TΨC Arm Research Articles

RNA-binding Site of Escherichia coli Peptidyl-tRNA Hydrolase

In a cell, peptidyl-tRNA molecules that have prematurely dissociated from ribosomes need to be recycled. This work is achieved by an enzyme called peptidyl-tRNA hydrolase. To characterize the RNA-binding site of Escherichia coli peptidyl-tRNA hydrolase, minimalist substrates inspired from tRNA(His) have been designed and produced. Two minisubstrates consist of an N-blocked histidylated RNA minihelix or a small RNA duplex mimicking the acceptor and TψC stem regions of tRNA(His). Catalytic efficiency of the hydrolase toward these two substrates is reduced by factors of 2 and 6, respectively, if compared with N-acetyl-histidyl-tRNA(His). In contrast, with an N-blocked histidylated microhelix or a tetraloop missing the TψC arm, efficiency of the hydrolase is reduced 20-fold. NMR mapping of complex formation between the hydrolase and the small RNA duplex indicates amino acid residues sensitive to RNA binding in the following: (i) the enzyme active site region; (ii) the helix-loop covering the active site; (iii) the region including Leu-95 and the bordering residues 111-117, supposed to form the boundary between the tRNA core and the peptidyl-CCA moiety-binding sites; (iv) the region including Lys-105 and Arg-133, two residues that are considered able to clamp the 5'-phosphate of tRNA, and (v) the positively charged C-terminal helix (residues 180-193). Functional value of these interactions is assessed taking into account the catalytic properties of various engineered protein variants, including one in which the C-terminal helix was simply subtracted. A strong role of Lys-182 in helix binding to the substrate is indicated.

17-alpha-hydroxylase deficiency and mitochondrial variant A8343G

Purpose17α-Hydroxylase deficiency (17OHD) is a rare type of secondary hypertension and well-known as a group of autosomal recessive disorders of adrenal steroidogenesis caused by a genetic disorder in one of...

Analysis of the complete mitochondrial genome sequence of Pielomastax zhengi

The complete mitochondrial genome sequence of Pielomastax zhengi was determined by using long PCR and conserved primer walking approaches. The results showed that the entire mitochondrial genome of Pielomastax zhengi is 15 602 bp long with A+T content of 71.8%. All 37 genes are conserved in the positions observed in those of Locusta migratoria. All the genes are closely assembled by leaving 10 intergenic spacers in between. Those intergenic spacers are 47 bp in total (excluding the A+T rich region), with individual size ranges from 1 bp to 20 bp. In addition, there are a total of 52 bp overlapping sequences among 14 genes, ranging from 1-8 bp. All protein-coding genes start with a typical initiation codon in insects, ATN. Twelve protein-coding genes use the usual TAA and TAG termination codons, whereas, the ND5 genes have an incomplete termination codon (T). Except the tRNASer (AGN), whose DHU arm is absent; all the other 21 tRNA genes have typical clover-leaf secondary structures. But in Pielomastax zhengi, the secondary structures of five tRNA (tRNA(Cys), tRNA(Lys), tRNA(Phe), tRNA(Pro), tRNA(Arg)) genes can not be predicted by the conventional methods as they have only 3-4, rather than 5 base pairs in the TψC arm, while, the tRNA(Lys) and tRNA(Arg) have only 4 base pairs in the anticode arm. The predicted secondary structures of lrRNA and srRNA have 6 domains with 44 helices and 3 domains with 30 helices, respectively. The results of the rRNA secondary structure comparison showed that Pielomastax zhengi is more closely related with Locusta migratoria tibetensis than Ruspolia dubia. Like most insects, the mitochondrial genome of Pielomastax zhengi has a non-coding A+T rich region containing a polythymidine stretch, which may be involved in the replication and/or translation initiation of other genes.

Extensive and Evolutionarily Persistent Mitochondrial tRNA Editing in Velvet Worms (Phylum Onychophora)

Mitochondrial genomes of onychophorans (velvet worms) present an interesting problem: Some previous studies reported them lacking several transfer RNA (tRNA) genes, whereas others found that all their tRNA genes were present but severely reduced. To resolve this discrepancy, we determined complete mitochondrial DNA (mtDNA) sequences of the onychophorans Oroperipatus sp. and Peripatoides sympatrica as well as cDNA sequences from 14 and 10 of their tRNAs, respectively. We show that tRNA genes in these genomes are indeed highly reduced and encode truncated molecules, which are restored to more conventional structures by extensive tRNA editing. During this editing process, up to 34 nucleotides are added to the tRNA sequences encoded in Oroperipatus sp. mtDNA, rebuilding the aminoacyl acceptor stem, the TΨC arm, and in some extreme cases, the variable arm and even a part of the anticodon stem. The editing is less extreme in P. sympatrica in which at least a part of the TΨC arm is always encoded in mtDNA. When the entire TΨC arm is added de novo in Oroperipatus sp., the sequence of this arm is either identical or similar among different tRNA species, yet the sequences show substantial variation for each tRNA. These observations suggest that the arm is rebuilt, at least in part, by a template-independent mechanism and argue against the alternative possibility that tRNA genes or their parts are imported from the nucleus. By contrast, the 3' end of the aminoacyl acceptor stem is likely restored by a template-dependent mechanism. The extreme tRNA editing reported here has been preserved for >140 My as it was found in both extant families of onychophorans. Furthermore, a similar type of tRNA editing may be present in several other groups of arthropods, which show a high degree of tRNA gene reduction in their mtDNA.

The complete mitochondrial DNA sequence and the phylogenetic position of Achalinus meiguensis (Reptilia: Squamata)

The mitochondrial genome complete sequence of Achalinus meiguensis was reported for the first time in the present study. The complete mitochondrial genome of A. meiguensis is 17239 bp in length and contains 13 protein-coding genes, 22 tRNA, 2 rRNA, and 2 non-coding regions (Control regions). On the basis of comparison with the other complete mitochondrial sequences reported, we explored the characteristic of structure and evolution. For example, duplication control regions independently occurred in the evolutionary history of reptiles; the pseudo-tRNA of snakes occurred in the Caenophidia; snake is shorter than other vertebrates in the length of tRNA because of the truncations of TψC arm (less than 5 bp) and “DHU“ arm. The phylogenic analysis by MP and BI analysis showed that the phylogenetic position of A. meiguensis was placed in Caenophidia as a sister group to other advanced snakes with the exclusion of Acrochordus granulatus which was rooted in the Caenophidia. Therefore we suggested that the subfamily Xenodermatinae, which contains A. meiguensis, should be raised to a family rank or higher rank. At the same time, based on the phylogenic statistic test, the tree of Bayesian was used for estimating the divergence time. The results showed that the divergence time between Henophidia and Caenophidia was 109.50 Mya; 106.18 Mya for divergence between Acrochordus granulatus and the other snakes of the Caenophidia; the divergence time of A. meiguensis was 103 Mya, and Viperidae diverged from the unilateral of Elapidae and Colubridae was 96.06 Mya.

The mitochondrial genome of the predatory mite Metaseiulus occidentalis (Arthropoda: Chelicerata: Acari: Phytoseiidae) is unexpectedly large and contains several novel features

The complete mitochondrial genome of the phytoseiid Metaseiulus occidentalis (Arthropoda: Chelicerata: Acari: Phytoseiidae) has been sequenced. It is 24,961 bp in length and contains a 14,695-bp unique region, a 345-bp triplicated region, and a 9921-bp duplicated region, in that order. The A+T content of the unique region is 76.9% and contains 11 protein coding ( COI–III; ATP6–8; CytB; ND1, 2, 4, 5 and 4L), two ribosomal RNA ( srRNA and lrRNA), 22 transfer RNA ( tRNA) genes, and two copies of D-loop control sequence. Two genes ( ND3 and 6) appear to be missing, but there is a large intergenic spacer (390 bp) present, which could contain ND3 if a different codon usage is employed. The gene order is completely different from the pattern in all other known chelicerates, including the horseshoe crab Limulus polyphemus [Lavrov et al., Mol. Biol. Evol., 2000; 17:813–824]. All the inferred tRNA genes are missing the TΨC arm, but this arm has fused with the variable arm to generate a TV replacement loop. The duplicated region (9921 bp) contains 18 genes in the same order as in the unique region from CytB to tRNA-His, plus one copy of D-loop control sequence (311 bp) and a partial tRNA-Leu2 sequence (34 bp). The small triplicated region (345 bp) contains a D-loop control sequence (311 bp) and a partial tRNA-Leu2 sequence (34 bp). Because of these anomalies, amplifying sequences posed technical difficulties, but were accomplished by using a primer-walking strategy and increasing the AT content to 75% in the high-fidelity PCR dNTP mix. This is the first phytoseiid mitochondrial genome to be completely sequenced and the largest (25 kb) detected from the Chelicerata.

The mitochondrial genome ofGyrodactylus salaris(Platyhelminthes: Monogenea), a pathogen of Atlantic salmon (Salmo salar)

In the present study, we describe the complete mitochondrial (mt) genome of the Atlantic salmon parasite Gyrodactylus salaris, the first for any monogenean species. The circular genome is 14,790 bp in size. All of the 35 genes recognized from other flatworm mitochondrial genomes were identified, and they are transcribed from the same strand. The protein-coding and ribosomal RNA (rRNA) genes share the same gene arrangement as those published previously for neodermatan mt genomes (representing cestodes and digeneans only), and the genome has an overall A+T content of 65%. Three transfer RNA (tRNA) genes overlap with other genes, whereas the secondary structure of 3 tRNA genes lack the DHU arm and 1 tRNA gene lacks the TphiC arm. Eighteen regions of non-coding DNA ranging from 4 to 112 bp in length, totalling 278 bp, were identified as well as 2 large non-coding regions (799 bp and 768 bp) that were almost identical to each other. The completion of the mt genome offers the opportunity of defining new molecular markers for studying evolutionary relationships within and among gyrodactylid species.

The tRNA primer activation signal in the human immunodeficiency virus type 1 genome is important for initiation and processive elongation of reverse transcription.

Human immunodeficiency virus type 1 (HIV-1) reverse transcription is primed by the cellular tRNA(3)(Lys) molecule, which binds, with its 3"-terminal 18 nucleotides (nt), to a complementary sequence in the viral genome, the primer-binding site (PBS). Besides PBS-anti-PBS pairing, additional interactions between viral RNA sequences and the tRNA primer are thought to regulate the process of reverse transcription. We previously identified a novel 8-nt sequence motif in the U5 region of the HIV-1 RNA genome that is critical for tRNA(3)(Lys)-mediated initiation of reverse transcription in vitro. This motif activates initiation from the natural tRNA(3)(Lys) primer but is not involved in tRNA placement and was therefore termed primer activation signal (PAS). It was proposed that the PAS interacts with the anti-PAS motif in the TphiC arm of tRNA(3)(Lys). In this study, we analyzed several PAS-mutated viruses and performed reverse transcription assays with virion-extracted RNA-tRNA complexes. Mutation of the PAS reduced the efficiency of tRNA-primed reverse transcription. In contrast, mutations in the opposing leader sequence that trigger release of the PAS from base pairing stimulated reverse transcription. These results are similar to the reverse transcription effects observed in vitro. We also selected revertant viruses that partially overcome the reverse transcription defect of the PAS deletion mutant. Remarkably, all revertants acquired a single nucleotide substitution that does not restore the PAS sequence but that stimulates elongation of reverse transcription. These combined results indicate that the additional PAS-anti-PAS interaction is needed to assemble an initiation-competent and processive reverse transcription complex.

Trichinella spiralis mtDNA: A Nematode Mitochondrial Genome That Encodes a Putative ATP8 and Normally Structured tRNAs and Has a Gene Arrangement Relatable to Those of Coelomate Metazoans

The complete mitochondrial DNA (mtDNA) of the nematode Trichinella spiralis has been amplified in four overlapping fragments and 16,656 bp of its sequence has been determined. This sequence contains the 37 genes typical of metazoan mtDNAs, including a putative atp8, which is absent from all other nematode mtDNAs examined. The genes are transcribed from both mtDNA strands and have an arrangement relatable to those of coelomate metazoans, but not to those of secernentean nematodes. All protein genes appear to initiate with ATN codons, typical for metazoans. Neither TTG nor GTT start codons, inferred for several genes of other nematodes, were found. The 22 T. spiralis tRNA genes fall into three categories: (i) those with the potential to form conventional "cloverleaf" secondary structures, (ii) those with TPsiC arm + variable arm replacement loops, and (iii) those with DHU-arm replacement loops. Mt-tRNA(R) has a 5'-UCG-3' anticodon, as in most other metazoans, instead of the very unusual 5'-ACG-3' present in the secernentean nematodes. The sequence also contains a large repeat region that is polymorphic in size at the population and/or individual level.

A Molecular Framework for the Phylogeny of the Ant Subfamily Dolichoderinae

Partial sequences are reported for the mitochondrial genes for cytochrome oxidase subunits 2 and 3 and for cytochrome b, and the entire sequence of the gene for tRNALeuUUR for species from 14 genera of dolichoderine ants and from three outgroup genera. Considerable variation was observed between tRNA genes in the size of the TΨC arm and the DHU and anticodon loops and whether or not the TΨC stem possesses a GC pair. The outgroup taxa showed complete TAA CO1 stop codons, but dolichoderines have either TA or T. The outgroup taxa showed a noncoding gap between the CO1 and the tRNALeuUUR genes. A phylogeny-independent compatibility test using the amino acid sequences showed differences between the genes consistent with variation in evolutionary rates, according with other studies. Base compositions proved heterogeneous between species, hence phylogenetic analysis was restricted to the protein sequences using maximum likelihood and the mtREV24 replacement matrix. A maximum-likelihood consensus tree has similarities to those from morphological studies with some exceptions such Leptomyrmex falling within the dolichoderine genera rather than basally, and the accretion of genera formerly included under Iridomyrmex. Features of the tRNA genes and the CO1 termination codons agree quite well with the molecular phylogeny.

The crystal structure of yeast phenylalanine tRNA at 2.0 Å resolution: cleavage by Mg2+ in 15-year old crystals

We have re-determined the crystal structure of yeast tRNAPhe to 2.0 Å resolution using 15 year old crystals. The accuracy of the new structure, due both to higher resolution data and formerly unavailable refinement methods, consolidates the previous structural information, but also reveals novel details. In particular, the water structure around the tightly bound Mg2+ is now clearly resolved, and hence provides more accurate information on the geometry of the magnesium-binding sites and the role of water molecules in coordinating the metal ions to the tRNA. We have assigned a total of ten magnesium ions and identified a partly conserved geometry for high-affinity Mg2+ binding. In the electron density map there is also clear density for a spermine molecule binding in the major groove of the TΨC arm and also contacting a symmetry-related tRNA molecule. Interestingly, we have also found that two specific regions of the tRNA in the crystals are partially cleaved. The sites of hydrolysis are within the D and anticodon loops in the vicinity of Mg2+.

Mitochondrial sequence evolution in spiders: intraspecific variation in tRNAs lacking the TPsiC Arm.

Analyses of mitochondrial DNA sequences from three species of Habronattus jumping spiders (Chelicerata: Arachnida: Araneae) reveal unusual inferred tRNA secondary structures and gene arrangements, providing new information on tRNA evolution within chelicerate arthropods. Sequences from the protein-coding genes NADH dehydrogenase subunit 1 (ND1), cytochrome oxidase subunit I (COI), and subunit II (COII) were obtained, along with tRNA, tRNA, and large-subunit ribosomal RNA (16S) sequences; these revealed several peculiar features. First, inferred secondary structures of tRNA and, likely, tRNA, lack the TPsiC arm and the variable arm and therefore do not form standard cloverleaf structures. In place of these arms is a 5-6-nt T arm-variable loop (TV) replacement loop such as that originally described from nematode mitochondrial tRNAs. Intraspecific variation occurs in the acceptor stem sequences in both tRNAs. Second, while the proposed secondary structure of the 3' end of 16S is similar to that reported for insects, the sequence at the 5' end is extremely divergent, and the entire gene is truncated about 300 nt with respect to Drosophila yakuba. Third, initiation codons appear to consist of ATY (ATT and ATC) and TTG for ND1 and COII, respectively. Finally, Habronattus shares the same ND1-tRNA-16S gene arrangement as insects and crustaceans, thus illustrating variation in a tRNA gene arrangement previously proposed as a character distinguishing chelicerates from insects and crustaceans.

The complete nucleotide sequence of a snake (Dinodon semicarinatus) mitochondrial genome with two identical control regions.

The 17,191-bp mitochondrial DNA (mtDNA) of a Japanese colubrid snake, akamata (Dinodon semicarinatus), was cloned and sequenced. The snake mtDNA has some peculiar features that were found in our previous study using polymerase chain reaction: duplicate control regions that have completely identical sequences over 1 kbp, translocation of tRNALeu(UUR) gene, shortened TpsiC arm for most tRNA genes, and a pseudogene for tRNAPro. Phylogenetic analysis of amino acid sequences of protein genes suggested an unusually high rate of molecular evolution in the snake compared to other vertebrates. Southern hybridization experiments using mtDNAs purified from multiple akamata individuals showed that the duplicate state of the control region is not a transient or unstable feature found in a particular individual, but that it stably occurs in mitochondrial genomes of the species. This may, therefore, be regarded as an unprecedented example of stable functional redundancy in animal mtDNA. However, some of the examined individuals contain a rather scanty proportion of heteroplasmic mtDNAs with an organization of genes distinct from that of the major mtDNA. The gene organization of the minor mtDNA is in agreement with one of models that we present to account for the concerted evolution of duplicate control regions.

Nucleotide correlations that suggest tertiary interactions in the TV-replacement loop-containing mitochondrial tRNAs of the nematodes, Caenorhabditis elegans and Ascaris suum.

In the predicted secondary structures of 20 of the 22 tRNAs encoded in mitochondrial DNA (mtDNA) molecules of the nematodes, Caenorhabditis elegans and Ascaris suum, the T psi C arm and variable loop are replaced with a loop of 6 to 12 nucleotides: the TV-replacement loop. From considerations of patterns of nucleotide correlations in the central regions of these tRNAs, it seems highly likely that tertiary interactions occur within five sets of binary and ternary combinations of nucleotides that correspond in location to nucleotides known to be involved in tertiary interactions in yeast tRNA(Phe) and other standard tRNAs. These observations are consistent with the nematode TV-replacement loop-containing mt-tRNAs being folded into a similar L-shaped functional form to that demonstrated for standard tRNAs, and for the bovine DHU (dihydrouridine) arm replacement-loop-containing mt-tRNA(Ser(AGY)). However, the apparent occurrence in nematode mt-tRNAs of tertiary bonds common to standard tRNAs contrasts with the situation in bovine mt-tRNA(Ser(AGY)) where the functional form is dependent on an almost unique set of tertiary interactions. Because three of the proposed conserved tertiary interactions in the nematode mt-tRNAs involve nucleotides that occur in the variable loop in standard tRNAs, it seems more likely that in nematode mt-tRNAs it is the T psi C arm rather than the variable loop that has undergone the greatest proportional decrease in nucleotide number.

Secondary structure at the 3′ terminal region of RNA coliphages: Comparison with tRNA

Secondary structure models for the 3′ non-coding region of the four groups of coliphage RNA are proposed based on comparative sequence analysis and on previously published data on the sensitivity of nucleotides in MS2 RNA to chemical modification and enzymes. We report the following observations. (1) In contrast to the coding regions, the structure at the 3′ terminus is characterized by stable regular helices. We note the occurrence of the loop sequences 5′-GUUCGC and 5′-CGAAAG, that are reported to confer exceptional stability to stem structures. These features are probably present to promote the segregation of mother and daughter strands during replication. (2) Comparison of homologous helices indicates that only those base pair substitutions are allowed that maintain the thermodynamic stability. (3) We have compared the structure of phage RNA with tRNA. Overall similarity is low, but one common element may exist. It is a quasi-continuous helix of 12 basepairs that could be the equivalent of the 12 basepair long coaxially stacked helix, formed by the TψC arm and the aminoacyl acceptor arm in tRNA. As in tRNA, this structure element starts after the fourth nucleotide from the 3′ end. (4) Phage RNA contains a large variable region of about 35 nucleotides bulging out from the quasi-continuous helix. We speculate that the variable loop in present-day tRNA could be the remnant of the variable region found in phage RNA. The variable region contains overlapping binding sites for the replicase enzyme and the maturation protein. This common binding site may serve as a switch from replication to packaging.