Post-transcriptional modification of the tRNA anticodon loop is critical for translation. Yeast Trm7 is required for 29-O-methylation of C 32 and N 34 of tRNA Phe , tRNA Trp , and tRNA Leu(UAA) to form Cm 32 and Nm 34 , and trm7-D mutants have severe growth and translation defects, but the reasons for these defects are not known. We show here that overproduction of tRNA Phe suppresses the growth defect of trm7-D mutants, suggesting that the crucial biological role of Trm7 is the modification of tRNA Phe . We also provide in vivo and in vitro evidence that Trm7 interacts with ORF YMR259c (now named Trm732) for 29-O-methylation of C 32 , and with Rtt10 (named Trm734) for 29-O-methylation of N 34 of substrate tRNAs and provide evidence for a complex circuitry of anticodon loop modification of tRNA Phe , in which formation of Cm 32 and Gm 34 drives modification of m 1 G 37 (1-methylguanosine) to yW (wyebutosine). Further genetic analysis shows that the slow growth of trm7-D mutants is due to the lack of both Cm 32 and Nm 34 , and the accompanying loss of yW, because trm732-D trm734-D mutants phenocopy trm7-D mutants, whereas each single mutant is healthy; nonetheless, TRM732 and TRM734 each have distinct roles, since mutations in these genes have different genetic interactions with trm1-D mutants, which lack m 2,2 G 26 in their tRNAs. We speculate that 29-O-methylation of the anticodon loop may be important throughout eukaryotes because of the widespread conservation of Trm7, Trm732, and Trm734 proteins, and the corresponding modifications, and because the putative human TRM7 ortholog FTSJ1 is implicated in nonsyndromic X-linked mental retardation.
tRNAs traffic between the nucleus and the cytoplasm in response to nutrient availability. Using a new assay to track tRNA within cells, we show that tRNA nuclear import is constitutive, whereas tRNA reexport to the cytoplasm is regulated. Msn5 functions only in tRNA re-export, whereas Los1 functions in both the primary and reexport steps.
Ribonucleotidyl transferases (rNTases) add non-templated ribonucleotides to diverse RNAs. We developed TRAID-Seq, a screening strategy in S. cerevisiae to identify sequences added to a reporter RNA at single-nucleotide resolution by overexpressing candidate enzymes from different organisms. The rNTase activities of 22 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 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.
A single protein can bind and regulate many mRNAs. Multiple proteins with similar specificities often bind and control overlapping sets of mRNAs. Yet little is known about the architecture or dynamics of overlapped networks. We focused on three proteins with similar structures and related RNA-binding specificities-Puf3p, Puf4p, and Puf5p of Using RNA Tagging, we identified a "super-network" comprised of four subnetworks: Puf3p, Puf4p, and Puf5p subnetworks, and one controlled by both Puf4p and Puf5p. The architecture of individual subnetworks, and thus the super-network, is determined by competition among particular PUF proteins to bind mRNAs, their affinities for binding elements, and the abundances of the proteins. The super-network responds dramatically: The remaining network can either expand or contract. These strikingly opposite outcomes are determined by an interplay between the relative abundance of the RNAs and proteins, and their affinities for one another. The diverse interplay between overlapping RNA-protein networks provides versatile opportunities for regulation and evolution.
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