Axon Death Pathways Converge on Axed to Promote Axon Disassembly

Burdett, Thomas C.

31 March 2017

Axons use a conserved program to actively drive their own destruction after injury. Axon degeneration is present in many neurological disorders and an axon death program could be a major pharmaceutical target to preserve neuronal function. This intrinsic signaling cascade activates pro-degenerative dSarm/Sarm1, rapidly depletes axonal stores of NAD+, and terminates in cytoskeletal breakdown. Conversely, loss of dSarm/Sarm1, maintenance of NAD+ levels or its biosynthetic enzyme Nmnat, result in long-term morphological perseveration of severed axons. Exactly how dSarm/Sarm1 and loss of NAD+ execute axon death remains poorly defined. We sought to uncover novel regulators of axon death and maintenance by performing a deficiency screen and a forward genetic mutagenesis screen in axotomized Drosophila wing sensory neurons. We identified a BTB domain protein enriched in neurons, we named Axundead (Axed), which is specifically required for axon death. Severed axons harboring loss of function mutations in axed, similar to dSarm mutants, remain preserved for 50 days post axotomy. Spontaneous neurodegeneration induced by activated dSarm or dNmnat depletion are both suppressed in axed mutants, but not in dSarm mutant alleles. Additionally, severed axed mutant axons also expressing activated dSarm or lacking Nmnat are preserved. These results indicate that dSarm acts upstream of dNmnat loss, and both events precede essential Axed function and axon destruction. Thus, the axon death pathway converges on Axed function.

Axon Degeneration

Molecular and Cellular Neuroscience

The Transcription Factor Pebbled/RREB1 Regulates Injury-Induced Axon Degeneration

Farley, Jonathan E.

11 December 2017

Neurons establish complex networks within the nervous system allowing for rapid cell-cell communication via their long, thin axonal processes. These wire-thin projections are susceptible to a number of insults or injuries, and axonal damage can lead to disruption in signal propagation and an overall dysfunction of the neural network. Recent research focused on investigating the underlying mechanisms of injury-induced axon degeneration led to the discovery of a number of endogenous, pro-degenerative molecules such as dSarm/Sarm1, Highwire/Phr1, and Axundead. These signaling molecules are thought to execute axon degeneration in response to injury locally within the distal severed axon, but the exact mechanism of action is unclear. To further identify novel participants of the axon death signaling cascade, we performed an unbiased forward genetic mutagenesis screen using the sensory neurons within the adult wing of Drosophila melanogaster. We identified a novel role for the C2H2 zinc finger transcription factor, Pebbled (Peb)/Ras-responsive element binding protein 1 (RREB1) in partially suppressing injury-induced axon degeneration. Loss of function peb mutant glutamatergic neurons present two distinct axon degeneration defects: either complete protection from axotomy, or they exhibit a novel phenotype in which axons fragment into long, continuous pieces instead of undergoing complete degeneration. Additionally, we show an enhancement of the peb protective phenotype when dSarm levels are decreased, but not with reduced levels of axundead. These data provide the first evidence of a transcription factor involved in regulating injury-induced axon degeneration signaling in vivo.

axons

axon death

axon degeneration

Wallerian degeneration

Molecular and Cellular Neuroscience

Quantitative Imaging of Net Axonal Transport in vivo: A Biomarker for Motor Neuron Health and Disease

Lee, Pin-Tsun Justin

21 December 2021

Amyotrophic lateral sclerosis (ALS) is a lethal, progressive neurodegenerative disorder that selectively affects both upper and lower motor neurons, leading to muscle weakness, paralysis and death. Despite recent advances in the identification of genes associated with ALS, the quest for a sensitive biomarker for rapid and accurate diagnosis, prognosis, and treatment response monitoring has not been fulfilled. In this thesis, I report a method of quantifying the integrity of motor neurons in vivo using imaging to record uptake and retrograde transport of intramuscularly injected tetanus toxin fragment C (TTC) into spinal motor neurons. This method tracks and profiles progression of disease (transgenic SOD1G93A and PFN1 ALS mice) and detects subclinical perturbations in net transport, as analyzed in C9orf72 transgenic mice. It also defines a progressive reduction in net transport with aging. To address whether our technique enables drug development, I evaluated therapeutic benefits of (1) gene editing and (2) mutant gene silencing (with RNAi targeting SOD1) in SOD1G93A transgenic mice by characterizing their net axonal transport profiles. I constructed a computational model to evaluate key molecular processes affected in net axonal transport in ALS mouse model. The model allows prediction of key parameters affected in a C9ORF72 BAC transgenic mouse line. Prior immunization with tetanus toxoid does not preclude use of this assay, and it can be used repetitively in the same subject. This assay of net axonal transport offers broad clinical application as a diagnostic tool for motor neuron diseases and as a biomarker for rapid detection of benefit from therapies for transport dysfunction in a range of motor neuron diseases.

Amyotrophic lateral sclerosis

axon degeneration

axon transport

neuromuscular disease imaging

biomarker

Diagnosis

Disease Modeling

Nervous System Diseases

Other Neuroscience and Neurobiology

ACID-SENSING ION CHANNELS: TARGETS FOR NEUROPEPTIDE MODULATION AND NEURONAL DAMAGE

Frey, Erin N.

23 July 2013

No description available.

Biomedical Research

Neurosciences

acid sensing ion channels

acidosis

ischemia

dynorphin

opioid peptides

RFamides

ASICs

Inhibiting Axon Degeneration in a Mouse Model of Acute Brain Injury Through Deletion of Sarm1

Henninger, Nils

24 May 2017

Traumatic brain injury (TBI) is a leading cause of disability worldwide. Annually, 150 to 200/1,000,000 people become disabled as a result of brain trauma. Axonal degeneration is a critical, early event following TBI of all severities but whether axon degeneration is a driver of TBI remains unclear. Molecular pathways underlying the pathology of TBI have not been defined and there is no efficacious treatment for TBI. Despite this significant societal impact, surprisingly little is known about the molecular mechanisms that actively drive axon degeneration in any context and particularly following TBI. Although severe brain injury may cause immediate disruption of axons (primary axotomy), it is now recognized that the most frequent form of traumatic axonal injury (TAI) is mediated by a cascade of events that ultimately result in secondary axonal disconnection (secondary axotomy) within hours to days. Proposed mechanisms include immediate post-traumatic cytoskeletal destabilization as a direct result of mechanical breakage of microtubules, as well as catastrophic local calcium dysregulation resulting in microtubule depolymerization, impaired axonal transport, unmitigated accumulation of cargoes, local axonal swelling, and finally disconnection. The portion of the axon that is distal to the axotomy site remains initially morphologically intact. However, it undergoes sudden rapid fragmentation along its full distal length ~72 h after the original axotomy, a process termed Wallerian degeneration. Remarkably, mice mutant for the Wallerian degeneration slow (Wlds) protein exhibit ~tenfold (for 2–3 weeks) suppressed Wallerian degeneration. Yet, pharmacological replication of the Wlds mechanism has proven difficult. Further, no one has studied whether Wlds protects from TAI. Lastly, owing to Wlds presumed gain-of-function and its absence in wild-type animals, direct evidence in support of a putative endogenous axon death signaling pathway is lacking, which is critical to identify original treatment targets and the development of viable therapeutic approaches. Novel insight into the pathophysiology of Wallerian degeneration was gained by the discovery that mutant Drosophila flies lacking dSarm (sterile a/Armadillo/Toll-Interleukin receptor homology domain protein) cell-autonomously recapitulated the Wlds phenotype. The pro-degenerative function of the dSarm gene (and its mouse homolog Sarm1) is widespread in mammals as shown by in vitro protection of superior cervical ganglion, dorsal root ganglion, and cortical neuron axons, as well as remarkable in-vivo long-term survival (>2 weeks) of transected sciatic mouse Sarm1 null axons. Although the molecular mechanism of function remains to be clarified, its discovery provides direct evidence that Sarm1 is the first endogenous gene required for Wallerian degeneration, driving a highly conserved genetic axon death program. The central goals of this thesis were to determine (1) whether post-traumatic axonal integrity is preserved in mice lacking Sarm1, and (2) whether loss of Sarm1 is associated with improved functional outcome after TBI. I show that mice lacking the mouse Toll receptor adaptor Sarm1 gene demonstrate multiple improved TBI-associated phenotypes after injury in a closed-head mild TBI model. Sarm1-/- mice developed fewer beta amyloid precursor protein (βAPP) aggregates in axons of the corpus callosum after TBI as compared to Sarm1+/+ mice. Furthermore, mice lacking Sarm1 had reduced plasma concentrations of the phosphorylated axonal neurofilament subunit H, indicating that axonal integrity is maintained after TBI. Strikingly, whereas wild type mice exhibited a number of behavioral deficits after TBI, I observed a strong, early preservation of neurological function in Sarm1-/- animals. Finally, using in vivo proton magnetic resonance spectroscopy, I found tissue signatures consistent with substantially preserved neuronal energy metabolism in Sarm1-/- mice compared to controls immediately following TBI. My results indicate that the Sarm1-mediated prodegenerative pathway promotes pathogenesis in TBI and suggest that anti-Sarm1 therapeutics are a viable approach for preserving neurological function after TBI.

Armadillo domain proteins

animal model

axon

axon

axon degeneration

behavior

beta amyloid precursor protein

brain Injuries

cerebral blood flow

corpus callosum

cytoskeletal proteins

cytoskeleton

functional outcome

histology

inbred C57BL

knockout

laser Doppler

magnetic resonance imaging

male

metabolism

mouse

neurofilament

neurosciences

pathology

proton magnetic resonance spectroscopy

recovery of function

spreading depolarization

spreading depression

translational research

traumatic axonal injury

traumatic brain injury

Wallerian degeneration

white matter

Critical Care

Emergency Medicine

Medical Cell Biology

Medical Neurobiology

Molecular and Cellular Neuroscience

Nervous System Diseases

Neurology

Other Neuroscience and Neurobiology

Sports Medicine

Sports Sciences

Translational Medical Research

Trauma