Proteomic profiling of the monothiol glutaredoxin Grx3 reveals its global role in the regulation of iron dependent processes
Authors:
Selma S. Alkafeef aff001; Shelley Lane aff001; Clinton Yu aff003; Tingting Zhou aff001; Norma V. Solis aff004; Scott G. Filler aff004; Lan Huang aff003; Haoping Liu aff001
Authors place of work:
Department of Biological Chemistry, University of California, Irvine, California, United States of America
aff001; Department of Biochemistry, Faculty of Medicine, Kuwait University, Kuwait City, Kuwait
aff002; Department of Physiology & Biophysics, University of California, Irvine, California, United States of America
aff003; Division of Infectious Diseases, Los Angeles Biomedical Research Institute at Harbor-UCLA Medical Center, Torrance, California, United States of America
aff004; David Geffen School of Medicine at UCLA, Los Angeles, California, United States of America
aff005
Published in the journal:
Proteomic profiling of the monothiol glutaredoxin Grx3 reveals its global role in the regulation of iron dependent processes. PLoS Genet 16(6): e32767. doi:10.1371/journal.pgen.1008881
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1008881
Summary
Iron is an essential nutrient required as a cofactor for many biological processes. As a fungal commensal-pathogen of humans, Candida albicans encounters a range of bioavailable iron levels in the human host and maintains homeostasis with a conserved regulatory circuit. How C. albicans senses and responds to iron availability is unknown. In model yeasts, regulation of the iron homeostasis circuit requires monothiol glutaredoxins (Grxs), but their functions beyond the regulatory circuit are unclear. Here, we show Grx3 is required for virulence and growth on low iron for C. albicans. To explore the global roles of Grx3, we applied a proteomic approach and performed in vivo cross-linked tandem affinity purification coupled with mass spectrometry. We identified a large number of Grx3 interacting proteins that function in diverse biological processes. This included Fra1 and Bol2/Fra2, which function with Grxs in intracellular iron trafficking in other organisms. Grx3 interacts with and regulates the activity of Sfu1 and Hap43, components of the C. albicans iron regulatory circuit. Unlike the regulatory circuit, which determines expression or repression of target genes in response to iron availability, Grx3 amplifies levels of gene expression or repression. Consistent with the proteomic data, the grx3 mutant is sensitive to heat shock, oxidative, nitrosative, and genotoxic stresses, and shows growth dependence on histidine, leucine, and tryptophan. We suggest Grx3 is a conserved global regulator of iron-dependent processes occurring within the cell.
Keywords:
Gene expression – Saccharomyces cerevisiae – Transcription factors – Homeostasis – Biosynthesis – Mouse models – Candida albicans – Transcriptional control
Introduction
Iron is an essential nutrient for almost all living organisms with critical roles in many biological processes including respiration, metabolism, and DNA synthesis and repair. While sufficient intracellular iron level is essential for life, excess intracellular iron can also be toxic as it can lead to the generation of reactive oxygen species (ROS) [1, 2]. For pathogens, bioavailable iron level is dictated by the host environment. Candida albicans, a commensal and pathogenic fungus of humans, is characterized by its ability to inhabit a variety of distinct host niches that encompasses a wide range of environmental iron bioavailability, including the bloodstream where most host iron is sequestered in the form of hemoglobin and transferrin, and the mammalian gastrointestinal tract, where iron levels are high as a result of dietary consumption [2]. Therefore, the ability to regulate iron acquisition and utilization in response to environmental iron levels is critical for C. albicans pathogenesis and survival.
To that end, C. albicans utilizes a conserved transcriptional regulatory circuit to maintain iron homeostasis. In iron-replete conditions, the conserved GATA family transcription factor Sfu1 directly represses iron uptake genes and the Cys6Zn2 transcription factor Sef1 [3–5]. Conversely, in low iron conditions, Sef1 activates the expression of iron uptake genes and the highly conserved CCAAT binding protein (CBP) transcription factor Hap43, which represses iron utilization genes and SFU1 [4, 6–8]. The roles of Sfu1 and Hap43 on the regulation of iron homeostasis are highly conserved across a broad range of fungi including S. pombe [9, 10], H. capsulatum [11, 12], and C. neoformans [13, 14]. However, how C. albicans senses iron availability to signal the iron regulatory circuit is unknown.
Monothiol glutaredoxins (Grxs) have been implicated in the regulation of iron homeostasis circuits in model yeasts. Grxs along with the functionally similar thioredoxins (Trxs) comprise a large family of thiol-disulfide oxidoreductases that regulate the redox state of cellular proteins from bacteria to mammals [15]. Grxs can be categorized as dithiol (Class I) or monothiol (Class II) [15]. Both mono- and dithiol Grxs utilize glutathione (GSH) and NADPH in redox reactions. Monothiol Grxs display little oxidoreductase activity in vitro [15, 16]. Instead, they play primary roles in the biogenesis and trafficking of Fe-S clusters [15, 17]. Mitochondrial monothiol Grxs are essential for early Fe-S cluster biogenesis that is necessary for the generation of all cellular Fe-S clusters [18]. Conversely, cytosolic monothiol Grxs are required for the trafficking and insertion of mature [2Fe-2S] clusters to client apoproteins [15, 17]. Loss of these proteins results in broad dysfunction in iron metabolism and increased cytosolic iron accumulation [17, 19]. In the model yeasts S. cerevisiae and S. pombe the cytosolic monothiol paralogs Grx3/4 along with their associated functional partner, the BolA-like protein Bol2/Fra2, are crucial for the iron-responsive regulation of their respective iron regulatory circuits [15, 19–24]. Grx3/4 functions in Fe-S trafficking by forming a heterodimer with the cytosolic BolA protein Bol2/Fra2, and they are thought to transfer the bound [2Fe-2S] cluster to downstream target proteins [15, 17, 19, 22]. Most studies have focused on Grxs regulation of the iron homeostasis circuit in model yeasts [24–28]. Whether these roles are conserved in C. albicans and what other proteins cytosolic monothiol Grxs regulate are yet to be determined.
Using a proteomic approach supported with mutational analysis, we identify a large number of Grx3 targets that function in diverse biological processes, most of which interact with Grx3 independently of iron status. Further analysis of Grx3 targets revealed Grx3 regulates the iron homeostasis circuit on multiple levels and is essential for full amplification of iron-regulated gene expression in response to iron level. This is the first such genome-wide proteomic approach to identify Grx3 targets. The broad range of Grx3 targets signifies the importance of Grx3 in a diverse array of biological processes that require Fe-S clusters to function.
Results
C. albicans grx3 mutant is sensitive to iron depletion
To identify the functional homolog of Grx3/4 in C. albicans, we compared the effects of oxidative and iron stresses on the growth of three grx mutants, the dithiol glutaredoxin mutant grx2 and the monothiol glutaredoxin mutants grx3 and grx5. We spotted cells onto YPD plates containing the iron chelator bathophenanthroline disulfonic acid (BPS) to simulate a reduced-iron environment. The grx3 mutant showed a strong sensitivity to low iron stress on BPS-containing plates (Fig 1A, top panel). In contrast, the grx2 and grx5 mutants showed no additional growth defect on BPS-containing plates in comparison to YPD. None of the mutants showed sensitivity to high iron stress in the form of excess FeCl3 The grx2 and grx5 mutant showed sensitivity to both 3mM and 5mM H2O2, while the grx3 mutant showed sensitivity to only 5mM H2O2 (Fig 1A, bottom panel). This is consistent with published data that Grx2 and Grx3 play roles in the oxidative stress response [29–31]. The grx5 mutant had a growth defect even on YPD without H2O2, consistent with the predicted mitochondrial localization and functions of Grx5. Therefore, of the C. albicans glutaredoxin mutants tested, only the grx3 mutant was sensitive to low iron level (Fig 1A).
Grx3 is required for C. albicans virulence in the murine host
Filamentation is a key contributing factor to C. albicans pathogenicity [32], therefore we tested if the grx3 mutant was defective in hyphal formation. The grx3 mutant behaved similarly to the wild-type strain, and was able to form robust filaments with nearly 100% of grx3 cells developing germ tubes by one hour after dilution into fresh YPD at 37°C (Fig 1B). This result suggests that intracellular iron levels do not directly influence hyphal induction.
To test the role of Grx3 in virulence in vivo, we utilized two murine models of candidiasis. In a disseminated model of candidiasis, mice infected with wild-type cells did not survive past day 12. In contrast, all mice infected with the grx3 mutant strain were still alive by day 21 (Fig 1C). The rescued grx3 mutant strain carrying a single copy of GRX3 driven by the TDH3 promoter was able to fully complement the grx3 mutant phenotype, and mice infected with the rescued strain all died by 9 (Fig 1C, S1 Fig). Therefore, the grx3 mutant shows attenuated virulence in a model of disseminated candidiasis. We also tested the pathogenicity of the grx3 mutant in the mouse model of oropharyngeal candidiasis (OPC). Mice infected with the grx3 mutant showed decreased oral fungal burden compared to those infected with the wild-type and GRX3 rescued strains (Fig 1D). Therefore, Grx3 is important for C. albicans pathogenicity in the murine host during both hematogenously disseminated and mucosal infection. How Grx3 contributes to virulence is unknown. To address this, we took a global proteomic approach to shed light on Grx3 functions.
Proteomic profiling of Grx3 interacting proteins identifies Grx interacting proteins in Fe-S assembly and delivery, the iron homeostasis regulon, and other processes
Grx3 is suggested to deliver Fe-S clusters to recipient proteins. Fe-S cluster trafficking and handoff are likely dynamic processes, consequently interactions between Grx3 and target proteins may be difficult to capture. Therefore we utilized in vivo cross-linked His-Biotin-His (HBH) tandem affinity purification, coupled with label-free quantitative mass spectrometry to identify Grx3 interacting proteins in living cells [33–36]. A functional pMAL2-driven Grx3-HBH fusion construct in the grx3 mutant strain (S2 Fig) was used for purifications. Any interacting proteins that appeared in the untagged control samples were excluded from analysis. To further reduce the incidence of false positives arising non-specifically from HBH purification, we also excluded any proteins that appeared in our previously published mass spectrometry datasets derived from HBH-purifications of the unrelated transcriptional regulators opaque-specific Wor1 and general co-repressor Tup1 [33]. We further reduced background noise by eliminating orthologs of S. cerevisiae proteins present in the CRAPome, a database of non-specific affinity purification contaminant proteins [37]. We identified 343 proteins present in at least 2 or more out of 4 Grx3-HBH purifications, 64 of which were identified in all 4 samples (S1 Table).
In order to assess the validity and sensitivity of our proteomic approach, we compiled a list of verified physical interactors of Grx3 homologs in S. cerevisiae and S. pombe (Fig 2A) based on the Saccharomyces Genome Database, Pombase, and BioGrid, [38–40]. We included proteins with two or more independent reports of interactions in S. cerevisiae, and only 10 proteins met the criteria from 27 high throughput physical interaction studies (BioGrid). Of the 10 validated proteins shown to physically interact with Grx3 homologs, we identified 9 C. albicans homologs in our Grx3 interaction data (Fig 2A, S1 Table). Therefore our proteomic approach is highly sensitive in capturing most of the known Grx3/4 interacting proteins. The observations of bona-fide Grx interacting proteins in our mass spectrometry data validate our proteomic method.
The most characterized of Grx3/4-interacting proteins are the Fe-S cluster binding BolA-like proteins Bol1 and Bol2/Fra2, the aminopeptidase P-like protein Fra1, and the iron homeostasis regulon proteins Aft1/2 (S. cerevisiae), Fep1, and Php4 (S. pombe) (Fig 2A) [15, 19, 24, 25, 27]. BolA-like proteins are integral to Fe-S cluster biogenesis and trafficking; Bol2/Fra2, and to a lesser extent Fra1, play crucial roles in Grx-mediated regulation of iron homeostasis circuits [15, 24]. Our observation that Grx3 interacts with the C. albicans homologs of these well-characterized BolA proteins suggests that C. albicans Grx3 likely retains similar functions as an iron trafficker as those described. Our proteomic approach also identified Hap43 and Sfu1, transcription factors in the C. albicans iron homeostasis circuit (Fig 2A) [3, 4, 7]. The identification of these Grx3 targets from our proteomic approach support the conserved role of Grx3 in the regulation of Fe-S cluster biogenesis, trafficking, and iron homeostasis in C. albicans [19, 22, 42, 43].
We performed Gene Ontology (GO) analysis to identify enriched functional categories of Grx3-associated proteins [44–46]. We found enrichment of proteins involved in a range of cellular processes including oxidation-reduction, metabolism, and amino acid biosynthetic processes (Fig 2B, S2A Table). Pathway analysis showed enrichment in flavin, histidine, tyrosine, and asparagine and aspartate biosynthetic processes (Fig 2C, S2B Table). Taken together, GO analysis of our Grx3-associated proteins is consistent with the known role of Grx3 in maintaining cellular redox homeostasis (Fig 1A) [31] and suggests a broader role for Grx3 in the regulation of multiple biological processes that are dependent on Fe-S clusters. To the best of our knowledge, this is the first such proteomic approach undertaken to identify a comprehensive listing of Grx-associated proteins in vivo.
Grx3 regulates the C. albicans iron homeostasis circuit and amplifies iron-responsiveness of gene expression
C. albicans maintains iron homeostasis by utilizing a transcriptional regulatory circuit comprised of the transcription factors Sfu1, Sef1, and Hap43 (Fig 3A) [4]. The mechanisms by which the C. albicans iron regulatory circuit is able to sense iron level are unknown, although in model yeasts monothiol glutaredoxins have been shown to functionally regulate iron homeostasis regulons in response to iron level (Fig 3A) [15, 19, 25, 28]. In S. cerevisiae, Grx3 homologs Grx3/4 regulate the localization and activity of the transcriptional activators Aft1/2 [20, 21, 23]. In S. pombe, the Grx3 homolog Grx4 directly interacts with Fep1, an Sfu1 homolog, in both iron replete and iron limited conditions to regulate Fep1 occupancy at target promoters [24, 27, 28]. Further, Grx4 regulates the activity of Hap43 homolog Php4 through a mechanism of nucleo-cytoplasmic shuttling in response to iron level [25, 26, 47]. Sfu1 and Hap43 both co-purified with Grx3 in our mass spectrometry data suggesting that Grx3 may similarly regulate Sfu1 and Hap43 activity. In wild-type cells, SFU1 is expressed in YPD but down regulated during iron limitation in BPS; conversely, expression of SEF1 and HAP43 is high during iron limitation and low in YPD (Fig 3B) [4]. In the grx3 mutant, expression levels of SFU1, SEF1, and HAP43 were relatively unchanged between YPD and BPS treatment. This suggests that the iron homeostasis regulatory circuit is no longer responsive to change in iron level in the absence of Grx3 (Fig 3B). Our data for the first time links Grx3 with iron-responsive transcriptional regulators in C. albicans.
Grx3 interacts with Sfu1 and is necessary for Sfu1 to associate with target promoters
To determine if Grx3 binds Sfu1 in C. albicans, we constructed a strain carrying Grx3-FLAG and MAL2-driven Sfu1-Myc. Immunoprecipitation of Grx3-FLAG confirmed that Grx3 and Sfu1 interact in vivo, both in YPM and BPS-containing media (Fig 3C). Therefore, Grx3 and Sfu1 interact independently of iron level. As Sfu1 binds target promoters to repress gene expression in iron replete conditions [4], we performed chromatin immunoprecipitation (ChIP) of maltose-induced Sfu1-Myc in wild-type and grx3 mutant cells and assessed Sfu1 binding at the promoter of RBT5, a GPI-linked cell wall protein involved in hemoglobin utilization [48]. Sfu1 occupancy at the RBT5 promoter was dependent on iron level (Fig 3D), consistent with previous observations [4]. In the grx3 mutant, the levels of promoter bound Sfu1 were similar in high and low iron conditions: lower than wild-type in iron replete conditions but higher than wild-type in iron limiting conditions (Fig 3D). This result indicates that Grx3 regulates iron-responsive binding of Sfu1 to the RBT5 promoter. RBT5 expression levels correlated with Sfu1 binding (Fig 3E). RBT5 transcription was highly induced in BPS in the wild-type cells, but the fold induction in response to iron depletion was much lower in the grx3 mutant (Fig 3E). Thus, loss of Grx3 corresponded to decreased amplitude of iron-responsiveness of gene expression. However, RBT5 still exhibited differential gene expression between high and low iron conditions (Fig 3E), suggesting the presence of Grx3-independent factors involved in the regulation of RBT5 expression.
Grx3 represses Hap43 activity by promoting cytoplasmic localization
We next assessed the role of Grx3 on Hap43 activity. Work in S. pombe has shown that the Grx3 homolog, Grx4, regulates the activity of Php4, a Hap43 homolog, by modulating Php4 localization in response to iron level [25, 26, 47]. To test if this regulation was conserved in C. albicans, we constructed a GFP-Hap43 fusion protein under the control of the MAL2 promoter and transformed it into the hap43 and grx3 mutant strains. The construct was able to complement the hap43 mutant phenotype on low concentrations of BPS (S3 Fig). When cultured in BPS-containing medium (low iron), GFP-Hap43 localized primarily to the nucleus (Fig 3G). Conversely, under iron replete conditions (SCM), GFP-Hap43 showed an increased cytosolic presence and was no longer enriched in the nucleus (Fig 3G). This iron-responsive change in GFP-Hap43 nuclear and cytoplasmic localization is at least partially dependent on Grx3, as grx3 cells displayed nuclear localization of GFP-Hap43 in both high and low iron conditions (Fig 3G). Therefore, we suggest that Grx3 likely represses Hap43 activity by promoting Hap43 localization to the cytosol under iron replete conditions.
Expression of the Hap43 target gene CCP1, an iron utilization gene, was measured under iron replete and iron limited conditions (Fig 3F). Of the three iron circuit regulators, only Hap43 binds to the CCP1 promoter, where it functions to repress CCP1 expression in low iron conditions, making CCP1 an ideal gene to assay Hap43 activity [4]. In wild-type cells, CCP1 was expressed in YPD but repressed by 819-fold in BPS-containing medium (Fig 3F). CCP1 expression was lower in the grx3 mutant in YPD compared to the wild-type strain (Fig 3F), suggesting increased Hap43 activity as a transcriptional repressor in the absence of Grx3. Furthermore, the fold repression of CCP1 in response to low iron in the grx3 mutant was only 18 fold, which is 45-fold lower than in wild-type cells. In contrast to deleting GRX3, deleting SFU1 only slightly reduced the fold repression of CCP1. Our data suggests that Grx3 represses Hap43 activity and plays a critical role in CCP1 repression in response to iron level. This is consistent with work in that has shown Php4 activity and localization are directly regulated by Grx4 in response to iron level [25, 26, 47]. These findings support our previous observations that Grx3 controls iron homeostasis by regulating the amplitude of iron-responsive gene expression (Fig 3B and 3E).
Grx3 contributes to the histidine, tryptophan, and leucine biosynthesis pathways
GO analysis of the Grx3 mass spectrometry data showed enrichment for general amino acid biosynthetic processes (Fig 2B) with specific enrichment for tyrosine, asparagine, aspartate, and histidine biosynthesis pathways (Fig 2C). Therefore we systematically tested which amino acids the grx3 mutant might require for optimal growth. The grx3 mutant displayed a growth defect on SCD plates lacking histidine, leucine, and a slight growth sensitivity to tryptophan deprivation (Fig 4A). We did not observe a growth defect on SCD media lacking any other amino acids. The grx3 mutant grew slower than WT on minimal media (YNB), and YNB supplemented with histidine, tryptophan, and leucine was sufficient to restore grx3 growth (Fig 4B). This function of Grx3 was independent of the iron homeostasis transcriptional circuit, as the iron circuit mutants sfu1, sef1, and hap43 were not sensitive to histidine, leucine, or tryptophan deprivation (Fig 4A and 4B). Further, the wild-type strain was not defective on BPS-treated SCD plates lacking histidine, tryptophan, or leucine, suggesting the growth dependency of the grx3 mutant on these amino acids is due to the role of Grx3 in regulating the activities of these pathways (Fig 4C).
This is the first report that Grx3 plays important roles in histidine, leucine, and tryptophan biosynthesis. Interestingly, in S. cerevisiae, the leucine biosynthesis pathway is regulated in response to iron level through both transcriptional and post-transcriptional regulation of the Fe-S cluster-containing enzyme Leu1, suggesting that it controls the key regulated step of leucine biosynthesis [49]. In C. albicans, LEU1 expression is upregulated 8-fold under iron-replete conditions [4]. Our findings describe a transcription-independent role for Grx3 in regulating iron-dependent metabolic and biosynthetic processes and support a novel function of Grx3 in amino acid biosynthesis pathways as identified by our proteomic approach.
Grx3 contributes to cellular stress responses
We next sought to experimentally assess and validate the roles of Grx3 in different processes enriched by GO analysis of our mass spectrometry data (Fig 2C, S2 Table). Fe-S cluster biogenesis has previously been implicated in DNA replication and repair pathways [50]. Defects in mitochondrial or cytosolic Fe-S cluster biogenesis result in genomic instability [51, 52]. Our mass spectrometry dataset included proteins involved in both Fe-S cluster biogenesis and DNA damage response such as Dre2 [53], Met18 (S. cerevisiae Mms19) [52, 54], Rad6 [55], and Rad51 [56]. To assess the role of Grx3 in genomic maintenance and the DNA damage response, we spotted cells onto YPD plates containing the genotoxic stress methyl methanesulfonate (MMS) and assayed for sensitivity (Fig 5A). The grx3 mutant was sensitive to MMS, but sef1, hap43, and sfu1 showed no growth defect in response to MMS treatment, indicating that the observed sensitivity of the grx3 mutant to genotoxic stress is not due to dysfunction of the iron regulatory circuit (Fig 5A). As a control, the grx3 mutant and iron homeostasis circuit mutants sef1 and hap43 were all unable to grow on BPS-treated plates. Therefore the role of Grx3 in maintaining genomic integrity is independent of its function in the regulation of the iron homeostasis circuit and likely occurs through its role in Fe-S cluster trafficking.
Having previously found the grx3 mutant sensitive to oxidative stress (Fig 1A) and having observed GO enrichment in oxidation-reduction processes (Fig 2B), we tested what other types of cellular stresses Grx3 may play a role in responding to. We found the grx3 mutant, but not the iron regulatory circuit mutants sef1, hap43, and sfu1, was sensitive to nitrosative stress (Fig 5B) and growth at 42°C (Fig 5C). This suggests that Grx3 contributes to the regulation of multiple stress response pathways in C. albicans. Beyond oxidation-reduction processes, we did not observe enrichment for GO categories relating to other general cellular stress response or heat shock processes (Fig 2). This is perhaps due to our stringent removal of common affinity purification contaminants from our Grx3 interaction dataset, which typically include HSP chaperones. Therefore our proteomic approach unveiled new functions for Grx3 in the regulation of cellular stress response processes independent of its role in the iron homeostasis transcriptional circuit.
Discussion
Here we show that the C. albicans cytosolic monothiol glutaredoxin Grx3 is essential for the regulation of not only the iron homeostasis circuit, but an array of Fe-S cluster-dependent processes occurring within the cell (Fig 6). In vivo cross-linked purification of Grx3 coupled with mass spectrometry enriched for interacting proteins involved in a variety of important processes including Fe-S cluster biogenesis and trafficking, iron homeostasis, redox homeostasis, metabolism, amino acid biosynthesis, and DNA maintenance and repair. The dependence of these processes on iron or Fe-S cofactors, the known function of Grxs in Fe-S cluster biogenesis and trafficking, and the fact that Grx3/4 deficiency in S. cerevisiae functionally impairs all iron-requiring processes [17] lead us to conclude that C. albicans Grx3 is a global regulator of iron responses that controls a multitude of Fe-S cluster-dependent pathways and processes (Fig 6).
One critical gap in our knowledge of how Grxs function within the cell is the lack of a global and comprehensive understanding of Grx targets. Most work, performed in model yeasts, focused either on how monothiol Grxs regulate iron homeostasis transcription factors in response to iron level or how Grxs physically interact with their BolA-like protein complex partners in Fe-S cluster trafficking. Beyond a small pool of identified Fe-S acceptors, very few Grx downstream targets are known. Our proteomic approach provides an unbiased global look at the full scope of Grx3 downstream targets and pathways Grx3 may regulate. The incorporation of in vivo cross-linking was key to capturing weak or dynamic interactions and provided us an extensive view of the Grx3 interactome. One drawback to this method is the high level of false positives that may arise due to non-specific affinity purification as well as increasingly sensitive instrumentation. To overcome these limitations we utilized multiple rounds of elimination using publicly available affinity purification contaminant repositories (the CRAPome) and our own previous unrelated affinity purifications [33, 37]. While stringent and possibly removing bona fide Grx3 interacting proteins (false negatives), we believe this approach lends confidence that the majority of our identified Grx3 interacting proteins represent legitimate interactions.
We identified Sfu1 and Hap43 as Grx3 interacting proteins and show that Grx3 is required for the iron-responsive regulation of the C. albicans iron homeostasis circuit, as loss of grx3 results in the insensitivity of transcriptional outputs to iron level. Grx3 interacts with Sfu1 and controls Sfu1 occupancy at its target promoters, consistent with the finding in S. pombe that Grx4 controls promoter association of the Sfu1 homolog Fep1 [27]. In addition, Grx3 regulates Hap43 activity and localization in response to iron level. This is similar to S. pombe where Grx4 is responsible for the nucleo-cytoplasmic shuttling of the Hap43 homolog Php4 in response to iron level [25, 26, 47]. We observed Grx3 interacts with Hap43 in both iron replete and limited conditions (S1 Table), consistent with work in S. pombe that has shown Grx4 interacts constitutively with Php4 through its TRX domain but in an Fe-S cluster-dependent manner through interactions with its GRX domain [25, 26, 47]. Our work suggests this Grx3-mediated regulation of Hap43 activity is likely conserved in C. albicans. Interestingly, in the grx3 mutant, the fold induction of downstream genes RBT5 and CCP1 in response to iron level was greatly reduced compared to wild-type (Fig 3E and 3F). While the transcriptional circuit of Sfu1, Sef1, and Hap43 toggles between the high and low iron response by controlling gene expression, Grx3 contributes to their regulation and amplifies the iron response. Therefore, Grx3 regulation of multiple transcriptional regulators of the iron homeostasis circuit increases the sensitivity of gene expression to iron level.
Although the iron homeostasis circuit has evolved to use different transcription factors in fungi, their regulation by Grx3 seems to be conserved. In S. cerevisiae, under iron replete conditions the Fe-S cluster-bridged Grx3/4-Bol2/Fra2 complex promotes the DNA dissociation and nuclear export of the transcription factors Aft1/2, thereby blocking Aft1/2-mediated induction of iron uptake genes [20, 21, 23, 57]. C. albicans Grx3 was recently implicated in regulating the nuclear localization of an Aft2-like protein [31], although Aft2 is not part of the iron regulatory circuit [5]. C. albicans has evolved to use Sef1 in addition to Sfu1 and Hap43 to control iron-responsive transcription [4]. Candida glabrata displays a hybrid system incorporating both Aft1 and Sef1 factors in the regulation of iron homeostasis [58]. The C. glabrata Grx3 homolog Grx4 likely plays a similar role in controlling iron-responsive transcription. Our study in C. albicans extends the previous findings from model organisms, linking cytosolic monothiol glutaredoxins to the regulation of their respective iron homeostasis transcriptional circuits in pathogenic fungi. Recently, a Grx3 homolog in another pathogenic fungus, Cryptococcus neoformans, was identified and characterized [59]. Using a transcriptomic approach, C. neoformans Grx4 was found to regulate iron homeostasis, virulence, metabolism, and cellular stress response, consistent with our proteomic findings presented here and work performed in other model organisms.
Bol2/Fra2 (orf19.7489.3) and Bol1 (orf19.5016) are both identified in our mass spectrometry data (S1 Table). Cytosolic Grx3/4-Bol2/Fra2 heterodimers have been shown to function as Fe-S cluster chaperones that facilitate Fe-S incorporation into apoproteins in the cytosol from yeast to mammalian cells [19, 24, 42]. It is likely C. albicans also uses the Grx3-Bol2/Fra2 complex as an Fe-S cluster chaperone for [2Fe-2S] trafficking to target proteins. While Bol2/Fra2 displays cytosolic localization, Bol1 and Bol3 occupy the mitochondria where they function in late stage iron-sulfur cluster (ISC) assembly and participate in the biogenesis of [4Fe-4S] clusters [60]. It is proposed that Grx3/4 functions downstream of the mitochondrial ISC and is a cytosolic recipient of [2Fe-2S] clusters generated from this pathway [15]. Although widely known for its role as a cytosolic or nuclear protein, Grx3/4 has also been shown to display mitochondrial localization [19, 60]. What role mitochondrial-associated Grx3 may play is unknown, but our data suggests it might involve the mitochondrial Bol1 in this function.
How does Grx3 sense cellular iron level and regulate the activity of so many different client proteins? It has been demonstrated in model organisms that the conserved cytosolic monothiol glutaredoxins are essential for inserting Fe-S clusters into target proteins [17, 24]. Cells without functional Grx3/4 accumulate iron but are unable to use it [17]. The Fe-S center of Grx3/4 is critical for both iron delivery and signaling [17, 24]. Substituting the active site cysteine with serine or alanine in the GRX domain of Grx3/4 blocks the ability of Grx3/4 to sense and deliver iron to its client proteins [17]. In addition, the Fe-S cluster binding sites of client proteins are also essential for their function [24]. Therefore, we speculate that glutaredoxins and BolA-like proteins govern client protein activity in response to iron level by regulating the Fe-S cluster status of the client protein. Our work suggests a broad role for Grx3 in overall iron regulation of an assortment of biological processes and pathways. Due to the ubiquitous nature of Grxs across all kingdoms of life, the functional relationships between monothiol Grxs and the biological processes described in this study should show broad conservation throughout the living world.
Materials and methods
Growth media and culturing conditions
Strains were grown at 30°C in either YEP (1% yeast extract, 2% peptone), synthetic complete (SC) medium (0.17% Difco yeast nitrogen base w/o ammonium sulfate, 0.5% ammonium sulfate, complete supplement amino acid mixture), or YNB medium (0.17% Difco yeast nitrogen base w/o ammonium sulfate, 0.5% ammonium sulfate) plus 2% either dextrose or maltose as indicated. Iron depletion was induced by growth in media containing 100μM, 300μM, or 500μM bathophenanthroline disulfonic acid (BPS), as indicated. High iron stress was induced through addition of 100μM FeCl3. All HBH purification cultures were grown in media supplemented with 4μM biotin.
Plasmid and strain construction
All strains used in this study are presented in S3 Table. All primers used are presented in S4 Table.
grx2, grx3, and grx5 strains
Strains were taken from the GRACE library and loss of the tetracycline transactivator was selected for by growth on 5-FOA plates [61].
pMAL2-SFU1-13xMYC
SFU1 was amplified by primers 1 and 2. The resulting amplicon was inserted by Gibson assembly into an XbaI and PacI digested BES119 vector backbone [62] resulting in p1248. The resulting plasmid was digested with AscI for insertion into the ADE2 locus and transformed into the CaSS1 wild-type strain resulting in HLY4498 or into the grx3 mutant strain (HLY4492) resulting in HLY4507.
pGRX3-GRX3-FLAG
The GRX3 coding sequence and promoter were amplified using primers 3 and 4. The FLAG sequence was amplified from the pMAL2-WOR1-FLAG plasmid (p1142) [33] using primers 5 and 6. The final pGRX3-GRX3-FLAG plasmid (p1252) was inserted by Gibson assembly into a PstI and KpnI digested pWOR1-GFP plasmid (p1029) carrying the NAT resistance gene. The resulting plasmid was digested with HindIII for insertion into the pGRX3 locus of HLY4498, yielding HLY4500.
pMAL2-GRX3-HBH
GRX3 was amplified using primers 7 and 8. The GRX3 amplicon were inserted by Gibson assembly into an XbaI and MluI digested pMAL2-WOR1-HBH plasmid (p1251) [33]. The resulting plasmid was digested with AscI for insertion into the ADE2 locus and transformed into the grx3 mutant (HLY4492), generating the strain HLY4559.
pMAL2-GFP-HAP43
HAP43 was amplified with primers 15 and 16 and inserted by Gibson assembly into an MluI and KpnI digested pMAL2-GFP-CPH2 plasmid (p1028) [63]. The resulting plasmid was digested with AscI for integration into the ADE2 locus and transformed into hap43 and grx3, yielding HLY4569 and HLY4570, respectively.
WT, Ura+ His+ strain
An empty BES116 plasmid [62] was digested with AscI and integrated into the ADE2 locus of the wild-type strain (HLY4494). Subsequently, the HIS3 gene along with flanking upstream and downstream regions was amplified using primers 9 and 10 and transformed into the His+ wild-type strain resulting in HLY4568.
grx3 Ura+ strain
An empty BES116 vector was linearized with AscI and integrated into the ADE2 locus of the grx3 strain (HLY4492), yielding HLY4565.
pTDH3-GRX3
933bp of the TDH3 promoter was amplified and fused to the GRX3 coding sequence using primers 11–14. The resulting PCR fusion was inserted by Gibson assembly into a NotI and KpnI digested pMAL2-WOR1-HBH (p1251) plasmid. The resulting plasmid was linearized with AscI and integrated into the ADE2 locus of grx3 (HLY4492) yielding the strain HLY4566.
Spot testing
Overnight cultures of the indicated strains were washed three times with H2O and diluted to an OD600 of 1.0. Strains were then serially diluted 10-fold, and 2.5–5μL was spotted onto plates of the indicated media. Plates were grown for 2–3 days at 30°C. For low iron stress, strains were spotted onto YPD plates containing 300μM or 500μM bathophenanthroline disulfonic acid (BPS) as indicated. For high iron stress, strains were spotted onto YPD plates with 100μM FeCl3. For oxidative stress, cells were treated to 3mM or 5mM H2O2. Genotoxic stress was induced through treatment with 0.02% methyl methanesulfonate (MMS), and nitrosative stress induced with 5mM dipropylenetriamine (DPTA) NONOate. SC spot plates were supplemented with all amino acids unless indicated otherwise. YNB spot plates were supplemented with arginine due to auxotrophic requirements of the sef1, hap43, and sfu1 mutants [64].
Quantitative PCR
RNA samples were prepared using the Quick-RNA Miniprep Kit from Zymo Research. cDNA was synthesized using the iScript Reverse Transcription Kit (Bio-Rad) and qPCR was performed using iQ SYBR Green Supermix (Bio-Rad). Primers used for qPCR are listed in S3 Table.
Immunoprecipitation
Cultures were grown overnight at 30°C in YPM then diluted into fresh YPM in the presence or absence of 500μM BPS. Cultures were grown for another 6hr then harvested, washed twice with ice cold H2O, and lysed. Lysates were clarified, input sample was saved, and the lysates were incubated at 4°C with 50μL anti-FLAG M2 affinity gel (Sigma) for 2hr, washed five times with lysis buffer, and eluted in TE buffer with 1% SDS. Samples were resolved by SDS-PAGE and analyzed by western blot.
Western blotting
Samples were resolved on 10% SDS-PAGE gels, transferred onto nitrocellulose membranes, blocked, and probed for the proteins of interest. FLAG-tagged proteins were detected with mouse monoclonal anti-FLAG M2 (Sigma), MYC-tagged proteins were detected with HRP-conjugated anti-MYC antibody (Roche), and PSTAIRE (Cdc28) was detected using a rabbit polyclonal antibody (Santa Cruz). All non-HRP conjugated antibodies were detected by either goat anti-mouse or goat anti-rabbit HRP-conjugated secondary antibodies (Bio-Rad).
Chromatin Immunoprecipitation
ChIP was performed as described, with slight modifications [65]. Strains were cultured overnight in YPM at 30°C then diluted into fresh YPM with or without 500μM BPS and grown for 6hr. Samples were then fixed with 1% formaldehyde for 15 min, quenched with 125mM glycine for 5 min, and washed twice with ice cold PBS. DNA was sheared by sonication for 10 cycles of 20s at 40s intervals using a Bioruptor (Diagenode) and 1% input samples were saved. Sfu1-FLAG was immunoprecipitated using anti-FLAG M2 affinity gel (Sigma). DNA from input and IP samples was quantified by qPCR. Enrichment of tagged samples was quantified by the percent input method comparing the region of interest over the control region ADE2 and further normalizing to an untagged strain, with values representing at least three independent experiments and error bars representing the SEM. Primers used are listed in S3 Table.
Microscopy
For pMAL2-GFP-HAP43 visualization, cells were grown in SCM with or without 300μM BPS and imaged. Cells were stained with DAPI (4’, 6-diamidino-2-phenylindole) for nuclear localization. Images were taken using an inverted Zeiss Axio Observer.Z1 microscope (Carl Zeiss MicroImaging) equipped with an X-Cite series 120 mercury lamp. DAPI, GFP fluorescence, and cell morphology were imaged using the DAPI, GFP, and DIC channels, respectively.
HBH purification for mass spectrometry
Protein purification was performed as described by Alkafeef et al., with modifications [33]. Cultures of a grx3 strain carrying pMAL2-GRX3-HBH and an untagged control strain were grown in YPM overnight then diluted into fresh YPM with or without 500μM BPS, grown for 6hr or 16hr as indicated, cross-linked in 1% formaldehyde for 10 min, quenched with 125mM glycine for 5 min, then centrifuged, washed twice with H2O, and either flash frozen and stored at -80°C or lysed with Buffer A (8M urea, 300mM NaCl, 0.5% NP-40, 50mM sodium phosphate pH 8, 50mM Tris pH 8, 20mM imidazole, 1mM PMSF, 1 Roche Complete EDTA-free protease inhibitor tablet). All other steps were performed as previously described.
Mass spectrometry and data analysis
LC-MS/MS analysis was carried out using an UltiMate 3000 UHPLC (Thermo Fisher Scientific) coupled on-line to an Orbitrap Fusion Lumos Tribrid mass spectrometer (Thermo Fisher Scientific). Each duty cycle comprises an FT scan mass spectrum (m/z 375–1500, resolution of 120,000 at m/z 400) followed by data-dependent MS/MS spectra at top speed for 3 s. Raw data for both analyses were searched against a database consisting of Candida proteins (PA.orf_trans_all_assembly_21_2009_0306_v2 with a total of 6243 protein entries) using MaxQUANT. The mass tolerance for parent ions and fragment ions were set as ± 20 ppm and 0.5 Da, respectively. Trypsin was set as the enzyme, and a maximum of two missed cleavages were allowed. Protein N-terminal acetylation and methionine oxidation were selected as variable modifications. Protein and PSM FDR was set as 0.01. LFQ protein quantitation was calculated using a minimum ratio count of 2 peptides [66, 67]. All raw data was deposited and can be accessed at ftp://MSV000084168@massive.ucsd.edu with Firefox (username, if prompted: MSV000084168; password: GRX3BPS2019).
Gene Ontology analysis
Proteins observed in 2 or more out of 4 purifications were subject to Gene Ontology analysis using both the Candida Genome Database (CGD) GO Slim tool and PANTHER Pathway [41, 46, 68]. Results with a FDR P value < 0.05 were excluded. A full table of all enriched GO terms is presented in S2 Table.
Hyphal initiation
Cells were grown overnight at 30°C in YPD media then diluted 1:100 into fresh pre-warmed YPD and grown at 37°C for 1hr. Cells morphology was then assessed by microscopy.
Virulence testing
The virulence of the grx3 mutant in mouse models of hematogenously disseminated candidiasis and OPC was determined as previously described (PMID: 21085601; 25693184;11600377; 22402633). Briefly, hematogenously disseminated candidiasis was induced by inoculating 5 male Balb/c mice per strain with 5 x 105 organisms via the lateral tail vein. The mice were monitored 3 times daily for survival and moribund mice were humanely euthanized. For the OPC model, each C. albicans strain was tested in 7 mice. Each mouse was immunosuppressed with cortisone acetate, anesthetized, and then inoculated by placing a swab saturated with 106 C. albicans cells per ml under the tongue for 75 min. After 5 days of infection, the mice were sacrificed and their tongues were harvested, weighed, homogenized, and quantitatively cultured.
Supporting information
S1 Table [xlsx]
Grx3 interacting proteins identified by mass spectrometry.
S2 Table [a]
GO analysis of Grx3 interacting proteins.
S3 Table [xlsx]
Strains used in this study.
S4 Table [xlsx]
Primers used in this study.
S1 Fig [tiff]
rescues the phenotype.
S2 Fig [tiff]
The Grx3-HBH tag is functional.
S3 Fig [tiff]
The GFP-Hap43 fusion protein is functional at low concentrations of BPS.
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