- Email: [email protected]
An altered pattern of ribosome synthesis in a mutant of E. coli
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
AN ALTERED PATTERN OF RIBOSOMESYNTHESIS IN A MUTANT OF E. m Leon J. Lewandowski and Barbara (The Wistar
Received
Institute
November
of Anatomy and Biology,
ribonucleoprotein 1965; Sypherd,
either
inhibitors
direction,
growth
to the trans-
exists
growing
cells
that the products
occurring
the study of ribosome
nucleoproteins synthesis
that mutants might exist
growth conditions,
in amounts large
of
1966; Hosokawa and
seem analogous
we considered
(Nakada,
1965) or by addition
and the normally
Approaching
under balanced
would accumulate
ribo-
enough to make possible
their
dependence and resistance
to
and characterization.
Recalling streptomycin
that
sensitivity,
(SM) resides
Speyer et al.,
19621, it
on the ribosomes seemed possible
the presence of a suppressor
bacterium
of unbalanced
19621, the possibility
of
whose metabolism
found in exponentially
manipulations
somal precursors
for
coli
and Horowitz,
precursors
are not identical.
isolation
by conditions
(Hills
(McCarthy et al.,
from another
in Escherichia
While such particles
ribosomal
of metabolic
Pa.)
to study the formation
1965; Nakada and Marquisee,
Nomura, 1965).
which,
become fashionable
particles
has been altered
sitory
Philadelphia,
9, 1966
It has recently
metabolic
L. Brownstein
to SM might display
that
(Flaks
et al,
that mutants selected
changed the response
a change in the physical
554
1962; of the
properties
BIOCHEMICAL
Vol. 25, No. 5, 1966
of the the
ribosomes
case.
or in
This
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the kinetics
paper
of synthesis.
describes
tracts
of one of our mutants,
growth
conditions,
the
particles
MATERIALS We have
this
isolated
the strain
properties
of this
(Brownstein Cultures
and Graham, glucose.
cell.
of the
in
mentation Beckman
L-2
fractions
sucrose
collected
extracts
Tris
buffer
in
fully
else-
cultures
(Paranchych and 0.2%
in early
were prepared (0.01
log at 4OC
M, pH 7.4)
contain-
at 15OcOpsi
in a French
pressure
and debris
and unbroken
cells
dodecyl
gradients
on filter
from
(Sagik
were analyzed
by sedi-
in an SW 39 rotor
were punctured paper
with
2 ml of PPO-POPOP-toluene
a Packard
4000
Tri-Carb
liquid
in a
and three-drop
in vials.
covered
555
such ex-
sulfate-phenol
fractions
Tubes
directly
and
medium
RNA was isolated
ultracentrifuge.
were dried,
and counted
5-20s
with
Cell
sodium
from
(K-106).
more
20 pg methionine/ml
RNA and ribosome
through
reported
with
by centrifugation.
1962).
selected
characterization is
and,
in preparation).
was added,
with
have
minimal
in
of
mutant,
Tris-maleate
and disrupting
by extraction
et al.,
rate
strain
to SM-independence
were performed
washed cells
mM MgC12,
(19601,
mutant
supplemented
DNase (5 pg/ml)
tracts
a sedimentation
a SM-dependent
isolation,
particular
studies
were removed
ters
K-100)
and Lewandowski,
1962)
by suspending 0.1
exponential
SM-sensitive
revertant
were grown
All
a wild-type
(5-40 x 107 cells/ml).
phase
with
of Hashimoto
a spontaneous description
where
under
of ex-
AND METHODS
number
techniques
A detailed
ing
from
K12 (laboratory
utilizing
which,
analyses
43s.
of approximately
&. &
sedimentation
K-106,
accumulates
Such has proven
scintillation
These
fil-
solution counter.
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RESULTS Figure of extracts
almost
after aside
equal
30 minutes
shows the
from
the
labeling
has markedly
areas
are more
by 60 minutes increased
clearly
the in
in
amount
proportion
centrifugation
sampled
It
of the
of isotope
gradient
cultures
of H3-uridine.
distribution these
of sucrose
growing
addition
and 30s peaks; peaks
results
of exponentially
60 minutes minutes,
la
AND CONCLUSIONS
is
clear
4s component, three
main
at 15, 30 and
there areas.
differentiated of label
at 15
that
is By
into in the
an
50,
43
50 and 30s
to the 43s material.
pattern of K-106 ribosomes. (la) At Figure 1. Sedimentation time 0, 150 PC HJ-uridine (1 mc/mg) was added to 100 ml of an Twenty-ml samples were exponentially growing culture of K-106. harvested and cell extracts obtained as described in Methods. Centrifugation was for 190 minutes at 38,000 rpm. Thirty fractions were collected from each gradient. Arrows from left to right mark the positions of 50, 43 and 30s respectively. ,-B-m Fifteen minute samples WW,~WW~; 30 minute ; 60 minute . ... ....... ... .
556
Vol. 25, No. 5, 1966
In
the
120 minutes for
label
experiment
a culture
with
H3-uridine,
divided,
Sucrose
unchased
of label
of the
total
possibility
label
is
suggested
label
after
chase
43s component by the
sedimentation in
Further
gradient
50 and 43s peaks
each of the total
in the the
presence
the
addition
is
patterns respective
(lb) K-106 incubated for 120 minutes the culture was analyzed immediately--.-culture was incubated for an additional uridine as described in text are omitted from figures; conditions
of the of
in Figure
lb,
unlabeled
chased
The dis37%
the
50s peak.
a precursor
of the
lb
of Figure
with
the
(dashed
gradients.
and
approximately
that
in Figure
unlabeled of the
patterns
is under
observation
557
of excess
shows that
for
was incubated
incorporation
sedimentation
the
was labeled
and one-half
shown superimposed
after
label that
in the
of the
are
of K-106
the
immediately
gradient
samples
tribution
in
as a chase.
RNA ceased
uridine.
particle
90 minutes
(100 pg/ml) into
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
next
an additional
uridine
for
BIOCHEMICAL
The 50s
sum of the line) la is
and also
A detailed
37% kinetic
H3-uridine one-half ; the re;ainder of 90 minutes with excess . For convenience,, points are the same as above.
BIOCHEMICAL
Vol. 25, No. 5, 1966
evaluation
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is now in progress
from these results incorporated
into
-- that
the material
which accumulate
to the l'core particle"
resulting
somes (Hosokawa et al,
1966).
in the 43s region
is later
in K-106 are not identical
from CsCl treatment When a mixture
are exposed to CsCl, the majority
is converted
what seems probable
50s ribosomes.
The 43s particles
particles
to corroborate
to 43s particles
while
the initial
of 50s ribo-
of 50s and 43s
of the 50s material 43s particles
sediment at 37s. To determine K-106, perties,
whether
and the wild-type,
the 50 and 30s ribosomes K-100, have similar
we analyzed an extract
prepared
of the mutant,
sedimentation
from a mixture
proof C'4-
FRACTION
Figure 2. Comparison of ribosomal sedimentation pattern of K-106 and wild-type, K-100. A sample of K-106 labeled with H3-uridine for 120 minutes was mixed with a sample of K-100 labeled with Cl4 -uridine for 120 minutes. Cells were lysed and extracts edimented for 190 minutes at 38000 rpm. UU..U.."" , cl e .
558
H3;
BIOCHEMICAL
Vol. 25, No. 5, 1966
labeled for
K-100 and H3-labeled
120 minutes.
the accumulation not seem to be
K-106, each exposed to labeled
The 30 and 50s peaks coincide;
lacks any distinguishable the generation
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
accumulation
however,
of 43s material.
K-100 Although
time of K-106 is 1.5 times that of the wild of 43s material merely
a
in one and not the other
function
uridine
of the slower growth rate.
type, does No
FRACTION
Figure 3. Comparison of RNA extracted from K-106 and wild-type. An aliquot of t e mixture of K-106 labeled with H3, and K-100 labeled with C1b described in Figure 2, was treated with phenolSDS and sedimentid for 6.5 hrs. at 390 0 rpm. Arrows mark the E3 position of 23 and 16s RNA. c14. Insert: RNA extracted from purified 43s parti%s~~;O6 and from crude extract of K-100 .,-...LU=II .
559
BIOCHEMICAL
Vol. 25, No. 5, 1966
comparable
43s peak
5 and 120 minutes
second
sample
mentation the
of
in
the
exactly
RNA extracted (Insert,
from
Figure It
between
with
al.
that
(19621,
are
now analyzing gel
proteins
any visible
RNA of K-106.
than
sediments
The
mutant
90% of the
with
23s RNA
step(s)
in
the
of the
from
assembly
a large
those the
of
production
of
the
43s particle
completed
or
particle.
43 and 50s components
to determine the
in
to the
of an otherwise proteins
than
a step
of proteins
electrophoresis
are missing
transitory
represents
addition
the
we may be observing
less
which
rearrangement
acrylamide
in K-106
The final
may be the
a molecular
show that
cause
More
control.
43s particles
particles,
50s ribosomes.
ribosome
The sedi-
material
for
a
3).
of neosome-like et --
between
from
23 and 16s RNAs of the
of the
purified
2.
does not pattern
the
that
seems therefore
McCarthy
resulting
43s particle
sedimentation
of label
coincides
of
the
overall
distribution
pool
in
was prepared
in Figure
3) of the
point
uridine.
extract
analyzed
(Figure
at any time
of labeled
a phenol
the material
profiles
in K-100
addition
control
RNA contained
change
accumulates
after
As a further
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
whether
We by
specific
43s particle.
ACKNOWLEDGMENTS This Health
investigation
Service
tute
of Allergy
from
the
from
the
Research
Grant
and Infectious
National
U. S. Public
was supported
Health
National
Science Service Institute
in
AI 02454-09 Diseases
Foundation. Research of General
560
part from
by U. S. Public the
and Research L.J.L.
Training Medical
is
National Grant
a trainee
Grant
InstiGB-4410 under
GM 00142-08
Sciences.
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES Flaks,
J.G., Cox, E.C., and White, J.R. Biochem. Biophys. Res. Comm. 2, 385, 1962. Genetics s, 49, 1960. Hashimoto, K. Hills, D. C., and Horowitz, J. Biochemistry 2, 1625, 1966. Hosokawa, K., and Nomura, M. J. Mol. Biol. l2, 225, 1965. Hosokawa, K., Fujimura, R. and Nomura, M. Proc. Natl. Acad. Sci. E, 198, 1966. McCarthy, B.J., Britten, R.J., and Roberts, R. B. Biophys. J. 2,
57, 1962.
Nakada, D. J. Mol. Biol. l2, 695, 1965. Nakada, D., and Marquisee, M. J. J. Mol. Biol. I.& 351, 1965. Paranchych, W., and Graham, A. F. J. Cell. Comp. Physiol. 60, 199. 1962. Sagik, B..P:, Greeb, M. H., Hayashi, M., and Spiegelman, S. Biophys. J. 2, 409, 1962. Speyer, J. F., Len el, P., and Basilio, C. Proc. Natl. Acad. Sci. 48, 6 @I , 1962. Sypherd, P. S. J. Bact. 90, 403, 1965.
561
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
AN ALTERED PATTERN OF RIBOSOMESYNTHESIS IN A MUTANT OF E. m Leon J. Lewandowski and Barbara (The Wistar
Received
Institute
November
of Anatomy and Biology,
ribonucleoprotein 1965; Sypherd,
either
inhibitors
direction,
growth
to the trans-
exists
growing
cells
that the products
occurring
the study of ribosome
nucleoproteins synthesis
that mutants might exist
growth conditions,
in amounts large
of
1966; Hosokawa and
seem analogous
we considered
(Nakada,
1965) or by addition
and the normally
Approaching
under balanced
would accumulate
ribo-
enough to make possible
their
dependence and resistance
to
and characterization.
Recalling streptomycin
that
sensitivity,
(SM) resides
Speyer et al.,
19621, it
on the ribosomes seemed possible
the presence of a suppressor
bacterium
of unbalanced
19621, the possibility
of
whose metabolism
found in exponentially
manipulations
somal precursors
for
coli
and Horowitz,
precursors
are not identical.
isolation
by conditions
(Hills
(McCarthy et al.,
from another
in Escherichia
While such particles
ribosomal
of metabolic
Pa.)
to study the formation
1965; Nakada and Marquisee,
Nomura, 1965).
which,
become fashionable
particles
has been altered
sitory
Philadelphia,
9, 1966
It has recently
metabolic
L. Brownstein
to SM might display
that
(Flaks
et al,
that mutants selected
changed the response
a change in the physical
554
1962; of the
properties
BIOCHEMICAL
Vol. 25, No. 5, 1966
of the the
ribosomes
case.
or in
This
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the kinetics
paper
of synthesis.
describes
tracts
of one of our mutants,
growth
conditions,
the
particles
MATERIALS We have
this
isolated
the strain
properties
of this
(Brownstein Cultures
and Graham, glucose.
cell.
of the
in
mentation Beckman
L-2
fractions
sucrose
collected
extracts
Tris
buffer
in
fully
else-
cultures
(Paranchych and 0.2%
in early
were prepared (0.01
log at 4OC
M, pH 7.4)
contain-
at 15OcOpsi
in a French
pressure
and debris
and unbroken
cells
dodecyl
gradients
on filter
from
(Sagik
were analyzed
by sedi-
in an SW 39 rotor
were punctured paper
with
2 ml of PPO-POPOP-toluene
a Packard
4000
Tri-Carb
liquid
in a
and three-drop
in vials.
covered
555
such ex-
sulfate-phenol
fractions
Tubes
directly
and
medium
RNA was isolated
ultracentrifuge.
were dried,
and counted
5-20s
with
Cell
sodium
from
(K-106).
more
20 pg methionine/ml
RNA and ribosome
through
reported
with
by centrifugation.
1962).
selected
characterization is
and,
in preparation).
was added,
with
have
minimal
in
of
mutant,
Tris-maleate
and disrupting
by extraction
et al.,
rate
strain
to SM-independence
were performed
washed cells
mM MgC12,
(19601,
mutant
supplemented
DNase (5 pg/ml)
tracts
a sedimentation
a SM-dependent
isolation,
particular
studies
were removed
ters
K-100)
and Lewandowski,
1962)
by suspending 0.1
exponential
SM-sensitive
revertant
were grown
All
a wild-type
(5-40 x 107 cells/ml).
phase
with
of Hashimoto
a spontaneous description
where
under
of ex-
AND METHODS
number
techniques
A detailed
ing
from
K12 (laboratory
utilizing
which,
analyses
43s.
of approximately
&. &
sedimentation
K-106,
accumulates
Such has proven
scintillation
These
fil-
solution counter.
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RESULTS Figure of extracts
almost
after aside
equal
30 minutes
shows the
from
the
labeling
has markedly
areas
are more
by 60 minutes increased
clearly
the in
in
amount
proportion
centrifugation
sampled
It
of the
of isotope
gradient
cultures
of H3-uridine.
distribution these
of sucrose
growing
addition
and 30s peaks; peaks
results
of exponentially
60 minutes minutes,
la
AND CONCLUSIONS
is
clear
4s component, three
main
at 15, 30 and
there areas.
differentiated of label
at 15
that
is By
into in the
an
50,
43
50 and 30s
to the 43s material.
pattern of K-106 ribosomes. (la) At Figure 1. Sedimentation time 0, 150 PC HJ-uridine (1 mc/mg) was added to 100 ml of an Twenty-ml samples were exponentially growing culture of K-106. harvested and cell extracts obtained as described in Methods. Centrifugation was for 190 minutes at 38,000 rpm. Thirty fractions were collected from each gradient. Arrows from left to right mark the positions of 50, 43 and 30s respectively. ,-B-m Fifteen minute samples WW,~WW~; 30 minute ; 60 minute . ... ....... ... .
556
Vol. 25, No. 5, 1966
In
the
120 minutes for
label
experiment
a culture
with
H3-uridine,
divided,
Sucrose
unchased
of label
of the
total
possibility
label
is
suggested
label
after
chase
43s component by the
sedimentation in
Further
gradient
50 and 43s peaks
each of the total
in the the
presence
the
addition
is
patterns respective
(lb) K-106 incubated for 120 minutes the culture was analyzed immediately--.-culture was incubated for an additional uridine as described in text are omitted from figures; conditions
of the of
in Figure
lb,
unlabeled
chased
The dis37%
the
50s peak.
a precursor
of the
lb
of Figure
with
the
(dashed
gradients.
and
approximately
that
in Figure
unlabeled of the
patterns
is under
observation
557
of excess
shows that
for
was incubated
incorporation
sedimentation
the
was labeled
and one-half
shown superimposed
after
label that
in the
of the
are
of K-106
the
immediately
gradient
samples
tribution
in
as a chase.
RNA ceased
uridine.
particle
90 minutes
(100 pg/ml) into
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
next
an additional
uridine
for
BIOCHEMICAL
The 50s
sum of the line) la is
and also
A detailed
37% kinetic
H3-uridine one-half ; the re;ainder of 90 minutes with excess . For convenience,, points are the same as above.
BIOCHEMICAL
Vol. 25, No. 5, 1966
evaluation
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is now in progress
from these results incorporated
into
-- that
the material
which accumulate
to the l'core particle"
resulting
somes (Hosokawa et al,
1966).
in the 43s region
is later
in K-106 are not identical
from CsCl treatment When a mixture
are exposed to CsCl, the majority
is converted
what seems probable
50s ribosomes.
The 43s particles
particles
to corroborate
to 43s particles
while
the initial
of 50s ribo-
of 50s and 43s
of the 50s material 43s particles
sediment at 37s. To determine K-106, perties,
whether
and the wild-type,
the 50 and 30s ribosomes K-100, have similar
we analyzed an extract
prepared
of the mutant,
sedimentation
from a mixture
proof C'4-
FRACTION
Figure 2. Comparison of ribosomal sedimentation pattern of K-106 and wild-type, K-100. A sample of K-106 labeled with H3-uridine for 120 minutes was mixed with a sample of K-100 labeled with Cl4 -uridine for 120 minutes. Cells were lysed and extracts edimented for 190 minutes at 38000 rpm. UU..U.."" , cl e .
558
H3;
BIOCHEMICAL
Vol. 25, No. 5, 1966
labeled for
K-100 and H3-labeled
120 minutes.
the accumulation not seem to be
K-106, each exposed to labeled
The 30 and 50s peaks coincide;
lacks any distinguishable the generation
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
accumulation
however,
of 43s material.
K-100 Although
time of K-106 is 1.5 times that of the wild of 43s material merely
a
in one and not the other
function
uridine
of the slower growth rate.
type, does No
FRACTION
Figure 3. Comparison of RNA extracted from K-106 and wild-type. An aliquot of t e mixture of K-106 labeled with H3, and K-100 labeled with C1b described in Figure 2, was treated with phenolSDS and sedimentid for 6.5 hrs. at 390 0 rpm. Arrows mark the E3 position of 23 and 16s RNA. c14. Insert: RNA extracted from purified 43s parti%s~~;O6 and from crude extract of K-100 .,-...LU=II .
559
BIOCHEMICAL
Vol. 25, No. 5, 1966
comparable
43s peak
5 and 120 minutes
second
sample
mentation the
of
in
the
exactly
RNA extracted (Insert,
from
Figure It
between
with
al.
that
(19621,
are
now analyzing gel
proteins
any visible
RNA of K-106.
than
sediments
The
mutant
90% of the
with
23s RNA
step(s)
in
the
of the
from
assembly
a large
those the
of
production
of
the
43s particle
completed
or
particle.
43 and 50s components
to determine the
in
to the
of an otherwise proteins
than
a step
of proteins
electrophoresis
are missing
transitory
represents
addition
the
we may be observing
less
which
rearrangement
acrylamide
in K-106
The final
may be the
a molecular
show that
cause
More
control.
43s particles
particles,
50s ribosomes.
ribosome
The sedi-
material
for
a
3).
of neosome-like et --
between
from
23 and 16s RNAs of the
of the
purified
2.
does not pattern
the
that
seems therefore
McCarthy
resulting
43s particle
sedimentation
of label
coincides
of
the
overall
distribution
pool
in
was prepared
in Figure
3) of the
point
uridine.
extract
analyzed
(Figure
at any time
of labeled
a phenol
the material
profiles
in K-100
addition
control
RNA contained
change
accumulates
after
As a further
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
whether
We by
specific
43s particle.
ACKNOWLEDGMENTS This Health
investigation
Service
tute
of Allergy
from
the
from
the
Research
Grant
and Infectious
National
U. S. Public
was supported
Health
National
Science Service Institute
in
AI 02454-09 Diseases
Foundation. Research of General
560
part from
by U. S. Public the
and Research L.J.L.
Training Medical
is
National Grant
a trainee
Grant
InstiGB-4410 under
GM 00142-08
Sciences.
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES Flaks,
J.G., Cox, E.C., and White, J.R. Biochem. Biophys. Res. Comm. 2, 385, 1962. Genetics s, 49, 1960. Hashimoto, K. Hills, D. C., and Horowitz, J. Biochemistry 2, 1625, 1966. Hosokawa, K., and Nomura, M. J. Mol. Biol. l2, 225, 1965. Hosokawa, K., Fujimura, R. and Nomura, M. Proc. Natl. Acad. Sci. E, 198, 1966. McCarthy, B.J., Britten, R.J., and Roberts, R. B. Biophys. J. 2,
57, 1962.
Nakada, D. J. Mol. Biol. l2, 695, 1965. Nakada, D., and Marquisee, M. J. J. Mol. Biol. I.& 351, 1965. Paranchych, W., and Graham, A. F. J. Cell. Comp. Physiol. 60, 199. 1962. Sagik, B..P:, Greeb, M. H., Hayashi, M., and Spiegelman, S. Biophys. J. 2, 409, 1962. Speyer, J. F., Len el, P., and Basilio, C. Proc. Natl. Acad. Sci. 48, 6 @I , 1962. Sypherd, P. S. J. Bact. 90, 403, 1965.
561