Received 29 August 2000/Returned for modification 26 September
2000/Accepted 24 October 2000
To determine the influence of posttranscriptional modifications on
3' end processing and RNA stability in plant mitochondria, pea
atp9 and Oenothera atp1 transcripts were
investigated for the presence and function of 3' nonencoded
nucleotides. A 3' rapid amplification of cDNA ends approach initiated
at oligo(dT)-adapter primers finds the expected poly(A) tails
predominantly attached within the second stem or downstream of the
double stem-loop structures at sites of previously mapped 3' ends.
Functional studies in a pea mitochondrial in vitro processing system
reveal a rapid removal of the poly(A) tails up to termini at the
stem-loop structure but little if any influence on further degradation
of the RNA. In contrast 3' poly(A) tracts at RNAs without such
stem-loop structures significantly promote total degradation in vitro.
To determine the in vivo identity of 3' nonencoded nucleotides more
accurately, pea atp9 transcripts were analyzed by a direct
anchor primer ligation-reverse transcriptase PCR approach. This
analysis identified maximally 3-nucleotide-long nonencoded extensions
most frequently of adenosines combined with cytidines. Processing
assays with substrates containing homopolymer stretches of different
lengths showed that 10 or more adenosines accelerate RNA processivity,
while 3 adenosines have no impact on RNA life span. Thus
polyadenylation can generally stimulate the decay of RNAs, but
processivity of degradation is almost annihilated by the stabilizing
effect of the stem-loop structures. These antagonistic actions thus
result in the efficient formation of 3' processed and stable transcripts.
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INTRODUCTION |
Control of the amount of
translatable mRNA is a common parameter to regulate gene expression in
many organisms. The available quantity of an RNA depends largely on the
rate of synthesis and/or posttranscriptional processes which control
the stability of a transcript by preventing it from degradation. Such
posttranscriptional processes have been studied in prokaryotes and
different subcellular compartments of eukaryotic cells. In spite of the
many variations, some common features behind these processes emerge in
all organisms and systems. These include the involvement of mRNA
secondary structures and 3' polyadenylation of RNA. While organized RNA
secondary structures generally support transcript stabilization,
polyadenylation has opposing functions in eukaryotes and prokaryotes.
In the nucleus of eukaryotic cells, pre-mRNAs are polyadenylated at 3'
ends that have been generated by endonucleolytic cleavages. These
poly(A) tails play important roles in translation initiation and mRNA
export from the nucleus and also have a major function in stabilizing
mRNAs (27). A completely different function has been attributed to polyadenylation in prokaryotes, where the
degradation of mRNA is stimulated by the presence of 3'
poly(A) tracts (4). The degradation-promoting effect of
polyadenylation was even found in transcripts, which were otherwise
protected and stabilized by stem-loop structures (3). A
similar effect has also been observed in chloroplasts, where
polyadenylation also accelerates the decay of mRNA (15,
25).
Polyadenylation has also been found in mitochondria of various
organisms. The addition of adenosines to mRNAs in mammalian mitochondria has been suggested to create functional translation stop
codons, which are not encoded in the DNA (22). Short
oligo(A) tails were also detected at the 3' ends of RNA in yeast
mitochondria. These are about 8 nucleotides (nt) long and predominantly
found at the large rRNAs (29). Similarly, oligo(A) tracts
were found at some RNA species of the fragmented rRNA in
Plasmodium falciparum (12). While the function
of the oligo(A) tails in yeast is still unclear, those in
Plasmodium were suggested to protect these RNA fragments
from exonucleolytic digestion. Recently, polyadenylation was also
reported for RNAs in plant mitochondria. In sunflower a dicistronic
mRNA associated with cytoplasmic male sterility was suggested to be
specifically destabilized by polyadenylation in fertility-restored
lines (10). In maize, polyadenylation was detected at
multiple sites of the cox2 transcripts. As in sunflower,
poly(A) tracts were indicated to decrease mRNA stability, although the
effect observed in maize mitochondrial extracts was very weak
(19). We report here nonencoded nucleotides at the 3' ends
of pea and Oenothera mitochondrial transcripts containing double inverted repeats in their 3' untranslated regions (UTRs). These
structures have been suggested to increase the stability of the RNA,
and the stem-loop structures of pea atp9 transcripts as well
as of orf138 mRNAs in Brassica were found to act
as processing signals and/or stability elements at least in vitro
(1, 5, 6, 16, 23). In this report special emphasis was
dedicated to the interaction of the stabilizing effect of such
double stem-loop structures and degradation-enhancing polyadenylation.
In addition to adenosines, nonencoded cytidines and, to a
lesser extent, uridines were detected in vivo. The combination of
nonencoded cytidines with adenosines may indicate an involvement
of the tRNA terminal nucleotidyltransferase in the addition of
nonencoded nucleotides to 3' ends of plant mitochondrial mRNAs.
| |
MATERIALS AND METHODS |
3' RACE analysis of mtRNA.
The 3' rapid amplification of
cDNA ends (RACE) was carried out in principle as described by Frohmann
et al. (9). First-strand synthesis was initiated on 5 µg
of total pea mitochondrial RNA (mtRNA) with an
oligo(dT)17-adapter primer (DTXSC) using Superscript II
reverse transcriptase (RT) (GIBCO-BRL) under conditions given in the
manufacturer's manual. About one-fourth of the total cDNA pool was
used as the template in a PCR with adapter primer XSC and
atp9-specific primer PA-1 (
349 to 329) with KlenTaq
polymerase in a buffer supplied by the manufacturer (Clontech). After
35 cycles (30 s at 94°C, 1 min at 40°C, and 1 min at 68°C), PCR
fragments were size fractionated on a 1.5% agarose gel and distinct
products with sizes of 0.3, 0.4, 0.8, and 1.0 kb were observed above a smear ranging from about 0.2 to 2.0 kb. Since the PCR fragments generated from pea atp9 transcripts, which are
polyadenylated downstream of the double stem-loops, are expected to be
at least 665 bp long, cDNA fragments between 0.5 and 0.9 kb in length
were eluted from the gel and used as templates in a PCR with primers XSC and PA-10, a nested atp9-specific primer (98 to 84
with a 5'-attached EcoRI restriction site). After 35 cycles
(30 s at 94°C, 1 min at 50°C, and 1 min at 68°C), reaction
products were digested with SalI and EcoRI and
run on an agarose gel. cDNA fragments between about 0.35 and 0.55 kb
long including the expected fragment of about 0.43 kb, were eluted from
the gel and cloned into pBluescript vectors (Stratagene) following
standard protocols (24). In an analogous approach,
oligo(dT)-adapter primer DTXSC and adapter primer XSC were replaced by
DTNSX-1 and NSX-1 oligonucleotides, and atp9-specific
primers PA-10 and PAX-1 (+259 to +274 with a 5'-attached
XbaI restriction site) were used. cDNA clones generated with
the NSX primer set carry NsiI restriction sites immediately downstream of the poly(A) tracts. Linearization at this site allows the
in vitro transcription of mRNAs ending with poly(A) tracts.
The 3' RACE analysis of Oenothera atp1 transcripts was
essentially performed as described above for pea atp9 with
the following modifications. About 10 µg of Oenothera
mtRNA and DTNSX, NSX, and atp1-specific primers OeatpA-RI
(+1362 to +1380 with a 5'-attached EcoRI restriction site)
and OeAXI (+1721 to +1736 with a 5'-attached XbaI
restriction site) were used for the amplification of the 3' regions of
atp1 transcripts. DNA fragments obtained in these PCRs were
digested with XbaI and SalI and were cloned into
pBluescript II vectors. Locations of all oligonucleotides are given
relative to the translation start codon.
Direct ligation of anchor primers to 3' ends of in vitro
processing products and steady-state mtRNA.
In vitro processing
assays were carried out under standard conditions, and reaction
products were separated on a 6% polyacrylamide gel. Radioactive bands
were visualized by autoradiography and were excised from the gel. The
RNAs were eluted from the gel in a buffer containing 0.5 M ammonium
acetate, 0.1 mM EDTA, and 0.1% sodium dodecyl sulfate. After
phenol-chloroform extraction, the in vitro processing products were
ethanol precipitated and ligated to 20 pmol of anchor primer (RiboNSX)
in the presence of 20 U of RNA ligase (GIBCO-BRL), 1% (vol/vol)
dimethyl sulfoxide, 50 mM Tris-HCl (pH 7.5), 10 mM MgCl2,
10 mM dithiothreitol, 0.25 mM ATP, and 0.6 µg of bovine serum albumin
per µl. The ligation reaction was performed for 24 h at 15°C
in a 10-µl total reaction volume. Following two rounds of
phenol-chloroform extraction, nonligated anchor primers were removed by
centrifugation in Microcon 30 microfiltration units at
14,000 × g to a final volume of 10 µl. First-strand
synthesis was primed with oligonucleotide NSX-1 using the complete
ligation reaction as the template and Superscript II RT. Subsequent
amplification with primers PAX-1 and NSX-1 was performed with KlenTaq
polymerase (Clontech) in a buffer supplied by the manufacturer. After
35 cycles (1 min at 94°C, 1 min at 50°C, and 30 s at 68°C), PCR
products were digested with XbaI and SalI and
were cloned into pBluescript vectors. Respective clones were identified
in a colony hybridization using Hybond-N membranes (Amersham Pharmacia
Biotech) and oligonucleotide PA-17hyb (+266 to +284) as probe,
following a protocol given by the manufacturer.
For the 3' end analysis of steady-state transcripts, the procedure
described above was used with the following modifications. One
microgram of total mtRNA was added to the ligation reaction mixture, and primer PA-10 was used as the atp9-specific
primer in the amplification reaction.
Lysate preparation and in vitro processing reactions.
Pea
mitochondrial lysate preparation and the in vitro processing reactions
were performed as described previously (6).
DNA templates and in vitro transcription.
Polyadenylated pea
atp9 precursor molecules are transcribed from cDNA clone
9.17 generated in the 3' RACE approach with primers PAX-1 and NSX-1 on
in vitro-transcribed RNA obtained from clone no. 9. Plasmid 9.17 was
linearized with NsiI and transcribed with T7 RNA polymerase.
The resulting transcript (117 nt) contains the pea atp9
double stem-loop and 43-nt upstream and 23-nt downstream sequences. The
upstream part corresponds to vector sequences from the T7 transcription
start point to the XbaI restriction site. The downstream
moieties comprise 21 adenosines at the 3' end. Transcripts containing
(A)3 or (A)10 poly(A) tracts downstream of the
inverted repeat are directly transcribed from DNA fragments obtained by
amplification with primer M13 universal and primers IR+dT3 [(A)3] and
IR+dT10 [(A)10] on clone 9.17 as
the DNA template.
The nonpolyadenylated standard substrate with original mitochondrial
upstream sequences is generated by the transcription of PCR products as
previously described by Dombrowski et al. (6).
The pea atp9 RNA substrate without inverted repeat (101 nt)
is transcribed from a DNA template amplified by PCR with primers T7IR
(+159 to +179 with a T7 promoter attached at the 5'
end) and PIR (+241 to +258). To generate analogous
substrates with (A)21 (122 nt), (A)10 (111 nt),
and (A)3 (104 nt) 3' homopolymer sequences, respectively,
primers IRdT, IRdT10, and
IRdT3 were used instead of PIR.
All cloned DNA templates were inspected by complete sequence analysis.
In vitro transcription reactions were performed with T7 RNA polymerase
(MBI Fermentas) in a buffer supplied by the manufacturer. Purification
of all in vitro transcripts by polyacrylamide gel electrophoresis was
carried out as described elsewhere (6).
Nucleic acids.
Pea and Oenothera mtRNAs were
isolated from respective organelles enriched by differential
centrifugation and purified on Percoll (Amersham Pharmacia Biotech)
gradients as described previously (2). Sequences of the
primers used are available on request. All oligonucleotides were
purchased from GIBCO-BRL.
Miscellaneous methods.
Sequencing reactions were carried out
with the Thermo Sequenase fluorescent labeling kit (Amersham Pharmacia
Biotech) according to instructions given by the manufacturer. All
standard methods were used as described by Sambrook et al.
(24).
| |
RESULTS |
Poly(A) tails at the 3' ends of atp9 mRNAs in pea
mitochondria.
The pea atp9 gene is transcribed into
three different mRNA species with differing 5' termini but identical 3'
ends. These 3' termini were mapped in two independent S1 protection
analyses within the 3' part of the second of two consecutive inverted
repeats and immediately downstream thereof (6, 21).
Recently it was found that this double inverted repeat with the
potential to fold into a double stem-loop structure does not terminate
transcription in vitro but rather functions as a processing
signal and stabilizing element during a controlled 3' processing event
(5, 6). To investigate whether nonencoded poly(A) tails
are present at these transcript termini, a 3' RACE analysis, including
two rounds of PCR with an oligo(dT)-adapter primer and two nested
atp9-specific primers, was performed with total pea mtRNA
(for details see Materials and Methods). The sequence analysis of 18 clones indicated the presence of nonencoded poly(A) tails at the 3'
ends of these mRNAs. In four clones, polyadenylation sites
are located at positions +6 and +2 relative to the first nonpaired
nucleotide (+1) downstream of the second stem (Fig.
1). The majority of the poly(A) tracts are found at positions 2 to 5 within the downstream part of the
second stem. These polyadenylation sites coincide with previously mapped 3' ends. Three clones contained poly(A) sequences attached within the second loop, while two others are added at the beginning and
end of the upstream part of the second stem, respectively. The lengths
of the poly(A) stretches vary between 14 and 25 adenosines, with 10 of
the 18 clones containing more than the 17 adenosines derived from
the oligo(dT)-adapter primer. In four clones, nonencoded cytidine,
guanosine, and thymidine (corresponding to uridine in the RNA)
nucleotides are found predominantly in the 5' part of the attached
sequences. Almost all clones investigated are edited at position
+20 (relative to the translation start codon [+1]), while a
cytidine-to-uridine alteration at position +50 is found less
frequently. Both editing events change the codon identity from serine
to leucine (data not shown).
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FIG. 1.
3' RACE analysis of pea mitochondrial atp9
transcripts. (A) Previously mapped 3' ends are indicated within the pea
atp9 potential double stem-loop structure (arrows). (B)
Nucleotide sequences of 3' RACE clones containing poly(A) tails.
Nonencoded nucleotides found in 18 analyzed cDNA clones (designations
are shown on the left) are given in lowercase letters. The positions of
the polyadenylation sites (indicated above the sequences) correspond to
the 3'-most nucleotide. Numbering refers to the first nucleotide (+1)
downstream of the inverted repeats (indicated by oppositely oriented
grey shadowing arrows) in the genomic sequence (gen). Vertical arrows
beneath the genomic sequence indicate previously mapped 3' ends. (C)
The numbers of clones identified are given for each polyadenylation
site.
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Potential poly(A) tracts in Oenothera atp1
transcripts.
The analysis of Oenothera atp1 transcripts
extends this study to other double-stem-loop-containing mRNAs from
mitochondria of another plant species (Fig.
2). Amplification with an
atp1-specific primer and an adapter primer on a total cDNA
pool primed with an oligo(dT)-adapter primer generated a dominant
product of about 0.45 kb expected of nonencoded poly(A) sequences
attached downstream of the stem-loop structure (Fig. 2B). This fragment
was eluted from the gel and was either used as a template in a second
PCR with a nested, atp1-specific primer and an adapter
primer or directly cloned. Sequencing of 10 cDNA clones obtained from
both amplification reactions revealed poly(A) tracts attached at
positions +5, +4, and +3 immediately downstream of the double stem-loop
structure. These polyadenylation sites are consistent with previously
mapped 3' ends (26). Only a single clone indicated a
polyadenylation site at position 3 within the downstream part
of the second stem (Fig. 2C). These results show that the
distribution of the polyadenylation sites in Oenothera atp1
mRNAs is less variable than in pea atp9 transcripts. The lengths of the poly(A) tails observed in the Oenothera atp1 cDNA clones range from 16 to 23 adenosines with only a single guanosine insertion within a poly(A)
sequence.
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FIG. 2.
Identification of potential polyadenylation sites in
Oenothera atp1 transcripts. (A) Potential double stem-loop
structure found in the 3' UTR of Oenothera atp1 mRNAs.
Previously mapped 3' termini are indicated by arrows. (B) DNA fragments
generated in a PCR with adapter primer (NSX) and an
atp1-specific oligonucleotide (OeatpA-RI) on
oligo(dT)-adapter-primed cDNA are size fractionated on a 1.5% agarose
gel (lane P). Besides minor fragments of about 1.0, 0.85, and 0.2 kb, a
strong cDNA fragment (0.45 kb) corresponding to RNAs polyadenylated
downstream of the stem-loop is detected. Lengths of coelectrophoresed
DNA marker fragments (lane M) are given in kilobase pairs on the left.
(C) Partial sequences of Oenothera atp1 cDNA clones
containing nonencoded poly(A) tails (indicated in lowercase letters).
Designations and numbering are analogous to those for Fig. 1. (D)
Correlation of the number of clones with poly(A) addition sites.
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Rapid and efficient processing of polyadenylated pea
atp9 transcripts in vitro.
The results of the 3' RACE
analyses identified nonencoded poly(A) tracts at the 3' ends of
transcripts containing double stem-loop structures in their 3'
UTRs. Such poly(A) tails were recently suggested to decrease mRNA
stability in plant mitochondria (10, 19). This
destabilizing effect would counteract the function of the double
stem-loop, which was found to act as a processing signal and stability
element at least in vitro (5, 6). To solve this question,
the consequence of poly(A) tails on double-stem-loop-containing mRNA
was tested in vitro. Nonpolyadenylated synthetic transcripts (96 nt)
used in these assays were transcribed from a T7 promoter-containing PCR product (Fig. 3A) and corresponded to
the standard substrate shown to be correctly processed in a pea
mitochondrial in vitro system (6). It contains the pea
atp9 double stem-loop structure and 21 and 28 original
mitochondrial nt upstream and downstream, respectively. In the
polyadenylated mRNA (113 nt), the 3' trailer downstream of the
stem-loop structure consists of a 21-mer adenosine homopolymer
downstream of two mitochondrially encoded nucleotides while the
upstream leader (42 nt) represents pBluescript vector sequences.
Details of the construction of the DNA templates for transcription of
these substrates (Fig. 3B) are given in Materials and Methods. To test
the influence of the regions upstream of the inverted repeat, an
analogous RNA substrate, which contains original mitochondrial
downstream sequences (28 nt) and the alien sequences deriving from the
vector (42 nt), was also tested in vitro. After incubation of the
nonpolyadenylated standard transcript for 60 min, a single processing
product of about 70 nt was observed (Fig. 3C, left). This product
corresponds to an RNA species where the downstream part is removed, as
seen in previous processing experiments (6). An
accelerated generation of processing products is observed upon
incubation of polyadenylated substrates. After 10 min, two processing
products of about 70 and 80 nt are generated. While the smaller product
has a size consistent with a 3' end similar to that of the product
obtained in the reaction with the nonpolyadenylated standard substrate,
an additional RNA, about 5 to 10 nt larger, is generated. Longer
incubation (for 60 min) resulted in the generation of two products that
seem to be slightly smaller than those observed after 10 min (Fig. 3C,
right). A product very similar to the one generated from the
nonpolyadenylated standard substrate and to the smaller one (70 nt)
deriving from the polyadenylated substrate was observed in in vitro
tests with the nonpolyadenylated substrate, with vector sequences
upstream of the stem-loop structure. The temporal dynamic of the
product formation is identical to that of the processing reaction of
the nonpolyadenylated standard substrate, which indicates that
sequences upstream of the stem-loop structure have no
degradation-promoting function (data not shown).
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FIG. 3.
In vitro processing of polyadenylated and
nonpolyadenylated pea atp9 precursor molecules. (A)
Generation of the pea atp9 standard transcript containing a
double inverted repeat (grey horizontal arrows). The substrate is
transcribed in vitro (IVT) from a PCR product obtained with
primers PA-12 and T7IVR+, which contains a promoter for T7
RNA polymerase (T7P, hatched box). (B) The polyadenylated substrate is
transcribed from the linearized clone 9.17, obtained by RT-PCR cloning
of a polyadenylated pea atp9 mRNA with primers NSX-dT
(adapter primer for cDNA synthesis), PAX-1, and NSX-1 (PCR). (C)
Identical amounts of substrates (about 12,000 cpm) with
[poly(A)+] and without [poly(A)] poly(A)
tracts are incubated for 10 and 60 min in a pea mitochondrial lysate.
Resulting reaction products are separated on a 6% polyacrylamide gel
(lanes 10 and 60). Control reactions (lanes C10 and
C60) are performed under identical conditions without
protein. Lengths of coelectrophoresed DNA marker fragments are given in
nucleotides (Nt) in the right margin. Discrepancies between the sizes
of RNA molecules and the DNA marker fragments are due to different
migration velocities of RNA and DNA molecules.
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A similar processing pattern was observed with heterologous synthetic
polyadenylated and nonpolyadenylated Oenothera atp1 transcripts. Again, accelerated processing is observed with
poly(A)+ substrates, while final degradation of this RNA
seems to be unaffected (data not shown).
The precise 3' ends of the detected products were determined by a
direct ligation of anchor primers (RiboNSX) to eluted RNA species,
followed by an RT-PCR analysis initiated with primer NSX complementary
to the anchor primer (Fig. 4). Sequencing
of 22 cDNA clones obtained from the processing products generated from
the nonpolyadenylated standard substrate revealed 3' ends which scatter
over a broad range (from nucleotide positions 26 to +17) with
reference to the first nucleotide (+1) downstream of the second
stem-loop (Fig. 4B). The 3' ends detected in 14 clones, however, are
located within the downstream part of the second stem or immediately
downstream of this structure and coincide with previously mapped
transcript termini (6) (Fig. 1 and 4B). In the larger gel
fragment excised, other termini are identified at low frequencies,
which are attributed to the background of random termini in the RNA
population of such an in vitro processing reaction (Fig. 4A).
Transcript termini from the smaller processing products generated after
10 and 60 min from polyadenylated substrates are detected in 9 and 12 clones, respectively, and are almost exclusively located within the
second stem, which is consistent with the majority of termini generated
from the nonpolyadenylated precursor RNA (Fig. 4D and F). In contrast
the bulk of the 3' ends of the larger processing products are found
immediately downstream of the second stem with slightly shorter
products observed after 60 min (Fig. 4C and E). Interestingly, half of
the 22 clones obtained from these products end with a nonencoded
adenosine, indicating that the poly(A) tail is not completely removed.
In summary the results of the in vitro processing assays indicate that
polyadenylated transcripts are processed much faster than
nonpolyadenylated substrates. Total degradation of the
double-stem-loop-containing substrates, however, is not significantly
accelerated.
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FIG. 4.
Precise determination of 3' termini of in vitro
processing products. (A) The in vitro processing products (b to f,
indicated by dotted boxes) obtained from nonpolyadenylated
[poly(A)] and polyadenylated [poly(A)+]
substrates with inverted repeats (IR+) were excised, and
the RNA molecules were eluted from the gel. The 3' ends of the
different products were analyzed by direct anchor primer ligation
followed by RT-PCR analysis. Lanes 10 and 60 represent results at 10 and 60 min; lanes C10 and C60 represent control
reactions at 10 and 60 min. (B to F) Secondary structures of the pea
atp9 double stem-loop with nonpolyadenylated (B) and
polyadenylated (C to F) downstream moieties. Arrows indicate the 3'
terminal nucleotide found in individual clones. The numbers of cDNA
clones containing certain 3' ends are given at the arrows. Designations
of the individual stem-loops (B to F) correspond to the designations of
the analyzed processing products (b to f).
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Temporal dynamics of the in vitro processing of polyadenylated pea
atp9 transcripts.
The generation of an additional
distinct product from polyadenylated transcripts raises the possibility
that this could be an intermediate processing product. To investigate
the temporal course of the in vitro processing of polyadenylated pea
atp9 mRNAs (Fig. 1B), the generation of processing products
was followed over a period of 90 min (Fig.
5). Already after 1 min, diffuse smaller
RNAs appear, indicating the initiation of the processing reaction,
which results in the detectable formation of the approximately 90- to
95-nt-long RNA fragment after 2.5 min. The smeared RNA between the
substrate and this product indicates exonucleolytic processivity. This
impression is substantiated by the continuously decreasing size of this
90- to 95-nt-long RNA, with several nucleotides being consecutively
removed upon prolonged incubation. A similar effect is also seen with
the 80- to 85-nt-long product, which first appears after 5 min. The
substrate and the two processing products show distinct dynamics in
their respective abundances. As expected, the substrate decreases
continuously over 90 min. The larger product (90 to 95 nt) has its
highest abundance after 10 min, while the smaller product (80 to 85 nt)
reaches maximum abundance after 60 min. These results suggest that the
large processing product, whose 3' ends map immediately downstream of
the double stem-loop, is a stabilized intermediate in the
exonucleolytic generation of the small product, with its 3' ends
located within the downstream part of the second stem. Thus, an
exoribonuclease seems to remove the poly(A) tails very rapidly but
stalls or falls away from the RNA either at the 3' end of the stem-loop
structure or simply at the transition from the poly(A) stretch to the
"normal" sequence. The smaller product most likely results from a
second steric hindrance within the downstream part of the stem.
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FIG. 5.
Time course of the in vitro processing of a
polyadenylated pea atp9 precursor. A polyadenylated pea
atp9 substrate is incubated over a period of 90 min, and
probes are taken at 0 to 90 min, as indicated above the lines. Control
reactions are performed under identical conditions in the absence of
protein for 0 (C0) and 90 (C90) min. Sizes of
coelectrophoresed DNA marker fragments are given in nucleotides (Nt).
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Accelerated total degradation of RNA substrates with no inverted
repeat.
The results presented above indicate that polyadenylation
accelerates RNA processing of stem-loop-containing RNAs, while the total degradation of the transcripts remains almost unaffected. To
investigate the stabilizing function of this stem-loop structure during
the formation of the different processing products, polyadenylated and
nonpolyadenylated RNAs without a stem-loop were tested in the in vitro
processing system. The substrate without a stem-loop structure and
poly(A) tract, representing 101-nt-long RNA molecules with 3' ends just
upstream of the first inverted repeat (Fig. 6A), is consecutively degraded without
formation of any stable intermediate, indicating that the stem-loop is
indeed responsible for the generation of stabilized products (Fig. 6B,
left). A different processivity is seen with polyadenylated
transcripts. Here the presence of a poly(A) tract in the substrate
significantly accelerates the total turnover of the precursor RNA (Fig.
6B, center). Only a weak signal indicates the presence of an
intermediate, which corresponds in size to the RNA without a poly(A)
tail. The low intensity of this signal indicates only weak stability of
this product.
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FIG. 6.
Accelerated degradation of RNAs without stem-loops
containing 3' poly(A) tails. (A) Substrates with no inverted repeat
containing no 3' homopolymer tract (IR) and a 3'
poly(A)21 [IR poly(A)+] are
transcribed in vitro (IVT) from PCR products with primer
T7IR containing a T7 promoter (T7P, hatched box) and
primers PIR and IRdT (A)21,
respectively. (B) Incubation of the respective substrates with pea
mitochondrial protein extracts for 10 and 60 min. Designation of the
lanes (10 and 60) corresponds to the length of incubation. Control
reactions are performed in the absence of protein under otherwise
identical conditions for 10 (C10) and 60 (C60)
min. The sizes of DNA marker fragments are indicated in nucleotides
(Nt).
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Since the diffuse RNAs between the substrate and this intermediate are
suggestive of an exonucleolytic digestion of the substrates, a
potential involvement of a 3'-to-5' exoribonuclease activity was
monitored with 5'- and 3'-labeled transcripts containing the inverted
repeat (Fig. 3A). While a stable product of the expected size is seen
with the 5'-labeled substrates, the 3'-labeled transcripts disappear
without formation of a detectable processing product or
intermediate (data not shown). This suggests that indeed a 3'-to-5'
exoribonuclease takes part in the 3' processing and/or degradation
event investigated here.
Detection of nonencoded nucleotides at 3' transcript termini of
steady-state RNA.
The 3' RACE analysis using an oligo(dT)-adapter
primer does indicate the presence of poly(A) sequences at the 3' ends
of mtRNAs. Several questions are, however, left unanswered in this
approach. First, the lengths of the poly(A) tails cannot be determined, and second, the majority of other nonencoded nucleotides (i.e., C, G,
or U) might remain undetected. This may be a major drawback, since, for
example, considerable uridylyltransferase activity has been detected in
plant mitochondrial protein extracts (S. Binder, unpublished results).
For an alternative approach, anchor primers were ligated directly to 3'
ends of total steady-state mtRNA from pea. The products of an RT-PCR
initiated at an oligonucleotide complementary to the anchor primer were
cloned and analyzed (Fig. 7A and
B).
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FIG. 7.
A direct anchor primer ligation-RT-PCR analysis
identifies nonencoded nucleotides at pea atp9 steady-state
transcripts. (A) Scheme of the direct anchor primer ligation-RT-PCR
approach as outlined in Materials and Methods. (B) Ethidium
bromide-stained agarose gel with DNA fragments obtained from a PCR
carried out with primers PA-10 and NSX-1. Sizes of DNA marker fragments
are given in kilobase pairs on the right. (C) Sequences of the
downstream inverted repeat of the pea atp9 3' UTR (indicated
by grey shading) obtained from a direct anchor primer ligation-RT-PCR
approach. Nonencoded nucleotides are given in lowercase letters.
Previously mapped 3' transcript termini are indicated by vertical
arrows beneath the genomic sequence (gen). The numbering of the
sequence is given with respect to the first nucleotide (+1) downstream
of the inverted repeat. (D) Number of clones containing encoded 3'
terminal nucleotides and clones with nonencoded nucleotides found at
certain positions relative to the first nucleotide downstream of the
inverted repeat (+1).
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|
From 39 clones sequenced, 13 contain 3' nonencoded nucleotides at sites
previously mapped as 3' termini (Fig. 7C and D). Adenosines were found
in 10 clones, but in addition, cytidines are detected in 5 clones and
thymidines (corresponding to uridines) are detected in 2 clones. The
cytidines are almost exclusively combined with adenosines. Sole
adenosines are found in seven clones, albeit five of these clones
contain only single nonencoded adenosines. This experiment confirms
that cytidines and, less frequently, uridines are added in vivo to the
3' ends of plant mitochondrial mRNAs. RNA fragments deriving from the
18S rRNA and the 5' UTR of the atp9 transcript are most
likely coincidentally ligated to the 3' ends of atp9 mRNA,
although identical atp9 5' UTR fragments are found in
two clones derived from independent ligation-RT-PCR approaches.
Poly(A) tracts with 10 or more adenosines stimulate RNA processing
and degradation.
The anchor primer ligation-RT-PCR analysis
detects only short nonencoded extensions up to 3 nt. Two explanations
are possible for such relatively short tracts. Either the extensions
per se are indeed only a few nucleotides long, or they are the result of the processing reaction. To test the latter assumption, substrates with no inverted repeat containing 0, 3, 10, or 21 additional adenosines were incubated with the pea mitochondrial lysate. While both
10 or 21 oligo(A) tails significantly accelerate degradation, no
difference is observed in the processing of substrates with 3 or 0 additional adenosines (Fig. 8A). An
analogous effect is seen with substrates containing inverted repeats.
An extension of 3 adenosines has no impact on processing, whereas a
processing product is rapidly formed from a precursor with 10 adenosines (Fig. 8B).
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FIG. 8.
Oligo(A) tails with 10 or more adenosines promote RNA
degradation or processing. (A) Incubation of synthetic transcripts with
no inverted repeat with either no extension (IR), a 3-nt
extension [IR(A)3], a 10-nt tract
[IR(A)10], or a 21-nt tail
[IR(A)21] are incubated with a pea
mitochondrial lysate for 10 and 60 min. Clear differences are observed
after 60 min with strong degradation-stimulating effects for the tails
with 10 and 21 adenosines. In comparison, no significant differences in
the decay are observed in reactions with substrates without extensions
or with three additional terminal adenosines. Nt, nucleotides. (B)
Substrates containing the pea atp9 inverted repeat with 3 [IR+poly(A)3] or 10 [IR+poly(A)10] adenosines attached 2 nt
downstream of the second stem were incubated with a pea mitochondrial
lysate. The product generated from the latter substrate where
sequences downstream of the stem-loops have been removed clearly
indicates a processing-promoting effect of the 10-adenosine extension.
In comparison, only a minor shortening of the substrate with three
terminal adenosines is observed after 10 and 60 min (lanes 10 and 60).
No degradation or processing is observed after incubation of the
substrates for 10 and 60 min in the absence of protein (lanes
C10 and C60). Nt, nucleotides.
|
|
These results and the fairly fragment in vitro processing products
containing one or more residual nonencoded adenosines (Fig. 4C to F)
strongly suggest that the short extensions detected in vivo are the
product of RNA processing and/or degradation.
| |
DISCUSSION |
3' nonencoded nucleotides in plant mitochondrial transcripts.
Two independent approaches were used to identify nonencoded nucleotides
at the 3' ends of plant mitochondrial transcripts. While the 3' RACE
analysis initiated with an oligo(dT)-adapter primer indirectly shows
the presence of nonencoded adenosines at the 3' transcript termini, the
direct anchor primer ligation-RT-PCR approach provides straightforward
evidence for the existence of such nonencoded 3' extensions without any
inherent experimental bias for certain nucleotides.
The 3' RACE analysis predominantly detects poly(A) tracts within the 3'
part of the second stem or immediately downstream thereof. Since no
adenosines are encoded in these regions downstream of both pea
atp9 and Oenothera atp1 genes, all these clones
should derive from annealing of the oligo(dT)-adapter primer at
nonencoded, posttranscriptionally added adenosines (Fig. 1 and 2). Only
the 3' ends observed in pea atp9 clones no. 7 and j27 are
located in regions which would allow an annealing of the oligo(dT)
stretch to encoded sequences (Fig. 1). Besides the adenosines expected from the use of an oligo(dT)-adapter primer, cytidines, thymidines (corresponding to uridines in the RNA), and guanosines are also found
in the 3' RACE products of pea atp9 and Oenothera
atp1 mRNAs. While the location of the guanosine within the 17-mer
adenosine (corresponding to thymidines) stretch in the adapter primer
rather suggests an artifact, several cytidines and a single thymidine are either found directly at or near the 3'-most nucleotides. The
direct anchor primer ligation-RT-PCR approach confirms the presence of
cytidines and uridines in more than half of the clones with nonencoded
nucleotides. Interestingly, no guanosine is found in the clones
obtained in this analysis. The detection of other RNA fragments at the
3' ends of atp9 mRNAs is due to the high content of usually
18S rRNA fragments in mtRNA preparations. Such fragments are also often
observed in chimeric clones of mitochondrial cDNA libraries
(11). The validity of the method is indirectly supported
by the analogous investigation of the in vitro processing products
(Fig. 4B), where in 64 clones no nucleotides were detected that could
be derived from artifacts generated in the ligation or amplification reactions.
The real in vivo length of the nonencoded extensions remains unclear. A
diagnostic 3' RACE analysis initiated by an oligo(dT)-adapter primer
with 17 thymidines on an RNA with a 24-mer adenosine poly(A) tail
results in clones containing between 15 and 24 adenosines, corroborating the length variation occurring under such experimental conditions (data not shown). Thus, such a 3' RACE analysis does not
allow any conclusion on the a priori lengths of the poly(A) tracts. In
the alternative approach, the number of nonencoded nucleotides found is
rather low. The majority of these clones contain a single nonencoded
nucleotide, and the maximum of three posttranscriptionally added
nucleotides is found in only three clones. No longer poly(A) tails are
observed in this approach, suggesting a very low frequency of such
longer extensions.
The in vitro assays of substrates with poly(A) tracts of different
sizes indicate that tails with 10 nucleotides already promote a similar
acceleration of degradation, as do longer poly(A) tails (Fig. 8A). In
contrast, short tails with only three adenosines have no influence on
transcript stability, suggesting that the termini seen in the direct
anchor primer ligation-RT-PCR analysis derive from relatively stable
end products rather than from substrates promoting and initiating
degradation. This assumption is substantiated by the detection of one
or more residual nonencoded adenosines at the processing products
generated from polyadenylated substrates.
The observation that mitochondria can discriminate between transcripts
with homopolymer tracts of different sizes and specifically degrade
those with 10 or more nucleotides supports the functional and
biological significance of these nonencoded nucleotides.
Function of polyadenylation in plant mitochondria.
Recent
reports of polyadenylation of plant mitochondrial transcripts suggested
that the presence of 3' poly(A) tails accelerates the degradation of
mRNAs (10, 19). Our results obtained for transcripts
without a stem-loop structure are consistent with these results. A
significant acceleration of RNA decay is caused by the presence of
poly(A) tails in these transcripts. Surprisingly, an even stronger
destabilizing effect is observed with poly(G)21 tails,
which contradicts previous reports on chloroplasts and cannot be
rationally explained at present (7, 8; data not shown). No
effects of poly(G) stretches were detected in transcripts of nuclear
reporter genes in plants, indicating that indeed the effects of poly(G)
stretches might differ for different compartments of the plant cell
(13).
In plant mitochondria we furthermore observe a differentiated response
to polyadenylation of mRNAs with double stem-loop structures. With
these substrates a significant acceleration of 3' end processing is
observed, while total degradation is only marginally increased (Fig.
3). In this reaction RNA moieties downstream of the stem-loop are
rapidly removed, but the progress of degradation is stopped or stalled
at the stem-loop structure (Fig. 4). The stabilizing effect of these
structures then seems to be stronger than the stimulation of mRNA decay
by polyadenylation. The identification of poly(A) addition sites within
the stem-loop indicates that these are polyadenylated again and
suggests repeated cycles of polyadenylation and removal of
poly(A) tails together with several adjacent nucleotides. This may be
an effective mechanism for eventually overcoming the stem-loop
structure and initiating the total degradation of the RNA. The life
span of such a transcript is thus balanced between the
degradation-promoting polyadenylation and the stabilizing effect of the
stem-loop. In plant mitochondria the former effect seems to be minor in
comparison to that in bacteria and chloroplasts, where poly(A) tails
have a much stronger destabilizing effect on stem-loop-containing
transcripts (3, 17, 18).
How are the 3' nonencoded nucleotides added to mRNAs?
The
presence of nonencoded nucleotides at the 3' ends of mRNAs raises the
question of how these nucleotides are added. In other compartments of
plant cells and in other organisms, poly(A) tails are generally
synthesized by poly(A) polymerase, which has so far not been reported
in plant mitochondria. It has recently been shown that this protein
from Escherichia coli incorporates all 4 nt into the 3'
extensions, at least in vitro, so one can speculate that an analogous
enzyme activity may add the nonencoded nucleotides to mRNA 3' ends in
plant mitochondria (28).
The presence of a significant number of cytidines among the nonencoded
nucleotides also raises the possibility that a tRNA terminal
nucleotidyltransferase is involved in the addition of the nonencoded
nucleotides. This theory is strengthened by the observation that the
cytidines are almost exclusively combined with adenosines and that
complete CCA additions were identified in two clones (Fig. 1 and 7).
This enzyme activity has been detected in plant mitochondrial extracts
from potato and wheat and should now be tested for the potential to add
short or even longer oligo(A) tracts to mRNA substrates (14,
20).
This work was supported by grant Bi 590/3-3 from the Deutsche
Forschungsgemeinschaft and a fellowship from the Studienstiftung des
Deutschen Volkes to J.K.
We thank Axel Brennicke for fruitful discussions and his constructive
comments on the manuscript.
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Abstract
Introduction
