On how a transcription factor can avoid its proteolytic activation in the absence of signal transduction

Interconnections between the Cation/Alkaline pH-Responsive Slt and the Ambient pH Response of PacC/Pal Pathways in Aspergillus nidulans

In the filamentous ascomycete Aspergillus nidulans, at least three high hierarchy transcription factors are required for growth at extracellular alkaline pH: SltA, PacC and CrzA. Transcriptomic profiles depending on alkaline pH and SltA function showed that pacC expression might be under SltA regulation. Additional transcriptional studies of PacC and the only pH-regulated pal gene, palF, confirmed both the strong dependence on ambient pH and the function of SltA. The regulation of pacC expression is dependent on the activity of the zinc binuclear (C6) cluster transcription factor PacX. However, we found that the ablation of sltA in the pacX- mutant background specifically prevents the increase in pacC expression levels without affecting PacC protein levels, showing a novel specific function of the PacX factor. The loss of sltA function causes the anomalous proteolytic processing of PacC and a reduction in the post-translational modifications of PalF. At alkaline pH, in a null sltA background, PacC72kDa accumulates, detection of the intermediate PacC53kDa form is extremely low and the final processed form of 27 kDa shows altered electrophoretic mobility. Constitutive ubiquitination of PalF or the presence of alkalinity-mimicking mutations in pacC, such as pacCc14 and pacCc700, resembling PacC53kDa and PacC27kDa, respectively, allowed the normal processing of PacC but did not rescue the alkaline pH-sensitive phenotype caused by the null sltA allele. Overall, data show that Slt and PacC/Pal pathways are interconnected, but the transcription factor SltA is on a higher hierarchical level than PacC on regulating the tolerance to the ambient alkalinity in A. nidulans.

Defining the transcriptional responses of Aspergillus nidulans to cation/alkaline pH stress and the role of the transcription factor SltA

Fungi have developed the ability to overcome extreme growth conditions and thrive in hostile environments. The model fungus Aspergillus nidulans tolerates, for example, ambient alkalinity up to pH 10 or molar concentrations of multiple cations. The ability to grow under alkaline pH or saline stress depends on the effective function of at least three regulatory pathways mediated by the zinc-finger transcription factor PacC, which mediates the ambient pH regulatory pathway, the calcineurin-dependent CrzA and the cation homeostasis responsive factor SltA. Using RNA sequencing, we determined the effect of external pH alkalinization or sodium stress on gene expression. The data show that each condition triggers transcriptional responses with a low degree of overlap. By sequencing the transcriptomes of the null mutant, the role of SltA in the above-mentioned homeostasis mechanisms was also studied. The results show that the transcriptional role of SltA is wider than initially expected and implies, for example, the positive control of the PacC-dependent ambient pH regulatory pathway. Overall, our data strongly suggest that the stress response pathways in fungi include some common but mostly exclusive constituents, and that there is a hierarchical relationship among the main regulators of stress response, with SltA controlling pacC expression, at least in A. nidulans.

G-protein-coupled Receptors in Fungi

G-protein-coupled receptors (GPCRs) are the largest family of transmembrane receptors in fungi. These receptors have an important role in the transduction of extracellular signals into intracellular sites in response to diverse stimuli. They enable fungi to coordinate cell function and metabolism, thereby promoting their survival and propagation, and sense certain fundamentally conserved elements, such as nutrients, pheromones, and stress, for adaptation to their niches, environmental stresses, and host environment, causing disease and pathogen virulence. This chapter highlights the role of GPCRs in fungi in coordinating cell function and metabolism. Fungal cells sense the molecular interactions between extracellular signals. Their respective sensory systems are described here in detail.

Ammonia activates pacC and patulin accumulation in an acidic environment during apple colonization by Penicillium expansum

Penicillium expansum, the causal agent of blue mould rot, causes severe post-harvest fruit maceration simultaneously with the secretion of d-gluconic acid (GLA) and the mycotoxin patulin in colonized tissue. The factor(s) inducing patulin biosynthesis during colonization of the host acidic environment is unclear. During the colonization of apple fruit in vivo and growth in culture, P. expansum secretes pH-modulating GLA and ammonia. Although patulin and its possible opportunistic precursor GLA accumulate together during fungal development, ammonia is detected on the colonized tissue's leading edge and after extended culture, close to patulin accumulation. Here, we demonstrate ammonia-induced transcript activation of the global pH modulator PacC and patulin accumulation in the presence of GLA by: (i) direct exogenous treatment of P. expansum growing on solid medium; (ii) direct exogenous treatment on colonized apple tissue; (iii) growth under self-ammonia production conditions with limited carbon; and (iv) analysis of the transcriptional response to ammonia of the patulin biosynthesis cluster. Ammonia induced patulin accumulation concurrently with the transcript activation of pacC and patulin biosynthesis cluster genes, indicating the regulatory effect of ammonia on pacC transcript expression under acidic conditions. Electrophoretic mobility shift assays using P. expansum PacC and antibodies to the different cleaved proteins showed that PacC is not protected against proteolytic signalling at pH 4.5 relative to pH 7.0, but NH4 addition did not further enhance its proteolytic cleavage. Ammonia enhanced the activation of palF transcript in the Pal pathway under acidic conditions. Ammonia accumulation in the host environment by the pathogen under acidic pH may be a regulatory cue for pacC activation, towards the accumulation of secondary metabolites, such as patulin.

Refining the pH response in Aspergillus nidulans: a modulatory triad involving PacX, a novel zinc binuclear cluster protein

The Aspergillus nidulans PacC transcription factor mediates gene regulation in response to alkaline ambient pH which, signalled by the Pal pathway, results in the processing of PacC⁷² to PacC²⁷ via PacC⁵³. Here we investigate two levels at which the pH regulatory system is transcriptionally moderated by pH and identify and characterise a new component of the pH regulatory machinery, PacX. Transcript level analysis and overexpression studies demonstrate that repression of acid‐expressed palF, specifying the Pal pathway arrestin, probably by PacC²⁷ and/or PacC⁵³, prevents an escalating alkaline pH response. Transcript analyses using a reporter and constitutively expressed pacC  trans‐alleles show that pacC preferential alkaline‐expression results from derepression by depletion of the acid‐prevalent PacC⁷² form. We additionally show that pacC repression requires PacX. pacX mutations suppress PacC processing recalcitrant mutations, in part, through derepressed PacC levels resulting in traces of PacC²⁷ formed by pH‐independent proteolysis. pacX was cloned by impala transposon mutagenesis. PacX, with homologues within the Leotiomyceta, has an unusual structure with an amino‐terminal coiled‐coil and a carboxy‐terminal zinc binuclear cluster. pacX mutations indicate the importance of these regions. One mutation, an unprecedented finding in A. nidulans genetics, resulted from an insertion of an endogenous Fot1‐like transposon.

Liaison alcaline: Pals entice non-endosomal ESCRTs to the plasma membrane for pH signaling

The alkaline pH-responsive Pal/Rim signal transduction pathway mediating regulation of gene expression by ambient pH has been extensively studied in Aspergillus nidulans and Saccharomyces cerevisiae. In A. nidulans, PalH, PalI, PalF, PalC, PalA and PalB are required for the proteolytic activation of the executing transcription factor PacC. Although necessary, Pal proteins are insufficient to transmit the signal, which additionally requires ESCRT-I, II and Vps20 with Snf7 in ESCRT-III. Although this initially suggested cooperation between a plasma membrane sensor and an ESCRT-containing Pal complex on endosomes, recent evidence convincingly indicates that pH signaling actually takes place in plasma membrane-associated foci in which Pal proteins and an ESCRT-III polymer scaffold cooperate for pH signaling purposes, representing another non-endosomal role of ESCRT components.

Aspergillus nidulans Ambient pH Signaling Does Not Require Endocytosis

Aspergillus nidulans (Pal) ambient pH signaling takes place in cortical structures containing components of the ESCRT pathway, which are hijacked by the alkaline pH-activated, ubiquitin-modified version of the arrestin-like protein PalF and taken to the plasma membrane. There, ESCRTs scaffold the assembly of dedicated Pal proteins acting downstream. The molecular details of this pathway, which results in the two-step proteolytic processing of the transcription factor PacC, have received considerable attention due to the key role that it plays in fungal pathogenicity. While current evidence strongly indicates that the pH signaling role of ESCRT complexes is limited to plasma membrane-associated structures where PacC proteolysis would take place, the localization of the PalB protease, which almost certainly catalyzes the first and only pH-regulated proteolytic step, had not been investigated. In view of ESCRT participation, this formally leaves open the possibility that PalB activation requires endocytic internalization. As endocytosis is essential for hyphal growth, nonlethal endocytic mutations are predicted to cause an incomplete block. We used a SynA internalization assay to measure the extent to which any given mutation prevents endocytosis. We show that none of the tested mutations impairing endocytosis to different degrees, including slaB1, conditionally causing a complete block, have any effect on the activation of the pathway. We further show that PalB, like PalA and PalC, localizes to cortical structures in an alkaline pH-dependent manner. Therefore, signaling through the Pal pathway does not involve endocytosis.

Conserved and Distinct Functions of the “Stunted” (StuA)-Homolog Ust1 During Cell Differentiation in the Corn Smut Fungus Ustilago maydis

Ustilago maydis, causal agent of corn smut, can proliferate saprobically in a yeast form but its infectious filamentous form is an obligate parasite. Previously, we showed that Ust1, the first APSES (Asm1p, Phd1p, Sok2p, Efg1p, and StuAp) transcription factor functionally characterized in the phylum Basidiomycota, controlled morphogenesis and virulence in this species. Here, we further analyzed Ust1 function using multiple experimental approaches and determined that i) Ust1 activity was able to partially reverse stuA− conidiophore defects in Aspergillus nidulans; ii) in U. maydis, normal development and virulence were strongly dependent on precise induction or repression of Ust1 activity; iii) consistent with its role as a transcription factor regulating multiple processes, Ust1 accumulated in the nucleus at various stages of the life cycle; iv) however, it was undetectable at specific stages of pathogenic growth, indicating that Ust1 repression is part of normal development in planta; v) StuA response elements upstream of the ust1 open reading frame exhibited affinity for U. maydis DNA-binding proteins; vi) however, loss of regulated ust1 transcription had minor phenotypic effects; and vii) Ust1 was subject to post-translational phosphorylation but is not a target of cAMP signaling. Thus, the broad functional conservation between Ust1 and Ascomycota APSES proteins does not extend to the mechanisms regulating their activity.

Modelling the activation of alkaline pH response transcription factor PacC in Aspergillus nidulans: involvement of a negative feedback loop

Alkaline pH adaptation represents an important environmental stress response in Aspergillus nidulans. It is mediated by the pal signalling pathway and the PacC transcription factor. Although studied extensively experimentally, the activation mechanism of PacC has not been quantified, and it is not clear how this activation is regulated. Here, by constructing mathematical models, we first show that the pattern of PacC activation observed in previously published experiments cannot be explained based on existing knowledge about PacC activation. Extending the model with a negative feedback loop is necessary to produce simulation results that are consistent with the data, suggesting the existence of a negative feedback loop in the PacC activation process. This extended model is then validated against published measurements for cells with drug treatment and mutant cells. Furthermore, we investigate the role of an intermediate form of PacC in the PacC activation process, and propose experiments that can be used to test our predictions. Our work illustrates how mathematical models can be used to uncover regulatory mechanisms in the transcription regulation, and generate hypotheses that guide further laboratory investigations.

Receptor-mediated signaling in Aspergillus fumigatus

Aspergillus fumigatus is the most pathogenic species among the Aspergilli, and the major fungal agent of human pulmonary infection. To prosper in diverse ecological niches, Aspergilli have evolved numerous mechanisms for adaptive gene regulation, some of which are also crucial for mammalian infection. Among the molecules which govern such responses, integral membrane receptors are thought to be the most amenable to therapeutic modulation. This is due to the localization of these molecular sensors at the periphery of the fungal cell, and to the prevalence of small molecules and licensed drugs which target receptor-mediated signaling in higher eukaryotic cells. In this review we highlight the progress made in characterizing receptor-mediated environmental adaptation in A. fumigatus and its relevance for pathogenicity in mammals. By presenting a first genomic survey of integral membrane proteins in this organism, we highlight an abundance of putative seven transmembrane domain (7TMD) receptors, the majority of which remain uncharacterized. Given the dependency of A. fumigatus upon stress adaptation for colonization and infection of mammalian hosts, and the merits of targeting receptor-mediated signaling as an antifungal strategy, a closer scrutiny of sensory perception and signal transduction in this organism is warranted.

An ordered pathway for the assembly of fungal ESCRT-containing ambient pH signalling complexes at the plasma membrane

The fungal pal/RIM signalling pathway, which regulates gene expression in response to environmental pH involves, in addition to dedicated proteins, several components of ESCRT complexes, which suggested that pH signalling proteins assemble on endosomal platforms. In Aspergillus nidulans, dedicated Pal proteins include the plasma membrane receptor PalH and its coupled arrestin, PalF, which becomes ubiquitylated in alkaline pH conditions, and three potentially endosomal ESCRT-III associates, including Vps32 interactors PalA and PalC and Vps24 interactor calpain-like PalB. We studied the subcellular locations at which signalling takes place after activating the pathway by shifting ambient pH to alkalinity. Rather than localising to endosomes, Vps32 interactors PalA and PalC transiently colocalise at alkaline-pH-induced cortical structures in a PalH-, Vps23- and Vps32-dependent but Vps27-independent manner. These cortical structures are much more stable when Vps4 is deficient, indicating that their half-life depends on ESCRT-III disassembly. Pull-down studies revealed that Vps23 interacts strongly with PalF, but co-immunoprecipitates exclusively with ubiquitylated PalF forms from extracts. We demonstrate that Vps23-GFP, expressed at physiological levels, is also recruited to cortical structures, very conspicuous in vps27Δ cells in which the prominent signal of Vps23-GFP on endosomes is eliminated, in a PalF- and alkaline pH-dependent manner. Dual-channel epifluorescence microscopy showed that PalC arrives at cortical complexes before PalA. As PalC recruitment is PalA independent and PalA recruitment is PalC dependent but PalB independent, these data complete the participation order of Pal proteins in the pathway and strongly support a model in which pH signalling takes place in ESCRT-containing, plasma-membrane-associated, rather than endosome-associated, complexes.

Systemic analysis of the response of Aspergillus niger to ambient pH

BACKGROUND

The filamentous fungus Aspergillus niger is an exceptionally efficient producer of organic acids, which is one of the reasons for its relevance to industrial processes and commercial importance. While it is known that the mechanisms regulating this production are tied to the levels of ambient pH, the reasons and mechanisms for this are poorly understood.

METHODS

To cast light on the connection between extracellular pH and acid production, we integrate results from two genome-based strategies: A novel method of genome-scale modeling of the response, and transcriptome analysis across three levels of pH.

RESULTS

With genome scale modeling with an optimization for extracellular proton-production, it was possible to reproduce the preferred pH levels for citrate and oxalate. Transcriptome analysis and clustering expanded upon these results and allowed the identification of 162 clusters with distinct transcription patterns across the different pH-levels examined. New and previously described pH-dependent cis-acting promoter elements were identified. Combining transcriptome data with genomic coordinates identified four pH-regulated secondary metabolite gene clusters. Integration of regulatory profiles with functional genomics led to the identification of candidate genes for all steps of the pal/pacC pH signalling pathway.

CONCLUSIONS

The combination of genome-scale modeling with comparative genomics and transcriptome analysis has provided systems-wide insights into the evolution of highly efficient acidification as well as production process applicable knowledge on the transcriptional regulation of pH response in the industrially important A. niger. It has also made clear that filamentous fungi have evolved to employ several offensive strategies for out-competing rival organisms.

Multi-factor regulation of pectate lyase secretion by Colletotrichum gloeosporioides pathogenic on avocado fruits

Tissue alkalinization during Colletotrichum gloeosporioides attack enhances the expression of PELB, which encodes pectate lyase (PL), and PL secretion, which is considered essential for full virulence. We studied the regulation of PL secretion by manipulation of C. gloeosporioides PELB. PELB was down-regulated by knocking out PAC1, which encodes the PacC transcription factor that regulates gene products with pH-sensitive activities. We functionally characterized a PACC gene homologue, PAC1, from C. gloeosporioides wild-type (WT) Cg-14 and two independent deletion strains, Deltapac1(372)and Deltapac1(761). Loss-of-function PAC1 mutants showed 85% reduction of PELB transcript expression, delayed PL secretion and dramatically reduced virulence, as detected in infection assays with avocado fruits. In contrast, PELB was up-regulated in the presence of carbon sources such as glucose. When glucose was used as a carbon source in the medium for the WT strain and the Deltapac1 mutant at pH 6.0, PELB transcript expression and PL secretion were activated. Other sugars, such as sucrose and fructose (but not galactose), also activated PELB expression. These results suggest that the pH-regulated response is only part of a multi-factor regulation of PELB, and that sugars are also needed to promote the transition from quiescent to active necrotrophic development by the pathogen.

Development of new tools for studying gene function in fungi based on the Gateway system

Genomic information of many fungi has been released but large scale functional genomic studies are still limited by a lack of high-throughput methods. The low rates of homologous recombination and low rates of transformation are limiting steps in filamentous fungi, but the molecular tools are also lagging behind. In this paper we describe two new high-throughput functional genomic tools for filamentous fungi that are based on the Gateway technology. One system is the Gateway RNAi vector for fungi that allows gene silencing in a high-throughput manner. The other system is a high-throughput deletion construct system. These systems were tested using the PAC1 gene of Colletotrichum gloeosporioides. Using these types of approaches, large scale functional genomics experiments can be performed in filamentous fungi.

Evidence for the Direct Involvement of the Proteasome in the Proteolytic Processing of the Aspergillus nidulans Zinc Finger Transcription Factor PacC

The 72-kDa zinc finger transcription factor PacC, distantly related to Ci/Gli developmental regulators, undergoes two-step proteolytic processing in response to alkaline ambient pH. "Signaling protease" cleavage of PacC(72) removes a processing-inhibitory C-terminal domain, making its truncated PacC(53) product accessible to a second "processing" protease, yielding PacC(27). Features of the processing proteolysis suggested the proteasome as a candidate protease. We constructed, using gene replacements, two missense active site mutations in preB, the Aspergillus nidulans orthologue of Saccharomyces cerevisiae PRE2 encoding the proteasome beta5 subunit. preB1(K101A) is lethal. Viable preB2(K101R) impairs growth and, like its equivalent pre2(K108R) in yeast, impairs chymotryptic activity. pre2(K108R) and preB2(K101R) active site mutations consistently shift position of the scissile bonds when PacC is processed in S. cerevisiae and A. nidulans, respectively, indicating that PacC must be a direct substrate of the proteasome. preB2(K101R) leads to a 2-3-fold elevation in NimE mitotic cyclin levels but appears to result in PacC instability, suggesting an altered balance between processing and degradation. preB2(K101R) compensates the marked impairment in PacC(27) formation resulting from deletion of the processing efficiency determinant in PacC, further indicating direct proteasomal involvement in the formation of PacC(27). Deletion of a Gly-Pro-Ala-rich region within this processing efficiency determinant markedly destabilizes PacC. Arg substitutions of Lys residues within this efficiency determinant and nearby show that they cooperate to promote PacC processing. A quadruple Lys-to-Arg substitution (4K-->R) impairs formation of PacC(27) and leads to persistence of PacC(53). Wild-type PacC(53) becomes multiply phosphorylated upon alkaline pH exposure. Processing-impaired 4K-->R PacC(53) becomes excessively phosphorylated.

The Colletotrichum acutatum gene encoding a putative pH-responsive transcription regulator is a key virulence determinant during fungal pathogenesis on citrus

Postbloom fruit drop of citrus and Key lime anthracnose (KLA) are caused by different pathotypes of Colletotrichum acutatum. Both pathotypes are pathogenic to citrus flowers, resulting in blossom blight and induction of young fruit abscission. Two fungal mutants defective in pathogenicity were recovered from a KLA pathotype after Agrobacterium-mediated mutagenesis. A PacC(KLAP2) gene encoding a polypeptide that resembles many pH-responsive PacC/ Rim101 transcription regulators in fungi was identified from one of the mutants, and functionally characterized to play a crucial role in pathogenesis to both Key lime leaves and citrus flowers. Gene disruption at the Pac(KLAP2) locus created fungal mutants that were hypersensitive to alkaline pH, altered in conidium and appressorium production and germination, and concomitant with reduced virulence to both tissues. The pacC(KLAP2) null mutants had lower alkaline phosphatase and protease activities, but increased pectolytic and lipolytic activities. The mutants initiated penetration and incited lesion formation on Key lime, indistinguishable from the wild type, when a functional copy of PacC(KLAP2) was reintroduced or the leaves were wounded prior to inoculation. The null mutants were blocked at the penetration stage and, thus, failed to initiate the necrotrophic phase. The PacC(KLAP2) transcript was barely detectable when the fungus was grown on medium buffered to pH 3 or 4, yet accumulated to high levels at a pH between 5 and 7. The Pac(KLAP2) transcript was detected 2 days postinoculation on Key lime leaves, correlating with the time of lesion formation. We conclude that PacC(KLAP2) is essential for C. acutatum pathogenesis by regulating multiple physiological and developmental processes.

Regulatory elements mediating expression of xylanase genes in Fusarium oxysporum

The role of DNA regulatory elements mediating activation of the xylanase-encoding gene xyl4 by the transcription factor XlnR in the fungal pathogen Fusarium oxysporum, was studied by in vitro and in vivo functional analysis of the xyl4 promoter. Recombinant XlnR protein specifically bound the sequence GGCTAA in electrophoretic mobility shift assays. Experiments with xyl4 promoter fusions with the lacZ reporter gene showed that the GGCTAA sequence is required for xylan-induced transcriptional activation of xyl4 in F. oxysporum. The results support a model in which the interaction between the transcriptional activator XlnR and an unknown constitutive repressor regulates xylanase gene expression in F. oxysporum.

Further characterization of the signaling proteolysis step in the Aspergillus nidulans pH signal transduction pathway

The Aspergillus nidulans pH-responsive transcription factor PacC is modulated by limited, two-step proteolysis. The first, pH-regulated cleavage occurs in the 24-residue highly conserved "signaling protease box" in response to the alkaline pH signal. This is transduced by the Pal signaling pathway, containing the predicted calpain-like cysteine protease and likely signaling protease, PalB. In this work, we carried out classical mutational analysis of the putative signaling protease PalB, and we describe 9 missense and 18 truncating loss-of-function (including null) mutations. Mutations in the region of and affecting directly the predicted catalytic cysteine strongly support the deduction that PalB is a cysteine protease. Truncating and missense mutations affecting the C terminus highlight the importance of this region. Analysis of three-hemagglutinin-tagged PalB in Western blots demonstrates that PalB levels are independent of pH and Pal signal transduction. We have followed the processing of MYC(3)-tagged PacC in Western blots. We show unequivocally that PalB is essential for signaling proteolysis and is definitely not the processing protease. In addition, we have replaced 15 residues of the signaling protease box of MYC(3)-tagged PacC (pacC900) with alanine. The majority of these substitutions are silent. Leu481Ala, Tyr493Ala, and Gln499Ala result in delayed PacC processing in response to shifting from acidic to alkaline medium, as determined by Western blot analysis. Leu498Ala reduces function much more markedly, as determined by plate tests and processing recalcitrance. Excepting Leu498, this demonstrates that PacC signaling proteolysis is largely independent of sequence in the cleavage region.

Recent advances in the characterization of ambient pH regulation of gene expression in filamentous fungi and yeasts

All microorganisms must adapt to the pH of their environment. One aspect of this adaptation, particularly important for organisms that grow over a wide pH range, is the ability to express appropriately genes whose roles ultimately involve functions at the cell surface or in the environment. Genes encoding permeases, secreted enzymes, enzymes involved in synthesis of exported metabolites such as toxins and antibiotics, and probably enzymes modifying secreted proteins posttranslationally all fall into this category. Here we discuss the most recent findings on the transcriptional regulatory system in fungi that enables such genes to be expressed only when the ambient pH is conducive to their ultimate functions. The intriguing issue of how pH is sensed and how the resulting signal is transmitted to the transcription factor involves at least one late endosome component. Proper functioning of the regulatory system responding to ambient pH is essential for fungal pathogenicity of both animals and plants.

Adaptation to environmental pH in Candida albicans and its relation to pathogenesis

For microorganisms that grow over a wide range of extracellular pH, systems must have evolved to sense and respond appropriately. The human opportunistic pathogen Candida albicans colonizes and infects anatomical sites of diverse pH, including the oral and gastro-intestinal tracts and the vaginal cavity. The ability to sense and respond to neutral-alkaline environments is governed by signal transduction pathways, one of which culminates in the activation of the transcription factor, Rim101p. The RIM101/pacC pathway, which governs pH responses and differentiation, has been the focus of study in both Saccharomyces cerevisiae and Aspergillus nidulans. This pathway has been identified in C. albicans and governs pH responses, dimorphism, and pathogenesis. Although C. albicans and S. cerevisiae are related fungi, it is becoming apparent that there are unique aspects of the pH response and the role the RIM101 pathway plays in this response in C. albicans.

Diverged binding specificity of Rim101p, the Candida albicans ortholog of PacC

The biology of Candida albicans, including dimorphism and virulence, is significantly influenced by environmental pH. The response to ambient pH includes the pH-conditional expression of several genes, which is directly or indirectly regulated by Rim101p. Rim101p is homologous to PacC, a transcription factor that regulates pH-conditional gene expression in Aspergillus nidulans. PacC binds 5'-GCCARG-3' sequences upstream of pH-responsive genes and either activates or represses transcription. The absence of pacC consensus binding sites upstream of PHR1, a RIM101-dependent, alkaline pH-induced gene of C. albicans, suggested either that PHR1 is indirectly regulated by Rim101p or that the binding specificity of Rim101p is different. In vitro binding studies demonstrated that Rim101p strongly bound two regions upstream of PHR1 that were only weakly bound by PacC. Deletion analysis and site-specific mutagenesis demonstrated that both sites were functionally significant, mutation of either site reduced RIM101-dependent induction, and expression was abolished in the double mutant. Furthermore, oligonucleotides containing these sites conferred pH-conditional expression when inserted upstream of a reporter gene. The consensus sequence of these sites, 5'-CCAAGAAA-3', was identical to the binding recognition sequence identified by in vitro selection of Rim101p binding oligonucleotides from a random pool. The functional significance of this binding sequence was reinforced by its observed presence upstream of a number of newly identified pH-conditional genes. We conclude that Rim101p acts as a transcription factor and directly regulates pH-conditional gene expression but has a binding specificity different from that of PacC.

The pH signalling transcription factor PacC controls virulence in the plant pathogen Fusarium oxysporum

Gene expression in fungi by ambient pH is regulated via a conserved signalling cascade whose terminal component is the zinc finger transcription factor PacC/Rim1p. We have identified a pacC orthologue in the vascular wilt pathogen Fusarium oxysporum that binds the consensus 5'-GCCAAG-3' sequence and is proteolytically processed in a similar way to PacC from Aspergillus nidulans. pacC transcript levels were elevated in F. oxysporum grown in alkaline conditions and almost undetectable at extreme acidic growth conditions. PacC+/- loss-of-function mutants displayed an acidity-mimicking phenotype resulting in poor growth at alkaline pH, increased acid protease activity and higher transcript levels of acid-expressed polygalacturonase genes. Reintroduction of a functional pacC copy into a pacC+/- mutant restored the wild-type phenotype. Conversely, F. oxysporum merodiploids carrying a dominant activating pacCc allele had increased pacC transcript and protein levels and displayed an alkalinity-mimicking phenotype with reduced acid phosphatase and increased alkaline protease activities. PacC+/- mutants were more virulent than the wild-type strain in root infection assays with tomato plants, whereas pacCc strains were significantly reduced in virulence. We propose that F. oxysporum PacC acts as a negative regulator of virulence to plants, possibly by preventing transcription of acid-expressed genes important for infection.

pH regulation in Aspergillus and parallels with higher eukaryotic regulatory systems

All organisms respond to their environment to some extent, and for many microbes the variation in environment can be enormous. An important asset for coping with environmental variation is physiological versatility--a hallmark of many fungi. The ability of fungi to thrive over a wide range of pH is partly due to a genetic regulatory system that tailors gene expression to the ambient pH. Here we focus on the pH regulatory system of Aspergillus nidulans, where a novel signal transduction (pal) pathway mediates the first of two steps in the proteolytic processing of a transcription factor (PacC). Such processing is reminiscent of that of some well-known higher eukaryotic transcription factors, such as Cubitus interruptus, NF-kappa B and sterol regulatory element binding proteins. Intriguingly, endocytosis seems to be connected to pH signalling.

YPXL/I is a protein interaction motif recognized by aspergillus PalA and its human homologue, AIP1/Alix

The zinc finger transcription factor PacC undergoes two-step proteolytic activation in response to alkaline ambient pH. PalA is a component of the fungal ambient pH signal transduction pathway. Its mammalian homologue AIP1/Alix interacts with the apoptosis-linked protein ALG-2. We show that both PalA and AIP1/Alix recognize a protein-protein binding motif that we denote YPXL/I, where Tyr, Pro, and Leu/Ile are crucial for its interactive properties. Two such motifs flanking the signaling protease cleavage site mediate direct binding of PalA to PacC, required for the first and only pH-regulated cleavage of this transcription factor. PalA can bind the "closed" (i.e., wild-type full-length) conformer of PacC, suggesting that PalA binding constitutes the first stage in the two-step proteolytic cascade, recruiting or facilitating access of the signaling protease, presumably PalB. In addition to recognizing YPXL/I motifs, both PalA and AIP1/Alix interact with the Aspergillus class E Vps protein Vps32 homologue, a member of a protein complex involved in the early steps of the multivesicular body pathway, suggesting that this interaction is an additional feature of proteins of the PalA/AIP1/Alix family.

New insights in the regulation of the afp gene encoding the antifungal protein of Aspergillus giganteus

The antifungal protein (AFP) secreted by the mould Aspergillus giganteus is a small, highly basic polypeptide with antifungal activity. Previous work has shown that transcription of the corresponding afp gene is regulated by ambient pH, being suppressed under acidic and strongly induced under alkaline conditions. This observation suggested that the afp gene is regulated by the wide-domain transcriptional factor PacC. Here, we show that two putative PacC binding sites within the afp promoter, denoted afpP1 and afpP2, are efficiently recognised in vitro by a PacC fusion protein of A. nidulans. In addition, we found that phosphate, which was used as a buffering agent during cultivation, plays an important role in regulating afp expression. AFP production was nearly completely inhibited in the presence of external phosphate. The results of Northern analysis indicate that the inhibitory effect of phosphate is mediated at the transcriptional level.

Relationship between secondary metabolism and fungal development

Filamentous fungi are unique organisms-rivaled only by actinomycetes and plants-in producing a wide range of natural products called secondary metabolites. These compounds are very diverse in structure and perform functions that are not always known. However, most secondary metabolites are produced after the fungus has completed its initial growth phase and is beginning a stage of development represented by the formation of spores. In this review, we describe secondary metabolites produced by fungi that act as sporogenic factors to influence fungal development, are required for spore viability, or are produced at a time in the life cycle that coincides with development. We describe environmental and genetic factors that can influence the production of secondary metabolites. In the case of the filamentous fungus Aspergillus nidulans, we review the only described work that genetically links the sporulation of this fungus to the production of the mycotoxin sterigmatocystin through a shared G-protein signaling pathway.

Regulation of gene expression by ambient pH in filamentous fungi and yeasts

Life, as we know it, is water based. Exposure to hydroxonium and hydroxide ions is constant and ubiquitous, and the evolutionary pressure to respond appropriately to these ions is likely to be intense. Fungi respond to their environments by tailoring their output of activities destined for the cell surface or beyond to the ambient pH. We are beginning to glimpse how they sense ambient pH and transmit this information to the transcription factor, whose roles ensure that a suitable collection of gene products will be made. Although relatively little is known about pH signal transduction itself, its consequences for the cognate transcription factor are much clearer. Intriguingly, homologues of components of this system mediating the regulation of fungal gene expression by ambient pH are to be found in the animal kingdom. The potential applied importance of this regulatory system lies in its key role in fungal pathogenicity of animals and plants and in its control of fungal production of toxins, antibiotics, and secreted enzymes.

A gene from Aspergillus nidulans with similarity to URE2 of Saccharomyces cerevisiae encodes a glutathione S-transferase which contributes to heavy metal and xenobiotic resistance

Aspergillus nidulans is a saprophytic ascomycete that utilizes a wide variety of nitrogen sources. We identified a sequence from A. nidulans similar to the glutathione S-transferase-like nitrogen regulatory domain of Saccharomyces cerevisiae Ure2. Cloning and sequencing of the gene, designated gstA, revealed it to be more similar to URE2 than the S. cerevisiae glutathione S-transferases. However, creation and analysis of a gstA deletion mutant revealed that the gene does not participate in nitrogen metabolite repression. Instead, it encodes a functional theta class glutathione S-transferase that is involved in resistance to a variety of xenobiotics and metals and confers susceptibility to the systemic fungicide carboxin. Northern analysis showed that gstA transcription is strongly activated upon exposure to 1-chloro-2,4-dinitrobenzene and weakly activated by oxidative stress or growth on galactose as a carbon source. These results suggest that nitrogen metabolite repression in A. nidulans does not involve a homolog of the S. cerevisiae URE2 gene and that the global nitrogen regulatory system differs significantly in these two fungi.

Activation of the Aspergillus PacC zinc finger transcription factor requires two proteolytic steps

The Aspergillus PacC transcription factor undergoes proteolytic activation in response to alkaline ambient pH. In acidic environments, the 674 residue translation product adopts a 'closed' conformation, protected from activation through intramolecular interactions involving the < or = 150 residue C-terminal domain. pH signalling converts PacC to an accessible conformation enabling processing cleavage within residues 252--254. We demonstrate that activation of PacC requires two sequential proteolytic steps. First, the 'closed' translation product is converted to an accessible, committed intermediate by proteolytic elimination of the C-terminus. This ambient pH-regulated cleavage is required for the final, pH-independent processing reaction and is mediated by a distinct signalling protease (possibly PalB). The signalling protease cleaves PacC between residues 493 and 500, within a conserved 24 residue 'signalling protease box'. Precise deletion or Leu498Ser substitution prevents formation of the committed and processed forms, demonstrating that signalling cleavage is essential for final processing. In contrast, signalling cleavage is not required for processing of the Leu340Ser protein, which lacks interactions preventing processing. In its two-step mechanism, PacC processing can be compared with regulated intramembrane proteolysis.

Genetic control of extracellular protease synthesis in the yeast Yarrowia lipolytica

Depending on the pH of the growth medium, the yeast Yarrowia lipolytica secretes an acidic protease or an alkaline protease, the synthesis of which is also controlled by carbon, nitrogen, and sulfur availability, as well as by the presence of extracellular proteins. Previous results have indicated that the alkaline protease response to pH was dependent on YlRim101p, YlRim8p/YlPalF, and YlRim21p/YlPalH, three components of a conserved pH signaling pathway initially described in Aspergillus nidulans. To identify other partners of this response pathway, as well as pH-independent regulators of proteases, we searched for mutants that affect the expression of either or both acidic and alkaline proteases, using a YlmTn1-transposed genomic library. Four mutations affected only alkaline protease expression and identified the homolog of Saccharomyces cerevisiae SIN3. Eighty-nine mutations affected the expression of both proteases and identified 10 genes. Five of them define a conserved Rim pathway, which acts, as in other ascomycetes, by activating alkaline genes and repressing acidic genes at alkaline pH. Our results further suggest that in Y. lipolytica this pathway is active at acidic pH and is required for the expression of the acidic AXP1 gene. The five other genes are homologous to S. cerevisiae OPT1, SSY5, VPS28, NUP85, and MED4. YlOPT1 and YlSSY5 are not involved in pH sensing but define at least a second protease regulatory pathway.

Specific expression and temperature-dependent expression of the acid protease-encoding gene (pepA) in Aspergillus oryzae in solid-state culture (Rice-Koji)

The synthesis of acid protease in rice-koji is important for sake brewing. Northern blot analysis was carried out to study the transcriptional regulation of acid protease-encoding gene (pepA in Aspergillus orytae. The pepA gene was not expressed in submerged culture, while it was expressed when cultured on steamed rice. Additionally, the culture at high temperature (>38 degrees C) caused a marked decrease in transcription level of pepA, although the alpha-amylase (amyB) and actin genes were expressed regardless of the temperature. To examine whether the pepA promoter controlled the temperature-dependent expression, the promoter regions of pepA and amyB were introduced into a vector containing the GUS reporter gene (uidA gene). Northern blot analysis showed that the elevation of culture temperature caused the loss of uidA expression in the pepA promoter-uidA transformant but not in the amyB promoter-uidA transformant. These results suggest that its promoter controlled the temperature-dependent expression of pepA.

Yeast PalA/AIP1/Alix homolog Rim20p associates with a PEST-like region and is required for its proteolytic cleavage

The Saccharomyces cerevisiae zinc finger protein Rim101p is activated by cleavage of its C-terminal region, which resembles PEST regions that confer susceptibility to proteolysis. Here we report that Rim20p, a member of the broadly conserved PalA/AIP1/Alix family, is required for Rim101p cleavage. Two-hybrid and coimmunoprecipitation assays indicate that Rim20p binds to Rim101p, and a two-hybrid assay shows that the Rim101p PEST-like region is sufficient for Rim20p binding. Rim101p-Rim20p interaction is conserved in Candida albicans, supporting the idea that interaction is functionally significant. Analysis of Rim20p mutant proteins indicates that some of its broadly conserved regions are required for processing of Rim101p and for stability of Rim20p itself but are not required for interaction with Rim101p. A recent genome-wide two-hybrid study (T. Ito, T. Chiba, R. Ozawa, M. Yoshida, M. Hattori, and Y. Sakaki, Proc. Natl. Acad. Sci. USA 98:4569-4574, 2000) indicates that Rim20p interacts with Snf7p and that Snf7p interacts with Rim13p, a cysteine protease required for Rim101p proteolysis. We suggest that Rim20p may serve as part of a scaffold that places Rim101p and Rim13p in close proximity.

Dimorphism in fungal pathogens: Candida albicans and Ustilago maydis--similar inputs, different outputs

The ability to switch between a yeast-like form and a filamentous form is an extended characteristic among several fungi. In pathogenic fungi, this capacity has been correlated with virulence because along the infection process, dimorphic transitions are often required. Two well-known organisms for which dimorphism have been studied are the pathogenic fungi Candida albicans and Ustilago maydis, which infect mammals and corn, respectively. In both cases, several signal transduction pathways have been defined. Not surprisingly, these pathways are similar to the well-known pathways involved in the pseudohyphal differentiation that some Saccharomyces cerevisiae diploid strains show when nutrients are starved. However, in spite of similarities at the molecular level, strikingly, fungi use similar pathways to respond to environmental inputs, but with differing outcomes.

Ambient pH signaling regulates nuclear localization of the Aspergillus nidulans PacC transcription factor

The Aspergillus nidulans zinc finger transcription factor PacC is activated by proteolytic processing in response to ambient alkaline pH. The pH-regulated step is the transition of full-length PacC from a closed to an open, protease-accessible conformation. Here we show that in the absence of ambient pH signaling, the C-terminal negative-acting domain prevents the nuclear localization of full-length closed PacC. In contrast, the processed PacC form is almost exclusively nuclear at any ambient pH. In the presence of ambient pH signaling, the fraction of PacC that is in the open conformation but has not yet been processed localizes to the nucleus. Therefore, ambient alkaline pH leads to an increase in nuclear PacC by promoting the proteolytic elimination of the negative-acting domain to yield the processed form and by increasing the proportion of full-length protein that is in the open conformation. These findings explain why mutations resulting in commitment of PacC to processing irrespective of ambient pH lead to permanent PacC activation and alkalinity mimicry. A nuclear import signal that targets Escherichia coli beta-galactosidase to the nucleus has been located to the PacC zinc finger region. A mutation abolishing DNA binding does not prevent nuclear localization of the processed form, showing that PacC processing does not lead to nuclear localization by passive diffusion of the protein made possible by the reduction in size, followed by retention in the nucleus after DNA binding.

Dominant active alleles of RIM101 (PRR2) bypass the pH restriction on filamentation of Candida albicans

Morphological development of the fungal pathogen Candida albicans is profoundly affected by ambient pH. Acidic pH restricts growth to the yeast form, whereas neutral pH permits development of the filamentous form. Superimposed on the pH restriction is a temperature requirement of approximately 37 degrees C for filamentation. The role of pH in development was investigated by selecting revertants of phr2Delta mutants that had gained the ability to grow at acid pH. The extragenic suppressors in two independent revertants were identified as nonsense mutations in the pH response regulator RIM101 (PRR2) that resulted in a carboxy-terminal truncation of the open reading frame. These dominant active alleles conferred the ability to filament at acidic pH, to express PHR1, an alkaline-expressed gene, at acidic pH, and to repress the acid-expressed gene PHR2. It was also observed that both the wild-type and mutant alleles could act as multicopy suppressors of the temperature restriction on filamentation, allowing extensive filamentation at 29 degrees C. The ability of the activated alleles to promote filamentation was dependent upon the developmental regulator EFG1. The results suggest that RIM101 is responsible for the pH dependence of hyphal development.

On the mechanism by which alkaline pH prevents expression of an acid-expressed gene

Previous work has shown that zinc finger transcription factor PacC mediates the regulation of gene expression by ambient pH in the fungus Aspergillus nidulans. This regulation ensures that the syntheses of molecules functioning in the external environment, such as permeases, secreted enzymes, and exported metabolites, are tailored to the pH of the growth environment. A direct role for PacC in activating the expression of an alkaline-expressed gene has previously been demonstrated, but the mechanism by which alkaline ambient pH prevents the expression of any eukaryotic acid-expressed gene has never been reported. Here we show that a double PacC binding site in the promoter of the acid-expressed gabA gene, encoding gamma-aminobutyrate (GABA) permease, overlaps the binding site for the transcriptional activator IntA, which mediates omega-amino acid induction. Using bacterially expressed fusion proteins, we have shown that PacC competes with IntA for DNA binding in vitro at this site. Thus, PacC repression of GABA permease synthesis is direct and occurs by blocking induction. A swap of IntA sites between promoters for gabA and amdS, a gene not subject to pH regulation, makes gabA expression pH independent and amdS acid expressed.

pH regulation of gene expression in fungi

A system for the regulation of gene expression by ambient (extracellular) pH was first identified in Aspergillus nidulans. This system consists of the products of the pacC and palA, B, C, F, H, and I genes. pacC encodes a zinc finger transcription factor and these pal genes encode components of an ambient pH signal transduction pathway. pH regulatory systems have also been identified in other fungi. Components of these regulatory systems are homologous to those in A. nidulans. This review describes the pH regulatory system in A. nidulans and the history of this research and how it relates to other systems. pH regulation in bacteria and animal cells is also briefly discussed.