Abstract
Unlike adult mammals, zebrafish regenerate spinal cord tissue and recover locomotor ability after a paralyzing injury. Here, we find that ependymal cells in zebrafish spinal cords produce the neurogenic factor Hb-egfa upon transection injury. Animals with hb-egfa mutations display defective swim capacity, axon crossing, and tissue bridging after spinal cord transection, associated with disrupted indicators of neuron production. Local recombinant human HB-EGF delivery alters ependymal cell cycling and tissue bridging, enhancing functional regeneration. Epigenetic profiling reveals a tissue regeneration enhancer element (TREE) linked to hb-egfa that directs gene expression in spinal cord injuries. Systemically delivered recombinant AAVs containing this zebrafish TREE target gene expression to crush injuries of neonatal, but not adult, murine spinal cords. Moreover, enhancer-based HB-EGF delivery by AAV administration improves axon densities after crush injury in neonatal cords. Our results identify Hb-egf as a neurogenic factor necessary for innate spinal cord regeneration and suggest strategies to improve spinal cord repair in mammals.
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Introduction
Adult mammals including humans display little or no regeneration in response to spinal cord injury, leading to sensorimotor deficits and paralysis. The pathophysiology of spinal cord injury is multifaceted and complex. It requires treatments acting not only on movement and sensation, but also on associated complications of respiratory, cardiovascular and urinary systems1. Rehabilitation can minimize deficits after moderate spinal cord injuries, and electrical stimulation has been shown to provide some benefits in recent years. Yet, they both fail to fully restore cell composition and function of the endogenous, damaged tissue, leaving individuals with spinal cord injury paralyzed for life in most cases. Consistent with initial results in opossum2, a recent study reported that the neonatal mouse spinal cord can mount a regenerative response to spinal cord injury that permits the growth of long projecting axons through lesion sites3. Stage-specific roles of immune cells like microglia were implicated as one component of this transient regenerative capacity3. Other candidate stage-dependent influences on the potential for mammalian spinal cord regeneration include the tissue composition of scar-forming fibroblasts or glial cells4,5,6,7,8, developmental changes in growth, survival, or metabolic programs9,10,11, and alterations in chromatin environment or transcription factor binding that might affect gene expression underlying any of the above processes12,13.
The study of high regenerative capacity in non-mammalian vertebrates is a centuries-old strategy to identify determinants of regeneration. Of note, laboratory zebrafish can fully regenerate and recover function after complete spinal cord transection and crush injuries, at any point in life14,15,16. Spinal cord injury in adult zebrafish triggers proliferation of ependymo-radial glial cells (ERGs) lining the central canal, also referred to as “radial glia”, “tanycytes” and “ependymoglia”15,16,17,18,19,20,21. A subpopulation of glial progeny helps form a tissue bridge between the rostral and caudal stumps, events that depends on signaling by Fibroblast growth factors (Fgfs) and Connective tissue growth factor a (Ctgfa)19,22. Though a topic of debate, these bridges have been proposed to serve as possible scaffolds across which axons extend to re-establish functional connections19,22. A variety of intrinsic and extracellular factors have been implicated in guidance of axons across the lesion site in adult zebrafish, among which are secreted proteins (Sema4D), extracellular matrix components (Tenascin-C), scaffolding proteins (Syntenin-A), transcription factors (Atf3 and 6), microRNAs (mi133) and immune-cell derived factors (Neurotrophin 3)23,24,25,26,27,28.
ERGs are also the source of new neurons in the vicinity of the lesion16,17. Although zebrafish ERGs are grossly homogeneous in morphology, their dorsoventral position with respect to the central canal has been reported to define their neuronal progeny after spinal cord injury, predicting whether they give rise to motoneurons or interneurons15,20,29. Similar progenitors with the ability to produce neurons also exist in the mammalian spinal cord, but they possess low neurogenic potential in vivo30. In this study, we examined transcriptomes for factors that are induced during the regeneration of injured adult zebrafish spinal cords and that may have neurogenic roles, and our experiments highlighted a key role for signaling by Heparin-binding epidermal growth factor (Hb-egf). Hb-egf is a secreted glycoprotein member of the epidermal growth factor (Egf) family of growth factors, and it signals through Egf receptor (Egfr) and the related receptor tyrosine kinase ErbB431. Binding of Hb-egf to its receptors triggers known downstream cascades, the most common of which are the mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) pathway, the (PIK3)/protein kinase B (Akt) pathway and the phospholipase Cγ (PLCγ) pathway. Wnt and Notch signaling cascades also act downstream of Hb-egf. Hb-egf has been implicated in neurogenesis during retinal regeneration in zebrafish using morpholino knockdown techniques32, and it has also been reported to induce neurogenesis in the hippocampal subventricular zone and dentate gyrus in mice and rats33,34.
Here, we employed a variety of molecular genetic, biomaterials, and profiling approaches in zebrafish to demonstrate a new role for Hb-egfa, produced by one of the zebrafish hb-egf paralogs, in innate spinal cord regeneration. We find that Hb-egfa is synthesized in ERGs at lesion sites and is required for neurogenesis and, ultimately, for axon crossing events and functional recovery. With a cross-species strategy that enlists hb-egfa-linked DNA control elements of zebrafish, we find that targeted HB-EGF delivery can boost axon density in mammalian spinal cord injury sites.
Results
Spinal cord injury induces expression of hb-egf genes
In an expression profiling experiment for potentially neurogenic growth factor genes induced during zebrafish spinal cord regeneration, we noted that both gene paralogs of heparin-binding epidermal growth factor, hb-egfa and hb-egfb, display sharp increases in RNA levels at 1 week after transection injury (wpi) (Fig. 1a–c, Supplementary Fig. 1b, c and Supplementary Data 1). In situ hybridization (ISH) visualized low presence of hb-egfa transcripts in uninjured spinal cord, which increased sharply in stump ependymal cells after transection injury, as well as in other cells surrounding the central canal (Fig. 1b and Supplementary Fig. 1b). hb-egfb expression was undetectable in uninjured spinal cord but could be detected sparsely in cells throughout the injured cord stumps at 1 and 2 wpi (Fig. 1c and Supplementary Fig. 1c). We assessed transcriptomic datasets for uninjured and 1 wpi cords, finding expression changes in several downstream targets of Hb-egf by pathway analysis of differentially modulated genes. These targets included Akt, the extracellular signal-regulated kinase ERK1/2, and Erbb receptors, previously shown to mediate downstream Hb-egf signaling cascades35 (Supplementary Fig. 1a).
To better visualize cell types expressing hb-egf after spinal cord injury, we generated reporter lines representing each paralogue. Sham-injured transgenic hb-egfa:EGFP fish, generated with ~100 kb BAC sequences spanning the hb-egfa locus, displayed little or no detectable enhanced green fluorescent protein (EGFP) expression in cord tissue (Fig. 1d). Upon spinal cord transection, hb-egfa-directed EGFP was detected by 1 wpi in cells lining the central canal, mimicking hb-egfa ISH patterns (Fig. 1d). At this timepoint, fluorescence largely co-localized with Sox2 and GFAP, markers of ERGs and glia, respectively, and showed indicators of cell cycling at 1 wpi in 5-ethynyl-2′-deoxyuridine (EdU) incorporation assays (Fig. 1e–g and Supplementary Fig. 1d). hb-egfa:EGFP partially colocalized with the neuronal marker HuC/D at 1 wpi, with ~10% of Hu/D+ cells also expressing EGFP (Supplementary Fig. 1e, f). hb-egfa:EGFP fluorescence largely faded by 6 wpi, at which point regeneration typically nears completion (Supplementary Fig. 1g). Interestingly, we found that both hb-egfa mRNA and hb-egfa:EGFP displayed a polarized distribution, with greater signals in caudal vs. rostral ends (Fig. 1b and Supplementary Fig. 1h, i), a distribution that we did not observe for other genes implicated in spinal cord regeneration like ctgfa, igf, and pdgfa (Supplementary Fig. 1j)19,36,37.
We assessed expression of hb-egfb by generating an EGFP knock-in allele, revealing negligible fluorescence in uninjured hb-egfbEGFP spinal cords and diffuse EGFP at 1 and 2 wpi (Fig. 1h and Supplementary Fig. 1c). Consistent with ISH, hb-egfbEGFP-directed fluorescence was poorly represented in ependymal cells around the central canal or at sites of tissue bridging (Fig. 1h and Supplementary Fig. 1k). Expression of the potential Hb-egf receptors Erbb4 and Egfr was undetectable in uninjured animals. By 1 wpi, Erbb4 protein was mostly localized in cells at the lesion site. Erbb4 showed little or no expression in ERGs lining the central canal (Fig. 1i). By contrast, egfra receptor transcripts were detectable in cells lining the central canal, the spinal cord domain where ERGs reside (Fig. 1j). Thus, hb-egf paralogs, receptors, and bioinformatically identified targets are induced after spinal cord injury, with the hb-egfa paralog displaying more prominent expression in ERG progenitors.
Hb-egfa is required for zebrafish spinal cord regeneration
To test requirements for hb-egf gene function during spinal cord regeneration, we removed sequences between exons 1 and 4 of hb-egfa (referred to as hb-egfaKO) and exons 3 and 4 of hb-egfb (referred to as hb-egfbKO) using CRISPR/Cas9 editing (Supplementary Fig. 2a, b). Animals with mutations in both hb-egf paralogues (hb-egf dKO) were generated and analyzed first, given the possibility of compensatory effects by gene paralogs that can mask phenotypes in zebrafish38. hb-egf dKO animals showed no detectable hb-egf mRNAs at 1 wpi and are viable to adulthood (Supplementary Fig. 2c, d). These animals showed minimal Sox2+ ERG cycling when uninjured like their wild-type clutchmates, assessed by incorporation of 5-ethynyl-2′-deoxyuridine (EdU) (Supplementary Fig. 2e, f), and they displayed grossly normal swim behavior (Fig. 2a and Supplementary Fig. 2g, h).
We subjected mutant animals to spinal cord injury and assessed regeneration at multiple timepoints, at histological and/or functional levels. We first assessed spinal cord function by testing the ability of animals to swim against increasing velocities of water currents. Our experiments revealed measurably reduced swim capacity in hb-egf dKO animals in the weeks following spinal cord injury, particularly at the 6 wpi timepoint (Fig. 2a). Notably, just by viewing animals in their standard aquarium setting at 4 wpi, we could discern less frequent or fluid swimming activities in hb-egf dKO animals compared with their wild-type clutchmates (Supplementary Movies 1 and 2). Reduced swim capacity was also indicated at 8 wpi (Supplementary Fig. 2i). We then directly assessed axon crossing across the tissue bridge by anterograde labeling, finding that hb-egf dKO animals showed ~80% reduction in rostrocaudal axon crossing compared to wild-types at 4 wpi (Fig. 2b, c). We finally measured tissue bridges, comprising both glia and neurons, by staining longitudinal sections of hb-egf dKO and wild-type spinal cords at 4 wpi for glial and axonal markers. The average diameter of bridges was reduced by ~59% in hb-egf dKO animals compared to wild-type clutchmates (Fig. 2d, e).
To assess which paralog(s) has an important function in spinal cord regeneration, we performed the same assays in hb-egfa and hb-egfb single mutants. Swim performance after spinal cord injury was reduced in hb-egfaKO animals compared to controls, with swim behavior in aquaria at 4 wpi noticeably different from wild-types, as observed with hb-egf dKO animals. Swim capacity in hb-egfbKO mutants was comparable to wild-types (Fig. 2f and Supplementary Movies 3 and 4). Correspondingly, hb-egfaKO animals showed a ~41% decrease in rostrocaudal axon crossing compared to wild- types at 4 wpi, whereas hb-egfbKO animals displayed no measureable defects (Fig. 3g, h). Furthermore, hb-egfbKO animals displayed similar tissue bridging compared to wild-types after spinal cord injury. By contrast, we observed a ~80% reduction in tissue bridging in hb-egfaKO zebrafish (Fig. 2i, j). Thus, hb-egf gene knockout delays and/or disrupts spinal cord regeneration, with our expression data and mutant analysis indicating Hb-egfa is the more crucial gene product of the two paralogs during spinal cord regeneration.
Impaired neurogenesis underlies defects in hb-egfa mutants
To initially chart the phenotype of hb-egfa mutants, we performed single-cell RNA sequencing (scRNAseq) profiling of wild-type and hb-egfaKO spinal cords that were sham-injured or at 1 wpi (Fig. 3a and Supplementary Fig. 3a–c). Unsupervised clustering of 10,652 cells revealed 22 cell clusters, including major spinal cord cell types, endothelial cells, and immune cells, identifiable by specific marker genes (Fig. 3b). Cell cluster composition was similar in the 4 groups (Fig. 3c), and no substantial differences were observed in the proportion of each cell type identified between wild-type and hb-egfaKO samples at this early stage (Supplementary Fig. 3d). hb-egfa was most enriched in ERG progenitor clusters, identified by expression of sox2, foxj1a, ccnd1 and mki67 (Fig. 3d and Supplementary Fig. 3f), and it was also expressed at low levels in other cell types including oligodendrocyte progenitors, neutrophils, neuroepithelial cells and mature neurons (Supplementary Fig. 3e).
To assess intercellular communication networks involving Hb-egf, we used CellChat to detect potential ligand-receptor pairing among the 22 cell clusters (Supplementary Fig. 3g). This analysis identified 81 signaling pathways showing activity during spinal cord regeneration, including those previously implicated like Tnf, Pdgf, Sema, Tenascin and Igf signaling23,36,37,39,40 (Supplementary Fig. 3h). Oligodendrocyte precursors displayed the most predicted signaling interactions, followed by mature oligodendrocytes, radial glial progenitors, interneurons and mature neurons (Supplementary Fig. 3h). Notably, EGF signaling was among the most represented pathways in wild-type samples at 1 wpi, most often as interactions between Hb-egfa ligand (produced predominantly but not exclusively by ERGs) and its Egfra receptor signaling in a variety of cell types (Supplementary Fig. 3i). Cell types interpreted as major influencers controlling Hb-egfa communication were endothelial cells, neutrophils, oligodendrocyte precursors, and radial glial progenitors, the last two of which were also interpreted as mediators (Supplementary Fig. 3j, k).
To assess effects of Hb-egfa deficiency on ERGs, we first performed Gene Ontology comparisons of expression signatures of wild-type and hb-egfaKO ERGs. hb-egfa mutant cells displayed limited induction of genes associated with neuron development and differentiation at 1 wpi, compared to the responses of wild-type ERGs (Fig. 3e, f). Analysis of canonical pathways revealed highest enrichment of components involved in Synaptogenesis and Axon Growth in 1 wpi wild-type ERGs, whereas pathways related to Fibrotic events were most enriched in hb-egfaKO ERGs (Supplementary Fig. 3l, m). Injury-associated increases in levels of neuronal markers such as neuroD4, sox11b and adcyap, as assessed by qPCR, were greater in wild-type spinal cords vs. hb-egfaKO cords at 1 wpi and 2 wpi (Supplementary Fig. 3n).
The dominant expression domains of hb-egfa by all expression assays were ERGs and their 2 major derivatives, glia and HuC/D+ neurons, in that order. To visualize ERG behavior in situ, we assessed cycling of Sox2+ cells at 1 wpi by EdU incorporation or PCNA immunostains. These experiments indicated a ~35% reduction in ERG cycling in hb-egfaKO animals as compared to wild-type clutchmates (Fig. 3g, h and Supplementary Fig. 4a, b). hb-egf dKO animals displayed a similar, ~52% reduction in Sox2+ ERG cycling compared to wild-types, whereas hb-egfbKO values were comparable to controls (Fig. 3g–i and Supplementary Fig. 4a, b). To test effects of hb-egf mutations on gliogenesis, which could occur by ERG differentiation or by direct glial cell division, we measured EdU incorporation in GFAP+ cells. We observed a ~52% reduction in cycling in injured hb-egf dKO cords compared to controls at 1 wpi (Supplementary Fig. 4c, d). Most cycling glial cells at this time were located dorsally around the central canal (Supplementary Fig. 4c). hb-egfa-directed fluorescence partly co-localized with a transgenic marker for the bridging glial marker ctgfa at 2 wpi (Supplementary Fig. 4e), as would be predicted by recent single-cell RNA-seq datasets41. Yet, there was no detectable difference in ctgfa mRNA expression patterns in hb-egfdKO cords, or in hb-egfa mRNA expression patterns in ctgfa mutant cords, that might have suggested a regulatory relationship (Supplementary Fig. 4f, g).
To visually assess neurogenesis to stages beyond ERG cell cycle entry, we performed spinal cord transection in mutant animals and measured EdU incorporation into cells expressing the neuronal marker HuC/D+ in regions near the lesion at 1 wpi. This assay indicated ~57% and ~65% reductions in HuC/D+ neuron labeling in hb-egf dKO and hb-egfaKO bridging sites, with no detectable difference between hb-egfbKO and control values (Fig. 3j, k). EdU incorporation indices into rostral and caudal neurons were similar, with decreases from wild-types in each domain in hb-egfaKO and hb-egf dKO cords (Supplementary Fig. 4k). EdU incorporation into HuC/D+ cells was similar between wild-type, hb-egfaKO, hb-egfbKO, and hb-egf dKO at a later stage of 2 wpi (Supplementary Fig. 4l). Axon regeneration was grossly normal in hb-egf dKO larvae after severing a small bundle of spinal cord axons, suggesting that Hb-egfa does not have a direct role to promote axon crossing during spinal cord regeneration (Supplementary Fig. 4m, n). For insights into mechanisms by which Hb-egfa supports neurogenesis at early stages after injury, we used Panther42 to perform statistical overrepresentation tests using the list of genes differentially modulated at 7 dpi in hb-egf dKO ERGs compared to hb-egf WT ERGs. Interestingly, genes involved in Notch and Wnt signaling pathways were over-represented in the gene list, with reductions in expression levels of genes implicated in these pathways in hb-egfaKO ERGs vs. controls. These same signaling pathways and genes were implicated as downstream effectors of Hb-egfa in a previous study of Muller glia during retinal regeneration32 (Supplementary Fig. 4o–q).
Taken together, our transcriptomics, EdU labeling and bioinformatic assays indicate that Hb-egfa has an early and essential role in producing key ERG derivatives including neurons at early stages upon spinal cord injury, enabling long-term recovery of motor function.
Local HB-EGF application improves spinal cord regeneration
To assess effects of a targeted increase in Hb-egf gene products, we implemented a biomaterial-assisted strategy using a hyaluronic acid (HA)-based dynamic hydrogel43. Injection of a FITC-loaded version adjacent to the region of spinal cord transection resulted in gradual diffusion from the injection site, and fading by 21 days post injection (Supplementary Fig. 5a). To supplement Hb-egf at injury sites, we injured animals and immediately applied HA-hydrogels containing either BSA (control) or embedded human recombinant (HR) HB-EGF protein. Both BSA and HR-HB-EGF hydrogel groups showed an improvement in swim capacity compared to untreated fish, consistent with a beneficial role of hydrogel scaffolds at the site of spinal cord injury as shown in mammals44,45, with swim capacity trending higher in the HB-EGF group (Fig. 4a). Localized delivery of HR-HB-EGF resulted in a ~46% increase in the average axon crossing index at 4 wpi (Fig. 4b, c) and a ~40% increase in the average diameter of tissue bridges at 2 wpi relative to controls (Fig. 4d, e). Values of ependymal cell cycling and dorsal glial cycling trended higher in HR-HB-EGF-treated animals at 1 wpi (Fig. 4f, g and Supplementary Fig. 5b, c). We also found that administration of HR-HB-EGF was sufficient to improve cycling in hb-egf dKO Sox2+ ERGs at 1 wpi, and tissue bridging and axon crossing at later stages, indicating specificity of the phenotypes as well as the treatment (Supplementary Fig. 5d–g).
We also generated transgenic fish expressing a soluble form of Hb-egfa under the control of a heat-shock-inducible promoter (hsp70:hb-egfa-2A-TBFP, referred to as hb-egfaOE). Daily heat shocks caused whole-animal overexpression visualized by TBFP fluorescence (Supplementary Fig. 5h, i). We injured animals subjected to this heat-shock regimen and examined features of spinal cord regeneration. We found that daily, animal-wide induction of hb-egfa grossly impaired recovery of swim capacity (Fig. 4h and Supplementary Movies 5 and 6), and caused a ~44% decrease in axon crossing indices at 4 wpi (Fig. 4i, j). ERG cycling and tissue bridging were not grossly affected (Supplementary Fig. 5j, k). Thus, higher levels of Hb-egf throughout the entire cord and surrounding tissues do not improve regeneration, but instead can adversely affect functional regeneration. Together, our gain-of-function experiments suggest that Hb-egf has instructive rather than permissive effects on spinal cord regeneration; i.e. it can modulate regeneration when expressed ectopically, with local augmentation improving indicators of regeneration.
hb-egfa-linked enhancer directs expression to cord injuries
Regeneration programs are orchestrated at least in part by gene regulatory elements named “tissue regeneration enhancer elements” (TREEs)46,47. These enhancers possess sequences that direct gene expression preferentially or specifically upon injury to the damaged area, maintain expression during regeneration, and allow expression to temper as regeneration concludes. We hypothesized that one or more DNA regulatory elements responsible for hb-egfa expression is located in sequences represented in the hb-egfa BAC used to generate transgenic reporter animals. To identify TREEs relevant to spinal cord regeneration, we employed Assay for Transposase-Accessible Chromatin using sequencing (ATAC-seq), a genome-wide assay of chromatin accessibility48 (Fig. 5a). From this assay, we identified 3901 and 2141 sequences changing accessibility at 1 and 2 wpi, respectively, most of which were in intergenic regions (49.5%), in promoters (27.7%) or within introns (10.9%). The remaining regions were located in UTRs, exons or immediate downstream regions of genes (Fig. 5b, c). We then bioinformatically assigned regions identified by ATAC-seq to their closest transcriptional start site and integrated them with RNA-seq transcriptomic data (1 wpi newly generated, 2 wpi from19; Fig. 5d, e and Supplementary Data 2 and 4). Gene ontology analyses of chromatin peaks associated with nearby genes revealed enrichment of pathways involved in developmental growth, with major functions in central nervous system development, axonogenesis and axon guidance, neurogenesis, and angiogenesis at 1 and 2 wpi, supporting the establishment of regeneration programs at early stages after injury (Supplementary Fig. 6a, c and Supplementary Data 3 and 5). We found 968 and 463 regions increasing accessibility after spinal cord injury and associated with upregulated genes during spinal cord regeneration at 1 and 2 wpi, respectively (Fig. 5d, e, red quarter and Supplementary Fig. 6b, d), potentially acting as TREEs. Several regulatory sequences were tested for enhancer activity in stable transgenic lines when encompassed upstream of the minimal promoter c-fos and an EGFP reporter gene (Fig. 5f). For example, separate sequences linked to ncoa4, prp38fb and ssuh2.1 each directed injury-responsive expression in spinal cords, showing differential tissue representation (Fig. 5g–l).
Interestingly, one of these dynamically accessible sequences was a 310 bp region located 15.6 kb downstream of the hb-egfa start site with increased accessibility at 1 wpi as compared to sham-injured spinal cords (referred to as hb-egfaEN, Fig. 5m). To test whether hb-egfaEN can direct injury-induced gene expression after spinal cord injury, we established transgenic lines as above (Fig. 5f). Whereas we did not detect spinal cord fluorescence in uninjured hb-egfaEN-cfos:EGFP animals or in animals carrying a cfos:EGFP control construct (Fig. 5n and Supplementary Fig. 6e), hb-egfaEN directed EGFP expression at spinal cord injury sites (3 stable lines assessed; Fig. 5n). hb-egfaEN-cfos:EGFP had very similar spatiotemporal dynamics after spinal cord injury as those in hb-egfa:EGFP BAC transgenics, with greater fluorescence in caudal vs. rostral stumps at 1 and 2 wpi, respectively (Fig. 5n and Supplementary Fig. 6f). Cells lining the central canal, including those positive for Sox2 and indicators of cell cycling, displayed hb-egfaEN-directed expression at 1 wpi (Fig. 5o, p). Fluorescence diminished by 4 wpi, with only limited expression evident in some animals at 6 wpi (Supplementary Fig. 6g). To identify potential upstream regulators, we performed bias-free transcription factor footprint enrichment-test (BiFET) sequencing analyses, which revealed over-representation of predicted binding motifs for Rreb, Znf317, Tcf3 and Hoxb5 (Supplementary Fig. 6i).
We examined the requirement of hb-egfaEN for hb-egfa expression by using CRISPR/Cas9 to excise a ∼1.2 kb DNA region encompassing hb-egfaEN (Fig. 5q), which did not detectably alter expression of hb-egfa after transection injury (Fig. 5r). Enhancer redundancy is common (reviewed in ref. 49), and we suspect that other regulatory sequences compensate to maintain hb-egfa expression in hb-egfaEN deletion mutants. To begin to address this, we examined hb-egfa upstream and downstream sequences for predicted TF binding motifs. Sox2 binding sites were enriched in these regions (Supplementary Fig. 6j), and, given that hb-egfa expression is induced in Sox2+ ERGs, we hypothesized that Sox2 regulates hb-egfa expression. Consistent with this idea, we found that induced overexpression of Sox250 is sufficient to increase hb-egfa transcript levels and hb-egfa BAC-directed EGFP fluorescence in larvae (Supplementary Fig. 6k, l). In contrast, Sox2 overexpression did not change EGFP expression in hb-egfaEN-cfos:EGFP zebrafish (Supplementary Fig. 6m). Together, our results provide evidence that hb-egfaEN is a TREE that directs one or more components of hb-egfa expression during spinal cord regeneration, and that hb-egfa regulation is likely complex, with key Sox2-responsive and -nonresponsive elements.
hb-egfaEN directs expression in neonatal mouse spinal cords
Recent reports have hypothesized that the acquisition, retention, or loss of TREEs might contribute to differences in regenerative capacity among species47,51. Moreover, we recently reported that zebrafish TREEs can activate injury induced expression when introduced in adult mammals52. We examined several vertebrate genomes for hb-egfaEN sequences, finding significant primary sequence identity only in Fugu (Fig. 6a). To test for functional conservation in mammals, we generated a recombinant adeno-associated viral vector (AAV) containing zebrafish hb-egfaEN upstream of a murine permissive Hsp68 promoter and an EGFP reporter gene (Fig. 6b). To maximize payload expression in spinal cord tissue, we used an AAV9-based capsid variant (AAV.cc4753) that we found to effectively transduce different spinal cord cell types when delivered systemically by tail vein injection to adult mice (Supplementary Fig. 7a–c). To assess if zebrafish hb-egfaEN can direct injury-induced expression in mice similarly as in zebrafish, we first injected 3-month-old adult mice with AAV-hb-egfaEN-Hsp68:EGFP construct, performed thoracic crush injuries (T9-T10 level) 2 weeks after injection, and assessed EGFP fluorescence at 1 wpi (Fig. 6c). Thoracic crush injuries are commonly used in mammals to model the human condition, and we also observed that hb-egfa and hb-egfaEN-directed EGFP are induced in zebrafish after crush injuries (Supplementary Fig. 6h). We observed little or no EGFP in spinal cords of adult mice treated with AAV-hb-egfaEN-Hsp68:EGFP or control AAV-Hsp68:EGFP in sham or crush injuries (Fig. 6d and Supplementary Fig. 7d–f), nor was EGFP observed after a severe transection injury (Supplementary Fig. 7g–i).
Likely explanations for differential cross-species reading of hb-egfaEN include: (1) changes in hb-egf linked non-coding sequences during evolution rendered zebrafish sequences unrecognizable by mammalian transcriptional machinery; and/or (2) relevant transcriptional activators are not present or active in injured spinal cord tissues of adult mice. To attempt to resolve this, we introduced these same vectors at the more regeneration-competent neonatal stages of mice. First, we performed spinal cord crush injury in P3 pups and assessed the extent of axon growth across lesions at 1 and 14 dpi. We observed serotonergic axons distal to the injury and modest GFAP accumulation at the lesion site by 14 dpi, indicating similar regenerative capacity as reported3 (Supplementary Fig. 8). After observing that our AAV9-based capsid variant effectively transduced spinal cord cell types in neonates as in adults (Supplementary Fig. 7k–m), we systemically administered AAV-hb-egfaEN-Hsp68:EGFP or control AAV-Hsp68-EGFP vectors at P1, subjected animals to crush injuries at P3 (T9-T10 level), and analyzed tissue at two timepoints after injury (Fig. 6e). AAV-Hsp68:EGFP directed occasional but minimal EGFP expression in sham or crush injuries, similar to experiments in adults (Supplementary Fig. 7n–p). Notably, neonatal mice transduced with AAV-hb-egfaEN-Hsp68:EGFP displayed a prominent and restricted EGFP domain in 4 and 7 dpi injury sites (Fig. 6f). hb-egfaEN:EGFP+ cells lined the lesion site and expressed markers characteristic of zebrafish ERGs like Sox2 and GFAP at 1 wpi, with many of these cells also positive for the cycling marker Ki67 (Fig. 6g–i). Most EGFP+ cells did not express markers of neurons (HuC/D), macrophages (F4/80), or microglia (CD68) at 4 dpi, nor did they express Fibronectin, a component of bridges in neonatal mice (Supplementary Fig. 9). We conclude that the injury-targeting instructions of the zebrafish TREE hb-egfaEN can be interpreted by murine transcription complexes, but that key components of this recognition are present only at early life stages and lose efficacy with age.
HB-EGF gene therapy improves axon density in neonatal mice
To test whether Hb-egf has instructive effects on regeneration after spinal cord injury in mice, we established a strategy harnessing hb-egfaEN to augment levels of human HB-EGF in the lesion sites of neonatal mice. Analysis of published transcriptomes3 indicated that Hb-egf RNA is expressed in murine astrocytes, where its levels increase upon injury (Supplementary Fig. 10a, b). We generated recombinant AAV vectors packaging the zebrafish hb-egfaEN upstream of an Hsp68 minimal promoter and a gene cassette encoding a constitutively secreted form of human HB-EGF (AAV9-hbegfaEN-Hsp68:HB-EGF) (Fig. 6j). Following systemic administration of this vector or an AAV-hbegfaEN-Hsp68:EGFP control vector at P1 and thoracic crush injuries at P3 as above, we analyzed spinal cord tissue histologically at P10 (Fig. 6j–l). As expected, zebrafish hb-egfEN was able to concentrate human HB-EGF mRNA at 7 dpi lesion sites in mice pre-treated systemically with experimental virus (Fig. 6l). To determine if the targeted HB-EGF payload altered responses to spinal cord injury, we quantified the density of serotonergic axons caudal to the crush site at 7 dpi. We observed increases in the numbers of serotonergic axons downstream of lesions in AAV-hbegfaEN-Hsp68:HB-EGF-transduced animals, measured at various distances from the trauma (Fig. 6m, n). We monitored these mice for functional recovery up to 4 wpi, finding a modest degree of recovery in hind-limb stepping and coordination, consistent with previous studies3, without gross differences between EGFP and HB-EGF groups (Supplementary Movies 7 and 8). Thus, by use of an enhancer sequence that directs injury-responsive expression during innate regeneration in zebrafish, we find that a spatiotemporally controlled dose of HB-EGF can improve an indication of spinal cord repair in mice.
Discussion
By generating stable genetic reagents for hb-egf genes and assessing a full panel of spinal cord regeneration assays, we propose a model in which Hb-egfa produced in ERGs at spinal cord injury sites promotes ERG cycling and neuron production, a neurogenic role that antecedes tissue bridging, axon crossing and functional recovery (Supplementary Fig. 5l). Few factors have yet been implicated in the process of neurogenesis during adult spinal cord regeneration, among which are Hedgehog54, Notch55, FGF56, dopamine57, serotonin58 and myostatin59. Inducible fate-mapping studies will be necessary to further define how the newly generated neurons integrate into and help construct the bridge, as will methods to visualize new synaptic connections and circuit formation. It is possible that Hb-egf-associated neurogenesis at injury stumps might also contribute more directly to reestablishing functional synaptic connections. Other factors such as Neurotrophin-3 have been shown to induce generation of spinal cord neurons at the lesion site after transection injury in rats. Over the long term, these neurons have been shown to interconnect severed ascending and descending axons, resulting in sensory and motor behavioral recovery60.
We identify an enhancer (hb-egfaEN) that directs expression of a reporter gene in response to spinal cord injury, with a pattern mimicking that of hb-egfa itself that includes a caudal expression bias. Deletion of this enhancer sequence does not alter the hb-egfa expression pattern, a feature that we have reported for other TREEs61,62 and in this case might reflect Sox2-dependent and -independent regulation. We find that zebrafish hb-egfaEN sequences can functionally interact with mammalian transcriptional machinery after spinal cord injury, a finding that is not entirely surprising based on our recent examination of zebrafish TREEs in other injury contexts in mammals52. Yet, intriguingly, our data indicate that cross-species recognition of hb-egfaEN is specific to the context of the neonatal stage. Whereas spinal cord injury in adult mice triggers the formation of a scar consisting of cells like reactive astrocytes, fibroblasts, microglia and macrophages, neonatal mice have a more permissive, pro-regenerative environment with limited scarring after spinal cord injury63. One aspect of the neonatal response is the construction of fibronectin bridges by microglia, which revert to their homeostatic state after exerting pro-regenerative functions3. The contextual, age-dependent recognition of hb-egfaEN we observe here hints at a potentially broad concept in which regenerative capacity can be defined in part by the ability to open, read, and follow the instructions of key regeneration-activated regulatory sequences. This ability might be founded on context-dependent chromatin environments, which have been affiliated with regeneration and early development in previous studies64,65, and/or with selective presence of central transcription factors and their ability to bind key TREEs. Further comparisons of chromatin structure and transcription complexes in mammalian spinal cord tissue at different life stages, including their ability to recognize additional TREEs, are likely to provide helpful perspective about the developmental loss of pro-regenerative capacity with aging.
Finally, we report here that human HB-EGF delivery via a gene therapy vector improves axon density downstream of injury sites after spinal cord crush injury in neonatal mice. Whether this occurs because of neurogenesis-related effects, as observed in zebrafish, or other potential mechanisms such as neuroprotection, remain to be investigated. In our experiments, although the experimental viral vector was delivered systemically, inclusion of hb-egfaEN in viral sequences focused HB-EGF expression to the injury site with temporal control. This element of control is attractive for potential therapies, given that the extent of neurogenesis and instructions for axons are likely to require some level of spatiotemporal precision. HB-EGF itself has been proposed to be tumorigenic, thus requiring spatiotemporally targeted delivery if used therapeutically66. There are many components of this delivery system that can be optimized with the intent to alter cell-type specificity, temporal dynamics, dose, and off-target effects. With such optimization, TREE-based delivery systems for factors like HB-EGF have potential applications in precision interventions to enhance regenerative responses after injury to the spinal cord.
Methods
Zebrafish
Wild-type, mutant, or transgenic male and female zebrafish of the Ekkwill (EK) strain were used for all experiments. Adult animals were between 3 and 12 months of age, with the majority between 6 and 12 months, and measured ~2.5 cm in length. Animals were maintained at a density of ~15–18 fish per 3 liters. Larvae used for experiments were between 3 and 6 days post fertilization. The following previously published lines were used for this study: Tg(gfap:EGFPmi2002)67, Tg(−5.5Kb-ctgfa:EGFPpd96)19, ctgfabns519, and Tg(hsp70:sox2x21)50. Transection and crush injuries were performed midway between the brainstem and the base of the caudal fin. Clutchmates were used as controls for all experiments. Experiments with zebrafish were approved by the Institutional Animal Care and Use Committee (IACUC) at Duke University. Animals in control and experimental groups received the same care, food and follow up for the duration of the experiments.
Generation of hb-egfa:EGFP zebrafish
To generate the hb-egfa:EGFP BAC construct, the first exon of the hb-egfa gene in the BAC clone CH73-26l13 (containing ~66 kb upstream and 31 kb downstream the hb-egfa gene) was replaced with the EGFP-SV40 polyA cassette using Red/ET recombineering technology (Gene Bridges). The 5′ and 3′ homologous arms for recombination were a 50 bp fragment upstream and downstream the first exon of hb-egfa, and were included in PCR primers to flank the EGFP-SV40 polyA cassette. We used the same technology to insert a I-SceI site in the final BAC construct, which was purified with Nucleobond BAC 100 kit (Clontech) and co-injected with I-SceI into one-cell-stage zebrafish embryos. A stable transgenic line showing EGFP fluorescence was selected. The allele designation for this line is pd360.
Generation of hb-egfb EGFP zebrafish
Transgenic fish were generated using TALEN-directed knock-in68 and PhiC31 mediated recombination69. Briefly, a pair of obligated heterodimeric TALENs targeting hbegfb ATG region (5′-TCAGTCAGACCGACTA-3′ and 5′-TTTCTTTGGGATAGTCCAA-3′) were assembled with standard golden gate assembly70,71 and in vitro transcribed with mMESSAGE mMACHINE SP6 Kit (Life Technologies). A 5′ phosphorylated single stranded oligo (ssOligo) was synthesized from Integrated DNA Technologies (IDT) and used as a homology-directed repair (HDR) template (5′- CCTTTTCTTTGGGATAGTCCAAGACACCCCCAACTGAGAGAACTCAAAGGTTACCCCAGTTGGGGTCTGACTGAACCTCCCTGCCTCCAGCGCCGTC-3′). hbegfb TALEN mRNAs and ssOligo were co-injected into one-cell stage zebrafish embryos and stable lines were screened by PCR. Next, stable hbegfbattP F1 zebrafish were sequenced and inter crossed and F2 embryos were injected with PhiC31o mRNA, FLPase mRNA as well as a donor plasmid pERBF-EGFP containing attB, GFP-SV40 polyA, and two FRT sites flanking the vector sequences. Finally, stable hb-egfbEGFP zebrafish were isolated based on EGFP expression and sequenced to ensure correct integration. The allele designation for this line is pd361.
Generation of hb-egfaKO and hb-egfbKO zebrafish
hb-egfa and hb-egfb mutants were generated using the CRISPR/Cas9 technology. The target sequences were 5′-TGGCCACGTTCATATTTAAGCGG-3′ and 5′-AGCCCTTGCTGTGGTAGCTGTGG-3′ for hb-egfa and 5′-CCACCAAACCCAAACATCCGTCG-3′ and 5′- CCACAGCGCTGGCGGTCATAGCA-3′ for hb-egfb and led to deletion of a 1512 bp and 2375 bp fragment, respectively. Injected embryos were raised to adulthood and screened using the following primers:
hb-egfaKO: Fw1 5′-GCAGGTAACCATACCAGGGATAAAAGG-3′
Rev1 5′-GGTAAAGACGAAAAGACGCAAGACTG-3′
Rev2 5′-CAGGAGGAGGCCAATGATGG-3′
hb-egfbKO: Fw1 5′-GCACTGACATCACTCTTGCTCAAC-3′
Rev1 5′-CCATGAATGCAGAAATCTTTGTATTCCTCC-3′
Rev2 5′-GCCTCGAGTTTGACCTTTTCTTCG-3′
The allele designations for these lines are pd362 and pd363.
Generation of hsp70:hb-egfa-P2A-TBFP zebrafish
hb-egfa cDNA was amplified from the embryonic cDNA using the following primers: hb-egfa_Fw 5′-ATGAACTTTTTAACAGTCTT-3′ and hb-egfa_Rev 5′ CAGAGAGAAATCGTGACATC-3′. Primers were linked to homology arms for Gibson assembly and inserted into an hsp70-2A-TBFP vector using Gateway LR Clonase II Enzyme mix (Thermo Fisher Cat#11791020). The final plasmid was co-injected into one-cell stage wild-type embryos with I-SceI. Multiple founders were isolated, propagated, and screened for germline transmission of the transgene selecting for TBFP expression after heat shock. A single line was chosen for maintenance. The allele designation for this line is pd364.
Generation of ncoa4EN-cfos:EGFP, prp38fbEN-cfos:EGFP, ssuh2.4EN-cfos:EGFP, hb-egfaEN-cfos:EGFP and cfos:EGFP zebrafish
Putative enhancer regions were PCR-amplified from genomic DNA of 3 dpf EK zebrafish embryos with the following primers: ncoa4EN: Fw: 5′-TGTCCCTGGATACACACATACTC-3′, Rev: 5′-CAAAATCAAGCCGTGCCCAA-3′; prp38fbEN: Fw: 5′-AATGCCGTCCAAAGCAAGAC-3′, Rev: 5′-GCCATTATGGGGCAACGAGA-3′;
ssuh2.4EN: Fw: 5′-TCAGAATAGCTGAAACAATCCTACA-3′, Rev: 5′-GGGAGGTGGTTTGCCATACA-3′; hb-egfaEN: Fw: 5′-ACACGTTTCCTCTAGTCCCAG-3′ and Rev: 5′-GGGTTTTACTGTGCTCAAATTGC-3′. The amplified sequences were inserted into pCR8-GW-topoTA (Invitrogen K2500-20) to generate pEntry vectors that were subsequently recombined with PMP6, a Gateway vector containing LR recombination sites upstream of the 95 bp minimal mouse cfos promoter driving EGFP72. Constructs were injected into fertilized zebrafish embryos along with I-SceI, using standard transgenesis techniques. F1 embryos were genotyped to check for transgene insertion and transmission with the following primers EGFP Fw 5′-ATGGTGAGCAAGGGCGAG-3′, EGFP Rev 5′-CTTGTACAGCTCGTCCATGC-3′. Three stable lines were established. Animals PCR-positive for the transgene were used for experiments. The allele designation for this lines are the following: hb-egfaEN-cfos:EGFP, pd365, lines 1–3; prp38fbEN-cfos:EGFP, pd366, lines 1–2; ssuh2.4EN-cfos:EGF, pd367, lines 1–2; ncoa4EN-cfos:EGFP, pd368, lines 1–5. As negative control, we generated control lines only carrying a cfos:EGFP construct, with an allele designation of pd369.
Generation of hb-egfaEN mutant zebrafish
hb-egfaEN was deleted using a pair of gRNAs and the CRISPR/Cas9 technology. gRNAs were designed using the CHOPCHOP website, target sequences were 5′-GTGACGTTTTGCGCCGAGCCGGG-3′ and 5′-TTTGGCATTTCTTCCAGGCATGG-3′, with PAM sequences underlined. To generate knockout animals, gRNAs were co-injected with Cas9 protein (CP01-200, PNA Bio) into one-cell stage embryos. hb-egfaEN mutants were screened by PCR with primers hb-egfENKO Fw: 5′- TGTGGGATCATTTGCTTTATCA-3′ and hb-egfENKO Rev: 5′- GCCGCAGCGCACATTACTTTC-3′. Deletions were confirmed by Sanger sequencing (Genewiz, Inc.). The allele designation for this line is pd371, lines 1–2.
Generation of ctgfa:mCherry-P2A-NTR zebrafish
The 5.5 Kb region upstream of the ctgfa coding sequence was amplified with the following primers: ctgfa Fw: 5′-ATCGATTTTGGCTACTTTCAGCTAAGACTGG-3′ and ctgfa Rev: 5′- ATCGATTCTTTAAAGTTTGTAGCAAAAAGAAA-3′. The amplified sequence was inserted into pCR8-GW-topoTA (Invitrogen K2500-20) to generate a pEntry vector that was subsequently recombined with a Gateway vector containing LR recombination sites upstream of a mCherry-P2A-NTR2.0 cassette. The final construct was injected into fertilized zebrafish embryos along with I-SceI, using standard transgenesis techniques. The allele designation for this line is pd372.
Spinal cord injuries in zebrafish
For adult spinal cord injuries, zebrafish were anesthetized using 0.75% 2-phenoxyethanol in fish water. Fine scissors were used to make a small incision through skin and muscle and expose the vertebral column. Then, for transection injuries, the vertebral column was transected halfway between the dorsal fin and the operculum. Complete transection was visually confirmed at the time of surgery. For crush injuries, the spinal cord was crushed using Dumont #5 forceps (Fine Science Tools, 11251-10). Zebrafish were allowed to recover at 28 °C. Sham-injured fish underwent an incision through skin and muscle to expose the spinal cord, which was left intact.
For larval spinal cord injuries, larvae at 3 dpf were anesthetized with 0.02% aminobenzoic-acid-ethyl methyl-ester (MS222, Sigma). Larvae were then transferred into a petri dish coated with agarose. Larvae were placed in a lateral position, and a 30½ G needle was used to perform a dorsal incision and transect the spinal cord. Larvae were allowed to recover at 28 °C73.
RNA- and ATAC-sequencing
All tissue samples were generated from adult zebrafish spinal cord regions collected 2 mm rostral and 2 mm caudal to the lesion site. Sham-operated clutchmate animals were used as controls, collecting the same portion of spinal cord as in injured experimental animals. All samples were prepared in triplicate for each time point.
For ATAC-seq, spinal cords from 60 male and female zebrafish at equal ratios were digested into a single-cell suspension using 0.25% trypsin-EDTA; dissociated cells were processed for FACS sorting using an Astrios sorter, to collect live and single cells. 50,000 cells were processed for ATAC-seq library preparation61, and sequencing was performed at the Duke Center for Genomic and Computational Biology on the Illumina HiSeq 4000 platform, with over 40 million 150 bp paired-end reads obtained for each library. Sequences were aligned to the zebrafish genome (danRer10) using Bowtie2 v 2.2.574. The mapped reads were filtered by samtools (v 1.3.1, with parameter -q 30)75 and duplicates were removed by picard (v 1.91) Peak calls were determined using MACS2 (v 2.1.0, with parameter -f BAM -g 1.5e9 -q 0.05 --nomodel --shift 37 --extsize 73)76, and csaw (v 1.20.0, cutoff p value < 0.05)77. DiffBind (v 2.14.0) was used to call differential accessible sites. Filter conditions were p value < 0.05 and fold change >1.2.
For RNA-seq, RNA was extracted using TRI reagent (Sigma), and genomic DNA was eliminated using the RNA Clean & Concentrator Kit (Zymo Research, R1013). Library preparation and sequencing was performed at the Duke Center for Genomic and Computational Biology using an Illumina HiSeq 4000, with over 40 million 50-bp single-end reads obtained for each library. As for ATAC-seq, reads were aligned to the zebrafish genome (danRer10) using Tophat2 (v 2.1.1)78. The mapped reads were filtered by samtools (v 1.3.1, with parameter -q 3075 and counted by htseq-count (v 0.6.0)79. Differential analyses were performed by Bioconductor package DESeq2 (v1.26.0)80.
ATAC-Seq peaks were paired to RNA-Seq differential expression data by annotated nearest gene symbols by ChIPpeakAnno (v3.20.1)81. A conservation test was performed using the DNA sequence alignment visualization online tool mVista82 and a circle plot was generated using circus (v 0.69-8)83. The motif enrichment analysis shown in Supplementary Fig. 6i were performed by AME (Version 5.5.0) at https://meme-suite.org/meme for the enhancer sequence extracted from danRer10: chr14:6760805-6761115. Analyses of predicted Sox2 binding sites in the promoter region of hb-egfa shown in Supplementary Fig. 6j were performed using motifmatchr (v 1.12.0)84 with motifs downloaded from JASPAR (v2018)85. The tracks and heatmaps of ATAC-seq and RNA-seq signals were plotted by Bioconductor package trackViewer (v 1.22.1)86 and ComplexHeatmap (v 2.2.0)87.
Single-cell RNA sequencing
Tissue samples were generated from adult zebrafish spinal cord regions collected 2 mm rostral and 2 mm caudal to the lesion site. Sham-operated clutchmate animals were used as controls, collecting the same portion of spinal cord as in injured experimental animals. Samples were processed following the 10X Chromium platform following the manufacturer’s guidelines, using 10X Single-Cell 3′ v3 chemistry (10X Genomics, Pleasanton, USA). For each genotype, injured and sham-injured conditions were prepared and processed in parallel. Sequencing was performed at BGI Genomics using the DNBSEQ platform. The raw reads were processed using the 10x Genomics Cell Ranger pipeline (v.6.0.1). The “cellranger count” was used to identify cell barcodes and feature counts to the fish transcriptomes (danRer11). Libraries were filtered by 200 <number of features <6000 and the percentage of mitochondria genes lower than 20%. The libraries were anchored and integrated using the top 3000 variable features per library in Seurat package (v4.1.1). The “SCT” normalization and reduction on these 3000 features between the libraries was calculated, and the first 30 dimensions used as input for anchoring. Post anchoring, PCA was performed and the first 30 PC’s were used for UMAP dimensionality reduction and subsequent clustering using resolution 0.5. Marker genes per cluster were calculated using Seurat’s “FindAllMarkers” function with parameters (assay = “SCT”, do.print = TRUE, logfc.threshold = 0.5, return.thresh = 0.1, min.pct = 0.5, only.pos = TRUE). Inferences of cell-cell communication were analyzed by CellChat (v 1.4.0) with “CellChatDB.zebrafish” database. Cell types were defined by R scripts “ScType” (v 1.0) by mapping the zebrafish homologs of “Brain” tissue for the scaled data.
Gene ontology and pathway analyses
Gene ontology analyses were performed using Metascape (v3.5.20230501)88. D. rerio was selected as species for input and analyses. Pathway and process enrichment analysis was performed using the following ontology sources: GO Biological Processes, KEGG Pathway, Reactome Gene Sets and WikiPathways. All statistically significant ontology terms (p value < 0.01) containing at least 3 genes of the initial gene list and with an enrichment factor (ratio between the observed genes in each ontology term and the genes expected by chance) >1.5 were collected and grouped into clusters based on their membership similarities. For each cluster, a subset of enriched ontology terms with a similarity >0.3 used generate networks, where each circle node represents an enriched ontology term. The most significant ontology term in each cluster based on p values was used to represent the cluster and is shown in the label. Pathway analysis was performed using Ingenuity Pathway Analysis (IPA, v. 70750971, QIAGEN Inc., Redwood City, CA, USA)89 and Panther (v17.0)42,90.
RNA isolation and qRT-PCR
Spinal cords were homogenized in Trizol, and RNA was extracted using the standard Trizol protocol. Genomic DNA removed using RNA clean and Concentrator Kit (Zymo Research, R1013). cDNA synthesis was performed using Transcriptor First Strand cDNA Synthesis Kit (Roche, 04897030001) and qPCR run was performed with LightCycler 480 SYBR Green I Master (Roche, 04707516001), and with LightCycler 480 software 1.5.0 SP4. All gene expression values were normalized to beta-actin levels. Primers used were the following:
hb-egfa: Fw 5′-GGGCCCTCATGCATATGTGA-3′, Rev 5′-AGAATTTCCACACGGTCGCC-3′;
hb-egfb: Fw 5′-AGCGGGATTTACGCACTCAT-3′, Rev 5′-GCATGCAGAATATCTTAATGCCA-3′;
neurod4 Fw 5′-CGTCCATCCATCCAAGGGAG-3′, Rev 5′- CGTCCATCCATCCAAGGGAG-3′;
sox11b Fw 5′-CCTTTGCCTCTCTCTGGTGG-3′, Rev 5′ CAGGAGTGCAATAGTCCGGG-3′;
adcyap1b Fw 5′-ATCCGCCAGAGAAAAGAACGG-3′, Rev 5′ CGCGAACTGCCATCAGAGA-3′;
sox2: Fw 5′-GGGCACGGGGAACACCAACT-3′, Rev 5′- TGGTCGCTTCTCGCTCTCGG-3′;
actin: Fw 5′-GACAACGGCTCCGGTATG-3′, Rev 5′-CATGCCAACCATCACTCC-3′.
EdU, biocytin and human recombinant (HR) HB-EGF treatment
For EdU incorporation, zebrafish were injected intraperitoneally with 10 μl of 10 mM 5-ethynyl-2′-deoxyuridine (EdU, Molecular Probes, A10055), and tissue was collected 24 h after a single treatment, or after daily treatments for 1 or 2 weeks. For biocytin treatment used for anterograde axon tracing, adult fish were anaesthetized using 0.75% 2-phenoxyethanol in fish water. Scissors were used to make a small incision on the dorsal side of the skin and to transect the spinal cord 2 mm rostral to the original spinal cord transection site. A biocytin-soaked gelfoam gelatin sponge was applied at a new injury site (Gelfoam, Pfizer, 09-0315-08; Alexa Fluor 594 Biocytin, Thermo Fisher Scientific A12922). The incision was closed and glued using Vetbond tissue adhesive material (Santa Cruz Biotechnology, sc-361931). Tissue was collected 24 hrs after biocytin application.
For HR-HB-EGF treatment, HR-HB-EGF protein (R&D Systems, 259-HE-250) was conjugated with hydrogel (see below) and 3 μl of solution was locally injected just rostral to the original spinal cord transection site with a Hamilton syringe.
Synthesis of hyaluronic acid-based hydrogel
Hyaluronic acid (HA) was reacted with ureidopyrimidinone (UPy) moiety following previously published protocol to obtain Upy conjugated HA (HA-Upy)43. Next, HA-Upy was oxidized by sodium periodate to obtain dialdehyde containing HA-Upy (HA-Upy-DA). Briefly, HA-Upy was dissolved in deionized water at 5 mg/ml. Sodium periodate (NaIO4, one equivalent with respect to the sugar ring of HA-Upy), dissolved in 5 ml of water, was added into the HA-Upy solution. After stirring for about 2 h at room temperature, the reaction mixture was quenched with excess of ethylene glycol (10 equivalent with respect to NaIO4) for about 30 min. The mixture was purified via dialysis against DI water. The solution was then freeze-dried to obtain HA-Upy-DA. The aldehyde content in HA-Upy-DA was determined by 1HNMR following reaction of tert-butyl carbazate (t-BC) with HA-Upy-DA, and the degree of oxidation was calculated by comparing the signal of t-BC group (1.38 ppm, 9H) to that of −NHCOCH3 methyl group of HA (1.9 ppm, 3H)91. The aldehyde content was found to be 9 ± 1%. Fluorescently labeled HA-Upy-DA was synthesis similarly by conjugating fluorescein isothiocyanate (FITC) to HA-Upy followed by oxidation of FITC conjugated HA-Upy. Hydrogels were prepared by dissolving the polymers in 1X PBS (pH 7.4) containing 0.1% bovine serum albumin (BSA). To encapsulate growth factor into the hydrogel, the growth factor (Recombinant Human HB-EGF Protein, R&D Systems) was first dissolved in PBS containing 0.1% BSA at 50 ug/100 μl. The solution of the growth factor was then added to freeze-dried HA-Upy-DA (3.5 wt%). Growth factor loaded hydrogel was obtained upon complete dissolution of the HA-Upy-DA. The hydrogel was transferred to a Hamilton syringe for application.
Histological analysis in zebrafish
PFA-fixed tissue was rinsed in phosphate buffer, then cryoprotected in 30% sucrose. Samples were embedded in optimal cutting temperature compound (OCT) (Tissue-Tek) and frozen in a dry ice. Twenty μm longitudinal (horizontal) or 16 μm transversal cryosections were used for histology. For immunohistochemistry, tissue sections were rehydrated in PBS, permeabilized in PBS containing 0.2% Triton X-100, and incubated with blocking buffer (5% goat serum in PBS-Tween) for 1 h at room temperature. Sections were incubated overnight with primary antibodies diluted in blocking agent, washed in PBS, and treated for 1 h in secondary antibodies and DAPI (Thermo Fisher Scientific, D3571, 1:5000). Following washes, sections were mounted in in VECTASHIELD® Antifade Mounting Medium (Vector Laboratories H-1000-10). Primary antibodies used for adult fish experiments were: rabbit anti-GFP (Life Technologies, A11122, 1:500), chicken anti-GFP (Aves Labs, GFP-1020, 1:500), mouse anti-GFAP (ZIRC, Zrf1, 1:200), rabbit anti-GFAP (Sigma, G9269, 1:200), rabbit anti-Sox2 (Abcam, ab97959, 1:200), mouse anti-HuC/D (Invitrogen, A-21271, 1:100), mouse anti-acetylated-α-tubulin (Sigma, T6793, 1:1000), rabbit anti-dsRed (Clontech, 632496, 1:200), mouse anti-PCNA (Sigma, P8825, 1:200). Secondary antibodies (Life Technologies, 1:200) used in this study were highly cross-absorbed Alexa Fluor 488/633/594 goat anti-rabbit, anti-mouse or anti-chicken antibodies (Alexa Fluor 488 Goat anti-Rabbit, Thermo Fisher Scientific, A-11034; Alexa Fluor 594 Goat anti-Rabbit, Thermo Fisher Scientific, A-11037; Alexa Fluor 488 Goat anti-Mouse, Thermo Fisher Scientific, A-11029; Alexa Fluor 633 Goat anti-Mouse, Thermo Fisher Scientific, A-21050; Alexa Fluor 594 Goat anti-Mouse, Thermo Fisher Scientific, A-11032; Alexa Fluor 488 Goat anti-Chicken, Thermo Fisher Scientific, A-11039; Alexa Fluor 633 Goat anti-Mouse, Thermo Scientific, A-21052). EdU staining was performed using 20 μM Alexa Fluor 594 azide (Molecular Probes, A10270). All confocal images were acquired with either a Zeiss LSM 700 or LSM 880 microscope with Zen 2010 B SP1.
In situ hybridization was performed on cryosections of paraformaldehyde-fixed spinal cord19, using an Intavis in situ robot. To generate probes, target sequences were placed upstream of a T7 promoter and gBlock fragments were ordered at IDT. Probes were generated using T7 RNA polymerase (M0251, New England BioLab). Signals were visualized by immunoassay using an anti-DIG-AP (alkaline phosphatase) antibody (11093274910, Sigma-Aldrich) and subsequent catalytic color reaction with NBT (nitroblue tetrazolium) (11383213001, Sigma-Aldrich)/BCIP (5-bromo-4-chloro-3-indolyl-phosphate) (11383221001, Sigma-Aldrich). Sections were imaged using a Leica DM6000 compound microscope with Leica Application Suite X (v.3.4.2). Whole mount immunofluorescence was performed using established protocols92. Larvae were imaged using a Zeiss Axio Zoom microscope with Zen Pro 2012.
Swim capacity assays
Swim capacity was measured by exercising fish in groups of 8–12 in a 5L swim tunnel respirometer device (Loligo, SW100605L, 120 V/60 Hz)19. Fish were acclimated for 20 min at a fixed low water current in the enclosed tunnel, then water current velocity was increased every 2 min and fish swam against the current until they reached exhaustion. For each animal reaching exhaustion, swim time and current velocity at exhaustion were recorded.
Zebrafish larvae experiments
For imaging experiments, 3 days post fertilization (dpf) larvae were placed in a 50 ml falcon tube in egg water and immersed in a 38 °C water bath for 1 h. Larvae were then placed in a petri dish in a 28 °C incubator. At 6 h post heat shock, larvae were imaged using a Zeiss Axio Zoom microscope, with settings unchanged between experimental and control groups.
For qPCR analyses, 3 dpf larvae were placed in a 50 ml falcon tube in egg water and immersed in a 38 °C water bath for 1 h. Larvae were then placed in a petri dish in a 28 °C incubator. At 3 h post heat shock, single larvae were lysed in Trizol. DNA and RNA were extracted using the manufacturer instructions for genotyping and qPCR analyses, respectively.
Mice
All experimental procedures with mice were performed in compliance with animal protocols reviewed and approved by the Duke IACUC. Wild-type male and female C57BL/6 mice were purchased from The Jackson Laboratory and used for all experiments. For neonatal experiments, injuries were performed at postnatal day 3 (P3). For experiments with adults, 3 month-old mice were used. Mice were housed in a temperature-controlled (~18–23 °C, 40–60% humidity) and enriched environment, with a 12 h light/dark cycle, and provided standard chow and water.
Spinal cord injuries in mice
For neonatal spinal cord crush injury, mice at postnatal day 3 (P3) were anaesthetized by hypothermia on an ice bed. A laminectomy was performed at thoracic level (T9-T10) to completely expose the spinal cord. The spinal cord was crushed for 2 sec using forceps. After visually confirming establishment of the injury, muscle and skin were sutured in layers with 6-0 absorbable sutures. Mice were warmed until awake and placed into a cage containing bedding from their original cage for at least 30 min before the mother was returned. In case of bladder dysfunction, bladder expression was performed daily. Sham-operated pups underwent the same procedure involving laminectomy without spinal cord crush3.
For adult crush and transection injuries, mice were anesthetized with ketamine (50–100 mg/kg) and xylazine (5–10 mg/kg) and given antibiotics (gentocin, 1 mg/kg)3,93. A midline incision was made over the thoracic vertebrae, followed by removal of the T9-T10 lamina to expose the spinal cord. The spinal cord was fully crushed for 2 s with Dumont #5 forceps (Fine Science Tools, 11251-10) modified to 0.5 mm tip94. For transection injuries, the spinal cord was cut using iridectomy scissors. Muscles were then sealed with 6-0 absorbable sutures and the skin was closed with wound clips. Two ml of sterile saline was administered subcutaneously (sq) to prevent de-hydration. During recovery, mice were kept on a heating pad and received antibiotic agents (1 mg/kg gentocin) and saline daily for 5 days. Manual bladder expression was performed twice per day until tissue harvest. Sham-operated mice underwent laminectomy without spinal cord crush and received all post-operative cares as injured mice.
Histological analyses in mice
Mice were given a lethal dose of anesthesia and were transcardially perfused with PBS followed by 4% paraformaldehyde (PFA). PFA-fixed tissues were post-fixed in 4% paraformaldehyde, rinsed in phosphate buffer, then cryoprotected in 30% sucrose. Samples were embedded in OCTand frozen in dry ice. Longitudinal horizontal sections were cut on a cryostat at 20-μm thickness and stored at −20 °C until processed. Before staining, sections were warmed to room temperature, permeabilized using Triton X-100, treated with blocking agent and incubated over night at 4 °C with primary antibodies. Following washes, sections were incubated washed in PBS and mounted in VECTASHIELD(R) Antifade Mounting Medium (Vector Laboratories H-1000-10). Primary antibodies used for mouse immunofluorescence anti-EGFP (rabbit, A11122, Life Technologies, 1:500), anti-EGFP (chicken, GFP-1020, Aves Labs, 1:500), mouse anti-GFAP (Sigma, G3893, 1:500), rabbit anti-Sox2 (Abcam, ab97959, 1:200), mouse anti-HuC/D (Invitrogen, A-21271, 1:100), rabbit anti-5-HT (Immunostar, 20079, 1: 5000), rabbit anti Ki67 (Abcam, ab15580, 1:200), rabbit anti-fibronectin (Sigma, F3648, 1:200), rat anti-CD68 (Bio-Rad, MCA1957, 1:600), F4/80 (Biorad, MCA497R, 1:200). Secondary antibodies (Life Technologies, 1:200) used in this study were highly cross-absorbed Alexa Fluor 488/633/594 donkey or goat anti-rabbit, anti-mouse, anti-rat or anti-chicken antibodies (Alexa Fluor 488 Goat anti-Rabbit, Thermo Fisher Scientific, A-11034; Alexa Fluor 594 Goat anti-Rabbit, Thermo Fisher Scientific, A-11037; Alexa Fluor 488 Goat anti-Mouse, Thermo Fisher Scientific, A-11029; Alexa Fluor 633 Goat anti-Mouse, Thermo Fisher Scientific, A-21050; Alexa Fluor 594 Goat anti-Mouse, Thermo Fisher Scientific, A-11032; Alexa Fluor 488 Goat anti-Chicken, Thermo Fisher Scientific, A-11039; Alexa Fluor 633 Goat anti-Mouse, Thermo Scientific, A-21052; Alexa Fluor 633 Goat anti-Rabbit, Thermo Scientific, A-21071; Alexa Fluor 568 Goat anti-Rat, Thermo Scientific, A-11007; Alexa Fluor 594 Rabbit anti-Goat, Thermo Scientific, A11080; Alexa Fluor 488 Donkey anti-Goat, Thermo Fisher Scientific, A-11055; Alexa Fluor 594 Donkey anti-Goat, Thermo Fisher Scientific, A-11058). Confocal images were acquired with Zeiss LSM 700 or Zeiss LSM 880 microscopes.
Virus production and titers
A triple-plasmid transfection protocol was used to produce recombinant AAV vectors in suspension HEK293s (obtained from the University of North Carolina Vector Core). Specifically, the transfected plasmids include a capsid-specific helper plasmid (AAV.cc47, containing AAV2 Rep and AAV9 variant Cap genes53), the adenoviral helper plasmid pXX680, and pTR-Enhancer-HSP68-GFP plasmids (encoding different enhancer elements), flanked by inverted terminal repeats (TRs) derived from the AAV2 genome. Culture media was harvested 6 days post transfection and cells were pelleted via centrifugation (1000 × g × 15 min) and discarded. Viral particles were precipitated from the culture media overnight at 4 °C with polyethylene glycol (PEG; final concentration of 12%). Media was subsequently centrifuged at 3000 × g × 1 h and discarded. The PEG pellet was resuspended in formulation buffer (1x PBS with 1 mM MgCl2 and 0.001% puronic F-68) and treated with DNase at 37 °C for 1 h. Viral vectors were purified using iodixanol density gradient ultracentrifugation. Vectors were subsequently subjected to buffer exchange using Pierce Protein PES centrifugation columns (100,000 MWCO, Thermo Scientific, catalog no. 88524). Following purification, viral genome titers were determined via quantitative PCR using a Roche Lightcycler 480 (Roche Applied Sciences). Quantitative PCR primers were designed to specifically recognize the AAV2 inverted terminal repeats (forward, 5′-AACATGCTACGCAGAGAGGGAGTGG-3′; reverse, 5′-CATGAGACAAGGAACCCCTAGTGATGGAG-3′) (Integrated DNA Technologies). 1011 virus particles were injected into neonatal mice, and 1012 into adult mice, by temporal vein and tail vein injection, respectively.
Data analysis and statistics
The number of animal analyzed for all quantifications (n) is indicated in the figure panels. The number of trials for each experiment (N) is indicated in Figure legends.
Quantification of tissue bridging was performed on Z-stacks, while quantification of biocytin and EdU incorporation in Sox2+ or HuC/D+ cells was performed on single-plane images. Glial bridge diameter was calculated using ImageJ software, measuring 3–5 longitudinal, horizontal sections per fish with the thickest bridge, which was identified by staining for axons and glia (acetylated α-tubulin and GFAP, respectively). Measurements at the regenerating lesion site were normalized on diameter of the spinal cord caudal to the lesion, as performed previously19. Biocytin-labeled axons were quantified from transverse sections, counting number of particles (each one representing the cross-section of an axon) using the “threshold” and “particle analysis” tools in the ImageJ software. We analyzed 3–5 transverse sections per fish, which were located ~0.5 mm caudal to the lesion; we then normalized measurements on signals detected ~1 mm rostral to the lesion core for each fish, as done previously19. Cycling of Sox2+ ERGs was quantified by manually counting the number of Sox2+ cells labeled with EdU surrounding the central canal, using transverse sections located ~0.5 mm caudal to the lesion. Labeling of HuC/D+ cells was quantified on longitudinal horizontal sections, in 0.3 mm regions rostral and caudal to the lesion site. Three to five longitudinal horizontal sections per animal were analyzed and averaged. qPCR experiments were performed 3 times, 3 technical replicates were run each time. Fold changes were calculated with the 2-ΔΔCT method.
For violin plots, solid lines indicate the group median; dotted lines indicate the 25th and 75th quartiles. All samples are shown in each violin plot. Sample sizes, statistical tests, and p values are indicated in the figures or the legends. All statistical analyses were performed using GraphPad Prism 9 software.
For zebrafish experiments, we injured ~ 5–15 fish per group, according to genotype availability after PCR genotyping. After injury, animals were randomly assigned to each experimental group (e.g. HR-HB-EGF treatment/BSA vehicle) and end-point. Viability was ~65%. For neonatal mouse experiments, we injured ~10 mice per group, and viability was ~70%. For adult mouse experiments, we injured 3–5 mice per group, with a viability of ~90%. No animals were excluded from the analyses. Investigators were not blinded during experiments and outcome assessment.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
The bulk RNA, ATAC and single-cell RNA sequencing datasets generated in this study have been deposited in the Gene Expression Omnibus (GEO) archive. The accession number for bulk RNA and ATAC sequencing is GSE193503. The accession number for single-cell RNA-seq data is GSE213435. The remaining data are available within the article or Source Data file. Unique biological materials are available from the corresponding author upon request. Source data are provided with this paper.
References
Sezer, N., Akkus, S. & Ugurlu, F. G. Chronic complications of spinal cord injury. World J. Orthop. 6, 24–33 (2015).
Fry, E. J., Stolp, H. B., Lane, M. A., Dziegielewska, K. M. & Saunders, N. R. Regeneration of supraspinal axons after complete transection of the thoracic spinal cord in neonatal opossums (Monodelphis domestica). J. Comp. Neurol. 466, 422–444 (2003).
Li, Y. et al. Microglia-organized scar-free spinal cord repair in neonatal mice. Nature 587, 613–618 (2020).
Burda, J. E. & Sofroniew, M. V. Reactive gliosis and the multicellular response to CNS damage and disease. Neuron 81, 229–248 (2014).
Dias, D. O. et al. Reducing pericyte-derived scarring promotes recovery after spinal cord injury. Cell 173, 153–165.e22 (2018).
Dorrier, C. E. et al. CNS fibroblasts form a fibrotic scar in response to immune cell infiltration. Nat. Neurosci. 24, 234–244 (2021).
Goritz, C. et al. A pericyte origin of spinal cord scar tissue. Science 333, 238–242 (2011).
Anderson, M. A. et al. Astrocyte scar formation aids central nervous system axon regeneration. Nature 532, 195–200 (2016).
Sun, F. et al. Sustained axon regeneration induced by co-deletion of PTEN and SOCS3. Nature 480, 372–375 (2011).
Park, K. K. et al. Promoting axon regeneration in the adult CNS by modulation of the PTEN/mTOR pathway. Science 322, 963–966 (2008).
Blackmore, M. & Letourneau, P. C. Changes within maturing neurons limit axonal regeneration in the developing spinal cord. J. Neurobiol. 66, 348–360 (2006).
Venkatesh, I., Mehra, V., Wang, Z., Califf, B. & Blackmore, M. G. Developmental chromatin restriction of pro-growth gene networks acts as an epigenetic barrier to axon regeneration in cortical neurons. Dev. Neurobiol. 78, 960–977 (2018).
Finelli, M. J., Wong, J. K. & Zou, H. Epigenetic regulation of sensory axon regeneration after spinal cord injury. J. Neurosci. 33, 19664–19676 (2013).
Becker, T., Wullimann, M. F., Becker, C. G., Bernhardt, R. R. & Schachner, M. Axonal regrowth after spinal cord transection in adult zebrafish. J. Comp. Neurol. 377, 577–595 (1997).
Reimer, M. M. et al. Motor neuron regeneration in adult zebrafish. J. Neurosci. 28, 8510–8516 (2008).
Cigliola, V., Becker, C. J. & Poss, K. D. Building bridges, not walls: spinal cord regeneration in zebrafish. Dis. Model Mech. 13 https://doi.org/10.1242/dmm.044131 (2020).
Becker, C. G. & Becker, T. Neuronal regeneration from ependymo-radial glial cells: cook, little pot, cook! Dev. Cell 32, 516–527 (2015).
Briona, L. K. & Dorsky, R. I. Radial glial progenitors repair the zebrafish spinal cord following transection. Exp. Neurol. 256, 81–92 (2014).
Mokalled, M. H. et al. Injury-induced ctgfa directs glial bridging and spinal cord regeneration in zebrafish. Science 354, 630–634 (2016).
Kuscha, V. et al. Lesion-induced generation of interneuron cell types in specific dorsoventral domains in the spinal cord of adult zebrafish. J. Comp. Neurol. 520, 3604–3616 (2012).
Ohnmacht, J. et al. Spinal motor neurons are regenerated after mechanical lesion and genetic ablation in larval zebrafish. Development 143, 1464–1474 (2016).
Goldshmit, Y. et al. Fgf-dependent glial cell bridges facilitate spinal cord regeneration in zebrafish. J. Neurosci. 32, 7477–7492 (2012).
Peng, S. X. et al. Semaphorin4D promotes axon regrowth and swimming ability during recovery following zebrafish spinal cord injury. Neuroscience 351, 36–46 (2017).
Yu, Y. M. et al. The extracellular matrix glycoprotein tenascin-C promotes locomotor recovery after spinal cord injury in adult zebrafish. Neuroscience 183, 238–250 (2011).
Wang, L. F. et al. Activating transcription factor 3 promotes spinal cord regeneration of adult zebrafish. Biochem. Biophys. Res. Commun. 488, 522–527 (2017).
Ji, Z. et al. Activating transcription factor 6 contributes to functional recovery after spinal cord injury in adult zebrafish. J. Mol. Neurosci. 71, 734–745 (2021).
Yu, Y. & Schachner, M. Syntenin-a promotes spinal cord regeneration following injury in adult zebrafish. Eur. J. Neurosci. 38, 2280–2289 (2013).
Hui, S. P. et al. Zebrafish regulatory T cells mediate organ-specific regenerative programs. Dev. Cell 43, 659–672.e5 (2017).
Kuscha, V., Barreiro-Iglesias, A., Becker, C. G. & Becker, T. Plasticity of tyrosine hydroxylase and serotonergic systems in the regenerating spinal cord of adult zebrafish. J. Comp. Neurol. 520, 933–951 (2012).
Meletis, K. et al. Spinal cord injury reveals multilineage differentiation of ependymal cells. PLoS Biol. 6, e182 (2008).
Dao, D. T., Anez-Bustillos, L., Adam, R. M., Puder, M. & Bielenberg, D. R. Heparin-binding epidermal growth factor-like growth factor as a critical mediator of tissue repair and regeneration. Am. J. Pathol. 188, 2446–2456 (2018).
Wan, J., Ramachandran, R. & Goldman, D. HB-EGF is necessary and sufficient for Muller glia dedifferentiation and retina regeneration. Dev. Cell 22, 334–347 (2012).
Jin, K. et al. Heparin-binding epidermal growth factor-like growth factor: hypoxia-inducible expression in vitro and stimulation of neurogenesis in vitro and in vivo. J. Neurosci. 22, 5365–5373 (2002).
Jin, K. et al. Neurogenesis and aging: FGF-2 and HB-EGF restore neurogenesis in hippocampus and subventricular zone of aged mice. Aging Cell 2, 175–183 (2003).
Reynolds, C. M., Eguchi, S., Frank, G. D. & Motley, E. D. Signaling mechanisms of heparin-binding epidermal growth factor-like growth factor in vascular smooth muscle cells. Hypertension 39, 525–529 (2002).
Tsata, V. et al. A switch in pdgfrb(+) cell-derived ECM composition prevents inhibitory scarring and promotes axon regeneration in the zebrafish spinal cord. Dev. Cell 56, 509–524.e9 (2021).
Zhao, L. et al. Insulin-like growth factor-1 enhances motoneuron survival and inhibits neuroinflammation after spinal cord transection in zebrafish. Cell Mol. Neurobiol. 42, 1373–1384 (2022).
Rossi, A. et al. Genetic compensation induced by deleterious mutations but not gene knockdowns. Nature 524, 230–233 (2015).
Cavone, L. et al. A unique macrophage subpopulation signals directly to progenitor cells to promote regenerative neurogenesis in the zebrafish spinal cord. Dev. Cell 56, 1617–1630.e6 (2021).
Tucic, M., Stamenkovic, V. & Andjus, P. The extracellular matrix glycoprotein tenascin C and adult neurogenesis. Front. Cell Dev. Biol. 9, 674199 (2021).
Klatt Shaw, D. et al. Localized EMT reprograms glial progenitors to promote spinal cord repair. Dev. Cell 56, 613–626.e7 (2021).
Mi, H., Muruganujan, A., Casagrande, J. T. & Thomas, P. D. Large-scale gene function analysis with the PANTHER classification system. Nat. Protoc. 8, 1551–1566 (2013).
Gilpin, A. et al. Self-healing of hyaluronic acid to improve in vivo retention and function. Adv. Healthc. Mater. e2100777 https://doi.org/10.1002/adhm.202100777 (2021).
Hejcl, A. et al. Biocompatible hydrogels in spinal cord injury repair. Physiol. Res. 57, S121–S132 (2008).
Hong, L. T. A. et al. An injectable hydrogel enhances tissue repair after spinal cord injury by promoting extracellular matrix remodeling. Nat. Commun. 8, 533 (2017).
Goldman, J. A. et al. Resolving heart regeneration by replacement histone profiling. Dev. Cell 40, 392–404.e5 (2017).
Kang, J. et al. Modulation of tissue repair by regeneration enhancer elements. Nature 532, 201–206 (2016).
Buenrostro, J. D., Wu, B., Chang, H. Y. & Greenleaf, W. J. ATAC-seq: a method for assaying chromatin accessibility genome-wide. Curr. Protoc. Mol. Biol. 109, 21.29.21–21.29.29 (2015).
Kvon, E. Z., Waymack, R., Gad, M. & Wunderlich, Z. Enhancer redundancy in development and disease. Nat. Rev. Genet. 22, 324–336 (2021).
Millimaki, B. B., Sweet, E. M. & Riley, B. B. Sox2 is required for maintenance and regeneration, but not initial development, of hair cells in the zebrafish inner ear. Dev. Biol. 338, 262–269 (2010).
Wang, W. et al. Changes in regeneration-responsive enhancers shape regenerative capacities in vertebrates. Science 369 https://doi.org/10.1126/science.aaz3090 (2020).
Yan, R. et al. An enhancer-based gene-therapy strategy for spatiotemporal control of cargoes during tissue repair. Cell Stem Cell 30, 96–111.e116 (2023).
Gonzalez, T. J. et al. Cross-species evolution of a highly potent AAV variant for therapeutic gene transfer and genome editing. Nat. Commun. 13, 5947 (2022).
Reimer, M. M. et al. Sonic hedgehog is a polarized signal for motor neuron regeneration in adult zebrafish. J. Neurosci. 29, 15073–15082 (2009).
Dias, T. B., Yang, Y. J., Ogai, K., Becker, T. & Becker, C. G. Notch signaling controls generation of motor neurons in the lesioned spinal cord of adult zebrafish. J. Neurosci. 32, 3245–3252 (2012).
Goldshmit, Y. et al. Different Fgfs have distinct roles in regulating neurogenesis after spinal cord injury in zebrafish. Neural Dev. 13, 24 (2018).
Reimer, M. M. et al. Dopamine from the brain promotes spinal motor neuron generation during development and adult regeneration. Dev. Cell 25, 478–491 (2013).
Barreiro-Iglesias, A. et al. Serotonin promotes development and regeneration of spinal motor neurons in zebrafish. Cell Rep. 13, 924–932 (2015).
Saraswathy, V. M. et al. Myostatin is a negative regulator of adult neurogenesis after spinal cord injury in zebrafish. Cell Rep. 41, 111705 (2022).
Yang, Z. et al. NT3-chitosan elicits robust endogenous neurogenesis to enable functional recovery after spinal cord injury. Proc. Natl Acad. Sci. USA 112, 13354–13359 (2015).
Thompson, J. D. et al. Identification and requirements of enhancers that direct gene expression during zebrafish fin regeneration. Development 147 https://doi.org/10.1242/dev.191262 (2020).
Sun, F. et al. Enhancer selection dictates gene expression responses in remote organs during tissue regeneration. Nat. Cell Biol. 24, 685–696 (2022).
O’Shea, T. M., Burda, J. E. & Sofroniew, M. V. Cell biology of spinal cord injury and repair. J. Clin. Invest. 127, 3259–3270 (2017).
Wang, Z. et al. Mechanistic basis of neonatal heart regeneration revealed by transcriptome and histone modification profiling. Proc. Natl Acad. Sci. USA 116, 18455–18465 (2019).
Avrahami, D. et al. Aging-dependent demethylation of regulatory elements correlates with chromatin state and improved beta cell function. Cell Metab. 22, 619–632 (2015).
Ongusaha, P. P. et al. HB-EGF is a potent inducer of tumor growth and angiogenesis. Cancer Res. 64, 5283–5290 (2004).
Bernardos, R. L. & Raymond, P. A. GFAP transgenic zebrafish. Gene Expr. Patterns 6, 1007–1013 (2006).
Bedell, V. M. et al. In vivo genome editing using a high-efficiency TALEN system. Nature 491, 114–118 (2012).
Hu, G., Goll, M. G. & Fisher, S. PhiC31 integrase mediates efficient cassette exchange in the zebrafish germline. Dev. Dyn. 240, 2101–2107 (2011).
Cermak, T. et al. Efficient design and assembly of custom TALEN and other TAL effector-based constructs for DNA targeting. Nucleic Acids Res. 39, e82 (2011).
Dahlem, T. J. et al. Simple methods for generating and detecting locus-specific mutations induced with TALENs in the zebrafish genome. PLoS Genet. 8, e1002861 (2012).
Fivaz, J., Bassi, M. C., Pinaud, S. & Mirkovitch, J. RNA polymerase II promoter-proximal pausing upregulates c-fos gene expression. Gene 255, 185–194 (2000).
Wehner, D. et al. Wnt signaling controls pro-regenerative Collagen XII in functional spinal cord regeneration in zebrafish. Nat. Commun. 8, 126 (2017).
Langmead, B. & Salzberg, S. L. Fast gapped-read alignment with Bowtie 2. Nat. Methods 9, 357–359 (2012).
Li, H. et al. The sequence alignment/map format and SAMtools. Bioinformatics 25, 2078–2079 (2009).
Zhang, Y. et al. Model-based analysis of ChIP-Seq (MACS). Genome Biol. 9, R137 (2008).
Lun, A. T. & Smyth, G. K. csaw: a Bioconductor package for differential binding analysis of ChIP-seq data using sliding windows. Nucleic Acids Res. 44, e45 (2016).
Kim, D. et al. TopHat2: accurate alignment of transcriptomes in the presence of insertions, deletions and gene fusions. Genome Biol. 14, R36 (2013).
Anders, S., Pyl, P. T. & Huber, W. HTSeq-a Python framework to work with high-throughput sequencing data. Bioinformatics 31, 166–169 (2015).
Love, M. I., Huber, W. & Anders, S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol. 15, 550 (2014).
Zhu, L. J. et al. ChIPpeakAnno: a Bioconductor package to annotate ChIP-seq and ChIP-chip data. BMC Bioinforma. 11, 237 (2010).
Mayor, C. et al. VISTA: visualizing global DNA sequence alignments of arbitrary length. Bioinformatics 16, 1046–1047 (2000).
Krzywinski, M. et al. Circos: an information aesthetic for comparative genomics. Genome Res. 19, 1639–1645 (2009).
Schep, A. N., Wu, B., Buenrostro, J. D. & Greenleaf, W. J. chromVAR: inferring transcription-factor-associated accessibility from single-cell epigenomic data. Nat. Methods 14, 975–978 (2017).
Sandelin, A., Alkema, W., Engstrom, P., Wasserman, W. W. & Lenhard, B. JASPAR: an open-access database for eukaryotic transcription factor binding profiles. Nucleic Acids Res. 32, D91–D94 (2004).
Ou, J. & Zhu, L. J. trackViewer: a Bioconductor package for interactive and integrative visualization of multi-omics data. Nat. Methods 16, 453–454 (2019).
Gu, Z., Eils, R. & Schlesner, M. Complex heatmaps reveal patterns and correlations in multidimensional genomic data. Bioinformatics 32, 2847–2849 (2016).
Zhou, Y. et al. Metascape provides a biologist-oriented resource for the analysis of systems-level datasets. Nat. Commun. 10, 1523 (2019).
Shoffner, A., Cigliola, V., Lee, N., Ou, J. & Poss, K. D. Tp53 suppression promotes cardiomyocyte proliferation during zebrafish heart regeneration. Cell Rep. 32, 108089 (2020).
Thomas, P. D. et al. PANTHER: Making genome-scale phylogenetics accessible to all. Protein Sci. 31, 8–22 (2022).
Hozumi, T., Kageyama, T., Ohta, S., Fukuda, J. & Ito, T. Injectable hydrogel with slow degradability composed of gelatin and hyaluronic acid cross-linked by Schiff’s base formation. Biomacromolecules 19, 288–297 (2018).
Opitz, R., Maquet, E., Zoenen, M., Dadhich, R. & Costagliola, S. TSH receptor function is required for normal thyroid differentiation in zebrafish. Mol. Endocrinol. 25, 1579–1599 (2011).
Faw, T. D. et al. Unique sensory and motor behavior in Thy1-GFP-M mice before and after spinal cord injury. J. Neurotrauma 35, 2167–2182 (2018).
Plemel, J. R. et al. A graded forceps crush spinal cord injury model in mice. J. Neurotrauma 25, 350–370 (2008).
Acknowledgements
We thank Jim Burris, Karina Olivieri, Larry Frauen, Colin Dolan, and Daniel Stutts for zebrafish care; Alexias Safi for help with library construction; Kelsey Oonk for ISH; Xin Lin for assistance with scRNA-Seq library construction; Duke DLAR staff for mouse care; and Fei Sun, Leslie Slota, and Jingli Cao for comments on the manuscript. V.C. was supported by Early (P2GEP3_175016) and Advanced (P400PM_186709) Postdoc Mobility fellowships from the Swiss National Science Foundation. Y.H. acknowledges support from grant 32070825 from National Natural Science Foundation of China. K.D.P. acknowledges research support from NIH grants R21 NS124635 and R35 HL150713.
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V.C. designed experimental strategy, generated transgenic and mutant zebrafish lines, performed experiments, analyzed data and wrote the manuscript. A.S. generated transgenic and mutant zebrafish lines. N.L., C.J.B., and G.S. performed experiments using zebrafish. J.O. performed bioinformatics analysis. J.H. and S.V. provided hydrogel and related advice for HR-HB-EGF delivery. Y.H. generated transgenic zebrafish. T.D.F. provided training and performed experiments in mice, and M.A.B. shared technical expertise on the latter. T.J.G. and A.A. provided AAV reagents and related advice. K.D.P. designed experimental strategy, analyzed data, and wrote the manuscript. All authors commented on the manuscript.
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V.C., A.S., and K.D.P. are listed as inventors on a patent application filed by Duke University on use of Hb-egf for spinal cord regeneration. Other authors declare no competing interests.
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Cigliola, V., Shoffner, A., Lee, N. et al. Spinal cord repair is modulated by the neurogenic factor Hb-egf under direction of a regeneration-associated enhancer. Nat Commun 14, 4857 (2023). https://doi.org/10.1038/s41467-023-40486-5
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DOI: https://doi.org/10.1038/s41467-023-40486-5
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