EGL-13/SoxD Specifies Distinct O and CO Sensory Neuron Fates in
: Animals harbor specialized neuronal systems that are used for sensing and coordinating responses to changes in oxygen (O2) and carbon dioxide (CO2). In Caenorhabditis elegans, the O2/CO2 sensory system comprises functionally and morphologically distinct sensory neurons that mediate rapid behavioral responses to exquisite changes in O2 or CO2 levels via different sensory receptors. How the diversification of the O2- and CO2-sensing neurons is established is poorly understood. We show here that the molecular identity of both the BAG (O2/CO2-sensing) and the URX (O2-sensing) neurons is controlled by the phylogenetically conserved SoxD transcription factor homolog EGL-13. egl-13 mutant animals fail to fully express the distinct terminal gene batteries of the BAG and URX neurons and, as such, are unable to mount behavioral responses to changes in O2 and CO2. We found that the expression of egl-13 is regulated in the BAG and URX neurons by two conserved transcription factors—ETS-5(Ets factor) in the BAG neurons and AHR-1(bHLH factor) in the URX neurons. In addition, we found that EGL-13 acts in partially parallel pathways with both ETS-5 and AHR-1 to direct BAG and URX neuronal fate respectively. Finally, we found that EGL-13 is sufficient to induce O2- and CO2-sensing cell fates in some cellular contexts. Thus, the same core regulatory factor, egl-13, is required and sufficient to specify the distinct fates of O2- and CO2-sensing neurons in C. elegans. These findings extend our understanding of mechanisms of neuronal diversification and the regulation of molecular factors that may be conserved in higher organisms.
Published in the journal:
EGL-13/SoxD Specifies Distinct O and CO Sensory Neuron Fates in. PLoS Genet 9(5): e32767. doi:10.1371/journal.pgen.1003511
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1003511
Summary
: Animals harbor specialized neuronal systems that are used for sensing and coordinating responses to changes in oxygen (O2) and carbon dioxide (CO2). In Caenorhabditis elegans, the O2/CO2 sensory system comprises functionally and morphologically distinct sensory neurons that mediate rapid behavioral responses to exquisite changes in O2 or CO2 levels via different sensory receptors. How the diversification of the O2- and CO2-sensing neurons is established is poorly understood. We show here that the molecular identity of both the BAG (O2/CO2-sensing) and the URX (O2-sensing) neurons is controlled by the phylogenetically conserved SoxD transcription factor homolog EGL-13. egl-13 mutant animals fail to fully express the distinct terminal gene batteries of the BAG and URX neurons and, as such, are unable to mount behavioral responses to changes in O2 and CO2. We found that the expression of egl-13 is regulated in the BAG and URX neurons by two conserved transcription factors—ETS-5(Ets factor) in the BAG neurons and AHR-1(bHLH factor) in the URX neurons. In addition, we found that EGL-13 acts in partially parallel pathways with both ETS-5 and AHR-1 to direct BAG and URX neuronal fate respectively. Finally, we found that EGL-13 is sufficient to induce O2- and CO2-sensing cell fates in some cellular contexts. Thus, the same core regulatory factor, egl-13, is required and sufficient to specify the distinct fates of O2- and CO2-sensing neurons in C. elegans. These findings extend our understanding of mechanisms of neuronal diversification and the regulation of molecular factors that may be conserved in higher organisms.
Introduction
The capacity of the nervous system to sense and respond to fluctuations in the external and internal environment is essential for homeostasis and survival. Neuronally controlled homeostatic buffering is delivered through cellular and systemic physiological adjustments and by seeking optimal environmental conditions through behavioral strategies [1]–[4]. A crucial homeostatic capacity of animals is the ability to sense and respond to changes in concentration of the respiratory gases oxygen (O2) and carbon dioxide (CO2) [5], [6]. O2 is essential for the generation of energy in the form of adenosine triphosphate (ATP); however, O2 also exerts toxicity through the production of reactive oxygen species (ROS) [1]–[4], [7]. CO2 is a by-product of oxidative metabolism and prolonged exposure leads to acidosis [5], [6], [8]. CO2 is also an environmental cue used in host- and mate- finding and can initiate both aversive or attractive behaviors [9]–[11]. The evolution of mechanisms required to sense and respond to O2 and CO2 is therefore paramount for survival.
In Drosophila, specific sensory systems respond to external O2 levels [1], [7], [12]. In addition, Drosophila uses specialized olfactory and gustatory neurons to detect CO2 changes via specialized chemosensory receptors called Gr21a/Gr63a [9], [13]. In humans, O2, CO2 and pH levels are monitored by specific regions of the brainstem and by specialized neurosecretory glomus cells of the carotid body [14], whereas in non-human mammals CO2 is also sensed by specific olfactory neurons that target the necklace glomeruli in the olfactory bulb via the guanylyl cyclase GC-D [15]. It is poorly understood how the specification of such specialized sensory neurons is regulated. However, recent work in Drosophila has shown that epigenetic mechanisms play an important role [16].
Respiratory gas sensing is a crucial modality for Caenorhabditis elegans whose natural environment, such as rotting fruit and compost, can have wide ranges of O2 and CO2 levels [17]. Previous work has shown that in the laboratory, worms have a behavioral preference for 5%–10% O2 and are exquisitely sensitive to minor changes in O2 concentration [18], [19]. In addition, worms mount avoidance responses to CO2 levels above 0.5% [4], [11]. Of the 302 neurons in the C. elegans nervous system, at least six neurons are specifically dedicated to the detection and response to changes in O2 and CO2 levels. These include the BAGL/R, URXL/R, AQR and PQR neurons. The BAG neurons are the primary CO2 sensors and they also respond to decrease in O2 concentration [11], [20]–[22]. The URX, AQR and PQR neurons are specialized for responding to increasing O2 concentrations [20]. In C. elegans, members of the guanylyl cyclase family of proteins are crucial factors required for O2 and CO2 sensing. Pioneering work revealed that the soluble guanylyl cyclases (sGCs) GCY-35 and GCY-36 mediate high O2 avoidance behavior via the URX, AQR and PQR neurons and that GCY-35 directly binds to molecular O2 [18]. In contrast, the sGCs, GCY-31 and GCY-33 function in the BAG neurons to sense decreases in O2 [20]. Recent work found that the membrane-bound receptor-type guanylyl cyclase GCY-9 acts specifically in the BAG neurons to mediate CO2 avoidance behavior [21]. Other molecules such as the Phe-Met-Arg-Phe-NH2 (FMRF-amide)-related peptides (FLP-8, FLP-13, FLP-17 and FLP-19) are expressed in either a subset or all of the O2- and CO2-sensing neurons; however their precise molecular functions in O2 and CO2 sensing are not known [23], [24].
Neuronal specialization within the O2/CO2-sensing system in C. elegans is an excellent model to study the control of neuron diversity. The O2-sensing (URX, AQR and PQR) and O2/CO2-sensing (BAG) neurons have overlapping and non-overlapping patterns of guanylyl cyclase and neuropeptide expression, which are reflected in their related, albeit distinct functionalities [20]. At present, it is unclear how the expression of these molecules is restricted to certain parts of the O2/CO2-sensing nervous system, and how such restrictions coordinate neuronal fate and function.
Here, we have identified the Sox transcription factor EGL-13 as an important regulator of the O2 and CO2-sensing neuron cell fate decision. EGL-13 is required for the expression of distinct proteins required for sensing both O2 and CO2 and as such, egl-13 mutant animals are unable to mount behavioral responses to changes in O2 and CO2. We found that the expression of EGL-13 is controlled by ETS-5 in the BAG neurons and by AHR-1 in the URX neurons, and acts in partially parallel pathways with these factors to drive neuronal fate. Finally, we found that EGL-13 is sufficient to drive O2- and CO2-sensing cell fates in certain cellular contexts. Therefore, EGL-13 is a core regulatory factor that is both required and sufficient to drive O2- and CO2-sensing neuron specification in C. elegans. As EGL-13 is a member of the SoxD family of transcription factors, we anticipate that the regulatory relationships described here will provide a paradigm for the control of neuronal fate specification by Sox proteins in other cellular contexts.
Results/Discussion
The SoxD transcription factor egl-13 specifies distinct O2- and CO2-sensing neurons
In order to identify molecules and pathways important for O2- and CO2-sensing neuron specification, we have taken a forward genetics approach in C. elegans. We isolated four independent allelic mutations (rp14, rp22, rp23 and rp26) that affect the expression of terminal differentiation markers in the O2 and/or CO2-sensing neurons (Figure 1 and Table S1) Mutant hermaphrodites of each of these alleles are severely egg-laying defective (Egl) and form a bag-of-worms where embryos hatch inside the mother (Figure S1). We investigated their vulval phenotype and found that the anchor cell fails to fuse with the uterine seam cell, causing a blockage of the uterus and the resultant Egl phenotype (Figure S1). This anchor cell fusion defect is reminiscent of that observed in egl-13(ku194) mutant animals [25] which we found to also exhibit defects in O2 and CO2 reporter expression (Figure 1 and Figure S1). Subsequent Sanger sequencing of rp14, rp22, rp23 and rp26 revealed genetic lesions in the egl-13 locus (Figure 1A). egl-13 encodes the C. elegans ortholog of the HMG-domain-containing SoxD family of transcription factors that has no previously reported role in the worm nervous system.
Loss of egl-13 affects terminal fate of O2- and CO2-sensing neurons
The BAG, URX, AQR and PQR neurons in C. elegans are required for sensing and responding to fluctuations of O2 and CO2 levels in the environment [11], [18], [19]. Distinct batteries of genes are expressed in these neurons that are predicted to provide the optimal functionality required for O2 and CO2 sensing, however the role of only a subset of these genes has been analyzed in detail [20], [21], [26]. We used fluorescent reporter constructs to monitor expression of these gene batteries to understand how egl-13 controls O2 and CO2-sensing neuron cell fate (Figure 1). We analyzed the expression of guanylyl cyclases (gcy-9, gcy-31, gcy-33, gcy-35 and gcy-36) and Phe-Met-Arg-Phe-NH2 (FMRF-amide)-related peptides (flp-8, flp-13, flp-17 and flp-19) that are all terminal differentiation genes expressed in all or a subset of O2 and CO2-sensing neurons [18], [19], [21], [24]. We crossed these reporter transgenes into egl-13 mutant animals (ku194 allele) and found that none of the reporters were properly expressed in egl-13 mutants (Figure 1 and Table S1). We also found similar effects in the four egl-13 mutant alleles we isolated (rp14, rp22, rp23 and rp26) (Figure S1C). We noticed that some of the reporters were exquisitely sensitive to egl-13 loss whereas others exhibited partially penetrant defects (Table S1). This suggests that the expression of some terminal differentiation factors are under the collaborative control of additional factors that are able to compensate for the loss of egl-13.
The BAG and URX neurons are derived from the AB lineage and are posterior sisters of other neurons that have distinct fates [27] (Figure S2). We therefore asked whether egl-13 is also required for the specification of the sister cells of BAG or URX. We crossed egl-13(ku194) mutant animals into fluorescent reporter strains for the SMDV, zfIs2 (lgc-55::mCherry) and CEPD, vtIs1 (dat-1::gfp), sister cells for BAG and URX neurons respectively. We found that the expression of these reporters were unaffected by loss of egl-13 suggesting a specific role for egl-13 in the posterior branch of these lineages (Table S1 and Figure S2). Taken together, we conclude that egl-13 controls the expression of the distinct O2- and CO2-sensing neuron terminal gene batteries that distinguish them from lineage-related neurons.
egl-13 acts cell-autonomously in O2- and CO2-sensing neurons
To monitor egl-13 expression, we generated two promoter-driven fluorescent reporters (egl-13prom1::mCherry and egl-13prom1::gfp) that contain 3.5 kb of egl-13 upstream sequence (Figure 2A and Figure S3). Expression is first detected in 4 neuronal cells at around 350 min post-fertilization, which is the time at which the BAG and URX neurons are born (Figure S3). Expression is restricted to these 4 neurons during embryogenesis (Figure S3). At the first larval stage, egl-13 expression is observed in the BAG and URX neurons plus occasionally in a small number of unidentified cells in the head and tail (including the AQR and PQR neurons) (Figure S3). Later during larval development, egl-13 expression is observed in body wall muscle and vulval cells (data not shown). Neuronal expression is restricted to the O2 and CO2-sensing neurons in the adult (Figure 2A). Using the 3.5 kb egl-13 promoter (egl-13prom1) we transgenically expressed egl-13isoformAcDNA in egl-13(ku194) mutant animals and were able to rescue both the defect in O2 and CO2-sensing neuron fate marker expression and the Egl phenotype (Figure 2B–2C, Figure S4 and data not shown). To confirm that egl-13 acts cell autonomously to control O2 and CO2-sensing neuron fate, we used neuron-specific promoters to drive egl-13isoformAcDNA expression in the BAG or URX neurons (Figure 2D). We found that indeed neuron-specific expression of egl-13 rescued the O2 and CO2-sensing neuron fate defect of egl-13(ku194) mutant animals (Figure 2D). Therefore, we conclude that egl-13 acts autonomously in the BAG and URX neurons to direct their fate.
The egl-13 gene has 4 predicted isoforms, all of which contain the same HMG DNA/protein binding domain, however they each have varying lengths of amino terminal tail. Such tails in SoxD proteins can cooperate with other factors to control gene expression [28]. We therefore tested whether the long N-terminal region of EGL-13isoformA is required for its rescuing ability. We used egl-13prom1 to drive EGL-13isoformD (lacking 157 amino acids of the N-terminal tail of isoformA) in egl-13(ku194) animals and found that it fully rescued the defect in O2 and CO2-sensing neuron fate marker expression and the Egl phenotype (Figure S4 and data not shown). Thus, the EGL-13 N-terminal region is not required for its roles in vulval cell nor O2 and CO2-sensing neuron specification. We next asked whether SoxD proteins play specific roles in these decisions by attempting to rescue the egl-13 mutant defects with the SoxB family member, sox-2. We expressed sox-2 cDNA under the control of egl-13prom1 in egl-13(ku194) mutant animals. We found that sox-2 is unable to rescue O2 and CO2-sensing neuron fate marker expression (Figure 2E). These data indicate that the SoxD HMG domain plays a specific role in the specification of O2 and CO2-sensing neuron fate in C. elegans.
egl-13 is required and sufficient to induce O2-sensing neuron fate
We have shown that egl-13 is expressed throughout the life of the worm in the O2 and CO2-sensing neurons; and is required to induce terminal differentiation features. To ask whether egl-13 is required continuously to maintain the expression of the terminal gene battery of these neurons, we sought to postdevelopmentally remove egl-13 gene activity. egl-13 gene activity could not be removed by RNA-mediated interference in an RNAi sensitized background (data not shown) and there are no temperature-sensitive alleles of egl-13 available. Instead, we generated animals that lack endogenous EGL-13 protein but express heat-shock inducible egl-13 cDNA from an extrachromosomal array under the control of the hsp-16.2 promoter (Figure 3). We focused our analysis on the URX neurons and found that the loss of gcy-33prom::gcy-33::gfp reporter expression in egl-13(ku194) worms could be rescued through heat-shock induction of egl-13 during mid-larval stages (Figure 3A). This indicates that O2-sensing neurons generated during embryogenesis persist in an egl-13-responsive state. These neurons are, therefore, not converted into another fate when egl-13 is lost; however, they do not acquire the terminal O2-sensing neuron differentiation program. When egl-13 activity was supplied transiently, through removal of heat-shock stimulus, we observed a gradual loss of reporter expression during adulthood in the URX neurons (Figure 3A). Therefore, egl-13 gene activity is continuously required to maintain URX cell fate. To ask whether misexpression of egl-13 in other neurons is sufficient to induce O2 and CO2 terminal fate we expressed egl-13 under the control of an early neuronal promoter (Figure 3B). We found that egl-13 is indeed sufficient to induce expression of O2 and CO2 terminal fate markers in some cellular contexts (Figure 3B). This suggests that egl-13 is not only required but also sufficient to induce O2 and CO2-sensing neuron fate in specific contexts, which is similar to previous studies of terminal selector genes [29]–[31]. The restricted induction we observed may be dependent on the embryonic time-point of induction or the expression of other unknown co-factors that are required for induction of O2 and CO2-sensing neuron fate.
egl-13 mutants are defective in O2 and CO2 sensing
The crucial role for egl-13 in O2 and CO2-sensing neuron fate determination suggested that egl-13 mutant animals would be defective in O2 and CO2 sensing. We applied three behavioral paradigms that have been previously reported to be specific to either one of these neuron classes: BAG neurons modulate the animals' locomotion speed in response to an oxygen downshift from 21% O2 towards 10% O2 (Figure 4A, 4E) [20]. In addition, BAG neurons detect increases in CO2 concentrations, which trigger reorientation movements (omega turns) (Figure 4G) [11], [21]. URX neurons modulate the animals' locomotion speed in response to O2 upshifts towards 21% O2 (Figure 4A, 4F) [20]. We applied these behavioral assays to test how BAG and URX neurons are functionally affected in egl-13 mutants. We tracked animals in a chamber without food, in an air-flow that switched between 21% O2 and 10% O2, or between 0% CO2 and 1% CO2. In contrast to wild-type animals, egl-13(ku194) mutant animals do not slow their locomotion in response to O2 upshift or downshift (Figure 4A, 4C, 4E, 4F). We found that egl-13(ku194) mutants are also defective in CO2 sensing since they fail to slow or perform omega turns in response to CO2 (Figure 4G). O2 and CO2 behavioral defects of egl-13(ku194) mutants are fully rescued when egl-13 cDNA is resupplied under the control of egl-13prom1 (Figure 4D–4G). These data confirm that egl-13 is crucial for the specification and function of O2 and CO2-sensing system in C. elegans.
The egl-13 promoter contains neuron-specific regulatory modules
One of the egl-13 mutant alleles retrieved from our screen was a promoter deletion mutant (rp23). The rp23 deletion removes 1128 bp of egl-13 promoter from −1700 to −572 upstream of the translational start site (Figure 1A and Figure 5A). Intriguingly, the rp23 mutation affects terminal marker expression in the URX but not BAG sensory neurons and is mostly defective in URX and less affected in BAG regulated behaviors (Figure 4B, 4E–4G; Figure S4C; and Table S1). This suggests that the rp23 promoter deletion removes element(s) required to drive egl-13 in the URX neurons while leaving the BAG-specific element(s) intact. To identify which upstream factors drive expression of egl-13 in the molecularly and functionally distinct BAG and URX neurons we performed promoter deletion analysis, using the 3.5 kb upstream element (egl-13prom1) as a template. We generated transgenic worms expressing truncated versions of egl-13prom1 driving mCherry or gfp protein and focused our expression analysis on BAG and URX regulation (Figure 5A). A 900 bp fragment (egl-13prom3), which includes 360 bp corresponding to the 3′ end of the rp23 deletion, drove expression in BAG and URX. However, a 691 bp fragment (egl-13prom4), which lacks the missing region in the rp23 deletion, only drove expression in the BAG neurons. Therefore, an important element required for egl-13 expression specifically in the URX neurons lies within the 200 bp region included in egl-13prom3. Bioinformatic analysis of this region revealed that there are two conserved motifs that are potential binding sites for EGL-13/SOX5 itself and AHR-1, an aryl hydrocarbon receptor bHLH protein. Interestingly, ahr-1 was previously shown to be required for the expression of some URX terminal fate markers [32]. Site-directed mutagenesis of the predicted AHR-1 binding site significantly reduced egl-13prom1::mCherry expression and a subsequent mutation in the putative EGL-13 binding site further reduced expression (Figure 5A). This suggests that both AHR-1 and EGL-13 regulate egl-13 expression. To test this, we crossed egl-13prom1mCherry/gfp-expressing animals into egl-13(ku194) and ahr-1(ia3) mutants and found that URX expression was reduced in both cases (Figure 5B). Therefore, AHR-1 and EGL-13 both contribute to the control of egl-13 expression in the URX neurons.
To identify the regulatory module(s) that control egl-13 expression in the BAG neurons, we continued to dissect the egl-13 promoter. We identified a 432 bp region (egl-13prom5.1), immediately upstream of the ATG codon, which is sufficient to drive expression in the BAG neurons. Intriguingly, we found two conserved ETS-5/Pet1 binding sites in this region (Figure 5). Previous work identified ETS-5 as a crucial factor required for the specification of the BAG neurons, suggesting that ETS-5 may regulate egl-13 expression in these neurons [26], [33]. We used site-directed mutagenesis to eliminate the ETS-5/Pet1 binding sites individually and in combination, and found that when both ETS-5/Pet1 binding sites are mutated the expression of egl-13 is abrogated in the BAG neurons (Figure 5A). This suggests that ETS-5 directly regulates the expression of egl-13 in the BAG neurons via conserved binding sites. We crossed the ets-5(tm1734) mutant into the egl-13prom1::mCherry strain and indeed found that BAG expression was affected (Figure 5B). In addition, we found that egl-13 can regulate its own expression in the BAG neurons independently of ets-5 via an, as yet, unidentified mechanism (Figure 5B).
Taken together, these data indicate that control of egl-13 expression is coordinated by two independent regulatory mechanisms. In the O2-sensing URX neurons, egl-13 expression is predominantly regulated by AHR-1 (Figure 5C). In contrast, an independent promoter module controlled by ETS-5 regulates egl-13 expression in the O2/CO2-sensing BAG neurons (Figure 5C). In addition, egl-13 is able to autoregulate in both the URX and BAG neurons (Figure 5C).
egl-13 acts in partially parallel pathways with ets-5 and ahr-1
Previous work has identified ets-5 and ahr-1 as regulators of BAG and URX specification respectively [26], [32], [33] and we have shown that these factors are predominantly required to drive egl-13 expression in these cells. To understand how these factors function together to coordinate BAG and URX specification, we analyzed the expression of terminal fate markers in single and double mutant combinations, where appropriate. We analyzed three URX markers (flp-8::gfp, flp-19::gfp and gcy-33prom::gcy-33::gfp) and six BAG markers (flp-13::gfp, flp-17::gfp, flp-19::gfp, gcy-9::gfp, gcy-31::gfp and gcy-33prom::gcy-33::gfp) and compared the effect of the individual loss of egl-13, ets-5 and ahr-1 (Figure S5).
The first observation from this analysis was that the expression of a subset of terminal differentiation markers is completely dependent on egl-13 and one of the other factors acting in a linear pathway. For example, we find that BAG expression of flp-13::gfp and flp-19::gfp is almost 100% affected in both the egl-13 and ets-5 single mutants (Figure S5). This suggests that for these markers egl-13 and ets-5 act in the same pathway to drive marker expression. In contrast, expression of gcy-9::mCherry is completely dependent on ets-5 with egl-13 playing a minor role in its regulation (Figure S5). At the other end of the spectrum, ets-5 and egl-13 are minimally required to drive gcy-31::mCherry expression in the BAG neurons suggesting other factor(s) control the expression of this terminal fate marker (Figure S5). Taken together, these data indicate that egl-13 and ets-5 act in partially parallel pathways to drive BAG cell fate and that other unknown factors possibly act in a combinatorial manner to drive specific aspects of BAG fate.
We also observed differential effects of egl-13 loss with URX terminal fate markers. Expression of the flp-8::gfp reporter is partially affected by single loss of egl-13 and ahr-1, whereas loss of both genes totally abrogates expression, suggesting that egl-13 and ahr-1 act in parallel pathways to regulate flp-8::gfp expression (Figure S5). However, in the case of flp-19::gfp, loss of egl-13 causes complete loss of expression and ahr-1 plays a minor role in its regulation (Figure S5).
To further investigate the regulatory relationship between egl-13, ets-5 and ahr-1 we analyzed how they affect the expression of each other. We have already shown that ets-5 positively regulates the expression of egl-13 in the BAG neurons (Figure 5B). In a reciprocal experiment, we found that ets-5::gfp expression is unaffected in egl-13(ku194) mutant animals (Figure 5B). These data and other work [26], [33] suggest that ets-5 acts upstream and in parallel to egl-13 to direct BAG cell fate (Figure 5C). In addition, we found that egl-13 is able to regulate its own expression in the BAG neurons, in parallel to ets-5; however, the mechanistic basis of this regulation is unclear (Figure 5B). In the URX neurons, we found that egl-13 and ahr-1 regulate the expression of each other in addition to having autoregulatory capabilities (Figure 5B,C and Figure S5).
Our studies have elucidated a novel function for egl-13, the SoxD homolog, in the specification of distinct classes of O2 and CO2 sensory neurons in C. elegans. We show that egl-13 is expressed in the O2- and CO2-sensing neurons and acts cell-autonomously to regulate their distinct cell fates. We further show that egl-13 is continuously expressed in the O2- and CO2-sensing system to maintain the expression of terminal features of these neurons. In certain cellular contexts, egl-13 is also sufficient to induce O2- and CO2-sensing neuron cell fate. We found that the regulatory inputs controlling the expression of egl-13 in the O2- and CO2-sensing system are mechanistically distinct. Independent regulatory modules control egl-13 expression in the BAG neurons (CO2 and O2 downshift sensors) versus the URX neurons (O2 upshift sensors). Interestingly, we found that egl-13 expression in the BAG neurons is controlled by the ETS-5 transcription factor via conserved ETS binding sites. In contrast, in the URX neurons, egl-13 expression is controlled by the bHLH transcription factor AHR-1 via a conserved AHR1 binding site.
The influence EGL-13 exerts on the expression of the terminal gene batteries of the distinct O2- and CO2-sensing neurons is diverse. Particular factors are exquisitely sensitive to loss of egl-13, whereas others are only partially affected. These findings suggest that alternative unknown modes of regulation are in place to ensure that particular molecules are faithfully expressed in the O2 and CO2 sensory neurons, which work in conjunction with and/or in parallel to egl-13.
Sox transcription factors have diverse functions during development and play crucial roles in regulating neuronal fate [34]–[37]. In addition, Sox proteins act at different levels to preselect neuronal genes in embryonic stem cells and to direct the activation of these genes in neuronal precursors and fully differentiated neurons [38]. Here we describe a novel role for EGL-13, the SoxD transcription factor in C. elegans, in driving the specification of different but related sensory neuron identities. Closely related orthologs of EGL-13 are found in vertebrates, some of which are expressed in sensory neurons [39], therefore; SoxD proteins may have a previously unrecognized conserved function in the specification of gas-sensing neurons in higher organisms.
Materials and Methods
Strains used in this study
Strains were grown using standard growth conditions on NGM agar at 20°C on Escherichia coli OP50 [8], [40]. Transgenic animals were created according to [41]. Strain information is detailed in Table S2.
Forward genetic screening approaches
In all screens, animals were mutagenized with EMS (ethyl methanesulfonate) according to standard protocols [42]. Worms were incubated at 25°C at all times. In the manual screens, 5 parental (P0) mutagenized animals were placed in each of 10 founder plates. Three days later, 400 F1 progeny of the mutagenized P0 animals were singled. Their ensuing F2 progeny were screened under a fluorescence stereomicroscope.
In the automated worm sorter screen, around 100,000 synchronized larval stage L4 animals were mutagenized with EMS, the following day the P0 young adult animals were bleached and their F1 progeny synchronized at larval stage L1 by starvation (approximately 1,000,000 animals). F1 animals were grown to the young adult stage, bleached and their F2 progeny synchronized at larval stage L1 by starvation (approximately 10,000,000 animals). The F2 progeny were grown until larval stage L4 and 10% of the population (approximately 1,000,000) was passed through a COPAS biosorter (Karolinska Institute, Stockholm, Sweden).
C. elegans expression constructs and generation of transgenic worms
Reporter gene constructs were generated by PCR amplifying promoter elements and cloning into the pPD95.75-mCherry and gfp vectors (Fire Vector Kit). Mutagenesis was performed using the QuikChange II XL Site-Directed Mutagenesis Kit (Stratagene). Rescue constructs were generated by cloning promoter and cDNA sequences into the pPD49.26 expression vector (Fire Vector Kit). Constructs were injected into young adult hermaphrodites as either simple arrays (gcy-33prom::gcy-33::gfp (50 ng ul−1) and pRF4 (50 ng ul−1) as injection markers) or as complex arrays using 1–10 ng ul−1 of linearized plasmid, 150 ng ul−1 of PvuII-digested bacterial genomic DNA and myo-2prom::dsRed (3–5 ng ul−1), elt-2prom::gfp (3–15 ng ul−1) as injection markers.
Behavioral assays
Animals were transferred without food to 14 cm NGM assay plates containing a cut out arena of Whatman filter paper soaked in 20 mM CuCl2 to prevent them from leaving a 56 mm×56 mm center area. Sixty to seventy animals were used in a single experiment and starved for one hour prior to examination. Each experiment was carried out three times, except for wild-type, which was performed six times. A custom-made transparent plexiglass device with a flow arena of 60 mm×60 mm×0.7 mm was placed onto the assay arena and animals were accustomed to a gas flow of 100 ml/min containing 21% (v/v) oxygen for 5 minutes. During the assays animals were exposed for 6 minutes to 21% O2 before and after a 6 minute stimulus interval of either 10% O2 or 1% CO2 (+21% O2). All gas mixtures were balanced with N2. Gases were mixed with a static mixing element connected to mass flow controllers (Vögtlin Instruments) that were operated by LabView software. Recordings of freely behaving animals illuminated with flat red LED lights were made at 3 fps on a 4 megapixel CCD camera (Jai) using Streampix software (Norpix). Movies were analyzed by MatLab-based image processing and tracking scripts as previously described [43], [44]. The resulting trajectories were used to calculate instantaneous speed during continuous forward movements (1 second binning). Omega turns were detected based on characteristic changes in object eccentricity and their frequency was calculated in 15 second bins. For quantifications, relative speed changes were calculated between representative intervals of 120 seconds before (basal level) and 4 seconds after the stimulus, capturing the minimum speed levels (4–8 seconds post stimulus). Data were normalized to the basal level. Changes in omega turn frequency were calculated between representative intervals of 180 seconds before (basal level) and 60 seconds after the stimulus, to capture the maximum rise phase (55–115 seconds post stimulus).
Heat-shock experiments
Two transgenic lines for hsp-16.2::egl-13 were used for the heat-shock experiments. For the rescue and maintenance experiments, third larval stage (L3) worms were heat shocked at 37°C two times for 30 min. After heat shock, worms were kept at 25°C overnight and then transferred to 15°C for 2 days.
Microscopy
Worms were mounted on 5% agarose on glass slides and images were taken using an automated fluorescence microscope (Zeiss, AXIO Imager M2) and MicroManager software (version 3.1).
Neuronal scoring
Neurons were given a numerical value according to their expression levels. Wild-type expression scored 1, decreased expression scored 0.5 and abolished expression scored 0. Percentage of GFP expressing animals was then correlated to the theoretical maximum score using the equation below.
Bioinformatic analysis
The Jaspar program (http://jaspar.genereg.net/) was used to predict the transcription factor binding sites in the egl-13 upstream regulatory sequence.
Statistical analysis
Statistical analysis was performed in GraphPad Prism 5 using one-way ANOVA with Newman-Keuls Multiple Comparison Test. Values are expressed as mean ± s.d. Differences with a P value<0.05 were considered significant. For the behavioral assays statistical significance was determined using one-way ANOVA with Bonferroni's Multiple Comparison Test.
Supporting Information
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Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2013 Číslo 5
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