- Email: [email protected]
Coordinate regulation of the individual ribosomal RNA operons in Escherichiacoli
Vol.
68,
BIOCHEMICAL
No. 3, 1976
COORDINATE
A.
Department University
SUMMARY: timesof tions of equally.
When Escherichia 40 minutes or relaxed control
There RNA in
are,
(r-RNA) the
undergoes by
F14
of
in
coli (3)
an
The
with
(7)
growth
scription
rRNA
can
in
Copyright All rights
5s
rRNA
Hall
61801
steady state up conditions, rRNA cistrons
of
genes
of
two
23s
of
two
of
been
position
organized a single
these
operons
of
the
the
5s
gene
presented
have
dictates
mapped --E.
genes
appears
to
factor
determined have
general
each
coli
electron
F prime
rRNA
that
been
by
the
operons
which
between
DNA of
for
6-7
molecule
identified to
ribosomal
in
differ
rRNA
additional
has
are
operons
and
An
copies
which
16~
with doubling or under condiare transcribed
6-7
as
sequences of
these during used
individual relation
in
Four
by Jarry
in
equivalence
(4).
whether
oligonucleotides transcripts
transcribed
Map
We have
the
are
(6).
rates,
reported of
Burrill Illinois
been
lo-
location
rRNA
“transcrip-
operon.
and
as
and
location
8).
independent
strain.
These
evidence
(8,
examined
rRNA
the
and
We have
A-
2).
location
analysis
low
131
approximately
mapping
cistrons
be
COLI
Kaplan
Urbana,
(1,
of
(5).
consistent
a rel
k.
heteroduplex
other
high
estimates,
analysis
recently
Samuel
coli is growing in hours, durinq shift of RNA.synthesis, all
cleavage
transductional
ton”
5s
most
6 strains
is
cated
20
maturational
and
INDIVIDUAL
ESCHERICHIA
and
of Microbiology, of Illinois,
16~-23~-5~
microscope
by
by
transductional
K12
Morgan
IN
COMMUNICATIONS
19,1975
genes
order
RESEARCH
OF THE
RNA OPERONS
Edward
December
BIOPHYSICAL
REGULATION
RIBOSOMAL
Received
AND
operons shift
the and
sequence Rosset
operons. to
0 I976 by Academic Press, Inc. of reproduction in any form reserved.
be of
the
transcribed
and
under
(10)
other used individual 969
coordinately relaxed
heterogeneity
The
each
principle
transcription
up,
are
in
relative and to
conditions within
order
to
those
determine rRNA
in
E.
&
distinguish
molarity to
at
of that
whether operons.
Kl2 tran-
fractional
occur there Published
in
al? is
an data
BIOCHEMICAL
Vol. 68, No. 3, 1976
(10)
indicate
conditions ine ential
that where
extreme
all
cistrons
growth
is
physiological
transcription
are optimum
states of
AND BIOPHYSICAL
individual
expressed or
in
near order
approximately optimum. to
rRNA
RESEARCH COMMUNICATIONS
We have
determine
operons
equally
whether
under
sought or
to not
examprefer-
exists.
METHODS All strains were grown at 37O C with aeration. E. coli K12 strain W3110 was grown on GRCLP salts (249 Tris-HCl, 6g KCl, 0.79 Na,SO,, 0.29 MgCl,, O.lg Na,HPO, per liter, pH 7.0) supplemented with carbon and nitrogen sources chosen to obtain the desired growth rates. Cells grown in GRCLP supplemented with 0.1% Casamino acids, 50 ug/ml tryptophan, 0.4% qlucose, and 20 mM NH.Cl i n GRCLP supplemented had a doubling time of 40 minutes. Ceils-grown witfi RNA was 0.4% glycerol and 0.2% histidine had a doubling t ime of 20 hours. purified from exponential cultures grown for at east two doublings in the presence of [32P]-orthophosphate. Cells labeled during shift up were initial y growing in GRCLP media supplemented with 0.4% glycerol, 0.2% histidine and shifted up by the simultaneous addition of [32P]-orthophosphate and Casam no acids to O.l%, tryptophan to.50 ug/ml,glucose to 0.4% and NH,Cl to 20 mM. A lag of approximately 63 minutes is observed before growth characteristic of this media begins. During this interval the rate of RNA accumulation increases in an approximately exponential fashion until the rate characteristic of the new growth rate is achieved at nearly 60 minutes following shift up (unpublished data). In [32P] labeling experiments RNA synthesis was terminated 40 minutes after shift up by addition of rifampicin to 50 yg/ml and the cells harvested by centrifugation. Relaxed rRNA was prepared from E. coli K12 strain LMUR (rel A-, RNase met-, ura-) growing in the Tow phosphate media of Maalde and Hana1-3 lys-, walt (11) supplemented with 0.4% glucose, 30 ug/ml uracil, and 50 ug/ml methionine and lysine. Starvation for methionine was induced following a one minute centrifugal collection, followed by a one minute centrifugal wash in icecold media without methionine, and resuspension in pre-warmed media without methionine. RNA accumulation resumes within 5 minutes and continues an additional 55 minutes with a doubling of the RNA content with little increase in the optical density or protein content of the culture (unpublished data). [32P]-orthophosphate was added 10 minutes after starvation for methionine was Labeling was terminated by pouring the culture over 0.4 volumes of induced. frozen , crushed M9 salts containing 0.4% glucose, 30 ug/ml uracil, and 50 ug/ml lysine, centrifuged one minute and resuspended in an equal volume of Cells were aerated an additional pre-warmed Mg salts media with methionine. 60 minutes and harvested by centrifugation. Growth resumes approximately 25 55 rRNA was isolated from 50s minutes after relieving methionine starvation. ribosomal subunits and was free of detectable contaminating RNA as determined by acrylamide gel electrophoresis. [32P] -5s rRNA was mixed with [3H]-uracil labeled 5s rRNA purified from strain LMUR grown on 20 ml of Mg media with 0.4% glucose, 15 pg/ml unlabeled uracil plus 2 MC[3H]-uracil, 50 pg/ml methionine and lysine and 1% Casamino acids (doubling time 40 minutes). The RNA was digested with RNase Tl and fingerprinted as described (12). Details of purification are similar to those which will be published elsewhere (Morgan and Kaplan, in preparation).
RESULTS The
relative
yield
of
individual
oligonucleotides
970
derived
from
5s
rRNA
BIOCHEMICAL
Vol. 68, No. 3, 1976
produced
under
presented
in
Table
use
of
the
relative
The comparing
the
synthesized
oligonucleotide
various
AND BIOPHYSICAL
physiological
RESEARCH COMMUNICATIONS
conditions
described
in
METHODS
are
1. a dual
label
technique
molarities
of
minimizes individual
the
possibility
oligonucleotides
Molarities of RNase Tl derived oligonucleotides of 5s under different conditions-relative
Molari in --E.
ty coli
20 hr ling
doubtime
.86
CG
5
UG
4
1.0
CCG;’
3.5
1.0
CAG
0.5
UAG
4
AUG”
.a2
1.0
.93 .81
1.1
1.1
1.6 .15
UCUG
.Vl
.74
1.0
error
in
produced
rRNA to
doubtime
1.0
.93
CCUG
40’ ling
1.2
CCAGA
of
from
a standard
shift up 1.0 1.1 .Vl 1.1 -99 1.2 .a7
RNA
relaxed RNA .vo 1.1 .Vl
.95 1.2 1.2
.92
1.3
1.3
1.2
1.2
1.4
1.1
.89
AAACG
1.1
1.2
AACUG
1.1
1.1
1.3
1.4
AACUCAG
1.1
1.0
1.3
1.3
ACCCCUAG
1.0
1.1
1.0
1.1
UCCCACCUG
1.2
1.3
1.3
1.2
UCUCCCCAUG
0.8-0.9
.80
.87
1.1
UCUCCUCAUG
0.1-0.2
.a5
.74
1.3
.Vl
.97 1.3
Table I. The molarities of 32P labeled oligonucleotides derived from 5s rRNA produced under various conditions relative to a f3H]-uracil labeled oligonucleotide from a 5s rRNA standard is compared to determine equivalancy of The 32P/3H ratios of individual oligoexpression of individual rRNA operons. nucleotides were multiplied by a correction for the pyrimidine/phosphate ratio (uracil labels uracil and cytosine equally) and divided by an average of similarly corrected values for CCG, AUG and CCAG. The approximate equal synthesis of rRNA from all cistrons under all conditions is indicated by values near 1.0 for oligonucleotides present in all, a few, or one 5s rRNA cistrons. Molarities of oligonucleotides present in E. -coli are those determined by Jarry & Rosset (1).
971
Vol. 68, No. 3, 1976
5s
rRNA
BIOCHEMICAL
labeled
general
under
consistent
find
that
within
with
may
other
the
results
be
due
to
in
relative
to due
to
preparation
the
in relative
other
rRNA
which
remains
variation
in
to
the
constant,
the
and
variable
CCAUG.
of
In
any
our
hands
that
the
of
case,
the
of
We
cleavage
oligonucleotide
expression
in
conditions.
enzyme
indicating
levels
(I). in
digestion
non-ideal
is
Rosset
amounts
the
contain
of
oligonucleotides
Jarry
on
due
molarity
spots
any
5s
in
depending
production
of
by
produced
and
spurious
present
fluctuations
is
RESEARCH COMMUNICATIONS
Recovery presented
CCAUG
RNA
sequences
not
conditions.
oligonucleotide
a given
This
various
AND BIOPHYSICAL
despite
32P/3H
ratio
fluctuation
individual
is
rRNA
cis-
trons. It into
was
necessary
ribosomes
cedure
in
used
the
chase,
into
new
rRNA
produced
release
5s
rRNA
the
uptake of
rRNA
5s rRNA of
and
since
is
synthesis
of
5s
rRNA,
incorporated
are
unable
in
the
RNA
incorporated rRNA
into
detect
isolated,
into
new
has
occurred
incorporation of
ribosomes
after
any
the
significant
conclude
after
the
from
after
proportion
we
RNA
pro-
cells
with
into to
The the
a substantial
we
synthesis label
5s
conditions
purity.
[32Pl
since is
relaxed
necessary
unpackaged
conditions
(13)
the
under
significant
However,
relaxed
produced of
pre-existing
possible.
equal
5S
obtain
preferential
an
relaxed
that
release
all
of
cistrons
under
conditions. We have
RNA
in
p.
detected
pressed
with
Jarry
and
Rosset
equally
in
contains
vidual
-P.
c.
two
the
be
maintained
e5S
are
not
at sequences
genes at
heterogeneous
i.
Both
mirabilis
5s
the
relevant
(1).
heterogeneous mirabilis
of
sequences
well
also
to
These
agree
by
some
containing
data).
data
mined
also
mirabilis
published
pears
is
significant
starvation,
Our
turnover
of
if
to
starvation
indication
chase
eliminate
under
of
even
order
should but
to
to
different
each
sequences
t-RNA present
genes in
heterogeneity E. high and other growth
972
on
p.
5s
rRNA
and
low
growth
map
genes
rates
to
of g.
coli
(unpublished
E.
coli
5s
Fl4
(un-
factor 5s
rRNA.
positions appear
rates.
stoichiometry and
F’
mirabilis
and
coli
of
deterto
be
p.
mirabilis
synthesis
of
5s
rRNA data).
genes
ex-
indiap-
Vol. 68, No. 3,1976
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS DISCUSSION
Several tence
of
alternative
multiple
scriptional of
from
individual
to
rRNA,
give
which
rRNA
rate;
tion
to
least
it
is
found
to
be
ceT1
growth
dictates
bably of
all
that
fractional
tribution
and
cation at the
rRNA
operons
all
the
reduces
different
preferential
conditions
changes
ponential
increase
synthesis
are
accumulation
tein
messenger
least
some
RNA.
coordinate
control A-
has
not
been
with
defect. clarified,
proteins Coordinate of
of
are RNA
control
protein Although this
or
synthesis the data
and
mechanism indicates
973
the
by
rRNA of that
of
in
to
occurs
at
rate.
No
which
These or
are
operons
also
a total
the
regulation
deproas
at
coordinately occurs is
of
exof
ribosomal
components
regulation
an
kinetics
dfstinguish
accumulation
repli-
operons
growth
of
dis-
rRNA
repression
individual
pro-
molarities
regulation
difficult
for
and
origin
of
translation
polymerase of
most
conditions
of
been
mandatory.
proposed
occurs.
release
possibilities and
up,
have
Symmetrical
dosage
RNA accumulation
a gradual
is
dictated
shift
are
necessary
relative
Coordinate
transcription
These
ribosomal (IS).
Rel
rate
autocatalytic
controlled
the
the
during
is
In
operon
tRNAs
for
the
clear.
rRNA
which
as
exist
RNA products yet
constant.
gene
of
occurs
in
relative rates.
rRNA
the
operon
here,
around
replication rates
consistent
and
in
of
nearly
operons
may operons,
different
this
studied
regula-
the
transcription
not
non-preferential
remains rRNA
transcription
repression
is
is of
one of
in
contain
which
two
least
transcription
of
chromosomal
widely
at
that
tran-
operons
may
exis-
a high
Multiple
6),
a way
the
off
different
regions
and
rRNA,
oligonucleotides clustering
the
“spacer”
transcription
under
probably
different
that
somehow shutting
(4,
in
(14)
with
for
ribosomes.
regulation
explain
provide
by
sequences
that
to
involved
3)
non-rRNA
co-transcribed
We feel
be
order to
regulated
non-homologous
and
may
heterogeneous
interesting
sometimes
1)
non-coordinately;
cellular
in
coli:
accumulation
appreciable
respect
--E.
operons
functionally
in
exist
in
multiple rRNA
involved
this
operons
operons
contain
at
2)
with
rise
somehow
possibilities
when
altered
rRNA
by
accumulation of
rRNA
is
un
BIOCHEMICAL
Vol. 68, No. 3, 1976
likely
to
be
complicated
by
AND BIOPHYSICAL
non-coordinate
RESEARCH COMMUNICATIONS
regulation
of
individual
rRNA
operons. Acknowledgment This ported by acknowledge
research was supported by N.I.H. N.I.H. pre-doctoral training grant C.R. Woese and E. Reichmann for
grant HD-03521. E.M. was GM 00510. We would like use of space and equipment.
supto
References 1.
Jarry,
2.
Pace,
3.
Doolittle,
4.
Ginsburg,
5.
Jarry,
B.,
6.
Deonier, Biol.,
89,
7. 8. 9.
B., B.,
Rosset,
and
Pace,
W.F., D., and
N.R.
N.R.
(1970).
R.
Ohtsubo,
R.S.,
M., Genet.,
Lee,
105,
142-149.
Nature, J.
228,
Biol.
Molec. H.J.,
113, 43-50.
Genet.,
Bact.,
(1975).
(1973).
E.,
Gen.
Lindahl,
Birnbaum, 119,
Chem.,
Gen.
Nomura,
and
5647-5654.
126,
Genet.,
Davidson,
M.,
250,
N.
29-35.
(1974).
J.
R.R.
(1975).
Burgess,
Molec.
L.S.,
(1970).
B.
and
Rosset,
11.
Maalde,
0.
and
Hanawalt,
and
Kaplan,
S.,
and
Pfister,
(1972).
A.
Molec.
377-380.
Jarry,
F.
L.,
125-129.
458-462.
L.
Sanger,
J.
J.A.
Rosset,
10.
12.
(1971).
Pace,
Steitz,
Mol.
619-629.
257,
Gorelic,
(1971).
R.
and and
R.C.,
Jaskunas, Nature, Unger, Gen.
and
Molec.
Gen.
R.
Browlee,
Genet., Molec.
(1971). P.
(19611.
G.G.
(1967).
J.
106,
323-327.
Gen.
Genet.,
Molec.
Biol.,
Methods
in
113, 3,
43-50.
144-155.
Enzymology,
12,
361-
381. 13.
Nakada,
14.
Lund’, Nomura,
15.
D.,
Anderson,
I.A.C.,
and
Mayasanik,
B.
9, 472-488.
Jaskunas,
E., M.
Dahlberg, In Press. S.R.,
J.E.,
Burgess,
L.,
Lindahl,
R.R.,
Lindahl,
974
Jaskunas,
L.,
and
J.
(1964). S.R.,
Dennis,
Nomura,
M.
Molec.
P.P.,
In
Press.
Biol.
and
68,
BIOCHEMICAL
No. 3, 1976
COORDINATE
A.
Department University
SUMMARY: timesof tions of equally.
When Escherichia 40 minutes or relaxed control
There RNA in
are,
(r-RNA) the
undergoes by
F14
of
in
coli (3)
an
The
with
(7)
growth
scription
rRNA
can
in
Copyright All rights
5s
rRNA
Hall
61801
steady state up conditions, rRNA cistrons
of
genes
of
two
23s
of
two
of
been
position
organized a single
these
operons
of
the
the
5s
gene
presented
have
dictates
mapped --E.
genes
appears
to
factor
determined have
general
each
coli
electron
F prime
rRNA
that
been
by
the
operons
which
between
DNA of
for
6-7
molecule
identified to
ribosomal
in
differ
rRNA
additional
has
are
operons
and
An
copies
which
16~
with doubling or under condiare transcribed
6-7
as
sequences of
these during used
individual relation
in
Four
by Jarry
in
equivalence
(4).
whether
oligonucleotides transcripts
transcribed
Map
We have
the
are
(6).
rates,
reported of
Burrill Illinois
been
lo-
location
rRNA
“transcrip-
operon.
and
as
and
location
8).
independent
strain.
These
evidence
(8,
examined
rRNA
the
and
We have
A-
2).
location
analysis
low
131
approximately
mapping
cistrons
be
COLI
Kaplan
Urbana,
(1,
of
(5).
consistent
a rel
k.
heteroduplex
other
high
estimates,
analysis
recently
Samuel
coli is growing in hours, durinq shift of RNA.synthesis, all
cleavage
transductional
ton”
5s
most
6 strains
is
cated
20
maturational
and
INDIVIDUAL
ESCHERICHIA
and
of Microbiology, of Illinois,
16~-23~-5~
microscope
by
by
transductional
K12
Morgan
IN
COMMUNICATIONS
19,1975
genes
order
RESEARCH
OF THE
RNA OPERONS
Edward
December
BIOPHYSICAL
REGULATION
RIBOSOMAL
Received
AND
operons shift
the and
sequence Rosset
operons. to
0 I976 by Academic Press, Inc. of reproduction in any form reserved.
be of
the
transcribed
and
under
(10)
other used individual 969
coordinately relaxed
heterogeneity
The
each
principle
transcription
up,
are
in
relative and to
conditions within
order
to
those
determine rRNA
in
E.
&
distinguish
molarity to
at
of that
whether operons.
Kl2 tran-
fractional
occur there Published
in
al? is
an data
BIOCHEMICAL
Vol. 68, No. 3, 1976
(10)
indicate
conditions ine ential
that where
extreme
all
cistrons
growth
is
physiological
transcription
are optimum
states of
AND BIOPHYSICAL
individual
expressed or
in
near order
approximately optimum. to
rRNA
RESEARCH COMMUNICATIONS
We have
determine
operons
equally
whether
under
sought or
to not
examprefer-
exists.
METHODS All strains were grown at 37O C with aeration. E. coli K12 strain W3110 was grown on GRCLP salts (249 Tris-HCl, 6g KCl, 0.79 Na,SO,, 0.29 MgCl,, O.lg Na,HPO, per liter, pH 7.0) supplemented with carbon and nitrogen sources chosen to obtain the desired growth rates. Cells grown in GRCLP supplemented with 0.1% Casamino acids, 50 ug/ml tryptophan, 0.4% qlucose, and 20 mM NH.Cl i n GRCLP supplemented had a doubling time of 40 minutes. Ceils-grown witfi RNA was 0.4% glycerol and 0.2% histidine had a doubling t ime of 20 hours. purified from exponential cultures grown for at east two doublings in the presence of [32P]-orthophosphate. Cells labeled during shift up were initial y growing in GRCLP media supplemented with 0.4% glycerol, 0.2% histidine and shifted up by the simultaneous addition of [32P]-orthophosphate and Casam no acids to O.l%, tryptophan to.50 ug/ml,glucose to 0.4% and NH,Cl to 20 mM. A lag of approximately 63 minutes is observed before growth characteristic of this media begins. During this interval the rate of RNA accumulation increases in an approximately exponential fashion until the rate characteristic of the new growth rate is achieved at nearly 60 minutes following shift up (unpublished data). In [32P] labeling experiments RNA synthesis was terminated 40 minutes after shift up by addition of rifampicin to 50 yg/ml and the cells harvested by centrifugation. Relaxed rRNA was prepared from E. coli K12 strain LMUR (rel A-, RNase met-, ura-) growing in the Tow phosphate media of Maalde and Hana1-3 lys-, walt (11) supplemented with 0.4% glucose, 30 ug/ml uracil, and 50 ug/ml methionine and lysine. Starvation for methionine was induced following a one minute centrifugal collection, followed by a one minute centrifugal wash in icecold media without methionine, and resuspension in pre-warmed media without methionine. RNA accumulation resumes within 5 minutes and continues an additional 55 minutes with a doubling of the RNA content with little increase in the optical density or protein content of the culture (unpublished data). [32P]-orthophosphate was added 10 minutes after starvation for methionine was Labeling was terminated by pouring the culture over 0.4 volumes of induced. frozen , crushed M9 salts containing 0.4% glucose, 30 ug/ml uracil, and 50 ug/ml lysine, centrifuged one minute and resuspended in an equal volume of Cells were aerated an additional pre-warmed Mg salts media with methionine. 60 minutes and harvested by centrifugation. Growth resumes approximately 25 55 rRNA was isolated from 50s minutes after relieving methionine starvation. ribosomal subunits and was free of detectable contaminating RNA as determined by acrylamide gel electrophoresis. [32P] -5s rRNA was mixed with [3H]-uracil labeled 5s rRNA purified from strain LMUR grown on 20 ml of Mg media with 0.4% glucose, 15 pg/ml unlabeled uracil plus 2 MC[3H]-uracil, 50 pg/ml methionine and lysine and 1% Casamino acids (doubling time 40 minutes). The RNA was digested with RNase Tl and fingerprinted as described (12). Details of purification are similar to those which will be published elsewhere (Morgan and Kaplan, in preparation).
RESULTS The
relative
yield
of
individual
oligonucleotides
970
derived
from
5s
rRNA
BIOCHEMICAL
Vol. 68, No. 3, 1976
produced
under
presented
in
Table
use
of
the
relative
The comparing
the
synthesized
oligonucleotide
various
AND BIOPHYSICAL
physiological
RESEARCH COMMUNICATIONS
conditions
described
in
METHODS
are
1. a dual
label
technique
molarities
of
minimizes individual
the
possibility
oligonucleotides
Molarities of RNase Tl derived oligonucleotides of 5s under different conditions-relative
Molari in --E.
ty coli
20 hr ling
doubtime
.86
CG
5
UG
4
1.0
CCG;’
3.5
1.0
CAG
0.5
UAG
4
AUG”
.a2
1.0
.93 .81
1.1
1.1
1.6 .15
UCUG
.Vl
.74
1.0
error
in
produced
rRNA to
doubtime
1.0
.93
CCUG
40’ ling
1.2
CCAGA
of
from
a standard
shift up 1.0 1.1 .Vl 1.1 -99 1.2 .a7
RNA
relaxed RNA .vo 1.1 .Vl
.95 1.2 1.2
.92
1.3
1.3
1.2
1.2
1.4
1.1
.89
AAACG
1.1
1.2
AACUG
1.1
1.1
1.3
1.4
AACUCAG
1.1
1.0
1.3
1.3
ACCCCUAG
1.0
1.1
1.0
1.1
UCCCACCUG
1.2
1.3
1.3
1.2
UCUCCCCAUG
0.8-0.9
.80
.87
1.1
UCUCCUCAUG
0.1-0.2
.a5
.74
1.3
.Vl
.97 1.3
Table I. The molarities of 32P labeled oligonucleotides derived from 5s rRNA produced under various conditions relative to a f3H]-uracil labeled oligonucleotide from a 5s rRNA standard is compared to determine equivalancy of The 32P/3H ratios of individual oligoexpression of individual rRNA operons. nucleotides were multiplied by a correction for the pyrimidine/phosphate ratio (uracil labels uracil and cytosine equally) and divided by an average of similarly corrected values for CCG, AUG and CCAG. The approximate equal synthesis of rRNA from all cistrons under all conditions is indicated by values near 1.0 for oligonucleotides present in all, a few, or one 5s rRNA cistrons. Molarities of oligonucleotides present in E. -coli are those determined by Jarry & Rosset (1).
971
Vol. 68, No. 3, 1976
5s
rRNA
BIOCHEMICAL
labeled
general
under
consistent
find
that
within
with
may
other
the
results
be
due
to
in
relative
to due
to
preparation
the
in relative
other
rRNA
which
remains
variation
in
to
the
constant,
the
and
variable
CCAUG.
of
In
any
our
hands
that
the
of
case,
the
of
We
cleavage
oligonucleotide
expression
in
conditions.
enzyme
indicating
levels
(I). in
digestion
non-ideal
is
Rosset
amounts
the
contain
of
oligonucleotides
Jarry
on
due
molarity
spots
any
5s
in
depending
production
of
by
produced
and
spurious
present
fluctuations
is
RESEARCH COMMUNICATIONS
Recovery presented
CCAUG
RNA
sequences
not
conditions.
oligonucleotide
a given
This
various
AND BIOPHYSICAL
despite
32P/3H
ratio
fluctuation
individual
is
rRNA
cis-
trons. It into
was
necessary
ribosomes
cedure
in
used
the
chase,
into
new
rRNA
produced
release
5s
rRNA
the
uptake of
rRNA
5s rRNA of
and
since
is
synthesis
of
5s
rRNA,
incorporated
are
unable
in
the
RNA
incorporated rRNA
into
detect
isolated,
into
new
has
occurred
incorporation of
ribosomes
after
any
the
significant
conclude
after
the
from
after
proportion
we
RNA
pro-
cells
with
into to
The the
a substantial
we
synthesis label
5s
conditions
purity.
[32Pl
since is
relaxed
necessary
unpackaged
conditions
(13)
the
under
significant
However,
relaxed
produced of
pre-existing
possible.
equal
5S
obtain
preferential
an
relaxed
that
release
all
of
cistrons
under
conditions. We have
RNA
in
p.
detected
pressed
with
Jarry
and
Rosset
equally
in
contains
vidual
-P.
c.
two
the
be
maintained
e5S
are
not
at sequences
genes at
heterogeneous
i.
Both
mirabilis
5s
the
relevant
(1).
heterogeneous mirabilis
of
sequences
well
also
to
These
agree
by
some
containing
data).
data
mined
also
mirabilis
published
pears
is
significant
starvation,
Our
turnover
of
if
to
starvation
indication
chase
eliminate
under
of
even
order
should but
to
to
different
each
sequences
t-RNA present
genes in
heterogeneity E. high and other growth
972
on
p.
5s
rRNA
and
low
growth
map
genes
rates
to
of g.
coli
(unpublished
E.
coli
5s
Fl4
(un-
factor 5s
rRNA.
positions appear
rates.
stoichiometry and
F’
mirabilis
and
coli
of
deterto
be
p.
mirabilis
synthesis
of
5s
rRNA data).
genes
ex-
indiap-
Vol. 68, No. 3,1976
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS DISCUSSION
Several tence
of
alternative
multiple
scriptional of
from
individual
to
rRNA,
give
which
rRNA
rate;
tion
to
least
it
is
found
to
be
ceT1
growth
dictates
bably of
all
that
fractional
tribution
and
cation at the
rRNA
operons
all
the
reduces
different
preferential
conditions
changes
ponential
increase
synthesis
are
accumulation
tein
messenger
least
some
RNA.
coordinate
control A-
has
not
been
with
defect. clarified,
proteins Coordinate of
of
are RNA
control
protein Although this
or
synthesis the data
and
mechanism indicates
973
the
by
rRNA of that
of
in
to
occurs
at
rate.
No
which
These or
are
operons
also
a total
the
regulation
deproas
at
coordinately occurs is
of
exof
ribosomal
components
regulation
an
kinetics
dfstinguish
accumulation
repli-
operons
growth
of
dis-
rRNA
repression
individual
pro-
molarities
regulation
difficult
for
and
origin
of
translation
polymerase of
most
conditions
of
been
mandatory.
proposed
occurs.
release
possibilities and
up,
have
Symmetrical
dosage
RNA accumulation
a gradual
is
dictated
shift
are
necessary
relative
Coordinate
transcription
These
ribosomal (IS).
Rel
rate
autocatalytic
controlled
the
the
during
is
In
operon
tRNAs
for
the
clear.
rRNA
which
as
exist
RNA products yet
constant.
gene
of
occurs
in
relative rates.
rRNA
the
operon
here,
around
replication rates
consistent
and
in
of
nearly
operons
may operons,
different
this
studied
regula-
the
transcription
not
non-preferential
remains rRNA
transcription
repression
is
is of
one of
in
contain
which
two
least
transcription
of
chromosomal
widely
at
that
tran-
operons
may
exis-
a high
Multiple
6),
a way
the
off
different
regions
and
rRNA,
oligonucleotides clustering
the
“spacer”
transcription
under
probably
different
that
somehow shutting
(4,
in
(14)
with
for
ribosomes.
regulation
explain
provide
by
sequences
that
to
involved
3)
non-rRNA
co-transcribed
We feel
be
order to
regulated
non-homologous
and
may
heterogeneous
interesting
sometimes
1)
non-coordinately;
cellular
in
coli:
accumulation
appreciable
respect
--E.
operons
functionally
in
exist
in
multiple rRNA
involved
this
operons
operons
contain
at
2)
with
rise
somehow
possibilities
when
altered
rRNA
by
accumulation of
rRNA
is
un
BIOCHEMICAL
Vol. 68, No. 3, 1976
likely
to
be
complicated
by
AND BIOPHYSICAL
non-coordinate
RESEARCH COMMUNICATIONS
regulation
of
individual
rRNA
operons. Acknowledgment This ported by acknowledge
research was supported by N.I.H. N.I.H. pre-doctoral training grant C.R. Woese and E. Reichmann for
grant HD-03521. E.M. was GM 00510. We would like use of space and equipment.
supto
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