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1.
J Pharm Biomed Anal ; 203: 114183, 2021 Sep 05.
Article in English | MEDLINE | ID: mdl-34098507

ABSTRACT

A "toolkit" consisting of a handheld Raman spectrometer equipped with a 1064 nm laser, a portable Fourier transform infrared (FT-IR) spectrometer and a portable direct analysis in real-time mass spectrometer (DART-MS) was employed in a laboratory setting to examine 82 representative products collected during a nationwide mail blitz for the presence of APIs. These results were compared to those obtained using laboratory-based methods; 8 of the products were not found to contain APIs and 74 of the products were found to contain a total of 88 APIs (65 of the 88 APIs were unique). The individual performance of each device and combined performance of the three-device toolkit were evaluated with regard to true positives, true negatives, false positives and false negatives. Using this toolkit, 81 (92.0 %) of the APIs were detected by at least one technique and 47 (64.8 %) of the APIs were detected by at least two techniques. Seven false negatives (8.0 %) were encountered and while the toolkit yielded 12 false positives, no false positives were detected by more than one technique. Overall, this study demonstrated that when the toolkit detects an API using two or more devices, the results are as reliable as those generated by a full-service laboratory.


Subject(s)
Pharmaceutical Preparations , Postal Service , Spectroscopy, Fourier Transform Infrared
2.
J Pharm Biomed Anal ; 201: 114104, 2021 Jul 15.
Article in English | MEDLINE | ID: mdl-33964724

ABSTRACT

The development of a method for the rapid screening of food and drug products for constituents such as mitragynine, the most abundant alkaloid found in Mitragyna speciosa (kratom) plant leaves, has become increasingly important. The use of kratom is said to produce stimulant or narcotic effects and poses risks of addiction, abuse, and dependence, much like other opioids. Direct Analysis in Real Time with thermal desorption mass spectrometry (DART-TD-MS), hand-held mass spectrometry, portable ion mobility spectrometry (IMS), and portable Fourier-transform infrared spectroscopy (FT-IR) were each evaluated as field-deployable screening techniques for the detection of mitragynine in food and drug products. These devices offer the potential for rapid, early detection of mitragynine in suspect products entering the United States through international mail facilities and other ports of entry. Ninety-six kratom products, including capsules, bulk powder, and bulk plant material, were analyzed by either direct sampling of the solid material or by solvent extraction. True and false positive and negative results are reported, based on comparison to results from qualitative screening using gas chromatography with mass spectral detection (GC-MS), liquid chromatography with mass spectral detection (LC-MS), and/or quantitative screening using high-performance liquid chromatography with ultraviolet detection (HPLC-UV), with a discussion of the assessment of each technique for use in the field. Each device demonstrated attributes that would be favorable for use in screening of suspected mitragynine-containing products at places like ports of entry, and simultaneous deployment of two or more of these devices as part of a workflow would be the most effective for rapid screening of these products. This combination of rapid screening orthogonal techniques suited to a non-laboratory environment will allow onsite destruction of products found to contain mitragynine.


Subject(s)
Mitragyna , Secologanin Tryptamine Alkaloids , Gas Chromatography-Mass Spectrometry , Spectroscopy, Fourier Transform Infrared
3.
Nature ; 542(7642): 494-497, 2017 02 22.
Article in English | MEDLINE | ID: mdl-28230119

ABSTRACT

Nucleic acids undergo naturally occurring chemical modifications. Over 100 different modifications have been described and every position in the purine and pyrimidine bases can be modified; often the sugar is also modified. Despite recent progress, the mechanism for the biosynthesis of most modifications is not fully understood, owing, in part, to the difficulty associated with reconstituting enzyme activity in vitro. Whereas some modifications can be efficiently formed with purified components, others may require more intricate pathways. A model for modification interdependence, in which one modification is a prerequisite for another, potentially explains a major hindrance in reconstituting enzymatic activity in vitro. This model was prompted by the earlier discovery of tRNA cytosine-to-uridine editing in eukaryotes, a reaction that has not been recapitulated in vitro and the mechanism of which remains unknown. Here we show that cytosine 32 in the anticodon loop of Trypanosoma brucei tRNAThr is methylated to 3-methylcytosine (m3C) as a pre-requisite for C-to-U deamination. Formation of m3C in vitro requires the presence of both the T. brucei m3C methyltransferase TRM140 and the deaminase ADAT2/3. Once formed, m3C is deaminated to 3-methyluridine (m3U) by the same set of enzymes. ADAT2/3 is a highly mutagenic enzyme, but we also show that when co-expressed with the methyltransferase its mutagenicity is kept in check. This helps to explain how T. brucei escapes 'wholesale deamination' of its genome while harbouring both enzymes in the nucleus. This observation has implications for the control of another mutagenic deaminase, human AID, and provides a rationale for its regulation.


Subject(s)
Methyltransferases/metabolism , Nucleoside Deaminases/metabolism , RNA Editing , RNA, Transfer, Thr/chemistry , RNA, Transfer, Thr/metabolism , Trypanosoma brucei brucei/enzymology , Trypanosoma brucei brucei/genetics , Anticodon/metabolism , Base Sequence , Cytosine/analogs & derivatives , Cytosine/metabolism , Deamination , Methylation , RNA, Transfer, Thr/genetics , Uridine/metabolism
4.
Sci Rep ; 6: 21438, 2016 Feb 18.
Article in English | MEDLINE | ID: mdl-26888608

ABSTRACT

Most eukaryotic ribosomes contain 26/28S, 5S, and 5.8S large subunit ribosomal RNAs (LSU rRNAs) in addition to the 18S rRNA of the small subunit (SSU rRNA). However, in kinetoplastids, a group of organisms that include medically important members of the genus Trypanosoma and Leishmania, the 26/28S large subunit ribosomal RNA is uniquely composed of 6 rRNA fragments. In addition, recent studies have shown the presence of expansion segments in the large ribosomal subunit (60S) of Trypanosoma brucei. Given these differences in structure, processing and assembly, T. brucei ribosomes may require biogenesis factors not found in other organisms. Here, we show that one of two putative 3-methylcytidine methyltransferases, TbMTase37 (a homolog of human methyltransferase-like 6, METTL6), is important for ribosome stability in T. brucei. TbMTase37 localizes to the nucleolus and depletion of the protein results in accumulation of ribosomal particles lacking srRNA 4 and reduced levels of polysome associated ribosomes. We also find that TbMTase37 plays a role in cytokinesis, as loss of the protein leads to multi-flagellated and multi-nucleated cells.


Subject(s)
Cell Division/physiology , Methyltransferases/metabolism , Protozoan Proteins/metabolism , Ribosomes/metabolism , Trypanosoma brucei brucei/metabolism , Humans , Methyltransferases/genetics , Protozoan Proteins/genetics , Ribosomes/genetics , Trypanosoma brucei brucei/genetics
5.
Nucleic Acids Res ; 43(8): 4262-73, 2015 Apr 30.
Article in English | MEDLINE | ID: mdl-25845597

ABSTRACT

Establishment of the early genetic code likely required strategies to ensure translational accuracy and inevitably involved tRNA post-transcriptional modifications. One such modification, wybutosine/wyosine is crucial for translational fidelity in Archaea and Eukarya; yet it does not occur in Bacteria and has never been described in mitochondria. Here, we present genetic, molecular and mass spectromery data demonstrating the first example of wyosine in mitochondria, a situation thus far unique to kinetoplastids. We also show that these modifications are important for mitochondrial function, underscoring their biological significance. This work focuses on TyW1, the enzyme required for the most critical step of wyosine biosynthesis. Based on molecular phylogeny, we suggest that the kinetoplastids pathways evolved via gene duplication and acquisition of an FMN-binding domain now prevalent in TyW1 of most eukaryotes. These findings are discussed in the context of the extensive U-insertion RNA editing in trypanosome mitochondria, which may have provided selective pressure for maintenance of mitochondrial wyosine in this lineage.


Subject(s)
Guanosine/analogs & derivatives , Mitochondria/enzymology , RNA, Transfer/metabolism , Trypanosoma brucei brucei/enzymology , Guanosine/biosynthesis , Guanosine/chemistry , Guanosine/metabolism , Protozoan Proteins/genetics , Protozoan Proteins/metabolism , RNA Processing, Post-Transcriptional , RNA, Transfer/chemistry , Trypanosoma brucei brucei/genetics
6.
Nucleic Acids Res ; 43(10): e64, 2015 May 26.
Article in English | MEDLINE | ID: mdl-25820423

ABSTRACT

Ribosomal ribonucleic acid (RNA), transfer RNA and other biological or synthetic RNA polymers can contain nucleotides that have been modified by the addition of chemical groups. Traditional Sanger sequencing methods cannot establish the chemical nature and sequence of these modified-nucleotide containing oligomers. Mass spectrometry (MS) has become the conventional approach for determining the nucleotide composition, modification status and sequence of modified RNAs. Modified RNAs are analyzed by MS using collision-induced dissociation tandem mass spectrometry (CID MS/MS), which produces a complex dataset of oligomeric fragments that must be interpreted to identify and place modified nucleosides within the RNA sequence. Here we report the development of RoboOligo, an interactive software program for the robust analysis of data generated by CID MS/MS of RNA oligomers. There are three main functions of RoboOligo: (i) automated de novo sequencing via the local search paradigm. (ii) Manual sequencing with real-time spectrum labeling and cumulative intensity scoring. (iii) A hybrid approach, coined 'variable sequencing', which combines the user intuition of manual sequencing with the high-throughput sampling of automated de novo sequencing.


Subject(s)
High-Throughput Nucleotide Sequencing/methods , RNA Processing, Post-Transcriptional , Sequence Analysis, RNA/methods , Software , Tandem Mass Spectrometry , Algorithms , RNA, Ribosomal/chemistry , RNA, Ribosomal/metabolism , RNA, Transfer/chemistry , RNA, Transfer/metabolism
7.
Mol Microbiol ; 93(5): 944-56, 2014 Sep.
Article in English | MEDLINE | ID: mdl-25040919

ABSTRACT

Transfer RNAs (tRNAs) through their abundance and modification pattern significantly influence protein translation. Here, we present a systematic analysis of the tRNAome of Lactococcus lactis. Using the next-generation sequencing approach, we identified 40 tRNAs which carry 16 different post-transcriptional modifications as revealed by mass spectrometry analysis. While small modifications are located in the tRNA body, hypermodified nucleotides are mainly present in the anticodon loop, which through wobbling expand the decoding potential of the tRNAs. Using tRNA-based microarrays, we also determined the dynamics in tRNA abundance upon changes in the growth rate and heterologous protein overexpression stress. With a fourfold increase in the growth rate, the relative abundance of tRNAs cognate to low abundance codons decrease, while the tRNAs cognate to major codons remain mostly unchanged. Significant changes in the tRNA abundances are observed upon protein overexpression stress, which does not correlate with the codon usage of the overexpressed gene but rather reflects the altered expression of housekeeping genes.


Subject(s)
Lactococcus lactis/genetics , RNA, Transfer/genetics , Anticodon , Codon , Lactococcus lactis/metabolism , RNA, Transfer/metabolism , Transcription, Genetic
8.
ACS Chem Biol ; 9(8): 1812-25, 2014 Aug 15.
Article in English | MEDLINE | ID: mdl-24911101

ABSTRACT

Queuosine (Q) is a modification found at the wobble position of tRNAs with GUN anticodons. Although Q is present in most eukaryotes and bacteria, only bacteria can synthesize Q de novo. Eukaryotes acquire queuine (q), the free base of Q, from diet and/or microflora, making q an important but under-recognized micronutrient for plants, animals, and fungi. Eukaryotic type tRNA-guanine transglycosylases (eTGTs) are composed of a catalytic subunit (QTRT1) and a homologous accessory subunit (QTRTD1) forming a complex that catalyzes q insertion into target tRNAs. Phylogenetic analysis of eTGT subunits revealed a patchy distribution pattern in which gene losses occurred independently in different clades. Searches for genes co-distributing with eTGT family members identified DUF2419 as a potential Q salvage protein family. This prediction was experimentally validated in Schizosaccharomyces pombe by confirming that Q was present by analyzing tRNA(Asp) with anticodon GUC purified from wild-type cells and by showing that Q was absent from strains carrying deletions in the QTRT1 or DUF2419 encoding genes. DUF2419 proteins occur in most Eukarya with a few possible cases of horizontal gene transfer to bacteria. The universality of the DUF2419 function was confirmed by complementing the S. pombe mutant with the Zea mays (maize), human, and Sphaerobacter thermophilus homologues. The enzymatic function of this family is yet to be determined, but structural similarity with DNA glycosidases suggests a ribonucleoside hydrolase activity.


Subject(s)
Fungi/metabolism , Nucleoside Q/metabolism , Plants/metabolism , Proteins/metabolism , Animals , Models, Molecular , Nucleoside Q/chemistry , Phylogeny
9.
Anal Chem ; 86(9): 4264-70, 2014 May 06.
Article in English | MEDLINE | ID: mdl-24738621

ABSTRACT

Mass spectrometry-based quantification of ribosomal proteins (r-proteins) associated with mature ribosomes and ribosome assembly complexes is typically accomplished by relative quantification strategies. These strategies provide information on the relative stoichiometry of proteins within the complex compared to a wild-type strain. Here we have evaluated the applicability of a label-free approach, enhanced liquid chromatography-mass spectrometry (LC-MS(E)), for absolute "ribosome-centric" quantification of r-proteins in Escherichia coli mature ribosomes. Because the information obtained in this experiment is related to the number of peptides identified per protein, experimental conditions that allow accurate and reproducible quantification of r-proteins were found. Using an additional dimension of gas-phase separation through ion mobility and the use of multiple endoproteinase digestion significantly improved quantification of proteins associated with mature ribosomes. The actively translating ribosomes (polysomes) contain amounts of proteins consistent with their known stoichiometry within the complex. These measurements exhibited technical and biological reproducibilities at %CV less than 15% and 35%, respectively. The improved LC-MS(E) approach described here can be used to characterize in vivo ribosome assembly complexes captured during ribosome biogenesis and assembly under different perturbations (e.g., antibiotics, deletion mutants of assembly factors, oxidative stress, nutrient deprivation). Quantitative analysis of these captured complexes will provide information relating to the interplay and dynamics of how these perturbations interfere with the assembly process.


Subject(s)
Bacterial Proteins/isolation & purification , Chromatography, Liquid/methods , Mass Spectrometry/methods , Ribosomal Proteins/isolation & purification , Reproducibility of Results
10.
Nucleic Acids Res ; 42(3): 1904-15, 2014 Feb.
Article in English | MEDLINE | ID: mdl-24194599

ABSTRACT

Translation of the isoleucine codon AUA in most prokaryotes requires a modified C (lysidine or agmatidine) at the wobble position of tRNA2(Ile) to base pair specifically with the A of the AUA codon but not with the G of AUG. Recently, a Bacillus subtilis strain was isolated in which the essential gene encoding tRNA(Ile)-lysidine synthetase was deleted for the first time. In such a strain, C34 at the wobble position of tRNA2(Ile) is expected to remain unmodified and cells depend on a mutant suppressor tRNA derived from tRNA1(Ile), in which G34 has been changed to U34. An important question, therefore, is how U34 base pairs with A without also base pairing with G. Here, we show (i) that unlike U34 at the wobble position of all B. subtilis tRNAs of known sequence, U34 in the mutant tRNA is not modified, and (ii) that the mutant tRNA binds strongly to the AUA codon on B. subtilis ribosomes but only weakly to AUG. These in vitro data explain why the suppressor strain displays only a low level of misreading AUG codons in vivo and, as shown here, grows at a rate comparable to that of the wild-type strain.


Subject(s)
Bacillus subtilis/genetics , Codon , Isoleucine/metabolism , Protein Biosynthesis , RNA, Transfer, Ile/chemistry , RNA, Transfer, Ile/metabolism , Amino Acyl-tRNA Synthetases/genetics , Bacillus subtilis/growth & development , Gene Deletion , Phenotype , RNA, Transfer, Ile/isolation & purification , Ribosomes/metabolism , Transfer RNA Aminoacylation
11.
RNA Biol ; 11(12): 1568-85, 2014.
Article in English | MEDLINE | ID: mdl-25616408

ABSTRACT

The analysis of ribonucleic acids (RNA) by mass spectrometry has been a valuable analytical approach for more than 25 years. In fact, mass spectrometry has become a method of choice for the analysis of modified nucleosides from RNA isolated out of biological samples. This review summarizes recent progress that has been made in both nucleoside and oligonucleotide mass spectral analysis. Applications of mass spectrometry in the identification, characterization and quantification of modified nucleosides are discussed. At the oligonucleotide level, advances in modern mass spectrometry approaches combined with the standard RNA modification mapping protocol enable the characterization of RNAs of varying lengths ranging from low molecular weight short interfering RNAs (siRNAs) to the extremely large 23 S rRNAs. New variations and improvements to this protocol are reviewed, including top-down strategies, as these developments now enable qualitative and quantitative measurements of RNA modification patterns in a variety of biological systems.


Subject(s)
Nucleosides/analysis , Oligonucleotides/analysis , RNA Processing, Post-Transcriptional , RNA, Messenger/analysis , RNA, Ribosomal, 23S/analysis , RNA, Small Interfering/analysis , RNA, Untranslated/analysis , Base Sequence , Escherichia coli/genetics , Escherichia coli/metabolism , Mass Spectrometry/instrumentation , Mass Spectrometry/methods , Molecular Sequence Data , Nucleic Acid Conformation , Nucleosides/chemistry , Nucleosides/metabolism , Oligonucleotides/chemistry , Oligonucleotides/metabolism , RNA, Messenger/chemistry , RNA, Messenger/metabolism , RNA, Ribosomal, 23S/chemistry , RNA, Ribosomal, 23S/metabolism , RNA, Small Interfering/chemistry , RNA, Small Interfering/metabolism , RNA, Untranslated/chemistry , RNA, Untranslated/metabolism , Thermoplasma/genetics , Thermoplasma/metabolism
12.
Mol Cell ; 52(2): 184-92, 2013 Oct 24.
Article in English | MEDLINE | ID: mdl-24095278

ABSTRACT

In cells, tRNAs are synthesized as precursor molecules bearing extra sequences at their 5' and 3' ends. Some tRNAs also contain introns, which, in archaea and eukaryotes, are cleaved by an evolutionarily conserved endonuclease complex that generates fully functional mature tRNAs. In addition, tRNAs undergo numerous posttranscriptional nucleotide chemical modifications. In Trypanosoma brucei, the single intron-containing tRNA (tRNA(Tyr)GUA) is responsible for decoding all tyrosine codons; therefore, intron removal is essential for viability. Using molecular and biochemical approaches, we show the presence of several noncanonical editing events, within the intron of pre-tRNA(Tyr)GUA, involving guanosine-to-adenosine transitions (G to A) and an adenosine-to-uridine transversion (A to U). The RNA editing described here is required for proper processing of the intron, establishing the functional significance of noncanonical editing with implications for tRNA processing in the deeply divergent kinetoplastid lineage and eukaryotes in general.


Subject(s)
Introns/genetics , RNA Editing , RNA Splicing , RNA, Transfer, Tyr/genetics , Trypanosoma brucei brucei/genetics , Amino Acid Sequence , Base Sequence , Blotting, Northern , Endoribonucleases/genetics , Endoribonucleases/metabolism , Molecular Sequence Data , Nucleic Acid Conformation , Protozoan Proteins/genetics , Protozoan Proteins/metabolism , RNA Interference , RNA Precursors/genetics , RNA Precursors/metabolism , RNA Processing, Post-Transcriptional , RNA, Protozoan/genetics , RNA, Protozoan/metabolism , RNA, Transfer, Tyr/chemistry , RNA, Transfer, Tyr/metabolism , Reverse Transcriptase Polymerase Chain Reaction , Sequence Homology, Amino Acid , Trypanosoma brucei brucei/metabolism
13.
J Mol Biol ; 425(20): 3888-906, 2013 Oct 23.
Article in English | MEDLINE | ID: mdl-23727144

ABSTRACT

The 2-thiouridine (s(2)U) at the wobble position of certain bacterial and eukaryotic tRNAs enhances aminoacylation kinetics, assists proper codon-anticodon base pairing at the ribosome A-site, and prevents frameshifting during translation. By mass spectrometry of affinity-purified native Escherichia coli tRNA1(Gln)UUG, we show that the complete modification at the wobble position 34 is 5-carboxyaminomethyl-2-thiouridine (cmnm(5)s(2)U). The crystal structure of E. coli glutaminyl-tRNA synthetase (GlnRS) bound to native tRNA1(Gln) and ATP demonstrates that cmnm(5)s(2)U34 improves the order of a previously unobserved 11-amino-acid surface loop in the distal ß-barrel domain of the enzyme and imparts other local rearrangements of nearby amino acids that create a binding pocket for the 2-thio moiety. Together with previously solved structures, these observations explain the degenerate recognition of C34 and modified U34 by GlnRS. Comparative pre-steady-state aminoacylation kinetics of native tRNA1(Gln), synthetic tRNA1(Gln) containing s(2)U34 as sole modification, and unmodified wild-type and mutant tRNA1(Gln) and tRNA2(Gln) transcripts demonstrates that the exocyclic sulfur moiety improves tRNA binding affinity to GlnRS 10-fold compared with the unmodified transcript and that an additional fourfold improvement arises from the presence of the cmnm(5) moiety. Measurements of Gln-tRNA(Gln) interactions at the ribosome A-site show that the s(2)U modification enhances binding affinity to the glutamine codons CAA and CAG and increases the rate of GTP hydrolysis by E. coli EF-Tu by fivefold.


Subject(s)
Anticodon/genetics , Protein Biosynthesis/physiology , RNA, Transfer/chemistry , RNA, Transfer/genetics , Thiouridine/analogs & derivatives , Adenosine Triphosphate/metabolism , Amino Acyl-tRNA Synthetases/metabolism , Anticodon/chemistry , Base Sequence , Crystallography, X-Ray , Escherichia coli/genetics , Escherichia coli/metabolism , Molecular Docking Simulation , Nucleic Acid Conformation , Nucleosides/chemistry , Nucleosides/metabolism , Protein Binding , Protein Conformation , RNA, Transfer/metabolism , RNA, Transfer, Gln/chemistry , RNA, Transfer, Gln/genetics , RNA, Transfer, Gln/metabolism , Ribosomes/metabolism , Thiouridine/metabolism
14.
RNA Biol ; 9(10): 1239-46, 2012 Oct.
Article in English | MEDLINE | ID: mdl-22922796

ABSTRACT

It is a prevalent concept that, in line with the Wobble Hypothesis, those tRNAs having an adenosine in the first position of the anticodon become modified to an inosine at this position. Sequencing the cDNA derived from the gene coding for cytoplasmic tRNA (Arg) ACG from several higher plants as well as mass spectrometric analysis of the isoacceptor has revealed that for this kingdom an unmodified A in the wobble position of the anticodon is the rule rather than the exception. In vitro translation shows that in the plant system the absence of inosine in the wobble position of tRNA (Arg) does not prevent decoding. This isoacceptor belongs to the class of tRNA that is imported from the cytoplasm into the mitochondria of higher plants. Previous studies on the mitochondrial tRNA pool have demonstrated the existence of tRNA (Arg) ICG in this organelle. In moss the mitochondrial encoded distinct tRNA (Arg) ACG isoacceptor possesses the I34 modification. The implication is that for mitochondrial protein biosynthesis A-to-I editing is necessary and occurs by a mitochondrion-specific deaminase after import of the unmodified nuclear encoded tRNA (Arg) ACG.


Subject(s)
Adenosine/metabolism , Anticodon/metabolism , Glycine max/genetics , Inosine/metabolism , Protein Biosynthesis , RNA, Transfer, Arg/metabolism , Triticum/genetics , Adenosine/genetics , Adenosine Deaminase/metabolism , Anticodon/chemistry , Anticodon/genetics , Base Pairing , Base Sequence , Cell Nucleus/genetics , Cell Nucleus/metabolism , Cell-Free System , Cytoplasm/genetics , Cytoplasm/metabolism , Escherichia coli/genetics , Escherichia coli/metabolism , Genetic Code , Inosine/genetics , Mitochondria/genetics , Mitochondria/metabolism , Molecular Sequence Data , Nucleic Acid Conformation , RNA, Transfer, Arg/chemistry , RNA, Transfer, Arg/genetics , Glycine max/metabolism , Sphagnopsida/genetics , Sphagnopsida/metabolism , Triticum/metabolism
15.
ACS Chem Biol ; 7(2): 300-5, 2012 Feb 17.
Article in English | MEDLINE | ID: mdl-22032275

ABSTRACT

Archaeosine (G(+)) is found at position 15 of many archaeal tRNAs. In Euryarchaeota, the G(+) precursor, 7-cyano-7-deazaguanine (preQ(0)), is inserted into tRNA by tRNA-guanine transglycosylase (arcTGT) before conversion into G(+) by ARChaeosine Synthase (ArcS). However, many Crenarchaeota known to harbor G(+) lack ArcS homologues. Using comparative genomics approaches, two families that could functionally replace ArcS in these organisms were identified: (1) GAT-QueC, a two-domain family with an N-terminal glutamine amidotransferase class-II domain fused to a domain homologous to QueC, the enzyme that produces preQ(0) and (2) QueF-like, a family homologous to the bacterial enzyme catalyzing the reduction of preQ(0) to 7-aminomethyl-7-deazaguanine. Here we show that these two protein families are able to catalyze the formation of G(+) in a heterologous system. Structure and sequence comparisons of crenarchaeal and euryarchaeal arcTGTs suggest the crenarchaeal enzymes have broader substrate specificity. These results led to a new model for the synthesis and salvage of G(+) in Crenarchaeota.


Subject(s)
Archaeal Proteins/metabolism , Crenarchaeota/enzymology , Guanosine/analogs & derivatives , Amino Acid Sequence , Archaeal Proteins/chemistry , Archaeal Proteins/genetics , Crenarchaeota/chemistry , Crenarchaeota/genetics , Crenarchaeota/metabolism , Genomics , Guanosine/chemistry , Guanosine/metabolism , Molecular Sequence Data , Phylogeny , Sequence Alignment , Substrate Specificity
16.
Nucleic Acids Res ; 39(17): 7641-55, 2011 Sep 01.
Article in English | MEDLINE | ID: mdl-21693558

ABSTRACT

The modified nucleosides N(2)-methylguanosine and N(2)(2)-dimethylguanosine in transfer RNA occur at five positions in the D and anticodon arms, and at positions G6 and G7 in the acceptor stem. Trm1 and Trm11 enzymes are known to be responsible for several of the D/anticodon arm modifications, but methylases catalyzing post-transcriptional m(2)G synthesis in the acceptor stem are uncharacterized. Here, we report that the MJ0438 gene from Methanocaldococcus jannaschii encodes a novel S-adenosylmethionine-dependent methyltransferase, now identified as Trm14, which generates m(2)G at position 6 in tRNA(Cys). The 381 amino acid Trm14 protein possesses a canonical RNA recognition THUMP domain at the amino terminus, followed by a γ-class Rossmann fold amino-methyltransferase catalytic domain featuring the signature NPPY active site motif. Trm14 is associated with cluster of orthologous groups (COG) 0116, and most closely resembles the m(2)G10 tRNA methylase Trm11. Phylogenetic analysis reveals a canonical archaeal/bacterial evolutionary separation with 20-30% sequence identities between the two branches, but it is likely that the detailed functions of COG 0116 enzymes differ between the archaeal and bacterial domains. In the archaeal branch, the protein is found exclusively in thermophiles. More distantly related Trm14 homologs were also identified in eukaryotes known to possess the m(2)G6 tRNA modification.


Subject(s)
Archaeal Proteins/metabolism , Methanococcales/enzymology , RNA, Transfer/metabolism , tRNA Methyltransferases/metabolism , Amino Acid Sequence , Archaeal Proteins/classification , Archaeal Proteins/genetics , Base Sequence , Biocatalysis , Molecular Sequence Data , Phylogeny , RNA, Transfer/chemistry , RNA, Transfer, Cys/chemistry , RNA, Transfer, Cys/metabolism , Recombinant Proteins/genetics , Recombinant Proteins/isolation & purification , Sequence Alignment , tRNA Methyltransferases/classification , tRNA Methyltransferases/genetics
17.
J Biol Chem ; 286(23): 20366-74, 2011 Jun 10.
Article in English | MEDLINE | ID: mdl-21507956

ABSTRACT

Editing of adenosine (A) to inosine (I) at the first anticodon position in tRNA is catalyzed by adenosine deaminases acting on tRNA (ADATs). This essential reaction in bacteria and eukarya permits a single tRNA to decode multiple codons. Bacterial ADATa is a homodimer with two bound essential Zn(2+). The ADATa crystal structure revealed residues important for substrate binding and catalysis; however, such high resolution structural information is not available for eukaryotic tRNA deaminases. Despite significant sequence similarity among deaminases, we continue to uncover unexpected functional differences between Trypanosoma brucei ADAT2/3 (TbADAT2/3) and its bacterial counterpart. Previously, we demonstrated that TbADAT2/3 is unique in catalyzing two different deamination reactions. Here we show by kinetic analyses and inductively coupled plasma emission spectrometry that wild type TbADAT2/3 coordinates two Zn(2+) per heterodimer, but unlike any other tRNA deaminase, mutation of one of the key Zn(2+)-coordinating cysteines in TbADAT2 yields a functional enzyme with a single-bound zinc. These data suggest that, at least, TbADAT3 may play a role in catalysis via direct coordination of the catalytic Zn(2+). These observations raise the possibility of an unusual Zn(2+) coordination interface with important implications for the function and evolution of editing deaminases.


Subject(s)
Adenosine Deaminase/metabolism , Protozoan Proteins/metabolism , RNA Editing/physiology , RNA, Protozoan/biosynthesis , RNA, Transfer/biosynthesis , Trypanosoma brucei brucei/enzymology , Zinc/metabolism , Adenosine Deaminase/genetics , Cations, Divalent/metabolism , Protozoan Proteins/genetics , RNA, Protozoan/genetics , RNA, Transfer/genetics , RNA-Binding Proteins , Trypanosoma brucei brucei/genetics
18.
Methods Mol Biol ; 718: 209-26, 2011.
Article in English | MEDLINE | ID: mdl-21370051

ABSTRACT

The primary sequence of all nucleic acids in a cell contain 4 canonical nucleotides (G, A, T, and C for DNA and G, A, U, and C for RNA). However, post-transcriptionally, nucleic acids can undergo a number of chemical modifications, which may change their structure and function. tRNAs contain the most diverse array of post-transcriptionally added chemical groups that involve both editing and modification. Because editing and modification events can serve vital roles in cell function, it is important to develop techniques that allow for fast and accurate analysis of these events. This chapter describes the methods used to purify tRNAs from total native RNA pools and for subsequent analysis of their edited and modified states using reverse transcriptase-based approaches. These techniques, in combination with 2D-TLC, allow for the routine analysis and quantitation of edited and modified nucleotides in a fast, cost effective manner and without the need for special equipment such as HPLC or a mass spectrometer. Admittedly, the techniques described here are only applicable to a subset of post-transcriptional changes occurring in a tRNA such as C to U and A to I editing as well as modifications that prevent reverse transcriptase elongation; these have been highlighted throughout the chapter.


Subject(s)
RNA Editing , RNA, Protozoan/genetics , RNA, Protozoan/isolation & purification , RNA, Transfer/genetics , RNA, Transfer/isolation & purification , Trypanosoma brucei brucei/genetics , Chromatography, Thin Layer/methods , Genetic Techniques , RNA, Protozoan/metabolism , RNA, Transfer/metabolism , RNA-Directed DNA Polymerase/metabolism , Reverse Transcriptase Polymerase Chain Reaction/methods , Trypanosoma brucei brucei/metabolism
19.
Methods ; 44(2): 170-5, 2008 Feb.
Article in English | MEDLINE | ID: mdl-18241798

ABSTRACT

Transfer RNA (tRNA) plays a pivotal role in protein synthesis within cells, where it is recognized by one cognate aminoacyl-tRNA synthetase, in competition with the remaining non-cognate synthetases, and esterified with an amino acid. For many years the levels of tRNA aminoacylation, in a given population of cellular RNA, have been analyzed using methods that include northern analysis and/or oxidation techniques to separate aminoacylated from non-aminoacylated species. In the present report we describe an approach recently developed by us that combines oxidation-protection with polyadenylation and PCR. The OXOPAP approach permits the amplification of tRNA species that are nearly identical and that evade differential identification by more classical northern hybridization methods. Our approach also allows the identification of aminoacylatable "naïve" species, where no prior knowledge of sequence content is necessary for amplification.


Subject(s)
Polyadenylation , RNA, Transfer, Amino Acyl/isolation & purification , Transfer RNA Aminoacylation , Nucleic Acid Amplification Techniques/methods , Oxidation-Reduction , Polymerase Chain Reaction/methods , Polynucleotide Adenylyltransferase/metabolism
20.
Nucleic Acids Res ; 35(20): 6740-9, 2007.
Article in English | MEDLINE | ID: mdl-17916576

ABSTRACT

In all organisms, precursor tRNAs are processed into mature functional units by post-transcriptional changes. These involve 5' and 3' end trimming as well as the addition of a significant number of chemical modifications, including RNA editing. The only known example of non-organellar C to U editing of tRNAs occurs in trypanosomatids. In this system, editing at position 32 of the anticodon loop of tRNA(Thr)(AGU) stimulates, but is not required for, the subsequent formation of inosine at position 34. In the present work, we expand the number of C to U edited tRNAs to include all the threonyl tRNA isoacceptors. Notably, the absence of a naturally encoded adenosine, at position 34, in two of these isoacceptors demonstrates that A to I is not required for C to U editing. We also show that C to U editing is a nuclear event while A to I is cytoplasmic, where C to U editing at position 32 occurs in the precursor tRNA prior to 5' leader removal. Our data supports the view that C to U editing is more widespread than previously thought and is part of a stepwise process in the maturation of tRNAs in these organisms.


Subject(s)
RNA Editing , RNA Processing, Post-Transcriptional , RNA, Transfer, Amino Acyl/metabolism , Trypanosoma brucei brucei/genetics , Trypanosoma brucei brucei/metabolism , Animals , Base Sequence , Molecular Sequence Data , Nucleic Acid Conformation , RNA, Transfer, Amino Acyl/chemistry , RNA, Transfer, Amino Acyl/genetics
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