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Deoxyribonucleic acid associated with yeast mitochondria
Vol.
15, No.
BIOCHEMICAL
2, 1964
DEOXYRIBONUCLEIC
ACID
G. Institut
January
Received
DNA
ASSOCIATED
SCHATZ, E. fur Biochemie,
considered
found
nuclear
BIOPHYSICAL
RESEARCH
WITH
HASLBRUNNER University
YEAST
and H. of Vienna,
COMMUNICATIONS
MITOCHONDRIA TUPPY Austria.
27, 1964
is generally
sometimes
AND
material
to be confined
in other
cell
(Allfrey
1959).
DNA
occurring
in the
somes
(Clark
and
1963)
is well
documented
cause
in these
DNA
nucleus.
usually
presence
of the
1960), but
are
The
cytoplasm
Wallace
cases
fractions
to the
attributed
of significant
amphibian
and
in the
is regarded
chloroplasts
with
amounts
of DNA
to contamination
by
amounts
&cyte
rather
is associated
Small
(Stich
1962),
the
of plant
cells
(Chun
as an exception
cellular
of extranuclear
than
components
kinetoet al.
as a rule,
absent
from
behigher
cells. This
paper
yeast,
purified
DNA.
The
presents
evidence
by flotation
amount
ribonucleotide
found
that
in density is far
component
preparations
gradients,
in excess
(Appleby
contain
of that
and
of mitochondria a significant
accounted
Morton,
from
1960)
for
by
baker’s
quantity the
of
polydeoxy-
of mitochondrial
cytochrome
b2. Since
the
those
of mammals,
cluding the
possibility,
mitochondrion
that
nature
the
is unknown.
factors The
of DNA
DNA
function
genetic
an organelle
occurrence
extranuclear
Mitochondrial chromosomal
represents
in the (Ephrussi
presence
is much cell
and
Hottinguer
of DNA
in yeast
more
yeast
present
in yeast
1951), mitochondria
cells,
mitochondria
common
is in part
in most
that
in-
suggests
hithertosuspected
controlled whose
by extraexact
is thus
chemical of special
interest.
Experimental (Schatz
: The wild type strain W of Saccharomyces
1963).
The concentration
yeast homogenates et al.
1963).
contained tion,
except
of glucose
and of the crude mitochondrial that the medium
0.25 M mannitol,
a linear continuous
employed
20 mM tris-buffer sucrose gradient
cerevisiae
in the growth
(volume
fractions
medium
was grown as described
was the same as in earlier
for the homogenization pH 7.4 and 1 mM EDTA. 25 ml: 0.98-l.
127
previously
was 0.8 %. The preparation
and washing For density
work
of the (Schatz
procedures gradient
66 M sucrose; additions
flota-
as above)
Vol.
15, No.
2, 1964
was constructed fraction
BIOCHEMICAL
AND
ultracentrifuge.
If sedimentation
involving
through
triiodo-benzoate.
flotation
an X-ray
the gradient
follows
: The crude mitochondrial
ficient
“Urografin”
fraction
as described
above.
After
from the top of the gradient
diluted
with homogenization
and an aliquot
activity
and acid-soluble
extracted
with 0.5 M perchloric followed
obtained
with this procedure
Button (1956). with pancreatic containing
within
DNase (Fluka)
150 pg/ml
pure cytochrome protein
pressed as pmoles : An
examined.
and
the
This
lack
the
removal
enzymic
of information
purification
ally
with
high
density
ever,
it was
come
these
initially
+) We are greatly
density Thus,
the preparation
indebted
c reductase
from as the
nucleus
and
by enzymatic
gradient
examined equilibrium
equilibrium of pure
thus
far
yeast
to Dr. Klose (Fa. Schering.
substance. 128
Vienna)
fracproperties
assessment
In view
not
known.
(Allfrey
for of their
of the
exception-
1959),
how-
might
in sucrose
mitochondria.
the
are
centrifugation
centrifugation
of 3.0 ml at 20’.
centrifugation
as the
tests.
are ex-
sedimentation
of differential
of
and that of
activities
mitochondrial
its fragments
as well
was
number
requires
the
pH 6.6
activity
activity
DNA
fragments
buffer
Specific
of mitochondrial
fractions
nuclei
1964).
and
Digestion
of the turnover
in a total volume
adoption
The results
of Dische (1930)
c reductase
for measurements
problems,
the
the DNA
1952).
per mg protein
yeast
material
isolated
that
difficulties. for
difficult
mitochondrial
of all
(Ceriotti
was
lipid was also
Finally,
error was always observed.
and Klima
nuclear
of the
nuclear
hoped,
tried
poses
precluded
of the
contamination
and
complement
In some experiments
L-lactate-cytochrome
(Schatz
demonstration
task
of the particles
by use of the methods
(1961)
at 30 000
c reductase
out at 26’ for 2 hours in 0.02 M acetate
pet minute
and
in homogenization
The remainder
at 0’.
suf-
They were then
succinate-cytochrome
of succinate-cytochrome
of nuclei
This
were resuspended
experimental
elsewhere
reduced
unambiguous
quantitative tions
of acceptor
syringe.
3 : 1 at room temperature.
and 0.05 M MgCl2.
as described
1.20 g. cme3)
were washed twice by centrifuging
checked of
containing
of 3.0 ml each were collected
designed
by the indole method
chosen by Nygaard
b2. The determination
were performed
Results
rhe limits
medium
4.5 ml of this heavy
(1.10
fractions
acid in 35 70 ethanol
was carried
enzyme
assayed under the conditions
gradient
compounds,
were frequently
Agreement
were conducted
to 1.25 g. cmu3.
The pellets
was determined
as above.
as
for the assay of protein.
-ether
and centrifuged
by Fa. Schering)?
centrifugation,
by ethanol
of these washed particles
gradient
6-
” Urografin’
deoxyribose-containing
4.5 ml of a mitochondrial
in homogenization
and the particles
was withdrawn
with ethanol,
content
gradient
medium
of a crude mitochondrial
(N, N’-diacetyl-3,5-diamino-2.4,
with the help of a specially
in the Spinco no. 30 rotor.
medium
washed twice
was dispersed of the suspension
by 25 ml of a linear
starting
rpm for 60 minutes
of * Urografin”
agent manufactured
to adjust the density
suspension were overlayered
was desired.
on top of the preformed
in gradients
contrasting
COMMUNICATIONS
at 25 000 rpm for 5 hours in the IOIOI SW 25.1 of the Spinco
SusPeosion in 0.5 M suctose were layered
centrifuged
RESEARCH
(Bock and Ling 1954) on top of 4.5 ml of a suspension
in 1.8 M sucrose and centrifuged
Experiments
BIOPHYSICAL
The
for the generous
over-
gradients resolution
supply with this
was of
BIOCHEMICAL
Vol. 15, No. 2, 1964
subcellular
components
satisfactory
for
the
a well-defined within
mitochondria
were
was
nuclear
fragments
gradients,
other
“Urografin”
types
obtained
by floating
schematically
depicted
which
also
crude
mitochondrial
of this
appeared
experiments,
protein
(table two
to DNA
well
content
widely
peaks
with
particles
protein.
and
to DNA
other
tions and drial
other
compounds (table
is not Morton
I).
not The
accounted 1960)
concentration
for
of mitochondrial of cytochrome
detergent
c reductase activation.
(The
analyzed
of the the
the
was due
mitochondria.
nuclear
matter)
from
20 - 250&mg
with
the
peak
The varied of
of mitochondrial
digestion
with
pancreatic
proved
to be due DNase,
rendered
acid-soluble.
In addition
3.5-4.8
rJg/mg
of deoxyribose-
by acid, found
in the
cytochrome
b2.
in the
of activation
129
mono-
purified
Table
mitochondrial
from
II gives the
purified by the
frac-
(Appleby the
specific mitochondrial detergent
to
or oligonu-
component
b2 as calculated measured
protein
presumably,
polydeoxyribonucleotide
extent
for
experimental
Upon
of DNA
mg of
peaks
thus
precipitable
by the
were
and
contained
particles
per
activity
was
of the
DNA
under
B,
mitochondria.
c reductase
DNA
amount
the
from
exactly
in band
microscope,
One
bands
are
activity
floated
ranged
The
c reductase
including
and
trials,
was found
4.3~~19
3).
not
sedimenting
of gradient
gradient
separated
coincided
type
the
work.
of yeast
and
the
of sucrose
present
protein
(figure
(probably
mitochondria.
mitochondria
L-lactate-cytochrome after
of DNA
mitochondrial
the
electron
the
through
numerous
in this
of the
were
clearly
material to the
with
purified
containing cleotides
thus
contained
shortcomings
for
1.1
fractions
succinate-cytochrome
associated
the
dense
peak
up to 75 % of this DNA,
were
oneexperiment
The
protein
and
between
which
large
to slowly
population
found
relatively
Essentially
After
of the
in the
were
between
which
due
suited
homogeneous
different
separated
of this
from
the
separation
mitochondrial.
the
formed
to be diffusely
of sedimentation)
bulk
If viewed
found
band
succinate-cytochrome
contained
When
employed
The
to be un-
mitochondria
The
in the
fractions
4.
as a fairly
associated
conditions DNA
I).
in DNA.
investigated.
to be well
of the
they
no clear
to avoid
mitochondrial
most
was
complications
were
found
fraction.
In five
DNA,
In an attempt
in figure
contained
band
2).
crude
was
(instead
to avoid
were
DNA
as truly
in order
of gradients
gradients
-3,
found
if flotation
(figure
the
rich
be regarded
proved
Whereas
l).There
of protein)
obtained,
employed
work.
particles
not
however,
I. 18 g.cm
gradient(figure
thus
procedure,
present of
(20-4Oug/mg
could
gradient
of the
contaminating
of DNA
results
by this
at a density
the
and
mitochondria same
purpose
band
distributed
amounts
effected
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
mitochonactivity
of fraction
as we,lI
as
Vol. 15, No. 2, 1964
BIOCHEMICAL
AND BIOPHYSICAL
‘B 2.0 -
-10 2.0 -
1.13
1.16
l.lq 1-b
1.13
RESEARCH COMMUNICATIONS
c
%j.3
““.. .
1.16
1.1-l I.22
1.10
143
Cl6
I.19
Figures 1 ~3 : Distribution of succinate-cytochrome c reductase activity (. . . . ), protein (- -- - -) and DNA (. -. -. -) after subjecting crude preparations of yeast mitochondtia to sedimentation in a sucrose gradient (fig. 1). flotation in a sucrose gradient (fig-S) and flotation in a “Urografin” gradient (fig. 3). Abscissa : density (g. cms3). Ordinate A : mg protein/ml fraction and A E550 pet minute per 0.4 ml fraction: ordinate B : fig DNA/O. 1 ml fraction: ordinate C : pg DNA/ml fraction.
A 6
Figure 4 : Banding of a crude mitochondrial fraction from yeast in a ” Urogtafin” gradient. A (1.12 g. cme3) : Mitochondtial precursors (Schatz 1963) B (1.15 g. cmm3) : Mitochondria C (1.19 g.cme3) : Double Membranes rich in ATPase (Schatz et al. 1963) D () 1.25 g. cmm3) : Debris including nuclear material. -
c
H
0
Fig.4 Deoxyribose compounds not precipitable by acid ++I ,ug / mg protein Experiment Experiment Experiment Experiment Experiment
Table
1 2 3 4 4a 5 5a
3.48 4.25 4.83
Deoxyribose compounds precipitable by acid (DNA) ,ug / mg protein 1. 55 1.18 1.06 1.51 3.60 4.30 4.30
5) +) &) &) f)
I : Deoxytibose compounds in purified yeast mirochondria. ++) Calculated as nucleotides f ) Particles incubated at 26O for 30 min at pH 6.6 after acid precipitation + ) Particles incubated at 26’ for 2 hours at pH 6.6 after acid precipitation & ) Lipid extracted as described under Experimental.
1.30
BIOCHEMICAL
Vol. 15, No. 2, 1964
Enzyme
tested
Specific without
L-lactatecytochrome reductase
c
succinatecytochrome reductase
c
Table
the
activity
detergent
activity
0.054
0.12
0.39
nil
of succinate-cytochrome
into
cleotide
account,
(Appleby
DNA
found
the
of the
pellet
found
in the
Discussion
for
2 hours
of DNA
from
supernatants
purified
mitochondrial
that
under
wos
assembly yeast
are
and
The the
chemical
the
1963).
information
mitochondrial
mitochondria amounts
of nucleic
the function
themselves. of DNA
flotation.
The the
This
associated material
deoxyribose
acid of the
possibility
was
in the
the
to arise
The the
and
but
as the that
primary
these
paper
reports
of small,
content
was (assayed
131
identified with
available
1955;
DNA
in question
and
Simpson
detection
in
(Ephrussi
is unknown,
of DNA
mitochondria
present
of mitochondria factors
from
organized
be extrochromosomal
yeast
DNA
previous
might
with
rotor).
the
appear
investigated
the
parti-
no.40
1963).
(Rout role
10 to 40,
that
by
function
factors
I n view
found
controlling
genetic
of
contaminant.
Schatz
and
of these
of
unlikely
mitochondria
factors
amounts
(Spinco
prompted
1962;
Structure
nature
involvement
Marcovich
of genetic
precipitability,
about
by extrachromosomol
governed
suggests
gradient
more
et al,
in part 1951).
regulating
ficant
to learn
it very
yeast
structure.
Moustocchi carrier
(Linnane
rpm
was an adsorbed
conditions
the
b2. was
at 40 000
were
comparison).
by a factor
homogenates
here
of mitochondrial
Hottinguer evidence
certain
that
cytochrome
made
described
precursors
undertaken
be calculated,
fractions
investigations
for
c
% of polvdeoxyribonu-
exceed,
centrifugation the
included
5-6
by mitochondrial
present
and of succinate-cytochrome
are
preparations
yeast
non-mitochondrial work
it con
in the
: The
observations,
c reductase
b2 contains
1960)
contributed
upon
absence
cytochrome
Morton
DNA
0.11
c reductase
mitochondrial
of DNA
All culate
and
in our
amounts
The
that
Calculated concentration of cytochrome b2 (% of mitochondrial protein)
with 0.1 % Triton X 100
II : Specific activities of L-lactate-cytochrome reductase in purified yeast mitochondria.
Taking
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
factors
present
within
but
signi-
purified
by density
as DNA
by its ocid-
different
methods)
and
its
Vol.
15, No.
2, 1964
digestion
BIOCHEMICAL
by pancreatic
mitochondrial
fraction
excluded,
since
from
the
drial
marker
bulk
regarded
results
of the
obtained
presence pounds
that
of DNA
here.
The not
the
might
of appreciable
amounts
phenomenon.
Acknowledgements Public Health the preparation
This
this
that
the
the
occurrence
have
been
found’in
in the
of small
amounts
possibility
is being
: This work was Service. The authors of the manuscript.
of the
whole
band
well
peak
of the
other
cells
ratio
possibility from cannot
virtually
to the
controlling
Moreover,
the
mitochondria of extranuclear
com-
metabolism all
of yeast DNA
plant may
the
support
deoxyribose-containing of DNA
the
to corroborate
factors DNA.
to be
of mitochon-
lends
extrachromosomal
be
mitochon-
but
in order
in mitochondria
can
of DNA
base
the
separated
unlikely,
the
with
material
absence
be mitochondrial
suggests
associated
The
comparing
of acid-soluble,
of DNA
only
is considered
of DNA
in yeast
occurrence
Because
from
function
the
c reductase.
extracted detection
DNA
COMMUNICATIONS
by nuclear
with
at present
it,
detection
the
in a discrete
coincided
homogenates
We are
Mitochondria The
to occur
artefacts.
that
in mitochondria
cells.
found
proving
organelles.
that
RESEARCH
to contamination
exactly
yeast
out.
though
mitochondrial
possibility
be due
of adsorption
with
BIOPHYSICAL
succinate-cytochrome
ruled
hypothesis,
The
was
and
enzyme,
portion
DNA
DNA
of DNA
be definitely drial
might
this
is that
soluble
DNase.
AND
in these and
thus
is a rather
animal indicate, general
investigoted.
supported by grant GM 11225-01 are indebted to Dr.R.Wolfe for
of the his help
Allfrey,V.,
in : “The Cell” (Brachet, J. and Mirsky,A., ed.). Academic 1959, vol. I, p. 193. Appleby, C.A. and Morton,R. K., Biochem. J. 75, 258 (1960). Bock,R.M. and Ling.N.S., Analyt.Chem.26, 1543 (1954). Burton,K., Biochem .J. 62, 315 (1956). Ceriotti,G., J .Biol. Chem. 198, 297 (1952). Chun,E.H.L., Vaughan,M.H. and Rich.A., J.Mol.Biol.7, 130(1963). Clark,T.B. and Wallace,F.G., J.Protozool. _7, 115 (196@. Dische,Z., Z.Mikrochem. 2, 26 (1930). Ephrussi, B. and Hottinguer, H., Cold String Harbor Sympos.Quant.Biol.
U.S. in
Press
3,
(1951). Linnane,A.W., Vitols,E. and Nowland,P.G., J.Cell Biol. 2, 345 (1962). Moustacchi,E. and Marcovich,H., Compt. rend. 256, 5646 (1963). Enzymes” (Falk,J.c Lemberg.R. and Morton,R.K., Nygaard,A.P., in : “Hematin ed .) Pergamon Press 1961, p. 547. Raut,C.W. and Simpson,W.C., Arch.Biochem.Biophys. 57, 218 (1955). Schatz,G, , Biochem. Biophys.Res. Communic. 2, 448 (1%3). Schatz,G., Tuppy,H. and Klima, J., Z. Naturforsch. g, 145 (1963). Schatz,G. and Klima,J., Biochim.Biophys.Acta, in press. Stich,H.F., Exp.Cell Res. 2, 136 (1962).
132
75
15, No.
BIOCHEMICAL
2, 1964
DEOXYRIBONUCLEIC
ACID
G. Institut
January
Received
DNA
ASSOCIATED
SCHATZ, E. fur Biochemie,
considered
found
nuclear
BIOPHYSICAL
RESEARCH
WITH
HASLBRUNNER University
YEAST
and H. of Vienna,
COMMUNICATIONS
MITOCHONDRIA TUPPY Austria.
27, 1964
is generally
sometimes
AND
material
to be confined
in other
cell
(Allfrey
1959).
DNA
occurring
in the
somes
(Clark
and
1963)
is well
documented
cause
in these
DNA
nucleus.
usually
presence
of the
1960), but
are
The
cytoplasm
Wallace
cases
fractions
to the
attributed
of significant
amphibian
and
in the
is regarded
chloroplasts
with
amounts
of DNA
to contamination
by
amounts
&cyte
rather
is associated
Small
(Stich
1962),
the
of plant
cells
(Chun
as an exception
cellular
of extranuclear
than
components
kinetoet al.
as a rule,
absent
from
behigher
cells. This
paper
yeast,
purified
DNA.
The
presents
evidence
by flotation
amount
ribonucleotide
found
that
in density is far
component
preparations
gradients,
in excess
(Appleby
contain
of that
and
of mitochondria a significant
accounted
Morton,
from
1960)
for
by
baker’s
quantity the
of
polydeoxy-
of mitochondrial
cytochrome
b2. Since
the
those
of mammals,
cluding the
possibility,
mitochondrion
that
nature
the
is unknown.
factors The
of DNA
DNA
function
genetic
an organelle
occurrence
extranuclear
Mitochondrial chromosomal
represents
in the (Ephrussi
presence
is much cell
and
Hottinguer
of DNA
in yeast
more
yeast
present
in yeast
1951), mitochondria
cells,
mitochondria
common
is in part
in most
that
in-
suggests
hithertosuspected
controlled whose
by extraexact
is thus
chemical of special
interest.
Experimental (Schatz
: The wild type strain W of Saccharomyces
1963).
The concentration
yeast homogenates et al.
1963).
contained tion,
except
of glucose
and of the crude mitochondrial that the medium
0.25 M mannitol,
a linear continuous
employed
20 mM tris-buffer sucrose gradient
cerevisiae
in the growth
(volume
fractions
medium
was grown as described
was the same as in earlier
for the homogenization pH 7.4 and 1 mM EDTA. 25 ml: 0.98-l.
127
previously
was 0.8 %. The preparation
and washing For density
work
of the (Schatz
procedures gradient
66 M sucrose; additions
flota-
as above)
Vol.
15, No.
2, 1964
was constructed fraction
BIOCHEMICAL
AND
ultracentrifuge.
If sedimentation
involving
through
triiodo-benzoate.
flotation
an X-ray
the gradient
follows
: The crude mitochondrial
ficient
“Urografin”
fraction
as described
above.
After
from the top of the gradient
diluted
with homogenization
and an aliquot
activity
and acid-soluble
extracted
with 0.5 M perchloric followed
obtained
with this procedure
Button (1956). with pancreatic containing
within
DNase (Fluka)
150 pg/ml
pure cytochrome protein
pressed as pmoles : An
examined.
and
the
This
lack
the
removal
enzymic
of information
purification
ally
with
high
density
ever,
it was
come
these
initially
+) We are greatly
density Thus,
the preparation
indebted
c reductase
from as the
nucleus
and
by enzymatic
gradient
examined equilibrium
equilibrium of pure
thus
far
yeast
to Dr. Klose (Fa. Schering.
substance. 128
Vienna)
fracproperties
assessment
In view
not
known.
(Allfrey
for of their
of the
exception-
1959),
how-
might
in sucrose
mitochondria.
the
are
centrifugation
centrifugation
of 3.0 ml at 20’.
centrifugation
as the
tests.
are ex-
sedimentation
of differential
of
and that of
activities
mitochondrial
its fragments
as well
was
number
requires
the
pH 6.6
activity
activity
DNA
fragments
buffer
Specific
of mitochondrial
fractions
nuclei
1964).
and
Digestion
of the turnover
in a total volume
adoption
The results
of Dische (1930)
c reductase
for measurements
problems,
the
the DNA
1952).
per mg protein
yeast
material
isolated
that
difficulties. for
difficult
mitochondrial
of all
(Ceriotti
was
lipid was also
Finally,
error was always observed.
and Klima
nuclear
of the
nuclear
hoped,
tried
poses
precluded
of the
contamination
and
complement
In some experiments
L-lactate-cytochrome
(Schatz
demonstration
task
of the particles
by use of the methods
(1961)
at 30 000
c reductase
out at 26’ for 2 hours in 0.02 M acetate
pet minute
and
in homogenization
The remainder
at 0’.
suf-
They were then
succinate-cytochrome
of succinate-cytochrome
of nuclei
This
were resuspended
experimental
elsewhere
reduced
unambiguous
quantitative tions
of acceptor
syringe.
3 : 1 at room temperature.
and 0.05 M MgCl2.
as described
1.20 g. cme3)
were washed twice by centrifuging
checked of
containing
of 3.0 ml each were collected
designed
by the indole method
chosen by Nygaard
b2. The determination
were performed
Results
rhe limits
medium
4.5 ml of this heavy
(1.10
fractions
acid in 35 70 ethanol
was carried
enzyme
assayed under the conditions
gradient
compounds,
were frequently
Agreement
were conducted
to 1.25 g. cmu3.
The pellets
was determined
as above.
as
for the assay of protein.
-ether
and centrifuged
by Fa. Schering)?
centrifugation,
by ethanol
of these washed particles
gradient
6-
” Urografin’
deoxyribose-containing
4.5 ml of a mitochondrial
in homogenization
and the particles
was withdrawn
with ethanol,
content
gradient
medium
of a crude mitochondrial
(N, N’-diacetyl-3,5-diamino-2.4,
with the help of a specially
in the Spinco no. 30 rotor.
medium
washed twice
was dispersed of the suspension
by 25 ml of a linear
starting
rpm for 60 minutes
of * Urografin”
agent manufactured
to adjust the density
suspension were overlayered
was desired.
on top of the preformed
in gradients
contrasting
COMMUNICATIONS
at 25 000 rpm for 5 hours in the IOIOI SW 25.1 of the Spinco
SusPeosion in 0.5 M suctose were layered
centrifuged
RESEARCH
(Bock and Ling 1954) on top of 4.5 ml of a suspension
in 1.8 M sucrose and centrifuged
Experiments
BIOPHYSICAL
The
for the generous
over-
gradients resolution
supply with this
was of
BIOCHEMICAL
Vol. 15, No. 2, 1964
subcellular
components
satisfactory
for
the
a well-defined within
mitochondria
were
was
nuclear
fragments
gradients,
other
“Urografin”
types
obtained
by floating
schematically
depicted
which
also
crude
mitochondrial
of this
appeared
experiments,
protein
(table two
to DNA
well
content
widely
peaks
with
particles
protein.
and
to DNA
other
tions and drial
other
compounds (table
is not Morton
I).
not The
accounted 1960)
concentration
for
of mitochondrial of cytochrome
detergent
c reductase activation.
(The
analyzed
of the the
the
was due
mitochondria.
nuclear
matter)
from
20 - 250&mg
with
the
peak
The varied of
of mitochondrial
digestion
with
pancreatic
proved
to be due DNase,
rendered
acid-soluble.
In addition
3.5-4.8
rJg/mg
of deoxyribose-
by acid, found
in the
cytochrome
b2.
in the
of activation
129
mono-
purified
Table
mitochondrial
from
II gives the
purified by the
frac-
(Appleby the
specific mitochondrial detergent
to
or oligonu-
component
b2 as calculated measured
protein
presumably,
polydeoxyribonucleotide
extent
for
experimental
Upon
of DNA
mg of
peaks
thus
precipitable
by the
were
and
contained
particles
per
activity
was
of the
DNA
under
B,
mitochondria.
c reductase
DNA
amount
the
from
exactly
in band
microscope,
One
bands
are
activity
floated
ranged
The
c reductase
including
and
trials,
was found
4.3~~19
3).
not
sedimenting
of gradient
gradient
separated
coincided
type
the
work.
of yeast
and
the
of sucrose
present
protein
(figure
(probably
mitochondria.
mitochondria
L-lactate-cytochrome after
of DNA
mitochondrial
the
electron
the
through
numerous
in this
of the
were
clearly
material to the
with
purified
containing cleotides
thus
contained
shortcomings
for
1.1
fractions
succinate-cytochrome
associated
the
dense
peak
up to 75 % of this DNA,
were
oneexperiment
The
protein
and
between
which
large
to slowly
population
found
relatively
Essentially
After
of the
in the
were
between
which
due
suited
homogeneous
different
separated
of this
from
the
separation
mitochondrial.
the
formed
to be diffusely
of sedimentation)
bulk
If viewed
found
band
succinate-cytochrome
contained
When
employed
The
to be un-
mitochondria
The
in the
fractions
4.
as a fairly
associated
conditions DNA
I).
in DNA.
investigated.
to be well
of the
they
no clear
to avoid
mitochondrial
most
was
complications
were
found
fraction.
In five
DNA,
In an attempt
in figure
contained
band
2).
crude
was
(instead
to avoid
were
DNA
as truly
in order
of gradients
gradients
-3,
found
if flotation
(figure
the
rich
be regarded
proved
Whereas
l).There
of protein)
obtained,
employed
work.
particles
not
however,
I. 18 g.cm
gradient(figure
thus
procedure,
present of
(20-4Oug/mg
could
gradient
of the
contaminating
of DNA
results
by this
at a density
the
and
mitochondria same
purpose
band
distributed
amounts
effected
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
mitochonactivity
of fraction
as we,lI
as
Vol. 15, No. 2, 1964
BIOCHEMICAL
AND BIOPHYSICAL
‘B 2.0 -
-10 2.0 -
1.13
1.16
l.lq 1-b
1.13
RESEARCH COMMUNICATIONS
c
%j.3
““.. .
1.16
1.1-l I.22
1.10
143
Cl6
I.19
Figures 1 ~3 : Distribution of succinate-cytochrome c reductase activity (. . . . ), protein (- -- - -) and DNA (. -. -. -) after subjecting crude preparations of yeast mitochondtia to sedimentation in a sucrose gradient (fig. 1). flotation in a sucrose gradient (fig-S) and flotation in a “Urografin” gradient (fig. 3). Abscissa : density (g. cms3). Ordinate A : mg protein/ml fraction and A E550 pet minute per 0.4 ml fraction: ordinate B : fig DNA/O. 1 ml fraction: ordinate C : pg DNA/ml fraction.
A 6
Figure 4 : Banding of a crude mitochondrial fraction from yeast in a ” Urogtafin” gradient. A (1.12 g. cme3) : Mitochondtial precursors (Schatz 1963) B (1.15 g. cmm3) : Mitochondria C (1.19 g.cme3) : Double Membranes rich in ATPase (Schatz et al. 1963) D () 1.25 g. cmm3) : Debris including nuclear material. -
c
H
0
Fig.4 Deoxyribose compounds not precipitable by acid ++I ,ug / mg protein Experiment Experiment Experiment Experiment Experiment
Table
1 2 3 4 4a 5 5a
3.48 4.25 4.83
Deoxyribose compounds precipitable by acid (DNA) ,ug / mg protein 1. 55 1.18 1.06 1.51 3.60 4.30 4.30
5) +) &) &) f)
I : Deoxytibose compounds in purified yeast mirochondria. ++) Calculated as nucleotides f ) Particles incubated at 26O for 30 min at pH 6.6 after acid precipitation + ) Particles incubated at 26’ for 2 hours at pH 6.6 after acid precipitation & ) Lipid extracted as described under Experimental.
1.30
BIOCHEMICAL
Vol. 15, No. 2, 1964
Enzyme
tested
Specific without
L-lactatecytochrome reductase
c
succinatecytochrome reductase
c
Table
the
activity
detergent
activity
0.054
0.12
0.39
nil
of succinate-cytochrome
into
cleotide
account,
(Appleby
DNA
found
the
of the
pellet
found
in the
Discussion
for
2 hours
of DNA
from
supernatants
purified
mitochondrial
that
under
wos
assembly yeast
are
and
The the
chemical
the
1963).
information
mitochondrial
mitochondria amounts
of nucleic
the function
themselves. of DNA
flotation.
The the
This
associated material
deoxyribose
acid of the
possibility
was
in the
the
to arise
The the
and
but
as the that
primary
these
paper
reports
of small,
content
was (assayed
131
identified with
available
1955;
DNA
in question
and
Simpson
detection
in
(Ephrussi
is unknown,
of DNA
mitochondria
present
of mitochondria factors
from
organized
be extrochromosomal
yeast
DNA
previous
might
with
rotor).
the
appear
investigated
the
parti-
no.40
1963).
(Rout role
10 to 40,
that
by
function
factors
I n view
found
controlling
genetic
of
contaminant.
Schatz
and
of these
of
unlikely
mitochondria
factors
amounts
(Spinco
prompted
1962;
Structure
nature
involvement
Marcovich
of genetic
precipitability,
about
by extrachromosomol
governed
suggests
gradient
more
et al,
in part 1951).
regulating
ficant
to learn
it very
yeast
structure.
Moustocchi carrier
(Linnane
rpm
was an adsorbed
conditions
the
b2. was
at 40 000
were
comparison).
by a factor
homogenates
here
of mitochondrial
Hottinguer evidence
certain
that
cytochrome
made
described
precursors
undertaken
be calculated,
fractions
investigations
for
c
% of polvdeoxyribonu-
exceed,
centrifugation the
included
5-6
by mitochondrial
present
and of succinate-cytochrome
are
preparations
yeast
non-mitochondrial work
it con
in the
: The
observations,
c reductase
b2 contains
1960)
contributed
upon
absence
cytochrome
Morton
DNA
0.11
c reductase
mitochondrial
of DNA
All culate
and
in our
amounts
The
that
Calculated concentration of cytochrome b2 (% of mitochondrial protein)
with 0.1 % Triton X 100
II : Specific activities of L-lactate-cytochrome reductase in purified yeast mitochondria.
Taking
the
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
factors
present
within
but
signi-
purified
by density
as DNA
by its ocid-
different
methods)
and
its
Vol.
15, No.
2, 1964
digestion
BIOCHEMICAL
by pancreatic
mitochondrial
fraction
excluded,
since
from
the
drial
marker
bulk
regarded
results
of the
obtained
presence pounds
that
of DNA
here.
The not
the
might
of appreciable
amounts
phenomenon.
Acknowledgements Public Health the preparation
This
this
that
the
the
occurrence
have
been
found’in
in the
of small
amounts
possibility
is being
: This work was Service. The authors of the manuscript.
of the
whole
band
well
peak
of the
other
cells
ratio
possibility from cannot
virtually
to the
controlling
Moreover,
the
mitochondria of extranuclear
com-
metabolism all
of yeast DNA
plant may
the
support
deoxyribose-containing of DNA
the
to corroborate
factors DNA.
to be
of mitochon-
lends
extrachromosomal
be
mitochon-
but
in order
in mitochondria
can
of DNA
base
the
separated
unlikely,
the
with
material
absence
be mitochondrial
suggests
associated
The
comparing
of acid-soluble,
of DNA
only
is considered
of DNA
in yeast
occurrence
Because
from
function
the
c reductase.
extracted detection
DNA
COMMUNICATIONS
by nuclear
with
at present
it,
detection
the
in a discrete
coincided
homogenates
We are
Mitochondria The
to occur
artefacts.
that
in mitochondria
cells.
found
proving
organelles.
that
RESEARCH
to contamination
exactly
yeast
out.
though
mitochondrial
possibility
be due
of adsorption
with
BIOPHYSICAL
succinate-cytochrome
ruled
hypothesis,
The
was
and
enzyme,
portion
DNA
DNA
of DNA
be definitely drial
might
this
is that
soluble
DNase.
AND
in these and
thus
is a rather
animal indicate, general
investigoted.
supported by grant GM 11225-01 are indebted to Dr.R.Wolfe for
of the his help
Allfrey,V.,
in : “The Cell” (Brachet, J. and Mirsky,A., ed.). Academic 1959, vol. I, p. 193. Appleby, C.A. and Morton,R. K., Biochem. J. 75, 258 (1960). Bock,R.M. and Ling.N.S., Analyt.Chem.26, 1543 (1954). Burton,K., Biochem .J. 62, 315 (1956). Ceriotti,G., J .Biol. Chem. 198, 297 (1952). Chun,E.H.L., Vaughan,M.H. and Rich.A., J.Mol.Biol.7, 130(1963). Clark,T.B. and Wallace,F.G., J.Protozool. _7, 115 (196@. Dische,Z., Z.Mikrochem. 2, 26 (1930). Ephrussi, B. and Hottinguer, H., Cold String Harbor Sympos.Quant.Biol.
U.S. in
Press
3,
(1951). Linnane,A.W., Vitols,E. and Nowland,P.G., J.Cell Biol. 2, 345 (1962). Moustacchi,E. and Marcovich,H., Compt. rend. 256, 5646 (1963). Enzymes” (Falk,J.c Lemberg.R. and Morton,R.K., Nygaard,A.P., in : “Hematin ed .) Pergamon Press 1961, p. 547. Raut,C.W. and Simpson,W.C., Arch.Biochem.Biophys. 57, 218 (1955). Schatz,G, , Biochem. Biophys.Res. Communic. 2, 448 (1%3). Schatz,G., Tuppy,H. and Klima, J., Z. Naturforsch. g, 145 (1963). Schatz,G. and Klima,J., Biochim.Biophys.Acta, in press. Stich,H.F., Exp.Cell Res. 2, 136 (1962).
132
75