Evidence that cAMP initiates nuclear division and infection structure formation in the bean rust fungus,Uromyces phaseoli

Involvement of Ca(2+) channel signalling in sclerotial formation of Polyporus umbellatus

Growth and morphogenesis transformation in Polyporus umbellatus were examined in the presence of various pharmacological compounds, to investigate signal transduction pathways that influence the development of sclerotia. Both the calcium channel blocker nifedipine and the calcium ionophor A23187 reduced sclerotial production in P. umbellatus; four classes of Ca(2+) signal agent-including calcium chelators, calcium channel blockers, calcium ionophors and calmodulin inhibitors-were further studied. Among them, EGTA and BAPTA, as calcium chelators, exhibited a complete inhibitory effect on sclerotial formation, among the levels tested. Calcium channel blockers and calcium ionophors at the concentrations used in this study could not eliminate sclerotia formation completely, but did greatly reduce sclerotial production. Notoginsenoside in dosages >250 microg/ml produced a significant negative effect on mycelial growth, and it prevented sclerotial formation entirely at a dosage of 500 microg/ml; no other drug influenced vegetative growth at all. The calcium ionophor A23187 did not decrease sclerotial mean weight at low doses (20 nM); at higher doses (200 nM), however, sclerotial development was significantly reduced, albeit not completely halted. The CaM inhibitors (W-7 and chlorpromazine) could each completely stop sclerotial formation. Using Fluo-3/AM as the indicator of cytosolic free calcium, the Ca(2+) content in the cytoplasm was found to have decreased significantly when hyphae were treated with different drugs, and there was no active Ca(2+) signal in the sclerotial mycelium. In general, the results suggest that Ca(2+) signal transduction may play an important role in sclerotial formation in P. umbellatus.

The hgl1 gene is required for dimorphism and teliospore formation in the fungal pathogen Ustilago maydis

The fungal pathogen Ustilago maydis causes a dramatic disease in maize involving the induction of tumours and the formation of masses of black teliospores. In this fungus, mating between haploid, budding cells results in the formation of the infectious, filamentous cell type that invades host tissue. Mating and filamentous growth are governed by the mating-type loci and by cAMP signalling, perhaps in response to signals from maize. To dissect the involvement of cAMP signalling further, the constitutive filamentous phenotype of a mutant with a defect in the catalytic subunit of protein kinase A was used to isolate suppressor mutations that restore budding growth. One such mutation identified the hgl1 gene, which is shown to be required for both the switch between budding and filamentous growth and teliospore formation during infection. In addition, the hgl1 gene product may be a target of phosphorylation by protein kinase A, and transcript levels for the gene are elevated during mating. Thus, the hgl1 gene provides a connection between mating, cAMP signalling and two important aspects of virulence: filamentous growth and the formation of teliospores.

Serine/threonine protein kinases and phosphatases in filamentious fungi

Protein phosphorylation and dephosphorylation are one of the central currencies by which living cells perceive and respond to environmental cues. A number of fundamental processes in fungi such as the cell cycle, transcription, and mating have been shown to require protein phosphorylation. The analysis of protein kinases and phosphatases in filamentous fungi is in its infancy; however, it has already become clear that kinases and phosphatases are likely to be important mediators of fungal proliferation and development as well as signal transduction and infection-related morphogenesis. In this review, we describe, summarize, and consider the rapidly expanding field of protein phosphorylation/dephosphorylation in various aspects of filamentous fungal growth and development.

Increase in Endogenous and Exogenous Cyclic AMP Levels Inhibits Sclerotial Development in Sclerotinia sclerotiorum

Growth and development of a wild-type Sclerotinia sclerotiorum isolate were examined in the presence of various pharmacological compounds to investigate signal transduction pathways that influence the development of sclerotia. Compounds known to increase endogenous cyclic AMP (cAMP) levels in other organisms by inhibiting phosphodiesterase activity (caffeine and 3-isobutyl-1-methyl xanthine) or by activating adenylate cyclase (NaF) reduced or eliminated sclerotial development in S. sclerotiorum. Growth in the presence of 5 mM caffeine correlated with increased levels of endogenous cAMP in mycelia. In addition, incorporation of cAMP into the growth medium decreased or eliminated the production of sclerotia in a concentration-dependent manner and increased the accumulation of oxalic acid. Inhibition of sclerotial development was cAMP specific, as exogenous cyclic GMP, AMP, and ATP did not influence sclerotial development. Transfer of developing cultures to cAMP-containing medium at successive time points demonstrated that cAMP inhibits development prior to or during sclerotial initiation. Together, these results indicate that cAMP plays a role in the early transition between mycelial growth and sclerotial development.

Isolation and characterization of genes expressed uniquely during appressorium formation by Colletotrichum gloeosporioides conidia induced by the host surface wax

Appressorium formation in germinating Colletotrichum gloeosporioides is induced by the surface wax of the host, the avocado fruit. To elucidate the mechanism by which differentiation of appressorium formation is induced, the fungal genes specifically activated by this host signal were sought. From a cDNA library of the transcripts present in appressorium-forming conidia, the clones representing nongerminating conidia were removed by hybridization with cDNAs synthesized from the nongerminating conidia. From this subtracted library, clones that hybridized with cDNA for transcripts from appressorium-forming conidia and not with cDNA for transcripts from germinating conidia were selected. Three such clones were isolated and sequenced. The genes for these three transcripts were also cloned and sequenced. Northern blot analysis showed that transcripts that hybridized with these three clones were expressed in the conidium only during the process of appressorium formation induced by avocado surface wax, and that these transcripts were not detectable when appressorium formation was prevented even in the presence of avocado wax. Nucleotide sequences of the clones revealed that one clone, cap3, contained an open reading frame (ORF) that would code for a 26-amino acid, cysteine-rich peptide with significant homology to Neurospora crassa copper metallothionein. Another clone, cap5, contained an ORF that would code for a 27-amino acid cysteine-rich peptide with less homology to metallothioneins. Cu2+ and Cd2+ also induced the expression of these genes at lower levels. The histochemical analysis of transformants containing the cap5 promoter fused to the beta-glucuronidase (GUS) gene showed that the cap5 gene promoter caused GUS expression exclusively during appressorium formation and most of the gus activity was in the appressorium. The cap22 clone contained an ORF coding for a 227-amino acid polypeptide of 22 kDa, which did not show significant homology to any known proteins. Recombinant CAP22 protein was produced using a pET-19b expression system in Escherichia coli, purified, and used to prepare rabbit antibodies. Western blot analysis of proteins from the appressorium-forming conidia revealed a major cross-reacting protein at 43 kDa and a minor band at 68 kDa, indicating that the potential glycosylation sites found in the primary translation product were probably glycosylated. Results of immunogold localization showed that CAP22 protein was located on the wall of the appressorium.

Signaling for Growth Orientation and Cell Differentiation by Surface Topography in Uromyces

The dimensions of the topographical signals for growth orientation and infection structure formation, a cell differentiation event that includes nuclear division, were determined for the stomatal penetrating rust fungus Uromyces appendiculatus. The differentiation signal was found to be a simple ridge on the substrate surface that had a markedly optimum height of 0.5 micrometer. Such ridges were microfabricated on silicon wafers by using electron-beam lithography. A similar ridge, in the form of a stomatal lip, was found associated with the stomatal guard cells of the bean (Phaseolus vulgaris) leaf. Ridge elevations greater than 1.0 micrometer or less than 0.25 micrometer did not serve as effective signals. Germ tubes of the fungus were highly oriented by ridge spacings of 0.5 to 6.7 micrometers. The data indicate that the fungus is able to distinguish uniquely minute differences in leaf surface topography in order to infect the host plant.