|
|
|
|||||||
|
|||||||||
J. Biol. Chem., Vol. 275, Issue 33, 25069-25072, August 18, 2000
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
From the Department of Biochemistry and Molecular Biology,
University of British Columbia, Vancouver,
British Columbia V6T 1Z3, Canada
Received for publication, June 6, 2000
RNase E is the major intracellular endonuclease
in Escherichia coli. Its ability to cleave susceptible
substrates in vitro depends on both the cleavage site
itself and the availability of an unstructured 5' terminus. To test
whether RNase E activity is 5'-end-dependent in
vivo in the presence of all the components of the RNA degradative
machinery, a known substrate, the rpsT mRNA, has been
embedded in a permuted group I intron to permit its efficient, precise
circularization in E. coli. Circular rpsT mRNAs are 4-6-fold more stable in vivo than their
linear counterparts. Even partial inactivation of RNase E activity
further enhances this stability 6-fold. However, the stabilization of
circular rpsT mRNAs depends strongly on their efficient
translation. These results show unambiguously the importance of an
accessible 5'-end in controlling mRNA stability in vivo
and support a two-step ("looping") model for RNase E action in
which the first step is end recognition and the second is actual cleavage.
The degradation of mRNAs is an important, if incompletely
understood, aspect of the regulation of gene expression. In
Escherichia coli, the initiating step in the decay process
is usually mediated by RNase E (1-3), a 5'-end-dependent
endoribonuclease (4). In vitro, RNase E activity is
conferred by a multi-enzyme complex, the degradosome (5, 6). In small
RNAs, such as the ColE1 replication regulator RNA 1, and the
rpsO or rpsT mRNAs encoding ribosomal
proteins S15 and S20, respectively, a single RNase E cleavage is
capable of inactivating the mRNA and rendering it susceptible to
complete destruction to mononucleotides (reviewed in Ref. 3). In larger
mRNAs this initiating endonucleolytic event can trigger a 5' Two features in the 5'-extremity of an mRNA, secondary structure
and the triphosphate terminus, can control the susceptibility of the
entire mRNA toward RNase E. The 5'-terminal stem-loop structure of
the ompA mRNA is largely responsible for the atypical
stability of this mRNA and can confer stability to heterologous
mRNAs to which it is grafted (8, 9). Stabilization is abolished by as few as three single-stranded residues at the extreme 5'-end of an
RNA (10). These effects of 5'-terminal secondary structure on mRNA
stability are mediated directly though Rne (4, 11). Evidence for the
critical role of the free 5'-end of RNA and its phosphorylation state
in mRNA turnover arises from several experiments. Most notably,
circular derivatives of the well characterized RNase E substrates,
rpsT mRNA or 9 S RNA, are highly resistant to cleavage in vitro by Rne or degradosomes (4). An RNase E cleavage at a site 5 residues from the 5'-end of RNA 1 destabilizes the 103-residue 3'-cleavage product in vivo. However, an artificial RNA
identical to the initial cleavage product but containing a
triphosphorylated terminus is significantly more stable (12). Likewise,
oligonucleotide-directed cleavage of the rpsT mRNA by
RNase H shows that the 5'-segment containing a triphosphorylated
terminus is quite stable, even in relatively crude extracts. In
contrast, the 3'-segment that would be monophosphorylated undergoes
RNase E cleavage at an accelerated rate compared with the unmodified
substrate (11, 13). Finally, either Rne protein alone or purified
degradosomes preferentially cleave monophosphorylated substrates
20-30-fold more rapidly than their triphosphorylated counterparts (4).
Together, these results imply that the vectorial nature of mRNA
decay is a reflection of the inherent preference of Rne for
5'-monophosphorylated substrates.
To address whether Rne or degradosomes display 5'-end dependence
in vivo where a circular RNA would be exposed to all the components of the degradative machinery, I have constructed chimeric RNAs in which a portion of the rpsT mRNA is embedded in
a permuted group I intron, a construction that should permit its
precise, autocatalytic circularization (14, 15). In this work I show that circular rpsT mRNAs form efficiently and are
4-6-fold more stable than their linear counterparts. Circular RNAs
are, however, cleaved slowly by RNase E in a 5'-end-independent
fashion, which is highly sensitive to ongoing translation.
Strains and Plasmids--
Bacterial strains JM109 (F'
traD36 lacIQ Extraction and Analysis of RNA--
Cultures were grown to
midexponential phase in LB medium (supplemented with ampicillin and
20 mg/liter thymidine as needed) at either 29 °C (MG1693 or SK5665)
or 37 °C (JM109), shifted to 39.5 °C as required, induced with
0.5 mM IPTG for 20 min, and when necessary treated with
rifampicin (>160 µg/ml) to inhibit transcription. Portions (2.0 ml) of the culture were harvested at intervals thereafter, and RNA was
extracted using method II (18). Yields were quantified by
A260, and the quality of the RNA was assessed by
the intactness of rRNA. For RT-PCR, 2 µg of total RNA (in some cases
pretreated with RNase H and oligonucleotide 481 (13)) was denatured at
90 °C and then mixed with a buffer containing 25 mM
Tris-HCl, pH 8.3, 37.5 mM KCl, 1.5 mM
MgCl2, 0.5 mM dNTPs, 10 mM
dithiothreitol, 2.5 µM oligonucleotide 992 (5'-CTGAATGGCAAGCTTCTTAGC; complementary to residues 151-169 in the
rpsT sequence (13)). Following addition of 100 units of Moloney murine leukemia virus reverse transcriptase (Life
Technologies, Inc.) and incubation for 30 min at 42 °C, a portion of
the products corresponding to 0.25 µg of RNA template was amplified
with 5 units of Taq DNA polymerase (Life Technologies, Inc.)
for 30 cycles in 10 mM Tris-HCl, pH 8.4, 50 mM
KCl, 1.5 mM MgCl2, 100 µM dNTPs, and 1 µg of primer 991 (5'-GCTAAAGGTCGGATCCACAAA; complementary to
residues 319-340 in the rpsT sequence (13)) and primer 992. For Northern blotting, samples of total RNA were dissolved in a buffer
containing 90% formamide, heated to 100 °C, and separated on a 6%
polyacrylamide gel containing 8 M urea. RNAs were
transferred electrophoretically to Hybond-N (Amersham Pharmacia
Biotech), fixed, and probed to detect the rpsT mRNAs
with either a complementary RNA or 5'-32P-labeled
oligonucleotide 993 (5'-GGTAGACCTGAGATCTTC). Hybridization with
oligonucleotides was performed at 37 °C in a buffer containing 0.75 M NaCl, 75 mM sodium citrate (pH 7), 0.1%
polyvinylpyrrolidone, 0.1% Ficoll, 0.1% bovine serum albumin
(fraction V), 20 mM Pipes (pH 6.4), 25 µg/ml salmon sperm
DNA, 62.5 µg/ml yeast RNA, 0.1% SDS. Membranes were washed with 0.3 M NaCl, 0.03 M sodium citrate (pH 7), 0.1% SDS
at 38-39 °C.
Synthesis and Characterization of Circular rpsT
RNAs--
Based on the finding that the separate "halves" of a
group I intron can self-assemble to form an active ribozyme (19) (Fig. 1a), permuted group I introns
have been designed to drive the circularization of "passenger"
sequences inserted between the halves of the intron (14, 15).
Sequences from the E. coli rpsT gene (13) were inserted into
the polylinker in pRR1 (17), flanked by the appropriate group I intron
sequences (Fig. 1b) and verified by DNA sequence analysis. A
set of constructions, whose prototype is pGM110, contains
rpsT sequences from residue 93 to 413, including the entire
5'-untranslated region, the coding sequence, and part of the
3'-untranslated region but lacking the transcriptional terminator (Fig.
1b). The plasmids pGM113 and pGM116 (see below) differ from
pGM110 only by point mutation. The insert in pGM111 extends from
residue 132 adjacent to the initiation codon (altered from UUG to AUG)
to residue 413 and lacks the 5'-untranslated region completely (Fig.
1b). All constructions contain a major internal RNase E
cleavage site at rpsT residues 300-301 as well as other
minor sites (20).
A Northern blot of total cellular RNA extracted from cultures of
JM109/pGM110 or JM109/pGM111 with or without induction showed that
expression of putative circular rpsT RNAs of 336 or 297 nucleotides, respectively, was induced by IPTG to appreciable levels.
These RNAs migrated at roughly half the mobility of the linear
rpsT mRNAs (Fig.
2a, compare lanes
2-3 and 4-5). The same blot was reprobed with a
complementary oligonucleotide spanning the circular junction, which
clearly identified the major species in lanes 3 and
5 as circular (Fig. 2a, lanes 6-10).
A permutation analysis (4) demonstrated that the putative circular RNAs
could be converted to linearly permuted, full-length monomers after
treatment with RNase H and an appropriate oligonucleotide (data not
shown). Further substantiation that circular rpsT RNAs are
formed in vivo was obtained by using "inverse" RT-PCR
(see "Experimental Procedures"). Primers were selected such that
only a circular RNA template can give rise to an amplified cDNA
product (Fig. 3a). Synthesis
of the expected 189-bp double-stranded DNA product from total RNA isolated from JM109/pGM110 (Fig. 3b, lanes 2,
3, and 6) was dependent on reverse transcription
in the first step (compare lanes 6 and 7) and was
not affected by prior treatment of the RNA template with DNase I (data
not shown). Yields of the anticipated product of 149 bp from total RNA
extracted from JM109/pGM111 were low (Fig. 3b, lane
4) but improved when the RNA template was initially linearized by
oligonucleotide-directed RNase H cleavage at a location outside the
sequences to be amplified (Fig. 3b, compare lanes 4 and 5). The amplification products of "inverse"
RT-PCR were purified, cloned into pUC19, and sequenced. Both sequences
agreed completely with those predicted from the sequence of pRR1 and the group I intron-rpsT boundaries in pGM110 and pGM111
(data not shown). Finally, a point mutation, G Stability of Circular rpsT mRNAs--
Measurements of RNA
half-life were performed using standard methods (1) (see
"Experimental Procedures"). The rate of decay of rpsT
RNAs extracted from strain JM109/pGM110 was measured initially from
blots probed with a complementary rpsT RNA (data not shown). The circular rpsT/circ-336 RNA disappeared with a half-life
of 290 s. In contrast, two linear RNAs larger than 500 nucleotides containing rpsT sequences, presumably incompletely processed
species, disappeared with half-lives of 50 and 33 s (data not
shown). A typical Northern blot of RNA extracted from cultures of
JM109/pGM111 probed with oligonucleotide 993, specific for circular
rpsT RNAs, is shown in Fig. 2b. Two species of
RNA are detectable, the major upper band representing intact circular
RNA (rpsT/circ-297) and the lower fainter band, marked with
an X in the left margin, which indicates circles
nicked during isolation. The half-life of the intact circular species
(rpsT/297-circ) was 560 s in this experiment. A similar
blot with the same samples was probed with oligonucleotide 995, complementary to sequences near the 3'-end of the T4 td
group I intron in the vector (Fig. 2c). A smear of discrete
bands is visible in the zero time sample, extending from about 400 to
over 1000 nucleotides (Fig. 2c, lane 0).
Virtually all the detectable species disappear within 3-4 min.
Half-lives were measured for three discrete non-circular species shown
by triangles in the left margin in
Fig. 2c, yielding values of 49-57 s. Thus either circular
rpsT mRNA species is considerably more stable than its linear precursors.
Although significantly stabilized, the circular rpsT RNAs
described above are, nonetheless, metabolically labile. To determine whether RNase E is responsible for initiating the degradation of
circular rpsT RNAs in vivo, the stabilities of
the rpsT/circ-336 RNAs in either MG1693/pGM110 (Fig.
2d) or SK5665 (rne1)/pGM110 (Fig. 2e)
were measured after cultures grown at the permissive temperature of
29 °C were induced with IPTG and shifted to 39.5 °C for 20 min to
achieve partial inactivation of the rne1 gene product prior
to RNA extraction. The half-life of the rpsT/circ-336 species in strain SK5665/pGM110 is 1800 ± 155 s (Fig.
2e). This represents a 6-fold increase relative to the same
RNA in the wild type strain under identical conditions (296 ± 33 s) (Fig. 2d).
Circular RNAs, including the rpsT/circ RNAs, are
translated in vivo (Ref. 17 and additional data not shown).
To assess a role for translation in the stability of circular RNAs,
half-lives were determined for several circular rpsT RNAs
containing mutations affecting translational efficiency (Table
I). For comparison, half-lives are also
given for a set of linear, chimeric rpsT mRNAs (rpsT/614) containing similar or identical rpsT
sequences embedded between 40 residues of lac operon
sequence in their 5'-leader and a portion of the 3'-end of the
rrnB operon (16). Such transcripts also effectively mimic
the linear precursors to the circular rpsT RNAs. The data in
Table I show that a circular rpsT RNA is 4-6-fold more
stable than a linear mRNA containing the same rpsT
sequences regardless of translational efficiency. Circular
rpsT/circ-336 (UUG) RNA, which spans residues 93-412
(Fig. 1b), exhibits a half-life 5-fold greater than
rpsT/614 (UUG) mRNA spanning the same rpsT sequences (Table I, line 1). A UUG to AUG change at the initiation codon increases expression of the S20 protein up to 6-fold in vivo (16). The half-life of the rpsT/circ-297 (AUG) RNA
is 4-fold greater than its linear counterpart, rpsT/614
(AUG) (Table I, line 3). A double mutation in the rpsT
leader (16) (G129C, A130U; "
The resistance of a circular RNA to exoribonucleases is obvious (14);
it is thus surprising, if not counterintuitive, that a circular RNA is
significantly more resistant to RNase E, a single-stranded specific
endoribonuclease of limited sequence preference (2, 3, 22), when the
same RNA in linear form is an excellent substrate (4, 13, 20). This
finding is, however, fully consistent with in vitro data
(4). Moreover, the increased stability of the circular
rpsT/circ-336 (UUG) mRNA when RNase E activity is
reduced shows that other ribonuclease activities in E. coli
(3), including RNase III, RNase G/CafA, and RNase I/I*/M, are unable to
compensate efficiently. These findings clearly demonstrate that RNase E
is a 5'-end-dependent endoribonuclease in vivo
as well as in vitro (4, 23, 24) and that the frequently observed 5'
The initial attack of RNase E on circular RNAs in vivo is
5-fold less efficient than on linear RNAs of similar primary sequence. This can be rationalized by a two-site or looping model (3). In this
model, RNase E in the degradosome would first contact linear substrate
mRNAs at their extreme 5'-ends. This 5'-contact would stabilize the
enzyme-substrate complex and would facilitate, possibly in a first
order rearrangement ("looping"), recognition of internal cleavage
sites that may be partially hindered by adjacent secondary structures.
In circular RNAs, there would be no 5'-contact, and cleavage site
recognition itself would become second order and much less efficient
unless the cleavage site were particularly accessible or exposed. Thus
the rate of attack of RNase E on a circular RNA, rather than on a
triphosphorylated RNA as suggested elsewhere (23), defines its basal
rate of activity. As shown here, linear RNA with an unobstructed
5'-triphosphate terminus is attacked 5-fold faster than a circular RNA,
showing that a triphosphate terminus can assist substrate recognition.
A 5'-monophosphate terminus provides a further 20-25-fold stimulation
of the initial rate of RNA cleavage by RNase E in vitro (4,
23) and by a significant but undefined amount in vivo (12).
One clear implication of these data for the two-step model is that
translation affects the second (rearrangement) step rather than the
initial recognition of the 5'-end of the substrate.
It is likely that the degradation of many mRNAs will follow the
behavior of the rpsT mRNA and exhibit 5'-end dependence.
Any exceptions that prove to be insensitive to the state of the 5' terminus will likely be explained by the presence of readily accessible RNase E sites in the body of the mRNA (permitting an increase in
the basal rate of RNase E cleavage) or by inefficient translation.
I thank colleagues and members of the
laboratory for comments and criticisms. Dr. M. Ares, University of
California, Santa Cruz, very kindly provided pRR1 and its sequence and
Dr. S. R. Kushner, University of Georgia, Athens, GA, furnished
strains MG1693 and SK5665.
*
This work was supported by the Medical Research Council of
Canada.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, June 27, 2000, DOI 10.1074/jbc.C000363200
The abbreviations used are:
PCR, polymerase
chain reaction;
IPTG, isopropyl-1-thio-
ACCELERATED PUBLICATION
Stabilization of Circular rpsT mRNA Demonstrates
the 5'-End Dependence of RNase E Action in Vivo*
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
3'
"wave" of subsequent endonucleolytic cleavages, which rapidly
inactivate the entire mRNA (7). The 3' termini generated by RNase E
cleavages are scavenged by 3'-5'-exoribonucleases (1, 3).
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
lacZ(M15)
proA+B+/mcrA
(lac-proAB) thi gyrA96 endA1 hsdR17 relA1 supE44
recA1) and GM323 (JM109 [
GP1]; Ref. 16) are from our
collection; MG1693 (thyA715 rph1) and SK5665 (thyA715
rph1 rne1) were obtained from Dr. S. R. Kushner, University of
Georgia. The vector pRR1 (17) was supplied by Dr. M. Ares, University
of California, Santa Cruz. The rpsT sequences in pGM110 and
pGM113 were amplified by
PCR1 using oligonucleotides
982 (5'-GGAATTCCCCATGGAATTCTCCATATGGAACACATTTGGGAG (5'-primer)), 983 (5'-TTCACAGATCTTCAGCAAATTGGC (3'-primer)), and previously
described DNA templates (13, 16). Amplified DNAs were purified
electrophoretically, cleaved with the appropriate enzymes, repurified,
and ligated into pRR1 cleaved with NcoI and BglII
(see Fig. 1b for a schematic). Following transformation into
JM109, the recombinant plasmids were confirmed by restriction analysis
and DNA sequencing.
RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
View larger version (20K):
[in a new window]
Fig. 1.
a, principle of circularization. In step
1, the 5' and 3' "halves" of a group I intron
(open boxes) can assemble into an active
conformation in the presence of an intervening "passenger" sequence
(solid box) (14, 15, 19). Attack of guanosine on
the 5' exon-intron junction leads to "splicing" of the ends of the
exon and its circularization in step 2. The
vertical arrows show the 5' and 3' splice sites
in permuted order. b, constructions that circularize the
rpsT mRNA. The upper line shows a
schematic of the vector pRR1 (17) whereas the two
lower lines illustrate the portions of the
rpsT gene (solid boxes) inserted
between the NcoI and BglII sites in the vector in
pGM110 and pGM111. Numbers give the sequence coordinates of
the rpsT gene (13).
C at position J7/8-5 (21), known to reduce the rate of self-splicing by group I introns by
>103, was introduced into the 3'-"half" of the
group I sequence in pGM110 generating pGM116. This mutation abolishes
formation of rpsT/circ-336 RNA (not shown). Taken together,
the Northern blots, the permutation analyses, and the sequences of the
RT-PCR products demonstrate unambiguously that expression of the
rpsT sequences embedded in pGM110 or pGM111 yields circular
rpsT RNAs, which accumulate to readily detectable levels,
roughly 4-5-fold higher than those of the endogenous rpsT
mRNAs (Fig. 2a, lanes 1-5).
View larger version (13K):
[in a new window]
Fig. 2.
Detection of circular RNAs by Northern
blotting. a, total RNA from JM109 (10 µg; lanes
1 and 6) or from JM109 containing pGM110 (5 µg;
lanes 2, 3, 7, and 8) or
pGM111 (5 µ g; lanes 4, 5, 9, and
10), extracted prior to ( 
) or after induction (+) was
analyzed by Northern blotting (see "Experimental Procedures"). RNAs
in lanes 1-5 were detected by a cRNA probe, and RNAs in
lanes 6-10 were detected by annealing to oligonucleotide
993 complementary to rpsT mRNAs with a circular
junction. Numbers in the left margin give the sizes (nucleotides
(nt)) of markers and the chromosomally encoded
rpsT mRNAs. The triangles show the circular
RNAs; X denotes circular RNA nicked during isolation or
handling. b-e, decay of circular or chimeric RNAs after
rifampicin treatment. Cultures of JM109/pGM111 (b and
c), MG1693/pGM110 (d), or SK5665/pGM110
(e) were induced with IPTG at 37 °C (b and
c) or at 39.5 °C (d and e) for 20 min prior to inhibition of transcription by rifampicin and extraction
of RNA at various times thereafter shown above each panel (see
"Experimental Procedures"). Circular rpsT mRNAs were
detected by annealing to oligonucleotide 993 (b,
d, and e). RNAs in c were probed with
oligonucleotide 995 (5'-GGTCGTTAATCTTACCCC) complementary to group I
intron sequences. Triangles in the right
margin denote circular rpsT species. The
triangles in the left margin of
c refer to the RNAs mentioned in the text. X
denotes nicked species.
View larger version (23K):
[in a new window]
Fig. 3.
Inverse PCR detection of circular
rpsT RNA. a, principle of the method.
Reverse transcription is primed by oligonucleotide 992, and the product
is amplified by oligonucleotides 991 and 992 (see "Experimental
Procedures"). The position and orientation of the primers are such
that circular RNA (left) but not linear RNA
(right) can serve as an amplifiable template. b,
analysis of inverse RT-PCR products. Template RNA was extracted from
JM109/pGM110 (lanes 2, 3, 6, and
7; predicted product of 189 bp) or JM109/pGM111 (lanes
4 and 5; predicted product of 149 bp) and used for
RT-PCR (see "Experimental Procedures"). In lanes 3 and
5, the template RNA was linearized outside the region of
amplification with RNase H and oligonucleotide 481 (13) prior to
RT-PCR. In lane 7, reverse transcriptase was omitted in the
first step.
3, 4"), which reduces S20
expression substantially, was introduced into pGM110 to form pGM113.
The half-life of the rpsT/circ-336 RNA encoded by pGM113 is
almost 2-fold lower than the nearly identical circular RNA encoded by
pGM110 (compare lines 1 and 2 in Table I) but is still much higher than
the corresponding rpsT/614 mRNA containing the 3,
4 mutation (Table I, line 2). These results show that the
stabilities of circular mRNAs are subject to almost the same degree
of translational modulation as their linear counterparts and more
interestingly that circularization protects the rpsT mRNA most effectively when translation is highly efficient (compare rpsT/297-circ (AUG) to rpsT/336-circ (3, 4)
in Table I).
Translational control of stability of circular and linear rpsT
mRNAs in vivo
3, 4
mutation in pGM113 and pGP12 reduces translational efficiency without
affecting the Shine-Dalgarno sequence or the initiation codon (16). The
initiation codon is altered to AUG and the entire 5'-untranslated
leader is deleted in pGM111 (Fig. 1b) and pGP11. These
constructs all contain the entire rpsT coding sequence
(residues 133-393) and 3' sequences extending to residue 412 or 413 (see also Fig. 1b).
3' vectorial character of mRNA decay in
vivo (1, 3, 4, 7) is due to the end dependence of RNase E (4, 23).
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: Dept. of Biochemistry
and Molecular Biology, D. H. Copp Bldg., University of British Columbia, 2146 Health Sciences Mall, Vancouver, B.C. V6T 1Z3, Canada. Tel.: 604-822-2792; Fax: 604-822-5227; E-mail:
gamackie@interchange.ubc.ca.
ABBREVIATIONS
-D-galactopyranoside;
RT, reverse
transcription;
Pipes, 1,4-piperazinediethanesulfonic acid;
bp, base pair(s).
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
1.
Belasco, J. G.
(1993)
in
Control of Messenger RNA Stability
(Belasco, J. G.
, and Brawerman, G., eds)
, pp. 3-12, Academic Press, San Diego, CA
2.
Melefors, Ö.,
Lundberg, U.,
and von Gabain, A.
(1993)
in
Control of Messenger RNA Stability
(Belasco, J. G.
, and Brawerman, G., eds)
, pp. 53-70, Academic Press, San Diego, CA
3.
Coburn, G. A.,
and Mackie, G. A.
(1999)
Prog. Nucleic Acid Res. Mol. Biol
62,
55-108
4.
Mackie, G. A.
(1998)
Nature
395,
720-724
5.
Miczak, A.,
Kaberdin, V. R.,
Wei, C.-L.,
and Lin-Chao, S.
(1996)
Proc. Natl. Acad. Sci. U. S. A.
93,
3865-3869
6.
Py, B.,
Higgins, C. F.,
Krisch, H. M.,
and Carpousis, A. J.
(1996)
Nature
381,
169-172
7.
Goodrich, A. F.,
and Steege, D. A.
(1999)
RNA
5,
972-985
8.
Emory, S. A.,
Bouvet, P.,
and Belasco, J. G.
(1992)
Genes Dev.
6,
135-148
9.
Hansen, M. J.,
Chen, L.-H.,
Fejzo, M. L. S.,
and Belasco, J. G.
(1994)
Mol. Microbiol.
12,
707-716
10.
Bouvet, P.,
and Belasco, J. G.
(1992)
Nature
360,
488-491
11.
Mackie, G. A.,
Genereaux, J. L.,
and Masterman, S. K.
(1997)
J. Biol. Chem.
272,
609-616
12.
Lin-Chao, S.,
and Cohen, S. N.
(1991)
Cell
65,
1233-1242
13.
Mackie, G. A.,
and Genereaux, J. L.
(1993)
J. Mol. Biol.
234,
998-1012
14.
Puttaraju, M.,
and Been, M. D.
(1992)
Nucleic Acids Res
20,
5357-5364
15.
Ford, E.,
and Ares, M.
(1994)
Proc. Natl. Acad. Sci. U. S. A.
91,
3117-3121
16.
Parsons, G. D.,
Donly, B. C.,
and Mackie, G. A.
(1988)
J. Bacteriol
170,
2485-2492
17.
Perriman, R.,
and Ares, M.
(1998)
RNA
4,
1047-1052
18.
Mackie, G. A.
(1989)
J. Bacteriol.
171,
4112-4120
19.
Galloway-Salvo, J.,
Coetzee, T.,
and Belfort, M.
(1990)
J. Mol. Biol
211,
537-549
20.
Mackie, G. A.
(1991)
J. Bacteriol.
171,
2488-2497
21.
Tanner, M. S.,
Anderson, E. M.,
Gutell, R. R.,
and Cech, T. R.
(1997)
RNA
3,
1037-1051
22.
McDowall, K. J.,
Lin-Chao, S.,
and Cohen, S. N.
(1994)
J. Biol. Chem.
269,
10790-10796
23.
Jiang, X.,
Diwa, A.,
and Belasco, J. G.
(2000)
J. Bacteriol.
182,
2468-2475
24.
Tock, M. R.,
Walsh, A. P.,
Carroll, G.,
and McDowall, K. J.
(2000)
J. Biol. Chem.
275,
8726-8732
Copyright © 2000 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
 |
|
  T. Perwez, D. Hami, V. F. Maples, Z. Min, B.-C. Wang, and S. R. Kushner Intragenic suppressors of temperature-sensitive rne mutations lead to the dissociation of RNase E activity on mRNA and tRNA substrates in Escherichia coli Nucleic Acids Res., September 1, 2008; 36(16): 5306 - 5318. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 V. G. Stepanov and G. E. Fox Stress-Driven In Vivo Selection of a Functional Mini-Gene from a Randomized DNA Library Expressing Combinatorial Peptides in Escherichia coli Mol. Biol. Evol., July 1, 2007; 24(7): 1480 - 1491. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 J. S. Hankins, C. Zappavigna, A. Prud'homme-Genereux, and G. A. Mackie Role of RNA Structure and Susceptibility to RNase E in Regulation of a Cold Shock mRNA, cspA mRNA J. Bacteriol., June 15, 2007; 189(12): 4353 - 4358. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
S. Even, O. Pellegrini, L. Zig, V. Labas, J. Vinh, D. Brechemmier-Baey, and H. Putzer Ribonucleases J1 and J2: two novel endoribonucleases in B.subtilis with functional homology to E.coli RNase E Nucleic Acids Res., April 14, 2005; 33(7): 2141 - 2152. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K. E. BAKER and C. CONDON Under the Tucson sun: A meeting in the desert on mRNA decay RNA, November 18, 2004; 10(11): 1680 - 1691. [Full Text] [PDF]
|
|
|
|
 |
|
 Y. Redko, M. R. Tock, C. J. Adams, V. R. Kaberdin, J. A. Grasby, and K. J. McDowall Determination of the Catalytic Parameters of the N-terminal Half of Escherichia coli Ribonuclease E and the Identification of Critical Functional Groups in RNA Substrates J. Biol. Chem., November 7, 2003; 278(45): 44001 - 44008. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
J. S. Sharp and D. H. Bechhofer Effect of Translational Signals on mRNA Decay in Bacillus subtilis J. Bacteriol., September 15, 2003; 185(18): 5372 - 5379. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 C. Condon RNA Processing and Degradation in Bacillus subtilis Microbiol. Mol. Biol. Rev., June 1, 2003; 67(2): 157 - 174. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 Y. Feng, T. A. Vickers, and S. N. Cohen The catalytic domain of RNase E shows inherent 3' to 5' directionality in cleavage site selection PNAS, November 12, 2002; 99(23): 14746 - 14751. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
D. Kennell Processing Endoribonucleases and mRNA Degradation in Bacteria J. Bacteriol., September 1, 2002; 184(17): 4645 - 4657. [Full Text] [PDF]
|
|
|
|
|
|
S. R. Kushner mRNA Decay in Escherichia coli Comes of Age J. Bacteriol., September 1, 2002; 184(17): 4658 - 4665. [Full Text] [PDF]
|
|
|
|
 |
|
 G. Hambraeus, K. Karhumaa, and B. Rutberg A 5' stem-loop and ribosome binding but not translation are important for the stability of Bacillus subtilis aprE leader mRNA Microbiology, June 1, 2002; 148(6): 1795 - 1803. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
A. P. Walsh, M. R. Tock, M. H. Mallen, V. R. Kaberdin, A. v. Gabain, and K. J. McDowall Cleavage of poly(A) tails on the 3'-end of RNA by ribonuclease E of Escherichia coli Nucleic Acids Res., May 1, 2001; 29(9): 1864 - 1871. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
| All ASBMB Journals | Molecular and Cellular Proteomics |
| Journal of Lipid Research | ASBMB Today |