Evolutionary conservation of post-transcriptional 3' end adenylation of small RNAs: S. cerevisiae signal recognition particle RNA and U2 small nuclear RNA are post-transcriptionally adenylated

The translational regulation of maternal mRNAs in time and space

Since their discovery, the study of maternal mRNAs has led to the identification of mechanisms underlying their spatiotemporal regulation within the context of oogenesis and early embryogenesis. Following synthesis in the oocyte, maternal mRNAs are translationally silenced and sequestered into storage in cytoplasmic granules. At the same time, their unique distribution patterns throughout the oocyte and embryo are tightly controlled and connected to their functions in downstream embryonic processes. At certain points in oogenesis and early embryogenesis, maternal mRNAs are translationally activated to perform their functions in a timely manner. The cytoplasmic polyadenylation machinery is responsible for the translational activation of maternal mRNAs, and its role in initiating the maternal to zygotic transition events has recently come to light. Here, we summarize the current knowledge on maternal mRNA regulation, with particular focus on cytoplasmic polyadenylation as a mechanism for translational regulation.

Integrity of SRP RNA is ensured by La and the nuclear RNA quality control machinery

The RNA component of signal recognition particle (SRP) is transcribed by RNA polymerase III, and most steps in SRP biogenesis occur in the nucleolus. Here, we examine processing and quality control of the yeast SRP RNA (scR1). In common with other pol III transcripts, scR1 terminates in a U-tract, and mature scR1 retains a U_4–5 sequence at its 3′ end. In cells lacking the exonuclease Rex1, scR1 terminates in a longer U_5–6 tail that presumably represents the primary transcript. The 3′ U-tract of scR1 is protected from aberrant processing by the La homologue, Lhp1 and overexpressed Lhp1 apparently competes with both the RNA surveillance system and SRP assembly factors. Unexpectedly, the TRAMP and exosome nuclear RNA surveillance complexes are also implicated in protecting the 3′ end of scR1, which accumulates in the nucleolus of cells lacking the activities of these complexes. Misassembled scR1 has a primary degradation pathway in which Rrp6 acts early, followed by TRAMP-stimulated exonuclease degradation by the exosome. We conclude that the RNA surveillance machinery has key roles in both SRP biogenesis and quality control of the RNA, potentially facilitating the decision between these alternative fates.

Traces of post-transcriptional RNA modifications in deep sequencing data

Many aspects of the RNA maturation leave traces in RNA sequencing data in the form of deviations from the reference genomic DNA. This includes, in particular, genomically non-encoded nucleotides and chemical modifications. The latter leave their signatures in the form of mismatches and conspicuous patterns of sequencing reads. Modified mapping procedures focusing on particular types of deviations can help to unravel post-transcriptional modification, maturation and degradation processes. Here, we focus on small RNA sequencing data that is produced in large quantities aimed at the analysis of microRNA expression. Starting from the recovery of many well known modified sites in tRNAs, we provide evidence that modified nucleotides are a pervasive phenomenon in these data sets. Regarding non-encoded nucleotides we concentrate on CCA tails, which surprisingly can be found in a diverse collection of transcripts including sub-populations of mature microRNAs. Although small RNA sequencing libraries alone are insufficient to obtain a complete picture, they can inform on many aspects of the complex processes of RNA maturation.

Biogenesis of the signal recognition particle

Assembly of ribonucleoprotein complexes is a facilitated quality-controlled process that typically includes modification to the RNA component from precursor to mature form. The SRP (signal recognition particle) is a cytosolic ribonucleoprotein that catalyses protein targeting to the endoplasmic reticulum. Assembly of SRP is largely nucleolar, and most of its protein components are required to generate a stable complex. A pre-SRP is exported from the nucleus to the cytoplasm where the final protein, Srp54p, is incorporated. Although this outline of the SRP assembly pathway has been determined, factors that facilitate this and/or function in quality control of the RNA are poorly understood. In the present paper, the SRP assembly pathway is summarized, and evidence for the involvement of both the Rex1p and nuclear exosome nucleases and the TRAMP (Trf4-Air2-Mtr4p polyadenylation) adenylase in quality control of SRP RNA is discussed. The RNA component of SRP is transcribed by RNA polymerase III, and both La, which binds all newly transcribed RNAs generated by this enzyme, and the nuclear Lsm complex are implicated in SRP RNA metabolism.

Adenylation of plant miRNAs

The modification or degradation of RNAs including miRNAs may play vital roles in regulating RNA functions. The polyadenylation- and exosome-mediated RNA decay is involved in the degradation of plant RNAs including the primary miRNA processing intermediates. However, plant miRNA levels are not affected by exosome depletion. Here, we report the cloning of a large number of 5' and/or 3' truncated versions of the known miRNAs from various tissues of Populus trichocarpa (black cottonwood). It suggests that plant miRNAs may be degraded through either 5' to 3' or 3' to 5' exonucleolytic digestion. We also show that a significant portion of the isolated miRNAs contains, at the 3'-end, one or a few post-transcriptionally added adenylic acid residues, which are distinct in length from the polyadenylate tail added to other plant RNAs for exosome-mediated degradation. Using an in vitro miRNA degradation system, where synthesized miRNA oligos were degraded in extracts of P. trichocarpa cells, we revealed that the adenylated miRNAs were degraded slower than others without adenylation. It indicates that addition of adenylic acid residues on the 3'-end plays a negative role in miRNA degradation. Our results provide new information for understanding the mechanism of miRNA degradation.

U2 small nuclear RNA is a substrate for the CCA-adding enzyme (tRNA nucleotidyltransferase)

The CCA-adding enzyme builds and repairs the 3' terminus of tRNA. Approximately 65% of mature human U2 small nuclear RNA (snRNA) ends in 3'-terminal CCA, as do all mature tRNAs; the other 35% ends in 3' CC or possibly 3' C. The 3'-terminal A of U2 snRNA cannot be encoded because the 3' end of the U2 snRNA coding region is CC/CC, where the slash indicates the last encoded nucleotide. The first detectable U2 snRNA precursor contains 10-16 extra 3' nucleotides that are removed by one or more 3' exonucleases. Thus, if 3' exonuclease activity removes the encoded 3' CC during U2 snRNA maturation, as appears to be the case in vitro, the cell may need to build or rebuild the 3'-terminal A, CA, or CCA of U2 snRNA. We asked whether homologous and heterologous class I and class II CCA-adding enzymes could add 3'-terminal A, CA, or CCA to human U2 snRNA lacking 3'-terminal A, CA, or CCA. The naked U2 snRNAs were good substrates for the human CCA-adding enzyme but were inactive with the Escherichia coli enzyme; activity was also observed on native U2 snRNPs. We suggest that the 3' stem/loop of U2 snRNA resembles a tRNA minihelix, the smallest efficient substrate for class I and II CCA-adding enzymes, and that CCA addition to U2 snRNA may take place in vivo after snRNP assembly has begun.

Purification, characterization, and cloning of the cDNA of human signal recognition particle RNA 3'-adenylating enzyme

The 3'-terminal adenylic acid residue in several human small RNAs including signal recognition particle (SRP) RNA, nuclear 7SK RNA, U2 small nuclear RNA, and ribosomal 5S RNA is caused by a post-transcriptional adenylation event (Sinha, K., Gu, J., Chen, Y., and Reddy, R. (1998) J. Biol. Chem. 273, 6853-6859). Using the Alu portion of the SRP RNA as a substrate in an in vitro adenylation assay, we purified an adenylating enzyme that adds adenylic acid residues to SRP/Alu RNA from the HeLa cell nuclear extract. All the peptide sequences obtained by microsequencing of the purified enzyme matched a unique human cDNA corresponding to a new adenylating enzyme having homologies to the well characterized mRNA poly(A) polymerase. The amino terminus region of the human SRP RNA adenylating enzyme showed approximately 75% homology to the amino terminus of the human mRNA poly(A) polymerase that includes the catalytic domain. The carboxyl terminus of the human SRP RNA adenylating enzyme showed less than 25% homology to the carboxyl terminus of poly(A) polymerase, which interacts with other factors and provides specificity. The SRP RNA adenylating enzyme is coded for by a gene located on chromosome 2 in contrast to the poly(A) polymerase gene, which is located on chromosome 14. A recombinant protein for the SRP RNA adenylating enzyme was prepared, and its activity was compared with the purified enzyme from HeLa cells. The data indicate that in addition to the SRP RNA adenylating enzyme, other factors may be required to carry out accurate 3'-end adenylation of SRP RNA.

Identification of a approximately 30S size non-ribosomal Saccharomyces cerevisiae RNA that is rapidly labeled on its 3' end by ATP or UTP

Cell-free extracts prepared from S. cerevisiae cells were incubated in the presence of [alpha-32P]-labeled ATP, CTP, GTP or UTP. An RNA larger than ribosomal 25S RNA with an apparent size of approximately 30S was prominently labeled on its 3' end in the presence of ATP or UTP but not with CTP or GTP. This labeled RNA was not hybrid-selected by cloned yeast ribosomal DNA; in addition, this approximately 30S RNA was not cleaved by RNase H in the presence of complementary deoxyribooligonucleotides to rRNA. These two lines of evidence show that this approximately 30S RNA is not structurally related to ribosomal RNA gene repeat. The cell-free extracts prepared from yeast cells containing temperature-sensitive poly(A) polymerase adenylated this novel yeast RNA at restrictive temperature with efficiency similar to extracts prepared from wild-type yeast cells. These data show that the enzyme responsible for adenylation of this approximately 30S RNA is distinct from mRNA poly(A) polymerase. While the human SRP RNA 3' adenylating enzyme in the HeLa cell extract adenylated human SRP or Alu RNAs, the yeast adenylating enzyme did not adenylate the human SRP or Alu RNAs in vitro; these data indicate species specificity for this adenylating enzyme.