- Email: [email protected]
Resistance of bacterial protein synthesis to double-stranded RNA
Vol.60,No.4,1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNKATIONS
RESISTANCE OF BACTERIAL PROTEIN SYNTHESIS TO DOUBLE-STRANDED RNA Gilbert
Jay,
William
R. Abrams
and Raymond Kaempfer
The Biological Laboratories Harvard University Cambridge, Massachusetts 02138 Received
September
3,1974
ABSTRACT Double-stranded RNA fails to inhibit the formation of translation initiation complexes on R17 bacteriophage RNA, overall synthesis of R17 proteins, or the ability of bacterial initiation factor IF-3 to prevent the association of 30s and 50s ribosomal subunits into single ribosomes. Yet, IF-3 can form complexes with double-stranded RNA. However, IF-3 binds to doublestranded RNA with lower apparent affinity than to either Rl7 RNA or 305 ribosomal subunits; this may explain the resistance of bacterial protein synthesis to double-stranded RNA. Double-stranded initiation very
of mannnalian
tion
(3,5).
factor
recently important
RNA is
to know if
We report required
for
formation
of ability
(11,lZ)
Abbreviation:
Copyright All rights
(B), here
tightly
that
has not bacterial
initiation
complexes
are
not
affected
initiation
association
RNA. 1357
RNA have
sensitive
protein
been detected
Loss of inhibition. been found
RNA (6),
it
to inhibition
directed
by f2 phage
in another
study
(4).
factor
IF-3,
the
(9,10),
binds
to dsRNA,
RNA, overall
synthesis
factor
of protein,
of 30s and 50s ribosomal
by dsRNA. Double-stranded
dsRNA, double-stranded
0 I974 by Academic Press, Inc. of reproduction in any form reserved.
of
RNA to ribosomes
the
of
or phage messenger
on R17 phage
to prevent
RNA (5).
is
complete
of an initia-
establishment
synthesis
lysates,
to give
addition
double-stranded
synthesis
inhibition
although
the
(6,7)
to one report
of messenger
IF-3
of
protein
attachment
of
with
of ribosomal
such
by the
of
reticulocyte
to double-stranded
regions
bacterial
according
inhibited
and the
forms
inhibitor
RNA are sufficient
is concomitant
RNase III-sensitive
in precursor
In rabbit
can be relieved
to bind
activity
by dsRNA. While
units
able
is a powerful
(l-5).
of double-stranded
is
factor
Because
synthesis
The inhibition
that
initiation
is
protein
low concentrations
inhibition
to RNase III,
RNA, sensitive
RNA appears
sub-
to possess
Vol. 60, No. 4,1974
multiple
BIOCHEMICAL
binding
sites
for IF-3,
than to R17 RNA. In particular, somal subunits protein
AND BIOPHYSICAL
but binding
of IF-3 to these sites
IF-3 has a higher apparent
than for dsRNA. This may explain
synthesis
RESEARCH COMMUNICATIONS
to inhibition
affinity
the resistance
by double-stranded
is weaker for 30s ribo-
of bacterial
RNA.
RESULTSAND DISCUSSION Initiation
Complex Formation.
As shown in Fig.
1A, the entry of 32P-labeled
R17 phage RNA into
70s initiation
ation
The amount of IF-3 added in this experiment
factor
IF-3.
that a decrease in IF-3 resulted
complexes is absolutely
in decreased formation
Thus, IF-3 is not in excess in the reaction Addition
of increasing
concentrations
(5) does not lead to a detectable II&&).
complex formation
the same preparation synthesis Ability
perceptibly
complexes.
of dsRNA from Penicillium
at 0.1 rig/ml , and completely
of IF-3 to Keep Ribosomal Subunits
chrysogenum
70s complexes (Fig.
1 rig/ml to 1 pg/ml,
In reticulocyte
of p. chrysogenum dsRNA inhibits
FRACTION
was chosen so
mixture.
of dsRNA tested,
is not inhibited.
upon initi-
of initiation
decrease in 32P entering
In the range of concentrations
tiation
dependent
lysates,
initiation
ini-
by contrast,
of protein
at 0.5 rig/ml (5).
Apart.
When "C-labeled
505
NUMBER
complex formation. 1 M-NH&l-washed FIG. 1. Effect of dsRNA on initiation riblosomes (1.25 A260 or 33 pmol), 32P-labeled Rl7amJS2RNA (0.3 A260), fMet-q (0.11 A260 or 180 pmol), 3 pg IF-2 and 1.3 vg IF-3 were incubated in the presence of the indicated amounts of $6 dsRNA (13) for 12 min at 37'C (151, and analyzed by sedimentation through sucrose gradients (15). Arrow: position of free RI.7 RNA.
1358
BIOCHEMICALAND BIOPHYSICALRESEARCHCOMMUNICATIONS
Vol.60,No.4,1974
ribosomal units,
subunits
(Fig.
they associate
to form single
however, association iting
is inhibited
affect
only partially.
(Fig.
this
activity
dsRNA by itself
of IF-3 (Fig.
does not influence
in an assay specific Rl7 RNA-Birected hibitory
effect
protein
S30 extract,
IF-3 (15),
2IJ). In a control the association
we fail
Protein
Synthesis.
synthesis
containing
of ribosomal
to detect
(Fig.
directed
subunits
mixture 25),
a lim-
fails
an effect
effectiveness
initiation
of protein
equal to that
As seen in Fig.
concentrations
of dsRNA, or
might be affected,
synthesis
not affected,
in a reticulocyte
we measEscherichia
including
lysate
of p. chrysogenum dsRNA (5; W.A. and R.K.,
3, the rate and extent
even though at the highest
: hu )B h
this
with an unpub-
of amino acid incorporation
concentration
Thus,
that an in-
by R17 RNA in a preincubated
synthesis
to
of dsRNA.
To examine the possibility
components for protein
is
it is seen that
of 30s and 50s subunits.
complex formation
all
experiment,
in the presence of 40 to 200 pg/ml of dsRNA from phage $6 (13);
RNA inhibits
lished).
In this
the association
30s sub-
In the presence of IF-3,
of dsRNA in the reaction
for IF-3,
than initiation
29.
2c)(11,12).
might be seen only at much higher
that a step other ured overall
Inclusion
with an excess of unlabeled
ribosomes (Fig.
amount of IF-3 was added, so that
prevented
coli
2A) are incubated
of dsRNA used there
are is
+lF-3 + dsRNA
50s Ill
OJ
IO
20
30
10
20
30 D FRACTION
20 NUME
FIG. 2. Effect of dsRNA on the inhibition of ribosomal subunit association by IF-3. "C-labeled 50s ribosomal subunits were incubated with SlOOB (ll), a supernatant highly enriched for 305 subunits, as described (15). SlOOBwas omitted in (A). IF-3 (3 pg) and $6 daRNA (5 ng; 50 rig/ml) were present as indicated. Analysis by centrifugation (15).
1359
Vol.60,No.4,
1974
approximately
one molecule
mixture.
This
needed
to inhibit
slightly caused ated ation
BIOCHEMICAL
during
is less
Even
seen
an effect
thesis.
This
if
is
not
protein
filters
a saturation
case.
between (Fig. binding
It
the
S30 extract
to dsRNA.
still
rate
free
Even though
curve
of
0
3
may be incub-
reaction
mixture,
degrad-
too
that
small
the
dsRNA is
to cause
one should
therefore,
that
it
is
inhibit
capable
inhib-
still
have
protein
syn-
the
failure
by their (5).
9
bacterial
of binding
retention The figure
66 dsRNA as a function
6 Time
degradation dsRNA is
however,
retained
32P-7abeled
that
when the
dsRNA does not
tested,
dsRNA is not
than
due to dsRNA degradation.
and dsRNA are detected
44);
this
of R77 RNA-dependent
is not
reaction
46 dsRNA is only
be argued
may be concluded,
at any concentration IF-3
to the
in the
greater
Much of for
to occur,
IF-3
times
fragments
initial
the
10'
a).
addition
It could
were
of
Labeled
action,
to TCA-precipitable
IF-3
synthesis
Complexes lose
of
its b).
dsRNA on the
of dsRNA to inhibit Binding
(curve
such degradation of
(curve
nuclease
RESEARCH COMMUNICATIONS
molecule
completely.
incubation
RNase before
degraded
ition.
the
pronounced
progressively
lysate
strand-specific
pancreatic
every
of dsRNA is more than
a reticulocyte
by single with
of dsRNA for
concentration
degraded
AND BIOPHYSICAL
to
IF-3.
on nitrocelluillustrates of increasing
12
(min)
FIG. 3. Effect of dsRNA on R17 RNA translation. ["4C]amino acid incorporation in a preincubated S30 (containing 100 pg ribosomes), with (0) or without(o) R17 RNA (0.4 Aca0) was as described (15). Before incubation, $6 dsRNA was f$ded: P 40 j.Ig/ml (A), 100 pg/ml (A), and 200 pg/ml (v). Curve a: TCA-precipitable in a parallel reaction mixture containing 100 pg 32P-labeled $6 d&WA and lacking [ 'C]amino acids. Curve b: as curve 5, except that the 32P-labeled 46 dsRNAcontaining mixture was preincubated for 5 min at 37'C with 50 vg/ml RNase A before addition of 530.
1360
Vol.60,No.4,1974
amounts ated
of
IF-3.
by the
addition trol
BIOCHEMICAL
That
finding
of
that
IF-3,
(data
not
Nearly
IF-3
ionic
labeled
R17 RNA (Fig.
.than with
IF-3
(14). the
obtained
is
the
needed
is
to reach
2% of
is conducted
with
from
4A,
half-maximal
complex
RNA is
the
untreated
completely
during
formation,
Fig.
the
indic-
RNase before
dsRNA can enter
complex
evident
in
pancreatic
is within
input
initiation
when binding It
with
R17 RNA is degraded of
for
44).
species
respectively The data
amount
retained
by contrast,
Affinities
3 equimolar
daltons,
radioactivity
treated
regions
complexes
the conthis
with
a proportion
an equal
amount
however,
that
formation
comof
"P-
3 to 4
with
R17 RNA
$6 dsRNA.
Relative of
to double-stranded
when dsRNA is
conditions
to
less
is
three-quarters
parable
times
that
the
shown);
treatment. under
binding
AND BIOW-IYSICAL RESEARCH COMMUNICATIONS
of
of dsRNA and R17 RNA for with
molecular
(13); Fig.
the
molecular
44 show that
of R17 RNA retained
A
weights
at any
on filters
of
weight IF-3
IF-3.
The $6 dsRNA consists
2.2x106,
2.8x10',
and 4.5~10~
of R17 RNA is
1.0~10~
concentration
up to saturation,
exceeds
that
of
$6 dsRNA.
daltons
Considering
RI7 RNA
0 IF-3
added (pg)
20
40 60 80 RNA added (pg)
100
4. Relative affinities of dsRNA and R17 RNA for IF-3. (A): freshly prepared, 32P-labeled $6 dsRlU (1.44 pg; 27,062 cpm) or R17 RNA (1.47 pg; 13,818 CPSI) were incubated for 12 min at 37°C with increasing amounts of purified IF-3 (15), in 0.05 M-Tris (pH 7.8), 0.05 M-NH&l, 0.005 M-Mg(OAc)z, 0.001 M-GTP and 0.016 M-2-mercaptoethanol. Samples were diluted with cold buffer A (0.05 M-Tris (pH 7.8), 0.05 M-N&&l, 0.005 M-Mg(OAc)a), and passed through Millipore HA 0.45 nm filters, washing extensively with buffer A. Filters were dried and analyzed for radioactivity. (B): 2 ug IF-3 (90 pmol), 12.4 ug 32P-labeled RI.7 RNA (12.4 pmol), and increasing amounts of 96 dsRNA or R17 RNA were incubated and analyzed as for Fig. 4&. FIG.
1361
Vol. 60, No. 4, 1974
the
fact
than
that
that
the
of
average
IF-3
er apparent
affinity
In the limiting
RNA or $6 dsRNA. cording
for
of
IF-3 it
Taking
into
R17 RNA, however,
account the
and $6 dsRNA compete If
we assume
binding
site
competes
is
as well
ent
affinity
for
IF-3,
for each
data
of
equally
that filled
for
32P-labeled
weight
that
(Fig.
weaker
than
4A), the
then
great-
with
on a molar
a
unlabeled
R17 and ac-
less
between
effect-
$6 dsRNA and
basis
on filters
once
a molecule.of
R17 RNA (Fig.
4E),
yet
subunits
more mol-
effectively
that
implies
3%
of
fact
site(s)
at
R17 RNA
IF-3.
the
IF-3
amounts
difference
with
of
that
exhibits
+6 dsRNA competes
is retained
as a molecule
IF-3
R17 RNA competes
an RNA molecule IF-3,
greater
Fig..4!
10 times
shows that
increasing
48 indicate for
of
of about
basis
molecular
well
curves
times
R17 RNA was incubated
of
unlabeled
Fig.
three
$6 dsRNA.
on a weight
the
the
result
presence
that
while
from
This
45
in the seen
to expectation,
ively.
Fig.
RESEARCH COMMUNICATIONS
of $6 dsRNA is
on filters
R17 RNA than of
It
retention
of 46 dsRNA.
experiment
amount
weight
can be calculated
causes
of R17 RNA than
AND BIOPHYSICAL
molecular
R17 RNA, it
half-saturation ecules
BIOCHEMICAL
that
exhibits
dsRNA possesses
a single 46 dsRNA a lower
multiple
appar-
binding
on R17 RNA.
added (pml)
subunits for IF-3. 2 pg IF-3 (9Opmol),2.5 vg 32P-labeled 46 dsRNA (0.8 pmol), and increasing amounts of 30s ribosomal subunits (1 M-NH&l-washed)(15) were incubated and analyzed as for Fig. 44. FIG.
5.
Relative
affinities
of dsRNA and 30s ribosomal
1362
BIOCHEMICALAND BIOPHYSICALRESEARCHCOMMUNICATIONS
Vol.60,No.4,1974
Relative
Affinities
experiment
of Fig.
sufficient
to retain
30s ribosomal
5, 32P-labeled
decreasing
IF-3 prefers
greater
30s subunits
We conclude that initiation,
formation resistance affinity
is related
affinity
protein
synthesis
that
to dsRNA. During
dsRNA is capable of binding for neither
of R17 RNA are affected that
is resistant
of R17 RNA to preformed fMet-tRNAm30S
show that while
to the fact
subunit,
of IF-3 for 30s subunits
for dsRNA. We have found similarly
bacterial
over dsRNA. By contrast,
initiation
to IF-3, complex
by dsRNA. Most likely, IF-3 possesses greater
for R17 RNA than for dsRNA and, in particular,
the 30s ribosomal factor
Since no more than one IF-3 molecule
is not accompanied by inhibition,
nor translation
is observed at low
over R17 RNA (G.J. and R.K., in preparation).
IF-3 mediates the binding
binding
with an amount of IF-3
competition
the apparent
than that
bacterial
complexes (17). Our results this
(16),
In the
In the presence of increasing
Effective
over IF-3.
can be bound per 30s subunit
IF-3.
amounts of 32P are bound. Thus, 30s subunits
dsRNA for IF-3.
of added 30s subunits
must be significantly
$6 dsRNA was incubated
50% of the RNA on filters.
subunits,
compete with labeled ratios
of dsRNA and 30s Ribosomal Subunits for
prefers
its
the apparent
natural
site,
the mammalian initiation
(5) binds dsRNA two orders of magnitude more tightly
than R17 RNA (W.A.
and R.K., unpublished).
We thank Dr. Anne Vidaver for phage +6 and its host strain, and Dr. G. D. Novelli for tRNAFt. Supported by Grant GM-19333 from the US Public Health Service.
REFERENCES Hunt, T. & Ehrenfeld, E. (1971) Nature New Biol. 230, 91-94. :: Ehrenfeld, E. & Hunt, T. (1971) Proc. Nat. Acad. sci. USA 68, 1075-1078. 3. Hunter, A., Hunt, T., Jackson, R. & Robertson, H. (1972) insynthese, Struktur und Funktion des Haemoglobins, eds. Martin, H. & Nowicki, L. (Lehmanns, Munich), 133-145. Robertson, H. & Mathews, M. (1973) Proc. Nat. Acad. Sci. USA 70 225-229 2: Kaempfer, R. & Kaufman, J. (1973) Proc. Nat. Acad. Sci. USA 7K'1222-1226. 6. Dunn, J. & Studier, F. (1973) Proc. Nat. Acad. Sci. USA70, z96-3300. 7. Nikolaev, N., Silengo, L. & Schlessinger, D. (1973) Proc. Nat. Acad. Sci. USA, 7&, 3361-3365.
1363
Vol. 60, No. 4, 1974
8. 9. 10. 11. 12. 13. 14. 15. 16. 17.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Chao, J., Chao, L. & Speyer, J. (1971) Biochem. Biophys. Res. Comnun. 45, 1096-1102. Iwasaki, K., Sabol, S., Wahba, A. & Ochoa, S. (1969) Arch. Biochem. Biophys. 125, 542-547. Revel, M., Herzberg, M. & Greenshpan, H. (1969) Cold Spring Harbor Symp. Quant. Biol. 34, 261-275. Kaempfer, R. (1971). Proc. Nat. Acad. Sci. USA 68, 2458-2462. Kaempfer, R. (1972). J. Mol. Biol. 71, 583-598. A. & Van Etten, J. (1973) J. Mol. Biol. 78-, 617-625. Semancik, J., Vidaver, Gesteland, R. & Boedtker, H. (1964) J. Mol. Biol. S, 496-507. Jay, G. & Kaempfer, R. (1974) J. Mol. Biol. 82, 193-212. Sabol, S. & Ochoa, S. (1971) Nature New Biol. 234, 233-236. Jay, G. & Kaempfer, R. (1974) Proc. Nat. Acad.Sci. USA, in press.
1364
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNKATIONS
RESISTANCE OF BACTERIAL PROTEIN SYNTHESIS TO DOUBLE-STRANDED RNA Gilbert
Jay,
William
R. Abrams
and Raymond Kaempfer
The Biological Laboratories Harvard University Cambridge, Massachusetts 02138 Received
September
3,1974
ABSTRACT Double-stranded RNA fails to inhibit the formation of translation initiation complexes on R17 bacteriophage RNA, overall synthesis of R17 proteins, or the ability of bacterial initiation factor IF-3 to prevent the association of 30s and 50s ribosomal subunits into single ribosomes. Yet, IF-3 can form complexes with double-stranded RNA. However, IF-3 binds to doublestranded RNA with lower apparent affinity than to either Rl7 RNA or 305 ribosomal subunits; this may explain the resistance of bacterial protein synthesis to double-stranded RNA. Double-stranded initiation very
of mannnalian
tion
(3,5).
factor
recently important
RNA is
to know if
We report required
for
formation
of ability
(11,lZ)
Abbreviation:
Copyright All rights
(B), here
tightly
that
has not bacterial
initiation
complexes
are
not
affected
initiation
association
RNA. 1357
RNA have
sensitive
protein
been detected
Loss of inhibition. been found
RNA (6),
it
to inhibition
directed
by f2 phage
in another
study
(4).
factor
IF-3,
the
(9,10),
binds
to dsRNA,
RNA, overall
synthesis
factor
of protein,
of 30s and 50s ribosomal
by dsRNA. Double-stranded
dsRNA, double-stranded
0 I974 by Academic Press, Inc. of reproduction in any form reserved.
of
RNA to ribosomes
the
of
or phage messenger
on R17 phage
to prevent
RNA (5).
is
complete
of an initia-
establishment
synthesis
lysates,
to give
addition
double-stranded
synthesis
inhibition
although
the
(6,7)
to one report
of messenger
IF-3
of
protein
attachment
of
with
of ribosomal
such
by the
of
reticulocyte
to double-stranded
regions
bacterial
according
inhibited
and the
forms
inhibitor
RNA are sufficient
is concomitant
RNase III-sensitive
in precursor
In rabbit
can be relieved
to bind
activity
by dsRNA. While
units
able
is a powerful
(l-5).
of double-stranded
is
factor
Because
synthesis
The inhibition
that
initiation
is
protein
low concentrations
inhibition
to RNase III,
RNA, sensitive
RNA appears
sub-
to possess
Vol. 60, No. 4,1974
multiple
BIOCHEMICAL
binding
sites
for IF-3,
than to R17 RNA. In particular, somal subunits protein
AND BIOPHYSICAL
but binding
of IF-3 to these sites
IF-3 has a higher apparent
than for dsRNA. This may explain
synthesis
RESEARCH COMMUNICATIONS
to inhibition
affinity
the resistance
by double-stranded
is weaker for 30s ribo-
of bacterial
RNA.
RESULTSAND DISCUSSION Initiation
Complex Formation.
As shown in Fig.
1A, the entry of 32P-labeled
R17 phage RNA into
70s initiation
ation
The amount of IF-3 added in this experiment
factor
IF-3.
that a decrease in IF-3 resulted
complexes is absolutely
in decreased formation
Thus, IF-3 is not in excess in the reaction Addition
of increasing
concentrations
(5) does not lead to a detectable II&&).
complex formation
the same preparation synthesis Ability
perceptibly
complexes.
of dsRNA from Penicillium
at 0.1 rig/ml , and completely
of IF-3 to Keep Ribosomal Subunits
chrysogenum
70s complexes (Fig.
1 rig/ml to 1 pg/ml,
In reticulocyte
of p. chrysogenum dsRNA inhibits
FRACTION
was chosen so
mixture.
of dsRNA tested,
is not inhibited.
upon initi-
of initiation
decrease in 32P entering
In the range of concentrations
tiation
dependent
lysates,
initiation
ini-
by contrast,
of protein
at 0.5 rig/ml (5).
Apart.
When "C-labeled
505
NUMBER
complex formation. 1 M-NH&l-washed FIG. 1. Effect of dsRNA on initiation riblosomes (1.25 A260 or 33 pmol), 32P-labeled Rl7amJS2RNA (0.3 A260), fMet-q (0.11 A260 or 180 pmol), 3 pg IF-2 and 1.3 vg IF-3 were incubated in the presence of the indicated amounts of $6 dsRNA (13) for 12 min at 37'C (151, and analyzed by sedimentation through sucrose gradients (15). Arrow: position of free RI.7 RNA.
1358
BIOCHEMICALAND BIOPHYSICALRESEARCHCOMMUNICATIONS
Vol.60,No.4,1974
ribosomal units,
subunits
(Fig.
they associate
to form single
however, association iting
is inhibited
affect
only partially.
(Fig.
this
activity
dsRNA by itself
of IF-3 (Fig.
does not influence
in an assay specific Rl7 RNA-Birected hibitory
effect
protein
S30 extract,
IF-3 (15),
2IJ). In a control the association
we fail
Protein
Synthesis.
synthesis
containing
of ribosomal
to detect
(Fig.
directed
subunits
mixture 25),
a lim-
fails
an effect
effectiveness
initiation
of protein
equal to that
As seen in Fig.
concentrations
of dsRNA, or
might be affected,
synthesis
not affected,
in a reticulocyte
we measEscherichia
including
lysate
of p. chrysogenum dsRNA (5; W.A. and R.K.,
3, the rate and extent
even though at the highest
: hu )B h
this
with an unpub-
of amino acid incorporation
concentration
Thus,
that an in-
by R17 RNA in a preincubated
synthesis
to
of dsRNA.
To examine the possibility
components for protein
is
it is seen that
of 30s and 50s subunits.
complex formation
all
experiment,
in the presence of 40 to 200 pg/ml of dsRNA from phage $6 (13);
RNA inhibits
lished).
In this
the association
30s sub-
In the presence of IF-3,
of dsRNA in the reaction
for IF-3,
than initiation
29.
2c)(11,12).
might be seen only at much higher
that a step other ured overall
Inclusion
with an excess of unlabeled
ribosomes (Fig.
amount of IF-3 was added, so that
prevented
coli
2A) are incubated
of dsRNA used there
are is
+lF-3 + dsRNA
50s Ill
OJ
IO
20
30
10
20
30 D FRACTION
20 NUME
FIG. 2. Effect of dsRNA on the inhibition of ribosomal subunit association by IF-3. "C-labeled 50s ribosomal subunits were incubated with SlOOB (ll), a supernatant highly enriched for 305 subunits, as described (15). SlOOBwas omitted in (A). IF-3 (3 pg) and $6 daRNA (5 ng; 50 rig/ml) were present as indicated. Analysis by centrifugation (15).
1359
Vol.60,No.4,
1974
approximately
one molecule
mixture.
This
needed
to inhibit
slightly caused ated ation
BIOCHEMICAL
during
is less
Even
seen
an effect
thesis.
This
if
is
not
protein
filters
a saturation
case.
between (Fig. binding
It
the
S30 extract
to dsRNA.
still
rate
free
Even though
curve
of
0
3
may be incub-
reaction
mixture,
degrad-
too
that
small
the
dsRNA is
to cause
one should
therefore,
that
it
is
inhibit
capable
inhib-
still
have
protein
syn-
the
failure
by their (5).
9
bacterial
of binding
retention The figure
66 dsRNA as a function
6 Time
degradation dsRNA is
however,
retained
32P-7abeled
that
when the
dsRNA does not
tested,
dsRNA is not
than
due to dsRNA degradation.
and dsRNA are detected
44);
this
of R77 RNA-dependent
is not
reaction
46 dsRNA is only
be argued
may be concluded,
at any concentration IF-3
to the
in the
greater
Much of for
to occur,
IF-3
times
fragments
initial
the
10'
a).
addition
It could
were
of
Labeled
action,
to TCA-precipitable
IF-3
synthesis
Complexes lose
of
its b).
dsRNA on the
of dsRNA to inhibit Binding
(curve
such degradation of
(curve
nuclease
RESEARCH COMMUNICATIONS
molecule
completely.
incubation
RNase before
degraded
ition.
the
pronounced
progressively
lysate
strand-specific
pancreatic
every
of dsRNA is more than
a reticulocyte
by single with
of dsRNA for
concentration
degraded
AND BIOPHYSICAL
to
IF-3.
on nitrocelluillustrates of increasing
12
(min)
FIG. 3. Effect of dsRNA on R17 RNA translation. ["4C]amino acid incorporation in a preincubated S30 (containing 100 pg ribosomes), with (0) or without(o) R17 RNA (0.4 Aca0) was as described (15). Before incubation, $6 dsRNA was f$ded: P 40 j.Ig/ml (A), 100 pg/ml (A), and 200 pg/ml (v). Curve a: TCA-precipitable in a parallel reaction mixture containing 100 pg 32P-labeled $6 d&WA and lacking [ 'C]amino acids. Curve b: as curve 5, except that the 32P-labeled 46 dsRNAcontaining mixture was preincubated for 5 min at 37'C with 50 vg/ml RNase A before addition of 530.
1360
Vol.60,No.4,1974
amounts ated
of
IF-3.
by the
addition trol
BIOCHEMICAL
That
finding
of
that
IF-3,
(data
not
Nearly
IF-3
ionic
labeled
R17 RNA (Fig.
.than with
IF-3
(14). the
obtained
is
the
needed
is
to reach
2% of
is conducted
with
from
4A,
half-maximal
complex
RNA is
the
untreated
completely
during
formation,
Fig.
the
indic-
RNase before
dsRNA can enter
complex
evident
in
pancreatic
is within
input
initiation
when binding It
with
R17 RNA is degraded of
for
44).
species
respectively The data
amount
retained
by contrast,
Affinities
3 equimolar
daltons,
radioactivity
treated
regions
complexes
the conthis
with
a proportion
an equal
amount
however,
that
formation
comof
"P-
3 to 4
with
R17 RNA
$6 dsRNA.
Relative of
to double-stranded
when dsRNA is
conditions
to
less
is
three-quarters
parable
times
that
the
shown);
treatment. under
binding
AND BIOW-IYSICAL RESEARCH COMMUNICATIONS
of
of dsRNA and R17 RNA for with
molecular
(13); Fig.
the
molecular
44 show that
of R17 RNA retained
A
weights
at any
on filters
of
weight IF-3
IF-3.
The $6 dsRNA consists
2.2x106,
2.8x10',
and 4.5~10~
of R17 RNA is
1.0~10~
concentration
up to saturation,
exceeds
that
of
$6 dsRNA.
daltons
Considering
RI7 RNA
0 IF-3
added (pg)
20
40 60 80 RNA added (pg)
100
4. Relative affinities of dsRNA and R17 RNA for IF-3. (A): freshly prepared, 32P-labeled $6 dsRlU (1.44 pg; 27,062 cpm) or R17 RNA (1.47 pg; 13,818 CPSI) were incubated for 12 min at 37°C with increasing amounts of purified IF-3 (15), in 0.05 M-Tris (pH 7.8), 0.05 M-NH&l, 0.005 M-Mg(OAc)z, 0.001 M-GTP and 0.016 M-2-mercaptoethanol. Samples were diluted with cold buffer A (0.05 M-Tris (pH 7.8), 0.05 M-N&&l, 0.005 M-Mg(OAc)a), and passed through Millipore HA 0.45 nm filters, washing extensively with buffer A. Filters were dried and analyzed for radioactivity. (B): 2 ug IF-3 (90 pmol), 12.4 ug 32P-labeled RI.7 RNA (12.4 pmol), and increasing amounts of 96 dsRNA or R17 RNA were incubated and analyzed as for Fig. 4&. FIG.
1361
Vol. 60, No. 4, 1974
the
fact
than
that
that
the
of
average
IF-3
er apparent
affinity
In the limiting
RNA or $6 dsRNA. cording
for
of
IF-3 it
Taking
into
R17 RNA, however,
account the
and $6 dsRNA compete If
we assume
binding
site
competes
is
as well
ent
affinity
for
IF-3,
for each
data
of
equally
that filled
for
32P-labeled
weight
that
(Fig.
weaker
than
4A), the
then
great-
with
on a molar
a
unlabeled
R17 and ac-
less
between
effect-
$6 dsRNA and
basis
on filters
once
a molecule.of
R17 RNA (Fig.
4E),
yet
subunits
more mol-
effectively
that
implies
3%
of
fact
site(s)
at
R17 RNA
IF-3.
the
IF-3
amounts
difference
with
of
that
exhibits
+6 dsRNA competes
is retained
as a molecule
IF-3
R17 RNA competes
an RNA molecule IF-3,
greater
Fig..4!
10 times
shows that
increasing
48 indicate for
of
of about
basis
molecular
well
curves
times
R17 RNA was incubated
of
unlabeled
Fig.
three
$6 dsRNA.
on a weight
the
the
result
presence
that
while
from
This
45
in the seen
to expectation,
ively.
Fig.
RESEARCH COMMUNICATIONS
of $6 dsRNA is
on filters
R17 RNA than of
It
retention
of 46 dsRNA.
experiment
amount
weight
can be calculated
causes
of R17 RNA than
AND BIOPHYSICAL
molecular
R17 RNA, it
half-saturation ecules
BIOCHEMICAL
that
exhibits
dsRNA possesses
a single 46 dsRNA a lower
multiple
appar-
binding
on R17 RNA.
added (pml)
subunits for IF-3. 2 pg IF-3 (9Opmol),2.5 vg 32P-labeled 46 dsRNA (0.8 pmol), and increasing amounts of 30s ribosomal subunits (1 M-NH&l-washed)(15) were incubated and analyzed as for Fig. 44. FIG.
5.
Relative
affinities
of dsRNA and 30s ribosomal
1362
BIOCHEMICALAND BIOPHYSICALRESEARCHCOMMUNICATIONS
Vol.60,No.4,1974
Relative
Affinities
experiment
of Fig.
sufficient
to retain
30s ribosomal
5, 32P-labeled
decreasing
IF-3 prefers
greater
30s subunits
We conclude that initiation,
formation resistance affinity
is related
affinity
protein
synthesis
that
to dsRNA. During
dsRNA is capable of binding for neither
of R17 RNA are affected that
is resistant
of R17 RNA to preformed fMet-tRNAm30S
show that while
to the fact
subunit,
of IF-3 for 30s subunits
for dsRNA. We have found similarly
bacterial
over dsRNA. By contrast,
initiation
to IF-3, complex
by dsRNA. Most likely, IF-3 possesses greater
for R17 RNA than for dsRNA and, in particular,
the 30s ribosomal factor
Since no more than one IF-3 molecule
is not accompanied by inhibition,
nor translation
is observed at low
over R17 RNA (G.J. and R.K., in preparation).
IF-3 mediates the binding
binding
with an amount of IF-3
competition
the apparent
than that
bacterial
complexes (17). Our results this
(16),
In the
In the presence of increasing
Effective
over IF-3.
can be bound per 30s subunit
IF-3.
amounts of 32P are bound. Thus, 30s subunits
dsRNA for IF-3.
of added 30s subunits
must be significantly
$6 dsRNA was incubated
50% of the RNA on filters.
subunits,
compete with labeled ratios
of dsRNA and 30s Ribosomal Subunits for
prefers
its
the apparent
natural
site,
the mammalian initiation
(5) binds dsRNA two orders of magnitude more tightly
than R17 RNA (W.A.
and R.K., unpublished).
We thank Dr. Anne Vidaver for phage +6 and its host strain, and Dr. G. D. Novelli for tRNAFt. Supported by Grant GM-19333 from the US Public Health Service.
REFERENCES Hunt, T. & Ehrenfeld, E. (1971) Nature New Biol. 230, 91-94. :: Ehrenfeld, E. & Hunt, T. (1971) Proc. Nat. Acad. sci. USA 68, 1075-1078. 3. Hunter, A., Hunt, T., Jackson, R. & Robertson, H. (1972) insynthese, Struktur und Funktion des Haemoglobins, eds. Martin, H. & Nowicki, L. (Lehmanns, Munich), 133-145. Robertson, H. & Mathews, M. (1973) Proc. Nat. Acad. Sci. USA 70 225-229 2: Kaempfer, R. & Kaufman, J. (1973) Proc. Nat. Acad. Sci. USA 7K'1222-1226. 6. Dunn, J. & Studier, F. (1973) Proc. Nat. Acad. Sci. USA70, z96-3300. 7. Nikolaev, N., Silengo, L. & Schlessinger, D. (1973) Proc. Nat. Acad. Sci. USA, 7&, 3361-3365.
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8. 9. 10. 11. 12. 13. 14. 15. 16. 17.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Chao, J., Chao, L. & Speyer, J. (1971) Biochem. Biophys. Res. Comnun. 45, 1096-1102. Iwasaki, K., Sabol, S., Wahba, A. & Ochoa, S. (1969) Arch. Biochem. Biophys. 125, 542-547. Revel, M., Herzberg, M. & Greenshpan, H. (1969) Cold Spring Harbor Symp. Quant. Biol. 34, 261-275. Kaempfer, R. (1971). Proc. Nat. Acad. Sci. USA 68, 2458-2462. Kaempfer, R. (1972). J. Mol. Biol. 71, 583-598. A. & Van Etten, J. (1973) J. Mol. Biol. 78-, 617-625. Semancik, J., Vidaver, Gesteland, R. & Boedtker, H. (1964) J. Mol. Biol. S, 496-507. Jay, G. & Kaempfer, R. (1974) J. Mol. Biol. 82, 193-212. Sabol, S. & Ochoa, S. (1971) Nature New Biol. 234, 233-236. Jay, G. & Kaempfer, R. (1974) Proc. Nat. Acad.Sci. USA, in press.
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