The Metalloproteinase adam19b Is Required for Sensory Axon Guidance in the Hindbrain

Abstract

Little is known about the molecular and cellular mechanisms involved in the formation of the cranial peripheral sensory system in vertebrates. To identify genes involved in the formation of these circuits, we performed a forward genetic screen utilizing a transgenic zebrafish line (p2rx3.2:gfp^sl1) that expresses green fluorescent protein (gfp) in sensory neurons of the Vth, VIIth, IXth and Xth cranial ganglia. Here, we describe a novel zebrafish mutant in which a missense mutation in the adam19b gene selectively affects the epibranchial sensory circuits.

Introduction

The peripheral sensory nervous system serves as an interface between the internal and external environments and the central nervous system (CNS). The information it carries must be relayed with precision so that appropriate behavioral and/or physiological responses are made. A subset of cranial nerves (V, VII, IX and X) containing both motor and sensory axons innervates structures in the head and neck, as well as the non-pelvic viscera. The sensory axons within these nerves originate from four distinct cranial sensory ganglia (CSG): the trigeminal (Vth), the facial (VIIth), the glossopharyngeal (IXth) and the vagal (Xth). These neurons transduce somatosensory, chemosensory and viscerosensory stimuli from peripheral receptors/organs and terminate within discrete regions of the hindbrain in a topographic fashion (Butler and Hodos, 2005). However, the genetic programs responsible for establishment of these circuits are poorly understood.

A powerful approach to identify genes involved in developmental programs is the forward genetic screen. To identify genes utilized in sensory circuit formation, we carried out a forward screen in a transgenic zebrafish line Tg(p2rx3.2:gfp^sl1; 3.2:gfp) that expresses green fluorescent protein (gfp) in sensory neurons of the Vth, VIIth, IXth and Xth cranial ganglia (Kucenas et al., 2006). One mutant line, 3.2:gfp^sl19 (sl19), showed aberrant projections of only the epibranchial axons. Here, we present data showing sl19 is the metalloprotease adam19b and is critical for sensory circuit formation.

Materials and Methods

Maintenance of Fish

All animal husbandry and staging was carried out according to Kimmel et al. (1995). Embryos used for microscopy were treated with 0.003% phenylthiourea to reduce pigmentation (for transgenic fish lines used in this study, see Supplementary Table S1).

Positional Cloning

Standard mapping methods using bulk segregant and meiotic recombination analysis of microsatellite markers (Green et al., 2009; Cox et al., 2014) were used to map the sl19 mutation to a critical interval on chromosome 14. Total RNA was then extracted from mutant and wild type 4 days post fertilization (dpf) larvae and cDNA synthesized with Superscript III reverse transcriptase (Invitrogen, Carlsbad, CA, USA). cDNAs encoding candidate genes within the critical interval were sequenced using gene specific primers.

Embryo Injections

RNA (100 pg/nl) or morpholino oligonucleotides (MO; Gene Tools, 1–2 ng/nl, Supplementary Table S2) were injected as previously described (Cox et al., 2014).

Imaging of Larvae

Imaging was carried out as described previously (Cox et al., 2014). Final brightness and/or contrast values of images were adjusted in Adobe Photoshop CC 2017.

Immunohistochemistry

This was performed as described in a previous article (Cox et al., 2014). Images were obtained by confocal microscopy as described above.

Wholemount in situ Hybridization

In situ hybridization (ISH) was performed as previously described (Kucenas et al., 2006). Primers were designed from the predicted sequence of the zebrafish adam19b mRNA (Supplementary Table S3) and a 600 bp fragment was obtained by PCR from 4-day-old zebrafish cDNA. This fragment was cloned into pBSII(+; Promega) and used to prepare digoxigenin-labeled RNA.

CRISPR/Cas9 Gene Editing

An RNA oligo complementary to a sequence in exon 2 of adam19b was designed using http://chopchop.cbu.uib.no/ (Supplementary Table S4). Alt-R oligos were synthesized by IDT. A complex consisting of Alt-R oligos and Cas9 protein (IDT) was injected into single cell zebrafish embryos according to the method of Essner as reported on the IDT website. To validate CRISPR/Cas9 targeting, genomic DNA was isolated at 4 dpf from control and injected larvae, exon 2 was amplified by PCR (see Supplementary Table S4 for primers) and the products sequenced.

Results

The sl19 Mutation Selectively Affects Cranial Sensory Circuits

A forward genetic screen investigating zebrafish cranial sensory circuit formation was performed using the reporter strain 3.2:gfp (Kucenas et al., 2006; Figure 1A, Supplementary Figures S1). 3.2:gfp^sl19 (sl19) was one of several mutant lines detected. sl19 showed a recessive Mendelian inheritance: mutants constituted 27% ± 6 of larvae in a clutch (n = 235/870 from nine clutches). By 4dpf, the sl19 line contained defects in the central projections of the epibranchial ganglia (gVII, gIX and gX; Figure 1B, Supplementary Figures S1); in all cases the axons projected to the hindbrain as normal, but once in the hindbrain, the axons showed aberrant pathfinding to their targets. While there was considerable variability in the misrouting of the axons, gVII axons typically failed to turn caudally towards the afferent plexus in the viscerosensory column and instead continued in a dorsal direction with no discernable terminal field (Supplementary Figures S1D,F). In some mutants, gIX axons turn rostrally instead of caudally towards the plexus and stop anteriorly to gVII nerve (Supplementary Figures S1C,F); sometimes gIX axons pathfind rostrally, then join gVII and turn towards the plexus Supplementary Figure S1E. In most cases, gX axons do not branch to form a normal hindbrain plexus (Supplementary Figures S1C,D,F). The gV projections do not appear to be affected in this mutant (Figure 1B, Supplementary Figure S1). These phenotypes were never observed in wild-type larvae (n > 5,000).

Figure 1

The sl19 Mutation Maps to the Metalloprotease Gene adam19b

Linkage mapping indicated that the sl19 allele was located on Chromosome 14, and high-resolution positional cloning identified a C > T mutation located within exon 17 of adam19b (Figure 1C) as the potential causative lesion. This nucleotide switch converts an arginine to a cysteine at amino acid 673. adam19b encodes a member of the A Disintegrin and Metalloproteinase (ADAM) family, and is a 923 amino acid Type I transmembrane protein composed of a series of conserved domains that include: a signal sequence, a pro-domain, a metalloproteinase domain, a disintegrin domain, a cysteine-rich domain (CRD), an EGF-like domain, a transmembrane region and a C-terminus containing signaling-related motifs (e.g., SH3 sequences; White, 2003; Figure 1C). The sl19 mutation is within the CRD of the protein, a region that has been shown to be critical for the protein’s metalloprotease activity (Smith et al., 2002; Kang et al., 2004). Supplementary Figure S2 shows an alignment of several vertebrate CRDs.

adam19b Expression Includes the Cranial Sensory Ganglia and Hindbrain

Whole mount ISH revealed adam19b mRNA in the CSG (Figure 1D). Expression was detectable in the ganglia early, present in the trigeminal (gV) and both lateral line ganglia at 24 hpf. In 48 hpf embryos, expression was detected in the CSG and also in CNS structures such as the cerebellar plate and optic tectum. By 72 hpf, adam19b expression included all of the CSG as well as cells in the retina, olfactory epithelium and hindbrain: this was also the pattern seen in 4 dpf larvae.

Ectopic/Overexpression of adam19b RNA Induces a Phenotype Resembling sl19

One approach to validating the identity of a candidate gene is to rescue the phenotype of the mutant by injection of the wild type full-length RNA. When full length adam19b RNA was injected into embryos from sl19^+/– in-crosses (three separate experiments), we unexpectedly observed a significant increase in the number of 4 dpf larvae exhibiting the mutant phenotype: 47% (57/121) of injected embryos had a mutant phenotype compared to 25% in un-injected clutchmates (n = 26/102; p < 0.0013, Fisher’s exact test; Figure 1E). This suggested that over-expression of adam19b induced perturbations in afferent circuits. To validate this hypothesis, full length adam19b RNA was injected into single-cell wild type 3.2:GFP embryos. This resulted in disruption of the epibranchial afferents, phenocopying sl19, in 24% of the 4 dpf embryos (9/37; Figure 1F). These findings indicate that appropriate guidance molecule processing by adam19b is critical for epibranchial axon pathfinding.

Knockdown of adam19b in Wild-Type Embryos Phenocopies sl19

We predicted that knock-down of adam19b would phenocopy the sl19 mutant. To test this, we used a morpholino targeting the start codon of adam19b (MO1). Injection of MO1 (2–4 ng) resulted in 19% of injected 4 dpf larvae exhibiting a phenotype resembling sl19: misrouting of the projections of the VIIth, IXth and Xth ganglia, but not those of the Vth (Figure 2A; n = 29 out of 156, six clutches vs. 0/127 of un-injected controls, p < 0.0001, Fisher’s Exact Test). Injection of a second morpholino (MO2), designed against the e17i17 splice junction, gave similar phenotypes (Supplementary Figure S3). To further validate adam19b as the affected gene and to address known concerns with the use of morpholinos, CRISPR/Cas9 targeting of exon 2 in adam19b in wild-type 3.2:GFP embryos was performed. These 4 dpf larvae phenocopied sl19 (n = 11 out of 49, three clutches, vs. 0/54 un-injected controls, p < 0.0001 Fisher’s Exact Test; Figure 2B). Confirmation of CRISPR/Cas9 targeting by sequencing is shown in Supplementary Figure S4. Combined, these results strongly support a role for adam19b in epibranchial afferent pathfinding.

Figure 2

Knockdown of sl19 Has No Effect on the Non-epibranchial Cranial Nerves

To determine if adam19b is required for the formation of other peripheral cranial circuits, we again turned to CRISPR/Cas9 targeting of exon 2 in transgenic fish. In 4 dpf larvae exhibiting defects in epibranchial circuits (Supplementary Figures S5, S6), we did not detect any perturbations in either lateral line circuits [Tg(p2rx3.2GR:nsfB-mcherry;cfos:gfp.sill); Figures 2C,D; Supplementary Figure S5; n = 0/41 or branchiomotor projections (Tg(p2rx3.2:gfp;hsp70:nsfB-mcherry.crest)); Figures 2E,F; Supplementary Figure S6; n = 0/32]. These results suggest that adam19b is utilized selectively by the epibranchial sensory neurons in their pathfinding to hindbrain targets.

sl19 Does Not Affect Hindbrain Organization

The configuration of the branchiomotor neurons and their axons was not affected at 4 dpf by adam19b CRISPR/Cas9 targeting (Figures 2E,F). This suggests that adam19b does not have a critical role in the segmental organization of the hindbrain. To verify this, we used immunostaining of acetylated tubulin, which labels axons throughout the CNS and periphery. As seen in Figures 2G,H, there are no gross perturbations in the CNS in sl19 mutants at 4 dpf (n = 52): the organization of the optic tectum, the cerebellum and commissural neurons appear normal.

Discussion

ADAMs are transmembrane zinc metalloproteases that contain multiple functional domains (Seals and Courtneidge, 2003). Members of this family have been shown to be involved in numerous cellular processes, such as adhesion, migration, proteolysis and signaling (Wolfsberg et al., 1995; Primakoff and Myles, 2000; Seals and Courtneidge, 2003; White, 2003). One member of this family, adam19, has been reported to have a role in neural crest migration, neuromuscular junction formation and cardiac development (Kurohara et al., 2004; Yumoto et al., 2008; Neuner et al., 2009; Schiffmacher et al., 2014). Adam19 is expressed in many tissues including the CSG (Kurisaki et al., 1998; Shirakabe et al., 2001; Yan et al., 2011), but its function in these neurons is unknown. In this report we demonstrate that the zebrafish ortholog, adam19b, plays a critical role in epibranchial sensory circuit formation.

We have identified a mutant, sl19, in which only the epibranchial afferents are misrouted. Positional cloning revealed a lesion (R673C) in the CRD of adam19b. Studies have shown that this region is critical for the post translational processing necessary for its protease and disintegrin functions (Blobel, 1997; Smith et al., 2002). Kang et al. (2002, 2004) have shown that the disulfide bonds formed between the cysteine residues in the CRD are critical for sheddase activity in the human ADAM19. We hypothesize that in sl19 the introduction of an extra cysteine leads to disordered formation of intra-domain disulfide bonds, disrupting the topology of the CRD and resulting in abnormal folding of the protein. As a result, adam19b could fail to translocate to the cell surface, or alternatively the CRD may not fold properly, resulting in either lack of conversion to an active form or alteration in the substrate specificity of the active form. Since the phenotype is recapitulated by depletion of adam19b in wild type larvae, we favor the hypothesis that sl19 is a loss of function mutant, rather than one with altered function; such a loss would result in disruption of the guidance cue recognition by these axons, leading to their variable misrouting. Given the expression of adam19b, it remains to be determined whether it is loss of function in axons or in the hindbrain (or both) that is responsible for the defects found.

It is striking that only the epibranchial sensory axons are affected in zebrafish in sl19 and not other circuits such as the trigeminal, lateral line or branchiomotor nerves. This suggests that the molecular targets of adam19b are critical for axon guidance of viscerosensory afferents, but not mechanosensory or branchiomotor axons. The identification of these substrates will require additional investigation.

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