The Ser/Thr phosphatase PP2A regulatory subunit widerborst inhibits notch signaling.

Drosophila Enhancer of split M8, an effector of Notch signaling, is regulated by protein kinase CK2. The phosphatase PP2A is thought to play an opposing (inhibitory) role, but the identity of the regulatory subunit was unknown. The studies described here reveal a role for the PP2A regulatory subunit widerborst (wdb) in three developmental contexts; the bristle, wing and the R8 photoreceptors of the eye. wdb overexpression elicits bristle and wing defects akin to reduced Notch signaling, whereas hypomorphic mutations in this PP2A subunit elicit opposite effects. We have also evaluated wdb functions using mutations in Notch and E(spl) that affect the eye. We find that the eye and R8 defects of the well-known Nspl mutation are enhanced by a hypomorphic allele of wdb, whereas they are strongly rescued by wdb overexpression. Similarly, ectopic wdb rescues the eye and R8 defects of the E(spl)D mutation, which affects the m8 gene. In addition, wdb overexpression also rescues the bristle defects of ectopically expressed M8, or the eye and R8 defects of its CK2 phosphomimetic variant M8-S159D. The latter finding suggests that PP2A may target M8 at highly conserved residues in the vicinity of the CK2 site, whose phosphorylation controls repression of Atonal and the R8 fate. Together, the studies identify PP2A-Wdb as a participant in Notch signaling, and suggest that M8 activity is controlled by phosphorylation and dephosphorylation. The conservation of the phosphorylation sites between Drosophila E(spl) and the HES/HER proteins from mammals, reptiles, amphibians, birds and fish raises the prospect that this mode of regulation is widespread.

Introduction

The Notch signaling pathway is highly conserved among metazoan organisms and plays a pivotal role in cell fate determination throughout development [1]–[4]. Extensive studies in invertebrate and vertebrate models have resulted in the identification of most of the components of this pathway, and revealed that Notch activation results in the transcription of a family of basic Helix-loop-Helix (bHLH) repressors [5]. These proteins, collectively called the Hairy-Enhancer of Split (HES) repressors, are the terminal effectors of Notch signaling [6]–[11].

Over the years a remarkably detailed picture has emerged on the conserved components and mechanisms controlling ligand binding, Notch receptor processing, the nuclear functions of its intracellular domain (NICD), and factors mediating expression of the HES repressors. Despite this progress, our understanding of the mechanisms by which the large number of HES repressors mediate the diverse functions of Notch still remains incomplete. Because of their conserved (bHLH) structure, it has been thought that the HES proteins are functionally redundant and that they act as dosage-dependent effectors of Notch signaling. Arguments against both views (see below) have emerged from studies in Drosophila, specifically during the patterning/selection of the ‘founding’ R8 photoreceptors in the compound eye and the bristle sensory organ precursors (SOPs).

The development of the R8 or SOP is dependent upon bHLH proneural activators [12], [13]. These are atonal (ato) in the case of the R8 photoreceptor [14], [15] and a group of activators encoded by the achaete scute Complex (ASC) in the case of the bristle SOP [16]–[21]. The expression of these activators maintains neural competency in groups of otherwise equipotential cells, the proneural clusters (PNCs). This broad expression of Ato/ASC is later refined by the HES repressors in a process called lateral inhibition [22]–[24], during which the presumptive R8/SOP activates Notch to elicit HES expression in all other cells of the PNC. The HES repressors then antagonize Ato/ASC, thereby ensuring the specification (birth) of a single R8/SOP from each PNC, which is critical for proper structure and patterning of the eye and bristles.

A body of genetic studies have sought to analyze the roles of the seven HES repressors of Drosophila encoded by the Enhancer of split Complex, E(spl)C [5], [25]–[37]. Although these studies were the first to identify the HES repressors and establish their role in tissue patterning, they have produced paradoxical results. For example, loss of the E(spl)C elicits the birth of supernumerary R8s/SOPs [38], phenotypes that mimic loss of the Notch receptor or the transcription factor Suppressor of Hairless (Su(H)) [39], [40], which controls E(spl) expression in concert with NICD. In contrast, gain-of-function (GoF) studies have elicited confounding results. While ectopic expression of most E(spl)-members extinguishes the bristle-SOP fate [31], [33], the R8 fate is largely refractory. This inactivity was observed even with eye-specific members such as E(spl)-M8 [41], whose expression correlates in time/space to the emergence of single R8 cells [42] and whose mutation (E(spl)D) elicits dominant loss of R8s and the eye [41], [43]. This was the first line of evidence that for E(spl)-M8, protein dosage is, by itself, insufficient to inhibit the R8 fate.

This paradox was resolved for E(spl)-M8 whose ability to bind and antagonize Ato requires phosphorylation by protein kinase CK2 [44]. This post-translational modification (PTM) converts autoinhibited (inactive) M8 to a conformation that is competent for binding and repressing Ato and the R8 fate [45]. CK2 targets Ser159 in a Ser-rich region of M8 (the P-domain), which is located in the C-terminal domain (CtD) and is highly conserved in Drosophila E(spl)-M8, -M5 and -M7, and in human HES6. Accordingly, CK2 phosphorylates HES6 within its similarly localized P-domain [46]. Like the M8-Ato interaction, phosphorylation is also key to the formation of a HES6-HES1 complex. This raises the likelihood that a better understanding of the regulation of M8 should reveal conserved mechanisms regulating HES repressors, and by extension Notch signaling. Because CK2 is required for cell viability, its roles have been evinced by RNAi or dominant-negative (DN) constructs [47], [48]. These studies reveal that reduced CK2 activity elicits twinned and juxtaposed R8s and SOPs, both hallmarks of impaired lateral inhibition, suggesting that regulation by PTM is likely to be more general to Notch-dependent resolution of the PNCs. A better understanding of this mode of regulation is warranted to fully appreciate mechanisms controlling Notch signaling.

The aforementioned studies, in turn, raise the question on control of E(spl)-M8 by dephosphorylation. A candidate enzyme is the phosphatase PP2A, whose role emerged in assays for impaired signaling in wild type and mutant Notch (N) backgrounds [48]. Specifically, increased dosage (GoF) of microtubule star (mts), the unique catalytic subunit of Drosophila PP2A, elicits twinned R8s/SOPs, defects that closely mimic loss of Notch or CK2. The possibility thus arises that PP2A antagonizes Notch signaling. However, the participating PP2A regulatory subunit remained to be identified, and it was unknown if this phosphatase impacted E(spl)-M8 activity in vivo.

Drosophila PP2A, like the mammalian enzyme, is composed of a catalytic (C) and a scaffolding (A) subunit that associate with a regulatory (R) subunit [49]–[52]. The core (AC) dimer is ubiquitously expressed, but lacks target recognition due to a shallow active site. Target recognition (substrate-specificity) is conferred by regulatory subunits, which in Drosophila include widerborst (wdb), twins (tws), B52 and B56. The studies described here focus on wdb [53]. Using mutations in Notch and E(spl), we provide evidence that Notch signaling is potentiated by loss of wdb and antagonized by its overexpression, and that wdb mitigates the activity of ectopically expressed M8 protein. The multiple lines of evidence in the bristle, eye and wing identify wdb as a component of Notch signaling and suggest that repression by E(spl) proteins is controlled by phosphorylation and dephosphorylation.

Materials and Methods

Fly stock and crosses

Flies were raised at 24°C on standard Yeast-Glucose medium. All crosses were performed at 24°C, unless indicated otherwise. The Gal4 drivers were generously provided by other investigators or obtained from the Bloomington Stock Center (denoted by the prefix B). The Gal4 drivers are 109-68Gal4 (B6479), scaGal4 [33], [54], and E(spl)Gal4 (B8225). The following mutants were obtained from the Bloomington Stock Center; wdb (B12977), N (B28813), N (B118, B182) and E(spl)D (B2447). wdb (see ref [55]) flies were a gift from Amita Sehgal (U. Penn). The UAS-m8 and UAS-m8S159D flies have been previously described by us [45]. The UAS-RNAi lines to the PP2A regulatory subunits were obtained from the Drosophila Genetic Resource Center and include PP2A–B’ (Flybase #22569) and tws (Flybase #108872).

Fly phenotypes

Fly heads were removed from newly eclosed flies. Heads were passed through a graded alcohol series for 24 hours each (25%–50%–75%-absolute), passed through Hexamethyldisalizane, and mounted on EM stubs using carbon tape (Ted Pella). Fly heads were dried for 24 hours, sputter coated with gold, and examined with a Hitachi scanning electron microscope at an accelerating voltage of 20 kV. Images were acquired as TIFF files that were collated using Adobe Illustrator. For quantitative analysis of eye size (facet number), crosses were established in duplicates, and ≥15 adult flies for each genotype were photographed using a Leica MZ16 stereomicroscope equipped with a Leica DFC-480 digital camera. Facet numbers were manually counted from TIFF images of the eyes and subjected to statistical analysis. For bristle phenotypes, newly eclosed adults were photographed using a Leica MZ16 stereomicroscope or by scanning EM. For quantitative analysis of the bristle phenotypes, multiple crosses were established (triplicates), and adults were scored for bristle defects. Wing margin phenotypes were documented using a Leica MZ16 stereomicroscope. Eye size (facet counts) and bristle and wing defects were statistically analyzed using the Student’s t-test, with the exception of Fig. 1F, which was determined using the chi-squared test.

Figure 1

Wdb overexpression elicits bristle and wing margin defects.

(A, B) Overexpression of Wdb elicits ectopic (arrow) and split macrochaetes (arrowhead). (B) Scanning EM of a split-MC. (C) Quantification of the penetrance of split-MCs; asterisks denote P-values<0.001 (n≥75). (D, E, F) Notched wing defects. (E) Overexpression of Wdb elicits wing margin defects. (F) Loss of wdb modifies the wing margin defects of N flies. Asterisks in panels E and F denote P-values<0.001 (n≥44).

Immunostaining

Imaginal discs were isolated from late third instar larvae, fixed in freshly prepared 4% paraformaldehyde in 1x phosphate buffered saline (PBS) for 45 minutes at 4°C, and washed three times with PBS containing 0.3% Triton X-100 (PBS-TX). The discs were incubated for 12 hours at 4°C in PBS-TX containing 5% normal goat serum and primary antibody, washed three times with PBS containing 0.3% Triton X-100 (PBS-TX) and immunostained for 2–3 hours in secondary antibody. Following this, eye discs were washed three times with PBS containing 0.3% Triton X-100 (PBS-TX) and mounted in Vectashield. The following antibodies were used in this study; guinea pig anti-Sens (gift of Hugo Bellen, HHMI-Baylor) at a dilution of 1∶500 and mouse anti-ELAV (DSHB, Iowa) at a dilution of 1∶500. The mouse anti-ELAV antibody (9F8A9) developed by Gerald Rubin was obtained from the Developmental Studies Hybridoma Bank, created by the NICHD of the NIH and maintained at The University of Iowa, Department of Biology, Iowa City, IA 52242. Secondary antibodies (Molecular Probes) were goat-anti mouse-IgG coupled to Alexa Fluor 594 (1∶1000) and goat anti-guinea pig-IgG coupled to Alexa Flour 488 (1∶1000).

Confocal microscopy

An Olympus FluoView (FV1000) was used for imaging. Images were generated from scans acquired every 1 µm along the apicobasal axis of the discs. Scanning was limited along the Z-axis to acquire full spectral output of the fluorophores, and no layers were removed from confocal stacks. Confocal images were compressed as a Z-stack, exported as TIFF files and collated in Adobe Illustrator.

Results

Increased wdb dosage elicits bristle and wing defects akin to Notch loss of function

Previous studies implicated the PP2A catalytic subunit, mts, in Notch signaling [48], but the relevant regulatory subunit remained to be identified. We focused on wdb because it had been identified in a GoF screen for genes that affect Drosophila bristle development [56]. This screen demonstrated that PNC-specific expression of wdb (UAS-wdb) by scaGal4 elicits ectopic and split macrochaetes (MCs) on the notum (Fig. 1A), both suggesting reduced Notch signaling, but no follow-up studies have been reported on the underlying mechanism(s). The effects of wdb have been recapitulated by UAS-wdb constructs in other studies [53], [57], demonstrating the responsiveness of the EP insertion to the GAL4-UAS system.

Because scaGal4/+ flies intrinsically display ectopic and split MCs with low-to-moderate penetrance (∼20–30%), we used the enhancer trap sca, a driver of weaker strength (abbreviated as 109-68Gal4, henceforth). 109-68Gal4/+ flies display a notably lower incidence of ectopic MCs (∼10%, data not shown), but importantly do not exhibit any split MCs (Fig. 1C). Using the latter as a bioassay, we find that ∼50% of flies overexpressing wdb (wdb display split MCs (Fig. 1B, C). This defect requires wdb expression, as no split MCs are seen in wdb flies (Fig. 1C). Thus wdb-GoF elicits bristle defects akin to loss of Notch.

We sought to determine the role of Wdb in the developing wing margin. We first tested for wdb-GoF effects using E(spl)Gal4. We find that expression of wdb elicits notched wings with a high penetrance (Fig. 1D, E). The absence or extremely low incidence of notched wings in wdb flies or in E(spl)Gal4/+ flies (Fig. 1E) reveals that this defect is wdb-dependent. The bristle and wing defects of UAS-wdb closely resemble those elicited by expression of UAS-mts with 109-68Gal4 or E(spl)Gal4 [48]. We also assessed if loss of wdb would modify the classical wing margin defect of the Notch allele N. Consistent with a wdb-GoF role in reducing Notch pathway activity, reduction of wdb dosage (through use of the hypomorphic allele wdb) yields a significant rescue of the wing margin defect of N heterozygotes (Fig. 1F). No such wing margin defects are intrinsic to flies that are heterozygous or homozygous for wdb (Fig. 1F, and data not shown). Thus Wdb and Mts activities occur in similar developmental contexts and display effects consistent with reduced Notch signaling.

wdb dosage modulates the retinal defects of N

Loss of CK2 compromises lateral inhibition and elicits ectopic (twinned) R8s and rough eyes [47]. If PP2A opposes Notch signaling, increased dosage of this phosphatase should elicit similar R8/eye defects. However, overexpression of wdb by scaGal4 or 109-68Gal4 did not affect the R8s or the adult eye (data not shown, and see below), similar to the inactivity of ectopic Mts, reported by us [48]. This raised the possibility that the threshold requirement for PP2A is higher during R8 selection, compared to that in the bristle or wing (Fig. 1).

To evaluate if wdb plays a role in R8 selection, we employed N, a widely studied mutation that mainly affects the eye. Specifically, N increases receptor sensitivity to the ligand Delta, thereby allowing inappropriate Notch activity in R8 precursors leading to loss of R8s [58]. Because morphogen secretion by differentiated R8s is required for ato expression and progression of eye development, further R8 specification becomes impaired. This reduces both, the number of ommatidia (facets) and their hexagonal phasing, which manifest as reduced and rough eyes, respectively (Fig. 2B, B’). Consistent with N rendering R8s sensitive to inhibitory Notch signaling, its eye defects are rescued by halved dosage of Delta, Su(H) or E(spl)C [42], [59], [60], or by conditions that should favor hypo-phosphorylation of M8 such as CK2-RNAi or Mts-GoF [43], [48]. This Notch mutation thus provides a sensitized background where modulation of endogenous E(spl) activity by CK2 or PP2A can be assessed.

Figure 2

Modulation of the eye defects of Nspl by Wdb.

Scanning EM of the adult eye at a magnification of 200x (A–D) and 1000x (B’–D’). (A) wdb homozygous flies display wild type eyes, whereas those of N (males) are reduced and rough (B, B’). The N eye is exacerbated by wdb (C, C’), but rescued by overexpression of UAS-wdb (D, D’). Graph shows ommatidial (facet) counts of the eyes in panels B–D. Facet counts were determined in ≥15 flies, and asterisks denote P-values<0.001. (E) Facet counts in other relevant genotypes; note that wild type flies typically display 750–800 facets. Inset shows R8 selection from intermediate groups (IG). During R8 specification, Ato expression initiates at stage-1 of the MF, then upregulates, and finally resolves at stage-2/3, a region that coincides with the expression domain of 109-68Gal4. Color codes are; Ato (pink/red), Sens (blue) and secondary R cells (grey).

Since the complete loss of PP2A elicits cell lethality [53], we tested if the hypomorphic allele wdb modifies the retinal defects of N. Indeed, when homozygous, wdb exacerbates the reduced and rough eye of N males (Fig. 2C, C’). This effect is not seen in N flies (Fig. 2E) or in wdb/wdb flies (Fig. 2A), reflecting the hypomorphic nature of this wdb allele. In addition, mispatterning of the inter-ommatidial bristles (IOBs) was exacerbated in N/Y; wdb/wdb flies (compare Fig. 2B’ and 2C’), wherein multiple IOBs were found at normal and ectopic positions in the ommatidial lattice. On their own, homozygous wdb flies do not exhibit such IOB defects (Fig. 2A). The effects of wdb reflect diminished PP2A activity, because precise excision of the P-element reverses the autophagy defects of this wdb mutation [57].

We next tested if the retinal defects of N are rescued by wdb overexpression. For this, we used the driver 109-68Gal4, which is active at stage 2/3 of the morphogenetic furrow (MF, see [61], [62]) where lateral inhibition drives R8 selection (inset in Fig. 2). Indeed, overexpression of UAS-wdb (wdb) rescues the reduced eye of N (Fig. 2D), and markedly improves the hexagonal phasing of the ommatidia and the positioning of the IOBs (Fig. 2D’).

To provide quantitative analysis, we determined facet counts (graph in Fig. 2), an approach that has been used to compare eye size [43], [48], [63], [64]. The facet number for N males, 320±10, was used as a baseline. Consistent with the adult eye, N/Y; wdb/wdb flies display a significantly reduced facet count (∼200±11, see graph in Fig. 2), whereas overexpression of wdb significantly increased facet counts (∼480±11). Importantly, no modulation was seen in relevant control genotypes (Fig. 2E). Thus loss of wdb exacerbates N, whereas its overexpression rescues. The opposite effects of wdb-LoF and-GoF strengthen the role of this regulatory subunit in Notch signaling.

We also tested a recessive lethal allele of twins, tws, and B’ (PP2A-B’), but found that neither modulated N (data not shown). As an alternative, we expressed UAS-RNAi lines that target tws and the B’ regulatory subunits with 109-68Gal4 but found that they did not modulate N (data not shown). Similarly, the recessive lethal allele mts did not exacerbate the reduced eye of N (data not shown), indicating that a 50% reduction in tws or mts activity is not limiting for PP2A activity. Therefore, our studies do not formally exclude the contributions of the regulatory subunits tws or B’.

wdb enhances the R8 defects of N

We next determined if the effects of wdb on N involve the R8 cells, the founding photoreceptors [65], [66]. For this, we stained third instar eye discs for Senseless (Sens), a marker for differentiated R8s [67], [68], and ELAV, a pan-neuronal marker [69]. In wild type discs (Fig. 3A) Sens expression initiates during R8 birth, after which Sens is maintained in differentiated R8s. To each R8, seven ELAV+ photoreceptors (R1–R7) are sequentially recruited. As previously shown, in N eye discs (Fig. 3B) Sens expression is not uniform along the dorso-ventral (DV) axis and is not sustained along the antero-posterior (AP) axis indicating that the inappropriate Notch activity impairs proper R8 differentiation. Importantly, wdb exacerbates the R8 defects of N (Fig. 3C), such that Sens expression is further diminished and poorly sustained along the AP axis. Notably, significant regions of the eye disc display no R8s or secondary photoreceptors. These patches of cells, which fail to undergo retinal fate specification, are randomly positioned in the eye disc (compare two such discs in Fig. 3C and C’) and do not manifest as gaps in the adult eye (see Fig. 2C), as unspecified cells are removed by apoptosis [70]. The reduced number and spacing of Sens+ and ELAV+ clusters are consistent with the exacerbated loss of the adult eye when wdb activity is compromised in N flies (Fig. 2C). Thus loss of wdb exacerbates the R8 defects of N.

Figure 3

Loss of wdb activity enhances the R8 defects of N.

Eye discs of the indicated genotypes were stained with α-Sens (Green) and α-ELAV (Red) to assess R8 differentiation and secondary photoreceptor recruitment, respectively. Panels C and C’ show two discs of the indicated genotype to illustrate random positioning of patches of non-specified and non-differentiated retinal tissue. Arrows denote direction of MF progression.

wdb overexpression rescues the eye defects of N flies

We next evaluated the role of wdb in an E(spl) mutant background. We employed the dominant m8 mutation E(spl)D, which elicits a reduced eye, but only in N flies (see Fig. 4B). Given the recessive nature of this Notch allele, N males display a severely reduced eye field (<15 facets, see ref. [41]) that is not amenable to modulation, whereas this effect is of moderate severity in N females (∼275 facets, Fig. 4B). This moderate effect (in females) is amenable to modulation, given rescue by loss of function mutations in Delta or E(spl)C [42].

Figure 4

Ectopic Wdb rescues the eye defects of N flies.

Scanning EM of the adult eye at 200x magnification (A–C). (A) Overexpression of wdb does not perturb the adult eye. The reduced eye of N flies (B) is rescued by overexpression of Wdb (C). Eye discs of the genotypes indicated in A–C were stained with α-Sens (Green) and α-ELAV (Red) to assess R8 differentiation and secondary photoreceptor recruitment, respectively, and arrows denote direction of MF progression. Panels A’–C’ show Sens+ELAV staining, whereas A’’–C’’ show Sens-only channel to highlight differentiated R8s. Graph shows ommatidial (facet) counts of the adult eyes. Data labeled B and C correspond to the adult eye shown in panels B and C. The genotype of relevant control progeny (D, E) is noted. Facet counts were determined in ≥15 flies, and asterisk denotes P-values<0.001.

We find that overexpression of wdb with 109-68Gal4 rescues the reduced eye of N females, appears to restore facet phasing (compare Fig. 4B and 4C), and significantly increases eye size (graph in Fig. 4). These effects require wdb expression, because no rescue is seen in the control genotypes (Fig. 4D, E). We next determined if rescue involves R8 specification and differentiation. Compared to WT (see Fig. 3A), N eye discs display gaps between differentiated R8s, regions also devoid of secondary (ELAV+) photoreceptors (Fig. 4B’, B’’). Moreover, many of the R8s that are born fail to properly recruit ELAV+ cells, indicating that the progressive recruitment of secondary photoreceptors is impaired. These R8 defects are strongly rescued by overexpression of wdb in N females (Fig. 4C’, C’’), an outcome consistent with the adult eye (Fig. 4C). Overexpression of wdb on its own does not affect the eye, R8 specification or secondary photoreceptor recruitment (Fig. 4A, A’, A’’). Thus increased wdb dosage rescues the eye and R8 defects of N, both alone or in combination with E(spl)D.

wdb overexpression rescues the IOB loss of ectopic E(spl)-M8

We next tested if wdb overexpression would attenuate the activity of ectopic M8, as this would provide in vivo evidence that PP2A affects E(spl) activity, rather than expression of endogenous E(spl) proteins by perturbed Notch signaling. This was deemed important, because the modulation observed in our studies (Figs. 1–4) could formally result from altered E(spl) expression in response to wdb-GoF/LoF. We have previously shown that expression of UAS-M8 (wild type) with scaGal4 elicits strong loss of the IOBs, but does not affect R8 birth, eye size or facet phasing (Fig. 5B, see ref. [45]). Indeed, co-expression of UAS-wdb significantly restores IOBs (Fig. 5C). This effect is not seen upon co-expression of UAS-LacZ (data not shown), excluding competition for limiting amounts of Gal4 protein. Expression of wdb-alone elicits only occasional loss or duplicated IOBs (see Fig. 5A). As these studies were conducted in Notch flies and M8 expression is under Gal4-UAS control, it seems unlikely that Wdb has direct (inhibitory) effects on components of the Notch receptor pathway.

Figure 5

Ectopic Wdb rescues the IOB defects of E(spl)-M8.

UAS-constructs were expressed with scaGal4 and adult eyes were analyzed by scanning EM. Note that overexpression of Wdb alone (A) elicits occasional loss of IOB’s (arrow) or duplication (dotted circle). Overexpression of wild type M8 elicits strong loss of the IOBs, but does not perturb the hexagonal pattern of ommatidia (B). Co-expression of Wdb strongly rescues the IOB-loss of M8 (C).

wdb overexpression rescues the eye defects of the CK2 mimic M8-S159D

We next tested if ectopic Wdb would rescue the reduced eye phenotype of a variant of M8 that harbors a phosphomimetic Asp in place of Ser159, a residue targeted by protein kinase CK2 [44]. This modification serves to activate M8 repression of Ato. We have previously reported [45] that expression of M8-S159D with scaGal4 elicits a severely reduced eye (≤15 facets, likely a limit phenotype), whereas that with 109-68Gal4 is more muted (∼300 facets, Fig. 6A and graph). Since the effects with 109-68Gal4 are of moderate severity, we reasoned that these should be responsive to ectopic wdb. Indeed, co-expression of wdb rescued the reduced eye and significantly increased facet numbers (Fig. 6B and graph). As co-expression of UAS-lacZ is ineffective (Fig. 6 graph), rescue by ectopic wdb does not reflect competition for a limiting amount of Gal4. We next stained eye discs with Sens and ELAV. In 109-68/+; UAS-m8-S159D/+ eye discs, R8 patterning is perturbed, and these R8s poorly sustain Sens expression and inefficiently recruit secondary (ELAV+) photoreceptors (Fig. 6A’), as also observed in N flies (see Fig. 4B’). These defects are rescued by co-expression of wdb (Fig. 6B’, see magnification in Fig. 6B’’). Importantly, in discs overexpressing M8-S159D+Wdb (Fig. 6B’, B’’), patterning of R8s appears closer to that in wild type discs (see Fig. 3A), which resemble those overexpressing only wdb (Fig. 4A’).

Figure 6

Ectopic Wdb rescues the eye defects of the CK2 mimic M8-S159D.

Scanning EM of the adult eye at 200x magnification (A–B). (A) Overexpression of M8-S159D elicits a moderately reduced eye (A), which is strongly rescued by co-expression of Wdb. Graph shows ommatidial (facet) counts of the adult eyes. Data labeled A and B correspond to the adult eye shown in panels A and B. The genotype of relevant control progeny (C) is noted. Facet counts were determined in ≥15 flies, and asterisk denotes P-values<0.001. Eye discs of the genotypes indicated in A–B were stained with α-Sens (Green) and α-ELAV (Red) to assess R8 differentiation and secondary photoreceptor recruitment, respectively, and arrows denote direction of MF progression. Panels A’–B’ show Sens+ELAV staining, whereas B’’ show a magnification of B’ to highlight rescue of differentiated R8s and ELAV clusters.

Together, the findings that ectopic Wdb rescues the eye/R8 defects of N males (Figs. 2, 3) or N females (Fig. 4) support the possibility that Wdb enables PP2A to oppose Notch signaling, while rescue of the IOB defects of ectopic M8 (Fig. 5) or the eye/R8 defects of M8-S159D (Fig. 6) strengthen the likelihood that Wdb enables PP2A to target the Notch effector M8.

Discussion

Control of protein activities by phosphorylation is a widespread regulatory mechanism, and reflects the need for rapid switching between two activity states. These modifications are often fine-tuned by the coordinated activities of phosphatases. One such enzyme is PP2A, whose role in Notch signaling was unclear. The studies described here identify wdb as a component of Notch signaling in multiple developmental contexts. We have conducted GoF and LoF studies on wdb in wild type flies, in Notch and E(spl) mutants, and upon ectopic expression of E(spl)-M8 or its CK2-site variant M8-S159D. Our studies suggest that PTM of HES repressors constitutes a sophisticated yet poorly studied component of Notch signaling.

Specifically, we demonstrate that ectopic wdb elicits bristle and wing margin defects that mimic loss of Notch (Fig. 1), rescues the eye/R8 defects of hypermorphic Notch and E(spl) mutations (Figs. 2, 3 and 4), and mitigates the activity of M8 during IOB development (Fig. 5) and that of the CK2 mimetic M8-S159D variant during eye/R8 development (Fig. 6). The effects of ectopic wdb are unlikely to reflect an artifact of mis-expression, because studies on N (Fig. 1) and N (Figs. 2 and 3) show direct genetic interactions with the hypomorphic allele wdb. Importantly, the eye/R8 defects respond in a predictable manner, i.e., exacerbated by wdb-LoF but rescued by wdb-GoF. Together, the bristle, wing and eye/R8 analyses demonstrate that PP2A opposes Notch signaling, that this function is mediated by Wdb, and that this phosphatase mitigates the activity of E(spl)-M8, one of the bHLH effectors of this pathway.

It has been previously shown that decreased dosage of E(spl) or CK2 rescues the eye/R8 defects of N, as does an increase in the dosage of mts, the PP2A catalytic subunit. At face value, the studies of Figs. 2–4 could be the outcome if ectopic wdb were to inhibit the Notch receptor, components of this pathway or signaling to the nucleus, e.g., by impairing NICD or Su(H) activity. If any of these were the case, ectopic wdb would attenuate expression of endogenous E(spl) proteins or the mutant (M8) protein encoded by the E(spl)D allele (Fig. 4), either of which would elicit rescue. However, this possibility is diminished, because studies on the IOB defects of M8 (Fig. 5) and the eye and R8 defects of M8-S159D (Fig. 6) were in Notch flies, and where the Gal4-UAS approach was used for transgene expression. Taken together, a simpler interpretation is that Wdb enables PP2A to mitigate E(spl)-M8 activity.

The modulation of the IOB defects of M8 (Fig. 5) appears more straightforward given that the P-domain is unperturbed (see Fig. 7A). In contrast, the modulation of the eye/R8 defects of the CK2 phospho-mimetic M8-S159D (Fig. 6) may seem paradoxical, as this Asp variant should not have been responsive to phosphatase activity if PP2A were to target the CK2 site. As shown in Fig. 7B, the P-domain is populated by a number of Ser residues that are highly conserved in M8, M7, M5, three of which are also conserved in the human, mouse and Anolis HES6. The importance of the CK2 site is now well understood for fly M8 and mouse HES6 (see Introduction), but the roles of the other highly conserved Ser residues are beginning to be resolved. In the case of HES6, the PGSP motif (see Fig. 7B) is targeted by MAPK [71], but its developmental role remains unknown. Likewise, the additional Ser residues in M8 appear to be subject to phosphorylation. In support, our ongoing studies reveal that replacement of the MAPK site of M8-S159D with PLAP neutralizes repression of Ato and the R8 fate (Bandyopadhyay and Bidwai, In preparation), raising the prospect that M8, like HES6, requires multi-site phosphorylation. In light of these findings, PP2A may target the MAPK site or modifications at the other Ser residues (see Fig. 7A), thereby controlling repressor activity. The possibility arises that coordinated functions of the participatory kinases and PP2A control M8 phosphorylation levels and/or activity (see model in Fig. 7C). Future biochemical studies are required to test this model for regulation, determine if Wdb permits PP2A to dephosphorylate M8, and identify which residue is a target of this phosphatase.

Figure 7

Conserved Ser residues in E(spl)/HES/HER and model for regulation of M8.

(A) Functional domains in E(spl) proteins; the red oval is the Ser-rich phosphorylation domain (PD) located in the C-terminal domain (CtD). The P-domain of M8 and its CK2 mimetic form M8-S159D. (B) Alignment of the P-domain in Drosophila E(spl)-M8, -M5, -M7, HES6 from mammals/reptiles/birds/frogs, and the fish HER13 isoforms. The consensus sites for CK2 and MAPK are shown. Note the invariant CK2 site in E(spl)/HES/HER. The underlined Ser residues highlighted in yellow denote biochemically identified CK2 and MAPK sites. Arrowheads below alignment denote residues predicted to also be modified by CK2, and PK denotes yet unidentified protein kinases. The number of residues separating the P-domain from the C-terminal WRPW motif is indicated. (C) Model for regulation of M8. CK2 in concert with other protein kinases (PK) converts M8 into an active repressor of Atonal, whereas PP2A in concert with yet unidentified factors (?) mediate inactivation, through a conformational change or by destruction.

Remarkably, the CK2 Site Is Conserved and Similarly Located in Chicken/Frog HES6-1, as Well as in HER13.1/2 from Fish (Fig. 7B, and See Ref [72]). Even Though They Lack a Recognizable MAPK Site, the P-Domain in HES6-1/HER13.1/2 Harbors Several Conserved Ser/Thr Residues, Many of Which Meet the Consensus for CK2 (See Residues in Red in Fig. 7B). Because CK2 Is an Acidophilic Kinase That Utilizes Pser/Pthr as Surrogates for Asp/Glu [73]–[76], the Possibility Remains That HES6-1/HER13.1/2 Are More Extensively Phosphorylated by This Enzyme. This Possibility May Explain a Report [72] That Mutation of the Primary CK2 Site in Chicken HES6-1 (the Ser Residue Colored in Green in Fig. 7B) to Ala Does Not Affect Repression of HES5. Direct (in vitro) Biochemical Studies Are Needed to Determine If CK2 Targets a Single/Multiple Sites in HES6-1 and HER13.1/2.

The E(spl)/HES/HER proteins display length and sequence heterogeneity of the CtD. Computational analysis of fly E(spl) proteins reveals that the P-domain and its flanking sequences (aside from WRPW) are intrinsically disordered (ID), as is also the case for the HES/HER proteins (ref [64], and data not shown). It is becoming increasingly apparent that ID-regions, which are rich in Ser/Thr and Asp/Glu residues, are used to regulate activity through PTM [77]–[79]. The possibility thus arises that this region in E(spl)/HES/HER proteins serves as a ‘charge-sensor’ that controls activity via phosphorylation. If so, one might expect that evolutionary pressure would select for phosphorylatable residues, regardless of the kinases required. Such an argument has, in fact, been made for the circadian clock (see below), which requires multi-site phosphorylation of fly/human Period (PER, [80]) and the Frequency protein from Neurospora [81], even though the participatory kinases vary across taxa.

Our studies raise a number of questions relevant to our understanding of Notch signaling. We address each of these individually.

Firstly, how widespread is the regulation of E(spl)/HES proteins by PTM? The P-domain is highly conserved amongst M8, M7 and M5 (Fig. 7), and our recent studies have uncovered a variant P-domain in Mγ that is efficiently phosphorylated by CK2 (Jozwick and Bidwai, In preparation). Consequently, four E(spl) members are now known to be CK2-targets, whereas three (M3, Mβ and Mδ) appear to not be modified by this kinase. Importantly, the CK2 site in these four members is invariant in the homologous proteins from 12 Drosophila species that diverged over 50×106 years (data not shown), a window of time over which mutations would have accumulated were these inconsequential for repressor activity.

Second, why are some E(spl)/HES proteins devoid of a P-domain? We speculate that this may reflect different modes by which E(spl)/HES proteins repress cell fate. Perhaps, the best example is the M8-Ato interaction. It was initially thought that E(spl) proteins bind N-box sequences to mediate repression [82]. However, no N-box has been identified in the ato-enhancers [83], leading to the view that protein-protein interactions underlie repression [84], [85]. In this model, heterodimers of Ato and Daughterless (Da) bind to E-boxes in the ato-enhancer [61], and repression by M8 involves formation of (DNA-binding independent) M8-Ato complexes. It is however, unlikely that this mode of repression is universal, given that the basic domain of HES members is conserved, and N-boxes have been identified in the ASC enhancer, whose mutations lead to impaired repression. Given the roles of HES proteins in myogenesis, oogenesis, somitogenesis, it is conceivable that either one or a combination of mechanisms regulate repression, or that in vivo targets of HES proteins are isoform-specific. Consistent with the latter possibility, the direct physical interaction of M8 with Ato has not been observed with E(spl)-Mγ and-Mδ [41], [86], two members whose expression in the MF closely correlates to birth of the R8s. Isoform specificity has also been reported for interactions of E(spl) members with ASC-bHLH activators [86].

Third, can the principles gleaned from other biological contexts apply to our studies on CK2, PP2A and Notch? The regulation of the central clock protein Period (PER) provides an attractive model. Detailed studies have revealed that PER activity/levels are regulated by CK2 and PP2A [55], [80], [87]–[89]. In this case, CK2 promotes PER activity, whereas PP2A opposes. Additional regulation is conferred by CK1 (doubletime [90]) and GSK3 (shaggy [91]), with PER degradation being controlled by CK1 and the F-box protein Slimb/β-TrCP [92], [93]. It is of interest to note that the additional Ser residues of the P-domain of M8 (Fig. 7A) resemble the consensus for CK1 and that phosphorylation is predicted to generate a strong site for Slimb binding (Majot and Bidwai, unpublished). If so, the cohort of kinases and phosphatases that regulate E(spl)-M8 may more closely resemble regulation of PER by PTM than has been recognized. Interestingly, sleep homeostasis is perturbed in N mutants [94], [95], although it is unknown if this reflects altered E(spl) expression and/or regulation. Future studies on E(spl)-M8 will be required to determine if its regulation is in fact similar to that of PER, or if the shared kinases and phosphatases is merely coincidental.

On its own, the shared regulation of M8 and HES6 makes for a strong evolutionary argument. Although the role of PP2A in HES6 regulation remains unknown, we note that HES6 regulates transitions in retinal cell fate specification and during development of the cerebral cortex, where progenitors give rise to the ordered specification of neurons (first), astrocytes (second) and oligodendrocytes (third) [96], [97]. It has, in fact, been proposed that regulated HES6 activity (phosphorylation/dephosphorylation) may underlie the timing of transitions from neurogenesis to astrocyte specification, during which HES6 promotes the former and inhibits the latter [71], [98]. In Drosophila, it may be the case that phosphorylation of M8 allows for proper R8 selection, whereas dephosphorylation controls rapid inactivation and/or clearance (see model in Fig. 7C). Given that R8 birth is closely followed (in time and space) by (Notch-dependent) recruitment of the R2/R5 photoreceptor pair, control by phosphorylation would be a significantly faster and more robust circuit, as compared to that based solely upon transcription. This mode of control would appear consistent with a mathematical model that R8 selection occurs in ≤10 minutes [99], a window of time more compatible with control of M8 activity/levels through PTM (phosphorylation and dephosphorylation). Such a mode of regulation may exploit tissue-specific expression patterns of select E(spl)-members [28], [100], their regulation by PTM and their preferred developmental targets.

Future studies to identify the site on M8 that is a target for PP2A, and whether HES6 is similarly regulated by dephosphorylation will be required to more fully reveal the mechanism(s) by which phosphorylation and dephosphorylation control repression. Thus, the observation of M8 control by PTM fortuitously opens a new window into regulation of Notch signaling, and raises the prospect that this mechanism is differentially employed in tissue patterning.