The small serine-threonine protein SIP2 interacts with STE12 and is involved in ascospore germination in Sordaria macrospora.

In fungi, the homoeodomain protein STE12 controls diverse developmental processes, and derives its regulatory specificity from different protein interactions. We recently showed that in the homothallic ascomycete Sordaria macrospora, STE12 is essential for ascospore development, and is able to interact with the alpha-domain mating-type protein SMTA-1 and the MADS box protein MCM1. To further evaluate the functional roles of STE12, we used the yeast two-hybrid approach to identify new STE12-interacting partners. Using STE12 as bait, a small, serine-threonine-rich protein (designated STE12-interacting protein 2, SIP2) was identified. SIP2 is conserved among members of the fungal class Sordariomycetes. In vivo localization studies revealed that SIP2 was targeted to the nucleus and cytoplasm. The STE12/SIP2 interaction was further confirmed in vivo by bimolecular fluorescence complementation. Nuclear localization of SIP2 was apparently mediated by STE12. Unlike deletion of ste12, deletion of sip2 in S. macrospora led to only a slight decrease in ascospore germination, and no other obvious morphological phenotype. In comparison to the Δste12 single knockout strain, ascospore germination was significantly increased in a Δsip2/ste12 double knockout strain. Our data provide evidence for a regulatory role of the novel fungal protein SIP2 in ascospore germination.

SmATG7 is required for viability in the homothallic ascomycete Sordaria macrospora.

In filamentous ascomycetes, autophagy is involved in several developmental processes. Nevertheless, until now little is known about its role in fruiting-body development. We therefore isolated a gene of the homothallic ascomycete Sordaria macrospora with high sequence similarity to the Saccharomyces cerevisiae autophagy-related gene ATG7, encoding a core autophagy regulator. This is the first characterization of an ATG7 homolog in filamentous ascomycetes. A S. cerevisiae complementation assay demonstrated that the S. macrospora Smatg7 gene functionally replaces the yeast homolog. We were not able to generate a homokaryotic knock-out mutant in S. macrospora, suggesting that Smatg7 is required for viability. However, a heterokaryotic DeltaSmatg7/Smatg7 strain and transformants generated by RNA interference showed considerable morphological phenotypes during fruiting-body development. Using real-time PCR, we demonstrated that in the wild type, the transcriptional expression of Smatg7 is markedly up-regulated under amino acid starvation conditions and at late stages during sexual development. Moreover, we showed that transcriptionally down-regulation of Smatg7 disturbs autophagy in S. macrospora.

Inteins and introns within the prp8 -gene of four Eupenicillium species.

Inteins are protein-intervening sequences that are translated with the host protein and can self-excise themselves post-translationally in an autocatalytic process. The flanking regions--called exteins--are then re-ligated with a new peptide bond, resulting in a mature host protein. Previously, we have identified inteins in the highly conserved 3.2 region of the PRP8 protein from species of the genus Penicillium. These inteins are integrated at the same position as that which has recently been described in PRP8 proteins from different strains of Cryptococcus neoformans and several ascomycetes. In this study, we investigated the presence of PRP8 inteins in four members of the genus Eupenicillium. Two species of this genus, Eupenicillium crustaceum and Eupenicillium baarnense, contain an intein at the same insertion site. Both inteins are mini-inteins and undergo self-splicing when heterologously expressed with a model host protein in Escherichia coli. Interestingly, we identified introns in the prp8-sequence encoding the 3.2 regions of the PRP8 protein in Eupenicillium meridianum and Eupenicillium terrenum. The introns are located 13 bps and 15 bps downstream of the putative intein insertion site. Here, we consider that the lack of inteins in these two species might be due to the prevention of endonuclease-mediated intein propagation in the intron-containing prp8-sequences.

A STE12 homologue of the homothallic ascomycete Sordaria macrospora interacts with the MADS box protein MCM1 and is required for ascosporogenesis.

The MADS box protein MCM1 controls diverse developmental processes and is essential for fruiting body formation in the homothallic ascomycete Sordaria macrospora. MADS box proteins derive their regulatory specificity from a wide range of different protein interactions. We have recently shown that the S. macrospora MCM1 is able to interact with the alpha-domain mating-type protein SMTA-1. To further evaluate the functional roles of MCM1, we used the yeast two-hybrid approach to identify MCM1-interacting proteins. From this screen, we isolated a protein with a putative N-terminal homeodomain and C-terminal C2/H2-Zn2+ finger domains. The protein is a member of the highly conserved fungal STE12 transcription factor family of proteins and was therefore termed STE12. Furthermore, we demonstrate by means of two-hybrid and far western analysis that in addition to MCM1, the S. macrospora STE12 protein is able to interact with the mating-type protein SMTA-1. Unlike the situation in the closely related heterothallic ascomycete Neurospora crassa, deletion (Delta) of the ste12 gene in S. macrospora neither affects vegetative growth nor fruiting body formation. However, ascus and ascospore development are highly impaired by the Deltaste12 mutation. Our data provide another example of the functional divergence within the fungal STE12 transcription factor family.

A MADS box protein interacts with a mating-type protein and is required for fruiting body development in the homothallic ascomycete Sordaria macrospora.

MADS box transcription factors control diverse developmental processes in plants, metazoans, and fungi. To analyze the involvement of MADS box proteins in fruiting body development of filamentous ascomycetes, we isolated the mcm1 gene from the homothallic ascomycete Sordaria macrospora, which encodes a putative homologue of the Saccharomyces cerevisiae MADS box protein Mcm1p. Deletion of the S. macrospora mcm1 gene resulted in reduced biomass, increased hyphal branching, and reduced hyphal compartment length during vegetative growth. Furthermore, the S. macrospora Deltamcm1 strain was unable to produce fruiting bodies or ascospores during sexual development. A yeast two-hybrid analysis in conjugation with in vitro analyses demonstrated that the S. macrospora MCM1 protein can interact with the putative transcription factor SMTA-1, encoded by the S. macrospora mating-type locus. These results suggest that the S. macrospora MCM1 protein is involved in the transcriptional regulation of mating-type-specific genes as well as in fruiting body development.

Protein splicing of PRP8 mini-inteins from species of the genus Penicillium.

Inteins are protein-intervening sequences found inside the coding region of different host proteins and are translated in-frame with them. They can self-excise through protein splicing, which ligates the host protein flanks with a peptide bond. In this study, four different species of the genus Penicillium were investigated for the presence of inteins inside the conserved splicing-factor protein PRP8. We identified 157 to 162 amino acid in-frame insertions in the PRP8 protein of Penicillium chrysogenum, Penicillium expansum, and Penicillium vulpinum (formerly Penicillium claviforme). The Penicillium PRP8 inteins are mini-inteins without a conserved endonuclease domain. We demonstrated that the PRP8 mini-inteins of P. chrysogenum, P. expansum, and P. vulpinum undergo autocatalytic protein splicing when heterologously expressed in E. coli, in a model host protein, and in a divided GFP model system. They are, thus, among the smallest known nuclear-encoded, active splicing protein elements. The GFP assay should be valuable as a screening system for protein splicing inhibitors as potential antimycotic agents and as tools for studying the mechanism of protein splicing of fungal mini-inteins.