Cell Adhesion-Dependent Biphasic Axon Outgrowth Elucidated by Femtosecond Laser Impulse

Axon outgrowth is promoted by the mechanical coupling between the dynamic actin cytoskeleton and adhesive substrates via clutch and adhesion molecules in the axonal growth cone. In this study, we utilized a femtosecond laser-induced impulse to break the coupling between an axonal growth cone and an adhesive substrate, enabling us to evaluate the strength of the binding between proteins in the growth cone and a laminin substrate, and also determine the contribution of adhesion strength to axon outgrowth. We found that the adhesion strength of axonal L1 cell adhesion molecule (L1CAM)-laminin binding increased with the density of the laminin substrate. In addition, fluorescent speckle microscopy revealed that the retrograde flow of actin filaments in the axonal growth cone was dependent on the laminin density such that the flow speed reduced with increasing L1CAM-laminin binding. However, axon outgrowth did not increase monotonically with increased L1CAM-laminin binding but rather exhibited biphasic behavior, in which the outgrowth was suppressed by excessive L1CAM-laminin binding. Our quantitative evaluations of the adhesion strength suggest that the biphasic outgrowth is regulated by the balance between traction force and adhesion strength as a result of changes in the number of L1CAM-laminin interactions. These results imply that adhesion modulation is key to the regulation of axon guidance.

Shaking hands is a homeodomain transcription factor that controls axon outgrowth of central complex neurons in the insect model Tribolium

Gene regulatory mechanisms which specify subtype identity of central complex (CX) neurons are the subject of intense investigation. The CX is a compartment within the brain common to all insect species and functions as a “command center” which directs motor actions. It is made up of several thousand neurons with more than 60 morphologically distinct identities. Accordingly, transcriptional programs must effect the specification of at least as many neuronal subtypes. We demonstrate a role for the transcription factor Shaking hands (Skh) in the specification of embryonic CX neurons in Tribolium. The developmental dynamics of Tc-skh expression are characteristic for terminal selectors of subtype identity. In the embryonic brain, Tc-skh expression is restricted to a subset of neurons, many of which survive to adulthood and contribute to the mature CX. Tc-skh expression is maintained throughout the lifetime in at least some CX neurons. Tc-skh knock-down results in axon outgrowth defects thus preventing the formation of an embryonic CX primordium. The as yet unstudied Drosophila skh shows a similar embryonic expression pattern suggesting that subtype specification of CX neurons may be conserved.

Guided Axon Outgrowth of Neurons by Real-Time Femtosecond Laser Penetration on a 4 μm Thick Thin-Glass Sheet

Transplantation of scaffold-embedded guided neurons has been reported to increase neuronal regeneration following brain injury. However, precise axonal integration between host and transplant neurons to form functional synapses remains a major problem. This study aims to develop a real-time femtosecond (fs) laser penetration on a 4 μm thick thin-glass sheet to promote guided axon outgrowth influenced by molecular gradients in a microfluidic device. The device enables the introduction of the guidance molecule (i.e., netrin-1), neuronal culture, and manipulation by fs laser. After fabricating multiple micro-holes on the thin-glass sheet using fs laser, netrin-1 gradients with radial concentrations are generated in the chamber, affecting axon outgrowth and guidance. A majority of axons (~92%) experiences guided outgrowth with positive angular changes towards netrin-1 gradients. These results demonstrate the capability of the precise and real-time manipulation system based on a fs laser and a microfluidic device to control the growth of neurons.

Rgs4 is a regulator of mTOR activity required for motoneuron axon outgrowth and neuronal development in zebrafish

The Regulator of G protein signaling 4 (Rgs4) is a member of the RGS proteins superfamily that modulates the activity of G-protein coupled receptors. It is mainly expressed in the nervous system and is linked to several neuronal signaling pathways; however, its role in neural development in vivo remains inconclusive. Here, we generated and characterized a rgs4 loss of function model (MZrgs4) in zebrafish. MZrgs4 embryos showed motility defects and presented reduced head and eye sizes, reflecting defective motoneurons axon outgrowth and a significant decrease in the number of neurons in the central and peripheral nervous system. Forcing the expression of Rgs4 specifically within motoneurons rescued their early defective outgrowth in MZrgs4 embryos, indicating an autonomous role for Rgs4 in motoneurons. We also analyzed the role of Akt, Erk and mechanistic target of rapamycin (mTOR) signaling cascades and showed a requirement for these pathways in motoneurons axon outgrowth and neuronal development. Drawing on pharmacological and rescue experiments in MZrgs4, we provide evidence that Rgs4 facilitates signaling mediated by Akt, Erk and mTOR in order to drive axon outgrowth in motoneurons and regulate neuronal numbers.

Pax3 induces neural circuit repair through a developmental program of directed axon outgrowth

ABSTRACTAlthough neurotrophins can reorganise surviving neuronal connections after a lesion, clinical improvement is minimal and underlying mechanisms ill-defined, which impedes the development of effective treatment strategies. Here we show that the neurotrophin brain derived neurotrophic factor (BDNF) upregulates the transcription factor Pax3, which in turn induces axon outgrowth and synaptogenesis to repair a neural circuit. This repair depends on Pax3 increasing polysialic acid-neural cell adhesion molecule (PSA-NCAM), which is both essential for, and mediates the amount of, reinnervation. Pax3 acts pre-synaptically: its expression in reinnervating neurons induces significant axonal growth, and Pax3 knockdown abolishes reinnervation induced by BDNF, either endogenous BDNF expression during spontaneous developmental repair, or exogenous BDNF treatment in the mature nervous system. This is a novel role for Pax3. We propose that neuronal Pax3 induces PSA-NCAM expression on axon terminals to increase their motility and outgrowth, thereby promoting neural circuit reorganisation and repair.

Htt is a repressor of Abl activity required for APP-induced axonal growth

Huntington’s disease is a progressive autosomal dominant neurodegenerative disorder caused by the expansion of a polyglutamine tract at the N-terminus of a large cytoplasmic protein. The Drosophila huntingtin (htt) gene is widely expressed during all developmental stages from embryos to adults. However, Drosophila htt mutant individuals are viable with no obvious developmental defects. We asked if such defects could be detected in htt mutants in a background that had been genetically sensitized to reveal cryptic developmental functions. Amyloid precursor protein (APP) is linked to Alzheimer’s disease. Appl is the Drosophila APP ortholog and Appl signaling modulates axon outgrowth in the mushroom bodies (MBs), the learning and memory center in the fly, in part by recruiting Abl tyrosine kinase. Here, we find that htt mutations suppress axon outgrowth defects of αβ neurons in Appl mutant MB by derepressing the activity of Abl. We show that Abl is required in MB αβ neurons for their axon outgrowth. Importantly, both Abl overexpression and lack of expression produce similar phenotypes in the MBs, indicating the necessity of tightly regulating Abl activity. We find that Htt behaves genetically as a repressor of Abl activity, and consistent with this, in vivo FRET-based measurements reveal a significant increase in Abl kinase activity in the MBs when Htt levels are reduced. Thus, Appl and Htt have essential but opposing roles in MB development, promoting and suppressing Abl kinase activity, respectively, to maintain the appropriate intermediate level necessary for axon growth.