- Email: [email protected]
Determination of some mitochondrial RNAs concentration in adult rat liver
Vol. 118, No. 1, 1984
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Januory 13, 1984
Pages 284-291
DETERMINATION
OF SOME MITOCHONDRIAL RNAs CONCENTRATION IN ADULT RAT LIVER
P. Cantatore,
M.N.
Institute
Gadaleta,
and C. Saccone
of Biological Chemistry, University of Bari, Bari, Italy
Received November 29, 1983
A method has been developed to accurately measure steady state concentrations of mitochondrial transcripts in adult rat liver. Total mitochondrial RNA has been hybridized with an excess of labelled mitochondrial DNA fragments coding for a single gene or a piece of it. The results obtained show that each mitochondrion contains 36 molecules of 165 rRNA, 81 of 125 rRNA and about 8 molecules of mRNAs coding for identified and unidentified reading frames. Thus, the rRNA/mRNA ratio in rat liver differs from that reported in HeLa cell mitochondria. These results are discussed in the light of mitochondrial DWA transcription regulation.
Very animal
information
mtDNA
HeLa
cell
first re
little
expression.
entirely
L-strand
In
(2).
bably
and
The
involved
two in
ed
that,
in
these unstable.
however,
the
this
may mt
of
rRNAs
gene
one
both
In the
of
The
mRNAs
of
mt
in
ileLa
have
by
cell
pro-
mRNA
and
the
de-
are
(3)
synthe-
have
report-
mRNA species
inhibited
Authors
matuthe
been
H-strand
are
transcript-
mRNA species used
same
to for
Attardi
rRNA
conditions of
the
to
are
leading
polycistronic and
mature
mainly
po-int
on
of
strands
H-strand
the
mechanisms
expression.
and
the
Gelfand
stability of
for in
DhA
processed.. initiation
and
cells,
ion, the
rRNA
regulation refer
both
points
Moreover,
metabolically be
two
the
literature
one
initiation
the
respectively.
the
then
Recently
on
cells
and
(1).
transcription
scribed
in
these
transcribed
products
available
Data
mitochondria.
gene
sis,
is
can
change
cell
to
measured
and
regulate
concentration
mitochondria,
by
kinetic
ex-
periments. To re
regulation
physiological
ations Fion nt:
extend of
of
systems, rat
standard nucleotite(s).
liver
mtDNA
we
mtRNAs
abbreviations:
0006-291X/84 $1.50 Copyright 0 1984 by Academic Press, Inc. All rights of reproduction in any form reserved.
transcription
decided
at mt:
the
to steady
mitochondrial;
284
studies
determinate state.
to the
This bp:
mo-
concentr-
was basepair(
made
BIOCHEMICAL
Vol. 118, No. 1, 1984 by
hybridizing The
total
results
obtained
mitochondrial rat
mtRNA
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
with
specific
reveal
mRNA species
labelled
consistent
mtDNA fragments.
differences
concentrations
in
between
t'eLa
celis
and
in
liver.
KCTiRIALS
AND METHODS
Liver mitochondria were isolated from an adult rat (150 g b.w.) through differential centrifugations (4). Care was taken to reduce nuclear contamination by centrifuging the postnuclear supernatant several times at low speed. After lysis in 120 mK NaCl, 10 rnN TRIS-HCl ptl 7.4, 1 mM EDTA, 1.2:: SDS, the nucleic acids were isolated through extraction with phenol-chloroformisoanylic alcohol (50/49/l) and repeated ethanol precipitations. The DNA fragments used as probe in the hybridization experiments were isolated by cutting recombinant plasmids containing Eco RI fragments A, 8, C, D and'E of rat liver mtDNA with the appropriate restriction enzymes. After separation on polyacrylamide gel, the fragments were eluted and ethanol precipitated as previously described (5). Probe labelling was carried out by nick translation (6) for 2 h at 15°C in presence of 75 uCi/mmole of c (S2P)dCTP. At the end of the reaction the labelled CNA was isolated by chromatography on a G-50 Sephadex column eluted with 10 mM TRIS-HCl pH 8.0, 1 di EDTA. The DNA size, determined by urea-polyacrylamide gel electrophoresis, ra ged from 200 to 400 bp and its specific activity was around 1.10 7 Cpmlpg. The soluticn hybridization experiments Kere done in a volg me of 40 ul using the conditions described by Casey and Davidson (7). After incubation (20 h at 48°C) the samples were digested with 100 U/ml cf 51 nuclease (Sigma) for 30 min at 45°C. The amount of hybrid formed c~as determined by t.richloroacetic acid precipitation. ihe DKA and RNA concentration was aetermined by colorimetric methods as diphenglamine and orcinol, or (in case of DNA) using the fluorimetric assay developed by Labarca and Paigen Protein concentration was determined through the Waddel me Kd (9). RESULTS The
strategy
used
concentrations
of
termination
of
zation
of
of
it.
This
mtDNA
is of
amount
for
could
be
since
gene
done, and
cells
containing liver
these
mtDNA
cells, and
plasmids
with
several genes
for
total
of the
were
E.coli
the
two
rRNA
285
165
D and
were
obtained The and
rat
liver
chimeric E fragextrac-
separated
on
by cutting
the
probes 125
a
a piece
DNA was
DNAs
were
of
or the
C,
de -
hybridi-
excess of
Total
enzymes. mt
an gene
B,
on the by
harbouring
plasmid
restriction
with
A,
available. probes
formed
organization RI
state
based
a single
E.coli
and
finally
mtRNA
Eco
steady
was
hybrids
of
gradient the
DNA-RNA coding
a CsCl tained
of
fragment
(10)
the
transcripts
quantity
rat
from
measure
mtDNA
pSF2124,
ments ted
the
known
plasmid
accurately
mitochondrial
a known
radioactive
to
and
useo for
confive
Vol. 118, No. 1, 1984 mRNA
the stion
Co111 , FTFase-6,
(CoI,
sentative
BIOCHEMICAL
pattern
of
As
shown
in
16s
rRNA
was
of
pSF2124
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
URFl
a13
mt
Fia.1,
and
URF4)
so
to
obtain
a repre-
transcripts.
the
fragment
the
1304
bp
(I))
with
HhaI
containing
long
one,
and
the
deriving
RI;
Eco
from
the
12s
gene the rRNA
for digegene
ECoRI A 4 > ECoRI
Hpa ll
c
Hpa ll
.I
Hpa II
+2opo
Lpi
Pro
g’u
,URF
u 1
II 1
I I
wtb
“!?”
ECoRI
+i
6ayi
6 URF 5
1111 \
t thr replication
origin
ECoRIB<
hi/;,
-
6 I
IATPase
‘1 fYS URFAG
t
Co III
ilURF3ll
L
ECoRI C
L H
alaayqy& I I III I 11 I t
-WI
1
origin
ECoRI
4
1
L strand “f
co I
ECoRI D <
L H
Twl
l2opo
replication
URF4
k
III Taq I
lopoC4
>
&I URF4L
f Taq-i Hind
--RF2
ECoRI 4
I
dY’
ECoRI 4
4-
H strand
)
II-II
-URF leu
III
t
-C0II-
> Hha I
ECoRl
+, 1500
5p
166 RNA
J
I IURF i
t
I!”
ECoRI E
>
ECoRI 4 L <
59
URF
1
ECoRl &j
>
Physical and transcription B, C, D and E. Only the A two be prepiration are shown. ments that were labelled by nick Hae III and Hinf I sites.
map of restriction headed arrow translation.
286
rat liver mtDNA fragsites used for proindicates the fragA and H are the
Vol. 118, No. 1, 1984
was
contained
BIOCHEMICAL
the
fragment
of
gestion
of
Eco
A with
HpaII.
The
gestion
of
Eco
RI
tained
in
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
in
the
and URF4
have
two,
were
prepared
6am
HI and
then
is
specific
with
of
of
labelled
by
ned
the
DNA coextracted
was
not
eliminated
dard
in
Therefore the
and
with
all
the
tion
are
reported
centration to tion per
amount with
of
used.
the
mitochondrion
that
there
rRNA
per
36
ranging
from
of
by
using
of
DXA
tofrag
of
mtRNA
0
are
URF4
and
in
the of levels
at
satura-
used
for
con-
by relating
them
mitochondrial of
frac-
5 DNA molecules in
81
present
mRNA to
species.
saturation
number
rRNA
It
stan-
added
were the
RNA.
activity
reported
16s
mRKAs f
mtRNA
species,
from
results,
The
of
RNA hybridized
a mean of
internal
specific
quantities
each
The
as
DNA was
the
contai-
the
reached
These
molecules
6 molecules
the
also
used
cold
for
pg
assuming
mitochondrion.
in DNA
maximizing
hybridization was
coextracted
(11).
are
out
concentration
The of
RNA and
grown
hybridized.
mitochondria.with
made
Tab.1.
mtCNA
and
calculate
conditions
Hybridization
determination
the
for
quantity
in
III
plasmid
to
carried
in
the
were
probes
were the
used
other
fragment
concentrations
amount
of
probes.
be
were
the
its
equivalent
radioactive
was
The
determine
and
con-
the
Hind
plasmids
di-
ATPase-6
whereas
To
uCi/ml)
was
B fragment. with
di-
the
CoIII,
for
first
to
used from
corrections
gene
the
(7).
preparation since
URFl
RI
I.
translation,
calculation an
blanks
B,
cpm/ug)
fcrmation
from
sites,
containing (0.5
and increasing
hybrid
the
Hinf
Rl!A
RNA-DNA
mtRNA
and
CNA fragment
the
The
RI
the
nick
Eco III
experiments
mitcchondrial
by
resulted
probes
Eco
1000
hybridization
The
Hind
cells
(about
concentrations
ments
III
Hae
originated the
the
two
3H-thymidine
activity
The
E.
digesting
bp,
whereas
from in
E.coli
presence
RI
prepared
contained
concentrations,
tal
Eco
been
probe
I,
Taq
fragment
URF4
the
C with
934
Co1 gene
Tab.1,
show
molecules at
of
lower
1'LS
levels,
16 molecules
of
CcI
mRNA. This direct same
yield
preparation tion cleic
approach
assuming from is
v;as acids
DNA extracted
to that
calculate
mtRi:fi
the
DNA and
mitochondria
and
of
verified
mitochondrial by
extraction from
that
the
is
coextracted
the only.
The
the
Di:A/RriA
ratio
mitochondria.
mitochondria
was 287
the with
Di:F, present
origin
determining from
the
concentration
RNA are
in
first
that
mtRliA
assump-
during
Furthermore, 1% of
more the
extracted
nuthe
Vol. 118, No. 1, 1984
BIOCHEMICAL
Determination
TABLE I the concentration of several species by hybridization
of
RNA
AND BIOPHYSICAL RESEARCH COMMIJNICATIONS
RNA
DNA hybridized per
RNA
RNA molecules mitochondrion
species
w
Pg
12s
10
102 + 2 225 f 7
81.0
+ 3
13 25
72 + 4 82 + 3 145 + 8
36.0
2 4
URF 1
100
82 + 4
8.5
+ 0.5
co1
100
16.0
+ 2
ATPase-6
100
49 + 7
7.1
+ 1.2
co111
100
38 + 8
7.3
+ 1.6
URF 4
100 150
67 + 2 71 + 2
6.4
+ 0.4
20 165
10
185 ~17
The values reported in the third They are the mean of saturation. far each RNA concentration, run was determined by measuring the cubated without mtRNA. The number chondrion has been calculated as
from
the
rature II,
homogenate (11).
was
mtRKA
absent
in
concentration
total
the the
DNA.
mitochondria the
same
column are those obtained at at least three experiments in triplicate. The background inS1 resistance of samples of RNA molecules per mi Odescribed in the text.
same
preparation
as
nuclear
marker
enzyme,
mitochonarial
RNA either
of of
the
were
cellular
ses
of
Finally,
hybridized
re
nitochondrial
to
also the
by
values
and
RNA occurring magnitude as
order
of
Estimates
referring
mitochondrial
The
the
or
normalized during those
of
pmoles
proteins
obtained,
lite
ymerase
RNA po
preparation. made
in
reported
of
to
for
the
the
the reported
extraction, in Tab.1.
measuring
the
10s we
DISCUSSION In tration chondria RNA is
this of are double
paper the
two
the rRi;As
reported. than
165
results and
obtained of
five
by mRNAs
They
show
that
RNA.
This
difference 288
the
in
rat
liver
mito-
concentration could
concen of
be
due
to
125 the
8lOCHEMlCAL
Vol. 118, No. 1, 1984 gene ly
order
in
adjacent
tration
to of
Co!
is
mRNA and
it
only
by
From
the cells
it in
10
to
100
Coi and their
to
data that
ring
early
which
in
of
the
ven
first
by
the
(19).
synthesis
is
cies
are
trationsare ted
this
mtDNA directly
level
their cannot,
addressed
well
of
rat
with clear liver
liver
the
out
absence In
the
cells
at
10
days
at might
decay also
stability. however,
replication takes
of
at
that
their
level.
steady
The rate,
by as
in
on this rat
mRNA could
A regulation
operating
excluded
measurement
of 289
state
and mtRNA
only stability
post is
that
of
when rnt
gi de-
mtRNA
mRXk
state
data
explained
mitochondrial be
of
of
a kinetic
steady and
stabilities
be
with
that
and
RNA syn
weeks
synthesis
du
mtDNk
k:hereas
indicated
de-
organ
birth, tt;ree
a
place
an
age,
the
the
respiratory of
mtDNA mtRNA
RNA decays
of
have
of
first
have
urchi'n
cerebellum,
the
rate
in
sea
after
that
proceeds
of
completely along
the
in
synthesis
suggesting
to
synthesis
carried
(20,21)
elevated of
mtRNA
Authors
inhibited
concentration
increase
rat
up
between
paper
conditionsof creased
in
concentration
Several
reguieted
in
of
of
assuming
its
increased,
concentration
mENAs
in is
mRNAs
seems
almost
By
ratio
gradation
of
it
the
of
peak
order,
and
(12,i3);
constant
(17,18).
con-
rRNA
correlate
(14-16).
synthesis
life
liver 125
systems
even
develops
remainsquite
natal
sp:te
development
protein
thesis
that
synthesis
rats
rat
aa 3 content
Studies
in
protein
the
iieL.a.
fashion.
monstrated
The
sta
repor-
mitochondria. of
rate
po-
steady been
concentration
respiratory
suggest
constitutive
the
cell in
concentration
higher the
the
the
measured
HeLa
cells.
two
for
have
concentration
HeLa
the
higher
the to
Some
in
in
on
Authors in
whereas
lower
except
mRNA genes.
obtained
the
systems
the
respect
mt
results
of
confirming
literature
mRNAs
that
cytochrome
that
related
and
the
times
respective
with
of
concen-
that
mitochondrial
These
of
out
order
immediatg
The
than
transcripts (3).
fact
point. lower
gene
the
and
mRNAs
therefore
in
in
mRNA measured of
rRNA
two
COIII
all of
Attardi
comes
the
for
mitochondrial
comparison
similar
is
same
existing
125
RNA is
order
pattern
and
of
one
independent
data
Gelfand
HeLa
mt
is
125 initiation
about
the
of
centration
is
is
transcription
The
the
transcription
concentration
ted
mtDNA:
mRNAs about
lycistronic
te
liver
the
the
It
rRNAs.
rat
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
spe-
concen-
nRNA:
repor-
mechanism.
In
liver,
the
depend
on
at
in an
promoter
experiments may
settle
Vol. 118, No. 1, 1984
the
problem.
since
the
This
that
their
lism.
Data
from
sibility.
The
tochondrial
genesis
apply,
liver
and is
used
here
number
of per study
could
during
be
development
mitochondrion. thyroid
cells
12s of
could
useful
in
(22)
is
per
cell
The
same
hormone
due or
metabo-
in
in
to
that
on
speci-
out
if
the
liver
at
to
the
rise
of
RNA con-
considerations
action
ml
different of
rat
either
pos-
studying
finding
observed
sug-
this
in or
rRNAs
level
cell
measurements help
the
confirm
development
Concentration
mitochondria of
HeLa
to
eventually
phosphorilation of
however,
independent
will
transcripts
stages
the
not
systems
expression
oxidative
centration
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
concentration other
mitochondrial
to
rat
conditions.
critical
ply
of
gene
increased the
does
approach
physiclogical
of
model
similarity
gests
fic
BIOCHEMICAL
could
mitochondrial
ail bio
(23).
ACKNOWLEDGEMENTS We thank Z. Flagella and G. Pesole of experiments and F. Fracasso for the stance. This work was partially supported Progetto Finalizzato Ingegneria Genetica le Maiattie Ereditarie, CNR - Italy.
for their help in skilfuil technical by a grant from e Basi Molecolari
some assithe del-
REFERENCES 1)
2) 3) 4) 5) 6) 7)
8)
91 10) llj 12) 13)
Attardi, G., Cantatore, P., Chomyn, A., Crews, S., Gelfand, R Montoja, J. and Ojala, 0. (19823 In “Mitoch~n!~~~~'~e~e;" (Sionimski P P. and Attardi, G. Borst, eds) pp. 51-71. Cold Spring'HarLor, New York. T., Levens, D., Rabinowitz, M., Montoja, J., Christianson, and Attardi, G. (1962) Proc. Natl. Acad. Sci. USA 79, 7195-7199. Gelfand, R. and Attardi, G. (1981) Mol. Ceil Biol. 1, 497-511. Saccone, C., Gadaleta, M.N., and Gallerani, R. (1969) Eur. J. Biochem. 10, 61-65. Saccone, C.,Cantatore, P., Gadaleta, G., G., Gallerani, R., Lanave, C., Pepe, G. and Kroon, A'.M. (1981) Nucl. AC. Res. 9, 4139-4147. :igby; PBYo:., Dieckmann, M., Rhodes, C. and Berg, P. (1977) 113, 237-251. Casey,‘J. and Davidson, N. (1977) Nucl. AC. Res. 4, 1539-1552. Labarca, C. and Paygen, K. (1980) An. Biochem. 102, 344-352. Waddei, W.J. (1956), J. Lab. and Clin. Med. 4B,Tl-314. Pepe, G., Holtrop, M., Gadaleta, G., Kroon, A.M., Cantatore, P Gallerani, .R., De Benedetto, C., Quagliariello, C., &a, E. and Saccone, C. (1983) Biochem. Int. 6, 553-563. Neubert, D., Gregg, C.T., Bass, R. and Marker, lT.3. (1975) In "Biochemistry of animal development" (ed. by Weber R.) Vol. III, Academic Press, New York, 387-464. 175-181. Williams, J.N., Jr (1968) Biochem. Bioohys Acta E, Hare, J., Ching, E. and Attardi, G. (1980) Biochem. 19, 2023-2030.
Vol. 118, No. 1, 1984
14) 15) 16) 17)
18)
19) 20) 21) 22) 23)
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Cantatore, P., Nicotra, A., Loria, P. and Saccone, C. (1972) Cell Differentiation 3, 45-53. Gadaleta, M.N., Nicotra, A., Del Prete, M.G. and Saccone, C. (1977) Cell Differentiation a* 85-94. Devlin, R. (19761, Dev. Biol. 2, 443-456. Gadaleta, M.N., Giuffrida, A.M., Renis, M., Serra, I., Del Prete, G., Geremia, E. and Saccone, C. (1979), Neurochem. Res. 4: 25-35. Giuffrida, A.M., Gadaleta, M.N., Serra, I., Renis, M., Del Prete, G. and Saccone, C. (1979) Neurochem. Geremia, E., ", 37-52. Res. Galau, G.A., Lipson, E.D., Britten, R.J. and Davidson, E.H. (1977), Cell 10, 415-432. England, J., Estantino, P. and Attardi, G. (1978) J. Mol. 119, 445-462. Biol. Gadale= M.N., Di Reda, N., Bove, G. and Saccone, C. (1975) Eur. J. Biochem. 51, 495-501. Pollak, J.K. and 'SiTtton, R. (1980) Trends in Biol. Sci. 1, 23-25. Jakovcic, S., Swift, H.H., Gross, N.J. and Rabinowitz, M., (1978) J. Cell Biol. -77, 887-901.
291
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Januory 13, 1984
Pages 284-291
DETERMINATION
OF SOME MITOCHONDRIAL RNAs CONCENTRATION IN ADULT RAT LIVER
P. Cantatore,
M.N.
Institute
Gadaleta,
and C. Saccone
of Biological Chemistry, University of Bari, Bari, Italy
Received November 29, 1983
A method has been developed to accurately measure steady state concentrations of mitochondrial transcripts in adult rat liver. Total mitochondrial RNA has been hybridized with an excess of labelled mitochondrial DNA fragments coding for a single gene or a piece of it. The results obtained show that each mitochondrion contains 36 molecules of 165 rRNA, 81 of 125 rRNA and about 8 molecules of mRNAs coding for identified and unidentified reading frames. Thus, the rRNA/mRNA ratio in rat liver differs from that reported in HeLa cell mitochondria. These results are discussed in the light of mitochondrial DWA transcription regulation.
Very animal
information
mtDNA
HeLa
cell
first re
little
expression.
entirely
L-strand
In
(2).
bably
and
The
involved
two in
ed
that,
in
these unstable.
however,
the
this
may mt
of
rRNAs
gene
one
both
In the
of
The
mRNAs
of
mt
in
ileLa
have
by
cell
pro-
mRNA
and
the
de-
are
(3)
synthe-
have
report-
mRNA species
inhibited
Authors
matuthe
been
H-strand
are
transcript-
mRNA species used
same
to for
Attardi
rRNA
conditions of
the
to
are
leading
polycistronic and
mature
mainly
po-int
on
of
strands
H-strand
the
mechanisms
expression.
and
the
Gelfand
stability of
for in
DhA
processed.. initiation
and
cells,
ion, the
rRNA
regulation refer
both
points
Moreover,
metabolically be
two
the
literature
one
initiation
the
respectively.
the
then
Recently
on
cells
and
(1).
transcription
scribed
in
these
transcribed
products
available
Data
mitochondria.
gene
sis,
is
can
change
cell
to
measured
and
regulate
concentration
mitochondria,
by
kinetic
ex-
periments. To re
regulation
physiological
ations Fion nt:
extend of
of
systems, rat
standard nucleotite(s).
liver
mtDNA
we
mtRNAs
abbreviations:
0006-291X/84 $1.50 Copyright 0 1984 by Academic Press, Inc. All rights of reproduction in any form reserved.
transcription
decided
at mt:
the
to steady
mitochondrial;
284
studies
determinate state.
to the
This bp:
mo-
concentr-
was basepair(
made
BIOCHEMICAL
Vol. 118, No. 1, 1984 by
hybridizing The
total
results
obtained
mitochondrial rat
mtRNA
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
with
specific
reveal
mRNA species
labelled
consistent
mtDNA fragments.
differences
concentrations
in
between
t'eLa
celis
and
in
liver.
KCTiRIALS
AND METHODS
Liver mitochondria were isolated from an adult rat (150 g b.w.) through differential centrifugations (4). Care was taken to reduce nuclear contamination by centrifuging the postnuclear supernatant several times at low speed. After lysis in 120 mK NaCl, 10 rnN TRIS-HCl ptl 7.4, 1 mM EDTA, 1.2:: SDS, the nucleic acids were isolated through extraction with phenol-chloroformisoanylic alcohol (50/49/l) and repeated ethanol precipitations. The DNA fragments used as probe in the hybridization experiments were isolated by cutting recombinant plasmids containing Eco RI fragments A, 8, C, D and'E of rat liver mtDNA with the appropriate restriction enzymes. After separation on polyacrylamide gel, the fragments were eluted and ethanol precipitated as previously described (5). Probe labelling was carried out by nick translation (6) for 2 h at 15°C in presence of 75 uCi/mmole of c (S2P)dCTP. At the end of the reaction the labelled CNA was isolated by chromatography on a G-50 Sephadex column eluted with 10 mM TRIS-HCl pH 8.0, 1 di EDTA. The DNA size, determined by urea-polyacrylamide gel electrophoresis, ra ged from 200 to 400 bp and its specific activity was around 1.10 7 Cpmlpg. The soluticn hybridization experiments Kere done in a volg me of 40 ul using the conditions described by Casey and Davidson (7). After incubation (20 h at 48°C) the samples were digested with 100 U/ml cf 51 nuclease (Sigma) for 30 min at 45°C. The amount of hybrid formed c~as determined by t.richloroacetic acid precipitation. ihe DKA and RNA concentration was aetermined by colorimetric methods as diphenglamine and orcinol, or (in case of DNA) using the fluorimetric assay developed by Labarca and Paigen Protein concentration was determined through the Waddel me Kd (9). RESULTS The
strategy
used
concentrations
of
termination
of
zation
of
of
it.
This
mtDNA
is of
amount
for
could
be
since
gene
done, and
cells
containing liver
these
mtDNA
cells, and
plasmids
with
several genes
for
total
of the
were
E.coli
the
two
rRNA
285
165
D and
were
obtained The and
rat
liver
chimeric E fragextrac-
separated
on
by cutting
the
probes 125
a
a piece
DNA was
DNAs
were
of
or the
C,
de -
hybridi-
excess of
Total
enzymes. mt
an gene
B,
on the by
harbouring
plasmid
restriction
with
A,
available. probes
formed
organization RI
state
based
a single
E.coli
and
finally
mtRNA
Eco
steady
was
hybrids
of
gradient the
DNA-RNA coding
a CsCl tained
of
fragment
(10)
the
transcripts
quantity
rat
from
measure
mtDNA
pSF2124,
ments ted
the
known
plasmid
accurately
mitochondrial
a known
radioactive
to
and
useo for
confive
Vol. 118, No. 1, 1984 mRNA
the stion
Co111 , FTFase-6,
(CoI,
sentative
BIOCHEMICAL
pattern
of
As
shown
in
16s
rRNA
was
of
pSF2124
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
URFl
a13
mt
Fia.1,
and
URF4)
so
to
obtain
a repre-
transcripts.
the
fragment
the
1304
bp
(I))
with
HhaI
containing
long
one,
and
the
deriving
RI;
Eco
from
the
12s
gene the rRNA
for digegene
ECoRI A 4 > ECoRI
Hpa ll
c
Hpa ll
.I
Hpa II
+2opo
Lpi
Pro
g’u
,URF
u 1
II 1
I I
wtb
“!?”
ECoRI
+i
6ayi
6 URF 5
1111 \
t thr replication
origin
ECoRIB<
hi/;,
-
6 I
IATPase
‘1 fYS URFAG
t
Co III
ilURF3ll
L
ECoRI C
L H
alaayqy& I I III I 11 I t
-WI
1
origin
ECoRI
4
1
L strand “f
co I
ECoRI D <
L H
Twl
l2opo
replication
URF4
k
III Taq I
lopoC4
>
&I URF4L
f Taq-i Hind
--RF2
ECoRI 4
I
dY’
ECoRI 4
4-
H strand
)
II-II
-URF leu
III
t
-C0II-
> Hha I
ECoRl
+, 1500
5p
166 RNA
J
I IURF i
t
I!”
ECoRI E
>
ECoRI 4 L <
59
URF
1
ECoRl &j
>
Physical and transcription B, C, D and E. Only the A two be prepiration are shown. ments that were labelled by nick Hae III and Hinf I sites.
map of restriction headed arrow translation.
286
rat liver mtDNA fragsites used for proindicates the fragA and H are the
Vol. 118, No. 1, 1984
was
contained
BIOCHEMICAL
the
fragment
of
gestion
of
Eco
A with
HpaII.
The
gestion
of
Eco
RI
tained
in
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
in
the
and URF4
have
two,
were
prepared
6am
HI and
then
is
specific
with
of
of
labelled
by
ned
the
DNA coextracted
was
not
eliminated
dard
in
Therefore the
and
with
all
the
tion
are
reported
centration to tion per
amount with
of
used.
the
mitochondrion
that
there
rRNA
per
36
ranging
from
of
by
using
of
DXA
tofrag
of
mtRNA
0
are
URF4
and
in
the of levels
at
satura-
used
for
con-
by relating
them
mitochondrial of
frac-
5 DNA molecules in
81
present
mRNA to
species.
saturation
number
rRNA
It
stan-
added
were the
RNA.
activity
reported
16s
mRKAs f
mtRNA
species,
from
results,
The
of
RNA hybridized
a mean of
internal
specific
quantities
each
The
as
DNA was
the
contai-
the
reached
These
molecules
6 molecules
the
also
used
cold
for
pg
assuming
mitochondrion.
in DNA
maximizing
hybridization was
coextracted
(11).
are
out
concentration
The of
RNA and
grown
hybridized.
mitochondria.with
made
Tab.1.
mtCNA
and
calculate
conditions
Hybridization
determination
the
for
quantity
in
III
plasmid
to
carried
in
the
were
probes
were the
used
other
fragment
concentrations
amount
of
probes.
be
were
the
its
equivalent
radioactive
was
The
determine
and
con-
the
Hind
plasmids
di-
ATPase-6
whereas
To
uCi/ml)
was
B fragment. with
di-
the
CoIII,
for
first
to
used from
corrections
gene
the
(7).
preparation since
URFl
RI
I.
translation,
calculation an
blanks
B,
cpm/ug)
fcrmation
from
sites,
containing (0.5
and increasing
hybrid
the
Hinf
Rl!A
RNA-DNA
mtRNA
and
CNA fragment
the
The
RI
the
nick
Eco III
experiments
mitcchondrial
by
resulted
probes
Eco
1000
hybridization
The
Hind
cells
(about
concentrations
ments
III
Hae
originated the
the
two
3H-thymidine
activity
The
E.
digesting
bp,
whereas
from in
E.coli
presence
RI
prepared
contained
concentrations,
tal
Eco
been
probe
I,
Taq
fragment
URF4
the
C with
934
Co1 gene
Tab.1,
show
molecules at
of
lower
1'LS
levels,
16 molecules
of
CcI
mRNA. This direct same
yield
preparation tion cleic
approach
assuming from is
v;as acids
DNA extracted
to that
calculate
mtRi:fi
the
DNA and
mitochondria
and
of
verified
mitochondrial by
extraction from
that
the
is
coextracted
the only.
The
the
Di:A/RriA
ratio
mitochondria.
mitochondria
was 287
the with
Di:F, present
origin
determining from
the
concentration
RNA are
in
first
that
mtRliA
assump-
during
Furthermore, 1% of
more the
extracted
nuthe
Vol. 118, No. 1, 1984
BIOCHEMICAL
Determination
TABLE I the concentration of several species by hybridization
of
RNA
AND BIOPHYSICAL RESEARCH COMMIJNICATIONS
RNA
DNA hybridized per
RNA
RNA molecules mitochondrion
species
w
Pg
12s
10
102 + 2 225 f 7
81.0
+ 3
13 25
72 + 4 82 + 3 145 + 8
36.0
2 4
URF 1
100
82 + 4
8.5
+ 0.5
co1
100
16.0
+ 2
ATPase-6
100
49 + 7
7.1
+ 1.2
co111
100
38 + 8
7.3
+ 1.6
URF 4
100 150
67 + 2 71 + 2
6.4
+ 0.4
20 165
10
185 ~17
The values reported in the third They are the mean of saturation. far each RNA concentration, run was determined by measuring the cubated without mtRNA. The number chondrion has been calculated as
from
the
rature II,
homogenate (11).
was
mtRKA
absent
in
concentration
total
the the
DNA.
mitochondria the
same
column are those obtained at at least three experiments in triplicate. The background inS1 resistance of samples of RNA molecules per mi Odescribed in the text.
same
preparation
as
nuclear
marker
enzyme,
mitochonarial
RNA either
of of
the
were
cellular
ses
of
Finally,
hybridized
re
nitochondrial
to
also the
by
values
and
RNA occurring magnitude as
order
of
Estimates
referring
mitochondrial
The
the
or
normalized during those
of
pmoles
proteins
obtained,
lite
ymerase
RNA po
preparation. made
in
reported
of
to
for
the
the
the reported
extraction, in Tab.1.
measuring
the
10s we
DISCUSSION In tration chondria RNA is
this of are double
paper the
two
the rRi;As
reported. than
165
results and
obtained of
five
by mRNAs
They
show
that
RNA.
This
difference 288
the
in
rat
liver
mito-
concentration could
concen of
be
due
to
125 the
8lOCHEMlCAL
Vol. 118, No. 1, 1984 gene ly
order
in
adjacent
tration
to of
Co!
is
mRNA and
it
only
by
From
the cells
it in
10
to
100
Coi and their
to
data that
ring
early
which
in
of
the
ven
first
by
the
(19).
synthesis
is
cies
are
trationsare ted
this
mtDNA directly
level
their cannot,
addressed
well
of
rat
with clear liver
liver
the
out
absence In
the
cells
at
10
days
at might
decay also
stability. however,
replication takes
of
at
that
their
level.
steady
The rate,
by as
in
on this rat
mRNA could
A regulation
operating
excluded
measurement
of 289
state
and mtRNA
only stability
post is
that
of
when rnt
gi de-
mtRNA
mRXk
state
data
explained
mitochondrial be
of
of
a kinetic
steady and
stabilities
be
with
that
and
RNA syn
weeks
synthesis
du
mtDNk
k:hereas
indicated
de-
organ
birth, tt;ree
a
place
an
age,
the
the
respiratory of
mtDNA mtRNA
RNA decays
of
have
of
first
have
urchi'n
cerebellum,
the
rate
in
sea
after
that
proceeds
of
completely along
the
in
synthesis
suggesting
to
synthesis
carried
(20,21)
elevated of
mtRNA
Authors
inhibited
concentration
increase
rat
up
between
paper
conditionsof creased
in
concentration
Several
reguieted
in
of
of
assuming
its
increased,
concentration
mENAs
in is
mRNAs
seems
almost
By
ratio
gradation
of
it
the
of
peak
order,
and
(12,i3);
constant
(17,18).
con-
rRNA
correlate
(14-16).
synthesis
life
liver 125
systems
even
develops
remainsquite
natal
sp:te
development
protein
thesis
that
synthesis
rats
rat
aa 3 content
Studies
in
protein
the
iieL.a.
fashion.
monstrated
The
sta
repor-
mitochondria. of
rate
po-
steady been
concentration
respiratory
suggest
constitutive
the
cell in
concentration
higher the
the
the
measured
HeLa
cells.
two
for
have
concentration
HeLa
the
higher
the to
Some
in
in
on
Authors in
whereas
lower
except
mRNA genes.
obtained
the
systems
the
respect
mt
results
of
confirming
literature
mRNAs
that
cytochrome
that
related
and
the
times
respective
with
of
concen-
that
mitochondrial
These
of
out
order
immediatg
The
than
transcripts (3).
fact
point. lower
gene
the
and
mRNAs
therefore
in
in
mRNA measured of
rRNA
two
COIII
all of
Attardi
comes
the
for
mitochondrial
comparison
similar
is
same
existing
125
RNA is
order
pattern
and
of
one
independent
data
Gelfand
HeLa
mt
is
125 initiation
about
the
of
centration
is
is
transcription
The
the
transcription
concentration
ted
mtDNA:
mRNAs about
lycistronic
te
liver
the
the
It
rRNAs.
rat
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
spe-
concen-
nRNA:
repor-
mechanism.
In
liver,
the
depend
on
at
in an
promoter
experiments may
settle
Vol. 118, No. 1, 1984
the
problem.
since
the
This
that
their
lism.
Data
from
sibility.
The
tochondrial
genesis
apply,
liver
and is
used
here
number
of per study
could
during
be
development
mitochondrion. thyroid
cells
12s of
could
useful
in
(22)
is
per
cell
The
same
hormone
due or
metabo-
in
in
to
that
on
speci-
out
if
the
liver
at
to
the
rise
of
RNA con-
considerations
action
ml
different of
rat
either
pos-
studying
finding
observed
sug-
this
in or
rRNAs
level
cell
measurements help
the
confirm
development
Concentration
mitochondria of
HeLa
to
eventually
phosphorilation of
however,
independent
will
transcripts
stages
the
not
systems
expression
oxidative
centration
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
concentration other
mitochondrial
to
rat
conditions.
critical
ply
of
gene
increased the
does
approach
physiclogical
of
model
similarity
gests
fic
BIOCHEMICAL
could
mitochondrial
ail bio
(23).
ACKNOWLEDGEMENTS We thank Z. Flagella and G. Pesole of experiments and F. Fracasso for the stance. This work was partially supported Progetto Finalizzato Ingegneria Genetica le Maiattie Ereditarie, CNR - Italy.
for their help in skilfuil technical by a grant from e Basi Molecolari
some assithe del-
REFERENCES 1)
2) 3) 4) 5) 6) 7)
8)
91 10) llj 12) 13)
Attardi, G., Cantatore, P., Chomyn, A., Crews, S., Gelfand, R Montoja, J. and Ojala, 0. (19823 In “Mitoch~n!~~~~'~e~e;" (Sionimski P P. and Attardi, G. Borst, eds) pp. 51-71. Cold Spring'HarLor, New York. T., Levens, D., Rabinowitz, M., Montoja, J., Christianson, and Attardi, G. (1962) Proc. Natl. Acad. Sci. USA 79, 7195-7199. Gelfand, R. and Attardi, G. (1981) Mol. Ceil Biol. 1, 497-511. Saccone, C., Gadaleta, M.N., and Gallerani, R. (1969) Eur. J. Biochem. 10, 61-65. Saccone, C.,Cantatore, P., Gadaleta, G., G., Gallerani, R., Lanave, C., Pepe, G. and Kroon, A'.M. (1981) Nucl. AC. Res. 9, 4139-4147. :igby; PBYo:., Dieckmann, M., Rhodes, C. and Berg, P. (1977) 113, 237-251. Casey,‘J. and Davidson, N. (1977) Nucl. AC. Res. 4, 1539-1552. Labarca, C. and Paygen, K. (1980) An. Biochem. 102, 344-352. Waddei, W.J. (1956), J. Lab. and Clin. Med. 4B,Tl-314. Pepe, G., Holtrop, M., Gadaleta, G., Kroon, A.M., Cantatore, P Gallerani, .R., De Benedetto, C., Quagliariello, C., &a, E. and Saccone, C. (1983) Biochem. Int. 6, 553-563. Neubert, D., Gregg, C.T., Bass, R. and Marker, lT.3. (1975) In "Biochemistry of animal development" (ed. by Weber R.) Vol. III, Academic Press, New York, 387-464. 175-181. Williams, J.N., Jr (1968) Biochem. Bioohys Acta E, Hare, J., Ching, E. and Attardi, G. (1980) Biochem. 19, 2023-2030.
Vol. 118, No. 1, 1984
14) 15) 16) 17)
18)
19) 20) 21) 22) 23)
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Cantatore, P., Nicotra, A., Loria, P. and Saccone, C. (1972) Cell Differentiation 3, 45-53. Gadaleta, M.N., Nicotra, A., Del Prete, M.G. and Saccone, C. (1977) Cell Differentiation a* 85-94. Devlin, R. (19761, Dev. Biol. 2, 443-456. Gadaleta, M.N., Giuffrida, A.M., Renis, M., Serra, I., Del Prete, G., Geremia, E. and Saccone, C. (1979), Neurochem. Res. 4: 25-35. Giuffrida, A.M., Gadaleta, M.N., Serra, I., Renis, M., Del Prete, G. and Saccone, C. (1979) Neurochem. Geremia, E., ", 37-52. Res. Galau, G.A., Lipson, E.D., Britten, R.J. and Davidson, E.H. (1977), Cell 10, 415-432. England, J., Estantino, P. and Attardi, G. (1978) J. Mol. 119, 445-462. Biol. Gadale= M.N., Di Reda, N., Bove, G. and Saccone, C. (1975) Eur. J. Biochem. 51, 495-501. Pollak, J.K. and 'SiTtton, R. (1980) Trends in Biol. Sci. 1, 23-25. Jakovcic, S., Swift, H.H., Gross, N.J. and Rabinowitz, M., (1978) J. Cell Biol. -77, 887-901.
291