Complex intron generation in the yeast genus Lipomyces.

In primary transcripts of eukaryotic nuclear genes, coding sequences are often interrupted by U2-type introns. Such intervening sequences can constitute complex introns excised by consecutive splicing reactions. The origin of spliceosomal introns is a vexing problem. Sequence variation existent across fungal taxa provides means to study their structure and evolution. In one class of complex introns called [D] stwintrons, an (internal) U2 intron is nested within the 5'-donor element of another (external) U2 intron. In the gene for a reticulon-like protein in species of the ascomycete yeast genus Lipomyces, the most 5' terminal intron position is occupied by one of three complex intervening sequences consistent of differently nested U2 intron units, as demonstrated in L. lipofer, L. suomiensis, and L. starkeyi. In L. starkeyi, the donor elements of the constituent introns are abutting and the complex intervening sequence can be excised alternatively either with one standard splicing reaction or, as a [D] stwintron, by two consecutive reactions. Our work suggests how [D] stwintrons could emerge by the appearance of new functional splice sites within an extant intron. The stepwise stwintronisation mechanism may involve duplication of the functional intron donor element of the ancestor intron.

A spliceosomal twin intron (stwintron) participates in both exon skipping and evolutionary exon loss.

Spliceosomal twin introns (stwintrons) are introns where any of the three consensus sequences involved in splicing is interrupted by another intron (internal intron). In Aspergillus nidulans, a donor-disrupted stwintron (intron-1) is extant in the transcript encoding a reticulon-like protein. The orthologous transcript of Aspergillus niger can be alternatively spliced; the exon downstream the stwintron could be skipped by excising a sequence that comprises this stwintron, the neighbouring intron-2, and the exon bounded by these. This process involves the use of alternative 3' splice sites for the internal intron, the resulting alternative intervening sequence being a longer 3'-extended stwintron. In 29 species of Onygenales, a multi-step splicing process occurs in the orthologous transcript, in which a complex intervening sequence including the stwintron and neigbouring intron-2, generates by three splicing reactions a "second order intron" which must then be excised with a fourth splicing event. The gene model in two species can be envisaged as one canonical intron (intron-1) evolved from this complex intervening sequence of nested canonical introns found elsewhere in Onygenales. Postulated splicing intermediates were experimentally verified in one or more species. This work illustrates a role of stwintrons in both alternative splicing and the evolution of intron structure.

Emergence and loss of spliceosomal twin introns.

BACKGROUND: In the primary transcript of nuclear genes, coding sequences-exons-usually alternate with non-coding sequences-introns. In the evolution of spliceosomal intron-exon structure, extant intron positions can be abandoned and new intron positions can be occupied. Spliceosomal twin introns ("stwintrons") are unconventional intervening sequences where a standard "internal" intron interrupts a canonical splicing motif of a second, "external" intron. The availability of genome sequences of more than a thousand species of fungi provides a unique opportunity to study spliceosomal intron evolution throughout a whole kingdom by means of molecular phylogenetics. RESULTS: A new stwintron was encountered in Aspergillus nidulans and Aspergillus niger. It is present across three classes of Leotiomyceta in the transcript of a well-conserved gene encoding a putative lipase (lipS). It occupies the same position as a standard intron in the orthologue gene in species of the early divergent classes of the Pezizomycetes and the Orbiliomycetes, suggesting that an internal intron has appeared within a pre-extant intron. On the other hand, the stwintron has been lost from certain taxa in Leotiomycetes and Eurotiomycetes at several occasions, most likely by a mechanism involving reverse transcription and homologous recombination. Another ancient stwintron present across whole Pezizomycotina orders-in the transcript of the bifunctional biotin biosynthesis gene bioDA-occurs at the same position as a standard intron in many species of non-Dikarya. Nevertheless, also the bioDA stwintron has disappeared from certain lineages within the taxa where it occurs, i.e., Sordariomycetes and Botryosphaeriales. Intriguingly, only the internal intron was lost from the Sordariomycetes bioDA stwintron at all but one occasion, leaving a standard intron in the same position, while where the putative lipase stwintron was lost, no intronic sequences remain. CONCLUSIONS: Molecular phylogeny of the peptide product was used to monitor the existence and fate of a stwintron in the transcripts of two neatly defined fungal genes, encoding well conserved proteins. Both defining events-stwintron emergence and loss-can be explained with extant models for intron insertion and loss. We thus demonstrate that stwintrons can serve as model systems to study spliceosomal intron evolution.

A mechanism for a single nucleotide intron shift.

Spliceosomal introns can occupy nearby rather than identical positions in orthologous genes (intron sliding or shifting). Stwintrons are complex intervening sequences, where an 'internal' intron interrupts one of the sequences essential for splicing, generating after its excision, a newly formed canonical intron defined as 'external'. In one experimentally demonstrated configuration, two alternatively excised internal introns, overlapping by one G, disrupt respectively the donor and the acceptor sequence of an external intron, leading to mRNAs encoding identical proteins. In a gene encoding a DHA1 antiporter in Pezizomycotina, we find a variety of predicted intron configurations interrupting the DNA stretch encoding a conserved peptidic sequence. Some sport a stwintron where the internal intron interrupts the donor of the external intron (experimentally confirmed for Aspergillus nidulans). In others, we found and demonstrate (for Trichoderma reesei) alternative, overlapping internal introns. Discordant canonical introns, one nt apart, are present in yet other species, exactly as predicted by the alternative loss of either of the internal introns at the DNA level from an alternatively spliced stwintron. An evolutionary pathway of 1 nt intron shift, involving an alternatively spliced stwintron intermediate is proposed on the basis of the experimental and genomic data presented.

Characterization of a second physiologically relevant lactose permease gene (lacpB) in Aspergillus nidulans.

In Aspergillus nidulans, uptake rather than hydrolysis is the rate-limiting step of lactose catabolism. Deletion of the lactose permease A-encoding gene (lacpA) reduces the growth rate on lactose, while its overexpression enables faster growth than wild-type strains are capable of. We have identified a second physiologically relevant lactose transporter, LacpB. Glycerol-grown mycelia from mutants deleted for lacpB appear to take up only minute amounts of lactose during the first 60 h after a medium transfer, while mycelia of double lacpA/lacpB-deletant strains are unable to produce new biomass from lactose. Although transcription of both lacp genes was strongly induced by lactose, their inducer profiles differ markedly. lacpA but not lacpB expression was high in d-galactose cultures. However, lacpB responded strongly also to ß-linked glucopyranose dimers cellobiose and sophorose, while these inducers of the cellulolytic system did not provoke any lacpA response. Nevertheless, lacpB transcript was induced to higher levels on cellobiose in strains that lack the lacpA gene than in a wild-type background. Indeed, cellobiose uptake was faster and biomass formation accelerated in lacpA deletants. In contrast, in lacpB knockout strains, growth rate and cellobiose uptake were considerably reduced relative to wild-type, indicating that the cellulose and lactose catabolic systems employ common elements. Nevertheless, our permease mutants still grew on cellobiose, which suggests that its uptake in A. nidulans prominently involves hitherto unknown transport systems.