. DNA
hydroxyurea,
data
(lb) which
a second
siowes:
to the
II from
recovery
the
to monomeric
shoulder
of m.. DNA;
2 shows
by sedimenting
corresponding
sedimenting
Table
can
the
in
series
a constant
re-examined
One
I and form
for
samples
sensitive
described
In this
standard
was not
gradient. (Ia)
form
velocity.
cells.
more
procedure,
m. DNA
be compared
fluorodeoxyuridine
RESEARCH COhW&INlCATlONS
and actually
This
experimental
for
CsCl-ethidium
separates
labeled
patterns
above.
and internal
with
which
from,
by sedimentation
thymidine
experiments
independent
method
nuclear
AND BIOPHYSICAL
are
first separa-
because
isotope by nuclear
the
eliminates DSX:
be-
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
Fraction
RESEARCH COMMUNICATIONS
II’
Fig. 4 Analysis by sedimentation velocity gradient of m. DNA labeled in the presence
in CsCl-ethidium of thymidine.
bromide
HeLa celis (2, 2. lo7 cells in 15 ml) were labeled withfH-G] in the absence (a) and in the presence (10 @/ml, 7, 5 C/mM) 2. 10m3M. See also legend Fig. 2 14 3H cts/min, . -----. -----. C cts/min . -.-.
cause (one
all
the
experiments
of which
is illustrated
-resistant
radioactivity
a ten-fold
increase
did
not
might drug
whese
cells,
results.
the
inhibition
used
at very
cells
were
incubated
r(iiii)), effect
DNA
high
of cytosine
arabinoside
of ethidium-
employed,
then
that
depends
on mitochondrial
derivative
(ara-CTP),
replication
is also
found
into
on m. DNA
891
tha:
mitochondria these
variations of the
of m. DN.‘A s:.-ntheinabilit>in analog)not
(6). Indeed,
was
found
of action
insensitivity
cytosine
also
to purify
relative
radioactive
no incorporation
absence
characteristics
concentrations
with
bromide
It was
We believe
on the
that
(5) where
bands.
deoxyadenosine (b) of thymidine
of ethidium
a complete
of DNase
dependent
unless
the
2)show
it to its triphosphate
in bacteria
and Methods
the
likely
in the presence
mitochondrial
amount
arabinoside
phosphorylate happens
in part
It is quite
sis to cytosine
bitor,
in the change
be at least
out
in Fig. in the
significantly
itself.
carried
two-step
to what
affected
b:- the
in two
ewgeriments
arabinoside m. DNA does
to
not
inhi-
(Xaterials (Fig, seem
5). in HeLa to depend
on
Vol. 60, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Fig. 5 Analysis by sedimentation velocity in CsCl -ethidium bromide two- step gradient of m. DNA isolated from HeLa cells (7. 1 07ceils in 70 ml) labeled for two ho,urs with [5-31-1] cytosine /j-D-arabinosi.de (2, 5 rC/ml, 14 C/m&:) See also legend Fig. 2.
the
concentration
occur,
(Table
we believe
uncontrolled caused
that
factors
by variable
meabilized
by toluene
concept
cells
is supported
mouse ted
Pica
nuclear
of two
only
into
Our
results,
since
play
a role
cultures):
into
the mitochondria
system.
It has
distinct
can
systems
by the results Kinase
cell
the
effect
shown
that
suppress
in E. coli
by Robberson
s where
radioactive
and
be phs s -
cells,
synthesis
phosphorylation
on
then
arabinoside
DNA
obtained
does
in turn would
of cytosine
of nucleoside
inhibition
(depending
inhibitory
been
in fact
a variable
per-
(7 1. in animal
Cla>-ton
th:-midine
(8) in
is incorpora-
m. DNA.
Mattocia
synthesis
hand,
might
, ara-CTP
L Thymidine
other
dell
leaking
by the
on the
permeability
in the
phorylated
The
i!),
finally
are
and Attardi’to
after
release
in favour interpret
of HeLa
cells
of the
second
the lack from
hypothesis
made
of synchronization
double
tly;-midine
b: of
m. DNA
block.
ACKNOWLEDGEMENTS We are manuscript
grateful to Dr. C. Vesco for advise in the preparation and Mrs. F. Sarracino for her excellent assistance.
of the
REFERENCES 1. 2.
Vesco, C. and Penman, S. Terschegget, J. and Borst,.
Biochem. Biophys. Res. Comn., 2, 249 (1969) P. Biochem. Biophys.Acta, 246, 239 (1971)
892
Vol. 60, No. 3,1974
3. 4.
Pica Storrie,
5. 6.
KarlstrlJm, Lark,
C.
7.
Staub, corr.nl. Robbersor
M., Warner, , 46, 1824 D. L.
8.
3810
Mattoccia, B.
BIOCHEMICAL
and
and
L. and Attardi,
H.O., Lark,
Attardi, G.,
Eur. J. K.G.,
J.
AND BIOPHYSICAL
G., Mol.
Biochem., J. Mol.
H. R. and (1972) and Clayton,
J. Mol. Biol. 17, Bier,
Reichard, D.A.
(1972)
893
RESEARCH COAWJNtCATfONS
Biol., ?I, 177 68(1970) 10, 120 F.,
Biocherr,.
Proc.Nat.Acad.Sci.
64, 465 (1972)
(1972)
(1964) Biophys. U.S.A.,
Res. B