Coordinate genomic association of transcription factors controlled by an imported quorum sensing peptide in Cryptococcus neoformans
Authors:
Diana K. Summers aff001; Daniela S. Perry aff001; Beiduo Rao aff001; Hiten D. Madhani aff001
Authors place of work:
Department of Biochemistry and Biophysics, University of California, San Francisco, CA, United States of America
aff001; Chan-Zuckerberg Biohub, San Francisco, CA, United States of America
aff002
Published in the journal:
Coordinate genomic association of transcription factors controlled by an imported quorum sensing peptide in Cryptococcus neoformans. PLoS Genet 16(9): e32767. doi:10.1371/journal.pgen.1008744
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1008744
Summary
Qsp1 is a secreted quorum sensing peptide required for virulence of the fungal meningitis pathogen Cryptococcus neoformans. Qsp1 functions to control cell wall integrity in vegetatively growing cells and also functions in mating. Rather than acting on a cell surface receptor, Qsp1 is imported to act intracellularly via the predicted oligopeptide transporter Opt1. Here, we identify a transcription factor network as a target of Qsp1. Using whole-genome chromatin immunoprecipitation, we find Qsp1 controls the genomic associations of three transcription factors to genes whose outputs are regulated by Qsp1. One of these transcription factors, Cqs2, is also required for the action of Qsp1 during mating, indicating that it might be a shared proximal target of Qsp1. Consistent with this hypothesis, deletion of CQS2 impacts the binding of other network transcription factors specifically to Qsp1-regulated genes. These genetic and genomic studies illuminate mechanisms by which an imported peptide acts to modulate eukaryotic gene expression.
Keywords:
Gene expression – Virulence factors – Transcription factors – Cell walls – DNA transcription – Cryptococcus neoformans – Transcriptional control – Quorum sensing
Introduction
The opportunistic basidiomycete yeast Cryptococcus neoformans is the most common cause of fungal meningitis, causing over 200,000 deaths annually [1]. The unique features of this organism that drive its virulence are incompletely understood. In many bacterial pathogens, quorum sensing plays a key role in the regulation of group behaviors and virulence [2,3]. In previous work, we described a peptide-based quorum sensing system in Cryptococcus neoformans, the first described in a eukaryote [4]. This system is mediated by an 11 residue peptide dubbed Qsp1, first purified because it complements a low-density phenotype produced by C. neoformans lacking a transcriptional co-repressor, Tup1 [5]. Our analysis revealed that Qsp1 is secreted as a pro-peptide that is matured extracellularly by the cell wall-associated serine protease, Pqp1 into a biologically active form [4]. The action of Qsp1 requires an oligopeptide transporter, Opt1 [4]. As cytosolic expression of the mature form of Qsp1 complements the qsp1Δ knockout phenotype (a dry colony phenotype), we infer that Qsp1 acts intracellularly after import [4].
In this prior work, we demonstrated that a WOPR domain transcription factor, Liv3, which is related to key regulatory proteins C. albicans Wor1 and H. capsulatum Ryp1, acts downstream of Qsp1 [4,6–10]. Like cells lacking other components of the Qsp1 system, cells lacking Liv3 display a rough colony morphology phenotype. Cells that lack Qsp1 or Liv3 are also attenuated for virulence in an intranasal mouse model of infection [4,11]. Others have discovered that Qsp1 also regulates unisexual and bisexual mating in C. neoformans as well as mating-induced transcription [12]. This function also requires Opt1 and a previously uncharacterized transcription factor, Cqs2, which has also been called Zfc3 [12,13]. The relationships between the roles of Qsp1 in colony morphology, virulence, and mating are not well-understood.
In this paper, we demonstrate that mutants of two transcription factors in addition to Liv3 display a rough colony phenotype when deleted, Nrg1 and Cqs2. By performing a series of transcriptomics experiments, we show that these transcription factors and Qsp1 regulate a common set of target genes. Whole-genome chromatin immunoprecipitation demonstrates that these transcription factors generally bind together to a common set of target genes, forming a highly connected transcription factor network. Significantly, the presence of Qsp1 impacts the binding of all three transcription factors to a subset of target genes which are highly enriched for genes whose expression is controlled by Qsp1. Cqs2 is particularly sensitive to the presence of Qsp1 for its genomic binding. Cqs2 is strongly required for the binding of Nrg1 and Liv3 to Qsp1-regulated genes, suggesting it may be an upstream factor in the pathways. Furthermore, while Qsp1 seems to negatively regulate protein levels of Nrg1 and Liv3, the association of these factors with promoters is still greatly decreased in the qsp1Δ mutant. These experiments illuminate the mechanism by which an imported quorum-sensing peptide impacts gene expression.
Results
Phenotypic identification of predicted transcription factors that act downstream of Qsp1
Wild-type yeast form glossy colonies, whereas cells lacking the QSP1 gene (qsp1Δ) exhibit a wrinkled colony morphology phenotype at either 25°C or 30°C [4]. We previously published that the transcription factor Liv3 mediates a large portion of the Qsp1 response in rich media, and that a liv3Δ knockout strain forms dry, wrinkled colonies at 30°C. We hypothesized that the deletion of genes encoding factors involved in the response to Qsp1 signaling would also exhibit a wrinkled colony morphology. Therefore, we screened strains in a C. neoformans knockout collection generated in our laboratory for genetic candidates. We discovered two additional strains that exhibited a qsp1Δ-like colony morphology that is also temperature-dependent, corresponding to genes encoding the transcription factors Cqs2 and Nrg1. Cqs2 was recently reported as a regulator of the Qsp1 response for unisexual filamentation [12]. Nrg1 is a transcriptional regulator that plays a role in several cellular processes, including carbohydrate acquisition, metabolism, and virulence [14].
In contrast to the qsp1Δ mutant, each transcription factor deletion strain exhibits this phenotype at a more restricted range of temperatures (Fig 1A). Colonies formed by nrg1Δ cells display their strongest phenotype at room temperature, and liv3Δ and cqs2Δ colonies show their strongest phenotype at 30°C. This dry and wrinkled colony morphology is not caused by an inability of these transcription factor deletion strains to synthesize Qsp1 peptide, as they are still able to secrete wild-type levels of Qsp1 peptide (Fig 1B). Additionally, each transcription factor deletion strain is able to complement a qsp1Δ strain when patched nearby on a plate, due to Qsp1 peptide diffusing through the agar (Fig 1C). In contrast, the colony morphology phenotype of the transcription factor deletion strains could not be complemented by the peptide produced by a wild-type strain (Fig 1C). Therefore, while each transcription factor knockout strain is able to produce Qsp1 peptide, none are complemented by the peptide. This supports the idea that all three of these transcription factors act downstream of Qsp1 production to promote wild-type colony morphology.
Saturated cultures of the qsp1Δ mutant are sensitive to the cell wall stressor SDS, a phenotype that can be rescued by prior growth of the cells in the presence of synthetic Qsp1 peptide [4]. To determine whether these three transcription factors could be involved in Qsp1 signaling in this context, we tested the sensitivity of the corresponding deletion mutants to SDS. We grew each strain to saturation in rich media, then incubated the cells in different concentrations of SDS (Fig 1D). The cells were then plated on YPAD agar to assay for viability following SDS treatment. The liv3Δ strain is not sensitive to SDS treatment, but nrg1Δ and cqs2Δ strains display sensitivity (Fig 1E). Thus, Nrg1 and Cqs2 function to promote resistance to cell wall stress, while Liv3 is dispensable for this phenotype.
To test whether Nrg1, Cqs2, or Liv3 were downstream of Qsp1, we created double knockouts of each transcription factor gene and QSP1 and grew these strains with or without an excess of synthetic Qsp1 peptide for 48 hours (Fig 1F). The qsp1Δnrg1Δ double mutant appears to not be complemented (compare dilutions for SDS sensitivity vs. dilutions for culture titer), and the qsp1Δcqs2Δ double mutant is unable to respond to peptide. The SDS sensitivity of the qsp1Δliv3Δ mutant could be rescued by prior growth in synthetic Qsp1, indicating that Liv3 is not required for the ability of Qsp1 peptide to promote SDS resistance (as expected from the lack of SDS sensitivity in the liv3Δ strain). These data are consistent with a model in which Cqs2 and Nrg1 function downstream of Qsp1 to promote resistance to a cell wall stress.
RNA-seq analysis reveals shared roles for Qsp1 and the three transcription factors
In previous work, we found that loss of Liv3 significantly impacts the response of cells to Qsp1 [4]. These experiments were performed at a single time point in rich media. To test more broadly media and culture density conditions for subsequent analysis, we collected RNA from either wild type or qsp1Δ mutant cultures grown in either rich media (YPAD) or minimal media (YNB) at an optical density at 600 nm (OD600) of 1, 5 and 10 (Fig 2A). We then performed RNA-seq analysis to identify differentially expressed genes. Over 400 genes were significantly affected by the loss of the QSP1 gene in minimal media at an OD600 of 1 (OD1) or OD600 of 5 (OD5), more genes than in rich media at any culture density (Fig 2B). Therefore, we chose to proceed with OD1 and OD5 conditions in minimal media for the subsequent experiment.
To assess whether Liv3, Nrg1, and Cqs2 were required for the expression of genes involved in the Qsp1 response, we performed RNA-seq analysis on RNA extracted from wild type, qsp1Δ, liv3Δ, cqs2Δ, and nrg1Δ cultures grown to OD1 or OD5 in minimal media. We compared differentially expressed genes from the qsp1Δ mutant and the three transcription factor deletion strains relative to wild type at both timepoints (Fig 2C). The P-value for the overlap in differentially expressed genes between targets of pairs of transcription factors or Qsp1 was significant under at least one condition, indicating that the targets of these transcription factors overlap with each other, and with Qsp1 targets, more than would be expected due to random chance (Fig 2C). While the Qsp1-dependent gene set consistently overlapped with those dependent on Cqs2 or Nrg1, this was not the case for the Liv3-dependent set (Fig 2C). The latter only significantly overlapped the Qsp1-dependent set for genes derepressed in the mutants at OD1 (Fig 2C). These data reveal strong similarities between the transcript signatures of the qsp1Δ mutant and those of cqs2Δ and nrg1Δ mutants, with only weak similarity to the liv3Δ mutant signature.
To further examine the involvement of these three transcription factors in Qsp1 signaling, each transcription factor was tagged with a FLAG epitope tag and expressed from their native promoters in either a wild type or qsp1Δ mutant background. To confirm that the tags did not affect protein function, we tested that each tagged strain displayed the expected colony morphology (not shown). Additionally, we confirmed that Qsp1 biology was not affected in these strains by verifying that qsp1Δ mutant strains harboring tagged C-terminally tagged Cqs2 and Liv3 and N-terminally tagged Nrg1 were sensitive to SDS in a manner that could be rescued by growing these strains in an excess of synthetic Qsp1 peptide (S1 Fig).
Quantitative immunoblots show a slight reduction in Cqs2 levels between wild type cells and cells lacking the QSP1 gene at OD1 in minimal media, though this difference was not significant (Fig 3A and S1 Table). However, cells lacking QSP1 expressed significantly more Nrg1 and Liv3 protein (Fig 3A and S1 Table). Due to the strong overlaps between genes controlled by Qsp1 and these three factors at OD1 in minimal media, we conducted ChIP-seq under this condition (Fig 3B and 3C, S2 Fig). To quantify transcription factor binding, a ChIP score for each gene was calculated as the sum of the read depth over a 1 kb region upstream of each transcription start site, normalized to the untagged strain. We employed a k-means clustering approach to divide the genes into groups whose promoters were significantly bound or not-bound (See Methods). We found that in wild type, these transcription factors generally bind to the same promoters (Fig 3C and 3D and S2 Table). The majority of the genes bound by any transcription factor are also bound by one or two others, with 274 genes bound by all three transcription factors (Fig 3D). The overlaps between the sets of promoters that are bound by any two of these three transcription factors are highly significant, further supporting the conclusion that these transcription factors are part of a network (Fig 3E and S2 Table).
Qsp1 affects the binding of all three transcription factors to a common set of promoters
To test whether Qsp1 could influence the binding of these transcription factors, we constructed tagged transcription factor strains that also harbor a knockout of QSP1, and conducted ChIP-seq. In specific regions, binding of the transcription factors is abolished or diminished in the absence of QSP1, indicating that Qsp1 peptide is required for binding of these factors to these promoters (Fig 3C). Our analysis revealed that Qsp1 affects the binding of Cqs2, Liv3, and Nrg1 to a large fraction of bound promoters (Fig 3F, S2 Fig, S3l Fig and S1 Table). We confirmed this by quantifying the amount of binding of each factor to two of the promoters that showed the highest differences by ChIP-seq using ChIP-qPCR (S4 Fig). In the majority of cases, Qsp1 promotes rather than inhibits the binding of a transcription factor to its targets. Overall, we observed a shift to lower levels of binding in the qsp1Δ mutant by Cqs2, with only 7 genes exhibiting an increase in ChIP signal compared to nearly 200 genes exhibiting a decrease in binding. Nrg1 and Liv3 binding increased for the majority of promoters and decreased for others (Fig 3G, S3 Fig, and S2 Table). These data indicate that Qsp1 promotes the binding of Cqs2, and modulates the binding of Nrg1 and Liv3, to upstream regions.
We next sought to understand whether Qsp1 influences the binding of Cqs2, Nrg1, and Liv3 to the same sets of promoters, and whether this influence was positive or negative. We examined the degree of overlap between the sets of promoters that displayed a mean fold-change greater than 1.5-fold in either direction that were called as bound in either wild type or qsp1Δ mutants and tested whether the overlaps between these sets were significant. We observed highly significant (P < 1x10-100) overlaps between promoters that displayed lower levels of binding by any two transcription factors in the qsp1Δ mutant, more so than between groups of promoters that are more bound in the qsp1Δ mutant (Fig 3G and 3H, and S2 Table). This indicates that Qsp1 functions to promote the binding of all three transcription factors upstream of a subset of genes. The overlaps between genes that are differentially bound by any two of these three transcription factors in the qsp1Δ mutant are also highly significant (Fig 3F and S2 Table), but most of the significance comes from genes that are less bound in the mutant (Fig 3G and S2 Table).
Cqs2, Nrg1, and Liv3 are transcription factors that bind to DNA and influence gene expression. Therefore, we tested whether the binding of each transcription factor upstream of a gene impacts the expression of that gene. We compared genes bound by a tagged transcription factor in wild type to genes whose expression was affected by loss of the corresponding transcription factor (Fig 4A). Genes that are bound by a transcription factor, but whose expression is not affected by deletion of a transcription factor, are very often the majority, as they are for Nrg1, Liv3, and Cqs2 (Fig 4A). The expression of these genes may be regulated by other signaling inputs that override the presence of Nrg1, Liv3, or Cqs2 at these promoters, such a s a repressor, or required in addition to these factors to promote expression. Transcriptional activators are often bound to their target promoters, even in non-inducing conditions, indicating that this is a general feature of transcriptional regulation [15]. Nonetheless, the overlaps between these two sets are significant in all comparisons, supporting the conclusion that these three transcription factors influence gene expression via binding to target genes (Fig 4A and S1 Table).
Qsp1 promotes the binding of Cqs2, Nrg1, and Liv3 to promoters, which activates expression of these genes
To test whether the Qsp1-dependent binding events had functional consequences, we next investigated whether the genes whose promoters were differentially bound in a qsp1Δ mutant by each transcription factor were also differentially expressed in a qsp1Δ mutant under a particular condition for all three transcription factors. For all three transcription factors, we observed significant overlaps between genes differentially bound by a transcription factor and genes that were differentially expressed in a qsp1Δ mutant compared to wild type, indicating that the influence of Qsp1 on binding of Cqs2, Nrg1, and Liv3 is important for gene expression (Fig 4B and S2 Table).
To test if there was a relationship between the combination of transcription factors bound and gene expression, we created a heatmap displaying data for genes whose promoters are differentially bound in a qsp1Δ mutant by any transcription factor at OD1, with their corresponding change in expression in a qsp1Δ mutant compared to wild type (S5 Fig and S4 Table). We observed that the largest impact on gene expression occurs for genes whose promoters were much less occupied by all three transcription factors together in the qsp1Δ mutant (Fig 4C, S5 Fig and S2 and S4 Tables). This decrease in occupancy of all three transcription factors in a qsp1Δ mutant compared to wild type corresponds to a significant decrease in expression of about a third of these genes (Fig 4C–4E and S2,S3 and S4 Tables).
From our conservative analysis, there are fourteen genes where Qsp1 promotion of Cqs2, Nrg1, and Liv3 binding correlates with a significant change in expression in the qsp1Δ mutant compared to wild type (Table 1). Five encode predicted transporters of sugars, amino acids, or other types of nutrients. Interestingly, one of the genes encodes Ral2, which is essential for mating in Schizosaccharomyces pombe [16]. Ral2 activates Ras1, a GTPase that is also activated by Ste6, the alpha mating factor transporter and exchange factor for Ras1 [16,17]. Another of these genes encodes Agn1, a putative α-glucanase, and could be related to the cell wall phenotype of qsp1Δ and cqs2Δ mutants [18].
Together, these data indicate that Qsp1 regulates the binding of Cqs2, Nrg1, and Liv3 together to a subset of Qsp1-regulated genes, and the loss of binding of all three of these factors results in altered expression of a set of genes predicted to be involved in nutrient sensing, signaling, and acquisition as well as cell wall remodeling.
Loss of NRG1 or CQS2 affects Liv3, Nrg1, and Cqs2 binding to promoters
To test whether Cqs2, Nrg1, and Liv3 impacted each other’s binding, we attempted to delete the genes encoding the other two transcription factors in the tagged strains described above. We conducted ChIP-seq on FLAG-tagged Liv3, Nrg1, or Cqs2 strains harboring deletions of NRG1 or CQS2 (we were unable to obtain deletions of LIV3) grown to OD1 in minimal media. Immunoblotting demonstrated that no significant difference in the levels of each of these tagged transcription factors in the mutant background compared to wild type (Fig 5A and S5 Table). An example of the binding pattern of Liv3, Nrg1, and Cqs2 in these backgrounds across part of chromosome 1 is shown (Fig 5B). We calculated a ChIP score for transcription factor binding for each promoter in each strain and plotted these for each gene in each transcription factor mutant versus wild type (S5 Fig and S6 Table). Strikingly, deletion of CQS2 results in reduced Liv3 binding to promoters. 357 genes exhibited a >1.5-fold decrease, and only 3 genes exhibited a >1.5-fold increase in binding (Fig 5C, S6 Fig, S2 and S6 Tables). In contrast, deletion of CQS2 both reduced and increased Nrg1 binding, depending on the promoter. Deletion of NRG1 also dramatically impacted Liv3 binding to targets, again primarily reducing binding. Finally, deletion of NRG1 increased Cqs2 binding to more targets than it decreased.
We sought to understand further the transcription factor network in the context of Qsp1 signaling. To accomplish this, we examined how the loss of NRG1 or CQS2 compared with loss of QSP1 on altering binding of Cqs2, Liv3, and Nrg1 to promoters, by comparing the sets of promoters that were affected by each deletion. Strikingly, almost all of the Qsp1-dependent promoters also exhibit a Cqs2-dependence for binding of Nrg1 and Liv3, and in the same direction (Fig 5D, S7 Fig, and S2 and S6 Tables). In other words, the same group of promoters that exhibit altered Nrg1 and Liv3 binding in a qsp1Δ knockout is also impacted in the same direction in a cqs2Δ knockout. Liv3 and Cqs2 binding to Qsp1-dependent promoters is also significantly regulated by Nrg1, but to a lesser extent (Fig 5D, S7 Fig and S2 and S6 Tables). Thus, there is a notable overlap between promoters whose transcription factor binding is promoted by Qsp1 and those that display transcription factor interdependencies for binding.
Discussion
Single-celled organisms often cooperate in a type of community-oriented signaling called quorum sensing, mediated by the accumulation of secreted autoregulatory molecules. Quorum sensing coordinates cellular adaptations that allow the cells to survive in response to environmental cues, such as in mating, biofilm formation, and host infection. Quorum sensing has been reported in many different microbes to regulate mating and competence [19–23], starvation and mating [24], regulation of sporulation in response to starvation [25], nutrient acquisition and virulence [3]. Our experiments have uncovered that Qsp1 regulates gene expression by influencing three transcription factors that play roles in mating, virulence, and nutrient acquisition, providing insight into the mechanism by which a eukaryotic quorum sensing molecule can influence gene expression and clues to the role that quorum sensing plays in the biology of C. neoformans.
Our previous work in C. neoformans demonstrated that Qsp1 is secreted as a precursor that is cleaved outside the cell [4]. The mature peptide accumulates in the culture supernatant, then appears to be imported back into the cell by Opt1, where it induces a transcriptional response [4]. This is remarkably similar to some gram-positive bacteria, which also secrete quorum sensing peptides that are imported into the cell via oligopeptide permeases. Once imported, these small peptides interact with phosphatases [26,27] or transcriptional regulators [28–30] to influence gene expression. In C. neoformans, the two transcription factors Liv3 and Cqs2 have been identified as regulators of the Qsp1 response [4,12]. In this study, we uncovered Nrg1 as a third Qsp1-regulated transcription factor. We showed that the response to Qsp1 signaling is mediated by a network formed by these three transcription factors (Fig 2), which were identified on the basis of a temperature-regulated rough colony morphology that is also exhibited by a qsp1Δ knockout (Fig 1). Surprisingly, we found that Qsp1 seems to promote the binding of Cqs2 to promoters and alter the binding of Nrg1 and Liv3 (Fig 3). These Qsp1-dependent promoters are shared between all three transcription factors, with the largest and most significant overlaps occurring between promoters to which Qsp1 promotes transcription factor binding (Fig 3). This decrease in transcription factor binding to Qsp1-dependent promoters correlates with a decrease in gene expression in cells lacking QSP1 compared to wild type (Fig 4). We observed this correlation with reduced binding leading to reduced expression in spite of higher levels of Cqs2 and Nrg1 protein in qsp1Δ mutants in this condition (Fig 3). Furthermore, Cqs2 promotes Liv3 binding to promoters (Fig 5). Additionally, Cqs2 impacts Nrg1 and Liv3 binding on almost all Qsp1-dependent promoters, given the strong overlap between promoters affected for binding of these transcription factors by loss of QSP1 and loss of CQS2 (Fig 5). Nrg1 also impacts Cqs2 and Liv3 binding (Fig 5). Qsp1 may influence on Nrg1 and Liv3 binding by promoting Cqs2’s affinity for promoter sites, since Cqs2 appears to be the principal factor through which Qsp1 acts under these conditions (Fig 6). Together, these data support the model that Qsp1 influences gene expression by controlling a network of transcription factors' ability to bind to DNA (Fig 6). It is unclear if Qsp1 directly binds to Cqs2, or if there is another unidentified Qsp1-regulated signaling factor upstream of Cqs2 that regulates the affinity of Cqs2 for target promoters. Binding of Qsp1 to a transcription factor could promote binding through a conformational change. Prokaryotic quorum sensing peptides directly bind to transcription factors via the tetratricopeptide repeat (TPR) domain of the regulator, causing conformational changes that alter the activity of the transcription factor, in some cases [26,28–30]. However, Nrg1, Liv3, and Cqs2 do not contain a TPR motif or similar repeats, so if Qsp1 directly binds these transcription factors, it would do so through an as-yet unidentified motif that has evolved for a similar purpose. One appealing hypothesis is that Qsp1 directly promotes cooperativity in DNA binding of Cqs2, Nrg1 and Liv3 to a subset of promoters that display a particular pattern of binding site spacing, sequences and orientations. It is possible that Qsp1 disrupts interactions in other contexts. Testing these hypotheses will require reconstitution of such binding in vitro using purified proteins.
Cqs2, Nrg1, and Liv3 are transcription factors that play roles in mating, nutrient acquisition and virulence in C. neoformans. Qsp1 has recently been shown to signal through Cqs2 to regulate unisexual reproduction and filamentation [12]. Liv3 is required for proliferation in the lung [11]. Liv3 is also a homolog of Wor1, the master regulator of white-opaque switching in C. albicans, a functional and morphological switch in phenotype that can be triggered by various environmental cues and determines which area of the body the fungus is best equipped to colonize [6,8,9]. Nrg1 is a transcriptional regulator that promotes bisexual mating and virulence, and plays a role in several cellular processes, including carbohydrate acquisition, metabolism, and capsule formation [14]. Homologs of Nrg1 in other fungi play roles in filamentation, nutrient sensing, and metabolism in response to environmental cues and are also regulated by quorum sensing [31–37]. Here, we show that Nrg1 and Liv3 protein levels are repressed by the QSP1 gene in minimal media (Fig 3A). We also found that Qsp1 promotes the binding of Cqs2 to promoters and influences the binding of Nrg1 and Liv3, and that these transcription factors influence each other’s binding (Fig 3). These experiments provide a mechanistic basis for quorum sensing control of these factors and further evidence for the implication of quorum sensing in mating and pathogenesis of C. neoformans.
It is unclear why Cqs2, Nrg1, and Liv3 transcription factors have been integrated into a quorum sensing system. One possibility is that quorum sensing enables cells to anticipate and prepare for future starvation and associated stresses, which could be critical in particular host niches or when deciding to mate. In prokaryotes, starvation and quorum sensing signaling pathways regulate each other [38]. In Saccharomyces cerevisiae, the production of autoregulatory aromatic alcohols is coupled to both culture density and nitrogen starvation, and serves as a species-specific trigger for transformation into a filamentous form [39]. In both bacteria and yeast, it is thought that entry into stationary phase once nutrients are exhausted provides benefits to the cell such as thickening of the cell wall, accumulation of reserve nutrients, and an increased resistance to environmental stressors, allowing the cells to survive long term [38,40]. Integration of quorum sensing and starvation signaling could explain why Qsp1 signaling increases as culture density increases in rich media as nutrients run out, but has the opposite trend in minimal media, where cells are starved immediately (Fig 2). In addition, we found that Qsp1 promotion of resistance of stationary-phase cells to cell wall stress requires Nrg1 and Cqs2 (Fig 1), further solidifying the relationship between quorum sensing and starvation responses.
In line with this idea, one of the promoters that exhibited a very dramatic dependence on Qsp1 for binding of all three transcription factors was the LAC1 gene (CNAG_03465) (S3 Fig), which encodes the melanization factor laccase [40–42]. Melanization is known to be a key virulence trait for C. neoformans infection [40,43]. In our previous work, we found that cells lacking Qsp1 display altered capacities to produce melanin when plated on media containing the substrate for melanin synthesis [4]. Although our conditions did not reveal laccase transcript regulation by Qsp1, it may be that these three transcription factors bind to the laccase promoter in the presence of Qsp1 in order to prime the cell to activate transcription as soon as the correct signals are received.
In conclusion, it seems that these three transcription factors are at the core of a gene regulatory network that integrates Qsp1 signaling with starvation or other unknown signaling inputs to determine which genes to express in different contexts (such as in the host or in different media), ultimately influencing the mating and virulence of this organism.
Methods
Cryptococcal strain construction
Gene deletions were generated using nourseothricin (NAT) resistance, neomycin (NEO) resistance, or hygromycin (HYG) resistance cassettes. Proteins were tagged with 2x-FLAG or 3x-FLAG epitope tags using one of these three resistance cassettes as previously described [41]. Constructs were made via homologous recombination using fragments amplified with the primers in Table 2. Strains constructed in this study are listed in Table 3.
All strains are derived from the KN99alpha (CM26) parent.
Cell wall stress assay
Part of a colony was cultured in 5 ml of YPAD (1% yeast extract, 2% Bacto-peptone, 2% glucose, 0.015% L-tryptophan, 0.004% adenine) for 48 hours, when all cultures were fully saturated. 1 uM pure synthetic Qsp1 peptide (LifeTein) was added to indicated cultures at the time of inoculation. 50 ul of saturated culture was mixed with 150ul of either water or SDS in a series of 1:2 dilutions (starting at 10%) and incubated for 3 hours at room temperature without shaking. The supernatant of settled incubations was partially replaced with water following SDS incubation and prior to cell resuspension to minimize the amount of SDS transferred to the recipient plate, and 3 ul were spotted on YPAD plates containing no SDS to assay survival. Cells incubated in water were then serially diluted 1:6 to provide a measure of the titer of the input culture. Plates were allowed to grow for 4 days at room temperature.
Immunoblots
Two biological replicates from each strain were cultured for immunoblot. 2 OD600 units of cells per sample were fixed with 10% TCA, then 100% acetone, then lysed by two 1.5 minute rounds of bead-beating in sample buffer. Samples were then boiled for 5 min and cell debris was spun down. For supernatant analysis, 2 mL of conditioned media were snap frozen and lyophilized overnight, then resuspended in 150 μl of 1x Laemmli Sample Buffer. 5–10 μl of each sample was loaded on 4–12% Bis-Tris gels (Thermofisher).
RNA-Seq and ChIP-Seq cultures
Each strain of C. neoformans was inoculated in YPAD or YNB at 30°C. The next day, larger cultures were started from the starter cultures at an OD < 0.01. On the following day, as each culture grew in density 50 OD600 units of cells were harvested sequentially from the same culture at the indicated ODs.
50 OD600’s of cells at each optical density (OD 1, 5, and 10) for each replicate for each strain were harvested sequentially as the cultures grew. For ChIP-seq samples, 50 OD600’s of cells were crosslinked in a 50 mL volume of conditioned media from the same culture, harvested at the same time as the cells.
RNA-Seq
Total RNA was isolated from 50 OD600’s of cells as previously described [42] and libraries prepared as previously described [43]. In brief, cell pellets were lyophilized overnight and then RNA was isolated using TRIzol (Invitrogen) as previously described [42] and DNase treated as previously described [44]. 0.5 μg RNA was then prepared for sequencing using the QuantSeq 3‘-mRNA-Seq Library Prep Kit FWD (Lexogen) according to the manufacturer’s instructions. Input RNA quality and mRNA purity were verified by Bioanalyzer Pico RNA chips (Agilent). Libraries were sequenced on the HiSeq 4000 platform (Illumina).
RNA-Seq analysis
Expression analysis for each transcription factor mutant was performed by counting the number of reads aligned by STAR for each transcript [45]. DEseq2 was used to determine genes differentially expressed between mutant and wild type conditions. Noncoding genes were not included in the analysis. See GEO accession #GSE147378 for raw data.
Chromatin immunoprecipitation (ChIP)
ChIP was performed as described previously [4], with the following changes: 50 OD600 units of cells were crosslinked in 50 mL total of conditioned media. Lyophilized pellets were resuspended in 600 ul ChIP lysis buffer with protease inhibitors for bead beating until >95% of cells were lysed. The chromatin pellet was resuspended in 350 ul ChIP lysis buffer for sonication. After sonication and removal of cell debris via centrifugation, the supernatant was brought to 3 ml in ChIP lysis buffer. Immunoprecipitation was performed at 4°C overnight with nutation in 1 ml chromatin aliquots with 3 ul of anti-FLAG M2 antibody (F3165, Sigma) and 20 ul of Protein G Dynabeads (Invitrogen). See GEO accession #GSE147378 for raw data. ChIP-qPCR primers are shown in Table 4.
ChIP-seq library construction
ChIP-seq library construction was performed as described previously [4] with the following changes: For each genotype, libraries for two biological replicates were prepared. Adaptors were selected out using Sera-Mag SpeedBead Carboxylate-Modified Magnetic Particles (Hydrophobic) and products between 200-500bp were selected by gel extraction. Library quality and concentration were determined by High Sensitivity DNA Bioanalyzer analysis (Agilent) and Qubit (Thermofisher), respectively.
ChIP-Seq analysis
ChIP-seq reads were trimmed with CutAdapt and aligned using Bowtie1 [46]. Up to two mismatches within the seed sequence. If a read could align to multiple loci, it was aligned at random. Indexed, sorted bam files were created for each dataset using SAMtools [47]. Bedgraph files were created using BEDtools [48,49], and normalized to the untagged sample by subtraction. The ChIP signal for each gene in each replicate was calculated as the sum of the read depth over the promoter region, defined as the 1kb upstream of the annotated transcription start site. Using the ChIP signal, genes were clustered into bound or unbound via k-means analysis. There was a high degree of overlap between genes called as bound in either replicate (S7 Table), but genes were only considered as bound in our analysis if it was called as bound in both replicates by k-means analysis (S6 Table). The average of the ChIP signal from both replicates was taken for subsequent analysis. Bedgraphs were plotted using Integrative Genomics Viewer 2.0.30 (Broad Institute). Genes were determined as differentially bound if the fold change in ChIP signal between both conditions was greater than 1.5-fold in either direction (based on [50]).
Statistical analysis
Immunoblot quantification was performed with ImageJ analysis on two biological replicates, and significance was determined using the student’s t-test. P-values <0.05 were considered significant. All other P-values were adjusted (P-adj) for multiple testing using the Bonferroni correction (S2 Table).
Supporting information
S1 Fig [tif]
Tagging Cqs2, Liv3, and Nrg1 does not affect protein function or the ability of mutants to respond to Qsp1.
S2 Fig [tif]
Closeups of binding patterns across all genotypes in this study for four individual promoters.
S3 Fig [tif]
Deletion of affects the binding of Cqs2, Liv3, and Nrg1 to promoters.
S4 Fig [tif]
ChIP-qPCR validation of ChIP-seq results.
S5 Fig [tif]
A heatmap of genes that are differentially bound by either Cqs2, Liv3, or Nrg1, and their respective log2-fold expression difference in compared to wild type.
S6 Fig [tif]
or deletion affects the binding of Cqs2, Liv3, and Nrg1 to their promoters.
S7 Fig [tif]
Promoters that are differentially bound by transcription factors in a mutant are also differentially bound by these transcription factors in an or mutant compared to wild type.
S1 Table [xlsx]
Data used to generate .
S2 Table [diff]
Analysis of the degree and significance of overlaps between different sets of genes either bound by Nrg1 (N), Liv3 (L), or Cqs2 (C) in each genotype, differentially bound by these three transcription factors in vs. wild type, or differentially expressed in vs. wild type.
S3 Table [xlsx]
Values used to create .
S4 Table [xlsx]
Numbers used to generate the heatmap in .
S5 Table [xlsx]
Data used to generate .
S6 Table [xlsx]
ChIP score values.
S7 Table [xlsx]
Comparison of the number of promoters called as bound in either replicate.
Zdroje
1. Armstrong-James D, Meintjes G, Brown GD. A neglected epidemic: fungal infections in HIV/AIDS. Trends Microbiol. 2014 Mar 1;22(3):120–7. doi: 10.1016/j.tim.2014.01.001 24530175
2. Bassler BL, Miller MB. Quorum Sensing. In: Rosenberg E, DeLong EF, S Lory, E Stackebrandt, Thompson F, editors. The Prokaryotes: Prokaryotic Communities and Ecophysiology [Internet]. Berlin, Heidelberg: Springer; 2013 [cited 2020 Feb 29]. p. 495–509. Available from: https://doi.org/10.1007/978-3-642-30123-0_60
3. de Kievit TR, Iglewski BH. Bacterial Quorum Sensing in Pathogenic Relationships. Infect Immun. 2000 Sep;68(9):4839–49. doi: 10.1128/iai.68.9.4839-4849.2000 10948095
4. Homer CM, Summers DK, Goranov AI, Clarke SC, Wiesner D, Diedrich JK, et al. Intracellular Action of a Secreted Peptide Required for Fungal Virulence. Cell Host Microbe. 2016 Jun 8;19(6):849–64. doi: 10.1016/j.chom.2016.05.001 27212659
5. Lee H, Chang YC, Nardone G, Kwon-Chung KJ. TUP1 disruption in Cryptococcus neoformans uncovers a peptide-mediated density-dependent growth phenomenon that mimics quorum sensing. Mol Microbiol. 2007 May 1;64(3):591–601. doi: 10.1111/j.1365-2958.2007.05666.x 17462010
6. Srikantha T, Borneman AR, Daniels KJ, Pujol C, Wu W, Seringhaus MR, et al. TOS9 Regulates White-Opaque Switching in Candida albicans. Eukaryot Cell. 2006 Oct;5(10):1674–87. doi: 10.1128/EC.00252-06 16950924
7. Alkafeef SS, Yu C, Huang L, Liu H. Wor1 establishes opaque cell fate through inhibition of the general co-repressor Tup1 in Candida albicans. PLOS Genet. 2018 Jan 16;14(1):e1007176. doi: 10.1371/journal.pgen.1007176 29337983
8. Huang G, Wang H, Chou S, Nie X, Chen J, Liu H. Bistable expression of WOR1, a master regulator of white-opaque switching in Candida albicans. Proc Natl Acad Sci U S A. 2006 Aug 22;103(34):12813–8. doi: 10.1073/pnas.0605270103 16905649
9. Cain CW, Lohse MB, Homann OR, Sil A, Johnson AD. A Conserved Transcriptional Regulator Governs Fungal Morphology in Widely Diverged Species. Genetics. 2012 Feb;190(2):511–21. doi: 10.1534/genetics.111.134080 22095082
10. Nguyen VQ, Sil A. Temperature-induced switch to the pathogenic yeast form of Histoplasma capsulatum requires Ryp1, a conserved transcriptional regulator. Proc Natl Acad Sci U S A. 2008 Mar 25;105(12):4880–5. doi: 10.1073/pnas.0710448105 18339808
11. Liu OW, Chun CD, Chow ED, Chen C, Madhani HD, Noble SM. Systematic genetic analysis of virulence in the human fungal pathogen Cryptococcus neoformans. Cell. 2008 Oct 3;135(1):174–88. doi: 10.1016/j.cell.2008.07.046 18854164
12. Tian X, He G-J, Hu P, Chen L, Tao C, Cui Y-L, et al. Cryptococcus neoformans sexual reproduction is controlled by a quorum sensing peptide. Nat Microbiol. 2018 Jun;3(6):698. doi: 10.1038/s41564-018-0160-4 29784977
13. Jung K-W, Yang D-H, Maeng S, Lee K-T, So Y-S, Hong J, et al. Systematic functional profiling of transcription factor networks in Cryptococcus neoformans. Nat Commun [Internet]. 2015 Apr 7 [cited 2019 Mar 6];6. Available from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4391232/
14. Cramer KL, Gerrald QD, Nichols CB, Price MS, Alspaugh JA. Transcription Factor Nrg1 Mediates Capsule Formation, Stress Response, and Pathogenesis in Cryptococcus neoformans. Eukaryot Cell. 2006 Jul;5(7):1147–56. doi: 10.1128/EC.00145-06 16835458
15. Wyrick JJ, Young RA. Deciphering gene expression regulatory networks. Curr Opin Genet Dev. 2002 Apr 1;12(2):130–6. doi: 10.1016/s0959-437x(02)00277-0 11893484
16. Fukui Y, Miyake S, Satoh M, Yamamoto M. Characterization of the Schizosaccharomyces pombe ral2 gene implicated in activation of the ras1 gene product. Mol Cell Biol. 1989 Dec;9(12):5617–22. doi: 10.1128/mcb.9.12.5617 2586528
17. Imai Y, Miyake S, Hughes DA, Yamamoto M. Identification of a GTPase-activating protein homolog in Schizosaccharomyces pombe. Mol Cell Biol. 1991 Jun;11(6):3088–94. doi: 10.1128/mcb.11.6.3088 2038319
18. Dekker N, Speijer D, Grün CH, van den Berg M, de Haan A, Hochstenbach F. Role of the α-Glucanase Agn1p in Fission-Yeast Cell Separation. Mol Biol Cell. 2004 Aug;15(8):3903–14. doi: 10.1091/mbc.e04-04-0319 15194814
19. Zhang H-B, Wang L-H, Zhang L-H. Genetic control of quorum-sensing signal turnover in Agrobacterium tumefaciens. Proc Natl Acad Sci U S A. 2002 Apr 2;99(7):4638–43. doi: 10.1073/pnas.022056699 11930013
20. Chatterjee A, Cook LCC, Shu C-C, Chen Y, Manias DA, Ramkrishna D, et al. Antagonistic self-sensing and mate-sensing signaling controls antibiotic-resistance transfer. Proc Natl Acad Sci. 2013 Apr 23;110(17):7086–90. doi: 10.1073/pnas.1212256110 23569272
21. Schneider KB, Palmer TM, Grossman AD. Characterization of comQ and comX, Two Genes Required for Production of ComX Pheromone in Bacillus subtilis. J Bacteriol. 2002 Jan;184(2):410–9. doi: 10.1128/jb.184.2.410-419.2002 11751817
22. Comella N, Grossman AD. Conservation of genes and processes controlled by the quorum response in bacteria: characterization of genes controlled by the quorum-sensing transcription factor ComA in Bacillus subtilis. Mol Microbiol. 2005;57(4):1159–74. doi: 10.1111/j.1365-2958.2005.04749.x 16091051
23. Hogan DA. Talking to Themselves: Autoregulation and Quorum Sensing in Fungi. Eukaryot Cell. 2006 Apr;5(4):613–9. doi: 10.1128/EC.5.4.613-619.2006 16607008
24. Honigberg SM, Purnapatre K. Signal pathway integration in the switch from the mitotic cell cycle to meiosis in yeast. J Cell Sci. 2003 Jun 1;116(11):2137–47.
25. Grossman AD, Losick R. Extracellular control of spore formation in Bacillus subtilis. Proc Natl Acad Sci U S A. 1988 Jun;85(12):4369–73. doi: 10.1073/pnas.85.12.4369 3132711
26. Pottathil M, Lazazzera BA. The extracellular Phr peptide-Rap phosphatase signaling circuit of Bacillus subtilis. Front Biosci J Virtual Libr. 2003 Jan 1;8:d32–45.
27. Perego M. Forty Years in the Making: Understanding the Molecular Mechanism of Peptide Regulation in Bacterial Development. PLoS Biol [Internet]. 2013 Mar 19 [cited 2020 Feb 29];11(3). Available from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3601992/
28. Slamti L, Lereclus D. A cell–cell signaling peptide activates the PlcR virulence regulon in bacteria of the Bacillus cereus group. EMBO J. 2002 Sep 2;21(17):4550–9. doi: 10.1093/emboj/cdf450 12198157
29. Grenha R, Slamti L, Nicaise M, Refes Y, Lereclus D, Nessler S. Structural basis for the activation mechanism of the PlcR virulence regulator by the quorum-sensing signal peptide PapR. Proc Natl Acad Sci U S A. 2013 Jan 15;110(3):1047–52. doi: 10.1073/pnas.1213770110 23277548
30. Kozlowicz BK, Shi K, Gu Z-Y, Ohlendorf DH, Earhart CA, Dunny GM. Molecular basis for control of conjugation by bacterial pheromone and inhibitor peptides. Mol Microbiol. 2006 Nov;62(4):958–69. doi: 10.1111/j.1365-2958.2006.05434.x 17038121
31. Murad AMA, Leng P, Straffon M, Wishart J, Macaskill S, MacCallum D, et al. NRG1 represses yeast–hypha morphogenesis and hypha-specific gene expression in Candida albicans. EMBO J. 2001 Sep 3;20(17):4742–52. doi: 10.1093/emboj/20.17.4742 11532938
32. Lu Y, Su C, Unoje O, Liu H. Quorum sensing controls hyphal initiation in Candida albicans through Ubr1-mediated protein degradation. Proc Natl Acad Sci U S A. 2014 Feb 4;111(5):1975–80. doi: 10.1073/pnas.1318690111 24449897
33. Gómez-Gil E, Franco A, Madrid M, Vázquez-Marín B, Gacto M, Fernández-Breis J, et al. Quorum sensing and stress-activated MAPK signaling repress yeast to hypha transition in the fission yeast Schizosaccharomyces japonicus. PLoS Genet [Internet]. 2019 May 31 [cited 2020 Jan 3];15(5). Available from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6561576/
34. Berkey CD, Vyas VK, Carlson M. Nrg1 and Nrg2 Transcriptional Repressors Are Differently Regulated in Response to Carbon Source. Eukaryot Cell. 2004 Apr;3(2):311–7. doi: 10.1128/ec.3.2.311-317.2004 15075261
35. Kim TS, Lee SB, Kang HS. Glucose Repression of STA1 Expression Is Mediated by the Nrg1 and Sfl1 Repressors and the Srb8-11 Complex. Mol Cell Biol. 2004 Sep;24(17):7695–706. doi: 10.1128/MCB.24.17.7695-7706.2004 15314176
36. Lee SB, Kang HS, Kim T. Nrg1 functions as a global transcriptional repressor of glucose-repressed genes through its direct binding to the specific promoter regions. Biochem Biophys Res Commun. 2013 Oct 4;439(4):501–5. doi: 10.1016/j.bbrc.2013.09.015 24025681
37. Kinnaer C, Dudin O, Martin SG. Yeast-to-hypha transition of Schizosaccharomyces japonicus in response to environmental stimuli. Mol Biol Cell. 2019 01;30(8):975–91. doi: 10.1091/mbc.E18-12-0774 30726171
38. Lazazzera BA. Quorum sensing and starvation: signals for entry into stationary phase. Curr Opin Microbiol. 2000 Apr 1;3(2):177–82. doi: 10.1016/s1369-5274(00)00072-2 10744996
39. Chen H, Fink GR. Feedback control of morphogenesis in fungi by aromatic alcohols. Genes Dev. 2006 May 1;20(9):1150–61. doi: 10.1101/gad.1411806 16618799
40. Herman PK. Stationary phase in yeast. Curr Opin Microbiol. 2002 Dec 1;5(6):602–7. doi: 10.1016/s1369-5274(02)00377-6 12457705
41. Chun CD, Madhani HD. Ctr2 Links Copper Homeostasis to Polysaccharide Capsule Formation and Phagocytosis Inhibition in the Human Fungal Pathogen Cryptococcus neoformans. PLoS ONE. 2010 Sep 2;5(9):e12503.
42. Dumesic PA, Natarajan P, Chen C, Drinnenberg IA, Schiller BJ, Thompson J, et al. Stalled Spliceosomes Are a Signal for RNAi-Mediated Genome Defense. Cell. 2013 Feb 28;152(5):957–68. doi: 10.1016/j.cell.2013.01.046 23415457
43. Burke JE, Longhurst AD, Natarajan P, Rao B, Liu J, Sales-Lee J, et al. A Non-Dicer RNase III and Four Other Novel Factors Required for RNAi-Mediated Transposon Suppression in the Human Pathogenic Yeast Cryptococcus neoformans. G3 GenesGenomesGenetics. 2019 May 15;9(7):2235–44.
44. Zhang Z, Theurkauf WE, Weng Z, Zamore PD. Strand-specific libraries for high throughput RNA sequencing (RNA-Seq) prepared without poly(A) selection. Silence. 2012 Dec 28;3:9. doi: 10.1186/1758-907X-3-9 23273270
45. Dobin A, Davis CA, Schlesinger F, Drenkow J, Zaleski C, Jha S, et al. STAR: ultrafast universal RNA-seq aligner. Bioinformatics. 2013 Jan;29(1):15–21. doi: 10.1093/bioinformatics/bts635 23104886
46. Aligning Short Sequencing Reads with Bowtie—Langmead—2010—Current Protocols in Bioinformatics—Wiley Online Library [Internet]. [cited 2020 Feb 23]. Available from: https://currentprotocols.onlinelibrary.wiley.com/doi/abs/10.1002/0471250953.bi1107s32
47. Li H, Handsaker B, Wysoker A, Fennell T, Ruan J, Homer N, et al. The Sequence Alignment/Map format and SAMtools. Bioinformatics. 2009 Aug 15;25(16):2078–9. doi: 10.1093/bioinformatics/btp352 19505943
48. Quinlan AR. BEDTools: the Swiss-army tool for genome feature analysis. Curr Protoc Bioinforma Ed Board Andreas Baxevanis Al. 2014 Sep 8;47:11.12.1–11.12.34.
49. Quinlan AR, Hall IM. BEDTools: a flexible suite of utilities for comparing genomic features. Bioinformatics. 2010 Mar 15;26(6):841–2. doi: 10.1093/bioinformatics/btq033 20110278
50. Garcia-Santamarina S, Festa RA, Smith AD, Yu C-H, Probst C, Ding C, et al. Genome-wide analysis of the regulation of Cu metabolism in Cryptococcus neoformans. Mol Microbiol. 2018 Jun;108(5):473–94. doi: 10.1111/mmi.13960 29608794
Článek vyšel v časopise
PLOS Genetics
2020 Číslo 9
- Antibiotika na nachlazení nezabírají! Jak můžeme zpomalit šíření rezistence?
- FDA varuje před selfmonitoringem cukru pomocí chytrých hodinek. Jak je to v Česku?
- Prof. Jan Škrha: Metformin je bezpečný, ale je třeba jej bezpečně užívat a léčbu kontrolovat
- Ibuprofen jako alternativa antibiotik při léčbě infekcí močových cest
- Jak a kdy u celiakie začíná reakce na lepek? Možnou odpověď poodkryla čerstvá kanadská studie
Nejčtenější v tomto čísle
- Alleviating chronic ER stress by p38-Ire1-Xbp1 pathway and insulin-associated autophagy in C. elegans neurons
- Cocoonase is indispensable for Lepidoptera insects breaking the sealed cocoon
- A mega-analysis of expression quantitative trait loci in retinal tissue
- Adiponectin GWAS loci harboring extensive allelic heterogeneity exhibit distinct molecular consequences