Abstract
The guidance cue UNC-6/Netrin regulates both attractive and repulsive axon guidance. Our previous work showed that in C. elegans, the attractive UNC-6/Netrin receptor UNC-40/DCC stimulates growth cone protrusion, and that the repulsive receptor, an UNC-5/UNC-40 heterodimer, inhibits growth cone protrusion. We have also shown that inhibition of growth cone protrusion downstream of the UNC-5/UNC-40 repulsive receptor involves Rac GTPases, the Rac GTP exchange factor UNC-73/Trio, and the cytoskeletal regulator UNC-33/CRMP, which mediates Semaphorin-induced growth cone collapse in other systems. The multidomain flavoprotein monooxygenase (FMO) MICAL also mediates growth cone collapse in response to Semaphorin by directly oxidizing F-actin, resulting in depolymerization. The C. elegans genome does not encode a multidomain MICAL-like molecule, but does encode five flavin monooxygenases (FMO-1, -2, -3, -4, and 5) and another molecule, EHBP-1, similar to the non-FMO portion of MICAL.
Here we show that FMO-1, FMO-4, FMO-5, and EHBP-1 may play a role in UNC-6/Netrin directed repulsive guidance mediated through UNC-40 and UNC-5 receptors. Mutations in fmo-1, fmo-4, fmo-5, and ehbp-1 showed VD/DD axon guidance and branching defects, and variably enhanced unc-40 and unc-5 VD/DD guidance defects. Developing growth cones in vivo of fmo-1, fmo-4, fmo-5, and ehbp-1 mutants displayed excessive filopodial protrusion, and transgenic expression of FMO-5 inhibited growth cone protrusion. Mutations suppressed growth cone inhibition caused by activated UNC-40 and UNC-5 signaling, and activated Rac GTPase CED-10 and MIG-2, suggesting that these molecules are required downstream of UNC-6/Netrin receptors and Rac GTPases. From these studies, we conclude that FMO-1, FMO-4, FMO-5, and EHBP-1 represent new players downstream of UNC-6/Netrin receptors and Rac GTPases that inhibit growth cone filopodial protrusion in repulsive axon guidance.
Author Summary Molecular mechanisms of axon repulsion mediated by UNC-6/Netrin are not well understood. Inhibition of growth cone lamellipodial and filopodial protrusion is critical to repulsive axon guidance. Previous work identified a novel pathway involving Rac GTPases and the cytoskeletal interacting molecule UNC-33/CRMP required for UNC-6/Netrin-mediated inhibition of growth cone protrusion. In other systems, CRMP mediates growth cone collapse in response to semaphorin. Here we demonstrate a novel role of flavoprotein monooxygenases (FMOs) in repulsive axon guidance and inhibition of growth cone protrusion downstream of UNC-6/Netrin signaling and Rac GTPases. In Drosophila and vertebrates, the multidomain MICAL FMO mediates semaphorin-dependent growth cone collapse by direct oxidation and depolymerization of F-actin. The C. elegans genome does not encode a multidomain MICAL-like molecule, and we speculate that the C. elegans FMOs might have an equivalent role downstream of UNC-6/Netrin signaling. Indeed, we show that EHBP-1, similar to the non-FMO portion of MICAL, also controls repulsive axon guidance and growth cone inhibition, suggesting that in C. elegans, the functions of the multidomain MICAL molecule might be distributed across different molecules. In sum, we show conservation of function of molecules involved in semaphorin growth cone collapse with inhibition of growth cone protrusion downstream of UNC-6/Netrin signaling.
Introduction
The formation of neural circuits during development depends on the guidance of growing axons to their proper synaptic targets. This process relies on the growth cone, a dynamic actin based structure present at the tip of a growing axon. Growth cones contain a dynamic lamellipodial body ringed by filopodial protrusions, both important in guiding the axon to its target destination [1-4]. Guidance receptors present on the leading edge of the growth cone sense and respond to various extracellular guidance cues, which attract or repel axons enabling them to reach their proper target destination [5, 6].
The secreted laminin-like guidance molecule UNC-6/Netrin mediates both axon attraction and axon repulsion and defines a dorsal-ventral guidance mechanism conserved from invertebrates to vertebrates [7-9]. Attractive or repulsive responses to UNC-6/Netrin depend on the receptors expressed on the growth cone. Homodimers of the UNC-6/Netrin receptor UNC-40/DCC mediate attraction, and UNC-5-UNC-40 heterodimers or UNC-5 homodimers mediate repulsion [10-12].
In C. elegans, UNC-6/Netrin is secreted by the ventral cells and along with its receptors UNC-40 and UNC-5 is required for the dorsal ventral guidance of circumferential neurons and axons [8, 13, 14]. Previous studies of repelled VD growth cones in Netrin signaling mutants revealed a correlation between attractive axon guidance and stimulation of growth cone protrusion, and repulsive axon guidance and inhibition of growth cone protrusion [15]. For example, in unc-5 mutants, growth cones were larger and more protrusive, and often displayed little or no directed movement. This is consistent with observation that increased growth cone size was associated with decreased neurite growth length [16]. Conversely, constitutive activation of UNC-40/UNC-5 signaling in repelled VD growth cones led to smaller growth cones with severely reduced filopodial protrusion [15, 17]. Thus, directed growth cone repulsion away from UNC-6/Netrin requires a balance of pro- and anti-protrusive activities of the receptors UNC-40 and UNC-40-UNC-5, respectively, in the same growth cone [15].
Genetic analysis has identified a cytoskeletal signaling pathway involved in stimulation of growth cone protrusion in response to the attractive UNC-40 signaling that includes CDC-42, the Rac-specific guanine nucleotide exchange factor TIAM-1, the Rac-like GTPases CED-10 and MIG-2, as well as the cytoskeletal regulators Arp2/3 and activators WAVE-1 and WASP-1, UNC-34/Enabled, and UNC-115/abLIM [18-23], consistent with findings in other systems [7]. Mechanisms downstream of UNC-5 in axon repulsion are less well described, but the PH/MyTH4/FERM molecule MAX-1 and the SRC-1 tyrosine kinase have been implicated [24, 25]. We delineated a new pathway downstream of UNC-5 required for its inhibitory effects on growth cone protrusion, involving the Rac GEF UNC-73/Trio, the Rac GTPases CED-10 and MIG-2, and the cytoskeletal-interacting molecule UNC-33/CRMP [17].
Collapsin response mediating proteins (CRMPs) were first identified as mediators of growth cone collapse in response to the Semaphorin family of guidance cues [26], and we have shown that UNC-33/CRMP inhibits growth cone protrusion in response to Netrin signaling [17]. This motivated us to consider other mediators of Semaphorin-induced growth cone collapse in Netrin signaling. In Drosophila, the large multidomain cytosolic protein MICAL (Molecule Interacting with CasL) is required for the repulsive motor axon guidance mediated by interaction of Semaphorin 1a and Plexin A [27, 28]. MICAL proteins are a class of flavoprotein monooxygenase enzymes that bind flavin adenine dinucleotide (FAD) and use the cofactor nicotinamide dinucleotide phosphate (NADPH) to facilitate oxidation-reduction (Redox) reactions [27]. MICAL regulates actin disassembly and growth cone collapse in response to semaphorin via direct redox interaction with F-actin [29, 30]. MICAL molecules from Drosophila to vertebrates have a conserved domain organization: and N-terminal flavin-adenine dinucleotide (FAD)-binding monooxygenase domain, followed by a calponin homology (CH) domain, a LIM domain, a proline-rich domain, and a coiled-coil ERM a-like motif [27, 31].
The C. elegans genome does not encode for a MICAL-like molecule with the conserved domain organization described above. However, it does contain five flavin monooxygenase (fmo) genes similar to the Flavin monooxygenase domain of MICAL: fmo-1, fmo-2, fmo-3, fmo-4 and fmo-5 [32]. Like MICAL, the C. elegans FMO molecules contain an N-terminal FAD binding domain and a C-terminal NADP or NADPH binding domain [27, 32]. The C. elegans gene most similar to the non-FMO portion of MICAL is the Eps-15 homology domain binding protein EHBP-1 [33], which contains a CH domain as does MICAL.
In this work, we test the roles of the C. elegans FMOs and EHBP-1 in Netrin-mediated axon guidance and growth cone protrusion. We find that fmo-1, fmo-4, fmo-5 and ehbp-1 mutants display pathfinding defects of the dorsally-directed VD/DD motor neuron axons that are repelled by UNC-6/Netrin, and that they interact genetically with unc-40 and unc-5. We also find that VD growth cones in these mutants display increased filopodial protrusion, similar to mutants in repulsive UNC-6/Netrin signaling (e.g. unc-5 mutants), and that transgenic expression of FMO-5 inhibits growth cone protrusion, similar to constitutively-activated UNC-40 and UNC-5. We also show that FMO-1, FMO-4, FMO-5 and EHBP-1 are required for the growth cone inhibitory effects of activated UNC-5, UNC-40, and the Rac GTPases CED-10 and MIG-2. Together, these genetic analyses suggest that FMO-1, FMO-4, FMO-5, and EHBP-1 normally restrict growth cone protrusion, and that they might do so in UNC-6/Netrin-mediated growth cone repulsion.
Results
fmo-1,4,5 and ehbp-1 affect VD/DD axon pathfinding
The C. elegans genome lacks an apparent homolog of MICAL. However, it contains five flavin monooxygenase genes (fmo-1,2,3,4,5) (Figure 1A) [32]. The C. elegans molecule most similar to the non-FMO portion of MICAL is EHBP-1, the homolog of the mammalian EH domain binding protein 1 (Ehbp1) protein [33]. We analyzed existing mutations in fmo genes and ehbp-1 (Figure 1B) for VD/DD axon guidance defects. fmo-1(ok405) was a 1,301-bp deletion that removed part of exon 3 and all of exons 4, 5 and 6. fmo-2(ok2147) was a 1070-bp deletion that removed part of exon 4 and 5.fmo-4(ok294) was a 1490-bp deletion that removed all of exons 2, 3, 4 and 5. fmo-5(tm2438) is a 296-bp deletion which removes part of intron 3 and exon 4. These deletions all affected one or both predicted enzymatic domains of the FMO molecules. fmo-3(gk184651) was a G to A substitution in the 3’ splice site of intron 6. ehbp-1(ok2140) is a 1,369-bp deletion that removed all of exon 5 and 6.
The 19 D-class motor neurons cell bodies reside in the ventral nerve cord. They extend axons anteriorly and then dorsally to form a commissure, which normally extend straight dorsally to the dorsal nerve cord (Figure 2 and Figure 3B) On the right side of wild-type animals, an average of 16 commissures were observed, due to the fasciculation of some processes as a single commissure (Figure 2C and Materials and Methods). fmo-1,4 and 5 and ehbp-1 mutants showed significant defects in VD/DD axon pathfinding, including ectopic axon branching and wandering (∼3-5%; see Materials and Methods and Figure 3A, C and D). fmo-2 and fmo-3 mutations showed no significant defects compared to wild-type (Figure 3A). Most double mutants showed no strong synergistic defects compared to the predicted additive effects of the single mutants (Figure 3E). However, the fmo-2; fmo-3 and the fmo-2; fmo-4 double mutants showed significantly more defects compared to the predicted additive effects of the single mutants. The fmo-4; ehbp-1 double mutant displayed significantly reduced defects than either mutation alone. Lack of extensive phenotypic synergy suggests that the FMOs do not act redundantly, but rather that they might have discrete and complex roles in axon guidance, as evidenced by fmo-4; ehbp-1 mutual suppression.
Axon pathfinding defects of unc-40 and unc-5 are increased by fmo-1, fmo-4 and fmo-5 mutations
In unc-40(n324) strong loss-of-function mutants, most axons (92%) extended past the lateral midline despite wandering (see Materials and Methods and Figures 4A and B). fmo-1, fmo-4, fmo-5 and ehbp-1 displayed < 1% failing to extend past the lateral midline (Figure 4A). fmo-1, fmo-4, and fmo-5 mutations significantly enhanced the VD/DD lateral midline crossing defects of unc-40(n324) (Figure 4A and C). ehbp-1 did not enhance unc-40 (Figure 4A).
unc-5(e53) strong loss-of-function mutants display a nearly complete failure of VD axons to reach the dorsal nerve cord [13, 15]. unc-5(e152) is a hypomorphic allele [34] and displayed 22% failure of axons to cross the lateral midline (Figure 5A). The unc-5(op468) allele [35] also displayed a weaker lateral midline crossing phenotype (10%), indicating that it is also a hypomorphic allele (Figure 5B). fmo-1, fmo-4 and fmo-5 significantly enhanced the VD/DD axon guidance defects of both unc-5(e152) and unc-5(op468), but ehbp-1 did not (Figure 5). These results indicate that FMO-1,4, and 5 might act with UNC-40 and UNC-5 in VD/DD axon pathfinding.
fmo-1, fmo-4 and fmo-5 act cell-autonomously in the VD/DD neurons
Expression of the fmo-1, fmo-4 and fmo-5 coding regions were driven in VD/DD motor neurons using the unc-25 promoter. Punc-25::fmo transgenes significantly rescued lateral midline crossing defects in fmo; unc-5(op468) and fmo; unc-5(e152) (Figure 6). These data suggest that the axon defects observed in fmo mutants are due to mutation of the fmo genes themselves, and that fmo-1, 4, and 5 can act cell-autonomously in the VD/DD neurons in axon guidance.
Previous studies showed that fmo-1 and fmo-5 promoter regions were active in intestinal cells and the excretory gland cell, whereas the fmo-4 promoter was active in hypodermal cells, duct and pore cells [32, 36]. ehbp-1 is expressed in all somatic cells including neurons [33]. Furthermore, cell-specific transcriptome profiling indicated that fmo-1, fmo-4 and fmo-5 were expressed in embryonic and adult neurons, including motor neurons [37-39]. We fused the upstream promoter regions of fmo-1, fmo-4, and fmo-5 to gfp. We could observe no fmo-1::gfp expression in transgenic animals, in contrast to previous studies using a LacZ reporter [32]. However, transcriptome profiling indicates neuronal expression of fmo-1 [39]. Our fmo-1::gfp transgene might be missing regulatory regions required for expression. fmo-4::gfp was expressed strongly in hypodermal cells, excluding the seam cells and vulval cells, consistent with previous studies [32] (Figure 6D). We also observed fmo-4::gfp expression in cells in the ventral nerve cord (Figure 6 D and D’). Pfmo-5::fmo-5::gfp was expressed strongly in the intestine as previously reported [32] (Figure 6E). We also observed expression along the ventral nerve cord (Figure 6E and E’).
In sum, previous expression studies combined with those described here suggest that fmo-1,4,5 and ehbp-1 are expressed in neurons, and that fmo-1,4, and 5 can act cell-autonomously in the VD/DD motor neurons in axon guidance.
fmo-1, fmo-4 and fmo-5 mutants display increased growth cone filopodial protrusion
The growth cones of dorsally-directed VD commissural axons are apparent in early L2 larvae (Figure 2B). We imaged VD growth cones at 16 hours post-hatching, when the VD growth cones have begun their dorsal migrations, as described previously [15]. fmo-1, fmo-4 and fmo-5 mutant growth cones displayed longer filopodial protrusions compared to wild type (e.g. 0.96 μm in wild type compared with 1.55 μm in fmo-5(tm2438); p < 0.001) (Figure 7). This effect was not significant in ehbp-1(ok2140) (Figure 7). Growth cone area was not significantly different in any mutant. These results suggest that fmo-1, fmo-4 and fmo-5 normally limit growth cone filopodial protrusion length. This is consistent with ectopic axon branches observed in post-development VD/DD neurons in these mutants (Figure 3), as other mutants with increased growth cone filopodial protrusions (e.g. unc-5, unc-73, unc-33) also display ectopic branches, likely due to failure of filopodial retraction and subsequent consolidation into a neurite [15, 17].
fmo-1, fmo-4, fmo-5 and ehbp-1 mutations suppress activated myr::unc-40 and myr::unc-5 and activated Rac GTPases
Previous studies showed that UNC-6/netrin signaling via the heterodimeric UNC-40/UNC-5 receptor leads inhibition of growth cone protrusion important in UNC-6/Netrin’s role in repulsive axon guidance [15, 17]. Constitutive activation of this pathway using expression of myristoylated versions of the cytoplasmic domains of UNC-40 and UNC-5 (myr::unc-40 and myr::unc-5) results in small growth cones with few if any filopodial protrusions (i.e. protrusion is constitutively inhibited by MYR::UNC-40 and MYR::UNC-5) [15, 17, 18]. Loss of fmo-1, fmo-4, fmo-5 and ehbp-1 significantly suppressed inhibition of filopodial protrusion and growth cone size caused by myr::unc-40 (Figure 8) and myr::unc-5 (Figure 9).
Expression of activated CED-10(G12V) and MIG-2(G16V) in the VD neurons results in reduced growth cone protrusion similar to MYR::UNC-40 and MYR::UNC-5 [17]. We found that fmo-1, fmo-4 and fmo-5 suppressed filopodial protrusion deficits caused by ced-10(G12V) and mig-2(G16V) (Figure 10). ehbp-1 suppressed mig-2(G16V), but ehbp-1(ok2140M+);ced-10(G12V) double mutants were inviable and could not be scored. Furthermore, fmo-4 and fmo-5, but not fmo-1, significantly suppressed growth cone size reduction caused by CED-10(G12V) and MIG-2(G16V). ehbp-1 also suppressed growth cone size reduction of MIG-2(G16V). Taken together, these data indicate that functional FMO-1, FMO-4, FMO-5, and EHBP-1 are required for the full effect of MYR::UNC-40, MYR::UNC-5, CED-10(G12V), and MIG-2(G16V) on growth cone protrusion inhibition, including filopodial protrusion and growth cone size.
FMO-5 can inhibit growth cone protrusion
fmo-5 loss-of-function mutant growth cones displayed excessively protrusive filopodia (Figure 7) and suppressed activated UNC-40/UNC-5 and Rac signaling (Figures 8-10). Transgenic expression of wild-type FMO-5 driven by its endogenous promoter rescued the long filopodial protrusions seen in fmo-5(tm2438) mutant VD growth cones (Figure 11A-D). In a wild-type background, fmo-5 transgenic expression resulted in growth cones with smaller area and shortened filopodia (Figure 11E, F and H), indicating that wild-type FMO-5 activity can inhibit growth cone protrusion. This was not observed in the fmo-5(tm2438) background, possibly due to the decreased levels of FMO-5 compared to the wild-type background.
A pathway involving the Rac GTPases MIG-2 and CED-10, the Rac GEF UNC-73/Trio, and the putative cytoskeletal interacting molecule UNC-33/CRMP act downstream of MYR::UNC-40 to inhibit protrusion [17]. In this pathway, UNC-33/CRMP acts downstream of the Rac GTPases [17], similar to the FMOs and EHBP-1 described in Figure 10. unc-73(rh40) specifically attenuates the Rac GEF domain of UNC-73 and results in excessively-protrusive growth cones, including increased growth cone area and filopodial length [17] (Figure 11F). Transgenic fmo-5 expression in unc-73(rh40) resulted in inhibited growth cone area and filopodial length compared to unc-73(rh40) alone, suggesting that FMO-5 can inhibit protrusion in the absence of UNC-73 Rac GEF activity. Transgenic fmo-5 expression inhibited growth cone size in unc-33(e204), but had a reduced capacity to inhibit filopodial protrusion (i.e. filopodial protrusion in unc-33(e204) with transgenic fmo-5 expression was reduced compared to unc-33 alone but was increased relative to fmo-5 transgenic expression alone) (Figure 11E-I). In sum, these data indicate that that FMO-5 (and possibly FMO-1 and FMO-4) act downstream of the Rac GTPases MIG-2 and CED-10 in filopodial inhibition. FMO-5 might also act downstream of UNC-33, but the hybrid interaction of fmo-5 transgenic expression with unc-33(e204) mutants suggests that FMO-5 and UNC-33 might represent distinct pathways downstream of the Rac GTPases to inhibit filopodial protrusion.
Discussion
Results here implicate the C. elegans flavoprotein monooxygenase molecules FMO-1, FMO-4 and FMO-5 in inhibition of growth cone protrusion via UNC-6/Netrin receptor signaling in repulsive axon guidance. The MICAL molecule found in vertebrates and Drosophila is a flavoprotein monooxygenase required for semaphorin-plexin mediated repulsive motor axon guidance [27, 40]. MICAL is a multi-domain molecule that also includes a calponin homology (CH) domain, a LIM domain and multiple CC domains. No molecule encoded in the C. elegans genome has a similar multi-domain organization. However, the Eps-15 homology (EH) domain binding protein EHBP-1 is similar to the non-FMO portion of MICAL and contains a CH domain [33]. We show here that EHBP-1 also is also involved in inhibition of growth cone protrusion and axon guidance. Thus, while C. elegans does not have a multidomain MICAL-like molecule, it is possible that the functional equivalents are the FMOs and EHBP-1.
FMO-1, FMO-4, FMO-5 and EHBP-1 regulate axon guidance and growth cone filopodial protrusion. fmo-1, fmo-4, fmo-5, and ehbp-1 mutants display defects in dorsal guidance of the VD/DD motor axons that are repelled from UNC-6/Netrin (Figure 3). Double mutant analysis did not uncover significant redundancy, suggesting that these molecules might have discrete roles in axon guidance. Consistent with this idea, fmo-4 and ehbp-1 mutually suppress VD/DD axon guidance defects. fmo-2 and fmo-3 mutations displayed no significant defects alone, suggesting that they are not involved in axon guidance. fmo-2 did significantly enhance fmo-4. Possibly, fmo-2 and fmo-3 have roles in axon guidance that were not revealed by the mutations used.
Drosophila and vertebrate MICAL regulate actin cytoskeletal dynamics in both neuronal and non-neuronal processes through direct redox activity of the monooxygenase domain [27, 30, 41-45]. In Drosophila, loss of MICAL showed abnormally shaped bristles with disorganized and larger F-actin bundles, whereas, overexpression of MICAL caused a rearrangement of F-actin into a complex meshwork of short actin filaments [29]. Here we show that loss of fmo-1, fmo-4, and fmo-5 resulted in longer filopodial protrusions in the VD motor neurons (Figure 7), suggesting that their normal role is to limit growth cone filopodial protrusion. Indeed, transgenic expression of wild-type FMO-5 resulted in VD growth cones with a marked decrease in growth cone filopodial protrusion (Figure 11). Growth cone size was not affected in any loss-of-function mutation, but growth cone size was reduced by transgenic expression of wild-type FMO-5 (Figure 11), suggesting a role of the FMO-5 in both filopodial protrusion and growth cone lamellipodial protrusion.
Previous studies have shown that Drosophila MICAL may require both its FMO and CH domain to induce cell morphological changes; however, mammalian MICAL in non-neuronal cell lines requires only its FAD domain suggesting a difference in the mechanism of action in these MICALs [29, 46]. These data suggest that in some cases, the FMO domain is sufficient for the function of MICAL. Thus, single domain FMOs as in C. elegans could function despite lacking the multi-domain structure of MICAL. Loss of EHBP-1, which contains a CH domain and is similar to the non-FMO portion of MICAL (Figure 1), also resulted in VD/DD axon guidance defects, but did not significantly affect growth cone filopodial protrusion. EHBP-1 might act with the FMOs in axon guidance. Phenotypic differences could be due to EHBP-1-dependent and independent events, or to the wild-type maternal contribution in ehbp-1 homozygous mutants derived from a heterozygous mother. It is also possible that EHBP-1 affects axon guidance independently of the FMOs. EHBP-1 is involved in Rab-dependent endosomal vesicle trafficking by bridging interaction of endosomal Rabs with the actin cytoskeleton [33, 47]. MICAL has also been implicated in Rab-dependent endosomal biogenesis and trafficking [48-50], suggesting that FMO/EHBP-1 and MICALs might share common functions, although it remains to be determined if FMOs in C. elegans regulate endosomal trafficking.
MICAL has been shown to directly oxidize cysteine residues in F-actin, leading to actin depolymerization and growth cone collapse [29, 30, 51, 52]. We speculate that FMO-1, FMO-4, and FMO-5 might act by a similar mechanism to inhibit growth cone filopodial protrusion. The role of EHBP-1 is less clear, but previous studies have shown that Drosophila MICAL might require both its FMO and CH domain to induce cell morphological changes [29]. Thus, in axon guidance, FMO-1, FMO-4, and FMO-5 might require the CH domain provided by EHBP-1 in some instances. Mammalian MICAL requires only the FMO domain [46], suggesting that in some cases the CH domain is not required and the FMO domain can act alone. Future studies will be directed at answering these questions.
FMOs can act autonomously in the VD/DD neurons
Expression of full length fmo-1, fmo-4 and fmo-5 coding regions under the control of the unc-25 promoter specific for GABA-ergic neuron expression (including the VD/DD neurons) rescued VD/DD axon guidance defects (Figure 6). Furthermore, the promoters of fmo-4 and fmo-5 were active in ventral nerve cord cells (Figure 6). Cell-specific transcriptome profiling indicated that fmo-1, fmo-4 and fmo-5 were expressed in embryonic and adult neurons, including motor neurons [37-39]. Together, these results suggest that the FMOs can act cell-autonomously in the VD/DD neurons in axon guidance.
FMO-1, FMO-4 and FMO-5 mediate UNC-6/Netrin receptor signaling in growth cone inhibition of protrusion
Our findings suggest that the FMOs act with the UNC-40 and UNC-5 receptors to mediate UNC-6/netrin repulsive axon guidance and inhibition of growth cone protrusion. fmo-1, fmo-4, and fmo-5 mutations enhanced axon pathfinding defects in unc-40 and hypomorphic unc-5 mutants (Figures 4 and 5). ehbp-1 did not enhance unc-40 or unc-5, suggesting discrete roles of these molecules or wild-type maternal ehbp-1 contribution. However, fmo-1, fmo-4, fmo-5, and ehbp-1 mutations each suppressed the effects of activated MYR::UNC-40 and MYR::UNC-5 on inhibition of growth cone protrusion (Figure 9). In this case, both filopodial protrusion and growth cone area was restored, consistent with a role of these molecules in inhibiting both growth cone filopodial and lamellipodial protrusion. That the FMOs and EHBP-1 were required for the effects of the constitutively active MYR::UNC-40 and MYR::UNC-5 suggest that they act downstream of these molecules in growth cone inhibition of protrusion.
FMOs and EHBP-1 act downstream of Rac GTPase signaling in inhibition of growth cone protrusion
Similar to activated MYR::UNC-40 and MYR::UNC-5, constitutively-activated Rac GTPases CED-10(G12V) and MIG-2(G16V) inhibit VD growth cone protrusion. We show that fmo-1, fmo-4, fmo-5 and ehbp-1 mutations suppressed activated CED-10(G12V) and MIG-2(G16V) (e.g. double mutant growth cones displayed longer filopodial protrusions similar to fmo-1, fmo-4, fmo-5 and ehbp-1 single mutants) (Figure 10). Furthermore, loss of the Rac GTP exchange factor UNC-73/Trio had no effect on the inhibited growth cone phenotype of FMO-5 transgenic expression (i.e. the growth cones resembled those of fmo-5 over expression alone) (Figure 11). UNC-73/Trio acts with the Rac GTPases CED-10 and MIG-2 in growth cone protrusion inhibition, and unc-73 mutants display excessive growth cone protrusion [17]. That FMO-5 transgenic expression could inhibit protrusion in the absence of the Rac activator UNC-73/Trio suggests that FMO-5 acts downstream of UNC-73/Trio, consistent with the FMOs and EHBP-1 acting downstream of the Rac GTPases.
FMO-5 might act upstream of UNC-33/CRMP
Previous studies have shown that the C. elegans CRMP-like molecule UNC-33 is required in a pathway downstream of Rac GTPases for inhibition of growth cone protrusion in response to UNC-6/Netrin [17]. unc-33 loss-of-function mutants with FMO-5 transgenic expression displayed a mutually-suppressed phenotype. The excessively-long filopodial protrusions of unc-33 mutants were reduced to wild-type levels, but were significantly longer than in animals with FMO-5 transgenic expression, and the growth cone area was reduced to resemble FMO-5 transgenic expression alone (Figure 11). This phenotype could be interpreted as FMO-5 acting upstream of UNC-33/CRMP (i.e. UNC-33/CRMP is required for the full effect on FMO-5 overexpression). Alternatively, this hybrid phenotype could be interpreted as FMO-5 and UNC-33/CRMP acting independently to inhibit protrusion.
One proposed mechanism of cytoskeletal regulation by MICAL is the production of the reactive oxygen species (ROS) H2O2 by the FAD domain in the presence of NADPH [53]. Upon activation by Sema3A, MICALs generate H2O2, which can, via thioredoxin, promote phosphorylation of CRMP2 by glycogen synthase kinase-3, leading to microtubule growth cone collapse [54]. This is consistent with our genetic results suggesting that FMO-5 may function upstream of UNC-33/CRMP in modulating the cytoskeleton of the VD growth cones to inhibit growth cone filopodial protrusion. CRMPs have been shown coordinate both microtubules and actin in axon elongation and growth cone dynamics [55, 56]. Thus, the FMOs have the potential to inhibit growth cone protrusion through direct oxidation of F-actin resulting in depolymerization, and through redox regulation of the activity of UNC-33/CRMP.
Conclusion
In summary, we present evidence of a novel role of the C. elegans flavin-containing monooxygenase molecules (FMOs) in inhibition of growth cone protrusion downstream of UNC-6/Netrin signaling. The FMOs acted downstream of the UNC-6/Netrin receptors UNC-5 and UNC-40, and downstream of the Rac GTPases CED-10 and MIG-2. Future studies will determine if the FMOs regulate UNC-33/CRMP, if they cause actin depolymerization, or both, to inhibit growth cone protrusion.
Materials and methods
Genetic methods
Experiments were performed at 20°C using standard C. elegans techniques [57]. Mutations used were LGI: unc-40(n324), unc-73(rh40); LGII: juIs76[Punc-25::gfp]; LGIII: fmo-3(gk184651); LGIV: fmo-1(ok405), fmo-2(ok2147), lqIs128[Punc-25::myr::unc-40], unc-5(op468 and e152), unc-33(e204); LGV: fmo-4(ok294), fmo-5(tm2438), ehbp-1(ok2140M+); LGX: lqIs182[Punc-25::mig-2(G16V)]. Chromosomal locations not determined: lqIs129[Punc-25::myr::unc-40], lqIs296[Punc-25::myr::unc-5], lqIs204[Punc-25::ced-10(G12V)], lhIs6[Punc-25::mCherry], lqIs311[fmo-5 genomic] by integration of lqEx1047. Extrachromosomal arrays were generated using standard gonadal injection [58] and include: lqEx901 and lqEx931[Pehbp-1::gfp, Pgcy-32::yfp]; lqEx1014, lqEx1015, lqEx1016, lqEx1045, lqEx1046 and lqEx1047[Pfmo-5::fmo-5, Pgcy-32::yfp]; lqEx949, lqEx950, lqEx951, lqEx1053, lqEx1054 and lqEx1055[Punc-25::fmo-1, Pgcy-32::yfp]; lqEx1057, lqEx1058 and lqEx1060[Punc-25::fmo-4, Pgcy-32::yfp]; lqEx952, lqEx953, lqEx954, lqEx1061, lqEx1062, lqEx1063, lqEx1078, lqEx1079 and lqEx1080[Punc-25::fmo-5, Pgcy-32::yfp]; lqEx1113 and lqEx1114[Pfmo-5::fmo-5::GFP, Pstr-1::gfp]; whEx28[Pfmo-4::gfp, pRF4/rol-6]. Multiple (≥3) extrachromosomal transgenic lines of Pfmo-5::fmo-5 for overexpression data of fmo-5 were analyzed with similar effect, and one was chosen for integration and further analysis. Genotypes containing M+ indicate that homozygous animals from a heterozygous mother were scored. The ehbp-1(ok2140M+) strain was balanced with the nT1 balancer.
Transgene construction
Details about transgene construction are available by request. Punc-25::fmo-1, Punc-25::fmo-4 and Punc-25::fmo-5 were made using the entire genomic regions of fmo-1, fmo-4 and fmo-5 respectively. Expression analysis for fmo-5 was done by amplifying the entire genomic region of fmo-5 along with its endogenous promoter (1.2kb upstream) and fusing it to gfp followed by the 3’ UTR of fmo-5.
Analysis of axon guidance defects
VD neurons were visualized with a Punc-25::gfp transgene, juIs76 [59], which is expressed in GABAergic neurons including the six DDs and 13 VDs, 18 of which extend commissures on the right side of the animal. The commissure on the left side (VD1) was not scored. In wild-type, an average of 16 of these 18 VD/DD commissures are apparent on the right side, due to fasciculation of some of the commissural processes (Figure 2C). In some mutant backgrounds, fewer than 16 commissures were observed (e.g. unc-5). In these cases, only observable axons emanating from the ventral nerve cord were scored for axon guidance defects. VD/DD axon defects scored include axon guidance (termination before reaching the dorsal nerve cord or wandering at an angle greater than 45° before reaching the dorsal nerve cord), lateral midline crossing (axons that fail to extend dorsally past the lateral midline) and ectopic branching (ectopic neurite branches present on the commissural processes). Fisher's exact test was used to determine statistical significance between proportions of defective axons. In double mutant comparisons, the predicted additive effect of the mutants was calculated by the formula P1+P2-(P1*P2), where P1and P2 are the phenotypic proportions of the single mutants. The predicted additive effect of single mutants was used in statistical comparison to the observed double mutant effect.
Growth cone imaging
VD growth cones were imaged as previously described [15, 22]. Briefly, animals at 16 h post-hatching at 20°C were placed on a 2% agarose pad and paralyzed with 5mM sodium azide in M9 buffer, which was allowed to evaporate for 4 min before placing a coverslip over the sample. Some genotypes were slower to develop than others, so the 16 h time point was adjusted for each genotype. Growth cones were imaged with a Qimaging Rolera mGi camera on a Leica DM5500 microscope. Projections less than 0.5 μm in width emanating from the growth cone were scored as filopodia. Filopodia length and growth cone area were measured using ImageJ software. Filopodia length was determined by drawing a line from the base where the filopodium originates on the edge of the peripheral membrane to the tip of the filopodium. Growth cone area was determined by tracing the periphery of the growth cone, not including filopodial projections. Significance of difference was determined a two-sided t-test with unequal variance.
Acknowledgments
The authors thank members of the Lundquist and Ackley labs for discussion, E. Struckhoff for technical assistance, and C. Dolphin for fmo strains and reagents. Some C. elegans strains were provided by the CGC, which is funded by NIH Office of Research Infrastructure Programs (P40OD010440). This work was supported by NIH grants R01NS040945, R56NS095682, and R21NS070417 to E.A.L., the University of Kansas Center for Molecular Analysis of Disease Pathways (NIH P20GM103638), and the Kansas Infrastructure Network of Biomedical Research Excellence (NIH P20GM103418), through which A.M.S. is a KINBRE Undergraduate Research Scholar.