N-glycosylation of the protein disulfide isomerase Pdi1 ensures full Ustilago maydis virulence
Authors:
Miriam Marín-Menguiano aff001; Ismael Moreno-Sánchez aff001; Ramón R. Barrales aff001; Alfonso Fernández-Álvarez aff001; José Ignacio Ibeas aff001
Authors place of work:
Centro Andaluz de Biología del Desarrollo (CABD), Universidad Pablo de Olavide-Consejo Superior de Investigaciones Científicas-Junta de Andalucía, Ctra. Utrera km.1, Seville, Spain
aff001
Published in the journal:
N-glycosylation of the protein disulfide isomerase Pdi1 ensures full Ustilago maydis virulence. PLoS Pathog 15(11): e32767. doi:10.1371/journal.ppat.1007687
Category:
Research Article
doi:
https://doi.org/10.1371/journal.ppat.1007687
Summary
Fungal pathogenesis depends on accurate secretion and location of virulence factors which drive host colonization. Protein glycosylation is a common posttranslational modification of cell wall components and other secreted factors, typically required for correct protein localization, secretion and function. Thus, the absence of glycosylation is associated with animal and plant pathogen avirulence. While the relevance of protein glycosylation for pathogenesis has been well established, the main glycoproteins responsible for the loss of virulence observed in glycosylation-defective fungi have not been identified. Here, we devise a proteomics approach to identify such proteins and use it to demonstrate a role for the highly conserved protein disulfide isomerase Pdi1 in virulence. We show that efficient Pdi1 N-glycosylation, which promotes folding into the correct protein conformation, is required for full pathogenic development of the corn smut fungus Ustilago maydis. Remarkably, the observed virulence defects are reminiscent of those seen in glycosylation-defective cells suggesting that the N-glycosylation of Pdi1 is necessary for the full secretion of virulence factors. All these observations, together with the fact that Pdi1 protein and RNA expression levels rise upon virulence program induction, suggest that Pdi1 glycosylation is important for normal pathogenic development in U. maydis. Our results provide new insights into the role of glycosylation in fungal pathogenesis.
Keywords:
Maize – Plant pathogens – Plant fungal pathogens – Virulence factors – glycoproteins – glycosylation – Plant cell walls – Ustilago maydis
Introduction
Protein glycosylation is a common eukaryotic post-translational mechanism required for the correct folding, activity and secretion of many proteins. Glycosylation involves the synthesis and addition of different polysaccharide cores (sugars) to specific amino acids within a consensus sequence. Most glycoproteins are plasma membrane-associated cell wall and secreted proteins, which acquire glycosyl groups during their transit through the Endoplasmic Reticulum (ER) and Golgi Apparatus (GA) [1,2]. Defects during the synthesis or addition of sugars to target proteins affect many biological processes; for instance, impaired human protein glycosylation causes more than 100 severe embryonic development disorders [3]. In pathogenic fungi, glycosylation defects lead to a reduction or absence of virulence in plant and animal pathogens [4–8].
Protein glycosylation is divided into different types based on the structure and composition of the oligosaccharide cores and the amino acids to which they are attached. N- and O-glycosylation are the most common types in pathogenic fungi. N-glycosylation consists of the addition of an oligosaccharide core, composed of two N-acetylglucosamines (NAcGlc), nine mannoses (Man) and three glucose (Glc) molecules, NAcGlc2Man9Glc3, to the nitrogen chain of an asparagine residue in the sequence Asn-x-Ser/Thr, where x can be any amino acid except proline [9,10]. O-glycosylation is more variable than N-glycosylation in terms of the types of sugars added. In fungi O-mannosylation is the most common type of O-glycosylation and is characterized by the addition of Man residues to target proteins. In contrast to N-glycosylation, O-glycosylation involves sequential additions of Man to the oxygen chain of Ser or Thr amino acids although no amino acid consensus sequence has been identified [11]. N- and O- linked glycans are later processed during their transit across the ER and GA, and specific trimming of sugars is also essential for the function and secretion of glycoproteins [5,12].
Crucial components for fungal pathogenesis belonging to N- and O-glycosylation pathways have been identified in several organisms such as Candida albicans, Aspergillus nidulans, Cryptococcus neoformans, Magnaporthe oryzae or Ustilago maydis [4,6–8,13–15]. The loss of these proteins primarily affects those stages of pathogenic development that require robust glycoprotein secretion. The involvement of protein glycosylation in fungal virulence has been extensively explored in the corn smut fungus U. maydis [4,5,16].
U. maydis combines both pathogenic and non-pathogenic phases during its life cycle. During the non-pathogenic stage, Ustilago grows as haploid yeast-like cells that can be easily cultured in the laboratory. The pathogenic phase starts when two sexually compatible strains mate on the maize plant surface. Sexual compatibility is determined by two independent loci: locus a, which encodes a pheromone-receptor system; and locus b, which encodes a transcription factor formed by a bE/bW heterodimer. Formation of the bE/bW complex triggers development of an infective dikaryon filament [17]. Physical and chemical plant signals are sensed by filaments that develop a morphogenetic structure called the appressorium, which mediates plant cuticle penetration [18]. Once inside plant tissues, the fungus expands in a branched filamentous form generating hypertrophied plant cells, macroscopically visible as tumors [19–23].
N- and O-glycosylation are both crucial for U. maydis pathogenic development. The loss of the O-mannosytransferase Pmt4, which catalyzes the addition of mannoses to target proteins, compromises both appressorium formation and plant cuticle penetration. Hence, Δpmt4 cells are unable to invade the plant tissues and tumor induction is fully abolished [4]. Glucosidase I and II (Gls1 and Gas1/Gas2) are important for N-glycan processing in the ER and play crucial roles during the early stages of U. maydis plant colonization [5,8]. A reasonable explanation for these drastic virulence defects is that deficient glycosylation could greatly alter the location and/or function of glycoproteins involved in virulence, and consequently compromise multiple stages of U. maydis pathogenic development such as plant cuticle penetration, fungal progression inside plant tissues or plant defense responses. Despite the importance of Pmt4 and Gls1 for maize infection, the virulence factors glycosylated by these proteins are still poorly described. In this context, an in silico search for putative Pmt4 targets identified Msb2 as an O-glycoprotein, whose deletion causes virulence defects that resemble some of those described for the Δpmt4 mutant [16]. However, a more wide-ranging approach is required to find new glycosylated virulence factors.
In this work we devise a proteomics approach designed to identify N- and O-glycoproteins produced when the infection program is activated. Using this method, we identify several Gls1 and Pmt4 targets involved in virulence. Among these, we further characterize Pdi1, a disulfide isomerase protein whose glycosylation we demonstrate to be required for full virulence in maize plants due to its involvement in glycoprotein folding. Furthermore, we show that the deletion of Pdi1 affects glycoprotein secretion in U. maydis. We speculate about its role during the infection process, which could be related to ensuring the effective production and secretion of many virulence factors.
Results
Glycoproteomic screening for Pmt4 and Gls1 substrates
Previous work from our laboratory have shown that the U. maydis proteome contains a high number of putative O-glycoproteins mannosylated by the O-mannosyltransferase Pmt4 [16]. An in silico screen for proteins harboring Ser/Thr-rich regions, where Pmt4 attaches mannoses, revealed that around 65% of U. maydis proteins are potential O-glycosylation targets [16]. If proteins containing N-glycosylation sites are included, this number rises to over 70% of the proteome, suggesting a potential role for protein glycosylation in the activity of a high proportion of U. maydis proteins (S1 Fig). In order to identify virulence-related glycosylation targets, we designed a selective glycoproteomic screen based on the hypothesis that glycoproteins whose expression is modified upon virulence program induction are likely to have important roles in the pathogenic phase of the U. maydis life cycle.
For this screen we set out to analyze cell extracts corresponding to cytosolic, cell wall and secreted proteins using two-dimensional differential gel electrophoresis (2D-DIGE) to detect glycoproteins whose spot area or intensity were altered by the loss of Pmt4 or Gls1 and corresponding effect on O- or N- glycosylation activities, respectively. To isolate glycoproteins from cytosolic extract and avoid interference with other proteins, total protein extracts were enriched for mannose-containing proteins by Fast-Performance Liquid Chromatography (FPLC) using concanavalin A columns (Fig 1). Due to the high proportion of glycoproteins in cell wall and secreted extracts, FPLC enrichment was not applied to these preparations. The loss of biz1 leads to severe defects in appressoria development and penetration [24], which are reminiscent of the phenotypes observed in Δpmt4 and Δgls1 maize infections [4,5]. biz1 encodes a b-dependent zinc-finger protein whose induction activates pathogenic filamentous growth [24]. Hence, we hypothesized that effectors controlled by Biz1 might require glycosylation mediated by Pmt4 and/or Gls1. To test this, we expressed biz1 under the control of the carbon source-regulated Pcrg promoter that is induced by arabinose (biz ON) and repressed by glucose (biz OFF) [24,25]. Thus, FB1 wild-type (wt), Δpmt4 and Δgls1 cells harboring Pcrg controlled-biz1 were collected under inducing and repressing conditions and protein samples compared, using three replicas of each, to identify the differentially migrating proteins (Fig 1).
By applying the approach described above, we detected protein spots whose areas showed altered electrophoretic mobility compared to wt in a Biz1-dependent manner in both Δpmt4 and Δgls1 cells, presumably corresponding to O- and N-glycoproteins respectively. Using Matrix-Assisted Laser Desorption/Ionization–Mass Spectrometry (MALDI–MS) we identified four proteins in the cytosolic extract with altered mobility in both mutants that probably correspond to both O- and N-glycosylated proteins: the chorismate mutase Cmu1, the α-L-arabinofuranosidase Afg1, the invertase Suc2 and UMAG_10156, a putative disulfide-isomerase (Fig 2). In addition, we identified 27 N- or O-glycoproteins from the cytosolic extract, 6 from the cell wall extract and 11 from the secreted extract showing electrophoretic mobility changes (Fig 3, S1 Table). Of the proteins identified only Cmu1, UMAG_04926 (Pep4), Afg1 and UMAG_04309 (Afg3) have been previously characterized. Cmu1 is a secreted virulence factor that controls the metabolic status of plant cells during fungal colonization; deletion of cmu1 reduces U. maydis virulence in the solopathogenic strain CL13 [26]. Pep4 is a proteinase A located at the vacuole, which is involved in the yeast to micelium dimorphic transition and whose deletion causes reduced virulence including incomplete teliospore maturation [27]. On the other hand, Afg1 and Afg3 are arabinofuranosidases that participate in the degradation of arabinoxylan, a plant cell wall component. While the loss of afg1 or afg3 is dispensable for virulence, the triple deletion of afg1, afg2 and afg3 compromises full pathogenic development [28]. The involvement of the other identified proteins in pathogenesis remains to be determined.
The disulfide-isomerase Pdi1 is a substrate of Pmt4 and Gls1, and Pdi1 is required for pathogenesis
To determine the involvement in pathogenesis of the uncharacterized proteins, we compared the virulence capability of CL13 strain mutants carrying deletions corresponding to several of the candidate proteins. The CL13 strain harbors genes encoding a compatible bE1/bW2 heterodimer allowing it to complete full pathogenic development [29]. Analysis of disease symptoms after infection revealed strong virulence defects in Δafg1, ΔUMAG_00309, ΔUMAG_02751, ΔUMAG_03416, ΔUMAG_04180, ΔUMAG_04422, ΔUMAG_04733, ΔUMAG_05223, ΔUMAG_10156, and ΔUMAG_11496 infections (Fig 4A, S2 Fig and S1 Table). Candidate genes were then tested in more virulent strains; the wild type FB1 and FB2 strains [30], which have a higher infection capacity, and SG200, which carries the mfa2 gene that encodes the compatible mating type pheromone [29] and confers stronger virulence. Based on the virulence assays in these backgrounds we identified UMAG_10156 as having the most significant role in plant infection (Fig 4B, 4C and 4D). Blast analysis for UMAG_10156 revealed 36% identity to Saccharomyces cerevisiae Pdi1 with 48% and 43% identity in the two thioredoxin domains (Fig 5A and S3 Fig). Thus, we will now refer to UMAG_10156 as Pdi1 for the remainder of the article. S. cerevisiae Pdi1 is a disulfide-isomerase protein, member of the thioredoxin superfamily of redox proteins whose canonical role is to support the folding of newly synthesized proteins in the ER via the addition of disulfide bonds [31].
The loss of Pdi1 compromises fungal expansion inside plant tissues
Previous studies in budding yeast have shown that Pdi1 function is critical under ER stress conditions, where a large number of misfolded proteins are produced [32,33]. To confirm that this function of Pdi1 is retained in U. maydis, we explored Pdi1 localization and studied the ability of Δpdi1 cells to grow under reductive ER stress induced by dithiothreitol (DTT). Microscopy co-localization analysis of Pdi1:GFP and the ER marker mRFP:HDEL confirmed the localization of Pdi1 to this organelle (Fig 5B), where it has been shown to work in conjunction with Calnexin and Calreticulin in the refolding of glucosidated proteins [34]. Moreover, Δpdi1 cells showed a hypersensitivity response to DTT, thus confirming the canonical role of Pdi1 in U. maydis (Fig 5C and 5D).
To identify the causes behind the failure of Δpdi1 plant infections we first analyzed if the pdi1 deletion causes growth alterations under axenic conditions. We found no differences in generation time (~2.5 hours in rich media) (S4A Fig) or cell morphology (S4B Fig) between wt and Δpdi1 cells. Moreover, Δpdi1 did not show any defects in cell wall integrity or oxidative stress resistance (S5 Fig). Next, we examined if the mating capability between sexually compatible cells depends on Pdi1. This can be tested by analyzing dikaryon filament formation on charcoal plates, which are recognizable by the formation of white fuzzy colonies. We observed similar mating efficiency in FB1Δpdi1 and FB2Δpdi1 crosses compared to the wt strains (Fig 6A). Therefore, the pathogenic defects affecting Δpdi1 infections are probably not caused by failures in cellular growth or mating stages. Hence, the plant infection defects observed in pdi1 mutant cells probably appear during interaction with the host. In fact, we have observed an increase in both Pdi1 protein levels upon biz1 activation and pdi1 transcription during the infection process, with a peak at three days post infection (dpi) (Fig 6B and 6C), in agreement with a high-throughput transcriptomic analysis of pathogenesis [35]. These observations suggest that Pdi1 function is required during the plant infection process, possibly to ensure the correct folding of the increased quantity of glycosylated and secreted proteins that must be expressed for a successful infection to develop.
To determine which step of U. maydis pathogenic development is affected by the loss of Pdi1, we analyzed the behavior of Δpdi1 cells during plant cuticle pre-penetration stages. A physicochemical plant signal is recognized by the fungal cell, triggering filamentous growth and appressoria formation [18]. In order to quantify both phenotypes, we generated the pdi1 deletion in SG200 cells carrying RFP under the control of the constitutive otef promoter and co-inoculated maize plants with an equal mixture of SG200 PotefGFP and SG200 PotefRFP Δpdi1 cells. The amount of filaments and appressoria in wt and Δpdi1 cells was quantified using fluorescence microscopy ~15 hours after infection. We found that the absence of Pdi1 did not alter filament formation capability (Fig 6D). Moreover, Δpdi1 filaments developed appressoria normally (Fig 6E). Thus, plant penetration stages do not require Pdi1, which suggests that deficient fungal expansion inside plant tissues might be behind the Δpdi1 infection defects.
To address the state of fungal colonization inside plant tissues we stained infected maize leaves 3 and 5 days after inoculation using Wheat Germ Agglutinin (WGA)-Alexa and propidium iodide to visualize fungal hyphae and plant cells, respectively (see Methods). Following this approach, we observed a defective proliferation of Δpdi1 hyphae inside the plant (Fig 6F). To confirm these observations, we quantified fungal biomass in plant samples. We used the expression level of the U. maydis ppi1 gene as a fungal marker [36]. We found that the amount of fungal biomass 3 days post-infection decreased two-fold during Δpdi1 infection versus infection with a wt strain (Fig 6G). Thus, Pdi1 plays a key role in U. maydis colonization after plant penetration. Interestingly, this phenotype is reminiscent of defects caused by N-glycosylation defective cells [5] suggesting that altered Pdi1 function might be partly responsible for the defects associated with the loss of N-glycosylation.
Loss of Pdi1 N-glycosylation mimics Δpdi1 virulence defects
An important remaining question is whether the loss of Pdi1 glycosylation mediated by Pmt4 and Gls1 leads to dysfunctional Pdi1 and a reduction in virulence similarly to Δpdi1 cells, or alternatively, a non-glycosylated Pdi1 form is still able to induce plant tumors and Pmt4 and Gls1 affect virulence elsewhere. To address this issue, putative O- and N-glycosylation sites were substituted with alanine (S4A, S24A, S340A, S344A, S346A, S350A, S477A and T486A) and glutamine (N36Q and N484Q) residues, respectively (Methods, Fig 7A). Pdi1 alleles harboring substitutions at all O-glycosylation sites (Pdi1ΔO-gly), all N-glycosylation sites (Pdi1ΔN-gly), all O- and N-glycosylation sites (Pdi1ΔN,O-gly) or the wild type allele were introduced as single copies in the exogenous ip locus of Δpdi1 cells under the control of the pdi1 promoter and their ability to infect maize plants tested. We found that while Pdi1ΔO-gly restored the virulence defects observed in Δpdi1 cells during infection in a similar manner to the wt allele, the Pdi1ΔN-gly form failed to complement the lack of Pdi1 (Fig 7B) and the Pdi1ΔN,O-gly form partially complemented the loss of Pdi1. Similar results were obtained when the different Pdi1 alleles were expressed under the control of the otef promoter (S6 Fig). This strongly suggests that only the N-glycosylation of Pdi1 is relevant for its role in virulence. Similarly to Δpdi1 cells, the virulence defects observed in Pdi1ΔN-gly, are due to a failure in the fungal expansion inside the plant tissues (Fig 7C). Remarkably, Pdi1ΔN-gly could be detected by western blot discarding a possible degradation of Pdi1 in the absence of proper N-glycosylation (Fig 7D). Moreover, Pdi1ΔN-gly:GFP maintained wild-type Pdi1:GFP subcellular localization to cells membranes and the ER (Fig 7E). Consistent with defective Pdi1 function during plant infection when N-glycosylation target residues are removed, we observed that Pdi1ΔN-gly does not complement the DTT sensitivity shown by the Pdi1 deletion mutant (Fig 7F) which has been previously associated to the lack of Pdi1 activity [37].
Δpdi1 and Δgls1 show similar secreted protein defects
Taking our results together with the established functions of Pdi1 in other model organisms lead us to propose a model whereby Gls1-mediated glycosylation of Pdi1 is required for correct folding and subsequent secretion of proteins activated by the virulence program. To explore this hypothesis, we compared the secretomes of wt, Δpdi1 and Δgls1 cells upon Biz1 induction (pathogenic filamentous growth) conditions. We found 6 secreted proteins showing differential electrophoretic mobility in wt versus Δpdi1 cells: UMAG_06158 (probable glutaminase A), UMAG_01829 (Afg1, previously identified in our first screening, see Fig 2), UMAG_04503, an α-N-acetylgalactosaminidase, and UMAG_01213, UMAG_00027 and UMAG_11462 (3 uncharacterized proteins) (see Fig 8). Remarkably, 4 out of these 6 proteins (UMAG_06158, UMAG_01829, UMAG_04503 and UMAG_00027) were also identified in the comparison between wt and Δgls1 secretomes suggesting that the effects caused by Δgls1 might be explained by deficient Pdi1 function. This indicates that there is a pool of secreted proteins that are glycosylated by Gls1 and their proper folding is dependent on Pdi1, which itself requires Gls1-mediated glycosylation for function. The fact that the number of glycoproteins altered by the loss of gls1 is higher than by pdi1 is probably because a group of N-glycoproteins does not require Pdi1 for correct folding, secretion and function (See model Fig 9). This is consistent with the fact that Δgls1 causes more severe virulence defects than Δpdi1.
Discussion
In this work, we have demonstrated that the use of glycosylation mutants Δpmt4 and Δgls1 in a virulence program-specific 2D-DIGE protein analysis is a suitable and effective approach for identifying Ustilago maydis glycoproteins involved in plant infection. We identified 35 glycoproteins, and showed that 14 out of the 28 assayed are involved in virulence, analyzing single deletion mutants. Of these mutants, loss of the protein disulfide isomerase Pdi1 had the strongest effect on virulence, most likely due to protein folding defects and changes in functionality and/or secretion of proteins required for plant infection.
An effective method for identifying new glycosylated fungal effectors
It is well established that protein glycosylation is essential for fungal infection. Mutants for specific glycosyltransferases or glycosidades are affected at different stages of the infection process in Ustilago maydis [4,5], other plant pathogens such as Penicilium digitatum [38], Margnaporthe oryzae [15,39] and Botrytis cinerea [40] as well as in animal pathogens such as Candida albicans [13,41] and Cryptococcus neoformans [6,42,43]. Thus, our interest focused on determining which of the glycosylated proteins produced during the infection process were responsible for those defects. We postulated cell wall and secreted proteins as the main sources of novel virulence factors. Cell wall proteins form the pathogen’s most external layer while secreted factors have well established roles as effector proteins [44]. Significantly, almost all cell wall and secreted factors are glycosylated [45,46]. U. maydis putatively secretes 467 effectors that contribute to the establishment of biotrophy with maize during the infection process [19,22]. In silico tools such as SignalP [47], ApoplastP [48] or EffectorP [49] can predict which proteins are secreted and could be putative effectors. Although useful guides, such bioinformatic tools are not completely reliable since it has also been demonstrated that some fungal effectors are not secreted through the canonical secretion pathway involving N-terminal signal peptide degradation prior to translocation to the ER [50–53]. For example, while around 90% of proteins secreted by Fusarium graminearum in axenic culture possess a signal peptide, only 56% of proteins secreted during the infection process have secretion signals [54]. Different strategies such as RNA-seq and microarray, have been employed in U. maydis in order to identify effectors whose transcription is induced during infection [55–58]. Such studies highlight the huge changes in gene expression that occur during different stages of the infection process. Nevertheless, none of these approaches took into consideration the relevance of protein modification, which are especially important for secreted proteins. For this reason, a proteomics approach can be an attractive alternative to identify proteins with important roles in the plant infection process. Hence, in this work we established a new strategy to identify glycosylated effectors based on their electrophoretic mobility. Alterations to the glycosylation status of a protein in O- or N-glycosylation mutant strains, Δpmt4 or Δgls1 respectively, can be detected by bidimensional gel electrophoresis. This strategy allowed us to identify 27 glycoproteins from the cytosolic extract, 11 from the secreted protein extract and 6 from the cell wall extract, with some detected in multiple extracts. It is important to highlight that this approach identified previously characterized proteins involved in virulence as well as known effectors such as Afg1 and Afg3 [28], Pep4 [27] and Cmu1 [26]. Among the 35 proteins identified, 4 are cell wall proteins that could be related to plant interaction during infection and 18 are located (Djamei, personal communication) and/or predicted to be located at the apoplastic region (S1 Table), which is consistent with effector protein function. Similar proteomic strategies based on glycosylation changes after the activation of virulence programs have been used to identify new fungal effectors in other pathogenic fungi. For example, the controlled induction of Mst11, a Magnaporthe oryzae Mitogen-Activated Protein Kinase (MAPK) essential for appressoria formation and plant infection [59] has been assayed in O-glycosylation mutants such as ΔMoPmt2 [39] and ΔMoPmt4 [60], as well as in N-glycosylation mutants such as Δalg3 [15] and ΔMogls2 [61].
Although it has been described that many single effector gene deletions do not affect plant infection [22], half of the glycoprotein deletions examined in a CL13 background showed a reduction in the number or size of tumors when maize plants were infected (Fig 4 and S2 Fig). In fact, 14 of the 28 single deletion mutants assayed showed a statistically significant decrease in the number of tumors. Interestingly, four of these deletions induced only very small (<1 mm) tumors. Ten of the most promising candidates were then deleted in the SG200 strain and tested for virulence in maize plants, showing that Δpdi1 was the least virulent mutant. Single deletions for the other genes in this background caused little or no reduction in virulence. This observation may be explained by the fact that the CL13 strain does not possess the pheromone encoding gene mfa2 [29] resulting in a reduced ability to develop filaments and produce tumors during maize plant infection. Thus, CL13 is more sensitive to the deletion of genes with minor but important contributions to the infection process.
Total disruption of the whole glycosylation process in U. maydis leads to avirulent phenotypes because of its inability to develop functional appressoria (Δpmt4) or due to failure to spread inside the maize plant (Δgls1) [4,5,62], however we did not find a single factor which resembles these phenotypes. The reason why this single factor was not identified might be because U. maydis instead uses a pool of glycosylated effectors that work cooperatively to perform the different steps involved in plant invasion and colonization.
Pdi1 is a key factor supporting U. maydis pathogenic development
Of all the virulence-related glycoproteins identified here, we chose to further characterize Pdi1 as its deletion led to the strongest reduction in virulence. As we expected, Pdi1 localized to the ER and its deletion led to growth defects in axenic culture when an ER stress-inducing drug such as DTT was added to either solid or liquid media (Fig 5). These results support the idea that Pdi1 is a disulfide-isomerase protein that might assist the folding of newly synthetized proteins in the ER via the addition of disulfide bonds, which is critical during ER stress conditions [33]. Hence, the loss of Pdi1 could potentially affect the function of other proteins leading to general defects in different processes such as cell viability, growth, metabolism or cell signaling, among others. Although pdi1 deletion did not impair cell viability or growth under normal conditions (S4 Fig), we cannot rule out the possibility that such indirect effects could influence pathogenic progression. Many U. maydis effector proteins harbor cysteine-rich regions suitable for the formation of disulfide bonds, which may be necessary for their acquisition of active conformations [22,63,64]. Thus, Pdi1’s role in establishing disulfide bonds in proteins involved in plant infection could be a major part of how the Δpdi1 mutation affects virulence. Moreover, both calreticulin (CRT) and calnexin (CNX), which bind glycosylated N-glycans in the ER, have a Pro-rich arm that may bind a protein disulfide isomerase [34], such as Pdi1. N-glycans may also play an important role in ER-associated degradation (ERAD) of proteins [34]. Consequently, Pdi1 may be directly or indirectly involved in the selection of misfolded glycoproteins for dislocation into the cytosol for degradation by proteasomes, i.e., through N-glycans and mannosidase 1 (Mns1) and a second set of proteins called MnlI (mannosidase-like), Htm1 (homologous to mannosidase), or ER degradation-enhancing α-mannosidase-like protein (EDEM) [1,34,65,66]. Additionally, it has been shown that Pdi1 from Botrytis cinerea is also related to NADPH oxidase signaling [67] and thus Pdi1 could be also involved in ROS production to counteract plant oxidative burst responses.
Modification of the two putative N-glycosylation motifs identified in the Pdi1 ORF affected its ability to recover the infective capacity of a pdi1 mutant. Because Pdi1 activity, in terms of cell growth capacity under DTT-induced reductive ER stress [37] it suggests that N-glycosylation of Pdi1 may be required for its in vivo function. Consistent with this idea, the modification of the putative N-glycosylation motifs affected Pdi1 electrophoretic mobility, without affecting Pdi1 cellular location or stability, making it unlikely that the Pdi1ΔN-gly point mutations have grossly affected Pdi1 synthesis or conformation. Moreover, similar alanine substitutions within all nine putative O-glycosylation motifs had no effect on the ability of Pdi1 to rescue the DTT-induced growth defect. Thus, while it remains possible that the two Pdi1ΔN-gly—point mutations have an effect on Pdi1 activity unrelated to N-glycosylation, the most likely explanation of our evidence is that N-glycosylation is specifically required for Pdi1 activity. Interestingly, while the double Pdi1ΔN,O-gly mutant shows similar defects in Pdi1 activity as the ΔN- mutant, it actually complements the lack of Pdi1 slightly better than the ΔN- one. In summary, our evidence suggests that N-glycosylation of Pdi1 is important for its activity in vivo but that further investigation is required to fully understand the role of glycosylation on Pdi1 function.
We have demonstrated that the Pdi1 deletion strain can complete the initial steps of the infection process, appressoria formation and dikaryotic filament formation normally (Fig 6D and 6E). Inside the maize plant, this mutant is able to form clamp-like cells and hyphae spread into maize cells although it cannot reach the vascular tissue. This growth defect was also observed by qPCR fungal biomass quantification, with more than a 50% reduction in fungal biomass versus wild-type (Fig 6G). During U. maydis biotrophic development until tumor formation at 6 dpi, the fungus has to form the dikaryotic filament, develop appressoria, penetrate into the plant, modify plant metabolism to avoid activation of the plant’s immune system and ensure its proper propagation inside the host. In order to achieve all these tasks, U. maydis secretes several early effectors such as Pep1 [68,69], Pit2 [70], Stp1 [35] and See1 [71]. As Δpdi1 did not show any defects in appressoria formation, dikaryotic filament formation or maize plant penetration, the reduction in fungal biomass observed in this mutant may be the result of a failure of the folding and secretion of proteins to the apoplast. Therefore, we propose four non-mutually exclusive mechanisms by which the loss of Pdi1 could affect fungal virulence: i) a reduction in ER stress resistance and defective Reactive Oxygen Species (ROS) signaling; ii) a decrease or abolition in the secretion of effectors; iii) a reduction or elimination of the activity of the secreted effectors; iv) the presence of abnormally folded proteins that behave as new pathogen-associated molecular patterns (PAMPs) and activate the plant immune system. Work towards deciphering the molecular basis of Pdi1 action during plant infection and testing the above hypotheses is currently ongoing in our laboratory. Our results raise the possibility that mechanisms linking glycosylation and disulfide bond formation of fungal effectors are conserved and highlight the need to explore Pdi1’s role in other fungal pathogens.
Materials and methods
Strains, plasmid and growth conditions
Escherichia coli DH5α and pGEM-T easy (Promega) and pJET1.2/blunt (ThermoFisher Scientific) were used for cloning purposes. Growth conditions for E. coli [72] and U. maydis [73] have been previously described. U. maydis strains used in this study are listed in S2 Table.
To induce the over-expression of transcription factor Biz1 [24], FB1Biz1crg and its derivative mutants (FB1Biz1crgΔpmt4, FB1Biz1crgΔgls1 and FB1Biz1crgΔpdi1) cells were grown at 28ºC in complete medium (CM) supplemented with D-glucose 25% (CMD), washed twice with water and grown in CM supplemented with arabinose 25% (CMA) at 28ºC for 8 hours.
Pathogenicity assays were performed as described in [19]. U. maydis cultures were grown at 28ºC to exponential phase in liquid YEPSL (0.4% bactopeptone, 1% yeast extract and 0.4% saccharose) and concentrated to an OD600 of 3, washed twice in water and injected into 7 days old maize (Zea mays) seedlings (Early Golden Bantam). Disease symptoms were quantified 14 dpi. Statistical analyses were performed in GraphPad Prism 6 software.
ER stress assays were carried out with cultures grown at 28ºC to exponential phase in CMD and spotted at 0.4 OD600 onto CM plates supplemented with 4 mM DTT (iNtRON Biotechnology). Plates were incubated for 48 h at 28ºC. For ER stress assay in liquid culture, U. maydis cells were grown to exponential phase in YEPSL and diluted to 0.1 OD600 in YEPSL with 10 mM DTT. Cell growth at 28ºC with continuous shaking was analyzed over 24 h using a Spark 10M (Tecan) fluorescence microplate reader.
Cell wall integrity and oxidative stress assays were carried out with cultures grown at 28ºC to exponential phase in CMD and spotted at 0.4 OD600 in CM plates supplemented with calcofluor white 40 μg/ml (Sigma-Aldrich), Congo Red 50 μg/ml (Sigma-Aldrich), Tunicamycin 1 μg/ml (Sigma-Aldrich), Sorbitol 1M (Sigma-Aldrich), 2% DMSO (Sigma-Aldrich), H2O2 1.5 mM (Sigma-Aldrich) and NaCl 1M (Sigma-Aldrich). Plates were incubated for 48 h at 28ºC.
For mating and filamentation assays, cells were grown in liquid YEPSL until exponential phase, washed twice with sterile bidistilled water, spotted onto PD-charcoal plates and grown for 24–48 hours at 25-28ºC.
DNA and RNA procedures
Molecular biology techniques were used as described in [72]. U. maydis DNA isolation and transformation were carried out following the protocol described in [74].
To generate deletion mutants, 1 kb fragments of the 5’ and 3’ flanks of the gene of interest (goi) ORF were generated by PCR using Phusion High Fidelity DNA polymerase (New England Biolabs) or Q5 High-Fidelity DNA polymerase (New England Biolabs) and U. maydis FB1 genomic DNA, using the primers goiKO5-1 and goiKO5-2 (containing a SfiI restriction site) to amplify the 5’ flank and goiKO3-1 (containing a SfiI restriction site) and goiKO3-2 to amplify the 3’ flank (S3 Table). These fragments were digested with SfiI and ligated with the 1.9-kb SfiI carboxin, 1.4-kb SfiI noursethricin (ClonNAT), 2-kb SfiI geneticin or 1.9-kb SfiI hygromicin resistance cassettes [75]. Constructs were cloned into pGEM-T easy (Promega) or pJET1.2/blunt (ThermoFisher Scientific) plasmids and amplified by PCR using the primers goiKO5-1/goiKO3-2, prior to their transformation in U. maydis.
To generate SG200 2xRFPΔpdi1 used for filament quantification into the maize plant, pGEM-TΔpdi1:cbx plasmid was digested with SfiI to excise the carboxin resistance cassette and ligated to a hygromicin resistance cassette isolated from pMF1h [75] with SfiI/BsaI double digestion, leading to pGEM-TΔpdi1:hyg. This construct was amplified by PCR with Phusion DNA polymerase using primers pdi1KO5-1/pdi1KO3-2 and integrated into the SG200 2xRFP strain [76].
For the SG200 3xGFP strain used for filament quantification in planta, the pOG plasmid [76], containing 3xGFP under the control of the otef promotor and a hygromicin resistance cassette, was digested with PsiI and integrated into the SG200 strain. Finally, Δpdi1:cbx was amplified by PCR using primers pdi1KO5-1/pdi1KO3-2 and integrated into the SG200 3xGFP strain.
To perform pdi1 deletion complementation assays, we generated the SG200Δpdi1Potefpdi1 strain. To this end, the eGFP fragment in p123 [77] was substituted with the pdi1 ORF. The pdi1 ORF was amplified by PCR using Phusion HF DNA polymerase (New England Biolabs) with primers pdi1StartXmaI and pdi1StopNotI, containing XmaI and NotI restriction sites, respectively. The PCR product was digested with XmaI and NotI, purified and cloned into the p123 plasmid digested with both restriction enzymes, creating p123-pdi1. Finally, p123-pdi1 was linearized with SspI and integrated into the SG200Δpdi1 ip locus by homologous recombination.
To create an O-glycosylation deficient pdi1 mutant, serine or threonine sites predicted by NetOgly 4.0 tool were replaced by site-direct mutagenesis using GenScript (Piscataway, USA), generating the plasmid pUC57-pdi1mutO-gly, with Sma1 and NotI restriction sites. The pdi1mutO-gly construct was reintroduced into p123 as described above, creating the p123-pdi1mutO-gly vector. This plasmid was linearized with SspI and integrated into the SG200Δpdi1 ip locus by homologous recombination, generating the SG200Δpdi1pdiΔO-gly strain.
To generate an N-glycosylation mutant version of pdi1, asparagine 36 and 484 were replaced by glutamine in N-glycosylation sites through PCR using the Gibson Assembly Cloning Kit (New England BioLabs, Frankfurt, Germany) with primers PDI1Asn36mut-1 and PDI1Asn36mut-2 for the mutation N36Q and primers PDI1Asn484mut-1 and PDI1Asn484mut-2 for the mutation N484Q, using p123-pdi1 as template, generating the plasmid p123-pdi1mutN-gly. This construction was integrated into the SG200Δpdi1 ip locus (as described above), leading to SG200Δpdi1pdiΔN-gly strain.
To generate the O- and N-glycosylation pdi1 mutant, N36 and N484 was replaced by glutamine using PCR and the Gibson Assembly Cloning Kit, with primers PDI1Asn36mut-1/PDI1Asn36mut-2 for the N36Q mutation and PDI1Asn484mutThr486mut-1/PDI1Asn484mutThr486mut-2 for the N484Q mutation, and the plasmid p123-pdi1mutO-gly as template, reintroduced into p123 to generate p123-pdi1mutN,O-gly. This construct was linearized with SspI and reintegrated into the SG200Δpdi1 ip locus.
All pdi1 mutants for N- and/or O-glycosylation were confirmed by sequencing, using primers PDI1SeqI and PDI1SeqII.
To generate plasmids containing the different pdi1 versions under the control of the pdi1 promoter, plasmids p123-pdi1, p123-pdi1mutN-gly, p123-pdi1mutO-gly and p123-pdi1mutN,O-gly were digested with PvuII and SmaI restriction enzymes to eliminate the otef promoter and purified. The pdi1 promoter was then amplified by PCR using Q5 DNA polymerase with primers pPdi1-F-NEB and pPdi1-R-NEB containing a p123 plasmid overlapping sequence of 20 bp and cloned into the different p123 derivative plasmids with NEBuilder HiFi DNA Assembly (New England Biolabs), according to the manufacturer’s protocol. These vectors were linearized with SspI and reintegrated into the SG200Δpdi1 ip locus by homologous recombination, leading to SG200Δpdi1 pPdi1:pdi1wt, SG200Δpdi1 pPdi1:pdiΔO-gly, SG200Δpdi1 pPdi1:pdiΔN-gly and SG200Δpdi1 pPdi1:pdiΔN,O-gly strains.
For GFP tagging of pdi1, we generated plasmid pDL51-pdi1. This plasmid is a p123 derivative [16] where pdi1 ORFs were PCR amplified using Phusion DNA polymerase with primers pdi1ORF5/pdi1ORF3, was cloned in frame with the GFP present in the plasmid, under the control of the constitutive expressed otef promotor. To achieve this, pDL51 was linearized with SfiI digestion and ligated with the pdi1 ORF digested with SfiI. For GFP tagging of the N-glycosylation mutant version of Pdi1, pdi1mutN-gly was amplified by PCR with primers pdi1StartXmaI and pdi1StopNcoI containing XmaI and NcoI restriction sites, respectively. The PCR product was digested with XmaI and NcoI, purified and cloned into the p123GFP plasmid digested with both restriction enzymes, to generate an in frame C-terminal pdi1mutN-gly GFP fusion. Finally, p123-pdi1mutN-glyGFP was linearized with SspI and integrated into the SG200Δpdi1 ip locus by homologous recombination.
For fungal biomass quantification, 3 and 5 dpi maize leaves were grown in liquid nitrogen and total DNA was isolated with DNeasy Plant Mini kit (Qiagen) according to manufacturer’s instructions. Fungal biomass was then quantified by Real-Time PCR with an ABIPRISM 7000 Sequence Detection System (Applied Biosystems) using the Power SYBR Green PCR Master Mix (ThermoFisher Scientific) according to the manufacturer’s protocol, measuring the constitutively-expressed fungal ppi1 gene, using primers RT-PPI1-5/RT-PPI1-3, and and constitutively-expressed plant gapdh, using primers Gapdh-F/Gapdh-R for normalization purposes. 100 ng of total DNA was used a template for each reaction.
For Pdi1 expression analysis, RNA from FB1 axenic culture and maize plants infected with FB1 and FB2 was isolated at 1, 3, 5 and 9 dpi, ground in liquid nitrogen using a pestle and mortar and purified using TRIzol reagent (Thermo Fisher Scientific) and the Direct-zol RNA Miniprep Plus kit (Zymo Research), following the manufacturer’s instructions. cDNA was synthetized using RevertAid H Minus First Strand cDNA Synthesis kit (Thermo Fisher Scientific) following the manufacturer’s instructions. Pdi1 expression levels were quantified by qRT-PCR using a Real-Time CFX Connect (Biorad) and SYBR Premix Ex Taq II (Tli RNase H Plus) (Takara) according to the manufacturer’s protocol, measuring pdi1 expression gene, using primers pdi1 RT-fwd/pdi1 RT-rev, and ppi1 as a constitutively-expressed control, using primers RT-PPI1-5/RT-PPI1-3.
Proteomic analysis
To detect pathogenesis-related changes to the cytosolic proteome caused by the loss of pmt4, we isolated O-glycosylated proteins from FB1Biz1crg and FB1Biz1crgΔpmt4 strains. FB1 and FB1Δpmt4 strains were used as controls. Cells from each strain were grown in 1 L of CMD to an OD600 = 0.5–0.8, washed twice with sterile bidistilled water and grown for 8 hours in 1 L of CMA. After filamentation induction, samples were harvested by centrifugation, washed twice in ice-cold 20 mM Tris-HCl buffer (pH 8.8) and frozen at −80ºC. Cells were then resuspended in lysis buffer (20 mM Tris-HCl, 0.5 M NaCl, pH 7.4) containing protease inhibitor cocktail (cOmplete Tablets, EDTA-free, Roche) after which cell lysis was performed using glass beads (Sigma) in a FastPrep-24 homogeniser (MP Biomedicals), with power set to 6.0 using 3 x 45” pulses at maximum speed with 5 min rest between cycles. After cell lysis, tubes were drilled with a needle and put into a new tube and samples were recovered by centrifugation at 4000 rpm for 1 min. Subsequently, samples were centrifuged at 14000 rpm for 30 min at 4ºC and the supernatant was collected. One volume of 2x binding buffer (20 mM Tris-HCl, 0.5 M NaCl, 2 mM MnCl2, 2 mM CaCl2, pH 7.4) was added and concentrated using Amicon Ultra-15 3 kDa centricon (Merk Millipore) and O-glycosylated proteins isolated by affinity chromatography using Concavaline A columns (HiTrap Con A 4B, GE Healthcare) in AKTA FPLC (GE Healthcare), and eluted with a buffer containing 20 mM Tris-HCl, 0.5 M NaCl and 0.5 M methyl-α-D-manopyranoside (pH 7.4).
To detect pathogenesis-related changes to the cytosolic proteome caused by the loss of gls1, FB1Biz1crg and FB1Biz1crgΔgls1 cells were grown in 1 L of CMD to an OD600 = 0.5–0.8, washed twice with sterile distilled water and grown for 8 hours in 1 L of CMA. FB1 and FB1Δgls1, used as controls, were grown in 2 L of CMD to an OD600 = 0.5–0.8, washed twice with sterile distilled water and grown during 8 hours in 2 L of CMA. Samples were harvested by centrifugation, washed twice in ice-cold 20 mM Tris-HCl buffer (pH 8.8) and frozen by dropping samples in liquid nitrogen. Cells were lysed with 3–4 cycles in 6870 Freezer/Mill (SPEX, SamplePrep) according to the manufacturer’s instructions. Samples were resuspended in binding buffer (20 mM Tris-HCl, 0.5 M NaCl, 2 mM MnCl2, 2 mM CaCl2, pH 7.4) containing protease inhibitor cocktail (cOmplete Tablets, EDTA-free, Roche) and centrifuged at 14000 rpm for 30 min at 4ºC. Supernatant was filtered and N-glycosylated proteins isolated by affinity chromatography using Concavaline A columns (HiTrap Con A 4B, GE Healthcare) in AKTA FPLC (GE Healthcare), and eluted with a buffer containing 20 mM Tris-HCl, 0.5 M NaCl and 0.5 M methyl-α-O-glucopyranoside (pH 7.4).
For differential analysis of secreted O- or N-glycoproteins in Δpmt4 or Δgls1 mutants, FB1Biz1crg and FB1Biz1crgΔpmt4 or FB1Biz1crgΔgls1 cells were grown in 1 L of CMD to an OD600 = 0.5–0.8, washed twice with sterile bidistilled water and grown for 8 hours in 1 L of CMA. After filamentation induction, cells were centrifuged, the supernatant filtered and secreted glycosylated proteins precipitated with deoxycholate acid and TCA.
Cell wall O- or N-glycoproteins in Δpmt4 or Δgls1 mutants were purified following the protocol described in [78], with some modifications. FB1Biz1crg and FB1Biz1crgΔpmt4 or FB1Biz1crgΔgls1 cells were grown in 1 L of CMD to an OD600 = 0.5–0.8, washed twice with sterile bidistilled water and grown for 8 hours in 1 L of CMA. After filamentation induction, samples were harvested by centrifugation, washed four times in ice-cold 10 mM Tris-HCl buffer (pH 7.4) and frozen at −80ºC. Cells were then resuspended in 10 mM Tris-HCl buffer (pH 7.4) containing protease inhibitor cocktail (cOmplete Tablets, EDTA-free, Roche) after which cell lysis was performed with glass beads (Sigma) in a FastPrep-24 homogeniser (MP Biomedicals), with power set to 6.5 using 6 x 60” pulses at maximum speed with 3 minutes rest between cycles. Samples were recovered by centrifugation at 3000 x g for 10 min at 4ºC, after drilling the bottom of the tube with a needle and placing into a new tube. The pellet (cell wall) was collected and washed sequentially with ice-cold sterile bidistilled water, 5% NaCl with protease inhibitor, 2% NaCl with protease inhibitor and 1% NaCl with protease inhibitor. Washing steps were repeated three more times and cell wall proteins (CWPs) purified after 10 min at 100ºC in extraction buffer (50 mM Tris-HCl pH 8.0, 100 mM EDTA, 2% SDS, 10 mM DTT) followed by 15 min centrifugation at 35000 x g. CWPs were then collected from the supernatant.
To analyze the common target between Gls1 and Pdi1, secreted proteins from FB1Biz1crg and FB1Biz1crgΔgls1 or FB1Biz1crgΔpdi1 were precipitated with deoxycholate acid and trichloroacetic acid (TCA) following the protocol described above for secreted O- and N-glycoproteins.
Isolated proteins for each fraction and genotype were then precipitated with 2D Clean-Up kit (GE Healthcare), and dissolved in TS buffer (7M urea, 2M thiourea, and 4% CHAPS) containing 30 mM Tris-HCl (pH 9.5). Protein concentration was determined using RC DC Protein Assay (Bio-Rad).
Fifty micrograms of protein extract from each sample were labeled with Cy3- or Cy5 Dye (GE Healthcare). Labeling was performed reciprocally so that each sample was separately labeled with Cy3 and Cy5 to account for any preferential protein labeling by the CyDyes. Twenty-five micrograms of each sample were labeled with Cy2-Dye and pooled together as an internal standard. Labeling was performed according to the manufacturer’s instructions. Different Isoelectric Focusing (IEF) procedures were performed. For cytosolic O-glycoproteins and CWPs, IEF was performed in 24 cm 4–7 NL Immobiline DryStrip (GE Healthcare) in an IPGphor unit (GE Healthcare) at 20ºC as follows: rehydratation for 12 h, 500 V for 1 h, linear gradient from 500 to 1000 V for 1 h, linear gradient from 1000 to 8000 V for 3 h and 8000 V to 60000 total Vhr for 5.5 h. The same IEF procedure using 24 cm 3–10 NL DryStrips was performed for secreted proteins. For cytosolic N-glycoproteins, IEF was performed using 24 cm 3–7 NL Immobiline DryStrip (GE Healthcare) in an IPGphor unit (GE Healthcare) at 20ºC as follows: rehydration for 12 h, 500 V for 1.5 h, linear gradient from 500 to 1000 V for 7 h, linear gradient from 1000 to 8000 V for 8 h and 8000 V to 60000 total Vhr for 5.5 h. After IEF, strips were incubated for 15 min at room temperature in a shaker in equilibration buffer (50 mM Tris-HCl [pH 8.5], glycerol 30% v/v, 6M urea, 2% w/v SDS) with 10 mg/mL DTT, followed by another 15 min incubation in equilibration buffer with 25 mg/mL iodoacetamide and loaded onto 10% acrylamide gels. Second dimension separation was performed using an EttanDalt Six Electrophoresis Unit (GE Healthcare).
After electrophoresis, gels were imaged using a Typhoon-9400 scanner (GE Healthcare) with a 100 μm resolution using appropriate emission and excitation wavelengths, photomultiplier sensitivity and filters for each of the Cy2, Cy3, and Cy5 dyes.
Relative protein spot quantification across experimental conditions was performed automatically and in a blind manner using DeCyder v7.0 software and the multivariate statistical module EDA v7.0 (Extended Data Analysis, GE Healthcare) as follows. First, the Batch Processor module detected spots across the three gel images (two experimental samples and an internal standard) and generates differential in-gel analysis images with information about spot abundance in each image with values expressed as ratios. After spot detection, the biological variation analysis module utilizes differential in-gel analysis images to match protein spots across all gels, using the internal standard for gel-to-gel matching. Statistical analysis was then carried out to determine protein expression changes. To perform a restrictive analysis, we considered spot changes significant when associated with a p-value lower than 0.01. This value was chosen based on Student’s t-test with multiple testing assessed using the false discovery rate. Multivariate analysis was performed by principal component analysis using the algorithm included in the DeCyder EDA module based on spots matched across all gels.
Protein identification was performed at the Proteomics Unit of the Pablo de Olavide University (Seville, Spain) and at the Proteomics service of Parque Científico de Madrid (Madrid, Spain). Spots were excised from the gels manually and transferred to 1.5 mL tubes. Sample digestion and MALDI-MS and MS/MS database searches were done by the Proteomics Units mentioned above.
Western blot analyses
For Western Blot analyses, cells were grown in YEPSL to an OD600 = 0.6–0.8 and were then collected by centrifugation at 4500 rpm for 5 min, washed twice with 20 mM Tris-HCl pH 8.8 and pellets were resuspended in lysis buffer (20 mM Tris-HCl, 0.5 M NaCL, pH 7.4) with protease inhibitor cocktail (cOmplete Tablets, EDTA-free, Roche). Samples lysis was performed with glass beads (Sigma) in a FastPrep-24 homogeniser (MP Biomedicals), with power set to 6.5 using 6 x 60” pulses at maximum speed with 4 minutes rest between cycles. After cell lysis, tubes were drilled with a needle and put into a new tube and samples were recovered by centrifugation at 4000 rpm for 1 min. Subsequently, samples were centrifuged at 14000 rpm for 30 min at 4ºC and the supernatant was collected. Protein concentration was measured using the RC DC Protein Assay kit (Bio-Rad). 60 μg of protein extract for each strain analyzed was loaded into a 10% TGX Stain-Free FastCast Acrylamide gel (Bio-Rad). Separated proteins were transferred onto a nitrocellulose membrane using the Trans-Blot Turbo transfer system (Bio-Rad). The membrane was incubated with mouse polyclonal anti-GFP antibody (Roche) (1:1000). As secondary antibody, anti-mouse IgG-horseradish peroxidase conjugated antibody (1:5000; Sigma Aldrich) was used. Immunoreactive bands were developed by SuperSignal West Femto Maximum Sensitivity substrate (ThermoFisher Scientific). Image gel and membrane acquisition was carried out with ChemiDoc XRS (Bio-Rad).
Microscopy
To corroborate ER Pdi1 localization, experimental SG200pdi1:gfp and ER localization control SG200cals:mrfp:HDEL cells [79] were visualized using a spinning-disk confocal microscope (IX-81, Olympus; CoolSNAP HQ2 camera, Plan Apochromat 100×, 1.4 NA objective, Roper Scientific). To determine ER Pdi1ΔN-gly:GFP localization, SG200pdi1ΔN-gly:gfp and SG200pdi1:gfp cells were visualized using a DeltaVision microscopy system comprising an Olympus IX71 microscope and CoolSnap HQ camera.
For morphology visualization, cells were observed by Differential Interference Contrast (DIC) using a DeltaVision microscopy system comprising an Olympus IX71 microscope and CoolSnap HQ camera.
For in planta quantification of filament and appressoria formation in co-infection experiments with U. maydis GFP and RFP labeled strains, 20 dpi leaf samples were stained with calcofluor white (Sigma-Aldrich) to visualize fungal material and then checked for GFP or RFP fluorescence.
To analyze the U. maydis progression inside the maize plant, leaf samples from 3 and 5 dpi infected plants were distained with ethanol, treated 4h at 60ºC with 10% KOH, washed in phosphate buffer and then stained with propidium iodide (PI) to visualize plant tissues in red and wheat germ agglutinin (WGA)/AF488 to visualize the fungus in green. Samples were examined using a Leica SPE (DM2500) confocal microscope. Image processing was carried out using Adobe Photoshop CS5 and ImageJ.
Supporting information
S1 Fig [docx]
Script for O- and N-glycosylation site identification.
S2 Fig [a]
Individual infection assays of pathogenic pathway glycoprotein candidates.
S3 Fig [tif]
UMAG_10156 is similar to Pdi1.
S4 Fig [a]
Loss of has no effect on the non-pathogenic stage.
S5 Fig [1]
N-glycosylation mutation in Pdi1 does not affect cell wall integrity nor oxidative stress.
S6 Fig [tif]
Pdi1 allele expressed under the control of the otef promoter failed to complement the lack of Pdi1.
S1 Table [xlsx]
Identified glycoproteins in this study.
S2 Table [docx]
List of strains used in this study.
S3 Table [docx]
List of primers used in this study.
S4 Table [docx]
Mann-Whitney statistical test individually performed for each pathogenic assay in .
Zdroje
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