- Email: [email protected]
Conservation of globin messenger RNA in rabbit reticulocyte monoribosomes after sodium fluoride treatment
Vol. 47, No. 4, 1972
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
CONSERVATION OF GLOBIN MESSENGER RNA IN RABBIT RETICULOCYTE MONORIBOSOMES AFTER SODIUM FLUORIDE TREATMENT. M. Toada,
J. Bavlkh , 1. W. Dvw, A. Eunh and P. A. Mahh
S. [email protected],
Department of Human Genetics Development, and Medicine Columbia University, College Physicians & Surgeons New York, N.Y. 10032
Received
April
and of
12, 1972
SUMMARY: Following NaF treatment of rabbit reticulocytes, polyribosomes dissociate to monoribosomes with concomitant cessation of protein synthesis. mRNA was isolated from different fractions of the cell before and after NaF treatment and quantitated by assay for globin synthesis in a cell-free system prepared from Krebs ascites tumor cells. mRNA activity present in polyribosomes of control cells was recovered quantitatively from monoribosomes following NaF treatment. On removal of NaF, polyribosomes reform with mRNA activity similar to that of control cells. During polyribosome dissociation, no significant amount of mRNA is recovered from ribosomal subunits, the supernatant fraction or is lost by degradation. Reticulocytes synthesis
at the
synthesize vious
ribosomes are
level
from
sodium
with
(NaF),
Thus,
mRNA for
globin
Further,
these
directly
polyribosome cating
dissociation
during
in Hela
that
with
polyribosomes
On release
is
or number cells
recovered
from NaF inhibition, 766
Copyright@1972,by
Academic Press,Inc.
treatment
(3)
cells
do not Pre-
of reticulocytes
to dissociate
into
These
removal
of NaF,
the rate
begin
to reform(l).
rate
effects
80s
(1,2).
inhibition the
these
of protein
are hemoglobins.
and polyribosomes
showed
on the size
after
cells;
that
of protein of protein
of polyribosomes and ascites
that the effect of NaF is not specific for This paper demonstrates that after treatment
associated region.
synthesis
mechanisms
formed
polyribosomes
conserved
studies
dependent
demonstrated
causes
to normal
is
studying
in mammalian
2 to 3 minutes
returns
for
90% of the protein
of protein
Within
NaF. not
than
cessation
synthesis
system
of translation
our laboratory
fluoride
reversible.
protein
a good model
RNA and more
reports
with
are
tumor
of NaF of
synthesis synthesis
by is
(2).
NaF causes
cells
(4),
indi-
reticulocytes. with NaF, the mRNA initially
quantitatively the mRNA again
in the monoribosomes becomes associated
Vol. 47, No. 4, 1972
with
BIOCHEMICAL
polyribosomes.
significant
Following
amount
or associated
NaF induced
of mRNA is
with
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
found
ribosomal
Kettering
II
Ascites
Laboratories,
tRNA are described from NaCl,
cells
or is
N.Y.
rabbits
kindly
The preparation paper
treated
(5).
with
of modified
when required, twice
with
washing
lysed
incubated medium,
and then
hr at 4°C to obtain in solution ribosomal 27,000
rpm,
4'C, for
gradients
were rotor
fractions SDS-method:
mRNA from were
1 mM EDTA, 0.1 M NaCl, one volume
of packed
fractions. added
the
An equal
and the mixture
total
cells
or to 5 volumes
phase
re-extracted
The resulting
aqueous
and the phenol at 4'C.
aqueous
phase
and re-extracted from
the
again final
with with
aqueous
K [0.6%
buffer, dient
pH 7.4,
was used to separate
in a SW 40 Spinco was pooled
rotor
at 4'C
volume
by adjusting
and precipitated
RNAs by spinning (5,6).
767
SDS, added
to
supernatant phase was
with
the
K for
15
first
of phenol.
The RNA
to 0.3 M NaCl,
and
by centrifugation 5 mM Tris-HCl
at 40,000
The 7s to 16s region
RNA was collected
Phenol-
was then
of Buffer
was combined
the addition of 2 volumes of ethanol. The RNA was recovered at 27,000 g for 10 min. A 5 to 20% sucrose density gradient hrs
were
The aqueous
an equal phase
(2)
supernatant
phenol
5 volumes
ribosome
(6);
ribosomal-free
30 min phase
Two methods
pH 5.01
distilled
times
sucrose
the pelleted
buffer,
at
rpm in a 65
reported
of the
of water-saturated
the
mRNA.
of the Buffer
acetate
at 4'C for
removed
at 60,000
and the ribosome-free
0.01 M potassium
rotor
from
to obtain
5
M MgClz]; for
fractions
mRNA from
with
for
in SW 27 Spinco
previously
washed
dissolved
centrifugation
10 volumes
shaken
min
was precipitated
were
SDS-method:
were
rotor
0.0015
processed
2
(5).
60 Spinco
ribosomal
M
10 mM NaF,
incubated
pellets
gradient
cells
were
described
by centrifugation
as follows:
volume
cells
and 0.13
with
cells
M KCl,
by the SDS-method
prepared
the
pH 7.4,
12 hr at 4OC and then
with
containing
incubation,
0.01
Burness,
obtained
The ribosome
Different
(1)
cell
system
cells
(2),
rpm in a Ti
density
used:
A.T.H.
were
of packed
by centrifugation
separately
mRNA were was prepared
fractions
sucrose
pelleted for
of preparing
buffer,
each experiment.
of the
and washed
as previously
at 55,000
obtained
cell-free
3 mM NaF when
ribosomes.
were using
After
prepared
M Tris-HCl
patterns
indicated Spinco
total
A[O.Ol
of Krebs
buffer
containing
an S-30
by Dr.
One volume
at 37'C.
The S-30 was centrifuged
supplied Reticulocytes
Krebs-Ringer-Bicarbonate
were
fraction
by degradation.
phenylhydrazine
7.4 mM MgC12 and 5 mM KC1 (6).
volumes
lost
no
and METHODS were
in a previous
New Zealand
NaF,
tumor
of polyribosomes,
in the supernatant
subunits MATERIALS
Krebs
dissociation
by centrifugation
rpm for
14
of the graand
Vol. 47, No. 4, 1972
washed lowed
twice
BIOCHEMICAL
with
70% ethanol
by two more washing
of Hp 0 and lyophilized. of water
for
purified
assay
rotor
for
The preparation for
protein
previously
methods
(5).
identical
reticulocyte
in a Krebs
cell
The incubation
1).
wash free
was performed
0.5 ml volume
gradient
in a SW 40
10s RNA extracted activity
fraction
system
in
10s RNA was further
stimulatory
ribosomal
ascites
density
(Figure
fol-
in a minimum
When indicated,
rpm at 4'C
had the
pH 5.5,
The RNA was dissolved
activity.
at 40,000
acetate
was redissolved
in a 15 to 30% sucrose
of rabbit
described
95% ethanol.
biological
26 hrs
synthesis
2% potassium
The RNA obtained
for
by SDS or SDS-phenol
containing
with
by centrifugation
Spinco
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
were at 37'C
per
and the performed for
O.D.260. assay as
20 minutes,
1.4 1.2 10 -
-
0.6
Fig.
1:
Sucrose density gradient profile of RNA extracted from monoribosomes after NaF treatment. RNA was extracted from monoribosomes after NaF treatment and analyzed on sucrose gradients as described in "Methods" (A) Pattern obtained after 5-20% sucrose density gradient centrifugation. The shaded area including the 10s peak was assayed for biological activity. (B) Pattern obtained after 15-30% sucrose density centrifugation of the RNA present in the shaded area of (A).
768
BIOCHEMICAL
fol. 47, No. 4, 1972
and [3H]leucine
incorporation
The small tions
makes it
by direct
curve
20 min) standard
over
a range
assuming tion
of 0 to 10 pmole
an average
molecular
least
two points
The amount ponding
of
to the
were
10s RNA added weight
of RNA content into
every
set
portion
daltons
of the
(7).
for
assayed;
curve
was taken
a known amount
system
For each preparawere
standard
in a RNA preparation
of incorporation
system.
of experiments
to the 50 ~1 cell-free
of the RNA fractions
on the linear
employing protein
to the cell-free
for
of 2~10~
concentrations
10s RNA present level
10s RNA added
frac-
was determined
(incorporation
2) was determined
(5).
ribosomal
determination
activity
of purified
of 10s RNA, three
cpms were measured
mRNA content
biological
(Figure
RESEARCH COMMUNICATIONS
in different
an accurate
measurement.
relating
curve
acid-insoluble
of 10s RNA present
to obtain
density
to O.D.260
This
into
amount
difficult
optical
a standard per
total
AND BIOPHYSICAL
at
(Figure
as that
of purified
2).
corres10s RNA
on the curve.
1
‘I
0 l!L 0
L-~.I-.L-L 2
I 6
4
mRNA
Fig.
2:
I 8
10
(pmoles)
Messenger RNA concentration curve. Purified rabbit 10s RNA prepared as described in "Methods" was added to the Krebs lysate cell-free system at different concentrations and assayed as described in "Methods' [3H]-leucine (39C/mM) was used as the labelled precursor.
RESULTS: Conditions
of incubation
of reticulocytes
cause complete dissociation of polyribosomes The 40s subunits are significantly decreased The cells
were
In these
cells,
10 min
I
(4C)
then
washed
polyribosome
and was almost
with
inhibitor,
reformation
reached
after 769
employed
which
to 80s ribosomes (Figure 3,4B). after NaF treatment (Figure 3).
to remove the complete
NaF were
60 min
and incubated 20% of control (Figure
4D).
at 37'C. levels
within
Vol. 47, No. 4, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
6.0 .
Fig.
from cells
3:
Effects of NaF on ribosome pattern: (A) Ribosome pattern in cells prior to incubation with NaF. The fractions indicated by shaded areas P,M and 40s were assayed for mRNA activity and the results summarized in Table I, experiment II. (B) Ribosome pattern of cells recovered after incubation with 10 u&l NaF for 60' at 37'C. The fractions indicated by shaded areas P, M and 40s were assayed for mRNA activity and the results sumP represents polyribosome region, M marized in Table I, experiment I. and 40s represents 405 ribosome subrepresents monoribosome region, unit region.
In cells
not
all
fractions,
cell
treated
monoribosome
with region
less able
than from
that
10s RNA activity
incubated NaF,
with NaF, was isolated
over
(Table
over from
75% of the mRNA activity the polyribosomes (Table
75% of the mRNA activity 1, Figure
4B).
In control
3% of the total mRNA recovered from 40s subunits or from the supernatant was not
inhibited
the cell fraction.
in preparations
18s RNA.
770
was recovered and NaF treated
recovered 1). In in
the cells,
fractions was extracIt was demonstrated containing
up to 95%
Vol. 47, No. 4, 1972
Fig.4:
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Reformation of polysomes after removal of NaF. 5 ml of packed cells were incubated with 10 mM NaF for 60 min as described in Table 1. After incubation the cells were washed with washing medium containing 3 mM NaF, lysed, ribosomes pelleted and analyzed by sucrose density gradient centrifugation for 3 hrs. (A) Ribosomal pattern obtained from 5 ml of packed cells not preincubated with NaF, following the above described procedure. (B) Ribosome pattern following NaF treatment for 60 min (C) and (D) 5 ml of packed cells were incubated as in (A), the NaF removed by 2x washing with washing medium, reincubated respectively for 10 (C) and 60 (D) min in the incubation medium (see "Methods"), then lysed and ribosome pattern obtained. P represents polyribosome region, D represents dimer region and M represents monoribosome region.
10 minutes medium,
after
removal
40% of the mRNA is
60 minutes
after
control,
recovered
is
found
NaF removal, from
of NaF and incubation in the dimer
region
of cells (Table
70% of the mRNA activity,
polyribosomes
(Table
771
2, Figure
in a NaF free 2,Figure
a value 4D).
4C).
comparable
to
Vol. 47, No. 4, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE 1 Distribution
of mRNA in NaF treated Total Cells __ 40
VOLUME [ml] [I]
NaF
rabbit
reticulocytes.
-T.R.P. -
p-
450
0-D-260
M
40
sup.
-
-
-
240
30
214
1.6
-
mRNA [pmole]
510
350
40
311
14
48
VOLUME [ml]
40
-
-
-
-
240
o-D.260
0
450
203
53
4.2
-
mRNA [pmole]
490
340
248
57
15
7.2
cells; [II] - cells not preincubated with NaF. III = NaF treated Messenger RNA was obtained with the "SDS-method" from fractions P, M and 40 as indicated in Fig.3, and from the total ribosomal pellet (T.R.P.) as described in the "Methods". The SDS-Phenolmethod was used to prepare 10s RNA from the ribosome-free supernatant (Sup.). The same method was used to obtain 10s RNA fraction from total cells. The Q.D.260 represents the amount present in the ribosome fractions prior to mRNA isolation. pmoles of mRNA are obtained as described in "Methods". TABLE 2 Distribution
of mRNA in NaF treated
reticulocytes
after
Messenger P 4.8
NaF removal.
RNA [pmoles] -M -D 8.4 31.0
[II
Fluoride
[II]
10 min after
NaF removal
6.2
21.0
25.0
[III]
60 min after
NaF removal
35.0
8.2
8.4
Messenger RNA was obtained (D) and monoribosome region Fig.4. Biological activity DISCUSSION: NaF induced
inhibition
from the polyribosome region (P), dimer region (M) of sucrose gradients B, C and D shown in was assayed as described in "Methods".
of protein
ted with polyribosome dissociation AlOS RNA fraction has been shown of NaF-treated evidence
that
cells
(8).
synthesis
The present
studies
the mRNA in NaF-treated
cells
association
with
80s monoribosomes
under
synthesis.
There
is no detectable
loss
supernatant
or by degradation.
The demonstration
that
in reticulocytes
is
and accumulation of 80s ribosomes to be present in the total ribosomal is
provide
the
almost
totally
conditions
of cessation
of biologically
biologically
active
772
first
active
associa(1). pellet
direct conserved
in
of protein mRNA into
mRNA can be conserved
in
the
Vol. 47, No. 4, 1972
reticulocytes "masked
BIOCHEMICAL
without
mRNA" which
being
that
actions
eggs,
may be analogous
suggested
maternal
to exist
(12,13).
or rend,ered result
is possible inactive
in effects
potentially
similar
to those
active
Although
the rate
of protein
able
to that
in untreated
than
40% of the mRNA has become associated
rate
of protein
mRNA associated rapid
rate
inhibits elongation reports together, are
the present
compatible
a mechanism
(3,15).
with which
ACKNOWLEDGEMENTS:
cells
data
whose
expression
of
be further
This
investigation
limited
is
only
while
using
GM-18153
and N.S.F.
grant
Award
the American
supported
by N.I.H.
is
the
of a more of
NaF specifically not
affecting
study
chain
confirms
previous
of NaF treatment. cell-free
Taken
systems
of protein
(16-18)
synthesis
by
at present.
GB-27388x.
Training
than
that
reformation
(2).
was supported
Research
there
partial
initiation
defined
indicate
by the amount
the present
obtained
and less
data
shown that
chains
GM-14452,
less
is not
to inhibit
cannot
of NaF (2),
These
has been
a Faculty
an EMBO visiting
may be (14)
compar-
polyribosomes
in 40s subunits
and those
Hematology
without
to a level
with
In addition,
from
cells
factors
from NaF inhibition
a decrease
NaF acting
also
periods
these
(2).
of new polypeptide
demonstrating
mRNA in
has returned
of mRNA when there
initiation
variable
10 min of removal
It
recovery
or release (3)
within
polyribosomes.
following
the
synthesis
in these
of translation
polyribosomes
cells
egg is
of NaF in preventing
are in polyribosomes
with
animal
mRNA.
cells
synthesis
for
that
of
on erythropoiesis
by inhibitory
biologically
40% of the ribosomes
Studies
and stored
It
other
in the unfertilized
(10,ll).
temporarily
to the presence
in several
mRNA stored
fertilization
mRNA may be synthesized
translated
"masked"
translated
has been
(9) * In sea urchin expressed only after indicate
being
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dr.
Cancer
Grant
in part
by N.I.H.
Bank is Society.
TI-AM5231.
Dr.
grants
a recipient
of
Dr.
is
L.W.Dow S. Metafora
is
Fellow. REFERENCES
1. 2. 3. 4. 5. 6. 7. 8. 9. 10.
Marks, P.A., E.R. Burka, F. Conconi, W. Per1 and R.A. Rifkind. Proc. Nat. Acad. Sci. 53:1437, 1965. Conconi, F.E, A. Bank and P.A. Marks. J. Mol. Biol. 19:525, 1966. Colombo, B., C. Vesco and C. Baglioni. Proc. Nat. Acad, Sci. -61:651, 1968. Hogan, B.L. Bioch. Biophys. Acta. 182:264, 1969. Metafora, S., M. Terada, L.W. Dow, P.A. Marks and A. Bank. Proc. Nat. Acad. Sci. in press. Lockhard, R.E. and J.B. Lingrel, Bioch. Biophys. Res. Commu. 37:204, 1969. Williamson, R., M. Morrison, G. Lanyon, R. Eason and J. Paul.Biochemistry 10:3014, 1971. Gbleu, B., G. Huez, A. Burny and G. Marbaix. Bioch. Biophys. Acta -138: 186, 1967. Spirin, A.S. in Current Topics in Development Biology 1:2, 1966. Gross, P.R. and Cousineau, G.H. Biochem. and Biophys. Res. Commu.10:321, 1963.
773
Vol. 47, No. 4, 1972
11. 12. 13. 14. 15. 16. 17. 18.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Exptl. Cell Res. -33:368, 1964. Gross, P.R. and Cousineau, G.H. Wilt, F.H. J. Mol. Biol. 1965. -12:331, Marks, P.A. and Rifkind, R.A. -___Science 175:1955, 1972. Metafora, S., Felicetti, L. and Gambino, R. Proc. Nat. Acad. Sci.68:660, 1971 21:51, 1966Lin, S., Moesteller, D. and Hardesty, B. J. Mol. Biol. Lebleu, B., G. Marbaix, J. Chantrenne, A. Burny and G. Hzz, Bioch. Biophys. Res. Commu. 40:731, 1970. Hoers, W. andK.S. McCarty, Bioch. Biophys. Acta 228:526, 1971. Irving, J. and Hardesty, B. Fed. Proc. 31:368a,1972.
774
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
CONSERVATION OF GLOBIN MESSENGER RNA IN RABBIT RETICULOCYTE MONORIBOSOMES AFTER SODIUM FLUORIDE TREATMENT. M. Toada,
J. Bavlkh , 1. W. Dvw, A. Eunh and P. A. Mahh
S. [email protected],
Department of Human Genetics Development, and Medicine Columbia University, College Physicians & Surgeons New York, N.Y. 10032
Received
April
and of
12, 1972
SUMMARY: Following NaF treatment of rabbit reticulocytes, polyribosomes dissociate to monoribosomes with concomitant cessation of protein synthesis. mRNA was isolated from different fractions of the cell before and after NaF treatment and quantitated by assay for globin synthesis in a cell-free system prepared from Krebs ascites tumor cells. mRNA activity present in polyribosomes of control cells was recovered quantitatively from monoribosomes following NaF treatment. On removal of NaF, polyribosomes reform with mRNA activity similar to that of control cells. During polyribosome dissociation, no significant amount of mRNA is recovered from ribosomal subunits, the supernatant fraction or is lost by degradation. Reticulocytes synthesis
at the
synthesize vious
ribosomes are
level
from
sodium
with
(NaF),
Thus,
mRNA for
globin
Further,
these
directly
polyribosome cating
dissociation
during
in Hela
that
with
polyribosomes
On release
is
or number cells
recovered
from NaF inhibition, 766
Copyright@1972,by
Academic Press,Inc.
treatment
(3)
cells
do not Pre-
of reticulocytes
to dissociate
into
These
removal
of NaF,
the rate
begin
to reform(l).
rate
effects
80s
(1,2).
inhibition the
these
of protein
are hemoglobins.
and polyribosomes
showed
on the size
after
cells;
that
of protein of protein
of polyribosomes and ascites
that the effect of NaF is not specific for This paper demonstrates that after treatment
associated region.
synthesis
mechanisms
formed
polyribosomes
conserved
studies
dependent
demonstrated
causes
to normal
is
studying
in mammalian
2 to 3 minutes
returns
for
90% of the protein
of protein
Within
NaF. not
than
cessation
synthesis
system
of translation
our laboratory
fluoride
reversible.
protein
a good model
RNA and more
reports
with
are
tumor
of NaF of
synthesis synthesis
by is
(2).
NaF causes
cells
(4),
indi-
reticulocytes. with NaF, the mRNA initially
quantitatively the mRNA again
in the monoribosomes becomes associated
Vol. 47, No. 4, 1972
with
BIOCHEMICAL
polyribosomes.
significant
Following
amount
or associated
NaF induced
of mRNA is
with
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
found
ribosomal
Kettering
II
Ascites
Laboratories,
tRNA are described from NaCl,
cells
or is
N.Y.
rabbits
kindly
The preparation paper
treated
(5).
with
of modified
when required, twice
with
washing
lysed
incubated medium,
and then
hr at 4°C to obtain in solution ribosomal 27,000
rpm,
4'C, for
gradients
were rotor
fractions SDS-method:
mRNA from were
1 mM EDTA, 0.1 M NaCl, one volume
of packed
fractions. added
the
An equal
and the mixture
total
cells
or to 5 volumes
phase
re-extracted
The resulting
aqueous
and the phenol at 4'C.
aqueous
phase
and re-extracted from
the
again final
with with
aqueous
K [0.6%
buffer, dient
pH 7.4,
was used to separate
in a SW 40 Spinco was pooled
rotor
at 4'C
volume
by adjusting
and precipitated
RNAs by spinning (5,6).
767
SDS, added
to
supernatant phase was
with
the
K for
15
first
of phenol.
The RNA
to 0.3 M NaCl,
and
by centrifugation 5 mM Tris-HCl
at 40,000
The 7s to 16s region
RNA was collected
Phenol-
was then
of Buffer
was combined
the addition of 2 volumes of ethanol. The RNA was recovered at 27,000 g for 10 min. A 5 to 20% sucrose density gradient hrs
were
The aqueous
an equal phase
(2)
supernatant
phenol
5 volumes
ribosome
(6);
ribosomal-free
30 min phase
Two methods
pH 5.01
distilled
times
sucrose
the pelleted
buffer,
at
rpm in a 65
reported
of the
of water-saturated
the
mRNA.
of the Buffer
acetate
at 4'C for
removed
at 60,000
and the ribosome-free
0.01 M potassium
rotor
from
to obtain
5
M MgClz]; for
fractions
mRNA from
with
for
in SW 27 Spinco
previously
washed
dissolved
centrifugation
10 volumes
shaken
min
was precipitated
were
SDS-method:
were
rotor
0.0015
processed
2
(5).
60 Spinco
ribosomal
M
10 mM NaF,
incubated
pellets
gradient
cells
were
described
by centrifugation
as follows:
volume
cells
and 0.13
with
cells
M KCl,
by the SDS-method
prepared
the
pH 7.4,
12 hr at 4OC and then
with
containing
incubation,
0.01
Burness,
obtained
The ribosome
Different
(1)
cell
system
cells
(2),
rpm in a Ti
density
used:
A.T.H.
were
of packed
by centrifugation
separately
mRNA were was prepared
fractions
sucrose
pelleted for
of preparing
buffer,
each experiment.
of the
and washed
as previously
at 55,000
obtained
cell-free
3 mM NaF when
ribosomes.
were using
After
prepared
M Tris-HCl
patterns
indicated Spinco
total
A[O.Ol
of Krebs
buffer
containing
an S-30
by Dr.
One volume
at 37'C.
The S-30 was centrifuged
supplied Reticulocytes
Krebs-Ringer-Bicarbonate
were
fraction
by degradation.
phenylhydrazine
7.4 mM MgC12 and 5 mM KC1 (6).
volumes
lost
no
and METHODS were
in a previous
New Zealand
NaF,
tumor
of polyribosomes,
in the supernatant
subunits MATERIALS
Krebs
dissociation
by centrifugation
rpm for
14
of the graand
Vol. 47, No. 4, 1972
washed lowed
twice
BIOCHEMICAL
with
70% ethanol
by two more washing
of Hp 0 and lyophilized. of water
for
purified
assay
rotor
for
The preparation for
protein
previously
methods
(5).
identical
reticulocyte
in a Krebs
cell
The incubation
1).
wash free
was performed
0.5 ml volume
gradient
in a SW 40
10s RNA extracted activity
fraction
system
in
10s RNA was further
stimulatory
ribosomal
ascites
density
(Figure
fol-
in a minimum
When indicated,
rpm at 4'C
had the
pH 5.5,
The RNA was dissolved
activity.
at 40,000
acetate
was redissolved
in a 15 to 30% sucrose
of rabbit
described
95% ethanol.
biological
26 hrs
synthesis
2% potassium
The RNA obtained
for
by SDS or SDS-phenol
containing
with
by centrifugation
Spinco
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
were at 37'C
per
and the performed for
O.D.260. assay as
20 minutes,
1.4 1.2 10 -
-
0.6
Fig.
1:
Sucrose density gradient profile of RNA extracted from monoribosomes after NaF treatment. RNA was extracted from monoribosomes after NaF treatment and analyzed on sucrose gradients as described in "Methods" (A) Pattern obtained after 5-20% sucrose density gradient centrifugation. The shaded area including the 10s peak was assayed for biological activity. (B) Pattern obtained after 15-30% sucrose density centrifugation of the RNA present in the shaded area of (A).
768
BIOCHEMICAL
fol. 47, No. 4, 1972
and [3H]leucine
incorporation
The small tions
makes it
by direct
curve
20 min) standard
over
a range
assuming tion
of 0 to 10 pmole
an average
molecular
least
two points
The amount ponding
of
to the
were
10s RNA added weight
of RNA content into
every
set
portion
daltons
of the
(7).
for
assayed;
curve
was taken
a known amount
system
For each preparawere
standard
in a RNA preparation
of incorporation
system.
of experiments
to the 50 ~1 cell-free
of the RNA fractions
on the linear
employing protein
to the cell-free
for
of 2~10~
concentrations
10s RNA present level
10s RNA added
frac-
was determined
(incorporation
2) was determined
(5).
ribosomal
determination
activity
of purified
of 10s RNA, three
cpms were measured
mRNA content
biological
(Figure
RESEARCH COMMUNICATIONS
in different
an accurate
measurement.
relating
curve
acid-insoluble
of 10s RNA present
to obtain
density
to O.D.260
This
into
amount
difficult
optical
a standard per
total
AND BIOPHYSICAL
at
(Figure
as that
of purified
2).
corres10s RNA
on the curve.
1
‘I
0 l!L 0
L-~.I-.L-L 2
I 6
4
mRNA
Fig.
2:
I 8
10
(pmoles)
Messenger RNA concentration curve. Purified rabbit 10s RNA prepared as described in "Methods" was added to the Krebs lysate cell-free system at different concentrations and assayed as described in "Methods' [3H]-leucine (39C/mM) was used as the labelled precursor.
RESULTS: Conditions
of incubation
of reticulocytes
cause complete dissociation of polyribosomes The 40s subunits are significantly decreased The cells
were
In these
cells,
10 min
I
(4C)
then
washed
polyribosome
and was almost
with
inhibitor,
reformation
reached
after 769
employed
which
to 80s ribosomes (Figure 3,4B). after NaF treatment (Figure 3).
to remove the complete
NaF were
60 min
and incubated 20% of control (Figure
4D).
at 37'C. levels
within
Vol. 47, No. 4, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
6.0 .
Fig.
from cells
3:
Effects of NaF on ribosome pattern: (A) Ribosome pattern in cells prior to incubation with NaF. The fractions indicated by shaded areas P,M and 40s were assayed for mRNA activity and the results summarized in Table I, experiment II. (B) Ribosome pattern of cells recovered after incubation with 10 u&l NaF for 60' at 37'C. The fractions indicated by shaded areas P, M and 40s were assayed for mRNA activity and the results sumP represents polyribosome region, M marized in Table I, experiment I. and 40s represents 405 ribosome subrepresents monoribosome region, unit region.
In cells
not
all
fractions,
cell
treated
monoribosome
with region
less able
than from
that
10s RNA activity
incubated NaF,
with NaF, was isolated
over
(Table
over from
75% of the mRNA activity the polyribosomes (Table
75% of the mRNA activity 1, Figure
4B).
In control
3% of the total mRNA recovered from 40s subunits or from the supernatant was not
inhibited
the cell fraction.
in preparations
18s RNA.
770
was recovered and NaF treated
recovered 1). In in
the cells,
fractions was extracIt was demonstrated containing
up to 95%
Vol. 47, No. 4, 1972
Fig.4:
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Reformation of polysomes after removal of NaF. 5 ml of packed cells were incubated with 10 mM NaF for 60 min as described in Table 1. After incubation the cells were washed with washing medium containing 3 mM NaF, lysed, ribosomes pelleted and analyzed by sucrose density gradient centrifugation for 3 hrs. (A) Ribosomal pattern obtained from 5 ml of packed cells not preincubated with NaF, following the above described procedure. (B) Ribosome pattern following NaF treatment for 60 min (C) and (D) 5 ml of packed cells were incubated as in (A), the NaF removed by 2x washing with washing medium, reincubated respectively for 10 (C) and 60 (D) min in the incubation medium (see "Methods"), then lysed and ribosome pattern obtained. P represents polyribosome region, D represents dimer region and M represents monoribosome region.
10 minutes medium,
after
removal
40% of the mRNA is
60 minutes
after
control,
recovered
is
found
NaF removal, from
of NaF and incubation in the dimer
region
of cells (Table
70% of the mRNA activity,
polyribosomes
(Table
771
2, Figure
in a NaF free 2,Figure
a value 4D).
4C).
comparable
to
Vol. 47, No. 4, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE 1 Distribution
of mRNA in NaF treated Total Cells __ 40
VOLUME [ml] [I]
NaF
rabbit
reticulocytes.
-T.R.P. -
p-
450
0-D-260
M
40
sup.
-
-
-
240
30
214
1.6
-
mRNA [pmole]
510
350
40
311
14
48
VOLUME [ml]
40
-
-
-
-
240
o-D.260
0
450
203
53
4.2
-
mRNA [pmole]
490
340
248
57
15
7.2
cells; [II] - cells not preincubated with NaF. III = NaF treated Messenger RNA was obtained with the "SDS-method" from fractions P, M and 40 as indicated in Fig.3, and from the total ribosomal pellet (T.R.P.) as described in the "Methods". The SDS-Phenolmethod was used to prepare 10s RNA from the ribosome-free supernatant (Sup.). The same method was used to obtain 10s RNA fraction from total cells. The Q.D.260 represents the amount present in the ribosome fractions prior to mRNA isolation. pmoles of mRNA are obtained as described in "Methods". TABLE 2 Distribution
of mRNA in NaF treated
reticulocytes
after
Messenger P 4.8
NaF removal.
RNA [pmoles] -M -D 8.4 31.0
[II
Fluoride
[II]
10 min after
NaF removal
6.2
21.0
25.0
[III]
60 min after
NaF removal
35.0
8.2
8.4
Messenger RNA was obtained (D) and monoribosome region Fig.4. Biological activity DISCUSSION: NaF induced
inhibition
from the polyribosome region (P), dimer region (M) of sucrose gradients B, C and D shown in was assayed as described in "Methods".
of protein
ted with polyribosome dissociation AlOS RNA fraction has been shown of NaF-treated evidence
that
cells
(8).
synthesis
The present
studies
the mRNA in NaF-treated
cells
association
with
80s monoribosomes
under
synthesis.
There
is no detectable
loss
supernatant
or by degradation.
The demonstration
that
in reticulocytes
is
and accumulation of 80s ribosomes to be present in the total ribosomal is
provide
the
almost
totally
conditions
of cessation
of biologically
biologically
active
772
first
active
associa(1). pellet
direct conserved
in
of protein mRNA into
mRNA can be conserved
in
the
Vol. 47, No. 4, 1972
reticulocytes "masked
BIOCHEMICAL
without
mRNA" which
being
that
actions
eggs,
may be analogous
suggested
maternal
to exist
(12,13).
or rend,ered result
is possible inactive
in effects
potentially
similar
to those
active
Although
the rate
of protein
able
to that
in untreated
than
40% of the mRNA has become associated
rate
of protein
mRNA associated rapid
rate
inhibits elongation reports together, are
the present
compatible
a mechanism
(3,15).
with which
ACKNOWLEDGEMENTS:
cells
data
whose
expression
of
be further
This
investigation
limited
is
only
while
using
GM-18153
and N.S.F.
grant
Award
the American
supported
by N.I.H.
is
the
of a more of
NaF specifically not
affecting
study
chain
confirms
previous
of NaF treatment. cell-free
Taken
systems
of protein
(16-18)
synthesis
by
at present.
GB-27388x.
Training
than
that
reformation
(2).
was supported
Research
there
partial
initiation
defined
indicate
by the amount
the present
obtained
and less
data
shown that
chains
GM-14452,
less
is not
to inhibit
cannot
of NaF (2),
These
has been
a Faculty
an EMBO visiting
may be (14)
compar-
polyribosomes
in 40s subunits
and those
Hematology
without
to a level
with
In addition,
from
cells
factors
from NaF inhibition
a decrease
NaF acting
also
periods
these
(2).
of new polypeptide
demonstrating
mRNA in
has returned
of mRNA when there
initiation
variable
10 min of removal
It
recovery
or release (3)
within
polyribosomes.
following
the
synthesis
in these
of translation
polyribosomes
cells
egg is
of NaF in preventing
are in polyribosomes
with
animal
mRNA.
cells
synthesis
for
that
of
on erythropoiesis
by inhibitory
biologically
40% of the ribosomes
Studies
and stored
It
other
in the unfertilized
(10,ll).
temporarily
to the presence
in several
mRNA stored
fertilization
mRNA may be synthesized
translated
"masked"
translated
has been
(9) * In sea urchin expressed only after indicate
being
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dr.
Cancer
Grant
in part
by N.I.H.
Bank is Society.
TI-AM5231.
Dr.
grants
a recipient
of
Dr.
is
L.W.Dow S. Metafora
is
Fellow. REFERENCES
1. 2. 3. 4. 5. 6. 7. 8. 9. 10.
Marks, P.A., E.R. Burka, F. Conconi, W. Per1 and R.A. Rifkind. Proc. Nat. Acad. Sci. 53:1437, 1965. Conconi, F.E, A. Bank and P.A. Marks. J. Mol. Biol. 19:525, 1966. Colombo, B., C. Vesco and C. Baglioni. Proc. Nat. Acad, Sci. -61:651, 1968. Hogan, B.L. Bioch. Biophys. Acta. 182:264, 1969. Metafora, S., M. Terada, L.W. Dow, P.A. Marks and A. Bank. Proc. Nat. Acad. Sci. in press. Lockhard, R.E. and J.B. Lingrel, Bioch. Biophys. Res. Commu. 37:204, 1969. Williamson, R., M. Morrison, G. Lanyon, R. Eason and J. Paul.Biochemistry 10:3014, 1971. Gbleu, B., G. Huez, A. Burny and G. Marbaix. Bioch. Biophys. Acta -138: 186, 1967. Spirin, A.S. in Current Topics in Development Biology 1:2, 1966. Gross, P.R. and Cousineau, G.H. Biochem. and Biophys. Res. Commu.10:321, 1963.
773
Vol. 47, No. 4, 1972
11. 12. 13. 14. 15. 16. 17. 18.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Exptl. Cell Res. -33:368, 1964. Gross, P.R. and Cousineau, G.H. Wilt, F.H. J. Mol. Biol. 1965. -12:331, Marks, P.A. and Rifkind, R.A. -___Science 175:1955, 1972. Metafora, S., Felicetti, L. and Gambino, R. Proc. Nat. Acad. Sci.68:660, 1971 21:51, 1966Lin, S., Moesteller, D. and Hardesty, B. J. Mol. Biol. Lebleu, B., G. Marbaix, J. Chantrenne, A. Burny and G. Hzz, Bioch. Biophys. Res. Commu. 40:731, 1970. Hoers, W. andK.S. McCarty, Bioch. Biophys. Acta 228:526, 1971. Irving, J. and Hardesty, B. Fed. Proc. 31:368a,1972.
774