Gene architecture directs splicing outcome in separate nuclear spatial regions

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Recovery of an Acanthamoeba strain with two group I introns in the nuclear 18S rRNA gene

Nuclear group I introns are parasitic mobile genetic elements occurring in the ribosomal RNA genes of a large variety of microbial eukaryotes. In Acanthamoeba, group I introns were found occurring in the 18S rDNA at four distinct insertion sites. Introns are present as single elements in various strains belonging to four genotypes, T3 (A. griffini), T4 (A. castellanii complex), T5 (A. lenticulata) and T15 (A. jacobsi). While multiple introns can frequently be found in the rDNA of several algae, fungi and slime moulds, they are usually rare and present as single elements in amoebae. We reported herein the characterization of an A. lenticulata strain containing two introns in its 18S rDNA. They are located to already known sites and show basal relationships with respective homologous introns present in the other T5 strains. This is the first and unique reported case of multiple nuclear introns in Acanthamoeba.     

Structure and Expression of the Tobacco Nuclear Gene Encoding RNA-binding Protein RZ-1: The Existence of an Intron in the 3'-Untranslated Region

We have previously characterized a tobacco cDNA encoding a noveltype RNA-binding protein (RZ-1), which contains a zinc fingermotif in addition to a consensus sequence-type RNA-binding domainand is localized in the nucleus. Here we isolated its genomicclone from a Nicotiana sylvestris genomic library. Southernblot analysis suggested that RZ-1 is coded for by a single locusper haploid genome. Comparison of the cDNA and genomic sequencesindicated that the RZ-1 gene contains two introns, one in thecoding region and another in the 3'-untranslated region. RT-PCRand ribonuclease protection analyses showed that splicing ofRZ-1 pre-mRNA occurs efficiently. The RZ-1 protein is activelysynthesized in rapidly dividing tobacco cells, as demonstratedby immunoblot analysis.     

In vivo analysis of intron processing using splicing-dependent reporter gene assays

The mechanisms of intron recognition and processing have been well-studied in mammals and yeast, but in plants the biochemistry of splicing is not known and the rules for intron recognition are not clearly defined. To increase understanding of intron processing in plants, we have constructed new pairs of vectors, pSuccess and pFail, to assess the efficiency of splicing in maize cultured cells. In the pFail series we use translation of pre-mRNA to monitor the amount of unspliced RNA. We inserted an ATG codon in the Bz2 (Bronze-2) intron in frame with luciferase: this construct will express luciferase activity only when splicing fails. In the pSuccess series the spliced message is monitored by inserting an ATG upstream of the Bz2 intron in frame with luciferase: this construct will express luciferase activity only when splicing succeeds. We show here, using both the wild-type Bz2 intron and the same intron with splice site mutations, that the efficiency of splicing can be estimated by the ratio between the luciferase activities of the vector pairs. We also show that mutations in the unique U-rich motif inside the intron can modulate splicing. In addition, a GC-rich insertion in the first exon increases the efficiency of splicing, suggesting that exons also play an important role in intron recognition and/or processing.