Study on construction of a cDNA library corresponding to an amino acid-specific tRNA and influence of the modified nucleotide upon nucleotide misincorporations in reverse transcription

The construction of a cDNA library corresponding to an amino acid-specific tRNA and the influence of the modified nucleotide in the tRNA upon misincorporation in reverse transcription were investigated. The distinctive feature of the constructive strategy is that the cDNA library was prepared in connection with the charging activity of the tRNA. The aminoacyl-tRNA was captured selectively by using a biotin-avidin system. After hydrolysis of the ester bond, the tRNA was collected as an amino acid-specific tRNA pool, and a poly(A) tail was attached to the CCA terminus for reverse transcription. To the 3'-terminus of the transcribed cDNA, poly (dC) was added by terminal deoxynucleotidyl transferase, and the cDNA was amplified by PCR. The double-stranded cDNA was used for transformation of Escherichia coli JM109. Sequence analyses of the obtained clones bearing the tRNA genes revealed that a few nucleotide substitutions occurred at the location where the modified nucleotides exist. Among them, it was noteworthy that 1-methyladenosine (m(1)A22) in the D-loop of Bacillus subtilis tRNA(Ser) was recognized as G in the reverse transcription and the result revealed different tendency of the misincorporation, which has been shown in the study of HIV-1 reverse transcription.

Uniform binding of aminoacyl-tRNAs to elongation factor Tu by thermodynamic compensation

Elongation factor Tu (EF-Tu) binds all elongator aminoacyl-transfer RNAs (aa-tRNAs) for delivery to the ribosome during protein synthesis. Here, we show that EF-Tu binds misacylated tRNAs over a much wider range of affinities than it binds the corresponding correctly acylated tRNAs, suggesting that the protein exhibits considerable specificity for both the amino acid side chain and the tRNA body. The thermodynamic contributions of the amino acid and the tRNA body to the overall binding affinity are independent of each other and compensate for one another when the tRNAs are correctly acylated. Because certain misacylated tRNAs bind EF-Tu significantly more strongly or weakly than cognate aa-tRNAs, EF-Tu may contribute to translational accuracy.

Recognition of cognate transfer RNA by the 30S ribosomal subunit

Crystal structures of the 30S ribosomal subunit in complex with messenger RNA and cognate transfer RNA in the A site, both in the presence and absence of the antibiotic paromomycin, have been solved at between 3.1 and 3.3 angstroms resolution. Cognate transfer RNA (tRNA) binding induces global domain movements of the 30S subunit and changes in the conformation of the universally conserved and essential bases A1492, A1493, and G530 of 16S RNA. These bases interact intimately with the minor groove of the first two base pairs between the codon and anticodon, thus sensing Watson-Crick base-pairing geometry and discriminating against near-cognate tRNA. The third, or "wobble," position of the codon is free to accommodate certain noncanonical base pairs. By partially inducing these structural changes, paromomycin facilitates binding of near-cognate tRNAs.

Crystal structure of the ribosome at 5.5 A resolution

We describe the crystal structure of the complete Thermus thermophilus 70S ribosome containing bound messenger RNA and transfer RNAs (tRNAs) at 5.5 angstrom resolution. All of the 16S, 23S, and 5S ribosomal RNA (rRNA) chains, the A-, P-, and E-site tRNAs, and most of the ribosomal proteins can be fitted to the electron density map. The core of the interface between the 30S small subunit and the 50S large subunit, where the tRNA substrates are bound, is dominated by RNA, with proteins located mainly at the periphery, consistent with ribosomal function being based on rRNA. In each of the three tRNA binding sites, the ribosome contacts all of the major elements of tRNA, providing an explanation for the conservation of tRNA structure. The tRNAs are closely juxtaposed with the intersubunit bridges, in a way that suggests coupling of the 20 to 50 angstrom movements associated with tRNA translocation with intersubunit movement.

Functional analysis of prokaryotic SELB proteins

Since the discovery of selenocysteine as the 21st amino acid considerable progress has been made in elucidating the system responsible for its insertion into proteins. Elongation factor SELB, whose amino-terminal part shows homology to EF-Tu, was found to be the key component mediating delivery of selenocysteyl-tRNA(Sec) to the ribosomal A site. It exhibits a distinct tertiary structure comprising binding sites for guanosine nucleotides, the cognate tRNA, an mRNA secondary structure (SECIS element) and presumably ribosomal components. The kinetics of interaction of SELB with its ligands have been studied in detail. GDP was found to bind with about 20-fold lower affinity than GTP and to be in rapid exchange, which obviates the need for a guanosine nucleotide exchange factor. The affinity of SELB for the SECIS element is in the range of 1 nM and further increases upon binding of selenocysteyl-tRNA(Sec) to the protein. This supports the model that SELB forms a tight quaternary complex on the SECIS element which is loosened after insertion of the tRNA into the ribosomal A site and the concomitant hydrolysis of GTP.

Interactions between 23S rRNA and tRNA in the ribosomal E site

Interactions between tRNA or its analogs and 23S rRNA in the large ribosomal subunit were analyzed by RNA footprinting and by modification-interference selection. In the E site, tRNA protected bases G2112, A2392, and C2394 of 23S rRNA. Truncated tRNA, lacking the anticodon stem-loop, protected A2392 and C2394, but not G2112, and tRNA derivatives with a shortened 3' end protected only G2112, but not A2392 or C2394. Modification interference revealed C2394 as the only accessible nucleotide in 23S rRNA whose modification interferes with binding of tRNA in the large ribosomal subunit E site. The results suggest a direct contact between A76 of tRNA A76 and C2394 of 23S rRNA. Protections at G2112 may reflect interaction of this 23S rRNA region with the tRNA central fold.

Search for characteristic structural features of mammalian mitochondrial tRNAs

A number of mitochondrial (mt) tRNAs have strong structural deviations from the classical tRNA cloverleaf secondary structure and from the conventional L-shaped tertiary structure. As a consequence, there is a general trend to consider all mitochondrial tRNAs as "bizarre" tRNAs. Here, a large sequence comparison of the 22 tRNA genes within 31 fully sequenced mammalian mt genomes has been performed to define the structural characteristics of this specific group of tRNAs. Vertical alignments define the degree of conservation/variability of primary sequences and secondary structures and search for potential tertiary interactions within each of the 22 families. Further horizontal alignments ascertain that, with the exception of serine-specific tRNAs, mammalian mt tRNAs do fold into cloverleaf structures with mostly classical features. However, deviations exist and concern large variations in size of the D- and T-loops. The predominant absence of the conserved nucleotides G18G19 and T54T55C56, respectively in these loops, suggests that classical tertiary interactions between both domains do not take place. Classification of the tRNA sequences according to their genomic origin (G-rich or G-poor DNA strand) highlight specific features such as richness/poorness in mismatches or G-T pairs in stems and extremely low G-content or C-content in the D- and T-loops. The resulting 22 "typical" mammalian mitochondrial sequences built up a phylogenetic basis for experimental structural and functional investigations. Moreover, they are expected to help in the evaluation of the possible impacts of those point mutations detected in human mitochondrial tRNA genes and correlated with pathologies.

The complete sequence of the mitochondrial genome of the crustacean Penaeus monodon: are malacostracan crustaceans more closely related to insects than to branchiopods?

The complete sequence of the mitochondrial genome of the giant tiger prawn, Penaeus monodon (Arthropoda, Crustacea, Malacostraca), is presented. The gene content and gene order are identical to those observed in Drosophila yakuba. The overall AT composition is lower than that observed in the known insect mitochondrial genomes, but higher than that observed in the other two crustaceans for which complete mitochondrial sequence is available. Analysis of the effect of nucleotide bias on codon composition across the Arthropoda reveals a trend with the crustaceans represented showing the lowest proportion of AT-rich codons in mitochondrial protein genes. Phylogenetic analysis among arthropods using concatenated protein-coding sequences provides further support for the possibility that Crustacea are paraphyletic. Furthermore, in contrast to data from the nuclear gene EF1alpha, the first complete sequence of a malacostracan mitochondrial genome supports the possibility that Malacostraca are more closely related to Insecta than to Branchiopoda.

The complete mitochondrial DNA sequence of the horseshoe crab Limulus polyphemus

We determined the complete 14,985-nt sequence of the mitochondrial DNA of the horseshoe crab Limulus polyphemus (Arthropoda: Xiphosura). This mtDNA encodes the 13 protein, 2 rRNA, and 22 tRNA genes typical for metazoans. The arrangement of these genes and about half of the sequence was reported previously; however, the sequence contained a large number of errors, which are corrected here. The two strands of Limulus mtDNA have significantly different nucleotide compositions. The strand encoding most mitochondrial proteins has 1. 25 times as many A's as T's and 2.33 times as many C's as G's. This nucleotide bias correlates with the biases in amino acid content and synonymous codon usage in proteins encoded by different strands and with the number of non-Watson-Crick base pairs in the stem regions of encoded tRNAs. The sizes of most mitochondrial protein genes in Limulus are either identical to or slightly smaller than those of their Drosophila counterparts. The usage of the initiation and termination codons in these genes seems to follow patterns that are conserved among most arthropod and some other metazoan mitochondrial genomes. The noncoding region of Limulus mtDNA contains a potential stem-loop structure, and we found a similar structure in the noncoding region of the published mtDNA of the prostriate tick Ixodes hexagonus. A simulation study was designed to evaluate the significance of these secondary structures; it revealed that they are statistically significant. No significant, comparable structure can be identified for the metastriate ticks Rhipicephalus sanguineus and Boophilus microplus. The latter two animals also share a mitochondrial gene rearrangement and an unusual structure of mt-tRNA(C) that is exactly the same association of changes as previously reported for a group of lizards. This suggests that the changes observed are not independent and that the stem-loop structure found in the noncoding regions of Limulus and Ixodes mtDNA may play the same role as that between trnN and trnC in vertebrates, i.e., the role of lagging strand origin of replication.

Eukaryotic selenocysteine tRNA has the 9/4 secondary structure

There are two secondary structure models for the eukaryotic selenocysteine (Sec) tRNA(Sec). One model, the 9/4 structure, was experimentally tested and possesses acceptor and T-stems with 9 and 4 bp, respectively [Sturchler et al., 1993; Hubert et al., 1998]. The other one, the 7/5 secondary structure with a bulge in the T-stem, was derived from theoretical calculation [Ioudovitch and Steinberg, 19991. In this report, we show more experimental results supporting the 9/4 secondary structure. Several tRNA(Sec) mutants, whose secondary structure can adopt only the 9/4 structure, were active for serylation and selenylation. Some mutants that cannot base-pair between positions 26 and 44 to provide the 6 bp anticodon stem were still active, inconsistent with the model by Steinberg. We also show that the orientation of the V-arm directly or indirectly influences the selenylation activity, and that the rigid 6 bp D-stem is important. Finally, we conclude that all tRNA(Sec) possess the 13 bp domain II made by the stacking of the colinear AA and T-stems, whether they present the 9/4 structure in Eukarya and Archaea or the 8/5 structure in bacteria.

Codon reading patterns in Drosophila melanogaster mitochondria based on their tRNA sequences: a unique wobble rule in animal mitochondria

Mitochondrial (mt) tRNA(Trp), tRNA(Ile), tRNA(Met), tRNA(Ser)GCU, tRNA(Asn)and tRNA(Lys)were purified from Drosophila melanogaster (fruit fly) and their nucleotide sequences were determined. tRNA(Lys)corresponding to both AAA and AAG lysine codons was found to contain the anticodon CUU, C34 at the wobble position being unmodified. tRNA(Met)corresponding to both AUA and AUG methionine codons was found to contain 5-formylcytidine (f(5)C) at the wobble position, although the extent of modification is partial. These results suggest that both C and f(5)C as the wobble bases at the anticodon first position (position 34) can recognize A at the codon third position (position 3) in the fruit fly mt translation system. tRNA(Ser)GCU corresponding to AGU, AGC and AGA serine codons was found to contain unmodified G at the anticodon wobble position, suggesting the utilization of an unconventional G34-A3 base pair during translation. When these tRNA anticodon sequences are compared with those of other animal counterparts, it is concluded that either unmodified C or G at the wobble position can recognize A at the codon third position and that modification from A to t(6)A at position 37, 3'-adjacent to the anticodon, seems to be important for tRNA possessing C34 to recognize A3 in the mRNA in the fruit fly mt translation system.

Structural compensation in an archaeal selenocysteine transfer RNA

A new type of structural compensation between the lengths of two perpendicularly oriented RNA double helices was found in the archaeal selenocysteine tRNA from Methanococcus jannascii. This tRNA contains only four base-pairs in the T-stem, one base-pair less than in all other cytosolic tRNAs. Our analysis shows that such a T-stem in an otherwise normal tRNA cannot guarantee the formation of the normal interactions between the D and T-loops. The absence of these interactions would affect the juxtaposition of the two tRNA helical domains, potentially damaging the tRNA function. In addition to the short T-stem, this tRNA possesses another unprecedented feature, a very long D-stem consisting of seven base-pairs. Taken as such, a seven base-pair D-stem will also disrupt the normal interaction between the D and T-loops. On the other hand, the presence of the universal nucleotides in both the D and T-loops suggests that these loops probably interact with each other in the same way as in other tRNAs. Here, we demonstrate that the short T-stem and the long D-stem can naturally compensate each other, thus providing the normal D/T interactions. Molecular modeling has helped suggest a detailed scheme of mutual compensation between these two unique structural aspects of the archaeal selenocysteine tRNA. In the light of this analysis, other structural and functional characteristics of the selenocysteine tRNAs are discussed.

The novel mitochondrial gene arrangement of the cattle tick, Boophilus microplus: fivefold tandem repetition of a coding region

We sequenced across all of the gene boundaries in the mitochondrial genome of the cattle tick, Boophilus microplus, to determine the arrangement of its genes. The mtDNA of B. microplus has a coding region, composed of tRNA(Glu) and 60 bp of the 3' end of ND1, that is repeated five times. Boophilus microplus is the first coelomate animal known to have more than two copies of a coding sequence. The mitochondrial genome of B. microplus has other unusual features, including (1) reduced T arms in tRNAs, (2) an AT bias in codon use, (3) two control regions that have evolved in concert, (4) three gene rearrangements, and (5) a stem-loop between tRNA(Gln) and tRNA(Phe). The short T arms and small control regions (CRs) of B. microplus and other ticks suggest strong selection for small genomes. Imprecise termination of replication beyond its origin, which can account for the evolution of tandem repeats of coding regions in other mitochondrial genomes, cannot explain the evolution of the fivefold repeated sequence in the mitochondrial genome of B. microplus. Instead, slipped-strand mispairing or recombination are the most plausible explanations for the evolution of these tandem repeats.

Selenocysteine inserting tRNAs: an overview

One of the recent discoveries in protein biosynthesis was the finding that selenocysteine, the 21st amino acid, is cotranslationally inserted into polypeptides under the direction of a UGA codon assisted by a specific structural signal in the mRNA. The key to selenocysteine biosynthesis and insertion is a special tRNA species, tRNA(Sec). The formation of selenocysteine from serine represents an interesting tRNA-mediated amino acid transformation. tRNA(Sec) (or the gene encoding it) has been found over all three domains of life. It displays a number of unique features that designate it a selenocysteine-inserting tRNA and differentiate it from canonical elongator tRNAs. Although there are still some uncertainties concerning the precise secondary and tertiary structures of eukaryal tRNA(Sec), the major identity determinant for selenocysteine biosynthesis and insertion appears to be the 13 bp long extended acceptor arm. In addition the core of the 3D structure of these tRNAs is different from that of class II tRNAs like tRNA(Sec). The biological implications of these structural differences still remain to be fully understood.

Two novel point mutations of mitochondrial tRNA genes in histologically confirmed Parkinson disease

Mutations in mitochondrially encoded tRNA genes have been described in a variety of neurological disorders. One such mutation, the A to G transition at nucleotide position 4336 of the mitochondrial tRNA(Gln) gene, has been associated with both Alzheimer and Parkinson disease. We have now performed a complete sequence analysis of all 22 mitochondrially encoded tRNA genes in 20 cases of histologically proven idiopathic Parkinson disease. Genomic DNA extracted from the substantia nigra of frozen or formalin-fixed and paraffin-embedded brains was used for amplification by polymerase chain reaction followed by automated sequencing. Two new homoplasmic point mutations were detected in the genes for tRNA(Thr) (15950 G/A) and tRNA(Pro) (15965 T/C) in 1 patient each. Restriction enzyme digestion revealed absence of the 15950 G/A mutation in 96 controls and in 40 cases of neuropathologically confirmed Alzheimer disease. The 15965 T/C mutation was shown to be absent from 100 control subjects and 47 Alzheimer cases. In addition to the two novel mutations, six known sequence variants were detected in a total of 6 different patients in the genes for tRNA(Asp) (G7521A, 1), tRNA(Arg) (T10463C, 1), tRNA(LeuCUN) (A12308G, 2), and tRNA(Thr) (A15924G, 1; G15928A, 2), including 1 patient carrying the tRNA(Gln) (A4336G) mutation. The G15950A transition affects position 70 of the aminoacyl acceptor stem of tRNA(Thr), which has been implicated as a recognition element for threonyl-tRNA synthetase and, at least in some tRNAs, in the processing of primary mitochondrial transcripts. The T15965C point mutation in the mitochondrial tRNA(Pro) gene alters position 64 of the TpsiC stem. The corresponding nucleotide in bacterial aminoacyl-tRNAs is involved in the interaction with elongation factor Tu. Thus, the two novel mutations are likely to be of functional relevance and could contribute to dopaminergic nerve cell death in affected individuals.

A cytotoxic ribonuclease targeting specific transfer RNA anticodons

The carboxyl-terminal domain of colicin E5 was shown to inhibit protein synthesis of Escherichia coli. Its target, as revealed through in vivo and in vitro experiments, was not ribosomes as in the case of E3, but the transfer RNAs (tRNAs) for Tyr, His, Asn, and Asp, which contain a modified base, queuine, at the wobble position of each anticodon. The E5 carboxyl-terminal domain hydrolyzed these tRNAs just on the 3' side of this nucleotide. Tight correlation was observed between the toxicity of E5 and the cleavage of intracellular tRNAs of this group, implying that these tRNAs are the primary targets of colicin E5.

Crystallization and X-ray diffraction data of a tRNASec acceptor-stem helix

tRNASec is a UGA suppressor tRNA which co-translationally inserts selenocysteine into proteins. Its eight-base-pair tRNASec acceptor stem, which contains key recognition elements, was synthesized using solid-phase phosphoramidite RNA chemistry. High-resolution X-ray diffraction data were collected using synchrotron radiation under cryogenic cooling conditions. The crystals diffract to a maximal resolution of 1.8 A. X-ray diffraction data were processed to 2.4 A. tRNASec microhelix crystallizes in space group R32, with cell constants a = 47.02, b = 47.02, c = 373.03 A, alpha = beta = 90, gamma = 120 degrees. The crystals contain three RNA molecules per asymmetric unit.

Processing and editing of overlapping tRNAs in human mitochondria

Overlapping tRNA genes in mitochondria of many metazoans introduce a problem for the processing of such polycistronic primary transcripts. Using runoff transcripts and an S100 extract from HeLa cell mitochondria, the processing of the human mitochondrial tRNATyr/tRNACys precursor (carrying an overlap of one base) was investigated: tRNACys is released in its complete form carrying the overlapping residue at the first position, whereas tRNATyr lacks that nucleotide at the discriminator position. Partial deletion of tRNACys or complete replacement by a non-tRNA-like sequence does not alter the processing reaction and indicates that the upstream tRNATyr alone is recognized by a 3'-endonuclease activity. The truncated 3'-end of this tRNATyr is then completed in an editing reaction that incorporates the missing residue. The processing of this tRNA overlap seems to be species-specific, because an overlapping tRNA precursor (tRNASer(AGY)/tRNALeu(CUN)) from opossum mitochondria is not recognized by the human extract. Because processing activities for overlapping and nonoverlapping tRNA precursors could not be separated, it seems that one general activity is responsible for the 3'-end processing of mitochondrial tRNAs and that this activity coevolved with the particular overlap between tRNATyr and tRNACys in human mitochondria, being unable to recognize overlaps between other tRNAs.

The dual identities of mammalian tRNA(Sec) for SerRS and selenocysteine synthase

Se is an essential trace element and is found as a selenocysteine in the active site of Se-enzymes, such as glutathione peroxidase. tRNASec is first aminoacylated with serine by Ser RS and further is converted to selenocysteyl-tRNA by selenocysteine synthase. Mammalian selenocysteine tRNA has dual identities with Ser RS and selenocysteine synthase. Key identity elements for selenocysteine synthase are the long 9 bp AA- and long 6 bp D-stems. Major serine tRNA was converted to a mutant with a 9 bp AA-stem and 6 bp D-stem, instead of a 7 bp AA-stem and 3 bp D-stem. This mutant was active for selenylation as well as serylation. The relative kinetic parameter (Vmax/Km) of the mutant was 0.052 of the value (1.00) of wild-type Sec tRNA. This low value suggests that there is an unknown fine base specific for selenocysteine synthase. For serylation, mutant having 12 bp and wild type tRNASec having 13 bp of the total length of AA- + T-stems were active but the mutants having 11 or 14 bp were inactive. This shows that SerRS measures the distance between the discrimination base and long extra arm for recognition of tRNASer.

A G.U base pair in the eukaryotic selenocysteine tRNA is important for interaction with SePF, the putative selenocysteine-specific elongation factor

In Escherichia coli, selenocysteine biosynthesis and incorporation into selenoproteins requires the action of four gene products, including the specialized selenocysteine tRNA(Sec) and elongation factor SELB, different from the universal EF-Tu. In this regard, the situation is less clear in eukaryotes, but we previously reported the existence of SePF, a putative SELB homologue. The secondary structure of the tRNA(Sec) differs slightly in eukaryotes, due to a change in the lengths of several stems. Two non-Watson-Crick base pairs, G5a x U67b and U6 x U67, reside in the acceptor stem and are conserved in the course of evolution. Since it has already been reported that changing them to Watson-Crick base pairs did not affect the serylation or selenylation levels of tRNA(Sec), we asked whether these non-Watson-Crick base pairs are required for the interaction with SePF. To this end, tRNA(Sec) variants carrying Watson-Crick changes at these positions were tested for their ability to maintain the interaction with SePF. In these assays, the tRNA(Sec)-SePF interaction was determined by the protective action it confers against hydrolysis of the amino acid ester bond, under basic conditions. All the changes introduced at U6 x U67 did not significantly affect the interaction. Interestingly, however, the G5a x U67b to G5a-C67b substitution was sufficient, by itself, to lead to unprotection of the ester bond. Therefore, our finding strongly suggests that SePF is unable to interact with a tRNA(Sec) mutant version carrying a Watson-Crick G5a-C67b instead of the wild-type G5a x U67b base pair, establishing that G5a x U67b constitutes a structural determinant for SePF interaction.

Ribosomal tRNA binding sites: three-site models of translation

The first models of translation described protein synthesis in terms of two operationally defined tRNA binding sites, the P-site for the donor substrate, the peptidyl-tRNA, and the A-site for the acceptor substrates, the aminoacyl-tRNAs. The discovery and analysis of the third tRNA binding site, the E-site specific for deacylated tRNAs, resulted in the allosteric three-site model, the two major features of which are (1) the reciprocal relationship of A-site and E-site occupation, and (2) simultaneous codon-anticodon interactions of both tRNAs present at the elongating ribosome. However, structural studies do not support the three operationally defined sites in a simple fashion as three topographically fixed entities, thus leading to new concepts of tRNA binding and movement: (1) the hybrid-site model describes the tRNAs' movement through the ribosome in terms of changing binding sites on the 30S and 50S subunits in an alternating fashion. The tRNAs thereby pass through hybrid binding states. (2) The alpha-epsilon model introduces the concept of a movable tRNA-binding domain comprising two binding sites, termed alpha and epsilon. The translocation movement is seen as a result of a conformational change of the ribosome rather than as a diffusion process between fixed binding sites. The alpha-epsilon model reconciles most of the experimental data currently available.

Minimal tRNA(Ser) and tRNA(Sec) substrates for human seryl-tRNA synthetase: contribution of tRNA domains to serylation and tertiary structure

The recognition process of tRNA(Ser) and tRNA(Sec) by human seryl-tRNA synthetase (SerRS) was studied using T7 transcripts representing defined regions of human tRNA(Ser) or tRNA(Sec) and the influence of the tRNA elements on serylation and tertiary structure was elucidated. The anticodon arms of both tRNAs showed no contribution to serylation in contrast to the acceptor stems and the long extra arms. D and T arms were only involved in formation of the L-shaped tRNA structure, not in the recognition process between tRNAs and SerRS. This is the first report of microhelices adapted from human tRNAs being aminoacylated by their homologous synthetase.

Modeling the tertiary interactions in the eukaryotic selenocysteine tRNA

A novel three-dimensional model of tertiary interactions in the core region of the eukaryotic selenocysteine tRNA is proposed based on the analysis of available nucleotide sequences. The model features the 7/5 tRNA(Sec) secondary structure characterized by seven and five base pairs in the acceptor and T-stems, respectively, and four nucleotides in the connector region between the acceptor and D-stems. The model suggests a unique system of tertiary interactions in the area between the major groove of the D-stem and the first base pair of the extra arm that provides a rigid orientation of the extra arm and contributes to the overall stability of the molecule. The model is consistent with available experimental data on serylation, selenylation, and phosphorylation of different tRNA(Sec) mutants. The important similarity between the proposed model and the structure of the tRNA(Ser) is shown. Based on this similarity, the ability of some tRNA(Ser) mutants to be serylated, selenylated, and phosphorylated was evaluated and found to be in a good agreement with experimental data.