Molecular and cellular events during the yeast to mycelium transition in Sporothrix schenckii

Characterization and ligand identification of a membrane progesterone receptor in fungi: existence of a novel PAQR in Sporothrix schenckii

Background

Adaptive responses in fungi result from the interaction of membrane receptors and extracellular ligands. Many different classes of receptors have been described in eukaryotic cells. Recently a new family of receptors classified as belonging to the progesterone-adiponectin receptor (PAQR) family has been identified. These receptors have the seven transmembrane domains characteristic of G-protein coupled receptors, but their activity has not been associated directly to G proteins. They share sequence similarity to the eubacterial hemolysin III proteins.

Results

A new receptor, SsPAQR1 (Sporothrixschenckiiprogesterone-adiponectinQ receptor1), was identified as interacting with Sporothrix schenckii G protein alpha subunit SSG-2 in a yeast two-hybrid assay. The receptor was identified as a member of the PAQR family. The cDNA sequence revealed a predicted ORF of 1542 bp encoding a 514 amino acids protein with a calculated molecular weight of 57.8 kDa. Protein domain analysis of SsPAQR1 showed the 7 transmembrane domains (TM) characteristic of G protein coupled receptors and the presence of the distinctive motifs that characterize PAQRs. A yeast-based assay specific for PAQRs identified progesterone as the agonist. S. schenckii yeast cells exposed to progesterone (0.50 mM) showed an increase in intracellular levels of 3^′, 5^′ cyclic adenosine monophosphate (cAMP) within the first min of incubation with the hormone. Different progesterone concentrations were tested for their effect on the growth of the fungus. Cultures incubated at 35°C did not grow at concentrations of progesterone of 0.05 mM or higher. Cultures incubated at 25°C grew at all concentrations tested (0.01 mM-0.50 mM) with growth decreasing gradually with the increase in progesterone concentration.

Conclusion

This work describes a receptor associated with a G protein alpha subunit in S. schenckii belonging to the PAQR family. Progesterone was identified as the ligand. Exposure to progesterone increased the levels of cAMP in fungal yeast cells within the first min of incubation suggesting the connection of this receptor to the cAMP signalling pathway. Progesterone inhibited the growth of both the yeast and mycelium forms of the fungus, with the yeast form being the most affected by the hormone.

Sporothrix schenckii and Sporotrichosis

Sporotrichosis, which is caused by the dimorphic fungus Sporothrix schenckii, is currently distributed throughout the world, especially in tropical and subtropical zones. Infection generally occurs by traumatic inoculation of soil, plants, and organic matter contaminated with the fungus. Certain leisure and occupational activities, such as floriculture, agriculture, mining, and wood exploitation, are traditionally associated with the mycosis. Zoonotic transmission has been described in isolated cases or in small outbreaks. Since the end of the 1990s there has been an epidemic of sporotrichosis associated with transmission by cats in Rio de Janeiro, Brazil. More than 2,000 human cases and 3,000 animal cases have been reported. In humans, the lesions are usually restricted to the skin, subcutaneous cellular tissue, and adjacent lymphatic vessels. In cats, the disease can evolve with severe clinical manifestations and frequent systemic involvement. The gold standard for sporotrichosis diagnosis is culture. However, serological, histopathological, and molecular approaches have been recently adopted as auxiliary tools for the diagnosis of this mycotic infection. The first-choice treatment for both humans and cats is itraconazole.

Calcium/calmodulin kinase1 and its relation to thermotolerance and HSP90 in Sporothrix schenckii: an RNAi and yeast two-hybrid study

Background

Sporothrix schenckii is a pathogenic dimorphic fungus of worldwide distribution. It grows in the saprophytic form with hyaline, regularly septated hyphae and pyriform conidia at 25°C and as the yeast or parasitic form at 35°C. Previously, we characterized a calcium/calmodulin kinase in this fungus. Inhibitors of this kinase were observed to inhibit the yeast cell cycle in S. schenckii.

Results

The presence of RNA interference (RNAi) mechanism in this fungus was confirmed by the identification of a Dicer-1 homologue in S. schenckii DNA. RNAi technology was used to corroborate the role of calcium/calmodulin kinase I in S. schenckii dimorphism. Yeast cells were transformed with the pSilent-Dual2G (pSD2G) plasmid w/wo inserts of the coding region of the calcium/calmodulin kinase I (sscmk1) gene. Transformants were selected at 35°C using resistance to geneticin. Following transfer to liquid medium at 35°C, RNAi transformants developed as abnormal mycelium clumps and not as yeast cells as would be expected. The level of sscmk1 gene expression in RNAi transformants at 35°C was less than that of cells transformed with the empty pSD2G at this same temperature. Yeast two-hybrid analysis of proteins that interact with SSCMK1 identified a homologue of heat shock protein 90 (HSP90) as interacting with this kinase. Growth of the fungus similar to that of the RNAi transformants was observed in medium with geldanamycin (GdA, 10 μM), an inhibitor of HSP90.

Conclusions

Using the RNAi technology we silenced the expression of sscmk1 gene in this fungus. RNAi transformants were unable to grow as yeast cells at 35°C showing decreased tolerance to this temperature. The interaction of SSCMK1 with HSP90, observed using the yeast two-hybrid assay suggests that this kinase is involved in thermotolerance through its interaction with HSP90. SSCMK1 interacted with the C terminal domain of HSP90 where effector proteins and co-chaperones interact. These results confirmed SSCMK1 as an important enzyme involved in the dimorphism of S. schenckii, necessary for the development of the yeast phase of this fungus. Also this study constitutes the first report of the transformation of S. schenckii and the use of RNAi to study gene function in this fungus.

Interaction of the heterotrimeric G protein alpha subunit SSG-1 of Sporothrix schenckii with proteins related to stress response and fungal pathogenicity using a yeast two-hybrid assay

Background

Important biological processes require selective and orderly protein-protein interactions at every level of the signalling cascades. G proteins are a family of heterotrimeric GTPases that effect eukaryotic signal transduction through the coupling of cell surface receptors to cytoplasmic effector proteins. They have been associated with growth and pathogenicity in many fungi through gene knock-out studies. In Sporothrix schenckii, a pathogenic, dimorphic fungus, we previously identified a pertussis sensitive G alpha subunit, SSG-1. In this work we inquire into its interactions with other proteins.

Results

Using the yeast two-hybrid technique, we identified protein-protein interactions between SSG-1 and other important cellular proteins. The interactions were corroborated using co-immuneprecipitation. Using these techniques we identified a Fe/Mn superoxide dismutase (SOD), a glyceraldehyde-3-P dehydrogenase (GAPDH) and two ion transport proteins, a siderophore-iron transporter belonging to the Major Facilitator Superfamily (MFS) and a divalent-cation transporter of the Nramp (natural resistance-associated macrophage protein) family as interacting with SSG-1. The cDNA's encoding these proteins were sequenced and bioinformatic macromolecular sequence analyses were used for the correct classification and functional assignment.

Conclusions

This study constitutes the first report of the interaction of a fungal G alpha inhibitory subunit with SOD, GAPDH, and two metal ion transporters. The identification of such important proteins as partners of a G alpha subunit in this fungus suggests possible mechanisms through which this G protein can affect pathogenicity and survival under conditions of environmental stress or inside the human host. The two ion transporters identified in this work are the first to be reported in S. schenckii and the first time they are identified as interacting with fungal G protein alpha subunits. The association of G protein alpha subunits to transport molecules reinforces the role of G proteins in the response to environmental signals and also highlights the involvement of fungal G protein alpha subunits in nutrient sensing in S. schenckii. These interactions suggest that these permeases could function as transceptors for G proteins in fungi.

Cytosolic phospholipase A2: a member of the signalling pathway of a new G protein alpha subunit in Sporothrix schenckii

Background

Sporothrix schenckii is a pathogenic dimorphic fungus, the etiological agent of sporotrichosis, a lymphocutaneous disease that can remain localized or can disseminate, involving joints, lungs, and the central nervous system. Pathogenic fungi use signal transduction pathways to rapidly adapt to changing environmental conditions and S. schenckii is no exception. S. schenckii yeast cells, either proliferate (yeast cell cycle) or engage in a developmental program that includes proliferation accompanied by morphogenesis (yeast to mycelium transition) depending on the environmental conditions. The principal intracellular receptors of environmental signals are the heterotrimeric G proteins, suggesting their involvement in fungal dimorphism and pathogenicity. Identifying these G proteins in fungi and their involvement in protein-protein interactions will help determine their role in signal transduction pathways.

Results

In this work we describe a new G protein α subunit gene in S. schenckii, ssg-2. The cDNA sequence of ssg-2 revealed a predicted open reading frame of 1,065 nucleotides encoding a 355 amino acids protein with a molecular weight of 40.9 kDa. When used as bait in a yeast two-hybrid assay, a cytoplasmic phospholipase A₂ catalytic subunit was identified as interacting with SSG-2. The sspla₂ gene, revealed an open reading frame of 2538 bp and encoded an 846 amino acid protein with a calculated molecular weight of 92.62 kDa. The principal features that characterize cPLA₂ were identified in this enzyme such as a phospholipase catalytic domain and the characteristic invariable arginine and serine residues. A role for SSPLA₂ in the control of dimorphism in S. schenckii is suggested by observing the effects of inhibitors of the enzyme on the yeast cell cycle and the yeast to mycelium transition in this fungus. Phospholipase A₂ inhibitors such as AACOCF3 (an analogue of archidonic acid) and isotetrandrine (an inhibitor of G protein PLA₂ interactions) were found to inhibit budding by yeasts induced to re-enter the yeast cell cycle and to stimulate the yeast to mycelium transition showing that this enzyme is necessary for the yeast cell cycle.

Conclusion

A new G protein α subunit gene was characterized in S. schenckii and protein-protein interactions studies revealed this G protein alpha subunit interacts with a cPLA₂ homologue. The PLA₂ homologue reported here is the first phospholipase identified in S. schenckii and the first time a PLA₂ homologue is identified as interacting with a G protein α subunit in a pathogenic dimorphic fungus, establishing a relationship between these G proteins and the pathogenic potential of fungi. This cPLA₂ homologue is known to play a role in signal transduction and fungal pathogenesis. Using cPLA₂ inhibitors, this enzyme was found to affect dimorphism in S. schenckii and was found to be necessary for the development of the yeast or pathogenic form of the fungus.

Functional, genetic and bioinformatic characterization of a calcium/calmodulin kinase gene in Sporothrix schenckii

Background

Sporothrix schenckii is a pathogenic, dimorphic fungus, the etiological agent of sporotrichosis, a subcutaneous lymphatic mycosis. Dimorphism in S. schenckii responds to second messengers such as cAMP and calcium, suggesting the possible involvement of a calcium/calmodulin kinase in its regulation. In this study we describe a novel calcium/calmodulin-dependent protein kinase gene in S. schenckii, sscmk1, and the effects of inhibitors of calmodulin and calcium/calmodulin kinases on the yeast to mycelium transition and the yeast cell cycle.

Results

Using the PCR homology approach a new member of the calcium/calmodulin kinase family, SSCMK1, was identified in this fungus. The cDNA sequence of sscmk1 revealed an open reading frame of 1,221 nucleotides encoding a 407 amino acid protein with a predicted molecular weight of 45.6 kDa. The genomic sequence of sscmk1 revealed the same ORF interrupted by five introns. Bioinformatic analyses of SSCMK1 showed that this protein had the distinctive features that characterize a calcium/calmodulin protein kinase: a serine/threonine protein kinase domain and a calmodulin-binding domain. When compared to homologues from seven species of filamentous fungi, SSCMK1 showed substantial similarities, except for a large and highly variable region that encompasses positions 330 – 380 of the multiple sequence alignment. Inhibition studies using calmodulin inhibitor W-7, and calcium/calmodulin kinase inhibitors, KN-62 and lavendustin C, were found to inhibit budding by cells induced to re-enter the yeast cell cycle and to favor the yeast to mycelium transition.

Conclusion

This study constitutes the first evidence of the presence of a calcium/calmodulin kinase-encoding gene in S. schenckii and its possible involvement as an effector of dimorphism in this fungus. These results suggest that a calcium/calmodulin dependent signaling pathway could be involved in the regulation of dimorphism in this fungus. The results suggest that the calcium/calmodulin kinases of yeasts are evolutionarily distinct from those in filamentous fungi.

Expression of a Pho85 cyclin-dependent kinase is repressed during the dimorphic transition in Sporothrix schenckii

Sporothrix schenckii is a pathogenic fungus that undergoes a dimorphic transition from yeast to mycelium in response to environmental conditions such as cell density, temperature, and calcium. We identified a homolog of the Pho85 cyclin-dependent kinase (Cdk) that mediates cellular responses to environmental conditions in other organisms. By Western blot, three proteins containing the PSTAIRE motif, which characterize the cyclin-dependent protein kinases, were identified in S. schenckii. The gene encoding a Pho85 homolog, PhoSs, was identified and sequenced. The phoSs gene consists of 990bp, contains one intron, and encodes a protein of 306 amino acids. The S. schenckii Pho85 homolog shares features with Cdks, including the PSTAIRE motif, an ATP binding domain, and a serine-threonine kinase domain. By quantitative competitive RT-PCR, expression of the phoSs gene was found to decrease 30-fold during the yeast to mycelium transition. The addition of extracellular calcium accelerated the dimorphic transition and restored phoSs expression. These findings suggest PhoSs may participate in the control of the yeast to mycelium transition in S. schenckii.

Characterization of a protein kinase C gene in Sporothrix schenckii and its expression during the yeast-to-mycelium transition

The yeast-to-mycelium transition in Sporothrix schenckii has been shown to respond to protein kinase C (PKC) effectors, indicating the involvement of PKC in this regulation. In this study, we identified the presence of two pkcl-like genes in S. schenckii. Using fungal genomic DNA as template and primers targeted to conserved sequences in the Saccharomyces cerevisiae pkc1 gene, two partially overlapping extra long polymerase chain reaction (XL-PCR) products were obtained. These XL-PCR products were sequenced and found to encode part of the C3/C4 domains of two different PKC-like proteins. The presence of two different genes was confirmed by Southern blot analysis. These two genes were named pkcSs-1 and pkcSs-2. The sequence of the pkcSs-2 gene was completed and revealed an open reading frame of 3942 nucleotides interrupted by five introns. A transcript of 8.7 kb was detected in northern blot analysis of poly A+ RNA. The pkcSs-2 gene encodes a protein of 1194 amino acids and 132.84 kDa that contains the characteristic structure and domains of other fungal PKCs reported to date. Using reverse transcription-PCR (RT-PCR), the pkcSs-2 gene was found to be expressed at all intervals tested during the yeast-to-mycelium transition.

Presence of a pertussis toxin-sensitive G protein alpha subunit in Sporothrix schenckii

As an initial step in the study of the role of G proteins in signal transduction in Sporothrix schenckii, we identified a Galphai subunit using different experimental approaches. Western blots of fungal membrane preparations using anti-Galphacommon and anti-Galphai1-Galphai2 antibodies identified a band of approximately 41 kDa. Pertussis toxin-catalyzed adenosine diphosphate (ADP)-ribosylation of these membrane fractions confirmed the presence of a protein substrate of 41 kDa. A 357 bp polymerase chain reaction (PCR) product obtained using fungal DNA as template and primers targeted to conserved Galphai sequences, was used as a probe to isolate a clone from an S. schenckii genomic library. A partial sequence for a Galphai subunit was obtained from this clone. The sequence was completed using the rapid amplification of cDNA ends (RACE) technique with mycelium and yeast cDNA. The cDNA sequence revealed a 1059 bp open reading frame encoding a 353 amino acid Galphai subunit of 41 kDa, more than 90% identical to the CPG-1 of Cryphonectria parasitica, and GNA-1 of Neurospora crassa. The genomic sequence was obtained by PCR using fungal DNA, and revealed a 1250 bp sequence and the presence of three introns. These results provide evidence for the first time of the presence and expression of a Galphai homolog in a pathogenic dimorphic fungus.

Different protein kinase C isoforms are present in the yeast and mycelium forms of Sporothrix schenckii

Protein kinase C (PKC) plays an important role in the control of proliferation and differentiation of a wide range of cell types, and fungi are no exception. Previous results reported by us on the effects of the phorbol ester, 12-myristate-13-acetate phorbol (PMA) and other PKC effector molecules, on dimorphism in Sporothrix schenckii suggested the presence of this enzyme in the fungus and its involvement in the control of morphogenetic transitions. The work summarized here confirms the presence of PKC in yeast and mycelium extracts of S. schenckii. Different isoforms of this enzyme were found to be present in the yeast and mycelium forms of the fungus and were identified by Western blot analysis using affinity purified anti-PKC isoforms specific antibodies: the gamma and zeta isoforms were detected in both the yeast and mycelium forms of the fungus, while the beta isoform was only detected in the yeast form. The presence of PKC was confirmed biochemically by measuring total enzyme activity in both forms of the fungus. No significant differences were observed for the PKC activity level recorded for both the mycelium and yeast forms of the fungus (p < or = 0.05). These data confirm the presence of PKC activity in Sporothrix schenckii and constitutes the first evidence concerning the differential expression of PKC isoforms in the mycelium and yeast forms of a dimorphic fungus, supporting the possible involvement of this important signal transduction enzyme in the control of morphogenesis in this fungus.

Yeast killer systems

The killer phenomenon in yeasts has been revealed to be a multicentric model for molecular biologists, virologists, phytopathologists, epidemiologists, industrial and medical microbiologists, mycologists, and pharmacologists. The surprisingly widespread occurrence of the killer phenomenon among taxonomically unrelated microorganisms, including prokaryotic and eukaryotic pathogens, has engendered a new interest in its biological significance as well as its theoretical and practical applications. The search for therapeutic opportunities by using yeast killer systems has conceptually opened new avenues for the prevention and control of life-threatening fungal diseases through the idiotypic network that is apparently exploited by the immune system in the course of natural infections. In this review, the biology, ecology, epidemiology, therapeutics, serology, and idiotypy of yeast killer systems are discussed.

Differential expression of the 45 kDa protein (actin) during the dimorphic transition of Sporothrix schenckii

We investigated the gene expression of a protein during the dimorphic transition from yeast to mycelial form of Sporothrix schenckii. Yeast cells were converted to mycelial cells in Sabouraud glucose broth at 25 degrees C. After 1, 3 and 5 days of culture, the intermediate form of cells between yeast and mycelium was obtained, and after 7 days these cells were morphologically similar to the mycelial cells. Proteins having the molecular weight of 45 kDa were found to by synthesized preferentially by intermediate form of day 7 and mycelial cells. On the other hand, the 45 kDa proteins were predominantly translated by the RNA isolated from the intermediate of day 7 and mycelial cells using in vitro cell-free translation assay. The 45 kDa proteins synthesized by mycelial cells were found to be identical with the 45 kDa translation products directed by the mRNA isolated from the intermediate and mycelial cells by V8 protease peptide mapping. The 45 kDa protein was considered to be actin by Western blot analysis using an anti-actin monoclonal antibody. These results suggest that the intermediate form of day 7 has the same phenotypes in the morphology and biosynthesis of actin as those of mycelial cells. The expression of the actin gene may be involved in the dimorphic transition of S. schenckii.

Calcium stimulates molecular and cellular events during the yeast-to-mycelium transition in Sporothrix schenckii

Calcium ions (Ca2+) have been identified as mediators of proliferative and morphogenetic processes in many eukaryotic cells. The effects of these ions on the cellular and macromolecular processes that accompany the dimorphic transition from the yeast-to-mycelial form of Sporothrix schenckii have been studied. Ca2+ were found to stimulate germ tube formation and growth in these cells at an optimal concentration of 1.0 mM. Studies concerning the effects of this cation on the molecular processes that precede germ tube formation revealed that the earliest molecular event which was stimulated by 1.0 mM Ca2+ was RNA synthesis. An increased incorporation of radioactivity into RNA in the presence of 1.0 mM Ca2+ was first observed at 0-3 h, and subsequently at all other times tested, following inoculation. A stimulation in rRNA and tRNA synthesis was detected in the presence of 1.0 mM Ca2+. The incorporation of radioactivity into proteins was stimulated 3-5 h following induction in the presence of Ca2+ suggesting a specific effect of Ca2+ on protein synthesis. This increased incorporation takes place prior to the start of DNA synthesis. Incorporation of radioactivity into DNA was also stimulated in the presence of Ca2+, 6 and 9 h after inoculation. This stimulation resulted in nuclear division taking place with a shorter lag period and proceeding with increased kinetics. The results reported here are evidence that Ca2+ plays a role in the control of the early molecular and cellular processes that accompany the yeast-to-mycelium transition in S. schenckii and offer an explanation of how Ca2+ can control the expression of the dimorphic potential of this fungus.

Calcium uptake and efflux during the yeast to mycelium transition in Sporothrix schenckii

A study was made of calcium metabolism during germ tube formation in Sporothrix schenckii yeast cells. A net efflux of calcium was observed very early in the transformation process and remained constant thereafter. The efflux of calcium in yeast cells induced to form germ tubes was twice that observed in yeast cells not induced to form germ tubes. Two peaks of calcium uptake were observed in germ tube forming yeast cells at 30 and 300 minutes following inoculation, while non-induced yeast cells, a continuous increase in uptake was observed which ultimately reached higher values than the ones obtained in germ tube forming cells. Substances which affect calcium metabolism in other cells such as cobalt ions, ionophore A23187 and compound R24571 were observed to inhibit germ tube formation and calcium uptake. In addition, ionophore A23187 was found to increase calcium efflux to approximately twice the control values. The inhibition of germ tube formation brought about by substances which inhibit calcium uptake or increase efflux suggests that the intracellular calcium concentration in these cells must be precisely regulated for the yeast to mycelium transition to occur.

Yeast killer toxins and dimorphism

The differential action of four selected yeast killer toxins on the mycelial and yeast forms of four isolates of the dimorphic fungus Sporothrix schenckii was comparatively evaluated. The results confirmed that the yeast killer phenomenon is present among hyphomycetes and yeasts and that both morphological forms of S. schenckii are susceptible to the action of the same yeast killer toxin. Quantitative differences in the response to the killer action of the mycelial and yeast forms in individual strains were also observed. To avoid retroconversion of the dimorphic forms, we used a modification of the conventional killer system.

Effects of zinc on macromolecular synthesis and nuclear division during the yeast to mycelium transition in Sporothrix schenckii

Zinc ions (10 mM) have been reported previously to inhibit the yeast to mycelium transition in Sporothrix schenckii. Yeast cells of this fungus were harvested, selected by filtration and allowed to form germ tubes in a basal medium with glucose in the presence of 10 mM zinc and the effects of this ion on protein, RNA and DNA synthesis and nuclear division recorded. All of these processes were affected by the addition of 10 mM zinc to the medium. Nevertheless, the inhibition of protein synthesis was observed earlier than that of RNA or DNA synthesis and was of a greater magnitude than that observed for both of these processes. Protein synthesis was inhibited within the first hour after inoculation, at which time this process begins in the control cells. RNA synthesis was inhibited during the 3 to 6 h interval after inoculation, that is, 3 h after the start of this process in the control cells. After 9 h of incubation, the inhibition of protein synthesis had reached its maximum at 70%, while that of RNA synthesis was only 52%. DNA synthesis was slightly inhibited, with maximum inhibition being observed 9 h after inoculation. Nuclear division in cells forming germ tubes in the presence of 10 mM zinc took place with a 3 h delay in relation to the control cells. These observations suggest that the inhibition of protein synthesis might be the most important mechanism by which zinc inhibits the yeast to mycelium transition in S. schenckii.

Molecular and cellular events during the germination of conidia of Sporothrix schenckii

Hyaline, non pigmented microconidia of Sporothrix schenckii were harvested and allowed to form germ tubes in a basal medium with glucose at pH 4.0 and 25 degrees C. These conditions supported only the development of the mycelial form of Sporothrix schenckii in a reproducible, synchronized manner which allowed further analysis of the early cellular events occurring during the germination of the conidia. The relationship between macro-molecular synthesis (DNA, RNA and protein synthesis) and nuclear division, hyphal growth and septum formation were established. Following inoculation, protein synthesis was observed after 10 minutes followed by RNA synthesis, after 1 h and DNA synthesis after 2 h. The first nuclear division was observed during the 9 to 12 h interval after inoculation. Germ tube formation slightly preceeded nuclear division and was first evidenced 9 h after the induction of germination but was not completed until 12 h after inoculation. Septation was first observed in the germ tubes 0.25 micron from the mother cell-germ tube function 9 h after induction of germination.