Drosophila melanogaster Thor and response to Candida albicans infection.

We used Drosophila melanogaster macrophage-like Schneider 2 (S2) cells as a model to study cell-mediated innate immunity against infection by the opportunistic fungal pathogen Candida albicans. Transcriptional profiling of S2 cells coincubated with C. albicans cells revealed up-regulation of several genes. One of the most highly up-regulated genes during this interaction is the D. melanogaster translational regulator 4E-BP encoded by the Thor gene. Analysis of Drosophila 4E-BP(null) mutant survival upon infection with C. albicans showed that 4E-BP plays an important role in host defense, suggesting a role for translational control in the D. melanogaster response to C. albicans infection.

Double-hairpin elements in the mitochondrial DNA of allomyces: evidence for mobility.

The mitochondrial DNA (mtDNA) of the chytridiomycete fungus Allomyces macrogynus contains 81 G+C-rich sequence elements that are 26-79 bases long and can be folded into a unique secondary structure consisting of two stem-loops. At the primary sequence level, the conservation of these double-hairpin elements (DHEs) is variable, ranging from marginal to complete identity. Forty of these DHEs are inserted in intergenic regions, 35 in introns, and 6 in variable regions of rRNA genes. Ten DHEs are inserted into other DHE elements (twins); two even form triplets. A comparison of DHE sequences shows that loop regions contain more sequence variation than helical regions and that the latter often contain compensatory base changes. This suggests a functional importance of the DHE secondary structure. We further identified nine DHEs in a 4-kb region of Allomyces arbusculus, a close relative of A. macrogynus. Eight of these DHEs are highly similar in sequence (90%-100%) to those in A. macrogynus, but only five are inserted at the same positions as in A. macrogynus. Interestingly, DHEs are also found in the mtDNAs of other chytridiomycetes, as well as certain zygomycete and ascomycete fungi. The overall distribution pattern of DHEs in fungal mtDNAs suggests that they are mobile elements.

The fungal mitochondrial genome project: evolution of fungal mitochondrial genomes and their gene expression.

The goal of the fungal mitochondrial genome project (FMGP) is to sequence complete mitochondrial genomes for a representative sample of the major fungal lineages; to analyze the genome structure, gene content, and conserved sequence elements of these sequences; and to study the evolution of gene expression in fungal mitochondria. By using our new sequence data for evolutionary studies, we were able to construct phylogenetic trees that provide further solid evidence that animals and fungi share a common ancestor to the exclusion of chlorophytes and protists. With a database comprising multiple mitochondrial gene sequences, the level of support for our mitochondrial phylogenies is unprecedented, in comparison to trees inferred with nuclear ribosomal RNA sequences. We also found several new molecular features in the mitochondrial genomes of lower fungi, including: (1) tRNA editing, which is the same type as that found in the mitochondria of the amoeboid protozoan Acanthamoeba castellanii; (2) two novel types of putative mobile DNA elements, one encoding a site-specific endonuclease that confers mobility on the element, and the other constituting a class of highly compact, structured elements; and (3) a large number of introns, which provide insights into intron origins and evolution. Here, we present an overview of these results, and discuss examples of the diversity of structures found in the fungal mitochondrial genome.

Mitochondrial tRNAs in the lower fungus Spizellomyces punctatus: tRNA editing and UAG 'stop' codons recognized as leucine.

The mitochondrial DNA of the chytridiomycete fungus Spizellomyces punctatusen codes only eight tRNAs, although a minimal set of 24-25 tRNAs is normally found in fungi. One of these tRNAs has a CAU anticodon and is structurally related to leucine tRNAs, which would permit the translation of the UAG 'stop' codons that occur in most of its protein genes. The predicted structures of all S. punctatus tRNAs have the common feature of containing one to three mis-pairings in the first three positions of their acceptor stems. Such mis-pairing is expected to impair proper folding and processing of tRNAs from their precursors. Five of these eight RNAs were shown to be edited at the RNA level, in the 5'portion of the molecules. These changes include both pyrimidine to purine and A to G substitutions that restore normal pairing in the acceptor stem. Editing was not found at other positions of the tRNAs, or in the mitochondrial mRNAs of S. punctatus. While tRNA editing has not been observed in other fungi, the editing pattern inS.punctatus is virtually identical to that described in the amoeboid protozoan Acanthamoeba castellanii. If this type of mitochondrial tRNA editing has originated from their common ancestor, one has to assume that it was independently lost in plants, animals and in most fungi. Alternatively, editing might have evolved independently, or the genes coding for the components of the editing machinery were laterally transferred.

Interspecific transfer of mitochondrial genes in fungi and creation of a homologous hybrid gene.

In eukaryotes, horizontal gene transfer is a rare event. Here we show that the mitochondrial genome of a lower fungus, Allomyces macrogynus, has an extra DNA segment not present in a close relative, Allomyces arbusculus. This insert consists of the C terminus of a foreign gene encoding a subunit of the ATP synthetase complex (atp6) plus an open reading frame encoding an endonuclease. The inserted atp6 portion is fused in phase to the resident gene, resulting in expression of a hybrid atp6 gene and the displacement of the original C-terminal atp6 region. We present evidence that this insertion may have been acquired by interspecific transfer and we discuss the possible role of the endonuclease in this process.