tRNA m1G9 modification depends on substrate-specific RNA conformational changes induced by the methyltransferase Trm10.

The methyltransferase Trm10 modifies a subset of tRNAs on the base N1 position of the ninth nucleotide in the tRNA core. Trm10 is conserved throughout Eukarya and Archaea, and mutations in the human gene (TRMT10A) have been linked to neurological disorders such as microcephaly and intellectual disability, as well as defects in glucose metabolism. Of the 26 tRNAs in yeast with guanosine at position 9, only 13 are substrates for Trm10. However, no common sequence or other posttranscriptional modifications have been identified among these substrates, suggesting the presence of some other tRNA feature(s) that allow Trm10 to distinguish substrate from nonsubstrate tRNAs. Here, we show that substrate recognition by Saccharomyces cerevisiae Trm10 is dependent on both intrinsic tRNA flexibility and the ability of the enzyme to induce specific tRNA conformational changes upon binding. Using the sensitive RNA structure-probing method SHAPE, conformational changes upon binding to Trm10 in tRNA substrates, but not nonsubstrates, were identified and mapped onto a model of Trm10-bound tRNA. These changes may play an important role in substrate recognition by allowing Trm10 to gain access to the target nucleotide. Our results highlight a novel mechanism of substrate recognition by a conserved tRNA modifying enzyme. Further, these studies reveal a strategy for substrate recognition that may be broadly employed by tRNA-modifying enzymes which must distinguish between structurally similar tRNA species.

tRNA m1G9 modification depends on substrate-specific RNA conformational changes induced by the methyltransferase Trm10.

The methyltransferase Trm10 modifies a subset of tRNAs on the base N1 position of the 9th nucleotide in the tRNA core. Trm10 is conserved throughout Eukarya and Archaea, and mutations in the human gene (TRMT10A) have been linked to neurological disorders such as microcephaly and intellectual disability, as well as defects in glucose metabolism. Of the 26 tRNAs in yeast with guanosine at position 9, only 14 are substrates for Trm10. However, no common sequence or other posttranscriptional modifications have been identified among these substrates, suggesting the presence of some other tRNA feature(s) which allow Trm10 to distinguish substrate from nonsubstrate tRNAs. Here, we show that substrate recognition by Saccharomyces cerevisiae Trm10 is dependent on both intrinsic tRNA flexibility and the ability of the enzyme to induce specific tRNA conformational changes upon binding. Using the sensitive RNA structure-probing method SHAPE, conformational changes upon binding to Trm10 in tRNA substrates, but not nonsubstrates, were identified and mapped onto a model of Trm10-bound tRNA. These changes may play an important role in substrate recognition by allowing Trm10 to gain access to the target nucleotide. Our results highlight a novel mechanism of substrate recognition by a conserved tRNA modifying enzyme. Further, these studies reveal a strategy for substrate recognition that may be broadly employed by tRNA-modifying enzymes which must distinguish between structurally similar tRNA species.

Profiling lariat intermediates reveals genetic determinants of early and late co-transcriptional splicing.

Long introns with short exons in vertebrate genes are thought to require spliceosome assembly across exons (exon definition), rather than introns, thereby requiring transcription of an exon to splice an upstream intron. Here, we developed CoLa-seq (co-transcriptional lariat sequencing) to investigate the timing and determinants of co-transcriptional splicing genome wide. Unexpectedly, 90% of all introns, including long introns, can splice before transcription of a downstream exon, indicating that exon definition is not obligatory for most human introns. Still, splicing timing varies dramatically across introns, and various genetic elements determine this variation. Strong U2AF2 binding to the polypyrimidine tract predicts early splicing, explaining exon definition-independent splicing. Together, our findings question the essentiality of exon definition and reveal features beyond intron and exon length that are determinative for splicing timing.

Transient kinetic analysis for studying ionizations in RNA modification enzyme mechanisms.

The application of in vitro kinetic tools has the potential to provide important insight into the molecular mechanisms of RNA modification enzymes. Utilizing quantitative biochemical approaches can reveal information about enzyme preferences for specific substrates that are relevant for understanding modification reactions in their biological contexts. Moreover, kinetic tools have been powerfully applied to identify and characterize roles for specific amino acid residues in catalysis, which can be essential information for understanding the molecular basis for human disease, as well as for targeting these enzymes for potential therapeutic interventions. RNA methyltransferases are a particularly interesting group of RNA modification enzymes because of the diversity in structure and mechanism that has been revealed among members of this group, even including some examples of enzymes that use entirely distinct reaction mechanisms to form identical methylated nucleotides in RNA. Yet, many questions remain unanswered about how these distinct catalytic strategies are facilitated by the relevant enzyme families. We have applied in vitro kinetic analysis to specifically focus on catalytically relevant ionizations in the context of tRNA methyltransferase reactions, by measuring rates under conditions of varied pH. This analysis can be applied broadly to RNA methyltransferases to expand our understanding of these important enzymes.

Insights into Catalytic and tRNA Recognition Mechanism of the Dual-Specific tRNA Methyltransferase from Thermococcus kodakarensis.

The tRNA methyltransferase Trm10, conserved throughout Eukarya and Archaea, catalyzes N1-methylation of purine residues at position 9 using S-adenosyl methionine as the methyl donor. The Trm10 family exhibits diverse target nucleotide specificity, with some homologs that are obligate m¹G9 or m¹A9-specific enzymes, while others are bifunctional enzymes catalyzing both m¹G9 and m¹A9. This variability is particularly intriguing given different chemical properties of the target N1 atom of guanine and adenine. Here we performed an extensive kinetic and mutational analysis of the m¹G9 and m¹A9-catalyzing Trm10 from Thermococcus kodakarensis to gain insight into the active site that facilitates this unique bifunctionality. These results suggest that the rate-determining step for catalysis likely involves a conformational change to correctly position the substrate tRNA in the active site. In this model, kinetic preferences for certain tRNA can be explained by variations in the overall stability of the folded substrate tRNA, consistent with tRNA-specific differences in metal ion dependence. Together, these results provide new insight into the substrate recognition, active site and catalytic mechanism of m¹G/m¹A catalyzing bifunctional enzymes.

A Family Divided: Distinct Structural and Mechanistic Features of the SpoU-TrmD (SPOUT) Methyltransferase Superfamily.

The SPOUT family of enzymes makes up the second largest of seven structurally distinct groups of methyltransferases and is named after two evolutionarily related RNA methyltransferases, SpoU and TrmD. A deep trefoil knotted domain in the tertiary structures of member enzymes defines the SPOUT family. For many years, formation of a homodimeric quaternary structure was thought to be a strict requirement for all SPOUT enzymes, critical for substrate binding and formation of the active site. However, recent structural characterization of two SPOUT members, Trm10 and Sfm1, revealed that they function as monomers without the requirement of this critical dimerization. This unusual monomeric form implies that these enzymes must exhibit a nontraditional substrate binding mode and active site architecture and may represent a new division in the SPOUT family with distinct properties removed from the dimeric enzymes. Here we discuss the mechanistic features of SPOUT enzymes with an emphasis on the monomeric members and implications of this "novel" monomeric structure on cofactor and substrate binding.

Mechanistic features of the atypical tRNA m1G9 SPOUT methyltransferase, Trm10.

The tRNA m1G9 methyltransferase (Trm10) is a member of the SpoU-TrmD (SPOUT) superfamily of methyltransferases, and Trm10 homologs are widely conserved throughout Eukarya and Archaea. Despite possessing the trefoil knot characteristic of SPOUT enzymes, Trm10 does not share the same quaternary structure or key sequences with other members of the SPOUT family, suggesting a novel mechanism of catalysis. To investigate the mechanism of m1G9 methylation by Trm10, we performed a biochemical and kinetic analysis of Trm10 and variants with alterations in highly conserved residues, using crystal structures solved in the absence of tRNA as a guide. Here we demonstrate that a previously proposed general base residue (D210 in Saccharomyces cerevisiae Trm10) is not likely to play this suggested role in the chemistry of methylation. Instead, pH-rate analysis suggests that D210 and other conserved carboxylate-containing residues at the active site collaborate to establish an active site environment that promotes a single ionization that is required for catalysis. Moreover, Trm10 does not depend on a catalytic metal ion, further distinguishing it from the other known SPOUT m1G methyltransferase, TrmD. These results provide evidence for a non-canonical tRNA methyltransferase mechanism that characterizes the Trm10 enzyme family.

TRMT10A dysfunction is associated with abnormalities in glucose homeostasis, short stature and microcephaly.

BACKGROUND: Trm10 is a tRNA m(1)G9 methyltransferase, which in yeast modifies 12 different tRNA species, yet is considered non-essential for viability under standard growth conditions. In humans, there are three Trm10 orthologs, one mitochondrial and two presumed cytoplasmic. A nonsense mutation in one of the cytoplasmic orthologs (TRMT10A) has recently been associated with microcephaly, intellectual disability, short stature and adolescent onset diabetes. METHODS AND RESULTS: The subjects were three patients who suffered from microcephaly, intellectual disability, short stature, delayed puberty, seizures and disturbed glucose metabolism, mainly hyperinsulinaemic hypoglycaemia. A homozygous Gly206Arg (G206R) mutation in the TRMT10A gene was identified using whole exome sequencing. The mutation segregated in the family and was absent from large control cohorts. Determination of the methylation activity of the expressed wild-type (WT) and variant TRMT10A enzymes with transcripts of (32)P -tRNA(Gly) GCC as a substrate revealed a striking defect (<0.1% of WT activity) for the variant enzyme. The binding affinity of the G206R variant enzyme to tRNA, determined by fluorescence anisotropy, was similar to that of the WT enzyme. CONCLUSIONS: The completely abolished m(1)G9 methyltransferase activity of the mutant enzyme is likely due to significant defects in its ability to bind the methyl donor S-adenosyl methionine. We propose that TRMT10A deficiency accounts for abnormalities in glucose homeostasis initially manifesting both ketotic and non-ketotic hypoglycaemic events with transition to diabetes in adolescence, perhaps as a consequence of accelerated ß cell apoptosis. The seizure disorder and intellectual disability are probably secondary to mutant gene expression in neuronal tissue.