| Q35046982 | "Standby" EMT and "immune cell trapping" structure as novel mechanisms for limiting neuronal damage after CNS injury |
| Q89599307 | A Role of Microtubules in Oligodendrocyte Differentiation |
| Q36587914 | A dominant mutation in mec-7/β-tubulin affects axon development and regeneration in Caenorhabditis elegans neurons |
| Q41677462 | A high mitochondrial transport rate characterizes CNS neurons with high axonal regeneration capacity. |
| Q37983531 | A novel role for retrograde transport of microtubules in the axon |
| Q41162349 | AAV-mediated expression of BAG1 and ROCK2-shRNA promote neuronal survival and axonal sprouting in a rat model of rubrospinal tract injury |
| Q35156228 | AKAP12 mediates barrier functions of fibrotic scars during CNS repair |
| Q97516678 | Acute Cellular and Functional Changes With a Combinatorial Treatment of Ion Channel Inhibitors Following Spinal Cord Injury |
| Q30587931 | An assay to image neuronal microtubule dynamics in mice |
| Q41047757 | An injectable hydrogel enhances tissue repair after spinal cord injury by promoting extracellular matrix remodeling. |
| Q37983990 | Assembly of a new growth cone after axotomy: the precursor to axon regeneration |
| Q30819691 | Autophagy induction stabilizes microtubules and promotes axon regeneration after spinal cord injury |
| Q41165088 | Axon injury triggers EFA-6 mediated destabilization of axonal microtubules via TACC and doublecortin like kinase |
| Q35162703 | Axon regeneration in C. elegans |
| Q34015740 | Axon regeneration mechanisms: insights from C. elegans |
| Q34029714 | Axon regeneration pathways identified by systematic genetic screening in C. elegans |
| Q30501903 | Axon regeneration requires coordinate activation of p38 and JNK MAPK pathways |
| Q28079729 | Axonal Transport and Neurodegeneration: How Marine Drugs Can Be Used for the Development of Therapeutics |
| Q27331607 | Axonal regeneration. Systemic administration of epothilone B promotes axon regeneration after spinal cord injury |
| Q38908215 | Axonal regrowth after spinal cord injury via chondroitinase and the tissue plasminogen activator (tPA)/plasmin system |
| Q90639155 | Axonal transport: Driving synaptic function |
| Q35084174 | Axoplasmic reticulum Ca(2+) release causes secondary degeneration of spinal axons |
| Q28589147 | B-RAF kinase drives developmental axon growth and promotes axon regeneration in the injured mature CNS |
| Q38070883 | BACE1 influences debris clearance and axonal regeneration in injured peripheral nerve |
| Q26852511 | BMP signaling in axon regeneration |
| Q43137854 | Between new genetic discoveries and large randomized trials--neurological research in the era of systems medicine |
| Q41881450 | Beyond taxol: microtubule-based strategies for promoting nerve regeneration after injury |
| Q37200301 | Beyond taxol: microtubule-based treatment of disease and injury of the nervous system |
| Q30041843 | Biogenesis of the crystalloid organelle in Plasmodium involves microtubule-dependent vesicle transport and assembly |
| Q47332307 | Biomaterial strategies for limiting the impact of secondary events following spinal cord injury. |
| Q49164561 | Biomaterial-Supported Cell Transplantation Treatments for Spinal Cord Injury: Challenges and Perspectives. |
| Q37899109 | Biophysics of substrate interaction: influence on neural motility, differentiation, and repair |
| Q36172067 | Bogijetong decoction and its active herbal components protect the peripheral nerve from damage caused by taxol or nerve crush |
| Q36374987 | Bone marrow mesenchymal stem cells combined with minocycline improve spinal cord injury in a rat model |
| Q37463947 | Branch-Specific Microtubule Destabilization Mediates Axon Branch Loss during Neuromuscular Synapse Elimination |
| Q26801526 | Building the Neuronal Microtubule Cytoskeleton |
| Q34497965 | CNP/cGMP signaling regulates axon branching and growth by modulating microtubule polymerization. |
| Q38830850 | CNS repair and axon regeneration: Using genetic variation to determine mechanisms |
| Q58590795 | CRISPR/Cas9-mediated kif15 mutations accelerate axonal outgrowth during neuronal development and regeneration in zebrafish |
| Q38875531 | CRMPs Function in Neurons and Glial Cells: Potential Therapeutic Targets for Neurodegenerative Diseases and CNS Injury |
| Q35834510 | CXCR7 antagonism prevents axonal injury during experimental autoimmune encephalomyelitis as revealed by in vivo axial diffusivity |
| Q45943126 | Calcium channel inhibition-mediated axonal stabilization improves axonal regeneration after optic nerve crush. |
| Q48250016 | Can injured adult CNS axons regenerate by recapitulating development? |
| Q93523166 | Cancer drug promotes axon regeneration |
| Q39454081 | Cell biology of spinal cord injury and repair |
| Q38188439 | Cell intrinsic control of axon regeneration |
| Q103803773 | Chronic neuronal activation increases dynamic microtubules to enhance functional axon regeneration after dorsal root crush injury |
| Q50682196 | Class II HDACs and neuronal regeneration. |
| Q97519999 | Collapsin Response Mediator Proteins: Their Biological Functions and Pathophysiology in Neuronal Development and Regeneration |
| Q54212643 | Combined Transcriptomics, Proteomics and Bioinformatics Identify Drug Targets in Spinal Cord Injury. |
| Q36390877 | Conduction failure following spinal cord injury: functional and anatomical changes from acute to chronic stages |
| Q36778723 | Context Specificity of Stress-activated Mitogen-activated Protein (MAP) Kinase Signaling: The Story as Told by Caenorhabditis elegans |
| Q26799148 | Coordinating neuronal actin-microtubule dynamics |
| Q30619667 | Crmp4 deletion promotes recovery from spinal cord injury by neuroprotection and limited scar formation |
| Q35472270 | Cytoskeletal disruption activates the DLK/JNK pathway, which promotes axonal regeneration and mimics a preconditioning injury. |
| Q91862504 | Deacetylation of Miro1 by HDAC6 blocks mitochondrial transport and mediates axon growth inhibition |
| Q28082410 | Deceivingly dynamic: Learning-dependent changes in stathmin and microtubules |
| Q26865654 | Developing therapeutic approaches to tau, selected kinases, and related neuronal protein targets |
| Q90429247 | Dextran-based biodegradable nanoparticles: an alternative and convenient strategy for treatment of traumatic spinal cord injury |
| Q41270098 | Differential Expression of Tubulin Acetylase and Deacetylase Between the Damaged Central and Peripheral Branch of Dorsal Root Ganglion Neurons |
| Q92131921 | Dissecting the Dual Role of the Glial Scar and Scar-Forming Astrocytes in Spinal Cord Injury |
| Q33761371 | Dopamine: a parallel pathway for the modulation of spinal locomotor networks. |
| Q64234909 | Dynein promotes sustained axonal growth and Schwann cell remodeling early during peripheral nerve regeneration |
| Q39391713 | Dyrk kinases regulate phosphorylation of doublecortin, cytoskeletal organization, and neuronal morphology |
| Q35015599 | Early axonal loss accompanied by impaired endocytosis, abnormal axonal transport, and decreased microtubule stability occur in the model of Krabbe's disease |
| Q38976812 | Effective improvement of the neuroprotective activity after spinal cord injury by synergistic effect of glucocorticoid with biodegradable amphipathic nanomicelles. |
| Q89975614 | Effects of Electrical Stimulation on Peripheral Nerve Regeneration in a Silicone Rubber Conduit in Taxol-Treated Rats |
| Q37633265 | Effects of Taxol on Regeneration in a Rat Sciatic Nerve Transection Model |
| Q45168459 | Effects of an immunomodulatory therapy and chondroitinase after spinal cord hemisection injury |
| Q37343521 | Enhancement of Peripheral Nerve Regrowth by the Purine Nucleoside Analog and Cell Cycle Inhibitor, Roscovitine. |
| Q49397380 | Environmental cues determine the fate of astrocytes after spinal cord injury |
| Q90244991 | Epac2 Promotes Axonal Outgrowth and Attenuates the Glial Reaction in an Ex Vivo Model of Spinal Cord Injury |
| Q48506586 | Epothilone B Benefits Nigrostriatal Pathway Recovery by Promoting Microtubule Stabilization After Intracerebral Hemorrhage |
| Q49483504 | Epothilone B Speeds Corneal Nerve Regrowth and Functional Recovery through Microtubule Stabilization and Increased Nerve Beading. |
| Q47388453 | Epothilone B impairs functional recovery after spinal cord injury by increasing secretion of macrophage colony-stimulating factor |
| Q104617068 | Epothilones Improve Axonal Growth and Motor Outcomes after Stroke in the Adult Mammalian CNS |
| Q37309719 | Evidence for an Age-Dependent Decline in Axon Regeneration in the Adult Mammalian Central Nervous System |
| Q35649570 | Exclusion of integrins from CNS axons is regulated by Arf6 activation and the AIS. |
| Q27005889 | Extracellular and Intracellular Signaling for Neuronal Polarity |
| Q35654115 | Extrinsic and intrinsic determinants of nerve regeneration |
| Q42428107 | Extrinsic and intrinsic regulation of axon regeneration at a crossroads |
| Q37941706 | Facilitating axon regeneration in the injured CNS by microtubules stabilization. |
| Q33723584 | Fenbendazole improves pathological and functional recovery following traumatic spinal cord injury |
| Q88502776 | Fibronectin EDA forms the chronic fibrotic scar after contusive spinal cord injury |
| Q36050019 | Filamin A is required in injured axons for HDAC5 activity and axon regeneration |
| Q43181885 | Force Generation by Molecular-Motor-Powered Microtubule Bundles; Implications for Neuronal Polarization and Growth |
| Q92497788 | Functional Regeneration of the Sensory Root via Axonal Invasion |
| Q38178501 | Functional regeneration beyond the glial scar. |
| Q37948144 | Gene transfer mediated by stem cell grafts to treat CNS injury |
| Q28506127 | Gene-Silencing Screen for Mammalian Axon Regeneration Identifies Inpp5f (Sac2) as an Endogenous Suppressor of Repair after Spinal Cord Injury |
| Q64059178 | Genetic inhibition of CRMP2 phosphorylation at serine 522 promotes axonal regeneration after optic nerve injury |
| Q38091321 | Glaucoma and optic nerve repair. |
| Q38225513 | Glial cells as progenitors and stem cells: new roles in the healthy and diseased brain |
| Q26829489 | Growing the growth cone: remodeling the cytoskeleton to promote axon regeneration |
| Q50666634 | Growth, collapse, and stalling in a mechanical model for neurite motility. |
| Q27013969 | HDAC signaling in neuronal development and axon regeneration |
| Q36103678 | HDAC5 is a novel injury-regulated tubulin deacetylase controlling axon regeneration |
| Q92565031 | High-resolution 3D imaging and analysis of axon regeneration in unsectioned spinal cord with or without tissue clearing |
| Q36602323 | High-throughput proteomics reveal alarmins as amplifiers of tissue pathology and inflammation after spinal cord injury |
| Q35853603 | Histone acetylation inhibitors promote axon growth in adult dorsal root ganglia neurons |
| Q26852732 | Hydrogels in spinal cord injury repair strategies |
| Q47720179 | Hyperdynamic microtubules, cognitive deficits, and pathology are improved in tau transgenic mice with low doses of the microtubule-stabilizing agent BMS-241027. |
| Q53935058 | Impact of neural cell adhesion molecule deletion on regeneration after mouse spinal cord injury. |
| Q34325157 | Independent evaluation of the anatomical and behavioral effects of Taxol in rat models of spinal cord injury. |
| Q26801125 | Inhibition of kinesin-5 improves regeneration of injured axons by a novel microtubule-based mechanism |
| Q37585122 | Insulin/IGF1 signaling inhibits age-dependent axon regeneration |
| Q38160670 | Interphase microtubules: chief casualties in the war on cancer? |
| Q36756735 | Intraspinal Delivery of Polyethylene Glycol-coated Gold Nanoparticles Promotes Functional Recovery After Spinal Cord Injury. |
| Q39205746 | Intrathecal epigallocatechin gallate treatment improves functional recovery after spinal cord injury by upregulating the expression of BDNF and GDNF. |
| Q57806427 | Intrinsic Determinants of Axon Regeneration |
| Q40965939 | KIF5A transports collagen vesicles of myofibroblasts during pleural fibrosis |
| Q36335711 | Kinesin-13 and tubulin posttranslational modifications regulate microtubule growth in axon regeneration |
| Q37679296 | Large-scale chondroitin sulfate proteoglycan digestion with chondroitinase gene therapy leads to reduced pathology and modulates macrophage phenotype following spinal cord contusion injury |
| Q34063481 | Learning-induced and stathmin-dependent changes in microtubule stability are critical for memory and disrupted in ageing |
| Q46666867 | Liraglutide activates autophagy via GLP-1R to improve functional recovery after spinal cord injury |
| Q34642744 | Live imaging of astrocyte responses to acute injury reveals selective juxtavascular proliferation. |
| Q99712204 | Local Delivery of Taxol From FGL-Functionalized Self-Assembling Peptide Nanofiber Scaffold Promotes Recovery After Spinal Cord Injury |
| Q41628695 | Local Release of Paclitaxel from Aligned, Electrospun Microfibers Promotes Axonal Extension |
| Q36353480 | Local axonal function of STAT3 rescues axon degeneration in the pmn model of motoneuron disease |
| Q30597088 | Loop formation and self-fasciculation of cortical axon using photonic guidance at long working distance |
| Q92482055 | MAP7 Prevents Axonal Branch Retraction by Creating a Stable Microtubule Boundary to Rescue Polymerization |
| Q48232313 | Maximizing functional axon repair in the injured central nervous system: Lessons from neuronal development |
| Q38330759 | Mechanisms of distal axonal degeneration in peripheral neuropathies. |
| Q33632434 | Mechanisms of kinetic stabilization by the drugs paclitaxel and vinblastine. |
| Q33588585 | Mechanisms responsible for the inhibitory effects of epothilone B on scar formation after spinal cord injury |
| Q93053162 | Metformin Promotes Axon Regeneration after Spinal Cord Injury through Inhibiting Oxidative Stress and Stabilizing Microtubule |
| Q24294186 | Mice lacking α-tubulin acetyltransferase 1 are viable but display α-tubulin acetylation deficiency and dentate gyrus distortion |
| Q46581382 | MicroRNA-133b Negatively Regulates Zebrafish Single Mauthner-Cell Axon Regeneration through Targeting tppp3 in Vivo |
| Q61805378 | Microglia are an essential component of the neuroprotective scar that forms after spinal cord injury |
| Q38984991 | Microtubule Destabilization Paves the Way to Parkinson's Disease. |
| Q30539763 | Microtubule alterations occur early in experimental parkinsonism and the microtubule stabilizer epothilone D is neuroprotective |
| Q27014695 | Microtubule deacetylation sets the stage for successful axon regeneration |
| Q91938846 | Microtubule dynamics in healthy and injured neurons |
| Q48680605 | Microtubule stabilization by peloruside A and paclitaxel rescues degenerating neurons from okadaic acid-induced tau phosphorylation |
| Q48230835 | Microtubule stabilization promoted axonal regeneration and functional recovery after spinal root avulsion |
| Q38307155 | Microtubule-Targeting Agents Enter the Central Nervous System (CNS): Double-edged Swords for Treating CNS Injury and Disease. |
| Q41576648 | Microtubules in health and degenerative disease of the nervous system |
| Q57484393 | Modeling the Axon as an Active Partner with the Growth Cone in Axonal Elongation |
| Q36539451 | Molecular and Cellular Mechanisms of Axonal Regeneration After Spinal Cord Injury |
| Q36178869 | Molecular and functional expression of cation-chloride cotransporters in dorsal root ganglion neurons during postnatal maturation |
| Q38246350 | Molecular mechanisms of scar-sourced axon growth inhibitors |
| Q92965151 | Moving beyond the glial scar for spinal cord repair |
| Q41595186 | Myelin Lipids Inhibit Axon Regeneration Following Spinal Cord Injury: a Novel Perspective for Therapy |
| Q30581187 | NAD+ and SIRT3 control microtubule dynamics and reduce susceptibility to antimicrotubule agents |
| Q41548065 | Nanoparticle Delivery of Fidgetin siRNA as a Microtubule-based Therapy to Augment Nerve Regeneration. |
| Q38043061 | Neural regeneration in Caenorhabditis elegans |
| Q47110818 | Neuron and microglia/macrophage-derived FGF10 activate neuronal FGFR2/PI3K/Akt signaling and inhibit microglia/macrophages TLR4/NF-κB-dependent neuroinflammation to improve functional recovery after spinal cord injury |
| Q58153852 | Neuronal Intrinsic Regenerative Capacity: The Impact of Microtubule Organization and Axonal Transport |
| Q38154639 | Neuronal cytoskeleton in synaptic plasticity and regeneration. |
| Q30597608 | Neuronal deletion of GSK3β increases microtubule speed in the growth cone and enhances axon regeneration via CRMP-2 and independently of MAP1B and CLASP2. |
| Q28085521 | Neuronal responses to stress and injury in C. elegans |
| Q58779669 | Neuronal-Specific TUBB3 Is Not Required for Normal Neuronal Function but Is Essential for Timely Axon Regeneration |
| Q35017020 | Neuroprotective effect of bone marrow stromal cell combination with atorvastatin in rat model of spinal cord injury |
| Q48656158 | Neurotoxic mechanisms of paclitaxel are local to the distal axon and independent of transport defects |
| Q39717740 | New approach to treating spinal cord injury using PEG-TAT-modified, cyclosporine-A-loaded PLGA/polymeric liposomes |
| Q41785238 | No simpler than mammals: axon and dendrite regeneration in Drosophila. |
| Q58796705 | Novel multi-drug delivery hydrogel using scar-homing liposomes improves spinal cord injury repair |
| Q43054526 | Optochemistry to control the microtubule cytoskeleton |
| Q37331013 | PI3K-GSK3 signalling regulates mammalian axon regeneration by inducing the expression of Smad1. |
| Q36618288 | Paclitaxel improves outcome from traumatic brain injury. |
| Q27691306 | Paclitaxel: new uses for an old drug |
| Q90833146 | Panoptic imaging of transparent mice reveals whole-body neuronal projections and skull-meninges connections |
| Q34674277 | Pharmacologically inhibiting kinesin-5 activity with monastrol promotes axonal regeneration following spinal cord injury |
| Q35729506 | Phenotypic assays to identify agents that induce reactive gliosis: a counter-screen to prioritize compounds for preclinical animal studies |
| Q99551117 | Photoswitchable paclitaxel-based microtubule stabilisers allow optical control over the microtubule cytoskeleton |
| Q90629410 | Plasticity Induced Recovery of Breathing Occurs at Chronic Stages after Cervical Contusion |
| Q29013578 | Promotion of Functional Nerve Regeneration by Inhibition of Microtubule Detyrosination |
| Q90216562 | Quantitative proteomics reveal the alterations in the spinal cord after myocardial ischemia‑reperfusion injury in rats |
| Q38901426 | Recombinant Nogo-66 via soluble expression with SUMO fusion in Escherichia coli inhibits neurite outgrowth in vitro |
| Q54969437 | Reducing Pericyte-Derived Scarring Promotes Recovery after Spinal Cord Injury. |
| Q26746785 | Regulation of Microtubule Dynamics in Axon Regeneration: Insights from C. elegans |
| Q90127299 | Regulation of autophagy by inhibitory CSPG interactions with receptor PTPσ and its impact on plasticity and regeneration after spinal cord injury |
| Q87315588 | Repair, protection and regeneration of spinal cord injury |
| Q41405823 | Restoration of Visual Function by Enhancing Conduction in Regenerated Axons |
| Q38277318 | Restoring function after spinal cord injury: towards clinical translation of experimental strategies |
| Q48246322 | Retrograde Activation of the Extrinsic Apoptotic Pathway in Spinal-Projecting Neurons after a Complete Spinal Cord Injury in Lampreys |
| Q34174996 | Robust CNS regeneration after complete spinal cord transection using aligned poly-L-lactic acid microfibers |
| Q52581900 | Role of Caspase-8 and Fas in Cell Death After Spinal Cord Injury. |
| Q26999096 | Role of the lesion scar in the response to damage and repair of the central nervous system |
| Q42144822 | STAT3 inhibition reduces toxicity of oncolytic VSV and provides a potentially synergistic combination therapy for hepatocellular carcinoma |
| Q38222632 | Scar-modulating treatments for central nervous system injury |
| Q36934092 | Secretory leukocyte protease inhibitor reverses inhibition by CNS myelin, promotes regeneration in the optic nerve, and suppresses expression of the transforming growth factor-β signaling protein Smad2. |
| Q39608368 | Serum response factor mediated gene activity in physiological and pathological processes of neuronal motility |
| Q36539447 | Signaling Over Distances |
| Q38204164 | Signaling regulations of neuronal regenerative ability |
| Q48320117 | Single-cell axotomy of cultured hippocampal neurons integrated in neuronal circuits. |
| Q38121716 | Spatial and temporal dynamics of neurite regrowth |
| Q36476708 | Spatial and temporal sensing limits of microtubule polarization in neuronal growth cones by intracellular gradients and forces |
| Q83493214 | Spinal cord injury: A regenerative medicine |
| Q38098567 | Spinal cord regeneration: where fish, frogs and salamanders lead the way, can we follow? |
| Q46928392 | Spinal duraplasty with two novel substitutes restored locomotor function after acute laceration spinal cord injury in rats |
| Q38737712 | Stability properties of neuronal microtubules |
| Q37980378 | Stimulating axonal regeneration of mature retinal ganglion cells and overcoming inhibitory signaling |
| Q39864495 | Sustained axon regeneration induced by co-deletion of PTEN and SOCS3 |
| Q41429757 | Targeting 14-3-3 adaptor protein-protein interactions to stimulate central nervous system repair. |
| Q36140051 | Targeting mTOR as a novel therapeutic strategy for traumatic CNS injuries. |
| Q53323988 | Taxol alleviates collagen-induced arthritis in mice by inhibiting the formation of microvessels. |
| Q27022343 | The DLK signalling pathway--a double-edged sword in neural development and regeneration |
| Q47133908 | The Regulatory Effects of Transforming Growth Factor-β on Nerve Regeneration |
| Q26796245 | The axonal cytoskeleton: from organization to function |
| Q39734891 | The biocompatibility manifesto: biocompatibility for the twenty-first century |
| Q30596882 | The effect of fluorescent nanodiamonds on neuronal survival and morphogenesis |
| Q34605908 | The microtubule minus-end-binding protein patronin/PTRN-1 is required for axon regeneration in C. elegans |
| Q57040182 | The molecular interplay between axon degeneration and regeneration |
| Q37571925 | The natural product 4,10-aromadendranediol induces neuritogenesis in neuronal cells in vitro through activation of the ERK pathway |
| Q47594962 | The neuronal and actin commitment: Why do neurons need rings? |
| Q36173863 | The preparation of rat's acellular spinal cord scaffold and co-culture with rat's spinal cord neuron in vitro |
| Q91287072 | The translational landscape in spinal cord injury: focus on neuroplasticity and regeneration |
| Q35046945 | Thermomineral water promotes axonal sprouting but does not reduce glial scar formation in a mouse model of spinal cord injury |
| Q50010676 | Timing of neuronal plasticity in development and aging |
| Q37294628 | Transcriptional insights on the regenerative mechanics of axotomized neurons in vitro |
| Q64061191 | Traumatic Spinal Cord Injury: An Overview of Pathophysiology, Models and Acute Injury Mechanisms |
| Q35840153 | Unraveling the mechanisms of synapse formation and axon regeneration: the awesome power of C. elegans genetics |
| Q37437333 | Uterine fibroids and current clinical challenges |
| Q30539852 | Xenopus cytoplasmic linker-associated protein 1 (XCLASP1) promotes axon elongation and advance of pioneer microtubules |
| Q37739993 | Zonisamide-loaded triblock copolymer nanomicelles as a novel drug delivery system for the treatment of acute spinal cord injury |
| Q35238411 | cGMP inhibits TGF-beta signaling by sequestering Smad3 with cytosolic beta2-tubulin in pulmonary artery smooth muscle cells |
| Q47103765 | let-7 miRNA controls CED-7 homotypic adhesion and EFF-1-mediated axonal self-fusion to restore touch sensation following injury. |
| Q35851553 | mRNAs and Protein Synthetic Machinery Localize into Regenerating Spinal Cord Axons When They Are Provided a Substrate That Supports Growth |
| Q37162763 | miR-155 Deletion in Mice Overcomes Neuron-Intrinsic and Neuron-Extrinsic Barriers to Spinal Cord Repair. |
| Q27863428 | p53 Regulates the neuronal intrinsic and extrinsic responses affecting the recovery of motor function following spinal cord injury. |
| Q51745472 | α-Tubulin Acetyltransferase Is a Novel Target Mediating Neurite Growth Inhibitory Effects of Chondroitin Sulfate Proteoglycans and Myelin-Associated Glycoprotein. |
| Q91596218 | βPix-d promotes tubulin acetylation and neurite outgrowth through a PAK/Stathmin1 signaling pathway |