Nucleotide specificity of the human terminal nucleotidyltransferase Gld2 (TUT2)

Chung, Christina Z.; Jo, David H S; Heinemann, Ilka U.

doi:10.1261/rna.056077.116

Cited by 27 publications

(42 citation statements)

References 63 publications

(105 reference statements)

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“…On the contrary, S. cerevisiae Trf4 and Trf5 proteins, displaying PAP activity (LaCava et al 2005;Vanacova et al 2005;Wyers et al 2005;Houseley and Tollervey 2006;Hamill et al 2010), contain DxxDxxN cluster at the equivalent position and the same is true for S. pombe nuclear noncanonical PAP, Cid14 (Table 1; Win et al 2006). Importantly, asparagine seems to be invariantly present in the last position of the NRM cluster in all noncanonical NTases, for which PAP activity has been experimentally demonstrated, including recently studied human GLD-2 (TUT2) which contains ExxDxxN cluster (Table 1; Chung et al 2016). In concordance, the Cid1 H336N mutation (creating DxxExxN cluster) changed Cid1 specificity from PUP into PAP (Lunde et al 2012).…”

Section: Discussionmentioning

confidence: 91%

Biochemical and structural bioinformatics studies of fungal CutA nucleotidyltransferases explain their unusual specificity toward CTP and increased tendency for cytidine incorporation at the 3′-terminal positions of synthesized tails

Kobyłecki

Kuchta

Dziembowski

et al. 2017

RNA

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Noncanonical RNA nucleotidyltransferases (NTases), including poly(A), poly(U) polymerases (PAPs/PUPs), and C/U-adding enzymes, modify 3'-ends of different transcripts affecting their functionality and stability. They contain PAP/OAS1 substrate-binding domain (SBD) with inserted NTase domain. CutA (AnCutA), synthesizes C/U-rich 3'-terminal extensions in vivo. Here, using high-throughput sequencing of the 3'-RACE products for tails generated by CutA proteins in vitro in the presence of all four NTPs, we show that even upon physiological ATP excess synthesized tails indeed contain an unprecedented number of cytidines interrupted by uridines and stretches of adenosines, and that the majority end with two cytidines. Strikingly, processivity assays documented that in the presence of CTP as a sole nucleotide, the enzyme terminates after adding two cytidines only. Comparison of our CutA 3D model to selected noncanonical NTases of known structures revealed substantial differences in the nucleotide recognition motif (NRM) within PAP/OAS1 SBD. We demonstrate that CutA specificity toward CTP can be partially changed to PAP or PUP by rational mutagenesis within NRM and, analogously, Cid1 PUP can be converted into a C/U-adding enzyme. Collectively, we suggest that a short cluster of amino acids within NRM is a determinant of NTases' substrate preference, which may allow us to predict their specificity.

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Section: Discussionmentioning

confidence: 91%

Biochemical and structural bioinformatics studies of fungal CutA nucleotidyltransferases explain their unusual specificity toward CTP and increased tendency for cytidine incorporation at the 3′-terminal positions of synthesized tails

Kobyłecki

Kuchta

Dziembowski

et al. 2017

RNA

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“…The active site regions of the PAPs and PUPs we identified bear on how U and A are distinguished by different enzymes in the same family. Prior work demonstrated that a histidine in the active-site regions of Human Gld2 and S. pombe Cid1 dictates their apparent preferences for A and U, respectively [62][63][64][65][66][67] . Similarly, U-adding enzymes appear to have arisen repeatedly in evolution by the insertion of histidine into ancestral A-adding enzymes 62 .…”

Section: Discussionmentioning

confidence: 99%

“…Prior work demonstrated that a histidine in the active-site regions of Human Gld2 and S. pombe Cid1 dictates their apparent preferences for A and U, respectively [62][63][64][65][66][67] . Similarly, U-adding enzymes appear to have arisen repeatedly in evolution by the insertion of histidine into ancestral A-adding enzymes 62 . However, among the U-adding enzymes we uncovered here, several (Sp Cid16, Ce PUP-3 and Ce F43E2.1) lack that histidine, and one that possesses a histidine (Hs TUT1/Star-PAP) adds adenosines 21 (Table 1).…”

Section: Discussionmentioning

confidence: 99%

Unbiased screen of RNA tailing enzymes at single-nucleotide resolution reveals a poly(UG) polymerase required for genome integrity and RNA silencing

Preston

Porter

Chen

et al. 2018

Preprint

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Ribonucleotidyl transferases (rNTases) add non-templated ribonucleotides to diverse RNAs. We developed a screening strategy in S. cerevisiae to identify sequences added by candidate enzymes from different organisms at single-nucleotide resolution. The rNTase activities of 19 previously unexplored enzymes were determined. In addition to poly(A)-and poly(U)-adding enzymes, we identified a C-adding enzyme that is likely part of a two-enzyme system that adds CCA to tRNAs in a eukaryote; a nucleotidyl transferase that adds nucleotides to RNA without apparent nucleotide preference; and a poly(UG) polymerase, C. elegans MUT-2, which adds alternating U and G nucleotides to form poly(UG) tails. MUT-2 is known to be required for certain forms of RNA silencing, and mutations in the enzyme that are defective in silencing also fail to add poly(UG) tails in our assay. We propose that MUT-2 poly(UG) polymerase activity is required to promote genome integrity and RNA silencing.

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“…In addition, a histidine residue in Cid1 (His336), conserved in some plant and human cytosolic TUTases but absent from trypanosomal TUTases, has been involved in UTP selectivity . A single amino acid substitution at this position is sufficient to switch the specificity of Cid1 from UTP to ATP, and vice versa for human Gld2 (TUT2) . Those experiments illustrate the ease of switching the nucleotide specificity of a terminal nucleotidyltransferase during evolution to allow for the acquisition of a novel biological function linked to RNA tailing.…”

Section: Key Features Of Terminal Uridylyltransferasesmentioning

confidence: 94%

RNA uridylation: a key posttranscriptional modification shaping the coding and noncoding transcriptome

et al. 2017

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RNA uridylation is a potent and widespread posttranscriptional regulator of gene expression. RNA uridylation has been detected in a range of eukaryotes including trypanosomes, animals, plants, and fungi, but with the noticeable exception of budding yeast. Virtually all classes of eukaryotic RNAs can be uridylated and uridylation can also tag viral RNAs. The untemplated addition of a few uridines at the 3 0 end of a transcript can have a decisive impact on RNA's fate. In rare instances, uridylation is an intrinsic step in the maturation of noncoding RNAs like for the U6 spliceosomal RNA or mitochondrial guide RNAs in trypanosomes. Uridylation can also switch specific miRNA precursors from a degradative to a processing mode. This switch depends on the number of uridines added which is regulated by the cellular context. Yet, the typical consequence of uridylation on mature noncoding RNAs or their precursors is to accelerate decay. Importantly, mRNAs are also tagged by uridylation. In fact, the advent of novel high throughput sequencing protocols has recently revealed the pervasiveness of mRNA uridylation, from plants to humans. As for noncoding RNAs, the main function to date for mRNA uridylation is to promote degradation. Yet, additional roles begin to be ascribed to U-tailing such as the control of mRNA deadenylation, translation control and possibly storage. All these new findings illustrate that we are just beginning to appreciate the diversity of roles played by RNA uridylation and its full temporal and spatial implication in regulating gene expression.

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Nucleotide specificity of the human terminal nucleotidyltransferase Gld2 (TUT2)

Cited by 27 publications

References 63 publications

Biochemical and structural bioinformatics studies of fungal CutA nucleotidyltransferases explain their unusual specificity toward CTP and increased tendency for cytidine incorporation at the 3′-terminal positions of synthesized tails

Biochemical and structural bioinformatics studies of fungal CutA nucleotidyltransferases explain their unusual specificity toward CTP and increased tendency for cytidine incorporation at the 3′-terminal positions of synthesized tails

Unbiased screen of RNA tailing enzymes at single-nucleotide resolution reveals a poly(UG) polymerase required for genome integrity and RNA silencing

RNA uridylation: a key posttranscriptional modification shaping the coding and noncoding transcriptome

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