Introducing fluorescence resonance energy transfer‐based biosensors for the analysis of cAMP‐PKA signalling in the fungal pathogen Candida glabrata

The cyclic adenosine monophosphate‐protein kinase A (cAMP‐PKA) pathway is central to signal transduction in many organisms. In pathogenic fungi such as Candida albicans, this signalling cascade has proven to be involved in several processes, such as virulence, indicating its potential importance in antifungal drug discovery. Candida glabrata is an upcoming pathogen of the same species, yet information regarding the role of cAMP‐PKA signalling in virulence is largely lacking. To enable efficient monitoring of cAMP‐PKA activity in this pathogen, we here present the usage of two FRET‐based biosensors. Both variations in the activity of PKA and the quantity of cAMP can be detected in a time‐resolved manner, as we exemplify by glucose‐induced activation of the pathway. We also present information on how to adequately process and analyse the data in a mathematically correct and physiologically relevant manner. These sensors will be of great benefit for scientists interested in linking the cAMP‐PKA signalling cascade to downstream processes, such as virulence, possibly in a host environment.     

Hsp90‐dependent regulatory circuitry controlling temperature‐dependent fungal development and virulence

The pathogenic fungi Candida albicans, Aspergillus fumigatus, and Cryptococcus neoformans are an increasing cause of human mortality, especially in immunocompromised populations. During colonization and adaptation to various host environments, these fungi undergo morphogenetic alterations that allow for survival within the host. One key environmental cue driving morphological changes is external temperature. The Hsp90 chaperone protein provides one mechanism to link temperature with the signalling cascades that regulate morphogenesis, fungal development and virulence. Candida albicans is a model system for understanding the connections between morphogenesis and Hsp90. Due to the high degree of conservation in Hsp90, many of the connections in C. albicans may be extrapolated to other fungal pathogens or parasites. Examining the role of Hsp90 during development and morphogenesis in these three major fungal pathogens may provide insight into key aspects of adaptation to the host, leading to additional avenues for therapy.     

Functional specialization and differential regulation of short‐chain carboxylic acid transporters in the pathogen Candida albicans

The major fungal pathogen Candida albicans has the metabolic flexibility to assimilate a wide range of nutrients in its human host. Previous studies have suggested that C. albicans can encounter glucose‐poor microenvironments during infection and that the ability to use alternative non‐fermentable carbon sources contributes to its virulence. JEN1 encodes a monocarboxylate transporter in C. albicans and we show that its paralogue, JEN2, encodes a novel dicarboxylate plasma membrane transporter, subjected to glucose repression. A strain deleted in both genes lost the ability to transport lactic, malic and succinic acids by a mediated mechanism and it displayed a growth defect on these substrates. Although no significant morphogenetic or virulence defects were found in the double mutant strain, both JEN1 and JEN2 were strongly induced during infection. Jen1‐GFP (green fluorescent protein) and Jen2‐GFP were upregulated following the phagocytosis of C. albicans cells by neutrophils and macrophages, displaying similar behaviour to an Icl1‐GFP fusion. In the murine model of systemic candidiasis approximately 20–25% of C. albicans cells infecting the kidney expressed Jen1‐GFP and Jen2‐GFP. Our data suggest that Jen1 and Jen2 are expressed in glucose‐poor niches within the host, and that these short‐chain carboxylic acid transporters may be important in the early stages of infection.     

cAMP regulates vegetative growth and cell cycle in <Emphasis Type="Italic">Candida albicans</Emphasis>

We demonstrate here the regulatory role of cAMP in cell cycle of Candida albicans. cAMP was found to be a positive signal for growth and morphogenesis. Phosphodiesterase inhibitor aminophylline exhibited significant effects, i.e., increased growth, as well as induced morphogenesis. Atropine and trifluoperazine negatively regulated (inhibited) growth and did not induce morphogenesis. These changes were attributed to increase in cAMP levels and protein kinase A (PKA) activity in presence of aminophylline, while reduction was observed in atropine and trifluoperazine (TFP) grown cells. Alteration in cAMP signaling pathway affected the cell cycle progression in Candida albicans. Increased cAMP levels in aminophylline grown cells reduced the duration of cell cycle by inciting the cell cycle-specific expression of G1 cyclins (CLN1 and CLN2). However atropine and trifluoperazine delayed the expression of G1 cyclins and hence prolonged the cell cycle. Implication of cAMP signaling pathway in both the cell cycle and morphogenesis further opened the channels to explore the potential of this pathway to serve as a target for development of new antifungal drugs.     

Evidence of morphology-specific isozymes inCandida albicans

S-Adenosylmethionine (SAM) synthetase of yeast and hyphal-phase cells of the dimorphic fungusCandida albicans was characterized by kinetic analysis and response to inhibitors. The enzyme from yeast-phase cells has a Km of 0.17 mM for methionine, 0.14 mM for ATP, and is inhibited (in vitro) by dimethyl-sulfoxide, methionine sulfone, and methionine sulfoxide. The hyphal-phase SAM synthetase has a Km of 0.06 mM for methionine, 0.02 mM for ATP, and its activity (in vitro) is enhanced by the substances that inhibit the yeast-phase enzyme. These data strongly suggest that isozymes of SAM synthetase are present inC. albicans and that they are possibly morphology specific. In vivo studies revealed that synthesis of the enzyme is repressed by the addition of methionine to the growth medium and that specific activity of the enzyme increases when intracellular SAM levels are lowered. In addition, it was shown that the increase in specific activity seen during yeast hypha morphogenesis and in yeast cells grown in a methionine-free medium involves de novo protein synthesis.     

Asc1p,a ribosomal protein,plays a pivotal role in cellular adhesion and virulence in <Emphasis Type="Italic">Candida albicans</Emphasis>

Candida albicans, the common human fungal pathogen, can switch morphology from yeast to pseudohyphal or hyphal form upon various environmental cues. It is well-known that the ability of morphological conversion and adhesive growth renders C. albicans virulent. It is noteworthy that every factor involved in the morphogenesis is known to be important for the virulence of this pathogen. To examine a functional relevance of Asc1p, a ribosomal protein, in morphogenesis and virulence, an asc1 homozygous null mutant was generated. Although a normal morphological transition of the asc1 deletion strain in liquid media was found, it did not change its morphology on solid media. Moreover, the adhesion activity and hyphal-specific gene expression were defective due to ASC1 deletion. Finally, it was found that the asc1 null mutant was avirulent in a mouse model. These results strongly suggested that Asc1p a component of the 40S ribosomal subunit and a signal transducer, plays a pivotal role in cellular adhesion and virulence through regulation of specific gene expression in C. albicans.     

LINE‐1 hypomethylation induced by reactive oxygen species is mediated via depletion of S‐adenosylmethionine

Whether long interspersed nuclear element‐1 (LINE‐1) hypomethylation induced by reactive oxygen species (ROS) was mediated through the depletion of S‐adenosylmethionine (SAM) was investigated. Bladder cancer (UM‐UC‐3 and TCCSUP) and human kidney (HK‐2) cell lines were exposed to 20 μM H₂O₂ for 72 h to induce oxidative stress. Level of LINE‐1 methylation, SAM and homocysteine (Hcy) was measured in the H₂O₂‐exposed cells. Effects of α‐tocopheryl acetate (TA), N‐acetylcysteine (NAC), methionine, SAM and folic acid on oxidative stress and LINE‐1 methylation in the H₂O₂‐treated cells were explored. Viabilities of cells treated with H₂O₂ were not significantly changed. Intracellular ROS production and protein carbonyl content were significantly increased, but LINE‐1 methylation was significantly decreased in the H₂O₂‐treated cells. LINE‐1 methylation was restored by TA, NAC, methionine, SAM and folic acid. SAM level in H₂O₂‐treated cells was significantly decreased, while total glutathione was significantly increased. SAM level in H₂O₂‐treated cells was restored by NAC, methionine, SAM and folic acid; while, total glutathione level was normalized by TA and NAC. Hcy was significantly decreased in the H₂O₂‐treated cells and subsequently restored by NAC. In conclusion, in bladder cancer and normal kidney cells exposed to H₂O₂, SAM and Hcy were decreased, but total glutathione was increased. Treatments with antioxidants (TA and NAC) and one‐carbon metabolites (SAM, methionine and folic acid) restored these changes. This pioneer finding suggests that exposure of cells to ROS activates glutathione synthesis via the transsulfuration pathway leading to deficiency of Hcy, which consequently causes SAM depletion and eventual hypomethylation of LINE‐1. Copyright © 2015 John Wiley & Sons, Ltd.     

Overexpression of S‐adenosyl‐l‐methionine synthetase increased tomato tolerance to alkali stress through polyamine metabolism

S‐adenosyl‐l ‐methionine (SAM) synthetase is the key enzyme involved in the biosynthesis of SAM, which serves as a common precursor for polyamines (PAs) and ethylene. A SAM synthetase cDNA (SlSAMS1) was introduced into the tomato genome using the Agrobacterium tumefaciens transformation method. Transgenic plants overexpressing SlSAMS1 exhibited a significant increase in tolerance to alkali stress and maintained nutrient balance, higher photosynthetic capacity and lower oxidative stress compared with WT lines. Both in vivo and in vitro experiments indicated that the function of SlSAMS1 mainly depended on the accumulation of Spd and Spm in the transgenic lines. A grafting experiment showed that rootstocks from SlSAMS1‐overexpressing plants provided a stronger root system, increased PAs accumulation, essential elements absorption, and decreased Na⁺ absorption in the scions under alkali stress. As a result, fruit set and yield were significantly enhanced. To our knowledge, this is the first report to provide evidence that SlSAMS1 positively regulates tomato tolerance to alkali stress and plays a major role in modulating polyamine metabolism, resulting in maintainability of nutrient and ROS balance.     

Towards non‐invasive monitoring of pathogen–host interactions during Candida albicans biofilm formation using in vivo bioluminescence

Candida albicans is a major human fungal pathogen causing mucosal and deep tissue infections of which the majority is associated with biofilm formation on medical implants. Biofilms have a huge impact on public health, as fungal biofilms are highly resistant against most antimycotics. Animal models of biofilm formation are indispensable for improving our understanding of biofilm development inside the host, their antifungal resistance and their interaction with the host immune defence system. In currently used models, evaluation of biofilm development or the efficacy of antifungal treatment is limited to ex vivo analyses, requiring host sacrifice, which excludes longitudinal monitoring of dynamic processes during biofilm formation in the live host. In this study, we have demonstrated for the first time that non‐invasive, dynamic imaging and quantification of in vitro and in vivo C. albicans biofilm formation including morphogenesis from the yeast to hyphae state is feasible by using growth‐phase dependent bioluminescent C. albicans strains in a subcutaneous catheter model in rodents. We have shown the defect in biofilm formation of a bioluminescent bcr1 mutant strain. This approach has immediate applications for the screening and validation ofantimycotics under in vivo conditions, for studying host–biofilm interactions in different transgenic mouse models and for testing the virulence of luminescent C. albicans mutants, hereby contributing to a better understanding of the pathogenesis of biofilm‐associated yeast infections.     

The type III effector AvrXccB in Xanthomonas campestris pv. campestris targets putative methyltransferases and suppresses innate immunity in Arabidopsis

Xanthomonas campestris pv. campestris (Xcc) causes black rot, one of the most important diseases of brassica crops worldwide. The type III effector inventory plays important roles in the virulence and pathogenicity of the pathogen. However, little is known about the virulence function(s) of the putative type III effector AvrXccB in Xcc. Here, we investigated the immune suppression ability of AvrXccB and the possible underlying mechanisms. AvrXccB was demonstrated to be secreted in a type III secretion system‐dependent manner. AvrXccB tagged with green fluorescent protein is localized to the plasma membrane in Arabidopsis, and the putative N‐myristoylation motif is essential for its localization. Chemical‐induced expression of AvrXccB suppresses flg22‐triggered callose deposition and the oxidative burst, and promotes the in planta growth of Xcc and Pseudomonas syringae pv. tomato in transgenic Arabidopsis plants. The putative catalytic triad and plasma membrane localization of AvrXccB are required for its immunosuppressive activity. Furthermore, it was demonstrated that AvrXccB interacts with the Arabidopsis S‐adenosyl‐l ‐methionine‐dependent methyltransferases SAM‐MT1 and SAM‐MT2. Interestingly, SAM‐MT1 is not only self‐associated, but also associated with SAM‐MT2 in vivo. SAM‐MT1 and SAM‐MT2 expression is significantly induced upon stimulation of microbe‐associated molecular patterns and bacterial infection. Collectively, these findings indicate that AvrXccB targets a putative methyltransferase complex and suppresses plant immunity.     

Viperin is an iron‐sulfur protein that inhibits genome synthesis of tick‐borne encephalitis virus via radical SAM domain activity

Viperin is an interferon‐induced protein with a broad antiviral activity. This evolutionary conserved protein contains a radical S‐adenosyl‐l ‐methionine (SAM) domain which has been shown in vitro to hold a [4Fe‐4S] cluster. We identified tick‐borne encephalitis virus (TBEV) as a novel target for which human viperin inhibits productionof the viral genome RNA. Wt viperin was found to require ER localization for full antiviral activity and to interact with the cytosolic Fe/S protein assembly factor CIAO1. Radiolabelling in vivo revealed incorporation of ⁵⁵Fe, indicative for the presence of an Fe‐S cluster. Mutation of the cysteine residues ligating the Fe‐S cluster in the central radical SAM domain entirely abolished both antiviral activity and incorporation of ⁵⁵Fe. Mutants lacking the extreme C‐terminal W361 did not interact with CIAO1, were not matured, and were antivirally inactive. Moreover, intracellular removal of SAM by ectopic expression of the bacteriophage T3 SAMase abolished antiviral activity. Collectively, our data suggest that viperin requires CIAO1 for [4Fe‐4S] cluster assembly, and acts through an enzymatic, Fe‐S cluster‐ and SAM‐dependent mechanism to inhibit viral RNA synthesis.     

S‐adenosyl‐l‐methionine usage during climacteric ripening of tomato in relation to ethylene and polyamine biosynthesis and transmethylation capacity

S‐adenosyl‐l ‐methionine (SAM) is the major methyl donor in cells and it is also used for the biosynthesis of polyamines and the plant hormone ethylene. During climacteric ripening of tomato (Solanum lycopersicum ‘Bonaparte’), ethylene production rises considerably which makes it an ideal object to study SAM involvement. We examined in ripening fruit how a 1‐MCP treatment affects SAM usage by the three major SAM‐associated pathways. The 1‐MCP treatment inhibited autocatalytic ethylene production but did not affect SAM levels. We also observed that 1‐(malonylamino)cyclopropane‐1‐carboxylic acid formation during ripening is ethylene dependent. SAM decarboxylase expression was also found to be upregulated by ethylene. Nonetheless polyamine content was higher in 1‐MCP‐treated fruit. This leads to the conclusion that the ethylene and polyamine pathway can operate simultaneously. We also observed a higher methylation capacity in 1‐MCP‐treated fruit. During fruit ripening substantial methylation reactions occur which are gradually inhibited by the methylation product S‐adenosyl‐l ‐homocysteine (SAH). SAH accumulation is caused by a drop in adenosine kinase expression, which is not observed in 1‐MCP‐treated fruit. We can conclude that tomato fruit possesses the capability to simultaneously consume SAM during ripening to ensure a high rate of ethylene and polyamine production and transmethylation reactions. SAM usage during ripening requires a complex cellular regulation mechanism in order to control SAM levels.