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Evidence for the synchronous replication of mitochondrial DNA during the yeast cell cycle
BIOCHEMICAL
Vol. 101, No. 4,19Bl August
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 1350-1356
31, 1981
EVIDENCE FOR THE SYNCHRONOUS REPLICATION
OF MITOCHONDRIAL
DNA DURING THE YEAST CELL CYCLE Stephen
F. Cottrell
Department
of Biology,
The City
July
13,
Brooklyn
University
Brooklyn, Received
and Lee H. Lee
of
New York
College
of
York
New
11210
1981
SUMMARY
The nature of mitochondrial DNA replication during the synchronous cell cycle in the yeast, Saccharomyces cerevisiae has been investigated by examining the rate of labeled DNA precursor incorporation into specific segments of the mitochondrial genome at defined points during synchronous growth. The movement of label uptake from one area of the DNA to another at different times during the synchronous cell cycle indicates mitochondrial DNA replication to be a synchronous process during this time with most or all molecules at the same point in replication at any given time during the cell cycle. INTRODUCTION The synthesis throughout time,
the entire
however,
remains
of mitochondrial
the exact
unclear.
molecules
(there
at random
molecules
could
replication points
are
directions might
ndture
cell,
the
synchronously fork(s)
each molecule.
Still
population
Inc. reserved.
cycle
50 molecules initiate or,
from moving other
1350
a specific
At this
process of these per haploid
and complete alternatively,
initiation
possibilities
replicaall
in the cell
in the same direction more exotic
place
(l-3).
replication
at the same point
be envisioned.
,Z 1981 b.v .4cademic Press, of reproducrion tn any form
could
to take
cerevisiae
intracellular
4,5)
0006-291X/81/161350-07$01.00/0 Copyrighl .4ff rights
5.
continuous
the cell
replication
the replication in
of this
throughout
initiate
the yeast,
is known
to be approximately
per diploid points
in
one hand,
believed
proceeding with
cycle
On the
and 100 molecules tion
cell
DNA (mtDNA)
mtDNA
cycle
point
or
or also
with
Vol. 101, No. 4,198l
BIOCHEMICAL
In the present tion
during
study
the yeast
precursors and following
label
genome after
cycle
administration
label
incorporation
into
synchronous ous cell
This
with
in this
areas
uptake
into
procedure
specific
endonucleases
us to distinguish during
of
isolated and assessing
separated
modes of mtDNA replication
cycle
segments
mtDNA molecules
restriction
has allowed
cell
DNA
of the mitochondrial
each of the electrophoretically
and asynchronous cycle
of labeled
synchronous
different
by dissecting
of mtDNA replica-
pulses
a single
Label
was determined
each pulse
fragments.
into
period.
after
tion
during
incorporation
RESEARCH COMMUNICATIONS
the mechanism
by administering
intervals
each labeling
the mtDNA molecule
BIOPHYSICAL
we have analyzed
cell
at different
AND
restric-
between the
the
synchron-
yeast. MATERIALS
AND METHODS
A diploid strain of 2. cerevisiae (ATCC 42029) was employed in this Both cells svnchronized by the modified (6) selection and induction study. method of Williamson-and Scopes (7) as well as asynchronous control cells were separately inoculated at initial cell densities of 2 g wet weight/ml in synthetic medium (8) and grown with vigorous aeration at 25". The quality of cell synchrony was determined by monitoring cell morphology and total cell At specific periods during a single synchronous cell cycle DNA content (9). or during exponential growth in the case of the asynchronous cells 160 ml aliquots of culture were removed and incubated for 15 min periods with 6 New York). uCi/ml of (2-3H) adenine (28 Ci/mmole, Schwarz/Mann, Orangeburg, Label uptake was terminated by the addition of KCN (1 me/ml), and immediately followed by 2 washes in chilled distilled H20 containing 1 mgfml KCN. All cell pellets were stored on ice until the completion of the sampling period. After the addition of cold carrier cells to each labeled sample, mitochondria were isolated according to the snail gut enzyme procedure of Casey --et al. (10) The mitochondrial pellets were with 1 mg/ml KCN included in all solutions. After resuspended in 10 mM Tris, pH 7.4, 2 mM EDTA and lysed in 1% sarkosyl. mtDNA was isolated by preparative an initial deproteinization step (ll), the gradients fractionated and CsCl density gradient centrifugation (12), extensive the mtDNA located by determining absorbance at 260 nm. After dialysis against 10 mM Tris, 2 mM EDTA at pH 7.4 in the cold, the mtDNA was concentrated by ethanol precipitation and subjected to either Barn HI or Hpa I digestion according to the manufacturer's instructions (New England Digested DNAs were fractionated by electroBiolabs, Beverly, Mass.). phoresis (13), the gels sliced, the gel slices (1 mm thick) solubilized (14) and counted in a toluene-based scintillation fluid (12). RESULTS AND DISCUSSION By following chondrial
label
incorporation
genome at different
into
intervals
various
throughout
1351
fragments the
of the mito-
synchronous
cell
cycle
BIOCHEMICAL
Vol. 101, No. 4,198l
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
2
1
3
p 40
a
5 z 20 e 8 .c 0 01 E 3 40 8 ml 20 a 5 0
4 3
20-
f m k E2
IO8 6-
-i
4-
k P
20-Q
2 0
z
E 40 z k P 20
t
01
1
2
5
0
20 30 10 gel slice number
1.
Times of (3H)adenine pulse label administration chronous growth are designated by the arrows. typical yeast cell profiles at 3 times during growth are also given.
Fig.
2.
The percent of total counts incorporated into each restriction fragment at the 3 times of pulse label administration during synchronous growth. In this case fragments were generated by Barn HI.
at least
of label
centage nearly
same during
stages
Alternatively,
label
pulse
with
delivery
each fragment cycle
The arrows chronous
cell
the distinct
centered
the percentage
be indicative in Figure
cycle
increases
it
with
of total
mtDNA label
pulse
labeling
those
1352
the per-
be assumed
all
molecules
delivery. after
each
incorporation periods
into
during
the
mode of mtDNA replication.
times
of tritiated in total
found
remaining
could
of each pulse
of a synchronous
1 designate
with
one or a few fragments
different
when each pulse stepwise
periods
If were
any one fragment
was random
at the time
cycle
fragments
labeling
mtDNA molecules
in just
during
in the cell
into
pulse
of replication
shifting
would
different
be anticipated.
restriction
incorporated
of these
at different
all
during synDrawings of synchronous
might
points
essentially
mtDNA label
the replication
of results
at different
into
of total the
two types
delivered
to be incorporated
Both
4
Fig.
pulses
cell
3 (hours)
Time
in -S. cerevisiae
that
02
I
I
during adenine
cell
the
second
syn-
was administered.
DNA content
and the regu-
Vol. 101, No. 4,1981
lar
appearance
achieved
of new buds
during
results the
BIOCHEMICAL
all
digested lyzed
for
Barn HI,
label
detectible labeling
with
the
cycle
ration
uptake.
for
observed synchronous level
of label asynchronous,
label
administration
function which tion
is
into
time
fragment pulse
intervals
labeling
degree conditions
during
yet
another
fragments
the cell remains
during
are
clearly
compatible
of synchronous
cell
complement
with
occurs
(Figure a model
of mtDNA molecules
1353
constant
of pulse
enzyme
a
(Hpa I)
a comparable
situa-
of total
to fragment
with
label at differ-
restriction
at 3 comparable label
uptake
again
at least
some
6). in which
the synthesis
The extent
growth.
the
to be just
5) whereas
growth
during
the
during
periods
constant
size
that
from mtDNA isolated
appears
fragment
relatively
of fragment
evident
the percentage
(Figure
asynchronous
synchrony
at all
our strain,
from
cycle
is
independent
restriction
growth
to change
at each labeling
generated
uptake
with
synchronous
a function
of replicative
intracellular
Using
mtDNA
to the relatively
cells
label
during
of incorpo-
reproducible
contrast
Here
incorporation
just
sharp
growing
observed
periods
Our data
the
During
is highly
4).
5 detectible
mtDNA is
label
apparently
size.
it
of pulse
of total
as 2 other
data
each of the 3
levels
percentage
2 as well
each Barn HI fragment
(Figure
observed.
uptake
in
and ana-
incorporation
fragment
From these
logarithmically
of fragment generates
is
each of
3 periods
in label
the
growth,
into
each of the
was
2 shows
after
incorporation
during
each fragment
into
Figure
electrophoretically
an increase
3.
synchrony
synchronous
A summary of the
This
cycle.
from
separated
in Figure
in
of cell
1 and 3 show decreasing
in Figure
uptake
during
each Barn HI restriction
movement
cell
level
mtDNA was isolated
of label
fragments
reported
given
label
fragments
RESEARCH COMMUNICATIONS
examined.
administration
same period.
the data is
in which
2 exhibiting
into
a high cycles
seen to shift
whereas this
experiments
ent
is
incorporation
period
that
The level
fragment
during
label
the
fragments
cell
label
BIOPHYSICAL
cell
experiment
of pulse
with
indicate
3 synchronous
of a typical
3 periods
AND
of this
remains
of mtDNA under synchrony
unclear
within
at this
time
BIOCHEMICAL
Vol. 101, No, 4,1981
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
5 i?
frag
2
frag
3
frag
1
.5 2’
“1
s 8
40-
mI z
-
.5
fraction
.75
of cell
Label
most
into each Barn HI fragment is plotted against of an asynchronous cell generation when pulse label occurred. This figure represents a summary of 2 experiments.
not
there
into
compatible
replication
in here
at least
the probable
this
yeast
unperturbed,
reflect
exponential
scheme of cell
growth cells. into
cannot
the
true
never
drops
other
cell
this
cellular
cycle.
These
origins
of mtDNA
that
the
data
method
to induce
cell
seems unlikely parameters
used
fragments
1354
during
since
under
have been
of unperturbed,
we have measured
restriction
findings
be excluded
characteristic since
indi-
the mitochon-
mode of mtDNA replication
but
to zero
fragments
within
of multiple
of the particular
(3,6,9,17) Moreover,
of the
fragments
The observation
in yet
of replication
It
16).
numerous
different
increases
existence
growth,
synchrony
balanced growing
(15,
the result
and do not
fragments
some portions
with
are
other
sites
restriction
may be involved.
certain
may be multiple
genome during
among certain
molecules
uptake
drial
incorporation
all
movement
before
that
synchrony
if
to decrease
cates
reported
of label
incorporation
fails
1
incorporated
that
and/or
3
.75
4.
label
frag
generation
Fig.
suggests
tially
.5 of cell
Label incorporated into each Barn HI fragment is plotted against that fraction of the synchronous cell cycle when pulse introduction occurred. The beginning of each cell cycle is defined by the first appearance of new buds and the initiation of stepwise increases in total cell DNA content. This figure represents a summary of 3 independent experiments including the one presented in Fig. 2.
the amplitude
exhibit
.25 fraction
0
;a
3.
although
are
4
v-
Fig.
that fraction introduction independent
that
r z
0
cycle
1
e4
_
T.3
1
frag
20-
2
.25
G
with
alterations time
our
shown to exponenin
and these
label
Vol. 101, No, 4,198l
BIOCHEMICAL
40
30
20
AND
frag
3
frag
2
frag
1
BIOPHYSICAL
RESEARCH COMMUNtCATIONS
b ,I 5 z
-
fw
1
dfrag2
20-
10 1 0
.25
3
fraction
frag frag
.75
of cell
_
5
5 4 1
E 8 5
06
cycle
0
p
.25
.5
fraction
of cell
.75
1
generation
Fig.
5.
Label incorporated into each Hpa I fragment is plotted against that fraction of the synchronous cell cycle when pulse introduction occurred. This figure represents a summary of 2 independent experiments.
Fig.
6.
Label
incorporated into each Hpa I fragment is plotted against fraction of an asynchronous cell generation when pulse label introduction occurred. that
values
are
expressed
that
time
this
molecule
adenine
point,
cell
cycle
has been
nothing
is
because
of the
existence our
enable this
known
obtained
synchrony
label-restriction
strains
reported
the
the
exact
fragments
2. cerevisiae,
appear
have been mapped,
thus
1355
label
during
the
genomic 1lY
organism
intermediates. cycle
dissection
The
in conjunction paradigm
should
of mtDNA replication in the
present
genome of the strain
somewhat
of
essentia
in this
cell
generated
in
here.
mitochondrial
mechanism
extent
total
to occur
replicating
during
in the mitochondrial
fragments that
intact
endonuclease
to examine
The restriction
these
the yeast,
in
at
to occur
the
changes
the mode of mtDNA replication
of replicative
been mapped
the
concerning
from
to isolate
pulse
nor
known
influences
the data
of information
incorporation
heterogeneity
genome reported
affect
inability
yeast.
Moreover,
would
about
us to begin
not yet
other
(3,19)
mtDNA label
clearly
each fragment
the mitochondrial
the bulk
organization
see 18) which
into
into
of total
the base sequence
review
incorporation
Although
with
neither (for
incorporation yeast
as a percentage
different we are not
from yet
those
study
in have
employed. generated
in a position
in to
Vol. 101, No. 4,198l
trace
the
exact
mtDNA replication
8lOCHEMlCAL
movement during
AND
of label the yeast
BIOPHYSICAL
incorporation cell
RESEARCH COMMUNICATIONS
and hence
the mechanism
of
cycle.
ACKNOWLEDGMENTS This study was supported by Public Health Service grant GM25901 from the National Institute of General Medical Sciences and a PSC-CUNY grant from The City University of New York. REFERENCES 1. 2. 3. 4. 5.
Williamson, D.H. and Moustacchi, E. (1971) Biochem. Biophys. Res. Commun. 42, 195-201. Sena, E.P., Welch, J.W., Halvorson, H.O. and Fogel, S. (1975) J. Bacterial. 123, 497-504. Cottrell, S.F. (1981) Exp. Cell Res. 132, 89-98. Williamson, D.H. (1970) in Control of Organelle Development (Miller, P.L. ed.) Cambrize University Press, Cambridge, pp. 247-276. Grimes, G.W., Mahler, H.R. and Perlman, P.S. (1974) J. Cell Biol. 61, 565-574.
6.
7. 8. 9.
10. 11. 12.
Cottrell, S.F. and Avers, C.J. (1971) in Autonomy and Biogenesis of Mitochondria and Chloroplasts (BoardmanTN.K., Linnane, A.W. and Smillie, R.M. eds.) North-Holland, Amsterdam, pp. 481-491. Williamson, D.H. and Scopes, A.W. (1962) Nature 193, 256-257. Rubin, B.Y. and Blamire, J. (1977) Molec. gen. Genet. 156, 41-47. Cottrell, S.F. and Avers, C.J. (1970) Biochem. Biophys. Res. Commun. 38, 973-980. Casey, J., Hsu, H.J., Rabinowitz, M., Getz, G.S. and Fukuhara, H. (1974) J. Mol. Biol. 88, 717-733. Marmur, J. (1961) J. Mol. Biol. 3, 208-218. Cottrell, S.F., Rabinowitz, M. and Getz, G.S. (1973) Biochemistry 12,
4374-4378.
17.
McCarron, R.J., Cabera, C.V., Esteban, M., McAllister, W.T. and Hdowezak, J.A. (1978) Virology 86, 88-101. Caplen, H.S. and Blamire, J. (1980) Cytobios 29, 115-128. Blanc, H. and Dujon, B. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 3942-3946. Goursot, R., de Zamaroczy, M., Baldacci, G. and Bernardi, G. (1980) Current Genet. 1, 173-176. Cottrell, S.F., Rabinowitz, M. and Getz, G.S. (1975) J. Biol. Chem.
18. 19.
Borst, Wells,
13. 14. 15. 16.
250,
4087-4094.
P. and Grivell, L.A. (1978) J.R. (1974) Exp. Cell Res.
1356
Cell 15, 705-723. 85, 278-286.
Vol. 101, No. 4,19Bl August
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 1350-1356
31, 1981
EVIDENCE FOR THE SYNCHRONOUS REPLICATION
OF MITOCHONDRIAL
DNA DURING THE YEAST CELL CYCLE Stephen
F. Cottrell
Department
of Biology,
The City
July
13,
Brooklyn
University
Brooklyn, Received
and Lee H. Lee
of
New York
College
of
York
New
11210
1981
SUMMARY
The nature of mitochondrial DNA replication during the synchronous cell cycle in the yeast, Saccharomyces cerevisiae has been investigated by examining the rate of labeled DNA precursor incorporation into specific segments of the mitochondrial genome at defined points during synchronous growth. The movement of label uptake from one area of the DNA to another at different times during the synchronous cell cycle indicates mitochondrial DNA replication to be a synchronous process during this time with most or all molecules at the same point in replication at any given time during the cell cycle. INTRODUCTION The synthesis throughout time,
the entire
however,
remains
of mitochondrial
the exact
unclear.
molecules
(there
at random
molecules
could
replication points
are
directions might
ndture
cell,
the
synchronously fork(s)
each molecule.
Still
population
Inc. reserved.
cycle
50 molecules initiate or,
from moving other
1350
a specific
At this
process of these per haploid
and complete alternatively,
initiation
possibilities
replicaall
in the cell
in the same direction more exotic
place
(l-3).
replication
at the same point
be envisioned.
,Z 1981 b.v .4cademic Press, of reproducrion tn any form
could
to take
cerevisiae
intracellular
4,5)
0006-291X/81/161350-07$01.00/0 Copyrighl .4ff rights
5.
continuous
the cell
replication
the replication in
of this
throughout
initiate
the yeast,
is known
to be approximately
per diploid points
in
one hand,
believed
proceeding with
cycle
On the
and 100 molecules tion
cell
DNA (mtDNA)
mtDNA
cycle
point
or
or also
with
Vol. 101, No. 4,198l
BIOCHEMICAL
In the present tion
during
study
the yeast
precursors and following
label
genome after
cycle
administration
label
incorporation
into
synchronous ous cell
This
with
in this
areas
uptake
into
procedure
specific
endonucleases
us to distinguish during
of
isolated and assessing
separated
modes of mtDNA replication
cycle
segments
mtDNA molecules
restriction
has allowed
cell
DNA
of the mitochondrial
each of the electrophoretically
and asynchronous cycle
of labeled
synchronous
different
by dissecting
of mtDNA replica-
pulses
a single
Label
was determined
each pulse
fragments.
into
period.
after
tion
during
incorporation
RESEARCH COMMUNICATIONS
the mechanism
by administering
intervals
each labeling
the mtDNA molecule
BIOPHYSICAL
we have analyzed
cell
at different
AND
restric-
between the
the
synchron-
yeast. MATERIALS
AND METHODS
A diploid strain of 2. cerevisiae (ATCC 42029) was employed in this Both cells svnchronized by the modified (6) selection and induction study. method of Williamson-and Scopes (7) as well as asynchronous control cells were separately inoculated at initial cell densities of 2 g wet weight/ml in synthetic medium (8) and grown with vigorous aeration at 25". The quality of cell synchrony was determined by monitoring cell morphology and total cell At specific periods during a single synchronous cell cycle DNA content (9). or during exponential growth in the case of the asynchronous cells 160 ml aliquots of culture were removed and incubated for 15 min periods with 6 New York). uCi/ml of (2-3H) adenine (28 Ci/mmole, Schwarz/Mann, Orangeburg, Label uptake was terminated by the addition of KCN (1 me/ml), and immediately followed by 2 washes in chilled distilled H20 containing 1 mgfml KCN. All cell pellets were stored on ice until the completion of the sampling period. After the addition of cold carrier cells to each labeled sample, mitochondria were isolated according to the snail gut enzyme procedure of Casey --et al. (10) The mitochondrial pellets were with 1 mg/ml KCN included in all solutions. After resuspended in 10 mM Tris, pH 7.4, 2 mM EDTA and lysed in 1% sarkosyl. mtDNA was isolated by preparative an initial deproteinization step (ll), the gradients fractionated and CsCl density gradient centrifugation (12), extensive the mtDNA located by determining absorbance at 260 nm. After dialysis against 10 mM Tris, 2 mM EDTA at pH 7.4 in the cold, the mtDNA was concentrated by ethanol precipitation and subjected to either Barn HI or Hpa I digestion according to the manufacturer's instructions (New England Digested DNAs were fractionated by electroBiolabs, Beverly, Mass.). phoresis (13), the gels sliced, the gel slices (1 mm thick) solubilized (14) and counted in a toluene-based scintillation fluid (12). RESULTS AND DISCUSSION By following chondrial
label
incorporation
genome at different
into
intervals
various
throughout
1351
fragments the
of the mito-
synchronous
cell
cycle
BIOCHEMICAL
Vol. 101, No. 4,198l
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
2
1
3
p 40
a
5 z 20 e 8 .c 0 01 E 3 40 8 ml 20 a 5 0
4 3
20-
f m k E2
IO8 6-
-i
4-
k P
20-Q
2 0
z
E 40 z k P 20
t
01
1
2
5
0
20 30 10 gel slice number
1.
Times of (3H)adenine pulse label administration chronous growth are designated by the arrows. typical yeast cell profiles at 3 times during growth are also given.
Fig.
2.
The percent of total counts incorporated into each restriction fragment at the 3 times of pulse label administration during synchronous growth. In this case fragments were generated by Barn HI.
at least
of label
centage nearly
same during
stages
Alternatively,
label
pulse
with
delivery
each fragment cycle
The arrows chronous
cell
the distinct
centered
the percentage
be indicative in Figure
cycle
increases
it
with
of total
mtDNA label
pulse
labeling
those
1352
the per-
be assumed
all
molecules
delivery. after
each
incorporation periods
into
during
the
mode of mtDNA replication.
times
of tritiated in total
found
remaining
could
of each pulse
of a synchronous
1 designate
with
one or a few fragments
different
when each pulse stepwise
periods
If were
any one fragment
was random
at the time
cycle
fragments
labeling
mtDNA molecules
in just
during
in the cell
into
pulse
of replication
shifting
would
different
be anticipated.
restriction
incorporated
of these
at different
all
during synDrawings of synchronous
might
points
essentially
mtDNA label
the replication
of results
at different
into
of total the
two types
delivered
to be incorporated
Both
4
Fig.
pulses
cell
3 (hours)
Time
in -S. cerevisiae
that
02
I
I
during adenine
cell
the
second
syn-
was administered.
DNA content
and the regu-
Vol. 101, No. 4,1981
lar
appearance
achieved
of new buds
during
results the
BIOCHEMICAL
all
digested lyzed
for
Barn HI,
label
detectible labeling
with
the
cycle
ration
uptake.
for
observed synchronous level
of label asynchronous,
label
administration
function which tion
is
into
time
fragment pulse
intervals
labeling
degree conditions
during
yet
another
fragments
the cell remains
during
are
clearly
compatible
of synchronous
cell
complement
with
occurs
(Figure a model
of mtDNA molecules
1353
constant
of pulse
enzyme
a
(Hpa I)
a comparable
situa-
of total
to fragment
with
label at differ-
restriction
at 3 comparable label
uptake
again
at least
some
6). in which
the synthesis
The extent
growth.
the
to be just
5) whereas
growth
during
the
during
periods
constant
size
that
from mtDNA isolated
appears
fragment
relatively
of fragment
evident
the percentage
(Figure
asynchronous
synchrony
at all
our strain,
from
cycle
is
independent
restriction
growth
to change
at each labeling
generated
uptake
with
synchronous
a function
of replicative
intracellular
Using
mtDNA
to the relatively
cells
label
during
of incorpo-
reproducible
contrast
Here
incorporation
just
sharp
growing
observed
periods
Our data
the
During
is highly
4).
5 detectible
mtDNA is
label
apparently
size.
it
of pulse
of total
as 2 other
data
each of the 3
levels
percentage
2 as well
each Barn HI fragment
(Figure
observed.
uptake
in
and ana-
incorporation
fragment
From these
logarithmically
of fragment generates
is
each of
3 periods
in label
the
growth,
into
each of the
was
2 shows
after
incorporation
during
each fragment
into
Figure
electrophoretically
an increase
3.
synchrony
synchronous
A summary of the
This
cycle.
from
separated
in Figure
in
of cell
1 and 3 show decreasing
in Figure
uptake
during
each Barn HI restriction
movement
cell
level
mtDNA was isolated
of label
fragments
reported
given
label
fragments
RESEARCH COMMUNICATIONS
examined.
administration
same period.
the data is
in which
2 exhibiting
into
a high cycles
seen to shift
whereas this
experiments
ent
is
incorporation
period
that
The level
fragment
during
label
the
fragments
cell
label
BIOPHYSICAL
cell
experiment
of pulse
with
indicate
3 synchronous
of a typical
3 periods
AND
of this
remains
of mtDNA under synchrony
unclear
within
at this
time
BIOCHEMICAL
Vol. 101, No, 4,1981
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
5 i?
frag
2
frag
3
frag
1
.5 2’
“1
s 8
40-
mI z
-
.5
fraction
.75
of cell
Label
most
into each Barn HI fragment is plotted against of an asynchronous cell generation when pulse label occurred. This figure represents a summary of 2 experiments.
not
there
into
compatible
replication
in here
at least
the probable
this
yeast
unperturbed,
reflect
exponential
scheme of cell
growth cells. into
cannot
the
true
never
drops
other
cell
this
cellular
cycle.
These
origins
of mtDNA
that
the
data
method
to induce
cell
seems unlikely parameters
used
fragments
1354
during
since
under
have been
of unperturbed,
we have measured
restriction
findings
be excluded
characteristic since
indi-
the mitochon-
mode of mtDNA replication
but
to zero
fragments
within
of multiple
of the particular
(3,6,9,17) Moreover,
of the
fragments
The observation
in yet
of replication
It
16).
numerous
different
increases
existence
growth,
synchrony
balanced growing
(15,
the result
and do not
fragments
some portions
with
are
other
sites
restriction
may be involved.
certain
may be multiple
genome during
among certain
molecules
uptake
drial
incorporation
all
movement
before
that
synchrony
if
to decrease
cates
reported
of label
incorporation
fails
1
incorporated
that
and/or
3
.75
4.
label
frag
generation
Fig.
suggests
tially
.5 of cell
Label incorporated into each Barn HI fragment is plotted against that fraction of the synchronous cell cycle when pulse introduction occurred. The beginning of each cell cycle is defined by the first appearance of new buds and the initiation of stepwise increases in total cell DNA content. This figure represents a summary of 3 independent experiments including the one presented in Fig. 2.
the amplitude
exhibit
.25 fraction
0
;a
3.
although
are
4
v-
Fig.
that fraction introduction independent
that
r z
0
cycle
1
e4
_
T.3
1
frag
20-
2
.25
G
with
alterations time
our
shown to exponenin
and these
label
Vol. 101, No, 4,198l
BIOCHEMICAL
40
30
20
AND
frag
3
frag
2
frag
1
BIOPHYSICAL
RESEARCH COMMUNtCATIONS
b ,I 5 z
-
fw
1
dfrag2
20-
10 1 0
.25
3
fraction
frag frag
.75
of cell
_
5
5 4 1
E 8 5
06
cycle
0
p
.25
.5
fraction
of cell
.75
1
generation
Fig.
5.
Label incorporated into each Hpa I fragment is plotted against that fraction of the synchronous cell cycle when pulse introduction occurred. This figure represents a summary of 2 independent experiments.
Fig.
6.
Label
incorporated into each Hpa I fragment is plotted against fraction of an asynchronous cell generation when pulse label introduction occurred. that
values
are
expressed
that
time
this
molecule
adenine
point,
cell
cycle
has been
nothing
is
because
of the
existence our
enable this
known
obtained
synchrony
label-restriction
strains
reported
the
the
exact
fragments
2. cerevisiae,
appear
have been mapped,
thus
1355
label
during
the
genomic 1lY
organism
intermediates. cycle
dissection
The
in conjunction paradigm
should
of mtDNA replication in the
present
genome of the strain
somewhat
of
essentia
in this
cell
generated
in
here.
mitochondrial
mechanism
extent
total
to occur
replicating
during
in the mitochondrial
fragments that
intact
endonuclease
to examine
The restriction
these
the yeast,
in
at
to occur
the
changes
the mode of mtDNA replication
of replicative
been mapped
the
concerning
from
to isolate
pulse
nor
known
influences
the data
of information
incorporation
heterogeneity
genome reported
affect
inability
yeast.
Moreover,
would
about
us to begin
not yet
other
(3,19)
mtDNA label
clearly
each fragment
the mitochondrial
the bulk
organization
see 18) which
into
into
of total
the base sequence
review
incorporation
Although
with
neither (for
incorporation yeast
as a percentage
different we are not
from yet
those
study
in have
employed. generated
in a position
in to
Vol. 101, No. 4,198l
trace
the
exact
mtDNA replication
8lOCHEMlCAL
movement during
AND
of label the yeast
BIOPHYSICAL
incorporation cell
RESEARCH COMMUNICATIONS
and hence
the mechanism
of
cycle.
ACKNOWLEDGMENTS This study was supported by Public Health Service grant GM25901 from the National Institute of General Medical Sciences and a PSC-CUNY grant from The City University of New York. REFERENCES 1. 2. 3. 4. 5.
Williamson, D.H. and Moustacchi, E. (1971) Biochem. Biophys. Res. Commun. 42, 195-201. Sena, E.P., Welch, J.W., Halvorson, H.O. and Fogel, S. (1975) J. Bacterial. 123, 497-504. Cottrell, S.F. (1981) Exp. Cell Res. 132, 89-98. Williamson, D.H. (1970) in Control of Organelle Development (Miller, P.L. ed.) Cambrize University Press, Cambridge, pp. 247-276. Grimes, G.W., Mahler, H.R. and Perlman, P.S. (1974) J. Cell Biol. 61, 565-574.
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Cottrell, S.F. and Avers, C.J. (1971) in Autonomy and Biogenesis of Mitochondria and Chloroplasts (BoardmanTN.K., Linnane, A.W. and Smillie, R.M. eds.) North-Holland, Amsterdam, pp. 481-491. Williamson, D.H. and Scopes, A.W. (1962) Nature 193, 256-257. Rubin, B.Y. and Blamire, J. (1977) Molec. gen. Genet. 156, 41-47. Cottrell, S.F. and Avers, C.J. (1970) Biochem. Biophys. Res. Commun. 38, 973-980. Casey, J., Hsu, H.J., Rabinowitz, M., Getz, G.S. and Fukuhara, H. (1974) J. Mol. Biol. 88, 717-733. Marmur, J. (1961) J. Mol. Biol. 3, 208-218. Cottrell, S.F., Rabinowitz, M. and Getz, G.S. (1973) Biochemistry 12,
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