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. 2011 Jan 27;6(1):e16561. doi: 10.1371/journal.pone.0016561

The Thioredoxin TRX-1 Modulates the Function of the Insulin-Like Neuropeptide DAF-28 during Dauer Formation in Caenorhabditis elegans

Juan Carlos Fierro-González 1, Astrid Cornils 2, Joy Alcedo 2, Antonio Miranda-Vizuete 3,4,*,#, Peter Swoboda 1,*,#
Editor: Ellen Nollen5
PMCID: PMC3029385  PMID: 21304598

Abstract

Thioredoxins comprise a conserved family of redox regulators involved in many biological processes, including stress resistance and aging. We report that the C. elegans thioredoxin TRX-1 acts in ASJ head sensory neurons as a novel modulator of the insulin-like neuropeptide DAF-28 during dauer formation. We show that increased formation of stress-resistant, long-lived dauer larvae in mutants for the gene encoding the insulin-like neuropeptide DAF-28 requires TRX-1 acting in ASJ neurons, upstream of the insulin-like receptor DAF-2. Genetic rescue experiments demonstrate that redox-independent functions of TRX-1 specifically in ASJ neurons are needed for the dauer formation constitutive (Daf-c) phenotype of daf-28 mutants. GFP reporters of trx-1 and daf-28 show opposing expression patterns in dauers (i.e. trx-1 is up-regulated and daf-28 is down-regulated), an effect that is not observed in growing L2/L3 larvae. In addition, functional TRX-1 is required for the down-regulation of a GFP reporter of daf-28 during dauer formation, a process that is likely subject to DAF-28-mediated feedback regulation. Our findings demonstrate that TRX-1 modulates DAF-28 signaling by contributing to the down-regulation of daf-28 expression during dauer formation. We propose that TRX-1 acts as a fluctuating neuronal signaling modulator within ASJ neurons to monitor the adjustment of neuropeptide expression, including insulin-like proteins, during dauer formation in response to adverse environmental conditions.

Introduction

Thioredoxins comprise a conserved family of proteins characterized by the so-called thioredoxin fold and the highly conserved cysteine–glycine–proline–cysteine (CGPC) catalytic active site (reviewed in [1], [2]). The two cysteines in the active site of thioredoxin are required for the reversible reduction of disulfide bonds in many target proteins. The functions of thioredoxins are extensive and mostly depend on their disulfide oxidoreductase attributes; in general, they can act as electron donors for metabolic enzymes, as antioxidants, or as redox regulators of signaling molecules and transcription factors (reviewed in [1]).

In some cases, thioredoxins have been reported to execute their specific functions in a redox-independent manner (reviewed in [2], [3]). For instance, the regulation of phage T7 DNA polymerase activity by E. coli Trx1 [4], [5], the cytokine function of human truncated thioredoxin (Trx80) [6], or the regulation of apoptosis signaling kinase 1 (ASK1) by human Trx1 [7], among others, are all functions carried out independently of their oxidoreductase activity. More recently, thioredoxins have also been shown to promote folding of proteins independently of their redox activities (reviewed in [3]).

In the nematode Caenorhabditis elegans, the gene trx-1 encodes a thioredoxin found to be expressed in the ASJ sensory neuron pair [8], [9]. These neurons are implicated in the regulation of aging, the response to stress conditions and the control of a state of developmental arrest called the dauer larva [10], [11], [12]. Previously, we and others have shown that trx-1 deletion shortens lifespan and increases sensitivity to oxidative stress, though it itself does not affect dauer formation [8], [9]. These findings implicate TRX-1 in processes that regulate aging and stress resistance, which raises the question whether it is involved in mechanisms implicated in the regulation of dauer formation.

The C. elegans dauer larva has evolved as a tightly-regulated, long-lived and stress-resistant developmental stage only triggered when the animals encounter harsh environmental conditions [13]. However, under circumstances in which genes involved in dauer development become inactivated due to mutations, animals arrest as dauers even under favorable conditions (dauer formation constitutive or Daf-c phenotype) [14]. Among the known daf-c genes whose functions are linked to ASJ, four have previously been well characterized for their role in the dauer formation pathway: daf-11 (abnormal dauer formation-11), daf-28, tax-2 (abnormal chemotaxis-2) and tax-4 (Figure S1; [12], [15], [16], [17], [18]). Moreover, mutations in these four daf-c genes have also been reported to extend lifespan [19], [20], [21], providing an additional link between dauer formation and aging. daf-11 encodes a transmembrane guanylyl cyclase, while tax-2 and tax-4 encode subunits of a cyclic guanosine monophosphate (cGMP)-gated ion channel; these three genes are expressed in subsets of amphid sensory neurons, including ASI and ASJ [15], [22]. DAF-11 regulates dauer formation by modulating the levels of cGMP in these neurons, to which TAX-2/TAX-4 respond [22], which then regulate the expression of transforming growth factor-beta (TGF-beta) [23] and insulin-like neuropeptides [18], [24] (Figure S1). There are ∼40 insulin-like neuropeptides in C. elegans (www.wormbase.org), and several, including DAF-28, have been reported to be produced in ASJ, among other neurons [18], [24]. To gain insight into whether TRX-1 plays a role in dauer formation in C. elegans, we analyzed at the cellular and genetic level its interaction with daf-c genes co-expressed in ASJ neurons.

We have identified the C. elegans thioredoxin TRX-1 as a novel modulator of the insulin-like neuropeptide DAF-28 during dauer formation. We found that trx-1 suppresses the Daf-c phenotype of all daf-28 insulin-like mutant alleles tested and that this suppression requires a functional DAF-2 insulin-like receptor. Genetic rescue experiments demonstrated that redox-independent functions of transgenic TRX-1 provided specifically in ASJ neurons can restore the suppression exerted by trx-1 deletion on the Daf-c phenotype of daf-28 mutants. The suppression observed at the genetic level is also manifest at the cellular level specifically during dauer formation: GFP reporters of trx-1 and daf-28 display opposing expression patterns in dauers, which is in contrast to what is observed in growing L2/L3 larvae. Moreover, functional TRX-1 is required for the down-regulation of a GFP reporter of daf-28 during dauer formation, a mechanism that is likely mediated by DAF-28-dependent feedback regulation. Our data suggest that TRX-1 contributes to the regulation of insulin-like neuropeptide expression, in particular DAF-28, during dauer formation in response to a changing environment.

Results

trx-1 has a novel synthetic dauer formation constitutive (Daf-c) phenotype

To investigate whether trx-1 plays a role in dauer formation, we first constructed double mutant combinations with different alleles of daf-11, since this gene is predicted to regulate dauer formation upstream of both the TGF-beta and insulin-like signaling (IS) pathways (Figure S1; [18], [23]). Previously, it has been suggested that ASJ neurons are required for the daf-11 Daf-c phenotype, since laser ablation of ASJ suppresses the Daf-c phenotype of a daf-11(sa195) mutant [12]. We tested whether trx-1 is also required for the daf-11 Daf-c phenotype. The trx-1(ok1449) allele used in this study is a null mutation: a deletion in the coding region preventing translation of the protein (Table S1; [9]). trx-1(ok1449) enhanced the Daf-c phenotype of all daf-11 alleles tested at 15°C (Figure 1A and Table 1). Even at 25°C, two of the three daf-11 alleles tested showed a significant increase in dauer formation (Figure 1B and Table 2). Thus, trx-1 has a novel synthetic Daf-c phenotype. In addition, the slight suppression of the daf-11(sa195) Daf-c phenotype exerted by trx-1(ok1449) at 25°C (Figure 1B and Table 2), partially phenocopies the effect of killing ASJ in a daf-11(sa195) single mutant background [12]. Together, our findings indicate that most of the Daf-c phenotype of daf-11 mutants is TRX-1-independent, while a small fraction requires TRX-1. This dual effect of the trx-1 mutation on daf-11 for dauer formation is reminiscent, although not identical, to that reported for mutations in the cGMP-gated ion channel genes tax-2 and tax-4 [16]. tax-2 and tax-4 mutants show weak Daf-c phenotypes, which are epistatic to the strong daf-11 Daf-c phenotypes [16]. trx-1 deletion did not affect the weak Daf-c phenotype caused by tax-4(p678) (Figures 1A and 1B; Tables 1 and 2). Since mutations in tax-4 essentially remove the input from daf-11 signaling for dauer formation [16], trx-1 deletion could not replicate the synthetic interaction observed with daf-11 mutants. These results further support the notion of tax-4 acting downstream of daf-11 for dauer formation [16], with trx-1 acting mostly independently of daf-11 in the dauer formation pathway. We speculate that for the most part TRX-1 and DAF-11 are affecting a separate set of neurons for dauer formation (e.g. TRX-1 in ASJ and DAF-11 in ASI) (this work; [23]), while they share some modulatory functions in ASJ neurons.

Figure 1. Redox-independent functions of TRX-1 in ASJ neurons modulate DAF-28 signaling during dauer formation.

Figure 1

Dauer formation at 15°C (A) and 25°C (B) is shown for each of the daf-c mutant alleles tested in a trx-1(+) wild-type background (white bars) or in combination with a trx-1(ok1449) deletion null mutant allele (black bars). (C) Rescue of the suppression of the Daf-c phenotype in trx-1(ok1449); daf-28(sa191) transgenic animals (patterned bars) expressing either Ptrx-1::trx-1::GFP, Pssu-1::trx-1::GFP, Ptrx-1::trx-1(SGPS)::GFP, Pgpa-4::trx-1::GFP, Pges-1::trx-1::GFP or Ptrx-1::GFP. The cellular site of expression for each transgenic extrachromosomal array is outlined above the graph in panel C. The non-transgenic control represents the average of all assays performed with non-transgenic progeny that segregated from the same transgenic parents (dotted line) ± standard error of the mean (SEM, horizontal gray line). The white bar corresponding to the daf-28(sa191) single mutant in panel C, has been taken from panel B for comparison. In all three panels, each bar represents the average of 2–3 independent assays ± SEM, with more than 165 animals assayed in total per genotype. * p<0.05, ** p<0.01, § p<0.05 relative to trx-1(ok1449); daf-28(sa191), §§ p<0.01 relative to trx-1(ok1449); daf-28(sa191), and ++ p<0.001 relative to non-transgenic animals, by chi-squared test (see also Tables 1, 2 and 3). na: not assayed. The molecular identities of all mutant alleles presented here are shown in Table S1.

Table 1. Percent dauer formation at 15°C of trx-1; daf-c double and triple mutants.

trx-1(+) trx-1(ok1449)
Genotype % ± SEM N % ± SEM N
wild type 0±0 478 0±0 442
daf-11(ks67) ** 0±0 357 92±2 300
daf-11(m47) ** 8±3 586 98±1 333
daf-11(sa195) * 31±4 412 59±8 172
tax-4(p678) 2±1 420 0±0 511
daf-7(e1372) ** 63±4 1257 95±1 754
daf-1(e1287) ** 13±3 451 51±6 485
daf-8(e1393) ** 21±3 1826 44±2 1281
daf-2(e1370) 0±0 388 0±0 333
daf-2(e1368) 0±0 280 0±0 167
daf-2(m577) 0±0 250 0±0 187
pdk-1(sa680) 37±4 863 44±4 627
daf-28(tm2308) ** 26±3 617 0±0 578
daf-28(sa191) 39±4 318 26±8 238
daf-2(e1370); daf-28(sa191) § na na 38±1 365

Mean percentage of dauer larvae ± standard error of the mean (SEM); 3 assays per genotype, except for wild type, tax-4(p678), daf-28(tm2308), daf-2(e1368), daf-2(m577) and the triple mutant: 2 assays. N: total (pooled) number of animals.

**p<0.01;

*p<0.05 by chi-squared test.

§

p<0.05 by chi-squared test with respect to trx-1(ok1449); daf-28(sa191). na: not assayed.

Table 2. Percent dauer formation at 25°C of trx-1; daf-c double and triple mutants.

trx-1(+) trx-1(ok1449)
Genotype % ± SEM N % ± SEM N
wild type 0±0 659 0±0 661
daf-11(ks67) ** 31±5 547 99±1 422
daf-11(m47) ** 78±5 421 100±0 474
daf-11(sa195) ** 97±1 595 82±2 221
tax-4(p678) 2±1 853 2±0 931
daf-2(e1370) 96±2 435 96±0 466
daf-2(e1368) 92±1 356 89±1 349
daf-2(m577) 100±0 621 100±0 501
pdk-1(sa680) 73±3 980 76±1 1196
daf-28(tm2308) ** 18±2 781 2±0 570
daf-28(sa191) ** 85±6 445 18±5 427
daf-2(e1370); daf-28(sa191) §§ na na 96±3 368

Mean percentage of dauer larvae ± standard error of the mean (SEM); 3 assays per genotype, except for wild type, tax-4(p678), daf-2(e1368) and the triple mutant: 2 assays. N: total (pooled) number of animals.

**p<0.01 by chi-squared test.

§§

p<0.01 by chi-squared test with respect to trx-1(ok1449); daf-28(sa191). na: not assayed.

trx-1 deletion enhances the Daf-c phenotype of mutations in the TGF-beta signaling pathway

There is evidence that DAF-11 acts upstream of the IS and TGF-beta signaling pathways (Figure S1; reviewed in [25], [26]). To determine if trx-1 interacts with any of these two genetic pathways for dauer formation, we first scored for dauers in double mutants containing trx-1(ok1449) and daf-c mutations in the TGF-beta signaling pathway. Previously, strong synergy was identified between daf-c mutations in several genes of the IS pathway, including daf-2 and daf-28, and mutations in genes of the parallel TGF-beta signaling pathway, represented here by daf-7, daf-1 and daf-8 [21], [27]. We observed a marked increase in dauer formation in all three trx-1;TGF-beta double mutant combinations tested at 15°C (Figure 1A and Table 1). A straightforward interpretation of this synthetic enhancement observed is that the Daf-c phenotype of mutations in the TGF-beta signaling pathway is TRX-1-independent. Since TGF-beta single mutants already form nearly 100% dauers at 25°C ([28]; data not shown), trx-1;TGF-beta double mutants did not display any further increase in dauer formation at that temperature (data not shown). We conclude that TRX-1 acts independently of the TGF-beta signaling pathway for dauer formation.

TRX-1 function is needed for the Daf-c phenotype of daf-28 mutants

To investigate the interaction of trx-1 with the IS pathway for dauer formation, we first analyzed double mutants of trx-1 with daf-28. trx-1 suppressed the Daf-c phenotype of the two daf-28 alleles tested (Figures 1A and 1B; Tables 1 and 2), regardless of their nature (sa191 is a dominant-negative allele; tm2308 is predicted to be null) (Table S1). These results indicate that the suppression is not allele-specific and that the Daf-c phenotype of daf-28 mutants requires TRX-1 function for dauer formation. Our findings suggest that loss of TRX-1 function likely increases insulin-like signaling upon mutation of daf-28.

Suppression of the daf-28 Daf-c phenotype by trx-1(ok1449) depends on DAF-2 insulin-like receptor signaling

To test whether the ability of trx-1(ok1449) to suppress the Daf-c phenotype of daf-28(sa191) depends on functional DAF-2, we first analyzed dauer formation in double mutants containing the trx-1(ok1449) deletion and hypomorphic (partial loss-of-function) mutant alleles of daf-2 or pdk-1. The latter encodes a homologue of the mammalian Akt/PKB kinase PDK1, involved in transducing DAF-2 signals on to the DAF-16 FOXO transcription factor to regulate dauer formation (Figure S1; [29]). Deletion mutations of daf-16 and daf-18 (the latter encoding a homologue of the mammalian PTEN tumor suppressor), which act downstream of daf-2 for dauer formation, suppress the Daf-c phenotype of daf-2 mutants [27], [30], [31]. In addition, RNA interference of the gene pptr-1 (encoding a homologue of a B56 regulatory subunit of the mammalian PP2A holoenzyme), which acts downstream of both daf-2 and pdk-1 for dauer formation, suppresses the Daf-c phenotypes of both daf-2 and pdk-1 mutants [32]. Thus, if TRX-1 acted downstream of DAF-2 and PDK-1, we would expect a suppressive effect of trx-1(ok1449) on the Daf-c phenotypes of either daf-2 or pdk-1 mutants. However, trx-1 deletion did not suppress the Daf-c phenotypes of three different hypomorphic daf-2 mutants or of one pdk-1 mutant at 15 and 25°C (Figures 1A and 1B; Tables 1 and 2). Moreover, at the intermediate temperature of 20°C, trx-1 deletion did not suppress the Daf-c phenotype of daf-2(e1370) animals: the percent dauer formation ± standard error of the mean was 26±4 for daf-2(e1370) and 21±1 for trx-1(ok1449); daf-2(e1370), with n>300 animals in total per genotype (p>0.1 by chi-squared test; 2 assays). Together, these data suggest that TRX-1 functions upstream of or in parallel to both DAF-2 and PDK-1 for dauer formation. To investigate whether the suppression of the daf-28 Daf-c phenotype by trx-1(ok1449) depends on DAF-2 signaling, we constructed the triple mutant trx-1(ok1449); daf-2(e1370); daf-28(sa191). If the suppression of daf-28(sa191) by trx-1(ok1449) was independent of DAF-2 signaling, we would expect the triple mutant to form dauers at levels comparable with those of trx-1(ok1449); daf-28(sa191) double mutant animals, indicating that the suppression still persists even after mutation of daf-2. However, trx-1(ok1449); daf-2(e1370); daf-28(sa191) triple mutant animals formed dauers at levels that were similar to those of daf-28(sa191) single mutant animals, at both 15 and 25°C (Figure 1A and 1B; Table 1 and 2), suggesting that the suppression is no longer effective when daf-2 is mutated. Therefore, although genetic interactions using non-null mutants (cf. Table S1) need to be interpreted with some caution, these data demonstrate that the ability of trx-1(ok1449) to suppress the Daf-c phenotype of daf-28(sa191) depends on functional DAF-2.

Redox-independent functions of transgenic TRX-1 specifically in ASJ neurons restore the suppression of daf-28(sa191) by trx-1(ok1449)

To investigate whether wild-type TRX-1 can restore the suppression of the daf-28(sa191) Daf-c phenotype caused by trx-1 deletion at 25°C, the transgene Ptrx-1::trx-1::GFP (see Materials and Methods) was used to transform trx-1(ok1449); daf-28(sa191) animals. Transgenic lines expressing this transgene restored the Daf-c phenotype back to daf-28(sa191) single mutant levels (Figure 1C and Table 3). Since the GFP-tagged transgene can be visualized in ASJ, this is in agreement with the hypothesis that wild-type trx-1 acts in ASJ neurons to modulate DAF-28 signaling during dauer formation. To confirm this notion, the expression of wild-type trx-1 genomic DNA fused to GFP was driven from another ASJ neuron-specific promoter, ssu-1 [33]. Consistent with our hypothesis, this transgene Pssu-1::trx-1::GFP also rescued the suppression of the Daf-c phenotype of daf-28(sa191) by trx-1(ok1449) (Figure 1C and Table 3).

Table 3. Percent dauer formation at 25°C of trx-1(ok1449); daf-28(sa191) double mutants expressing the indicated transgene.

Transgenic animals Non-transgenic animals
Transgene Transgenic line % ± SEM N % ± SEM N
Ptrx-1::trx-1::GFP ++ 1 80±1 284 39±3 397
2 82±3 245 48±7 395
3 66±2 252 23±1 363
Pssu-1::trx-1::GFP ++ 1 74±4 441 43±14 471
2 78±1 514 46±3 496
Ptrx-1::trx-1(SGPS)::GFP ++ 1 81±3 271 35±6 305
2 86±3 316 41±1 385
3 66±6 226 21±5 376
Pgpa-4::trx-1::GFP 1 53±14 424 34±9 531
2 36±10 502 38±9 472
3 34±9 450 28±7 616
Pges-1::trx-1::GFP 1 40±12 518 37±6 503
2 46±13 501 39±6 507
Ptrx-1::GFP 1 43±8 474 30±12 470
2 48±7 339 30±10 479
3 34±8 455 31±9 541

Mean percentage of dauer larvae ± standard error of the mean (SEM); 2 assays per transgenic line, except for Ptrx-1::GFP and Pgpa-4::trx-1::GFP: 3 assays. N: total (pooled) number of animals.

++

p<0.001 by chi-squared test.

C. elegans TRX-1 shares many conserved residues with its thioredoxin orthologues throughout evolution [9], including the active site, which has extensively been demonstrated to be essential for its oxidoreductase activity in bacteria [5], yeast [34], fruit fly [35], and in humans [36]. To investigate whether the redox activity of TRX-1 is necessary for rescue of trx-1(ok1449); daf-28(sa191) double mutants, we transformed these animals with Ptrx-1::trx-1(SGPS)::GFP, a transgene containing the mutated active site SGPS instead of the wild-type CGPC. The conversion of thioredoxin active-site cysteines to serines has been widely shown to eliminate its ability to function as oxidoreductase in classical reduction assays [5], [36], [37]. Interestingly, transgenic animals expressing the mutated transgene Ptrx-1::trx-1(SGPS)::GFP restored the Daf-c phenotype just as Ptrx-1::trx-1::GFP did (Figure 1C and Table 3), indicating that TRX-1 function in dauer formation does not require its oxidoreductase activity.

In contrast, the Daf-c restoration rescue could not be achieved when trx-1(ok1449); daf-28(sa191) double mutants either expressed a transgene containing the ASI neuron-specific gpa-4 promoter [38] with the complete coding region of wild-type trx-1 fused to GFP (Pgpa-4::trx-1::GFP), a transgene that drives expression of wild-type trx-1::GFP from the ges-1 promoter in the intestine (Pges-1::trx-1::GFP) [39] or a transgene that only drives GFP expression from the trx-1 promoter in ASJ neurons (Ptrx-1::GFP) (Figure 1C and Table 3). Together, these findings suggest that redox-independent functions of TRX-1 specifically in ASJ neurons are required for the Daf-c phenotype caused by defects in daf-28 function.

TRX-1 contributes to the down-regulation of daf-28 expression during dauer formation, a process likely controlled by DAF-28-mediated feedback regulation

Previously, it was shown that Pdaf-28::GFP expression in dauers is down-regulated by conditions of starvation and exposure to dauer pheromone [18]. To test whether trx-1 expression responds to these dauer-promoting signals, we analyzed Ptrx-1::GFP expression in both wild-type natural dauers, which are induced by a combination of both signals, and in daf-c mutant dauers, represented here by daf-11 and daf-2. Since trx-1 suppresses the Daf-c phenotype of daf-28 mutants (cf. above), one could expect that the response of Ptrx-1::GFP levels to dauer-promoting signals might be opposite to that of Pdaf-28::GFP. Consistent with our hypothesis, Pdaf-28::GFP was down-regulated and Ptrx-1::GFP was up-regulated in wild-type natural dauers, and in daf-11 and daf-2 mutant dauers (Figures 2A and 2C). In contrast, these opposing expression levels observed in dauers were not seen in well-fed, growing L2/L3 larvae of the corresponding genotypes (Figure S2), suggesting a possible regulatory effect of TRX-1 on DAF-28 (or vice versa) only during dauer formation. Therefore, to test whether TRX-1 function contributes to the down-regulation of daf-28 expression during dauer formation, we analyzed Pdaf-28::GFP expression in trx-1 mutant dauers. If the down-regulation of daf-28 expression during dauer formation was independent of TRX-1, we would expect trx-1 mutant dauers to express Pdaf-28::GFP at levels comparable with those of wild-type natural dauers (cf. Figure 2A), indicating that the down-regulation still persists even after loss of trx-1. Interestingly, we observed that Pdaf-28::GFP expression in trx-1 mutant dauers is not down-regulated, but is in fact not significantly different from what is seen in well-fed, growing L2/L3 wild-type larvae (Figures 2B and 2D). These findings suggest that the up-regulation of TRX-1 specifically during dauer formation is, at least in part, causative of a reduction in DAF-28 signaling. Moreover, the up-regulation of Ptrx-1::GFP expression in daf-28 mutant dauers (Figures 2B and 2D), is further increased when compared with that seen in wild-type natural dauers (cf. Figures 2A and 2C). This result suggests that trx-1 up-regulation during dauer formation is likely subject to DAF-28-mediated feedback regulation. Together, these results are consistent with a model (Figure 3) in which TRX-1 modulates DAF-28 signaling by contributing to the down-regulation of daf-28 expression exclusively during dauer formation, a modulatory process that is likely controlled by DAF-28-dependent feedback regulation.

Figure 2. TRX-1 contributes to the down-regulation of daf-28 insulin-like gene expression during dauer formation.

Figure 2

Quantification of Ptrx-1::GFP and Pdaf-28::GFP expression in dauers and well-fed, growing L2/L3 larvae in ASJ or ASI neurons. Average fluorescence intensity in ASJ or ASI neurons, normalized to that of well-fed, growing L2/L3 wild-type larvae, is shown for wild-type dauers and for daf-2 and daf-11 mutant dauers in (A), and for trx-1 and daf-28 mutant dauers in (B). Two independent transgenic lines were examined for each of the two transcriptional Ptrx-1::GFP and Pdaf-28::GFP reporters, and the results were very similar; one transgenic line was tested for daf-28(tm2308) dauers. The data derived from one transgenic line are presented. Each bar represents the average relative fluorescence intensity of 28–34 animals ± standard error of the mean (SEM). ** p<0.01 relative to L2/L3 wild-type larvae, by Student's t test (two-tailed, two-sample unequal variance); na: not assayed; ns: not significant. Shown in (C) and (D) are representative color-inverted images of animals assayed in (A) and (B), respectively, revealing the differences in GFP intensity in ASJ or ASI neurons (boxed). The tip of the head points to the left in all panels.

Figure 3. Model for TRX-1 function during dauer formation.

Figure 3

TRX-1 is a novel modulator of the insulin-like neuropeptide DAF-28 during dauer formation. It modulates DAF-28 signaling, upstream of DAF-2, by specifically contributing to the down-regulation of daf-28 expression during dauer formation; this modulatory process is likely subject to DAF-28-mediated feedback regulation (black dashed line). In addition, TRX-1 possibly affects dauer formation independently of both DAF-28 and DAF-2 by modulating other neuropeptides co-expressed in ASJ neurons (see Results and Discussion for details).

Discussion

Here, we have identified the thioredoxin TRX-1 as a novel modulator of the insulin-like neuropeptide DAF-28 during dauer formation in C. elegans. We found that trx-1 suppresses the Daf-c phenotypes of all daf-28 insulin-like mutant alleles tested, and that this suppression is dependent on a functional DAF-2 insulin-like receptor (Figures 1A and 1B; Tables 1 and 2). Genetic rescue experiments showed that redox-independent functions of TRX-1 specifically in ASJ neurons are needed for the Daf-c phenotype caused by defects in daf-28 function (Figure 1C and Table 3). The suppression observed at the genetic level phenocopied that seen at the cellular level specifically during dauer formation: Ptrx-1::GFP and Pdaf-28::GFP showed opposing expression patterns in dauers (Figures 2A and 2C), which were not observed in growing L2/L3 larvae (Figure S2). In addition, Pdaf-28::GFP down-regulation during dauer formation required functional TRX-1, a mechanism that is likely controlled by DAF-28-dependent feedback regulation (Figures 2B and 2D). Taken together, our results suggest a model in which TRX-1 contributes to the adjustment of daf-28 insulin-like expression, and consequently its function, during dauer formation (Figure 3).

C. elegans neuropeptides are classified into three classes: the insulin-like proteins, the FMRF (Phe-Met-Arg-Phe)-amide peptides (referred to as FLPs) and the neuropeptide-like proteins or NLPs (reviewed in [40]). In addition to DAF-28, it might be possible that TRX-1 also modulates other neuropeptides co-expressed in ASJ neurons (Figure 3), such as the insulin-like proteins INS-9 and INS-1, or NLP-3 and FLP-21 ([24], [41]; reviewed in [40]). If the effect of TRX-1 on dauer formation was solely dependent on DAF-28 signaling, we would expect that overexpression of trx-1 in the likely null mutant daf-28(tm2308) results in no enhancement of the Daf-c phenotype. Interestingly, the observation that overexpression of wild-type trx-1::GFP in ASJ was sufficient to enhance the weak Daf-c phenotype of the likely null mutant daf-28(tm2308) (Table S2), suggests that TRX-1 in part affects dauer formation independently of DAF-28, and potentially independently of DAF-2 (Figure 3). Moreover, the fact that trx-1 deletion, like daf-28(sa191) [21], enhanced the Daf-c phenotype of TGF-beta pathway mutations and of most daf-11 mutations, whereas trx-1 deletion suppressed the Daf-c phenotype of daf-28 mutations (Figures 1A and 1B; Tables 1 and 2), also supports the notion that TRX-1 to some extent modifies dauer formation independently of DAF-28, and possibly also of DAF-2 (Figure 3). Furthermore, because wild-type animals overexpressing wild-type trx-1::GFP in ASJ were not induced to form dauers at 25°C (Table S2), other pathways and/or neurons might act in parallel to contribute, together with TRX-1, to the modulation of DAF-28 signaling. In fact, the cGMP pathway has previously been suggested to regulate DAF-28 signaling during dauer formation (Figure S1; [18]).

ASJ neurons have been shown to regulate dauer formation in concert with other sensory neurons [11], [12], despite their discrete synaptic connectivity (ASK is the only sensory neuron in synaptic contact with ASJ; www.wormatlas.org). The localized function of TRX-1 in ASJ neurons for dauer formation (Figure 1C; Table 3) and the effect of TRX-1 on daf-28 expression (Figures 2B and 2D) support a model wherein TRX-1 modulates (the levels of) neurosecretory signals emanating from ASJ neurons to regulate dauer formation in a cell non-autonomous fashion. Although our results do not exclude that TRX-1 affects other neurons through direct synaptic connections, the control it exerts on neuropeptidergic signaling would allow TRX-1 to function locally in ASJ neurons and affect dauer formation remotely. Such a model would explain the observation that deletion of trx-1 modifies the Daf-c phenotypes of mutations in genes not expressed in ASJ neurons (Figure 1A; Table 1) (e.g. daf-7 is only expressed in ASI neurons) [42]. Similarly, TRX-1 could contribute to the down-regulation of daf-28 expression in ASI, either through ASJ-derived DAF-28 or other TRX-1-modified neuropeptides released from ASJ neurons.

Previously, mammalian Trx1 has been proposed to participate in the redox regulation that mediates insulin secretion via NADPH as a signaling molecule [43]. However, we have shown in this report that TRX-1 function in dauer formation does not require its redox activity (Figure 1C and Table 3), suggesting that TRX-1 contributes to the down-regulation of daf-28 expression during dauer formation via mechanisms other than redox regulation of neuropeptide production and/or release.

It has recently been found in mammals that key neuronal lipid metabolites act as hypothalamic signaling mediators that monitor energy status and contribute to maintaining organism metabolic homeostasis (reviewed in [44]). We propose that the thioredoxin TRX-1 might similarly act as a neuronal modulator in ASJ neurons to monitor metabolic status and thus adjust neuropeptide expression, including the insulin-like neuropeptide DAF-28, during dauer formation in response to adverse conditions (Figure 3). In this context, ASJ neurons would monitor the choice between reproductive development and dauer formation by responding to intra-neuronal fluctuations of TRX-1 (Figure 3). In turn, these TRX-1 fluctuations would be triggered in response to signals from the environment and peripheral tissues that reflect the animal's global energy status. Interestingly, the C. elegans ASI neurons have been suggested to mediate responses to nutrient availability through neuroendocrine signals that promote adult longevity by sensing similar energy-monitoring molecules within them [45]. Moreover, ASJ neurons have been proposed to influence dauer formation through sulfated neuroendocrine signals [33]. Thus, together with previous observations by others, our findings anticipate a neuroendocrine network in the nematode involved in adjusting the animal's global energy status in response to a changing environment, both during development and adulthood. Future work is needed to identify and dissect the components of such a neuroendocrine network that, including TRX-1, are involved in regulating mechanisms designed to monitor energy homeostasis in varying environmental conditions in the nematode, and most likely also in higher organisms.

Materials and Methods

Nematode strains and culture conditions

The standard methods used for culturing C. elegans were described previously ([46]; reviewed in [47]). Strains and transgenes used in this work are summarized in Table S3. All strains were grown at 20°C, except for daf-c mutant strains, which were grown at 15°C.

Transgene injection constructs and germline transformation

The Ptrx-1::trx-1::GFP translational fusion construct (cf. Figure 1C; Tables 3 and S2) and the Pdaf-28::GFP transcriptional fusion construct (cf. Figures 2 and S2) were previously reported [9], [48]. For the Ptrx-1::GFP transcriptional fusion construct (cf. Figures 1C, 2 and S2; Table 3), ∼1 kb of sequence upstream of the trx-1b splice variant, plus the first 65 nucleotides of the coding sequence were amplified by PCR and cloned in-frame with GFP into the pPD95.77 vector. The Ptrx-1::trx-1(SGPS)::GFP translational fusion construct (cf. Figure 1C and Table 3) was obtained by site-directed mutagenesis of the trx-1 active site, as specified in the QuikChange II Site-Directed Mutagenesis Kit (Stratagene), using the Ptrx-1::trx-1::GFP translational fusion construct as a template. The Pssu-1::trx-1::GFP, Pgpa-4::trx-1::GFP and Pges-1::trx-1::GFP translational fusion constructs (cf. Figure 1C and Table 3) included ∼0.5 kb (ssu-1) or ∼2.5 kb (gpa-4 and ges-1) of promoter sequence upstream of the respective start codon fused to the full-length trx-1 genomic DNA fragment, in-frame with GFP, into the pPD95.77 vector. For the experiments shown in Figures 2 and S2, 80 ng/µl of Ptrx-1::GFP or 50 ng/µl of Pdaf-28::GFP were coinjected with 20 ng/µl of the injection marker Pelt-2::mCherry (a gift from Gert Jansen, Rotterdam), into trx-1(ok1449); daf-28(sa191) or trx-1(ok1449) animals. These extrachromosomal arrays were then crossed into wild-type, daf-11(ks67), daf-2(e1370), daf-28(sa191) or daf-28(tm2308) animals. For the rescue experiments shown in Figure 1C and Table 3, 40 ng/µl of Ptrx-1::trx-1::GFP, Pssu-1::trx-1::GFP, Ptrx-1::trx-1(SGPS)::GFP, Pgpa-4::trx-1::GFP, Pges-1::trx-1::GFP or Ptrx-1::GFP were coinjected with 30 ng/µl of the injection marker Punc-122::DsRed [49], into trx-1(ok1449); daf-28(sa191) animals. For the overexpression experiments shown in Table S2, 100 ng/µl of Ptrx-1::trx-1::GFP were coinjected with 30 ng/µl of the injection marker Punc-122::DsRed into wild-type or daf-28(tm2308) animals. Germline transformation was performed as described elsewhere [50].

Construction of double and triple mutants

To construct trx-1; daf-c double mutants, trx-1 homozygous males were crossed to the appropriate daf-c mutant, and F1 cross progeny hermaphrodites were grown singly at 25°C. We singled F2 dauers and allowed them to recover at 15°C. Recovered dauers were considered to be homozygous for the daf-c mutation. To construct the trx-1; tax-4 double mutant, trx-1; daf-2 homozygous hermaphrodites were crossed to tax-4 homozygous males. F2 progeny were grown singly at 25°C from F1 cross progeny. tax-4 homozygous candidates were selected further from F2s that did not segregate dauers at 25°C. To confirm the presence of the tax-4 mutation, we performed a soluble compound chemotaxis assay, as described elsewhere [51]. To construct the triple mutant trx-1(ok1449); daf-2(e1370); daf-28(sa191), we took advantage of the fact that daf-28 dauers recover well at 25°C, whereas daf-2 dauers do not recover or only recover with difficulties at this temperature [21], [52]. In brief, trx-1 homozygous males where crossed to trx-1; daf-2 double mutant hermaphrodites. The resulting male progeny were crossed to trx-1; daf-28 hermaphrodites, and F1 cross progeny hermaphrodites were grown individually at 25°C. We then picked many F2 dauers from several F1s onto new, seeded plates and kept them at 25°C. Those dauers that recovered after ∼14–24 h, were considered to be daf-28 homozygotes. F3 progeny of these daf-28 homozygous candidates that remained arrested as dauers after ∼17–24 h at 25°C were potential daf-2 homozygotes. We singled these dauers and transferred them to 15°C for recovery. We tested all candidates for the presence of the daf-28 and daf-2 mutations by sequencing. In all cases, the presence of the trx-1 deletion was demonstrated by performing PCR on single-worm lysates, based on methods previously described ([53]; reviewed in [54]).

Analysis of dauer formation

For dauer formation assays, 8–20 gravid hermaphrodites were allowed to lay eggs for a given time at the test temperature (Tables S4 and S5), and then removed. Dauers and non-dauers (L3 and L4 larvae and adult animals) on the agar and side of the plate were then counted at specific time points after egg-laying ended (Table S4). The scoring time points were selected for each genotype so that all animals had passed the pre-dauer or L2 stages at the time of scoring. Corresponding single and double mutant strains were always assayed in parallel. In all cases, dauers were discriminated from non-dauers based on the absence of pharyngeal pumping, intestinal re-organization and radial shrinkage of the body [13]. More than 165 animals were counted in a total of 2–3 independent assays per genotype. Dauers of selected key genotypes used in this study were subjected to morphological analysis using differential interference contrast (DIC) microscopy at an optical magnification of x800 or x1000, and also tested for resistance to 1% sodium dodecylsulfate (SDS) [13]. All dauers analyzed were identical to wild-type dauers in their morphological features (i.e. pharynx and alae) and SDS-resistance.

Microscopy and fluorescence imaging

The average relative intensity of a transcriptional Ptrx-1::GFP or Pdaf-28::GFP reporter was assessed by quantifying GFP intensity in ASJ neurons of dauers or growing L2/L3 larvae mutant for a specific daf-c gene as compared to growing L2/L3 wild-type larvae. Animals were visualized on a Zeiss Axioplan fluorescence microscope at an optical magnification of x640. Worms were put into M9 buffer on a very thin 2% agarose pad containing an anesthetic (15 mM NaN3). Previously, it had been shown that exposure to 20 mM NaN3 or less during 60 min [55], ∼30 mM NaN3 for 20 min [56] or 50 mM NaN3 for 5 min [57] can induce evident physiological changes in the worm. All animals assayed in our study have been exposed to only 15 mM NaN3 for a maximum of 10–15 min prior to image acquisition, thereby avoiding the induction of evident physiological changes. A Hamamatsu CCD camera and Openlab software (Improvision) were used for image acquisition at the brightest focal plane and a fixed exposure time. Pixel intensity in the entire ASJ cell body was determined from captured images in the form of maximum gray values by using NIH ImageJ software. An exception was made for Pdaf28::GFP expression intensity in dauers, which was measured from either ASJ or ASI, due to the fact that overall very low expression levels hindered correct neuron identification. Since the brightest expressing cell was always measured for every dauer, the data for Pdaf-28::GFP expression intensity in dauers, therefore, is necessarily a conservative (over-) estimate. In all cases, fold differences with respect to growing L2/L3 wild-type larvae were calculated to show the average relative intensity among the assayed animals. Wild-type or mutant dauers and growing L2/L3 daf-c mutant larvae were always assayed in parallel with growing L2/L3 wild-type larvae at the test temperature. In brief, wild-type, trx-1(ok1449), daf-28(sa191) and daf-28(tm2308) dauers were collected from crowded starved plates maintained at 20°C, while daf-11(ks67) and daf-2(e1370) dauers were picked from uncrowded well-fed plates grown at 25°C; growing L2/L3 daf-c mutant larvae were collected from uncrowded well-fed plates maintained at 20°C. Growing L2/L3 wild-type larvae were always picked from uncrowded well-fed plates. Twenty-eight to thirty-six animals were analyzed per genotype and condition. Two independent extrachromosomal transgenic lines were examined for each of the two transcriptional Ptrx-1::GFP and Pdaf-28::GFP reporters, and the results were very similar; one transgenic line was tested for daf-28(tm2308) dauers. The data derived from one transgenic line are presented in Figures 2 and S2. To clarify whether the expression of Pdaf-28::GFP in ASJ and ASI changed in a similar fashion among dauers of the four genotypes assayed, we focused our attention on dauers showing expression in at least three of the four possible neuronal cell bodies in the head (ASJL/R, ASIL/R). This approach seeks to exclude expression changes that are due to transgenic extrachromosomal array variability or to transgene mosaicism. The expression of Pdaf-28::GFP changed in a similar manner in all cell bodies examined (n = 80 dauers; data not shown), suggesting that similar changes of Pdaf-28::GFP expression occur in ASJ and ASI.

Supporting Information

Figure S1

A speculative model describing the genetic pathways that regulate dauer formation. Not all genes known to act in these pathways are shown. Solid lines represent active regulation, and dashed lines represent inactive regulation. Arrows indicate positive regulation and crossbars indicate repressive regulation. See text for details and references.

(TIF)

Figure S2

Ptrx-1::GFP levels are similar to Pdaf-28::GFP levels in growing L2/L3 larvae. The opposing expression levels observed in dauers (cf. Figures 2A and 2C) were not seen in growing L2/L3 larvae. Average fluorescence intensity in ASJ or ASI neurons, normalized to that of growing L2/L3 wild-type larvae, is shown for growing L2/L3 larvae mutant for the indicated daf-c genes. Two independent transgenic lines were examined for each of the two transcriptional Ptrx-1::GFP and Pdaf-28::GFP reporters, and the results were very similar. The data derived from one transgenic line are presented. Each bar represents the average relative fluorescence intensity of 28–36 animals ± standard error of the mean (SEM).

(TIF)

Table S1

Molecular identities of all mutant alleles used in this study.

(DOC)

Table S2

Percent dauer formation at 25°C of animals overexpressing the extrachromosomal array transgene Ptrx-1::trx-1::GFP at 100 ng/µl.

(DOC)

Table S3

Strains and extrachromosomal arrays used in this study.

(DOC)

Table S4

Egg-laying periods and post-egglay scoring time points for the analysis of dauer formation.

(DOC)

Table S5

Percent dauer recovery at 15°C of the egg-laying defective ( egl ) mutants used in this study.

(DOC)

Acknowledgments

We thank Gautam Kao, Simon Tuck and Gert Jansen for plasmids; the Caenorhabditis Genetics Center, the C. elegans Gene Knockout Consortium, the National Bioresource Project for the nematode C. elegans, Makoto Koga, Silvia Fernández-Martínez and Jaime Santo-Domingo for strains; the Swoboda and Bürglin labs for excellent discussions; and Manuel Muñoz and Peter Askjaer for their insightful comments on the manuscript.

Footnotes

Competing Interests: The Friedrich Miescher Institute is financially supported by the Novartis Research Foundation. The authors have declared that no competing interests exist and that they adhere to the journal's policy on sharing of materials, methods and data.

Funding: This study was supported by grants from The Swedish Foundation for Strategic Research, The Swedish Research Council and The NordForsk Nordic C. elegans Network to PS; from Instituto de Salud Carlos III (Projects PI050065 and PI080557, co-financed by Fondo Social Europeo, FEDER) and Junta de Andalucía (Projects CVI-3629 and CVI-2697) to AMV; and from The Novartis Research Foundation to JA. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Figure S1

A speculative model describing the genetic pathways that regulate dauer formation. Not all genes known to act in these pathways are shown. Solid lines represent active regulation, and dashed lines represent inactive regulation. Arrows indicate positive regulation and crossbars indicate repressive regulation. See text for details and references.

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Figure S2

Ptrx-1::GFP levels are similar to Pdaf-28::GFP levels in growing L2/L3 larvae. The opposing expression levels observed in dauers (cf. Figures 2A and 2C) were not seen in growing L2/L3 larvae. Average fluorescence intensity in ASJ or ASI neurons, normalized to that of growing L2/L3 wild-type larvae, is shown for growing L2/L3 larvae mutant for the indicated daf-c genes. Two independent transgenic lines were examined for each of the two transcriptional Ptrx-1::GFP and Pdaf-28::GFP reporters, and the results were very similar. The data derived from one transgenic line are presented. Each bar represents the average relative fluorescence intensity of 28–36 animals ± standard error of the mean (SEM).

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Table S1

Molecular identities of all mutant alleles used in this study.

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Table S2

Percent dauer formation at 25°C of animals overexpressing the extrachromosomal array transgene Ptrx-1::trx-1::GFP at 100 ng/µl.

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Table S3

Strains and extrachromosomal arrays used in this study.

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Table S4

Egg-laying periods and post-egglay scoring time points for the analysis of dauer formation.

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Table S5

Percent dauer recovery at 15°C of the egg-laying defective ( egl ) mutants used in this study.

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