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Selective resistance of bacterial polyadenylate-containing RNA to hydrolysis by guanosine 3′-5′-monophosphate-sensitive nuclease of Bacillus brevis
BIOCHEMICAL
Vol. 103, No. 2,1981 November 30, 1981
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 454-460
SELECTIVE RESISTANCE OF BACTERIAL POLYADENYLATE-CONTAINING RNA TO HYDROLYSIS BY GUANOSINE3'-5'-MONOPHOSPHATE-SENSITIVE NUCLEASE OF BACILLUS BREVIS Yanamandra Gopalakrishna and Nilima Sarkar Department of Metabolic Regulation Boston Biomedical Research Institute Boston, MA. 02114 and Department of Biological Chemistry Harvard Medical School Boston, MA. 02115 Received
October
12.1981 SUMMARY
Earlier experiments had shown that the degradation of newly synthesized RNA in permeable cells of Bacillus brevis is mediated primarily by a guanosine 3',5'-monophosphate-sensitive 3' -exonuclease [N. Sarkar and H. Paulus (1975) J. Biol. Chem. 250, 684-6901. More recently, we found that a substantial fraction of pulse-labeled RNA in B. brevis is polyadenylylated [N. Sarkar, D. Langley, and H. Paulus (1978) Biochemistry 17, 3468-34741, and it was thus of interest to examine the effect of polyadenylylation on Purified the susceptibility of RNA to degradation by the 3'-exonuclease. 3'-exonuclease from B. brevis hydrolyzed the unadenylylated fraction of pulse-labeled RNA from B. brevis much more rapidly than poly(A)-containing results were obtained with the pulse-labeled unadenylylated RNA. Similar Control experiand polyadenylylated RNA fractions from BaciZZus subtiZis. ments showed that the differential hydrolysis of the labeled RNA preparations by 3'-exonuclease was not due to the presence of inhibitors or activators. These results suggest that the stability of mRNA in BaciZZus species may be regulated by polyadenylylation.
The degradation
brevis is primarily
Bacillus vity
is
sensitive
(1, 2). acts
very
bacterial this
INTRODUCTION synthesized RNA in
of newly
to inhibition
The observation slowly
poly(A)-containing
B. brevis (3).
by guanosine
that
this
on poly(adenylic
mRNA might
possibility
due to the action
led
molecules High
levels
0 1981 by Academic Press, of reproduction in any form
suggested
of relatively
among the rapidly of poly(A)-RNA
0006-291X/81/220454-07$01.00/0 Copyright All righrs
(2)
Inc. reserved.
RNA from that
454
were
also
acti-
(cGMP) the
3'-end
and
the stability
of
The exploration
of
levels
(30-40%)
of
RNA species
of
high
labeled
of
whose
3',5'-monophosphate
by polyadenylylation.
to the discovery
cells
of an exonuclease
enzyme degrades acid)
be modulated
toluene-treated
found
in Escherichia
BIOCHEMICAL
Vol. 103, No. 2,198l
coZi
and BaciZZus
resemble cation, bacterial
subtilis
(4),
AND
BIOPHYSICAL
both
of which
enzyme from B. brevis
the
we compare
the
by the
harbor
3'-exonucleases
in many respects
sensitivities
RNA to hydrolysis
RESEARCH COMMUNICATIONS
(5,
of unadenylylated
6).
which
In this
communi-
and polyadenylylated from B. brevis.
3'-exonuclease
MATERIALS --AND METHODS Materials [2,8-3H]adenosine (25.5 Ci/mmole) and [5-'Hluridine (25 Ci/mmole) were obtained from New England Nuclear and oligo(dT)-cellulose (Type 7) from P-L Biochemicals. Proteinase K (Boehringer) [l'C?poly(A) and [3H]poly(U) were made from ["C]ADP (0.1 Ci/mmole and [3H]UDP (0.2 Ci/mmole) respectively as described earlier (2). The sources of all other materials are as published earlier (3, 4). Bacterial
Strains
and Growth 8185 and BaciZZus subtiZis ATCC 6051 were supplemented with salts and glucose (4).
Bacill~i~TCC nutrient
broth
grown
in
Labeling of RNA and Fractionation --Two ml of exponentially growing cultures were treated with [2,8-'Hladenosine or [5-3H]uridine (20 pCi) for 30 set and the labeled cells were processed by proteinase K method as described earlier except proteinase K was incubated for 20 min at 37" C (5mg/ml in 10 mM Tris-HCl, pH 7.5) just prior to use (4). Pulse-labeled RNA was fractionated into polyadenylylated and unadenylylated fractions by affinity chromatography on oligo(dT)-cellulose. Unadenylylated RNA was isolated from the unadsorbed fraction by precipitating 5 times with 2.5 volumes of ethanol in the presence of 10 mM MgC12. Poly(A)RNA was isolated from oligo(dT)-cellulose bound fraction by repeatedethanol precipitation in the presence of 10 mM MgClz without carrier. Labeled rRNA and tRNA were isolated from exponentially growing cultures of BaciZZus brevis that had been incubated with [3H]uridine for at least 3 generations as described (4). Nuclease from Bacilhs brevis The cGMP-sensitive nuclease was purified from BacizZus brevis cells as described earlier (2). Ribonuclease-assay ,was done by incubating labeled substrate in 0.1 M Tris-HCl, pH 7.1, 10 mM MgClz, 2 mM MnClz, .lO mM 2-mercaptoethanol and enzyme and measuring the amount of alcohol-soluble product as detailed earlier (2). The assay was done using the conditions where degree of hydrolysis was a linear function of time. A unit of ribonuclease activity was defined as the amount of enzyme that produced 1 nmole of alcoholsoluble product per min from poly(LJ). RESULTS AND DISCUSSION The relative
considerably
and tRNA were bility
of hydrolysis
from B. brevis
3'-exonuc:Lease hydrolyzed
rates
hydrolyzed
to exonucleolytic
are
of various compared
more rapidly
than
at intermediate degradation
in Fig.
1.
polyadenylic rates.
is a function
455
polynucleotides
by purified
Polyuridylic acid,
However,
acid
whereas
since
of the number
was
rRNA
the susceptiof nucleic
Vol. 103, No. 2,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
1
A
I
1
80.
01
ENZYME
(UNITS)
ENZYME(UNITS)
Figure
1:
Rate of exonucleolytic degradation of Hydrolysis was measured using standard cribed in "Materials and Methods," at Substrate input per assay was 0.45 mM 0.2 mM for [ 'C]poly(A) (A*.* A), 0.17 0.17 n&l for [3H]rRNA (D-3).
labeled polyribonucleotides. assay conditions as desthe enzyme levels indicated. for [3H]poly(LJ) (D-D), mM for [3H]tRNA (o-o) and
Figure
2:
(A) Rate of exonucleolytib degradation of [3H]adenosine-labeled unadenylylated RNA and [aH]adenosine-labeled poly(A)-RNA, isolated from BacilZus brevis cells. Hydrolysis was measured using standard assay condition as described in "Materials and Methods" at the enzyme levels indicated. Substrate input per assay was 1500 cpm for [3H]p~1y(A)-~A (o---o) and 1400 cpm for ['Hlunadenylylated RNA (o-0). (B) Rate of exonucleolytic degradation of [3H]adenosine-labeled unadenylylated RNA and ['Hladenosine-labeled poly(A) RNA isolated from BaciZtus sxbtilis cells. Details are as in (A). Substrate input per assay was 1250 cpm for [3H]p~ly(A)-RNA (o---o) and 1150 for [3H]unadenylylated RNA (0-o).
acid
chains,
RNA species
the relative
One can thus
substrate
of the
Exponentially
pulse-labeled
earlier
growing
fraction in Fig.
more rapidly responding
the
that not (2)
than
with
acid
is
suggested
by these
a relatively
poor
with
synthetic
but also
in comparison
with
natural
of B. brevis into
fraction
Similar
from B. subtilis (data
not
456
were
pulse-labeled
an unadenylylated
chromatography
2A, the unadenylylated
[3H]uracil
than
molecularweight
in comparison
by affinity
ENA fractions
greater
high
only
cultures
poly(A)-RNA.
with
nuclease
polyadenylic
and the ENA was fractionated
adenylylated As shown
conclude
3'-exonuclease,
as shown
adenosine
of
such as rRNA may be considerably
results.
nucleotides
activity
results (Fig. shown).
polyIWAs.
with and a poly-
on oligo(dT)-cellulose was hydrolyzed were
obtained
2B),
or with
The extent
[?I]-
(3). considerably
with
the cor-
ENA fractions of hydrolysis
of
BIOCHEMICAL
Vol. 103, No. 2,198l
polyadenylylated which
RNA did
unadenylylated
that
the
limited
about
poly(A)-RNA
other
with
fraction.
reconstitution
similar
two types
affected
fraction.
In another mixtures
unadenylylated
(Table
sensitivities are not
of
RNA were
exonuclease
type
II).
could
to exonuclease due to the presence
involved
control
I,
to
prepaappropriof
poly(A)-RNA
was sig-
of the complemen-
additivity
was observed
[3H]p~1y(A)-RNA by limiting
and [?I]amounts
show that
of poly(A)-RNA
of inhibitors
out
the hydrolysis
strict
experiments
digestion
carried
so as to permit
amounts
to hydrolysis
to be interby the presence
were
3H-labeled
acid,
3'-exonuclease
the simultaneous
in Table of
pure
in the poly(A)-RNA
experiments
of experiment,
subjected These
be produced
of equivalent
[?I]polyuridylic
that
have
RNA fractions
RNA nor
possible
described
of an activator
As shown
by the addition
thus
type
One of these
unadenylylated
is
when treated
by the
results
and unlabeled
we had observed
to degradation
of control
experiments.
?+labeled
when various
of the
It
suggests
due to contaminating
to be adsorbed
(3).
at
behavior
Indeed,
failed
or the absence
of pulse-labeled
nificantly
of 3'-
the differential
and unadenylylated
or activators
RNA
in the variousnucleic
fractions. Since
yotic
since
inhibitor
fraction.
time
experiments
This
may have been
refractory
such possibilities.
neither
acid
hand,
Accordingly,
ration
tary
a second
caution,
of a nuclease
eliminate
hydrolyzed.
fraction
may be essentially
On the
ate
15% of this
RESEARCH COMMUNICATIONS
10% even at enzyme concentrations
observed
oligo(dT)-cellulose
preted,
exceed
RNA in the poly(A)-RNA
that
with
BIOPHYSICAL
RNA was completely hydrolysis
unadenylylated earlier
not
AND
the discovery
mRNA (7-g),
stabilizing
mRNA.
the microinjection had been modified the results stabilized
of polyadenylylate
much attention Experiments into
frog
by in
vitro
have been somewhat by polyadenylylation
sequences
has been devoted to test oocytes
this
at the 3'-ends to their
possibility
of mRNA fractions
treatment
with
equivocal, (lo-12)whilethe
457
have mostly whose
appropriate
some mRNAs (e.g. stability
potential
poly(A)
enzymes. globin of others
of eucarrole
in
involved content However, mRNA)being (e.g.
of
Unlabeled
c
Alcohol-soluble
were labeled
radioactivity.
RNA fractions corresponding
prepared counterpart,
using
same methods
as
the
b Unlabeled
for
labeled
RNA and
[3H]adenosine-labeled standard condition.
+
f
using cpm.
0.3
+
+
20
46
14
44
amount
used
was equivalent
B. brevis,described in Input for 13HJunadenyl-
0.6
0.6
380 1030
1.2 0.3
+
+
172
1110
0.6
+
+
+
0.3
+
+
+
1.2
(cpm)
Substrate HydrolyzedC
(Units)
3'-Exonuclease
+
a ['HlUnadenylylated RNA and [3H]poly(A)-RNA werepreparedfrom "Materials and Methods" and nuclease digestion was done ylated RNA was 2200 cpm and for [3H]p~ly(~)-RNA was 630
to
on the Exonuclease
422
3'
246
Polyadenylylated
RNA by
RNA Fraction
0.3
Unadenylylated
Unlabeled RNA Fractionb
['HIAdenosine-labeled
Addition
0.6
of
+
Polyadenylylated
of
I
+
Unadenylylated
Radioactive RNA Fractiona
Effect Hydrolysis
TABLE
BlOCHEMlCAL
Vol. 103, No. 2,1981
AND
TABLE 3'-Exonuclea~e
Digestion
[3H]Poly(U)
of
BIOPHYSICAL
II
[3H]P~ly(U)
in
["HlUnadenylylated
RNA or
['HlPoly(A)-RNA
[3H]Unadenylylated RNA
(cd
RESEARCH COMMUNICATIONS
the
presence
of
[%]poly(~)-RNA
(cpm)
Substrate
hydrolyzed
(cpm)
(cpmf
10,000
1,220 1,246
10,000
140
1,246
1,324
10,000
1,070
10,000 Standard and either described
interferon,
dtro
entities,
experiments
with
intracellular
poly(A)-RNA therefore
degradation
cells
in the
that
bacterial
by the bacterial
polyadenyl.ylation
no longer
in bacterial
enzyme as
represented
that
thus
results
the
implicating
the
in the sensitivities
exonuclease. cells
459
cGMF'-sensitive Secondly,
of total
almost
pulse-
by the 3'-exonuclease
complete
One of the major
may thus
stability.
of rapidly
of RNA to the extent with
in
we know from
in mRNA degradation.
RXA to hydrolysis
it
subject-
bacterial
degradation
difference
endows
with
Firstly,
factor
cell
were
The
physiological
as a major
polyadenylylation
14).
of mRNA degradation
of the
Z),
(13,
the RNA fractions
is much simpler.
and unadenylylated
clear
that
of B. brevis
by cGMP (1,
all-or-none
units of substrates
of the enzymology
communication
3 '-exonuclease
labeled
naturally
2,200
the interpretation
inhibited
a nearly
is
ignorance
permeable
we find
It
and thus
to our
in this
RNA is
1,500
mRNAs) was unaffected
due to the fact
In contrast,
described
labeled
is
modification
in part
eucaryotes. mRNA
and crzu-globin
uncertainty
ed to in
L,O18
nuclease assay was done using 0.24 single or combination of labeled in "Materials and Methods."
mengovirus,
resulting
1,500
be the modulation
that
occurs
resistance functions
to of RNA
of mRNA
Vol. 103, No. 2,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
ACKNOWLEDGMENT We are grateful to Dr. reading of the manuscript.
H. Paulus for stimulating This work was supported
discussions by NIH grant
and critical GM 26517.
REFERENCES 1.
Paulus, Plenum
H. and Sarkar, N. (1974) Control Publishing Corporation, New York.
2.
Sarkar,
N. and Paulus,
3.
Sarkar,
N.,
4.
Gopalakrishna, 3545-3554.
5.
Nossal,
N. G. and Singer,
M. F.
6.
Kerjan,
P. and Szulmajster,
J.
7.
Darnell, J. E., Wall, R. and Tushinski, Sci. USA 68, 1321-1325.
a.
Edmonds, M., Vaughan, M. H. and Nakazato, Sci. USA 68, 1336-1340.
9.
Lee, S. Y., Mendecki, USA 68, 1331-1335.
Langley, Y.,
H. (1975)
J. Biol.
D. and Paulus, Langley,
J.,
of Transcription, Chem. 250,
H. (1978)
D. and Sarkar, (1968) (1976)
Brawermann,
Biochim. R. J.
Nut.
Acids
Chem. 243, 58,
Res.
9,
913-922.
533-541.
(1971)
Proc.
H. (1971)
G. (1971)
17, 3468-3474.
Natl.
Proc.
Proc.
Natl.
Natl.
U. A., Marbaix, G., Huez, H. (1976) Eur. J. Biochem.
Acad. Acad.
Acad.
Sci.
10.
Nudel, U., M., Hubert,
11.
G., Huez, G., Marbaix, and Cleuter, Y. (1978)
12.
Marbaix, G., Huex, G., Burny, A., Cleuter, Y., Hubert, E., Leclercq, M., Chantrenne, H., Soreq, H., Nucel, U. and Littauer, U. Z. (1975) Proc. Natl. Acad. Sci. USA 72, 3065-3067.
13.
Sehgal, P. B., Soreq, H. and Tamm, I. (1978) Proc. Natl. 75, 5030-5033. Despande, A. K., Chatterjee, B. and Roy, A. K. (1979) J. 89374942.
14.
Soreq, H., Littauer, E. and Chantrenne,
Biol.
21-33,
684-690.
Biochem.
N. (1981)
J.
pp.
Gallwitz, D., Weinberg, Nature 271, 572-573.
460
E.,
Devos,
G., Leclercq, 64, 115-121. R.,
Hubert,
E.
Acad.
Sci.
USA
Biol.
Chem. 254,
Vol. 103, No. 2,1981 November 30, 1981
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 454-460
SELECTIVE RESISTANCE OF BACTERIAL POLYADENYLATE-CONTAINING RNA TO HYDROLYSIS BY GUANOSINE3'-5'-MONOPHOSPHATE-SENSITIVE NUCLEASE OF BACILLUS BREVIS Yanamandra Gopalakrishna and Nilima Sarkar Department of Metabolic Regulation Boston Biomedical Research Institute Boston, MA. 02114 and Department of Biological Chemistry Harvard Medical School Boston, MA. 02115 Received
October
12.1981 SUMMARY
Earlier experiments had shown that the degradation of newly synthesized RNA in permeable cells of Bacillus brevis is mediated primarily by a guanosine 3',5'-monophosphate-sensitive 3' -exonuclease [N. Sarkar and H. Paulus (1975) J. Biol. Chem. 250, 684-6901. More recently, we found that a substantial fraction of pulse-labeled RNA in B. brevis is polyadenylylated [N. Sarkar, D. Langley, and H. Paulus (1978) Biochemistry 17, 3468-34741, and it was thus of interest to examine the effect of polyadenylylation on Purified the susceptibility of RNA to degradation by the 3'-exonuclease. 3'-exonuclease from B. brevis hydrolyzed the unadenylylated fraction of pulse-labeled RNA from B. brevis much more rapidly than poly(A)-containing results were obtained with the pulse-labeled unadenylylated RNA. Similar Control experiand polyadenylylated RNA fractions from BaciZZus subtiZis. ments showed that the differential hydrolysis of the labeled RNA preparations by 3'-exonuclease was not due to the presence of inhibitors or activators. These results suggest that the stability of mRNA in BaciZZus species may be regulated by polyadenylylation.
The degradation
brevis is primarily
Bacillus vity
is
sensitive
(1, 2). acts
very
bacterial this
INTRODUCTION synthesized RNA in
of newly
to inhibition
The observation slowly
poly(A)-containing
B. brevis (3).
by guanosine
that
this
on poly(adenylic
mRNA might
possibility
due to the action
led
molecules High
levels
0 1981 by Academic Press, of reproduction in any form
suggested
of relatively
among the rapidly of poly(A)-RNA
0006-291X/81/220454-07$01.00/0 Copyright All righrs
(2)
Inc. reserved.
RNA from that
454
were
also
acti-
(cGMP) the
3'-end
and
the stability
of
The exploration
of
levels
(30-40%)
of
RNA species
of
high
labeled
of
whose
3',5'-monophosphate
by polyadenylylation.
to the discovery
cells
of an exonuclease
enzyme degrades acid)
be modulated
toluene-treated
found
in Escherichia
BIOCHEMICAL
Vol. 103, No. 2,198l
coZi
and BaciZZus
resemble cation, bacterial
subtilis
(4),
AND
BIOPHYSICAL
both
of which
enzyme from B. brevis
the
we compare
the
by the
harbor
3'-exonucleases
in many respects
sensitivities
RNA to hydrolysis
RESEARCH COMMUNICATIONS
(5,
of unadenylylated
6).
which
In this
communi-
and polyadenylylated from B. brevis.
3'-exonuclease
MATERIALS --AND METHODS Materials [2,8-3H]adenosine (25.5 Ci/mmole) and [5-'Hluridine (25 Ci/mmole) were obtained from New England Nuclear and oligo(dT)-cellulose (Type 7) from P-L Biochemicals. Proteinase K (Boehringer) [l'C?poly(A) and [3H]poly(U) were made from ["C]ADP (0.1 Ci/mmole and [3H]UDP (0.2 Ci/mmole) respectively as described earlier (2). The sources of all other materials are as published earlier (3, 4). Bacterial
Strains
and Growth 8185 and BaciZZus subtiZis ATCC 6051 were supplemented with salts and glucose (4).
Bacill~i~TCC nutrient
broth
grown
in
Labeling of RNA and Fractionation --Two ml of exponentially growing cultures were treated with [2,8-'Hladenosine or [5-3H]uridine (20 pCi) for 30 set and the labeled cells were processed by proteinase K method as described earlier except proteinase K was incubated for 20 min at 37" C (5mg/ml in 10 mM Tris-HCl, pH 7.5) just prior to use (4). Pulse-labeled RNA was fractionated into polyadenylylated and unadenylylated fractions by affinity chromatography on oligo(dT)-cellulose. Unadenylylated RNA was isolated from the unadsorbed fraction by precipitating 5 times with 2.5 volumes of ethanol in the presence of 10 mM MgC12. Poly(A)RNA was isolated from oligo(dT)-cellulose bound fraction by repeatedethanol precipitation in the presence of 10 mM MgClz without carrier. Labeled rRNA and tRNA were isolated from exponentially growing cultures of BaciZZus brevis that had been incubated with [3H]uridine for at least 3 generations as described (4). Nuclease from Bacilhs brevis The cGMP-sensitive nuclease was purified from BacizZus brevis cells as described earlier (2). Ribonuclease-assay ,was done by incubating labeled substrate in 0.1 M Tris-HCl, pH 7.1, 10 mM MgClz, 2 mM MnClz, .lO mM 2-mercaptoethanol and enzyme and measuring the amount of alcohol-soluble product as detailed earlier (2). The assay was done using the conditions where degree of hydrolysis was a linear function of time. A unit of ribonuclease activity was defined as the amount of enzyme that produced 1 nmole of alcoholsoluble product per min from poly(LJ). RESULTS AND DISCUSSION The relative
considerably
and tRNA were bility
of hydrolysis
from B. brevis
3'-exonuc:Lease hydrolyzed
rates
hydrolyzed
to exonucleolytic
are
of various compared
more rapidly
than
at intermediate degradation
in Fig.
1.
polyadenylic rates.
is a function
455
polynucleotides
by purified
Polyuridylic acid,
However,
acid
whereas
since
of the number
was
rRNA
the susceptiof nucleic
Vol. 103, No. 2,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
1
A
I
1
80.
01
ENZYME
(UNITS)
ENZYME(UNITS)
Figure
1:
Rate of exonucleolytic degradation of Hydrolysis was measured using standard cribed in "Materials and Methods," at Substrate input per assay was 0.45 mM 0.2 mM for [ 'C]poly(A) (A*.* A), 0.17 0.17 n&l for [3H]rRNA (D-3).
labeled polyribonucleotides. assay conditions as desthe enzyme levels indicated. for [3H]poly(LJ) (D-D), mM for [3H]tRNA (o-o) and
Figure
2:
(A) Rate of exonucleolytib degradation of [3H]adenosine-labeled unadenylylated RNA and [aH]adenosine-labeled poly(A)-RNA, isolated from BacilZus brevis cells. Hydrolysis was measured using standard assay condition as described in "Materials and Methods" at the enzyme levels indicated. Substrate input per assay was 1500 cpm for [3H]p~1y(A)-~A (o---o) and 1400 cpm for ['Hlunadenylylated RNA (o-0). (B) Rate of exonucleolytic degradation of [3H]adenosine-labeled unadenylylated RNA and ['Hladenosine-labeled poly(A) RNA isolated from BaciZtus sxbtilis cells. Details are as in (A). Substrate input per assay was 1250 cpm for [3H]p~ly(A)-RNA (o---o) and 1150 for [3H]unadenylylated RNA (0-o).
acid
chains,
RNA species
the relative
One can thus
substrate
of the
Exponentially
pulse-labeled
earlier
growing
fraction in Fig.
more rapidly responding
the
that not (2)
than
with
acid
is
suggested
by these
a relatively
poor
with
synthetic
but also
in comparison
with
natural
of B. brevis into
fraction
Similar
from B. subtilis (data
not
456
were
pulse-labeled
an unadenylylated
chromatography
2A, the unadenylylated
[3H]uracil
than
molecularweight
in comparison
by affinity
ENA fractions
greater
high
only
cultures
poly(A)-RNA.
with
nuclease
polyadenylic
and the ENA was fractionated
adenylylated As shown
conclude
3'-exonuclease,
as shown
adenosine
of
such as rRNA may be considerably
results.
nucleotides
activity
results (Fig. shown).
polyIWAs.
with and a poly-
on oligo(dT)-cellulose was hydrolyzed were
obtained
2B),
or with
The extent
[?I]-
(3). considerably
with
the cor-
ENA fractions of hydrolysis
of
BIOCHEMICAL
Vol. 103, No. 2,198l
polyadenylylated which
RNA did
unadenylylated
that
the
limited
about
poly(A)-RNA
other
with
fraction.
reconstitution
similar
two types
affected
fraction.
In another mixtures
unadenylylated
(Table
sensitivities are not
of
RNA were
exonuclease
type
II).
could
to exonuclease due to the presence
involved
control
I,
to
prepaappropriof
poly(A)-RNA
was sig-
of the complemen-
additivity
was observed
[3H]p~1y(A)-RNA by limiting
and [?I]amounts
show that
of poly(A)-RNA
of inhibitors
out
the hydrolysis
strict
experiments
digestion
carried
so as to permit
amounts
to hydrolysis
to be interby the presence
were
3H-labeled
acid,
3'-exonuclease
the simultaneous
in Table of
pure
in the poly(A)-RNA
experiments
of experiment,
subjected These
be produced
of equivalent
[?I]polyuridylic
that
have
RNA fractions
RNA nor
possible
described
of an activator
As shown
by the addition
thus
type
One of these
unadenylylated
is
when treated
by the
results
and unlabeled
we had observed
to degradation
of control
experiments.
?+labeled
when various
of the
It
suggests
due to contaminating
to be adsorbed
(3).
at
behavior
Indeed,
failed
or the absence
of pulse-labeled
nificantly
of 3'-
the differential
and unadenylylated
or activators
RNA
in the variousnucleic
fractions. Since
yotic
since
inhibitor
fraction.
time
experiments
This
may have been
refractory
such possibilities.
neither
acid
hand,
Accordingly,
ration
tary
a second
caution,
of a nuclease
eliminate
hydrolyzed.
fraction
may be essentially
On the
ate
15% of this
RESEARCH COMMUNICATIONS
10% even at enzyme concentrations
observed
oligo(dT)-cellulose
preted,
exceed
RNA in the poly(A)-RNA
that
with
BIOPHYSICAL
RNA was completely hydrolysis
unadenylylated earlier
not
AND
the discovery
mRNA (7-g),
stabilizing
mRNA.
the microinjection had been modified the results stabilized
of polyadenylylate
much attention Experiments into
frog
by in
vitro
have been somewhat by polyadenylylation
sequences
has been devoted to test oocytes
this
at the 3'-ends to their
possibility
of mRNA fractions
treatment
with
equivocal, (lo-12)whilethe
457
have mostly whose
appropriate
some mRNAs (e.g. stability
potential
poly(A)
enzymes. globin of others
of eucarrole
in
involved content However, mRNA)being (e.g.
of
Unlabeled
c
Alcohol-soluble
were labeled
radioactivity.
RNA fractions corresponding
prepared counterpart,
using
same methods
as
the
b Unlabeled
for
labeled
RNA and
[3H]adenosine-labeled standard condition.
+
f
using cpm.
0.3
+
+
20
46
14
44
amount
used
was equivalent
B. brevis,described in Input for 13HJunadenyl-
0.6
0.6
380 1030
1.2 0.3
+
+
172
1110
0.6
+
+
+
0.3
+
+
+
1.2
(cpm)
Substrate HydrolyzedC
(Units)
3'-Exonuclease
+
a ['HlUnadenylylated RNA and [3H]poly(A)-RNA werepreparedfrom "Materials and Methods" and nuclease digestion was done ylated RNA was 2200 cpm and for [3H]p~ly(~)-RNA was 630
to
on the Exonuclease
422
3'
246
Polyadenylylated
RNA by
RNA Fraction
0.3
Unadenylylated
Unlabeled RNA Fractionb
['HIAdenosine-labeled
Addition
0.6
of
+
Polyadenylylated
of
I
+
Unadenylylated
Radioactive RNA Fractiona
Effect Hydrolysis
TABLE
BlOCHEMlCAL
Vol. 103, No. 2,1981
AND
TABLE 3'-Exonuclea~e
Digestion
[3H]Poly(U)
of
BIOPHYSICAL
II
[3H]P~ly(U)
in
["HlUnadenylylated
RNA or
['HlPoly(A)-RNA
[3H]Unadenylylated RNA
(cd
RESEARCH COMMUNICATIONS
the
presence
of
[%]poly(~)-RNA
(cpm)
Substrate
hydrolyzed
(cpm)
(cpmf
10,000
1,220 1,246
10,000
140
1,246
1,324
10,000
1,070
10,000 Standard and either described
interferon,
dtro
entities,
experiments
with
intracellular
poly(A)-RNA therefore
degradation
cells
in the
that
bacterial
by the bacterial
polyadenyl.ylation
no longer
in bacterial
enzyme as
represented
that
thus
results
the
implicating
the
in the sensitivities
exonuclease. cells
459
cGMF'-sensitive Secondly,
of total
almost
pulse-
by the 3'-exonuclease
complete
One of the major
may thus
stability.
of rapidly
of RNA to the extent with
in
we know from
in mRNA degradation.
RXA to hydrolysis
it
subject-
bacterial
degradation
difference
endows
with
Firstly,
factor
cell
were
The
physiological
as a major
polyadenylylation
14).
of mRNA degradation
of the
Z),
(13,
the RNA fractions
is much simpler.
and unadenylylated
clear
that
of B. brevis
by cGMP (1,
all-or-none
units of substrates
of the enzymology
communication
3 '-exonuclease
labeled
naturally
2,200
the interpretation
inhibited
a nearly
is
ignorance
permeable
we find
It
and thus
to our
in this
RNA is
1,500
mRNAs) was unaffected
due to the fact
In contrast,
described
labeled
is
modification
in part
eucaryotes. mRNA
and crzu-globin
uncertainty
ed to in
L,O18
nuclease assay was done using 0.24 single or combination of labeled in "Materials and Methods."
mengovirus,
resulting
1,500
be the modulation
that
occurs
resistance functions
to of RNA
of mRNA
Vol. 103, No. 2,1981
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
ACKNOWLEDGMENT We are grateful to Dr. reading of the manuscript.
H. Paulus for stimulating This work was supported
discussions by NIH grant
and critical GM 26517.
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Marbaix, G., Huex, G., Burny, A., Cleuter, Y., Hubert, E., Leclercq, M., Chantrenne, H., Soreq, H., Nucel, U. and Littauer, U. Z. (1975) Proc. Natl. Acad. Sci. USA 72, 3065-3067.
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