Determinants that specify the integration pattern of retrotransposon Tf1 in the fbp1 promoter of Schizosaccharomyces pombe.

Long terminal repeat (LTR) retrotransposons are closely related to retroviruses and, as such, are important models for the study of viral integration and target site selection. The transposon Tf1 of Schizosaccharomyces pombe integrates with a strong preference for the promoters of polymerase II (Pol II)-transcribed genes. Previous work in vivo with plasmid-based targets revealed that the patterns of insertion were promoter specific and highly reproducible. To determine which features of promoters are recognized by Tf1, we studied integration in a promoter that has been characterized. The promoter of fbp1 has two upstream activating sequences, UAS1 and UAS2. We found that integration was targeted to two windows, one 180 nucleotides (nt) upstream and the other 30 to 40 nt downstream of UAS1. A series of deletions in the promoter showed that the integration activities of these two regions functioned autonomously. Integration assays of UAS2 and of a synthetic promoter demonstrated that strong promoter activity alone was not sufficient to direct integration. The factors that modulate the transcription activities of UAS1 and UAS2 include the activators Atf1p, Pcr1p, and Rst2p as well as the repressors Tup11p, Tup12p, and Pka1p. Strains lacking each of these proteins revealed that Atf1p alone mediated the sites of integration. These data indicate that Atf1p plays a direct and specific role in targeting integration in the promoter of fbp1.

Retrotransposon Tf1 is targeted to Pol II promoters by transcription activators.

The LTR-retrotransposon Tf1 preserves the coding capacity of its host Schizosaccharomyces pombe by integrating upstream of open reading frames (ORFs). To determine which features of the target sites were recognized by the transposon, we introduced plasmids containing candidate insertion sites into S. pombe and mapped the positions of integration. We found that Tf1 was targeted specifically to the promoters of Pol II-transcribed genes. A detailed analysis of integration in plasmids that contained either ade6 or fbp1 revealed insertions occurred in the promoters at positions where transcription factors bound. Further experiments revealed that the activator Atf1p and its binding site were required for directing integration to the promoter of fbp1. An interaction between Tf1 integrase and Atf1p was observed, indicating that integration at fbp1 was mediated by the activator bound to its promoter. Surprisingly, we found Tf1 contained sequences that activated transcription, and these substituted for elements of the ade6 promoter disrupted by integration.

Translation of a yeast mitochondrial tRNA synthetase initiated at redundant non-AUG codons.

Although initiation of translation at non-AUG codons occurs occasionally in prokaryotes and higher eukaryotes, it has not been reported in yeast until very recently. Evidence presented here shows that redundant ACG codons are recognized as alternative translation start sites for ALA1, the only gene in Saccharomyces cerevisiae coding for alanyl-tRNA synthetase. ALA1 is shown to be a bifunctional gene that provides both cytoplasmic and mitochondrial activities. Unlike most bifunctional genes that contain alternative in-frame AUG initiators, there is only one AUG codon, designated AUG1, close to the 5'-end of the ALA1 open reading frame. Transcriptional mapping identified three overlapping transcripts, with 5'-ends at positions 54, 105, and 117 nucleotides upstream of AUG1, respectively. Site-specific mutagenesis demonstrated that the cytoplasmic and mitochondrial functions of ALA1 are provided by two protein isoforms with distinct amino termini; that is, a short cytoplasmic form initiated at AUG1 and a longer mitochondrial isoform initiated at two upstream in-frame ACG codons, i.e. ACG(-25) and ACG(-24). These two ACG codons function redundantly in initiation of translation. Either codon can function in the absence of the other. The short transcript appears to serve as the template for the cytoplasmic form, whereas the longer transcripts are likely to code for both isoforms via alternative initiation. Because yeast ribosomes in general cannot efficiently recognize a non-AUG initiator, this unique feature of redundancy of non-AUG initiators in a single mRNA may in itself represent a novel paradigm for translation initiation from poor initiators.