Gérard Keith

A New Yeast Poly(A) Polymerase Complex Involved in RNA Quality Control

Eukaryotic cells contain several unconventional poly(A) polymerases in addition to the canonical enzymes responsible for the synthesis of poly(A) tails of nuclear messenger RNA precursors. The yeast protein Trf4p has been implicated in a quality control pathway that leads to the polyadenylation and subsequent exosome-mediated degradation of hypomethylated initiator tRNAMet (tRNAi Met). Here we show that Trf4p is the catalytic subunit of a new poly(A) polymerase complex that contains Air1p or Air2p as potential RNA-binding subunits, as well as the putative RNA helicase Mtr4p. Comparison of native tRNAi Met with its in vitro transcribed unmodified counterpart revealed that the unmodified RNA was preferentially polyadenylated by affinity-purified Trf4 complex from yeast, as well as by complexes reconstituted from recombinant components. These results and additional experiments with other tRNA substrates suggested that the Trf4 complex can discriminate between native tRNAs and molecules that are incorrectly folded. Moreover, the polyadenylation activity of the Trf4 complex stimulated the degradation of unmodified tRNAi Met by nuclear exosome fractions in vitro. Degradation was most efficient when coupled to the polyadenylation activity of the Trf4 complex, indicating that the poly(A) tails serve as signals for the recruitment of the exosome. This polyadenylation-mediated RNA surveillance resembles the role of polyadenylation in bacterial RNA turnover.

Small finger protein of avian and murine retroviruses has nucleic acid annealing activity and positions the replication primer tRNA onto genomic RNA.

Retrovirus virions carry a diploid genome associated with a large number of small viral finger protein molecules which are required for encapsidation. Our present results show that finger protein p12 of Rous sarcoma virus (RSV) and p10 of murine leukaemia virus (MuLV) positions replication primer tRNA on the replication initiation site (PBS) at the 5′ end of the RNA genome. An RSV mutant with a Val‐Pro insertion in the finger motif of p12 is able to partially encapsidate genomic RNA but is not infectious because mutated p12 is incapable of positioning the replication primer, tRNATrp. Since all known replication competent retroviruses, and the plant virus CaMV, code for finger proteins analogous to RSV p12 or MuLV p10, the initial stage of reverse transcription in avian, mammalian and human retroviruses and in CaMV is probably controlled in an analogous way.

Non-standard translational events in Candida albicans mediated by an unusual seryl-tRNA with a 5'-CAG-3' (leucine) anticodon.

From in vitro translation studies we have previously demonstrated the existence of an apparent efficient UAG (amber) suppressor tRNA in the dimorphic fungus Candida albicans (Santos et al., 1990). Using an in vitro assay for termination codon readthrough the tRNA responsible was purified to homogeneity from C.albicans cells. The determined sequence of the purified tRNA predicts a 5′‐CAG‐3′ anticodon that should decode the leucine codon CUG and not the UAG termination codon as originally hypothesized. However, the tRNA(CAG) sequence shows greater nucleotide homology with seryl‐tRNAs from the closely related yeast Saccharomyces cerevisiae than with leucyl‐tRNAs from the same species. In vitro tRNA‐charging studies demonstrated that the purified tRNA(CAG) is charged with Ser. The gene encoding the tRNA was cloned from C.albicans by a PCR‐based strategy and DNA sequence analysis confirmed both the structure of the tRNA(CAG) and the absence of any introns in the tRNA gene. The copy number of the tRNA(CAG) gene (1–2 genes per haploid genome) is in agreement with the relatively low abundance (< 0.5% total tRNA) of this tRNA. In vitro translation studies revealed that the purified tRNA(CAG) could induce apparent translational bypass of all three termination codons. However, peptide mapping of in vitro translation products demonstrated that the tRNA(CAG) induces translational misreading in the amino‐terminal region of two RNA templates employed, namely the rabbit alpha‐ and beta‐globin mRNAs. These results suggest that the C.albicans tRNA(CAG) is not an ‘omnipotent’ suppressor tRNA but rather may mediate a novel non‐standard translational event in vitro during the translation of the CUG codon. The possible nature of this non‐standard translation event is discussed in the context of both the unusual structural features of the tRNA(CAG) and its in vitro behaviour.

Queuosine modification of the wobble base in tRNAHis influences in vivo decoding properties

The ‘in vivo’ decoding properties of four tRNAHis isoacceptors, two from Drosophila melanogaster and two from brewers yeast, were studied after their microinjection, along with turnip yellow mosaic virus (TYMV) coat protein mRNA, into Xenopus laevis oocytes. The two Drosophila isoacceptors are identical besides containing either a guanosine (G) or the hypermodified nucleoside queuosine (Q) in the wobble position. The brewers yeast isoacceptors differ by four bases in the anticodon stem, and by one base in the amino acceptor stem. Our results show that, under competing ‘in vivo’ conditions, the Drosophila tRNAHis with the anticodon GUG clearly prefers the histidine codon CAC to the codon CAU, whereas little preference is observed for the tRNAHis with the anticodon QUG for the codon CAU, and no preference for either codon by the two yeast isoacceptors. Hence, it can be concluded that the presence of the Q‐base clearly affects the choice of the codon. This is the first demonstration of an ‘in vivo’ codon preference by tRNA isoacceptors differing in the modification of the wobble base during the elongation step of protein synthesis. These results imply that one function of the Q‐base is at the translational level.

The crystal structure of HIV reverse-transcription primer tRNA(Lys,3) shows a canonical anticodon loop.

We have solved to 3.3 A resolution the crystal structure of the HIV reverse-transcription primer tRNA(Lys,3). The overall structure is exactly comparable to the well-known L-shape structure first revealed by yeast tRNA(Phe). In particular, it unambiguously shows a canonical anticodon loop. This contradicts previous results in short RNA fragment studies and leads us to conclude that neither frameshifting specificities of tRNA(Lys) nor tRNA(Lys,3) primer selection by HIV are due to a specific three-dimensional anticodon structure. Comparison of our structure with the results of an NMR study on a hairpin representing a nonmodified anticodon stem-loop makes plausible the conclusion that chemical modifications of the wobble base U34 to 5-methoxycarbonyl-methyl-2-thiouridine and of A37 to 2-methylthio-N-6-threonylcarbamoyl-adenosine would be responsible for a canonical 7-nt anticodon-loop structure, whereas the unmodified form would result in a noncanonical UUU short triloop. The hexagonal crystal packing is remarkable and shows tight dimers of tRNAs forming a right-handed double superhelix. Within the dimers, the tRNAs are associated head-to-tail such that the CCA end of one tRNA interacts with the anticodon of the symmetry-related tRNA. This provides us with a partial view of a codon-anticodon interaction and gives insights into the positioning of residue 37, and of its posttranscriptional modifications, relative to the first base of the codon.

Differential gene expression in mesothelioma.

To investigate the molecular events controlling malignant transformation of human pleural cells, we compared constitutive gene expression of mesothelioma cells to that of pleural cells. Using cDNA microarray and high‐density filter array, we assessed expression levels of >6500 genes. Most of the highly expressed transcripts were common to both cell lines and included genes associated with stress response and DNA repair, outcomes consistent with the radio‐ and chemo‐resistance of mesothelioma. Interestingly, of the fewer than 300 genes that differed between cell lines, most functioned in (i) macromolecule stability, (ii) cell adhesion and recognition, (iii) cell migration (invasiveness), and (iv) extended cell division. Expression levels of several of these genes were confirmed by RT‐PCR and could be useful as diagnostic markers of human mesothelioma.

Detection of enzymatic activity of transfer RNA modification enzymes using radiolabeled tRNA substrates.

The presence of modified ribonucleotides derived from adenosine, guanosine, cytidine, and uridine is a hallmark of almost all cellular RNA, and especially tRNA. The objective of this chapter is to describe a few simple methods that can be used to identify the presence or absence of a modified nucleotide in tRNA and to reveal the enzymatic activity of particular tRNA-modifying enzymes in vitro and in vivo. The procedures are based on analysis of prelabeled or postlabeled nucleotides (mainly with [(32)P] but also with [(35)S], [(14)C] or [(3)H]) generated after complete digestion with selected nucleases of modified tRNA isolated from cells or incubated in vitro with modifying enzyme(s). Nucleotides of the tRNA digests are separated by two-dimensional (2D) thin-layer chromatography on cellulose plates (TLC), which allows establishment of base composition and identification of the nearest neighbor nucleotide of a given modified nucleotide in the tRNA sequence. This chapter provides useful maps for identification of migration of approximately 70 modified nucleotides on TLC plates by use of two different chromatographic systems. The methods require only a few micrograms of purified tRNA and can be run at low cost in any laboratory.

The yeast Ty3 retrotransposon contains a 5′–3′ bipartite primer‐binding site and encodes nucleocapsid protein NCp9 functionally homologous to HIV‐1 NCp7

Retroviruses, including HIV‐1 and the distantly related yeast retroelement Ty3, all encode a nucleoprotein required for virion structure and replication. During an in vitro comparison of HIV‐1 and Ty3 nucleoprotein function in RNA dimerization and cDNA synthesis, we discovered a bipartite primer‐binding site (PBS) for Ty3 composed of sequences located at opposite ends of the genome. Ty3 cDNA synthesis requires the 3′ PBS for primer tRNAiMet annealing to the genomic RNA, and the 5′ PBS, in cis or in trans, as the reverse transcription start site. Ty3 RNA alone is unable to dimerize, but formation of dimeric tRNAiMet bound to the PBS was found to direct dimerization of Ty3 RNA–tRNAiMet. Interestingly, HIV‐1 nucleocapsid protein NCp7 and Ty3 NCp9 were interchangeable using HIV‐1 and Ty3 RNA template–primer systems. Our findings impact on the understanding of non‐canonical reverse transcription as well as on the use of Ty3 systems to screen for anti‐NCp7 drugs.

Identification of modifications in microbial, native tRNA that suppress immunostimulatory activity

2′-O-methylation of guanosine 18 is a naturally occurring tRNA modification that can suppress immune TLR7 responses.

Detection and quantification of modified nucleotides in RNA using thin-layer chromatography.

Identification of a modified nucleotide and its localization within an RNA molecule is a difficult task. Only direct sequencing of purified RNA molecules and high-performance liquid chromatography mass spectrometry analysis of purified RNA fragments allow determination of both the type and location of a given modified nucleotide within an RNA of 50-150 nt in length. The objective of this chapter is to describe in detail a few simple procedures that we have found particularly suited for the detection, localization, and quantification of modified nucleotides within an RNA of known sequence. The methods can also be used to reveal the enzymatic activity of a particular RNA-modifying enzyme in vitro or in vivo. The procedures are based on the use of radiolabeled RNA (with [32P], [14C], or [3H]) or [32P]-postlabeled oligonucleotides and two-dimensional thin-layer chromatography of labeled nucleotides on cellulose plates. This chapter provides useful maps of the migration characteristics of 70 modified nucleotides on thin-layer cellulose plates.