Complete spinal cord lesions interrupt the connection of all axonal projections with their neuronal targets below and above the lesion site. In particular, the interruption of connections with the neurons at lumbar segments after thoracic injuries impairs voluntary body control below the injury. The failure of spontaneous regrowth of transected axons across the lesion prevents the reconnection and reinnervation of the neuronal targets. At present, the only treatment in humans that has proven to promote some degree of locomotor recovery is physical therapy. The success of these strategies, however, depends greatly on the type of lesion and the level of preservation of neural tissue in the spinal cord after injury. That is the reason it is key to design strategies to promote axonal regrowth and neuronal reconnection. Here, we test the use of a developmental axon guidance molecule as a biological agent to promote axonal regrowth, axonal reconnection, and recovery of locomotor activity after spinal cord injury (SCI). This molecule, netrin-1, guides the growth of the corticospinal tract (CST) during the development of the central nervous system. To assess the potential of this molecule, we used a model of complete spinal cord transection in rats, at thoracic level 10–11. We show that in situ delivery of netrin-1 at the epicenter of the lesion: (1) promotes regrowth of CST through the lesion and prevents CST dieback, (2) promotes synaptic reconnection of regenerated motor and sensory axons, and (3) preserves the polymerization of the neurofilaments in the sciatic nerve axons. These anatomical findings correlate with a significant recovery of locomotor function. Our work identifies netrin-1 as a biological agent with the capacity to promote the functional repair and recovery of locomotor function after SCI. These findings support the use of netrin-1 as a therapeutic intervention to be tested in humans.
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References
1.
YezierskiR.P. (2009). Spinal cord injury pain: spinal and supraspinal mechanisms. J. Rehabil. Res. Dev. 46, 95–107.
2.
RabchevskyA.G., PatelS.P., and SpringerJ.E. (2011). Pharmacological interventions for spinal cord injury: where do we stand?. How might we step forward? Pharmacol. Ther. 132, 15–29.
3.
QuintaH.R., PasquiniJ.M., RabinovichG.A., and PasquiniL.A. (2014). Glycan-dependent binding of galectin-1 to neuropilin-1 promotes axonal regeneration after spinal cord injury. Cell Death Differ. 21, 941–955.
4.
YuW.R., and FehlingsM.G. (2011). Fas/FasL-mediated apoptosis and inflammation are key features of acute human spinal cord injury: implications for translational, clinical application. Acta Neuropathol. 122, 747–761.
FehlingsM.G., TetreaultL.A., WilsonJ.R., KwonB.K., BurnsA.S., MartinA.R., HawrylukG., and HarropJ.S. (2017). A clinical practice guideline for the management of acute spinal cord injury: introduction, rationale, and scope. Global Spine J. 7, SUPPL. 3, 84S–94S.
7.
HarkemaS.J., Schmidt-ReadM., LorenzD.J., EdgertonV.R., and BehrmanA.L. (2012). Balance and ambulation improvements in individuals with chronic incomplete spinal cord injury using locomotor training-based rehabilitation. Arch. Phys. Med. Rehabil. 93, 1508–1517.
8.
HarkemaS.J. (2008). Plasticity of interneuronal networks of the functionally isolated human spinal cord. Brain Res. Rev. 57, 255–264.
9.
DietzV., ColomboG., and JensenL. (1994). Locomotor activity in spinal man. Lancet, 344, 1260–1263.
10.
LiuZ., LiY., ZhangJ., EliasS., and ChoppM. (2008). Evaluation of corticospinal axon loss by fluorescent dye tracing in mice with experimental autoimmune encephalomyelitis. J. Neurosci. Methods, 167, 191–197.
11.
WelniarzQ., DusartI., and RozeE. (2017). The corticospinal tract: evolution, development, and human disorders. Dev. Neurobiol. 77, 810–829.
CourtineG., GerasimenkoY., van den BrandR., YewA., MusienkoP., ZhongH., SongB., AoY., IchiyamaR.M., LavrovI., RoyR.R., SofroniewM.V., and EdgertonV.R. (2009). Transformation of nonfunctional spinal circuits into functional states after the loss of brain input. Nat. Neurosci. 12, 1333–1342.
14.
BachmannL.C., MatisA., LindauN.T., FelderP., GulloM., and SchwabM.E. (2013). Deep brain stimulation of the midbrain locomotor region improves paretic hindlimb function after spinal cord injury in rats. Sci. Transl. Med. 5, 208ra146.
15.
WangZ.H., WalterG.F., and GerhardL. (1996). The expression of nerve growth factor receptor on Schwann cells and the effect of these cells on the regeneration of axons in traumatically injured human spinal cord. Acta Neuropathol. 91, 180–184.
16.
BjorklundA., and SteneviU. (1979). Regeneration of monoaminergic and cholinergic neurons in the mammalian central nervous system. Physiol. Rev, 59, 62–100.
17.
PoplawskiG.H., KawaguchiR., Van NiekerkE., LuP., MehtaN., CaneteP., LieR., DragatsisI., MevesJ.M., ZhengB., CoppolaG., and TuszynskiM.H. (2020). Injured adult neurons regress to an embryonic transcriptional growth state. Nature, 581, 77–82.
18.
MeneretA., FranzE.A., TrouillardO., OliverT.C., ZagarY., RobertsonS.P., WelniarzQ., GardnerR.J., GalleaC., SrourM., DepienneC., JasoniC.L., DubacqC., RiantF., LamyJ.C., MorelM.P., GueroisR., AndreaniJ., FouquetC., DoulazmiM., VidailhetM., RouleauG.A., BriceA., ChedotalA., DusartI., RozeE., and MarkieD. (2017). Mutations in the netrin-1 gene cause congenital mirror movements. J. Clin. Invest. 127, 3923–3936.
19.
TepavcevicV., KerninonC., AigrotM.S., MeppielE., MozafariS., Arnould-LaurentR., RavassardP., KennedyT.E., Nait-OumesmarB., and LubetzkiC. (2014). Early netrin-1 expression impairs central nervous system remyelination. Ann. Neurol. 76, 252–268.
20.
QuintaH.R., WilsonC., BlidnerA.G., Gonzalez-BillaultC., PasquiniL.A., RabinovichG.A., and PasquiniJ.M. (2016). Ligand-mediated Galectin-1 endocytosis prevents intraneural HO production promoting F-actin dynamics reactivation and axonal re-growth. Exp. Neurol. 283, 165–178.
21.
QuintaH.R., PasquiniL.A., and PasquiniJ.M. (2015). Three-dimensional reconstruction of corticospinal tract using one-photon confocal microscopy acquisition allows detection of axonal disruption in spinal cord injury. J. Neurochem. 133, 113–124.
22.
Institute of Laboratory Animal Resources (U.S.) (1996). Guide for the Care and Use of Laboratory Animals. 7th ed. Washington, D.C.: National Academies Press.1996.
23.
KanekoS., IwanamiA., NakamuraM., KishinoA., KikuchiK., ShibataS., OkanoH.J., IkegamiT., MoriyaA., KonishiO., NakayamaC., KumagaiK., KimuraT., SatoY., GoshimaY., TaniguchiM., ItoM., HeZ., ToyamaY., and OkanoH. (2006). A selective Sema3A inhibitor enhances regenerative responses and functional recovery of the injured spinal cord. Nat. Med. 12, 1380–1389.
24.
BregmanB.S. (1987). Spinal cord transplants permit the growth of serotonergic axons across the site of neonatal spinal cord transection. Brain Res. 431, 265–279.
25.
BassoD.M., BeattieM.S., and BresnahanJ.C. (1995). A sensitive and reliable locomotor rating scale for open field testing in rats. J. Neurotrauma, 12, 1–21.
26.
MetzG.A., and WhishawI.Q. (2009). The ladder rung walking task: a scoring system and its practical application. J. Vis. Exp. 28, 1204.
27.
QuintaH.R., MaschiD., Gomez-SanchezC., Piwien-PilipukG., and GalignianaM.D. (2010). Subcellular rearrangement of Hsp90-binding immunophilins accompanies neuronal differentiation and neurite outgrowth. J. Neurochem. 115, 716–734.
28.
QuintaH.R., and GalignianaM.D. (2012). The neuroregenerative mechanism mediated by the Hsp90-binding immunophilin FKBP52 resembles the early steps of neuronal differentiation. Br. J. Pharmacol. 166, 637–649.
29.
MaierI.C., BaumannK., ThallmairM., WeinmannO., SchollJ., and SchwabM.E. (2008). Constraint-induced movement therapy in the adult rat after unilateral corticospinal tract injury. J. Neurosci. 28, 9386–9403.
30.
HirakawaM., McCabeJ.T., and KawataM. (1992). Time-related changes in the labeling pattern of motor and sensory neurons innervating the gastrocnemius muscle, as revealed by the retrograde transport of the cholera toxin B subunit. Cell Tissue Res. 267, 419–427.
31.
PasquiniJ.M., BarrantesF.J., and QuintaH.R. (2017). Normal development of spinal axons in early embryo stages and posterior locomotor function is independent of GAL-1. J. Comp. Neurol. 525, 2861–2875.
32.
PatelA., LiZ., CaneteP., StroblH., DulinJ., KadoyaK., GibbsD., and PoplawskiG.H.D. (2018). AxonTracer: a novel ImageJ plugin for automated quantification of axon regeneration in spinal cord tissue. BMC Neurosci. 19, 8.
33.
MetzG.A., MerklerD., DietzV., SchwabM.E., and FouadK. (2000). Efficient testing of motor function in spinal cord injured rats. Brain Res. 883, 165–177.
34.
DominiciC., Moreno-BravoJ.A., PuiggrosS.R., RappeneauQ., RamaN., VieugueP., BernetA., MehlenP., and ChedotalA. (2017). Floor-plate-derived netrin-1 is dispensable for commissural axon guidance. Nature, 545, 350–354.
35.
VaradarajanS.G., KongJ.H., PhanK.D., KaoT.J., PanaitofS.C., CardinJ., EltzschigH., KaniaA., NovitchB.G., and ButlerS.J. (2017). Netrin1 produced by neural progenitors, not floor plate cells, is required for axon guidance in the spinal cord. Neuron, 94, 790–799.e793.
36.
CourtineG., and SofroniewM.V. (2019). Spinal cord repair: advances in biology and technology. Nat. Med. 25, 898–908.
37.
O'SheaT.M., BurdaJ.E., and SofroniewM.V. (2017). Cell biology of spinal cord injury and repair. J. Clin. Invest. 127, 3259–3270.
38.
TuszynskiM.H., and StewardO. (2012). Concepts and methods for the study of axonal regeneration in the CNS. Neuron, 74, 777–791.
FriedliL., RosenzweigE.S., BarraudQ., SchubertM., DominiciN., AwaiL., NielsonJ.L., MusienkoP., Nout-LomasY., ZhongH., ZdunowskiS., RoyR.R., StrandS.C., van den BrandR., HavtonL.A., BeattieM.S., BresnahanJ.C., BezardE., BlochJ., EdgertonV.R., FergusonA.R., CurtA., TuszynskiM.H., and CourtineG. (2015). Pronounced species divergence in corticospinal tract reorganization and functional recovery after lateralized spinal cord injury favors primates. Sci. Transl. Med. 7, 302ra134.
41.
PivettaC., EspositoM.S., SigristM., and ArberS. (2014). Motor-circuit communication matrix from spinal cord to brainstem neurons revealed by developmental origin. Cell, 156, 537–548.
42.
WilliamsM.E., de WitJ., and GhoshA. (2010). Molecular mechanisms of synaptic specificity in developing neural circuits. Neuron, 68, 9–18.
43.
SudhofT.C. (2018). Towards an understanding of synapse formation. Neuron, 100, 276–293.
44.
RaineteauO., and SchwabM.E. (2001). Plasticity of motor systems after incomplete spinal cord injury. Nat. Rev. Neurosci. 2, 263–273.
45.
CaffertyW.B., McGeeA.W., and StrittmatterS.M. (2008). Axonal growth therapeutics: regeneration or sprouting or plasticity?. Trends Neurosci. 31, 215–220.
46.
BareyreF.M., KerschensteinerM., RaineteauO., MettenleiterT.C., WeinmannO., and SchwabM.E. (2004). The injured spinal cord spontaneously forms a new intraspinal circuit in adult rats. Nat. Neurosci. 7, 269–277.
47.
BermanS.A., YoungR.R., SarkaratiM., and ShefnerJ.M. (1996). Injury zone denervation in traumatic quadriplegia in humans. Muscle Nerve, 19, 701–706.
48.
ZhengC., ZhuY., LuF., MaX., TianD., and JiangJ. (2017). Trans-synaptic degeneration of motoneurons distal to chronic cervical spinal cord compression in cervical spondylotic myelopathy. Int. J. Neurosci. 127, 988–995.
49.
NacimientoW., SappokT., BrookG.A., TothL., SchoenS.W., NothJ., and KreutzbergG.W. (1995). Structural changes of anterior horn neurons and their synaptic input caudal to a low thoracic spinal cord hemisection in the adult rat: a light and electron microscopic study. Acta Neuropathol. 90, 552–564.
50.
FingerJ.H., BronsonR.T., HarrisB., JohnsonK., PrzyborskiS.A., and AckermanS.L. (2002). The netrin 1 receptors Unc5h3 and Dcc are necessary at multiple choice points for the guidance of corticospinal tract axons. J. Neurosci. 22, 10346–10356.
51.
SzaroB.G., and StrongM.J. (2010). Post-transcriptional control of neurofilaments: new roles in development, regeneration and neurodegenerative disease. Trends Neurosci. 33, 27–37.
52.
ClevelandD.W., MonteiroM.J., WongP.C., GillS.R., GearhartJ.D., and HoffmanP.N. (1991). Involvement of neurofilaments in the radial growth of axons. J. Cell Sci. Suppl. 15, 85–95.
53.
MilichL.M., RyanC.B., and LeeJ.K. (2019). The origin, fate, and contribution of macrophages to spinal cord injury pathology. Acta Neuropathol. 137, 785–797.
54.
CekanaviciuteE., and BuckwalterM.S. (2016). Astrocytes: integrative regulators of neuroinflammation in stroke and other neurological diseases. Neurotherapeutics, 13, 685–701.
55.
PopovichP.G., GuanZ., WeiP., HuitingaI., van RooijenN., and StokesB.T. (1999). Depletion of hematogenous macrophages promotes partial hindlimb recovery and neuroanatomical repair after experimental spinal cord injury. Exp. Neurol. 158, 351–365.
56.
JonesT.B., McDanielE.E., and PopovichP.G. (2005). Inflammatory-mediated injury and repair in the traumatically injured spinal cord. Curr. Pharm. Des. 11, 1223–1236.
57.
TianD.S., YuZ.Y., XieM.J., BuB.T., WitteO.W., and WangW. (2006). Suppression of astroglial scar formation and enhanced axonal regeneration associated with functional recovery in a spinal cord injury rat model by the cell cycle inhibitor olomoucine. J. Neurosci. Res. 84, 1053–1063.
58.
PineauI., SunL., BastienD., and LacroixS. (2010). Astrocytes initiate inflammation in the injured mouse spinal cord by promoting the entry of neutrophils and inflammatory monocytes in an IL-1 receptor/MyD88-dependent fashion. Brain Behav. Immun. 24, 540–553.
59.
WangX., CaoK., SunX., ChenY., DuanZ., SunL., GuoL., BaiP., SunD., FanJ., HeX., YoungW., and RenY. (2015). Macrophages in spinal cord injury: phenotypic and functional change from exposure to myelin debris. Glia, 63, 635–651.
60.
BuschS.A., HornK.P., SilverD.J., and SilverJ. (2009). Overcoming macrophage-mediated axonal dieback following CNS injury. J. Neurosci. 29, 9967–9976.
61.
EvansT.A., BarkauskasD.S., MyersJ.T., HareE.G., YouJ.Q., RansohoffR.M., HuangA.Y., and SilverJ. (2014). High-resolution intravital imaging reveals that blood-derived macrophages but not resident microglia facilitate secondary axonal dieback in traumatic spinal cord injury. Exp. Neurol. 254, 109–120.
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