Identification and Structural Characterization of Nucleus-encoded Transfer RNAs Imported into Wheat Mitochondria*

Kathleen E. GloverDagger, David F. Spencer, and Michael W. Gray§

From the Department of Biochemistry and Molecular Biology, Dalhousie University, Halifax, Nova Scotia B3H 4H7, Canada

Received for publication, August 23, 2000, and in revised form, October 4, 2000



    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Despite its large size (200-2400 kilobase pairs), the mitochondrial genome of angiosperms does not encode the minimal set of tRNAs required to support mitochondrial protein synthesis. Here we report the identification of cytosolic-like tRNAs in wheat mitochondria using a method involving quantitative hybridization to distinguish among three tRNA classes: (i) those encoded by mitochondrial DNA (mtDNA) and localized in mitochondria, (ii) those encoded by nuclear DNA and located in the cytosol, and (iii) those encoded by nuclear DNA and found in both the cytosol and mitochondria. The latter class comprises tRNA species that are considered to be imported into mitochondria to compensate for the deficiency of mtDNA-encoded tRNAs. In a comprehensive survey of the wheat mitochondrial tRNA population, we identified 14 such imported tRNAs, the structural characterization of which is presented here. These imported tRNAs complement 16 mtDNA-encoded tRNAs, for a total of at least 30 distinct tRNA species in wheat mitochondria. Considering differences in the set of mtDNA-encoded and imported tRNAs in the mitochondria of various land plants, the import system must be able to adapt relatively rapidly over evolutionary time with regard to the particular cytosolic-like tRNAs that are brought into mitochondria.



    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In flowering plants (angiosperms), all of the codons of the canonical genetic code are represented in the protein genes encoded by mtDNA,1 yet the mitochondrial genome appears to specify fewer than the 23-24 or 33 tRNAs minimally required to read these codons by either expanded or standard wobble base pairing, respectively. This observation, coupled with the identification of cytosolic-like tRNAs in mitochondrial RNA preparations of bean (1), wheat (2), and potato (3), suggests that tRNAs must be imported into angiosperm mitochondria (4-6), as they are into the mitochondria of many unicellular eukaryotes (7). A requirement for mitochondrial tRNA import in plants is rather surprising in view of the large size of the angiosperm mitochondrial genome (200-2400 kilobase pairs), which in principle could easily accommodate a full set of tRNA genes, as do the much more compact mtDNAs of most animals and fungi (8).

Depending on their genome of origin, plant mitochondrial tRNAs (mt-tRNAs) can be divided into three groups (see Refs. 2 and 4-6): (i) native mt-tRNAs, encoded by plant mtDNA and presumed to originate from the eubacteria-like endosymbiont that was the evolutionary source of the mitochondrion and its genome; (ii) chloroplast-like tRNAs, also encoded by plant mtDNA but originating from promiscuous chloroplast DNA sequences that in the course of evolution have been transferred to and are now an integral part of the mitochondrial genome; and (iii) imported tRNAs, encoded by nDNA and localized in mitochondria as well as the cytosol. Given that tRNAs encoded by a particular genome within a plant cell may function in more than one subcellular compartment, complete characterization of a plant tRNA requires not only determination of its anticodon sequence and aminoacylation specificity, but also its intracellular localization and that of the gene encoding it. Although the set of mtDNA-encoded tRNAs or their genes has been examined in a variety of angiosperms (3, 9, 10), only in potato (a dicotyledonous plant) has the mt-tRNA population been extensively characterized (3). In that plant, 31 mt-tRNAs were found, including 20 encoded by mtDNA (15 native and 5 chloroplast-like) and 11 specified by nDNA.

The research reported here aimed to identify and comprehensively characterize nDNA-encoded tRNAs that are imported into wheat mitochondria from the cytosol. The possibility of mitochondrial tRNA import emerged when studies to catalog wheat mtDNA-encoded tRNA genes revealed only 16 genes specific for 13 amino acids (2). Although we considered that some mtDNA-encoded tRNA genes might have escaped detection in this survey, it seemed unlikely that all of the remaining ~17 tRNA genes required by standard wobble rules could have been missed. The apparently limited number of wheat mtDNA-encoded tRNAs prompted a preliminary investigation of the wheat mitochondrial tRNA population, which identified three cytosolic-like tRNA species (2); however, the latter study did not address the issue of possible cytosolic tRNA contamination of the wheat mitochondrial tRNA preparation. In the present investigation, we systematically examined the question of preparative contamination and established criteria and procedures for the identification of tRNAs that are genuinely imported into wheat mitochondria.


    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Isolation of Mitochondria-- The procedures of Spencer et al. (11) were used for preparation of viable wheat embryos (from pedigree seed of Triticum aestivum var. Katepwa; Alberta Wheat Pool, Calgary, Alberta, Canada), germination of embryos and isolation of mitochondria.

Isolation of Mitochondrial and Nuclear DNA-- Wheat mtDNA was prepared from DNase-treated, sucrose gradient-purified mitochondria (11) by sequential sarkosyl lysis, incubation of the lysate with Pronase, and recovery of DNA by centrifugation in CsCl-ethidium bromide gradients (11, 12). Wheat nDNA was isolated in a similar fashion from a crude nuclear fraction that was further purified in a discontinuous sucrose gradient (11), except that nuclei were extracted with a phenol/cresol mixture rather than being treated with Pronase.

Isolation of RNA Fractions-- Mitochondrial RNA (from purified mitochondria) and cytosolic RNA (from a post-mitochondrial supernatant) were prepared as described previously (11). For isolation of total cellular RNA, germinating embryos were ground in a mortar with equal volumes of 0.05 M Tris-HCl, 0.02 M Na-EDTA (pH 8.0) and phenol/cresol mix. The homogenate was centrifuged at 18,000 × g for 20 min, an equal volume of phenol/cresol solution was added to the supernatant, and the mixture was shaken for 10 min at 4 °C and then centrifuged at 18,000 × g for 10 min. After addition of NaCl to 0.5 M to the aqueous phase, RNA was purified by repeated phenol extraction and ethanol precipitation.

Fractionation of Wheat Mitochondrial tRNAs by Polyacrylamide Gel Electrophoresis-- To obtain a sufficient quantity of individual tRNAs for subsequent analysis, a two-dimensional gel electrophoresis procedure (13) was adapted. Gel solutions and electrophoretic conditions were as described (3), except that gels were 0.75 mm thick and stacking gels were employed. Approximately 125 µg of 1 M NaCl-soluble wheat mitochondrial RNA (11) was electrophoresed in the first dimension. The tRNAs were located by ultraviolet shadowing, and a gel slice containing them was excised for electrophoresis in the second dimension. The separated tRNAs were visualized by ethidium bromide staining and recovered from individual spots by elution (14) in the presence of 10 µg of linear polyacrylamide carrier (15). Isolated tRNAs were 3'-end-labeled using 5'-[32P]pCp and RNA ligase (16) and electrophoresed in a 6% polyacrylamide, M urea gel (33 × 40 × 0.04 cm) at 1600 V for 3 h. Following autoradiography, the resolved tRNA species were recovered by elution (14).

Sequence Analysis-- Sequences and labeling of tRNA-specific oligonucleotides used as primers for reverse transcriptase (RT) sequencing (17) are described below. Reaction products from 1-2 µl of chemical (16) or RT (avian myeloblastosis virus) sequencing reactions (heated at 80 °C for 5 min) were electrophoresed in a 10% polyacrylamide gel containing 7 M urea, 40% (v/v) formamide, and 1× TBE (90 mM Tris-HCl, 90 mM boric acid, 2 mM EDTA (pH 8.0)) at 65 W (3000-3500 V; 50 °C) until a xylene cyanol marker reached 17 cm (~2 h). Gels were pre-run for 1 h at 2000 V.

Thin-layer Chromatography-- Thin-layer chromatography was employed to determine the anticodon sequence of a wheat mt-tRNAArg. The tRNA was partially hydrolyzed in alkali, and the resulting 5'-OH-terminated fragments were 5'-end-labeled, separated by gel electrophoresis, and individually recovered, as described (14). The isolated fragments were completely digested to nucleoside 5'-monophosphates (pN) with nuclease P1 (18), and the resulting 32P-labeled, 5'-terminal nucleotide of each eluted fragment was identified by co-chromatography with markers in two solvent systems (14).

End Labeling of tRNA-specific Oligonucleotides-- Oligodeoxyribonucleotides (Regional DNA Synthesis Laboratory, University of Calgary, Calgary, Alberta, Canada; see Table I) were labeled using polynucleotide kinase and [alpha -32P]ATP under standard conditions (17), except that spermidine was used at a final concentration of 1 mM.

Slot Blot Hybridization and Analysis-- Slot blots contained mitochondrial, cytosolic and total cellular RNA samples. In some cases, RNA that had been treated with DNase I served as a control.

To prepare the samples, 12 µg of RNA were dissolved in 50 µl of TE and added to 250 µl of 20× SSC (1× SSC = 0.15 M NaCl, 0.015 M sodium citrate), 100 µl of 37% (v/v) formaldehyde and 100 µl of H2O. The RNA-containing solution was heated at 65 °C for 15 min, immediately cooled on ice, then serially diluted seven times with an equal volume of 10× SSC, to generate 1:2- to 1:128-fold dilutions. RNA samples (6-0.047 µg) were applied to a Biotrans nylon membrane (ICN Biomedicals) using a Bio-Dot SF blotting apparatus (Bio-Rad) according to the supplier's instructions, with 10× SSC as wash solution. Blots were baked for 2 h at 80 °C, then rinsed in 2× SSC. Prehybridization, hybridization using 0.1 µg of oligonucleotide probe (5'-end-labeled as described above), and washing of blots were conducted as described (20). Hybridizations were performed for ~16 h at 5-7 °C lower than the calculated dissociation temperature (Td) of the oligonucleotide probe (20). Blots were exposed to Kodak X-Omat K x-ray film without intensifying screens, the resulting autoradiographs were digitized, the intensity of each band was determined using the NIH Image Analysis program, and linear regression coefficients were calculated using MacCurveFit.

Polymerase Chain Reaction (PCR) Amplification and Cloning of Wheat Nuclear tRNA Genes-- PCR amplification experiments employed oligonucleotides (generally 20-mers) designed to target the 5'- and 3'-terminal regions of the desired tRNA gene, using sequence information obtained by chemical and RT sequencing of the corresponding tRNA. Nucleus-encoded tRNA sequences (DNA and RNA) of other plants (21) assisted in primer construction.

Purified nDNA (11) was used either directly or after extensive shearing by two passes at 20,000 p.s.i. through a French pressure cell. The sheared DNA (mean size about 400 base pairs) produced few, if any, artifactual bands and so was the preferred template. Amplification was in a Perkin Elmer GeneAmp PCR System 2400 using Vent(exo-) DNA polymerase (New England Biolabs) with 500 ng of nDNA. An optimized regime employed 40 cycles and included a 30-s annealing at 55 °C and a 30-s extension at 72 °C, with the ramp-up from annealing to extension slowed to 50% of maximum. PCR was also attempted with 5% (v/v) dimethyl sulfoxide or 1.3 M betaine in the reaction mix; however, neither reagent supported the amplification of tRNA sequences that were not also recovered using the standard protocol.

For cloning, blunt-ended PCR products were ligated into pT7 Blue® (Novagen) and transformed into DH5alpha cells that had been prepared by the protocol of Inoue et al. (22). Sequence was determined using the fmol Cycle Sequencing® kit (Promega) with 5'-32P-labeled vector-based primers.


    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The term "mitochondrial tRNA" (mt-tRNA) is used here to refer generally to tRNA species present in the isolated mitochondrial tRNA population, whether these species are encoded by the mitochondrial genome (mtDNA-encoded mt-tRNA) or nuclear genome (nDNA-encoded mt-tRNA). The term "cytosolic tRNA" (cy-tRNA) is reserved for nDNA-encoded tRNAs that are normally localized to and function in the cytosol. The term "imported tRNA" is applied to those nDNA-encoded tRNAs that are selectively accumulated in mitochondria, presumably for use in mitochondrial protein synthesis.

Preliminary Experiments-- When radioactively end-labeled wheat mt-tRNAs were incubated with mtDNA or nDNA, only a fraction of the total mt-tRNA population hybridized to mtDNA. After two-dimensional polyacrylamide gel electrophoresis, the latter tRNAs generated a distinctly different pattern than those hybridizing to nDNA (23). Among the latter group were three cytosolic-like tRNAs (Gly (CCC); Leu (CAA); Val (GAC); anticodon sequences in parentheses) previously identified in the wheat mt-tRNA population (2). Total cy-tRNA had a more complex gel electrophoretic profile than the mt-tRNA fraction hybridizing to nDNA, and it contained unique species (23). This makes it unlikely that cy-tRNA contamination of the mt-tRNA fraction is of such magnitude and extent that those mt-tRNAs that hybridize to nDNA represent contaminating cy-tRNAs, rather than bona fide imported tRNAs. Nevertheless, this approach cannot unequivocally distinguish imported nDNA-encoded tRNAs from nDNA-encoded cy-tRNA contaminants of the mitochondrial preparation.

To assess the level of cy-tRNA co-isolating with wheat mitochondrial RNA, a wheat cytosolic RNA preparation was incubated with [alpha -32P]ATP and tRNA nucleotidyltransferase (2), and the resulting labeled RNA was added to homogenizing medium containing germinating wheat embryos. Embryos were processed according to the standard protocol for isolation of mitochondria and mitochondrial RNA (11) and radioactivity in various preparative fractions was assessed by liquid scintillation counting. From measurements of RNA recovered from subcellular fractions together with calculated specific activities, we estimated that co-isolating cy-tRNA could comprise as much as 20-25% of the total mt-tRNA prepared by our standard protocol (23).

To determine whether the cy-tRNA associated with the mitochondrial fraction in this way represents a specific subset of the cy-tRNA population or is a representative sampling, mitochondrial RNA containing radiolabeled cy-tRNA was subjected to polyacrylamide gel electrophoresis. No differences in the electrophoretic banding or intensity patterns of the radiolabeled cy-tRNA associated with the mitochondrial fraction could be discerned in comparison to those of similarly labeled cy-tRNA fractions (23).

Micrococcal nuclease treatment of isolated mitochondria has been used in other studies to reduce contamination of mitochondrial RNA preparations by cytosolic tRNA (24, 25). To assess the effectiveness of this treatment, we carried out a quantitative investigation (23), which showed that such treatment reduced the amount of radiolabeled cy-tRNA co-isolating with mitochondrial RNA by at least 50% compared with untreated mitochondria. However, as in other published work, the yield of mitochondrial RNA was also substantially reduced. This meant that, on average, micrococcal nuclease treatment lowered residual contamination by approximately 35%, not 50%.

To ascertain whether the cy-tRNA remaining after micrococcal nuclease treatment was a specific subset of the cy-tRNA population, the mitochondrial RNA was electrophoresed in a 4 M urea, 10% polyacrylamide gel. Although the signal was faint, no selection was evident (23).

Determination of the Subcellular Location of Wheat tRNAs-- Because micrococcal nuclease treatment of wheat mitochondria was not effective in reducing the amount of added cy-tRNA that co-isolated with mt-tRNA to what we would consider a negligible level (<5% of total mt-tRNA), we therefore developed an alternative approach for distinguishing bona fide, imported tRNAs from ones nonspecifically associated with mitochondria, possibly as a result of preparative contamination by cy-tRNAs. Slot blots containing mitochondrial RNA and cytosolic RNA were hybridized with oligonucleotides (Table I) specific for mtDNA-encoded tRNAUGGPro (26), the cytosolic-like tRNAGCCGly (27) previously identified in wheat mitochondrial RNA (2), and nDNA-encoded cy-tRNAGAAPhe (28). The latter tRNA is not required in wheat mitochondria (i.e. is functionally redundant) because the mtDNA encodes a tRNAGAAPhe (2).


                              
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Table I
Sequences of tRNA-specific oligonucleotides used for slot blot hybridization analyses

As expected, distinctly different hybridization patterns were obtained in these experiments (Fig. 1). With the tRNAUGGPro oligonucleotide, there was a strong signal with mitochondrial RNA and a much weaker signal with cytosolic RNA. The reverse was seen with the tRNAGAAPhe oligonucleotide: a strong signal with cytosolic RNA and a much weaker signal with mitochondrial RNA. With tRNAGCCGly (a nDNA-encoded tRNA previously considered to be imported into wheat mitochondria (Ref. 2)), the corresponding oligonucleotide hybridized equally well with mitochondrial and cytosolic RNA.



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Fig. 1.   Slot blot analyses of three wheat tRNA-specific oligonucleotide probes hybridized to wheat mitochondrial RNA and cytosolic RNA. Autoradiographs show the hybridization of 5'-32P-labeled oligonucleotides specific for mtDNA-encoded mt-tRNAUGGPro (A), cy-tRNAGGAPhe (B), and nDNA-encoded mt-tRNAGCCGly (C), to wheat mitochondrial RNA (M), wheat cytosolic RNA (C), total cellular RNA that had been treated with DNase I (T1), and cytosolic RNA that had been treated with DNase I (C1). RNA samples were serially diluted 2-fold to produce amounts ranging from 6 µg to 0.047 µg and applied to wells of the slot blot apparatus as described under "Experimental Procedures."

To quantify the relative intensities of the hybridization signals, autoradiographs were digitized and the relationship between the strength of each signal and RNA concentration was determined in the linear region of the plot. The slopes of the lines (regression coefficients) obtained following hybridization of an oligonucleotide to mitochondrial RNA and cytosolic RNA were then compared, providing an estimate of the relative intensities of the two signals (Table II).


                              
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Table II
Linear regression coefficients calculated from slot blot hybridization analyses of wheat mt-tRNAs using tRNA-specific oligonucleotide probes
Slot blots containing mitochondrial (mt) RNA and cytosolic (cy) RNA were prepared as described in Experimental Procedures. Sequences of the oligonucleotide probes are presented in Table I.

The ratios (mitochondrial RNA/cytosolic RNA) of the regression coefficients (RRC) for tRNAGAAPhe and another cy-tRNA, tRNAGUCAsp (also not required by the mitochondria because wheat mtDNA encodes a tRNAAsp (Refs. 26 and 29)), were only 0.24 and 0.31, respectively, compared with an RRC of 8.3 for tRNAUGGPro. As expected, the RRC for tRNAGCCGly was different than in the case of the other two classes of tRNA, being close to 1 (1.35). This method provides a relative measure of the concentration of each tRNA in the cytosolic and mitochondrial fractions and offers a way to distinguish nDNA-encoded tRNAs that specifically accumulate in mitochondria (i.e. imported tRNAs, by our definition) from those cy-tRNAs that may be present solely as a result of contamination.

This slot blot procedure was used to assess the import status of 16 cytosolic-like wheat mt-tRNAs isolated by two-dimensional gel electrophoresis, as described in the next section. Sequence analysis of individual tRNAs provided information for synthesis of tRNA-specific oligonucleotide probes (Table I). Discussion of the import status of these tRNA species follows below, after presentation of data relating to their structural characterization.

Isolation and Sequencing of Wheat Mitochondrial tRNAs-- To isolate individual tRNAs, we adopted a procedure involving two-dimensional polyacrylamide gel electrophoresis of a relatively large quantity (125 µg) of a 1 M NaCl-soluble fraction of wheat mitochondrial RNA (~85% tRNA). Fig. 2 shows the resulting ethidium bromide-stained RNA profile. Heterogeneity at the metabolically labile 3'-CCAOH terminus (all or a portion of which may be lacking in an individual tRNA) was anticipated (30) and, as confirmed by sequence analysis, is particularly evident at the periphery of the RNA profile. In general, a single isoaccepting tRNA was resolved into three species by this procedure.



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Fig. 2.   Fractionation of wheat mt-tRNAs by two-dimensional polyacrylamide gel electrophoresis. Arrows indicate direction of migration in the first (1st) and second (2nd) dimensions. Conditions of electrophoresis are specified under "Experimental Procedures." A, photograph of ethidium bromide-stained gel taken under ultraviolet light, showing the tRNA fractionation pattern. B, schematic representation of pattern shown in A. Spots have been numbered 1-51 and 70-79 as explained in the text. Lowercase letters denote potential resolution of a single tRNA into separate species differing in the extent of completion of the 3'-terminal -CCAOH sequence.

Spots numbered 1-50 in Fig. 2 correspond to tRNAs in the two-dimensional gel electrophoretic pattern previously reported in Ref. 2. Prior to electrophoresis in that study, wheat mt-tRNAs were 3'-end-labeled using wheat tRNA nucleotidyltransferase, thereby eliminating the 3'-end heterogeneity observed here. Lowercase letters in Fig. 2 denote putative single tRNA species with varying degrees of completion of the 3'-terminal -CCAOH. Bands numbered 70-79 do not appear to match any of those reported in Ref. 2.

Following the initial two-dimensional polyacrylamide gel fractionation, recovered tRNAs were radiolabeled and electrophoresed in a denaturing polyacrylamide gel ("third dimension") (Fig. 3). Many of the tRNAs isolated from the initial two-dimensional gel were homogeneous at this stage, whereas others separated into two, three, and occasionally four bands. This result is primarily a consequence of overlap of species in the two-dimensional gel because of 3'-end heterogeneity, although it is known that individual tRNAs can exist in distinct, separable forms due to variation in post-transcriptional modifications (31). Species resolved in the third dimension are identified by a suffix (1-4; see Table III), in order of increasing mobility.



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Fig. 3.   Autoradiograph showing resolution of isolated tRNAs in the third electrophoretic separation. Transfer RNAs recovered from a two-dimensional electrophoretic separation (see Fig. 2) were 3'-end-labeled with [5'-32P]pCp and electrophoresed in a fully denaturing polyacrylamide gel ("third dimension"; see "Experimental Procedures"). Separated components are designated by a number (1-4), in order of increasing mobility.


                              
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Table III
Identity of wheat nDNA-encoded mitochondrial tRNAs resolved by polyacrylamide gel electrophoresis

Sequence Analysis-- To avoid sequencing previously identified mtDNA-encoded tRNAs (2), species obviously coincident in migration position with these tRNAs were not analyzed. These species primarily included tRNAs on the periphery of the two-dimensional gel pattern, which in the previous analysis (2) proved to be homogeneous. Altogether, material was recovered from 44 spots in the two-dimensional gel and electrophoresed in the third dimension, generating 78 species in total, all of which were subjected to chemical sequence analysis. Table III lists the wheat mt-tRNAs identified here as nDNA-encoded; previously identified mtDNA-encoded tRNAs are not included.

A limitation of the direct chemical sequencing procedure was the appearance of a truncated C ladder in certain cases, which we attribute to the presence in the variable loop of an unidentified modified nucleoside with greatly enhanced reactivity in the C reaction. Virtually complete scission of the polynucleotide chain occurred at the residue in question, with the result that very faint or no bands appeared in the C track of sequencing films beyond (5' of) this position.

Except for tRNAGCCGly, all of the tRNAs listed in Table III were also sequenced using RT. In addition to confirming chemical sequence data, RT analysis was particularly useful in establishing sequence in the variable loop (a region often containing a number of unassigned nucleosides in the chemical sequence analysis) and in allowing identification of C residues unable to be assigned on the basis of the chemical sequence analysis because of the anomalous C-specific cleavage noted above. As well, RT sequencing confirmed or expanded anticodon sequence information for six of the tRNAs (Table III).

Thin-layer Chromatography-- In chemical sequencing reactions the modified nucleoside inosine (I) is cleaved in the G-specific reaction, generating a band in the G lane. Inosine is present in the first position of the anticodon (position 34, the only site at which this modification occurs in tRNA; Ref. 21) in several plant tRNAs, including wheat germ tRNAIAUIle (32) and tRNAICGArg (33), potato mt-tRNAIGCAla (a nDNA-encoded species; Ref. 3), and lupin cy-tRNAIACVal (34). In the present study, the sequence of the anticodon loop region of the Arg2 tRNA (anticodon "G"CG; Table III) was directly determined (see "Experimental Procedures"), showing that inosine occupies the first (wobble) position of the anticodon of this tRNA (23), as documented independently elsewhere (33).

PCR Amplification of Nuclear tRNA Genes-- PCR was used in an attempt to amplify nuclear gene sequences corresponding to all of the 16 cytosolic-like mt-tRNA species characterized here by RNA sequencing. This approach was successful in 11 cases (Table III), with sequence data from cloned PCR products either confirming the anticodon sequence or clarifying ones remaining ambiguous after RNA sequencing. Although an exhaustive attempt was made to recover the remaining five nuclear tRNA genes using a variety of amplification conditions and primer combinations, PCR products were not obtained in these cases.

Nucleotide Sequence Comparisons-- The wheat mt-tRNAs described in this report were identified as cytosolic-like by comparison (35) with homologous mt- and cy-tRNA sequences from various organisms (23). In general, each wheat mt-tRNA identified here proved to be substantially more similar to a corresponding plant cy-tRNA or nuclear tRNA gene sequence (>80% identity) than to a plant mtDNA-encoded one (<60%), in cases where such mtDNA-encoded counterparts are available for comparison (23).

Primary and Secondary Structures of Sequenced tRNAs-- The 16 wheat tRNA sequences determined here (Table III) can be folded into the standard cloverleaf secondary structure (Fig. 4). With few exceptions (23), these structures contain the expected invariant and semi-invariant nucleosides characteristic of a conventional tRNA.



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Fig. 4.   Primary sequences and potential secondary structures of wheat nDNA-encoded mt-tRNAs (see Table III), derived from chemical and reverse transcriptase sequencing data. Positions that could not be identified by direct or RT sequencing or by PCR amplification are indicated by the letter N; those tentatively identified are denoted by lowercase letters, with probable or possible dihydrouridine residues indicated by d. The filled square denotes absence of a nucleotide at that position. The sequence of the 5'-terminal region of tRNAIACVal was not determined. A small lowercase letter within the latter structure and beside the other structures is the corresponding nucleotide at that position in the reference DNA sequence listed in Table III. An uppercase letter beside a structure indicates that the reference sequence is RNA rather than DNA, with asterisks (*) denoting positions of post-transcriptional modification. Positions of apparent disagreement between direct sequencing and PCR analysis or positions of heterogeneity in individual PCR clones are denoted by a slash (e.g. G/A). I, inosine.

For each wheat mt-tRNA sequence reported here, BLASTN searches (35) identified a number of highly similar plant homologs that allowed assignment of most of the remaining undetermined positions in the wheat sequences, and which provided sufficient additional information to permit inference of the anticodon sequence in all cases.

Alanine-- Species Ala1 and Ala3 differ slightly in nucleotide sequence, but we conclude that they have the same anticodon, IGC. PCR amplification provided evidence of heterogeneity (C/T) at one position in the variable loop, and homologous Arabidopsis sequences with the corresponding heterogeneity were identified in BLAST searches (Table III and Fig. 4). PCR amplification also demonstrated that anticodon loop positions 34 and 37 are both A in the gene sequence, as they are in the corresponding Arabidopsis and other plant tRNAAla sequences. Positions 34 and 37 are inosine and 1-methylinosine (m1I) in sequenced cytoplasmic tRNAAla species, which would account for the fact that these residues registered as G during sequencing of wheat Ala1. Like their Arabidopsis counterparts, the wheat Ala1 and Ala3 sequences have A at position 54, rather than the almost universally conserved 5-methyluridine (m5U).

We infer that species Ala2 (ugN) has the anticodon sequence UGC, based on comparison with an Arabidopsis tRNAUGCAla sequence that differs by one compensated base pair in the T stem (Table III and Fig. 4). Because position 37 is A rather than G in the Arabidopsis gene sequence, it is likely that this position is occupied by m1I in the wheat Ala2 tRNA, as we suggest above for the Ala1 and Ala3 tRNAs.

Arginine-- The Arg1 and Arg2 tRNA species are essentially identical to previously sequenced wheat tRNAArg species with anticodons CCU (36) and ICG (33), respectively. PCR amplification of the wheat Arg2 sequence revealed the presence of wobble position A; as noted above, direct analysis identified this residue as inosine, as in the published sequence (33).

Aspartate-- This sequence is identical to an Arabidopsis tRNAAsp sequence also having the anticodon GUC (Table III).

Glycine-- The sequences of Gly1 and Gly2 are identical, respectively, to those of a previously published wheat tRNAGCCGly (27) and an Arabidopsis homolog with anticodon UCC (Table III). Both Gly1 and Gly2 appear to have unmodified U rather than the usual m5U at position 54, as noted previously for wheat tRNAGCCGly (37).

Histidine-- The wheat sequence differs at six positions from a sequenced lupin tRNAHis (38) but at only two positions from several Arabidopsis tRNAHis homologs (Table III and Fig. 4). Curiously, all of the Arabidopsis tRNAHis sequences currently in the data base (representing genes on several different chromosomes) have C rather than T at position 54, which is normally m5U in the mature tRNA. Both the wheat and lupin tRNAsHis evidently contain unmodified U at this position.

Isoleucine-- This tRNA sequence differs at several positions from a published wheat tRNAIle sequence (32). Within the D loop, the stretch AGUGG in our sequence is AGDDGG in the published wheat germ sequence and AG(C/T)TGG in homologous Marchantia and Arabidopsis sequences. At several other positions (A49:U65, G59, A60, G70), our sequence matches the homologous Marchantia sequence rather than the published wheat germ sequence. Position 34 is A in the Marchantia and Arabidopsis sequences and inosine in the published wheat sequence; therefore, the anticodon tentatively identified here as "G"AU by direct sequencing is very likely IAU.

Leucine-- The wheat Leu1 (anticodon UAG) is virtually identical to an Arabidopsis tRNAUAGLeu sequence (Table III and Fig. 4). The Leu2 (anticodon "G"AG) is most similar to a rice tRNALeu species with anticodon IAG. Although no PCR data were obtained for wheat Leu2, other homologous plant tRNA gene sequences have only A at position 34, with the homologous lupin tRNALeu (39) also having an IAG anticodon.

Wheat Leu3 (anticodon confirmed as CAA by PCR; Table III) is virtually identical to an Arabidopsis tRNACAALeu gene sequence, the pair differing by only two substitutions in the variable loop. Wheat Leu4 (anticodon UAA by PCR) is likewise highly similar to the gene sequence for an Arabidopsis tRNAUAALeu. In yeast, two different tRNANAALeu species have either a modified U (40) or a modified C (41) in the wobble position, restricting base pairing to either UUA or UUG codons, respectively. The same situation probably also exists in mammals (42) and plants (1, 25). Judging by the results of direct sequencing of the wheat Leu3 and Leu4 tRNAs, the wobble nucleoside in both species also appears to be modified.

Valine-- The wheat Val1 sequence appeared to have a UAC anticodon on the basis of direct sequence analysis but CAC (in two independently isolated clones) by PCR amplification. With a wheat mitochondrial tRNA preparation, sequencing of an RT product provided evidence only of the CAC anticodon, which we therefore assign to wheat Val1. Homologous Arabidopsis sequences all have C at the wobble position. Wheat Val2 is virtually identical over the sequenced region to a number of Arabidopsis tRNAAACVal sequences from different chromosomes. Although direct sequencing suggested a "G"AC anticodon, PCR analysis gave AAC. The corresponding lupin tRNAVal sequence has an IAC anticodon (34), which wheat Val2 most likely has, as well.

Determination of Import Status of Cytosolic-like Mitochondrial tRNAs-- Most of the 16 cytosolic-like tRNAs isolated from wheat mitochondria had an RRC >0.9 (Table II), indicating that these tRNAs are present in wheat mitochondria at levels substantially exceeding those observed for cy-tRNAs that are not required by the mitochondrion for protein synthesis. Notably, the RRC for one cytosolic-like tRNA, tRNAU*AALeu4, was significantly greater than the usual range of 1-2, which may indicate that this tRNA is not used or is not required in large amounts in the cytosol, and/or is required in mitochondria in greater relative proportion than it is in the cytosol. In a different case (cytosolic-like tRNAIAGLeu2), the RRC was only 0.47. The latter tRNA was isolated from a major band in the two-dimensional polyacrylamide gel, and in an additional gel electrophoretic purification step (see above), it produced a band similar in intensity to that of the tRNAUAGLeu1. Several possibilities may explain this result. (i) The oligonucleotide used in this experiment may not have been completely specific for cytosolic tRNAIAGLeu2. However, the fact that it was successfully used for RT sequencing provides at least partial confirmation of its hybridizing target in the mitochondrial RNA fraction. (ii) The tRNAIAGLeu2-specific oligonucleotide may have bound nonspecifically to other RNA species, particularly cytosolic RNAs. This was a potential problem for all of the slot blot hybridizations and was addressed in a control experiment using a tRNAIAUIle-specific oligonucleotide having a single nucleotide mismatch with its target sequence. This oligonucleotide did not generate a visible signal within the usual time period for the slot blot hybridization experiments, although a faint signal was obtained upon much longer exposure (data not shown). (iii) The tRNAIAGLeu2 may actually constitute a greater proportion of the cytosolic RNA than it does of the mitochondrial RNA. The amount of this tRNA in mitochondria is comparable to that of other tRNAs having RCRs close to 1.0; nevertheless, the slot blot hybridization data presented here cannot unambiguously distinguish this mt-tRNA species from a cytosolic species nonspecifically associated with mitochondria.

Reverse Transcriptase Sequencing of mtDNA-encoded tRNAGUCAsp-- In the present study, a nDNA-encoded species of wheat mt-tRNAGUCAsp was identified on the basis of its high sequence similarity to plant cy-tRNAs having the same anticodon (Table III). A native tRNAAsp gene, distinct in sequence, has been found in wheat mtDNA (26); however, a tRNA corresponding to this gene was not encountered in the present or in a previous (2) analysis of the wheat mitochondrial tRNA population.

To examine the possibility of low level expression of the wheat mt-tRNAGUCAsp gene, a gene-specific oligonucleotide was used as a primer in RT sequencing. A clear sequence ladder was generated, with a strong stop at the position marking the mature 5' end of the tRNA, as well as pauses within the ladder itself, diagnostic of the presence of modified nucleosides (data not shown). This makes it unlikely that the sequence ladder was produced from low levels of mtDNA in purified mitochondrial RNA preparations. The sequence for this tRNAAsp was identical to the previously published gene sequence (26) at all positions that could be discerned.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Subcellular Localization of tRNAs-- From the data presented here, 14 of 16 cytosolic-like mt-tRNAs are considered to be imported into wheat mitochondria. These imported tRNAs almost entirely complement the codon recognition and amino acid specificities of the previously characterized mtDNA-encoded tRNA population. Moreover, the majority of these tRNAs constitute approximately the same proportion of either the cytosolic or mitochondrial tRNA populations, the two exceptions being tRNAU*AALeu4, which represents a significantly greater (~5-fold) proportion of the mitochondrial RNA than it does of the cytosolic RNA, and tRNAIAGLeu, which comprises a much smaller proportion of the mitochondrial RNA than of the cytosolic RNA. From the slot blot analysis, it is not possible to assess the import status of those nDNA-encoded tRNA species whose relative abundance in mitochondria does not significantly exceed that of a cy-tRNA that is not required for mitochondrial protein synthesis. However, even though we cannot definitively classify the tRNAIAGLeu species as an imported one, it is presumably required by the wheat mitochondrial translation system because no mtDNA-encoded counterpart has been found.

The mtDNA-encoded mt-tRNAAsp (detected here by RT sequencing) also appears to be present in relatively low amounts in wheat mitochondria, given that it eluded detection by direct sequencing of electrophoretically separated mt-tRNAs in the present and a previous (2) study. A similarly low level of mtDNA-encoded tRNAAsp in potato mitochondria has been noted (3). In considering how the evolutionary replacement of a mtDNA-encoded tRNA by a nDNA-encoded species might occur, we anticipate a transitional stage in which both tRNAs are functional in mitochondria, thereby allowing subsequent loss of the mitochondrial gene. When low levels of both nDNA-encoded and mtDNA-encoded species are detected in the mt-tRNA population, it is conceivable that the nDNA-encoded species is in fact required because the mtDNA-encoded tRNA is present at insufficient levels to support mitochondrial translation on its own. The case of tRNAAsp described here may represent an example of an intermediate stage in the loss of expression of a mtDNA-encoded tRNA. A similar redundancy of nDNA- and mtDNA-encoded tRNAVal species has been reported in Marchantia mitochondria (45).

The Wheat Mitochondrial tRNA Population-- In view of the apparent absence of any tRNALeu genes in wheat mtDNA, wheat mitochondria may well utilize the nDNA-encoded tRNAIAGLeu identified here. If so, the characterized wheat mt-tRNA population would include 10 native, 6 chloroplast-like and 15 nDNA-encoded tRNAs, for a total of 31 distinct species. The potential codon recognition pattern of these tRNAs is presented in Table IV. All 61 sense codons have been identified in the collection of wheat mitochondrial protein genes sequenced to date, and there is no evidence of any departure from the standard genetic code (46). That being the case, it is evident that not all of the required wheat mt-tRNAs have been identified; in particular, (a) tRNA(s) specific for threonine remain(s) to be found.


                              
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Table IV
Potential codon recognition pattern in the wheat mitochondrial translation system
Codons are in uppercase letters; assigned anticodons of the corresponding tRNAs (see Table III) are in lowercase letters (i, inosine; l, lysidine; c*, modified C; u*, modified U). A minus sign (-) indicates that a tRNA corresponding to that particular codon has not been identified, whereas a number sign (#) indicates that the codon may be recognized by a tRNA that pairs with other codons in that box. Standard font denotes a native mtDNA-encoded tRNA; italicized font denotes a chloroplast-like mtDNA-encoded tRNA; bold font denotes a nDNA-encoded mt-tRNA. The deduced codon recognition pattern is based on standard wobble rules. The mtDNA-encoded tRNAs were previously characterized in Ref. 2 except for tRNAAsp, which along with the nDNA-encoded tRNAs was identified in the present study (see text).

Because the wobble pairing rules for codon/anticodon recognition have not yet been established for the plant mitochondrial translation system, it is unclear how many wheat mt-tRNA species are actually required to support protein synthesis in the organelle. In vertebrate mitochondria, expanded wobble base pairing in conjunction with a modified genetic code reduces the number of tRNAs required for translation to only 22-23, depending on whether the same or different tRNAsMet are used for initiation and elongation (46). In angiosperm chloroplasts, which like plant mitochondria use the standard genetic code, a minimum of 32 tRNAs is required if conventional wobble base pairing occurs (47), but only 30 tRNAs have been identified. However, Pfitzinger et al. (47) have demonstrated that chloroplast tRNAU*GCAla, tRNAICGArg, tRNAUAGLeu, and tRNAU*GGPro are able to read all four codons of the respective amino acid families, apparently employing a "two out of three" base pair recognition mechanism.

It is possible that eight tRNAs having UNN anticodons could decipher the 32 codons represented by the eight four-codon families of the standard genetic code. Table IV shows that wheat mt-tRNAs of this type have been identified for five of these eight families. However, in four of these cases, tRNAs bearing either a GNN or INN anticodon have also been identified, rendering U·N wobble pairing unnecessary. This might suggest that expanded wobble pairing does not occur in wheat mitochondria, in which case a tRNAGGGPro would remain to be found.

Finally, it is necessary to account for recognition of CGG (Arg) and AGA (Arg) codons, for which corresponding tRNAs have not been found. The tRNACCUArg anticodon was characterized here by both RT sequencing and PCR analysis, and an unmodified wobble position C has been confirmed by direct sequence analysis of this tRNA species. Thus, it is unlikely that tRNACCUArg would be able to decode both AGA and AGG codons. The remaining arginine codon (CGG) may be recognized by tRNAICGArg, as proposed for angiosperm chloroplasts (47).

Nuclear DNA-encoded tRNA Populations in Monocotyledon, Dicotyledon, and Liverwort Mitochondria-- The study reported here represents the most comprehensive sequence survey of nDNA-encoded mt-tRNA species in any plant system. Homologs of some of these wheat nDNA-encoded mt-tRNAs have been found in the mitochondria of maize (another monocotyledon) (48), potato (a dicotyledon) (3), and larch (a gymnosperm) (48); however, few anticodon sequences were directly determined in these cases.

In M. polymorpha, the mitochondrial genome encodes 29 "native" tRNA genes specifying 27 distinct species (49). No chloroplast-like tRNA genes are present in Marchantia mtDNA (49). Compared with angiosperm and gymnosperm mitochondria, liverwort mitochondria contain the largest number of mtDNA-encoded tRNAs. However, even allowing for both G·U and U·N wobble base pairing, tRNAs reading the isoleucine codons AUU and AUC and the threonine codons ACA and ACG are still required (50). In both angiosperm and larch mitochondria, these tRNAs are imported, and nDNA-encoded tRNAAAUIle and tRNAAGUThr species have since been identified in liverwort mitochondria (51, 52).

Other similarities between the nDNA-encoded tRNA populations of angiosperm and larch mitochondria include import of tRNAs specific for alanine, arginine, leucine, and valine codons. However, larch mitochondria import tRNAs that angiosperm mitochondria do not (48), including tRNAUGGPro and tRNAGAALys, genes for which have been identified in angiosperm mitochondria. Although wheat mitochondria contain the largest number of identified imported tRNAs (at least 14 species representing seven amino acids), larch mitochondria import tRNAs specific for a greater number of amino acids (at least 11 tRNA species corresponding to 10 amino acids).

The work presented here and elsewhere (48) determined that the wheat mt-tRNAHis is imported. This is in contrast not only to the situation in several dicots (53, 54) but also several other graminaceous plants (55-57), where the mt-tRNAHis is a chloroplast-like, mtDNA-encoded species. Similarly, there is no tRNAPhe gene in the mitochondrial genome of A. thaliana (19); instead, a cytosolic tRNAPhe is imported into Arabidopsis mitochondria (43), a signal departure from other dicots. Another difference between relatively closely related plants concerns tRNAGCUSer and tRNAUGASer, which are imported species in sunflower (44) but are native mt-tRNAs in potato (3) and other dicots.

In view of the number of documented differences with respect to which tRNA species are imported into mitochondria within the range of monocotyledonous and dicotyledonous plants, distinctions between these two groups are becoming increasingly blurred. Clearly, before more definitive comments can be made about the differences in the imported tRNA populations of monocot, dicot, and gymnosperm mitochondria, a larger number of plant species will have to be studied. Nevertheless, the differences demonstrated to date serve to emphasize that the plant mitochondrial translation system is quite flexible with respect to the genetic origin of the tRNAs it uses. Moreover, the import system must be able to adapt relatively rapidly over evolutionary time with regard to the particular cytosolic-like tRNAs that are brought into mitochondria to function there.


    ACKNOWLEDGEMENT

We thank M. N. Schnare for valuable advice on experimental approaches and techniques and for critical review of the manuscript.


    FOOTNOTES

* This work was supported in part by Grant MT-4124 from the Medical Research Council of Canada (to M. W. G.).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.

Dagger Supported in part by a predoctoral fellowship from the Walter C. Sumner Foundation.

§ Supported by a fellowship from the Canadian Institute for Advanced Research (Program in Evolutionary Biology). To whom correspondence should be addressed. Tel.: 902-494-2521; Fax: 902-494-1355; E-mail: m.w.gray@dal.ca.

Published, JBC Papers in Press, October 10, 2000, DOI 10.1074/jbc.M007708200


    ABBREVIATIONS

The abbreviations used are: mt, mitochondrial; cy, cytosolic; RT, reverse transcriptase; PCR, polymerase chain reaction; RRC, ratio of the regression coefficients.


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RESULTS
DISCUSSION
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