INTRODUCTION

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Studies of pre-tRNA processing in Escherichia coli have revealed that although the order of 5' and 3' processing events can vary among substrates, many eukaryotic precursor (pre)-tRNAs are processed in a preferred order (21). Classical eukaryotic tRNA genes are monocistronic and compared to most of their prokaryotic counterparts their primary transcripts are short and simple (18, 33). Although many features of tRNA maturation, including 5' processing by RNase P, have been conserved from bacteria to humans, mechanisms of 3'-end maturation were not. Like other transcripts synthesized by RNA polymerase III (Pol III), pre-tRNAs are terminated at their 3' end by the sequence motif UUU_OH, hereafter referred to as 3' oligo(U), which comprises a high-affinity binding site for the La protein (34). This oligo(U) tract, together with a short sequence stretch proximal to it, comprise the 3' trailer of eukaryotic pre-tRNAs which must be removed prior to enzymatic addition of CCA (8).

Evolutionary conservation of La phosphoprotein and its interaction with 3' oligo(U) indicate the importance of this protein in the biogenesis of Pol III transcripts (38, 42). Indeed, La can modulate pre-tRNA 3'-end metabolism in Saccharomyces cerevisiae (43). Yeast cells can process pre-tRNA 3' ends by either exonuclease- or endonuclease-mediated pathways, and La can influence which pathway is used (43).

La's involvement in RNA biogenesis is almost certainly not limited to tRNAs since La is also found associated with the precursors of 5S rRNA, U6 snRNA, 7SL RNA, Alu retroposon RNAs, and all other nascent transcripts synthesized by Pol III (see reference 35). Experiments performed in cell extracts have revealed activities for human La in transcript release and Pol III reinitiation, as well as B1-Alu RNA 3' end metabolism (12, 23, 25). Thus, while specificity for 3' oligo(U) reflects La's activity as a transcription termination factor (13, 14), this interaction is also a means by which La remains associated with nascent Pol III transcripts after their synthesis (16, 30, 35). Investigating La's role in tRNA expression should also provide insight into the biogenesis and maturation of this broad class of eukaryotic RNAs.

An earlier study suggested that a Pol III transcription-coupled factor could modulate 3'-end maturation of B1-Alu transcripts in a manner that is sensitive to the sequence context of the Pol III terminator (24). The La protein was then identified as the Pol III termination factor that protected B1-Alu RNA from 3' processing (25). Human La is 408 amino acids long and contains an N-terminal domain that binds RNA and a phosphoserine-containing C-terminal domain that is not required for general RNA binding (5, 6, 12, 19, 29). It is therefore significant that alterations in the C-terminal domain of La were found to disrupt RNA recognition by La and render nascent B1-Alu transcripts susceptible to processing (12). This same basic region in the C-terminal domain is also required for the transcription factor activity of human La protein (12), which can be regulated by phosphorylation and dephosphorylation of serine 366, which resides within a conserved casein kinase II (CKII) site (10). Involvement of the C-terminal basic region of La in RNA recognition and transcription factor activity presumably reflects a mechanistic coupling between the Pol III termination and reinitiation cofactor activities of La (23).

The appearance of a B1-Alu intermediate RNA in the presence of certain C-terminal altered forms of La suggested that the N- and C-terminal domains of La may mediate distinct RNA recognition events (12). We have therefore extended our investigation to a previously studied pathway of human pre-tRNA_i^Met processing, using a cell-free system to define the determinants in the La protein (and the RNA substrate) involved in protection of pre-tRNA_i^Met from processing. Interaction of the N-terminal domain of La with the 3' oligo(U) tract of pre-tRNA_i^Met is required for La's C-terminal-domain-mediated protection of the 5'-end region of pre-tRNA from processing by RNase P. Site-specific phosphorylation of La on serine 366, adjacent to the C-terminal basic region, modulates this 5' protection activity specifically.

	MATERIALS AND METHODS

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Pol III transcription-processing reactions. In vitro Pol III transcription reaction mixtures (40 µl) contained 200 ng of plasmid DNA [270-bp human pre-tRNA_i^Met gene 2 fragment in pBluescript(SK⁺), designated ptRNA_i^Met₂₇₀] and either 2 µl of unfractionated S100 extract or 4 µl of TFIIIB-Pol III, 3 µl of TFIIIC1, and 2 µl of TFIIIIC2 (see Fig. 1B). In subsequent experiments, 4 µl of each TF was used (see Fig. 5A and 8A). Reactions were carried out in mixtures containing 25 mM HEPES (pH 7.9); 5 mM MgCl₂; 90 mM KCl; 1 mM dithiothreitol (DTT), 0.5 µl of RNase inhibitor (Promega); 5% glycerol; 0.5 mM each of ATP, CTP, and UTP; 25 mM of GTP, 2 µCi of [-³²P]GTP (New England Nuclear), and either 2 pmol (100 ng) of purified La protein or the amount indicated. All components except the nucleoside triphosphates (NTPs) were premixed and incubated on ice for 5 min. Reactions were started by addition of NTPs and incubation at 30°C. The time course experiment (Fig. 1A) utilized streptavidin agarose-immobilized biotinylated ptRNA_i^Met₂₇₀ DNA. After a pulse of [-³²P]GTP incorporation, excess unlabeled GTP was added and the supernatant was separated from the template by centrifugation. Aliquots were removed at specified times thereafter and analyzed.

Fractionated HeLa cell extract. HeLa cell-derived cytoplasmic S100 was fractionated in buffer A (20 mM HEPES, pH 7.9; 20% glycerol; 0.2 mM EDTA; 0.5 mM DTT; 0.5 mM phenylmethylsulfonyl fluoride [PMSF]) containing 100 mM KCl by phosphocellulose (P11) chromatography into PC-A, -B, and -C (10). Crude PC-B was dialyzed in buffer A containing 100 mM KCl and refractionated on P11 phosphocellulose; fractions eluting at 0.25 to 0.3 M KCl contained TFIIIB-Pol III and were used as they were. PC-C was dialyzed as described above and fractionated on Mono Q (44). Fractions eluting at 0.2 to 0.28 M KCl were pooled and rechromatographed on Mono Q; TFIIIC1 eluted at 0.26 M KCl, was dialyzed as described above, and was fractionated on heparin-Sepharose. The resulting TFIIIC1 activity was fractionated on Mono S and eluted at 0.45 to 0.5 M KCl. TFIIIC2 activity that eluted from the first Mono Q column at 0.35 to 0.55 M KCl was adjusted to 1 M NH₄SO₄ in buffer A and fractionated on phenyl-Sepharose, eluting at 0.05 to 0 M NH₄SO₄. This was adjusted to 0.1 M KCl and fractionated on B-box-DNA affinity resin (7). The eluted TFIIIC2 activity was dialyzed as described above, fractionated on Mono Q, step eluted with 0.35 M KCl, and collected as TFIIIC2. Activities of TFIIIC1, TFIIIC2, and TFIIIB-Pol III were monitored by in vitro transcription. For most reactions, 20 times the amount of La present in the TFIIIB-Pol III fraction was used for reconstitution. This amount of La was used because it represents the amount found in the unfractionated S100.

La proteins. C-terminal histidine (His)-tagged La proteins, derived from E. coli, as well as HeLa-derived U-La and S-La, were as previously described (10). After phosphorylation by recombinant CKII, the His-tagged La was affinity purified by using nickel agarose as described previously (10).

T7 RNA polymerase (RNAP)-synthesized transcripts. T7 RNAP-synthesized transcripts were produced from templates generated by PCR (22) designed to yield RNAs corresponding precisely to pre-tRNA_i^Met, the 5' processed pre-tRNA_i^Met5', and the fully processed tRNA_i^Met as described previously (45). For some experiments, T7-synthesized ³²P-labeled RNAs were incubated in 200 µl of calf intestinal phosphatase (CIP) buffer and 45 U of CIP (Boehringer Mannheim) for 30 min at 37°C. All ³²P-labeled RNAs were gel purified prior to use.

RNA electrophoretic mobility shift assays (EMSAs). EMSAs were performed as described earlier (10) in 10 µl with poly(rG) or 100 ng of 5S rRNA competitor as described below (Fig. 1E).

RNA processing. In vitro processing of T7-synthesized RNA was carried out in 10-µl reaction mixtures containing 3,000 or 6,000 cpm of ³²P-labeled RNA; 0.5 µl of RNasin (Promega); 100 ng of E. coli 5S rRNA carrier (Boehringer Mannheim); 25 mM HEPES (pH 7.9); 5 mM MgCl₂; 120 mM KCl; 1 mM DTT, 6% glycerol; 0.5 mM concentrations each of ATP, CTP, and UTP; 25 mM GTP; 3 pmole of La protein or the amount indicated; and 1 µl each of TFIIIB-Pol III, TFIIIC1, and TFIIIC2 (these conditions were used because they are similar to the Pol III transcription-processing reactions). After addition of all three TF fractions, reaction mixtures were incubated at 30°C for 45 min and then stopped, and the RNA was purified.

Primer extension. The primer extension was performed as described earlier (11) with ³²P-5'-end-labeled oligoDNA 5'-TAGCAGAGGATGGTTTCGATCCATCGACCTCT-3', which is complementary to the last 32 nucleotides of 3'-processed tRNA_i^Met (45). This primer was chosen because it is complementary to a region within the 5'-processed intermediate, the 3'-processed intermediate, and the fully processed tRNA (5' and 3' processed) and therefore detects all three species. Negative control reactions in which NTPs were omitted from the Pol III transcription reaction confirmed that our purified fractions were not contaminated by endogenous tRNA_i^Met species (not shown). Use of T7 RNAP-synthesized marker species corresponding to pre-tRNA_i^Met and 5'-processed pre-tRNA_i^Met provided positive controls. With these controls in place, it was clear that this assay distinguished the unprocessed and 5'-processed pre-tRNA_i^Met species in our processing reactions.

RNase P protection assay. Nuclear RNase P, purified from S. cerevisiae, was separated from all contaminating nuclease activities by a multistep chromatography protocol that included Mono Q fast protein liquid chromatography as described (4). Reactions were carried out in 10 µl containing ~6,000 cpm of T7-synthesized ³²P-labeled RNA substrate, 100 ng of 5S rRNA carrier, 3 pmol of purified La protein or buffer alone, 0.2 µl of RNasin, RNase P (diluted 10-fold immediately prior to use), 20 mM HEPES (pH 7.9), 10 mM MgCl₂, and 110 mM KCl.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

La protects human pre-tRNA_i^Met from processing in a homologous cell-free system. The nascent transcript synthesized from the human pre-tRNA_i^Met gene is processed by removal of the 8-nucleotide leader and the ~10-nucleotide trailer (heterogeneity is found in the number of U residues at the 3' end [45]). Using a fractionated Pol III transcription system that contains trace residual LA under pulse-chase conditions, we demonstrated a precursor-product relationship for the transcripts produced from this human tRNA_i^Met gene (Fig. 1A, lanes 3 to 8). T7 RNAP-synthesized ³²P-labeled RNAs corresponding to pre-tRNA_i^Met (lane 1), pre-tRNA_i^Met lacking its 5' leader (pre-tRNA_i^Met5'; lane 2), and fully processed tRNA_i^Met (lane 9), as determined by Zasloff et al. (45), were used as size markers to show that the slow- and fast-migrating Pol III-synthesized transcripts corresponded in size to pre-tRNA_i^Met and tRNA_i^Met, respectively. Analysis by primer extension (see Materials and Methods) confirmed that the tRNA_i^Met-size product had had its 5' leader removed as described previously (45; data not shown). A reproducible band that migrated between the precursor and fully processed product (Fig. 1A, lanes 6 to 8) suggested that processing occurred in two steps as expected for distinct 5'- and 3'-processing events described for this and other eukaryotic pre-tRNAs (8, 45).

View larger version (46K): [in this window] [in a new window]   FIG. 1.   La inhibits processing of pre-tRNAiMet in a homologous in vitro system. (A) After assembly of transcription complexes from fractionated HeLa components and partial elongation of Pol III in the presence of CTP, ATP, and [-32P]GTP, a pulse of synthesis was allowed to occur in the presence of all four NTPs. The supernatant was then separated from the immobilized template by centrifugation, and aliquots were removed from it at various times thereafter as indicated (lanes 3 to 8). Lanes 1, 2, and 9 contain T7 RNAP-synthesized transcripts representing pre-tRNAiMet of 89 nucleotides (lane 1), pre-tRNAiMet that lacks the 5' leader sequence (pre-tRNA5', lane 2), and the mature tRNAiMet of 72 nucleotides (lane 9), as determined by Zasloff et al. (45). (B) A fraction containing TFIIIB and Pol III, along with TFIIIC1 and TFIIIC2 fractions (including trace amounts of La), reconstitute transcription of the human tRNAiMet gene but yield a product of 72 nucleotides (lane 2). Supplementation of the reconstituted reaction mixture with La protein to 50 nM (lane 1) or use of unfractionated S100 extract in a reaction mixture that contains 50 nM endogenous La (lane 3) produces a larger transcript. Products were analyzed by denaturing 6% polyacrylamide gel electrophoresis and autoradiography. (C) Pre-tRNAiMet processing was examined in reactions that were immunodepleted with anti-La immunoglobulin G immobilized on protein A-Sepharose and after repletion with buffer alone (lane 2) or La (lane 3). RNA synthesized in the nondepleted reaction is shown in lane 1. (D) 32P-labeled pre-tRNAiMet was synthesized by T7 RNAP, purified, and incubated with fractionated extract, 100 ng of E. coli 5S rRNA nonspecific competitor, and either buffer alone (lane 1) or increasing amounts of La (0.1, 0.3, 0.5, 1.0, 2.0, and 5.0 pmol; lanes 2 to 7, respectively) and examined for processing. Lane 8 contains input RNA ("i") that was not subjected to extract and lane 9 contains a T7 RNAP-synthesized 32P-labeled tRNAiMet5' ("m") corresponding to the 5' processed intermediate as described earlier (45) which served as size markers. (E) Processing (upper panel) and binding (lower panel) of T7 RNAP-synthesized pre-tRNAiMet were examined in 10-µl reaction mixtures containing 100 ng of 5S rRNA and buffer alone (lane 1) or 3 pmol of La (lane 2) or 3 pmol of E. coli single-strand binding protein (lane 3). HeLa fractions were omitted from the EMSA reactions. For the upper panel, the positions of unprocessed pre-tRNAiMet (U) and processed (P) RNAs are shown; for the lower panel, the positions of bound (B) and free (F) pre-tRNAiMet probe are shown.

The 3' oligo(U) tract of pre-tRNA_i^Met is required for protection from 5' and 3' processing by La. Presynthesized transcripts corresponding to precursor and singly processed pre-tRNA_i^Met intermediates were previously used to examine the individual 5'- and 3'-processing events (2, 3). We used T7 RNAP-synthesized pre-tRNA_i^Met transcripts carrying deletions or substitutions at either the 3' end or the 5' end to examine processing (Fig. 2). Conversion of the nonmutated, full-length pre-tRNA_i^Met to the tRNA_i^Met-size product is inhibited by La (Fig. 2, lanes 1 to 3). The substrate pre-tRNA_i^Met3' lacks the entire 3' trailer, including the oligo(U) tract, and was used to monitor 5' processing. This substrate (lane 4) was processed to the stable tRNA_i^Met-size product in the absence of La (lane 5) and, as expected, could not be protected by La (lane 6). The substrate shown in lane 7, pre-tRNA_i^Met5', contains an intact 3' trailer but lacks the 5' leader and has been used previously to monitor 3' processing (3). This substrate was processed to the stable tRNA_i^Met-size product in the absence of La (lane 8) but was protected in the presence of La (lane 9). These data suggested that the 3' trailer is required for La-mediated protection from two distinct processing events.

View larger version (29K): [in this window] [in a new window]   FIG. 2.   La-mediated protection of pre-tRNA is specific and dependent on the RNA 3' oligo(U) terminus. Effects of La on processing of T7 RNAP-synthesized pre-tRNAiMet (lanes 1 to 3), pre-tRNAiMet-derived transcripts bearing deletion of the 3' trailer (3', lanes 4 to 6), deletion of the 5' leader (5', lanes 7 to 9), substitution of the terminal 4 Us (3'UA, lanes 10 to 12; 3'UC, lanes 13 to 15), and deletion of the terminal 4 Us (3'U, lanes 16 to 18) as indicated below the lanes. Lanes 1, 4, 7, 10, 13, and 16 show the input RNAs for each reaction. Lane 19 shows the T7 RNAP-synthesized mature tRNAiMet transcript of 72 nucleotides. 5S rRNA (100 ng) was included as a nonspecific competitor in all reactions; other components including HeLa fractions (fxns) are indicated above the lanes.

Specific, high-affinity binding of La to the 3' oligo(U) tract of pre-tRNA_i^Met. Although our nuclease protection assays indicated an interaction between La and the terminus of pre-tRNA_i^Met, it was important to demonstrate specificity for the 3' oligo(U) tract of pre-tRNA_i^Met in a direct binding assay. Four tRNA_i^Met-derived transcripts carrying terminal mutations were examined in parallel and in triplicate by EMSA with various concentrations of La. At all of the concentrations tested, La formed stable complexes with pre-tRNA_i^Met (Fig. 3A) and pre-tRNA_i^Met5' (Fig. 3C), both of which carry oligo(U) 3' termini. In contrast to these substrates pre-tRNA_i^Met3' (Fig. 3B) and pre-tRNA_i^Met3'U (Fig. 3D), both of which lack oligo(U) 3' termini, were bound less avidly, requiring a substantially higher concentration of La for complex formation.

View larger version (52K): [in this window] [in a new window]   FIG. 3.   High-affinity binding of La to pre-tRNAiMet is dependent on the 3' oligo(U) terminus. EMSAs with wild-type and pre-tRNAiMet-derived transcripts bearing various terminal mutations and increasing amounts of La were performed in parallel with 0.1 ng of probe and 20 ng of poly(rG) competitor. Each concentration was tested in triplicate as shown in three lanes. Amounts of La are indicated above the lanes in femtomoles. All reactions were performed and analyzed in parallel on the same autoradiogram.

The C-terminal basic region of La is required to protect pre-tRNA_i^Met from 5' processing. A panel of His-tagged, affinity-purified, mutant La proteins (12) was used to determine which regions of La are required for pre-tRNA_i^Met protection. A diagram illustrating a working model of human La struture is shown in Fig. 4, along with a representation of the La constructs used in this study and a summary of the results obtained. La deletion constructs were examined in three assays: (i) Pol III transcription-processing, (ii) RNase P-mediated processing, and (iii) 3' processing of pre-tRNA_i^Met5' (Fig. 5). In the transcription-processing assay, the tRNA_i^Met-size product was generated in the absence of La (Fig. 5A, lane 1), whereas La 1-408 (i.e., La amino acid residues 1 to 408) and La 1-363 protected pre-tRNA_i^Met from any detectable processing (lanes 2 and 3). La 1-328 and La 1-235 allowed processing of approximately 50% of pre-tRNA_i^Met to an intermediate band (lanes 4 and 5). La 1-187 also reproducibly allowed processing to the intermediate band only (not shown). These data suggest that residues 329 to 363 contribute to the protective action of La. Although a significant amount of pre-tRNA_i^Met remained unprocessed in the presence of La 1-235 and La 1-328, these proteins did not appear to be generally defective since a processing intermediate, but not the final processed product, accumulated in their presence. If these proteins were generally defective we would have expected a distribution of all three bands.

View larger version (16K): [in this window] [in a new window]   FIG. 4.   A schematic representation of human La. Deletion and substitution mutants used for the experiments described below are shown according to the three-RRM model of human La (12, 19). +++, C-terminal basic region. Phosphoserine 366 is indicated by the encircled P (10). A His tag is present on the C termini of the recombinant constructs but is absent from the native HeLa proteins S-La and U-La (10). Results obtained in the RNase P (5') and the pre-tRNAiMet5' (3') processing protection assays for these proteins are summarized to the right.

View larger version (42K): [in this window] [in a new window]   FIG. 5.   Dissection of the regions of La responsible for protection of pre-tRNAiMet from processing. (A) The Pol III transcription-processing assay was performed in the absence of added La (lane 1) or in the presence of the truncated La proteins as indicated above the lanes. The positions of the T7-synthesized markers pre-tRNAiMet, pre-tRNAiMet5', and tRNAiMet are indicated. (B) T7 RNAP-synthesized pre-tRNAiMet was subjected to RNase P in the presence of the La proteins indicated above the lanes. Portions (1.00 µl) of RNase P were used for each reaction, and the incubation time was 15 min. Positions of input and processed RNAs are indicated to the left. (C) T7-synthesized pre-tRNAiMet5' was assayed for processing in reactions containing HeLa fractions and the La proteins indicated above the lanes. The positions of input and processed RNAs are indicated to the left.

Both a C-terminal basic region and the N-terminal RNA-binding domain of La are required for protection of pre-tRNA_i^Met from 5' processing by RNase P. The data suggested that the N-terminal domain of La associates with the 3' oligo(U) tract of a pre-tRNA and that this promotes blockage of both processing sites on the substrate, with the C-terminal domain blocking 5' processing specifically. There is no evidence to indicate and we think it unlikely that La interacted with either RNase P or another processing nuclease in our fractions to inhibit these enzymes directly (see Discussion). This model is consistent with all of our results, including those described below that were obtained with a preparation of highly purified, yeast nuclear RNase P.

Evidence of an interaction between the nascent 5' triphosphate of pre-tRNA_i^Met and La. A T7 RNAP-synthesized nascent transcript lacking the 5' leader of pre-tRNA_i^Met exhibited high-affinity for La (Fig. 3C), suggesting that La does not interact with the leader in a sequence-specific manner. The basic region of human La was previously noted to contain the sequence ₃₃₃GRRFKGKG₃₄₀, representing a potential NTP binding site of the consensus sequence GXXXXGKX found in a number of ATP-binding proteins (reference 37 and references therein). This observation, in conjunction with this region's overall basic nature, suggested that La might recognize the 5' triphosphate as a distinct determinant of a newly synthesized RNA. This mode of contact allows specific recognition of the 5' ends of a variety of pre-tRNAs despite their lack of sequence homology (see Discussion). This model is consistent with efficient binding of La to pre-tRNA_i^Met5' which, because of synthesis by T7 RNAP, contains a nascent pppG 5' terminus.

View larger version (48K): [in this window] [in a new window]   FIG. 6.   Direct binding evidence that La recognizes the 5' triphosphate of nascent pre-tRNA. (A) EMSA with nascent pre-tRNA3'U (CIP, upper panel) or dephosphorylated pre-tRNA3'U (+CIP, lower panel) and increasing amounts of full-length La as indicated. Reaction mixtures were 10 µl and contained a small amount (2 ng) of the nonspecific competitor poly(rG). The fraction of bound RNA (percent bound = [bound/bound + unbound] × 100) was quantitated and is shown below the lanes. Positions of free RNA and RNA-protein (RNP) are indicated to the left. (B) EMSAs as described in panel A were performed in triplicate. The bound versus unbound RNA was then quantitated by phosphorimager analysis, and the bound RNA (percent bound = [bound/bound + unbound] × 100) was plotted against the La concentration; error bars represent the range of three experiments. Equilibrium Kd values under these conditions are 120 nM for nascent pre-tRNAiMet3'U and 142 nM for CIP-treated tRNAiMet3'U (see text). (C) Same as for panel B except that La 1-328 was used. Note that concentrations of La 1-328 (indicated above the upper panel) span a different range than in panel A (see text). Experiments represented in panels A and C were performed in parallel and quantitated from the same exposure by phosphorimager analysis (not shown). The CIP-treated and mock-treated probes were nearly indistinguishable in their migration in these assays and migrated as indicated by "free RNA" in panels A and C when coelectrophoresed in the same gels (not shown). (D) Same as for panel B except that La 1-328 was used. Note that both axes are on scales different from that in panel B (see text). Experiments represented in panels B and D were performed and analyzed in parallel.

View larger version (37K): [in this window] [in a new window]   FIG. 7.   RNase protection evidence that La recognizes the 5' triphosphate of nascent pre-tRNA. (A) Nascent pre-tRNAiMet (lanes 2 and 3) and pre-tRNAiMet dephosphorylated by CIP (lanes 4 and 5) were compared in the RNase P protection assay in the presence and absence of La as indicated. The CIP-treated pre-tRNA substrate is presented in lane 1 to show its integrity. RNase P (1.00 µl) was incubated with the substrates for 45 min. (B) The data from three additional experiments performed as described in panel A were quantitated by phosphorimager analysis and converted to percent processed ([processed/processed + unprocessed] × 100) and plotted as bars. Error bars reflect the range of three datum points.

Phosphorylation of La serine 366 interferes with protection of pre-tRNA_i^Met from 5' processing. Native HeLa La can be separated into a serine 366-phosphorylated form (U-La) and an unphosphorylated form (S-La) (10). Since human recombinant La can be phosphorylated in vitro by CKII specifically at this site and subsequently purified (10), we could also examine recombinant His-tagged La 1-408 in both phosphorylated and unphosphorylated forms in the Pol III transcription-processing assay (Fig. 8A), the RNase P protection assay (Fig. 8B), and the 3' nuclease protection assay (Fig. 8C), along with the native proteins U-La and S-La.

View larger version (45K): [in this window] [in a new window]   FIG. 8.   Phosphorylation of La on serine 366 interferes with protection of pre-tRNAiMet from 5' processing. (A) The human tRNAiMet gene was expressed in the Pol III transcription-processing system with reconstituted fractions alone (lane 1) or with the added La proteins indicated (lanes 2 to 5). (B) RNase P (1.50 µl) was incubated with pre-tRNAiMet and the La proteins indicated. Lanes 1 and 2 show the pre-tRNAiMet input ("I") substrate and a pre-tRNAiMet5' size marker ("M") in the absence of RNase P. (C) The proteins indicated above the lanes (lanes 3 to 8) were examined for protection of pre-tRNAiMet5' from processing by HeLa fractions. Lanes 1 and 2 contain the RNA size markers indicated to the left.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The results reported here suggest that 5' processing of tRNA precursors may be regulatable in eukaryotes. La antigen has previously been shown to modulate 3' processing of tRNA precursors in yeast (43). Human tRNA_i^Met maturation occurs along an ordered pathway with 5' processing preceding 3' processing (3, 45), which is consistent with the pre-tRNA maturation pathways elucidated in yeast cells (38, 43). The data reported here extend our understanding of La's role in tRNA metabolism by showing that in addition to modulating 3' processing, La can also modulate 5' processing of pre-tRNA. In addition, a new binding modality for La was identified, the ability to recognize the 5' triphosphate of a nascent transcript. Because of its unique position on newly synthesized RNAs, the triphosphate moiety would provide La with the ability to interact with the initiation ends of various nascent transcripts while 3' oligo(U) recognition promotes interaction with the termination ends. Triphosphate binding may also help explain other activities that have been reported for La as discussed below. Finally, regions within both La and the pre-tRNA required for 5' and 3' protection were identified.

We wish to emphasize that 3' processing of pre-tRNAs can proceed by either of two pathways (43). In our system, 3' processing is presumably mediated by an exonuclease, one similar to the 3' exonuclease that matures pre-tRNA in S. cerevisiae cells that have been depleted of La (43).

Several considerations suggest that 5' protection by La occurs in vivo. First, protection occurred at a concentration of La found in unfractionated S100. La immunodepletion and repletion experiments confirmed that La is a pre-tRNA processing inhibitory factor. Second, the effects of La in this system were shown to be specific by several criteria. Concordance of specificity in binding and protection assays demonstrated that La functionally interacts with pre-tRNA_i^Met via the 3' oligo(U) tract, a well-known characteristic of La. Modulation of 5' processing by La's basic region was also shown to be specific, since proteins altered in this region remain active for high-affinity binding to oligo(U)-containing RNAs (10, 12), as well as for 3' protection (Fig. 5A and C), while losing 5' protection activity specifically (Fig. 5B). Likewise, loss of 5' protection by phosphorylated La (Fig. 8A and B) is specific, since this modification does not interfere with La's ability to bind oligo(U)-containing RNAs (10) and to protect the oligo(U)-containing substrate, pre-tRNA_i^Met5', from 3' processing (Fig. 8C). Expression of human La in La-deleted S. pombe cells corrects aberrant tRNA 3'-end maturation but also leads to a disproportionately large amount of pre-tRNA (relative to mature tRNA) that retains its 5' leader (38). Although other explanations are possible, this suggests that human La protects S. pombe pre-tRNAs from 5' processing because it is not phosphorylated efficiently when overexpressed in S. pombe. Finally, previous results suggested that 5' processed tRNA_i^Met intermediates are associated with La in vivo (30) and therefore support the notion that a La-pre-tRNA complex is a substrate for RNase P (Fig. 5 and 8). The structure of this complex appears to be altered by the phosphorylation status of La serine 366.

Phosphorylation and dephosphorylation control La activity. Although a small amount of La is present in the TFIIIB-Pol III fraction used for transcription, this amount of La is clearly insufficient to protect pre-tRNA from processing. This endogenous La is phosphorylated by endogenous CKII, or a CKII-like activity, during our transcription-processing reactions (9). Therefore, pre-tRNA processing and La phosphorylation both appear to be occurring in our Pol III transcription-processing reactions. Addition of exogenous La overwhelms the phosphorylation capacity of these reactions and protects against 5' processing. Consistent with this, exogenous CKII added to these reactions reverses the 5' protection activity of exogenous La (9).

La protects the pre-tRNA as opposed to inhibiting RNase P directly. The C-terminal basic region of La does not inhibit RNase P directly or in a general way, as demonstrated by the N-terminal truncated proteins, La 26-408, La 104-408 and La 303-408, which contain the C-terminal basic region but do not inhibit RNase P (Fig. 5B, lanes 8 to 10). Thus, the C-terminal basic region exhibits 5' protective activity only when present in cis with the RRM-containing N-terminal domain of La.

General versus specific binding of La to RNA. In the cell, La is presumably directed to its natural ligands, nascent Pol III transcripts (30, 34), by the La-containing Pol III holoenzyme (39). However, La protein can bind certain viral mRNAs. These include the leader sequence of vesicular stomatitis virus RNA (20), as well as the 5' regions of TAR RNA (6), rubella virus RNA (28), poliovirus RNA (27), and hepatitis C virus RNA (1). Since these are not Pol III transcripts, the pathway(s) by which La interacts with them has remained a mystery. Our data indicate that La recognizes the 5' triphosphate of newly synthesized RNA (Fig. 6 and 7). These findings suggest the possibility that La may interact with leader sequences through contacts made with their nascent 5' triphosphate termini. Although the results with these leader sequences suggest that La may be involved in viral RNA biogenesis, we should also suspect that an RNA motif that is normally buried within a longer transcript but removed from its context by synthesis in vitro and therefore bearing a 5' triphosphate might exhibit a higher affinity for La than it otherwise would. Moreover, templates with EcoRI-restricted 3' ends artificially add 3' U residues to the transcript, further increasing the apparent affinity of the RNA for La (1, 6, 26).

Bipartite binding by La and nascent RNA. 5'- and 3'-end-mediated binding of RNA to La can probably be accommodated by most Pol III nascent transcripts, since their 5' and 3' termini are often found in proximity to one another. The conserved structure of La in which two RRMs reside in the N-terminal domain and a basic region resides in the C-terminal domain (19) suggests that bipartite interactions with nascent RNA may be of fundamental importance to La function (see references 10 and 38 for alignments). It is also noteworthy that the 5' triphosphate of the tRNA-like transcript of E. coli known as RNA I guards against a 3' nuclease. In that case, a protein that mediates RNA I 3'-end metabolism also influences 5' processing (41).

A role for La in coordinating RNA biogenesis and maturation. Previous data indicate a role for La phosphorylation in regulating the recycling efficiency of Pol III transcription complexes (10). In view of the present results that indicate a role for La phosphorylation in posttranscriptional events, we must consider the possibility that La phosphorylation-dephosphorylation allows coordination of transcriptional and early posttranscriptional stages of RNA biogenesis.