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dc.contributor.advisorRobert H. Brown, Jr., MD, DPhil
dc.contributor.authorHenninger, Nils
dc.date2022-08-11T08:08:46.000
dc.date.accessioned2022-08-23T16:07:36Z
dc.date.available2022-08-23T16:07:36Z
dc.date.issued2017-05-24
dc.date.submitted2017-06-07
dc.identifier.doi10.13028/M29S30
dc.identifier.urihttp://hdl.handle.net/20.500.14038/32280
dc.description.abstractTraumatic 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.
dc.language.isoen_US
dc.publisherUniversity of Massachusetts Medical School
dc.rightsLicensed under a Creative Commons license
dc.rights.urihttp://creativecommons.org/licenses/by-nc/4.0/
dc.subjectArmadillo domain proteins
dc.subjectanimal model
dc.subjectaxon
dc.subjectaxon
dc.subjectaxon degeneration
dc.subjectbehavior
dc.subjectbeta amyloid precursor protein
dc.subjectbrain Injuries
dc.subjectcerebral blood flow
dc.subjectcorpus callosum
dc.subjectcytoskeletal proteins
dc.subjectcytoskeleton
dc.subjectfunctional outcome
dc.subjecthistology
dc.subjectinbred C57BL
dc.subjectknockout
dc.subjectlaser Doppler
dc.subjectmagnetic resonance imaging
dc.subjectmale
dc.subjectmetabolism
dc.subjectmouse
dc.subjectneurofilament
dc.subjectneurosciences
dc.subjectpathology
dc.subjectproton magnetic resonance spectroscopy
dc.subjectrecovery of function
dc.subjectspreading depolarization
dc.subjectspreading depression
dc.subjecttranslational research
dc.subjecttraumatic axonal injury
dc.subjecttraumatic brain injury
dc.subjectWallerian degeneration
dc.subjectwhite matter
dc.subjectCritical Care
dc.subjectEmergency Medicine
dc.subjectMedical Cell Biology
dc.subjectMedical Neurobiology
dc.subjectMolecular and Cellular Neuroscience
dc.subjectMusculoskeletal, Neural, and Ocular Physiology
dc.subjectNervous System Diseases
dc.subjectNeurology
dc.subjectOther Neuroscience and Neurobiology
dc.subjectSports Medicine
dc.subjectSports Sciences
dc.subjectTranslational Medical Research
dc.subjectTrauma
dc.titleInhibiting Axon Degeneration in a Mouse Model of Acute Brain Injury Through Deletion of Sarm1
dc.typeDoctoral Dissertation
dc.identifier.legacyfulltexthttps://escholarship.umassmed.edu/cgi/viewcontent.cgi?article=1904&context=gsbs_diss&unstamped=1
dc.identifier.legacycoverpagehttps://escholarship.umassmed.edu/gsbs_diss/900
dc.legacy.embargo2018-06-07T00:00:00-07:00
dc.identifier.contextkey10265751
refterms.dateFOA2022-08-27T04:55:05Z
html.description.abstract<p>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.</p> <p>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.</p> <p>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.</p> <p>Remarkably, mice mutant for the Wallerian degeneration slow (Wld<sup>s</sup>) protein exhibit ~tenfold (for 2–3 weeks) suppressed Wallerian degeneration. Yet, pharmacological replication of the Wld<sup>s</sup> mechanism has proven difficult. Further, no one has studied whether Wld<sup>s</sup> protects from TAI. Lastly, owing to Wld<sup>s</sup> 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.</p> <p>Novel insight into the pathophysiology of Wallerian degeneration was gained by the discovery that mutant <em>Drosophila</em> flies lacking <em>dSarm</em> (sterile a/Armadillo/Toll-Interleukin receptor homology domain protein) cell-autonomously recapitulated the Wld<sup>s</sup> phenotype. The pro-degenerative function of the <em>dSarm</em> gene (and its mouse homolog <em>Sarm1</em>) is widespread in mammals as shown by <em>in vitro</em> 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 <em>Sarm1</em> null axons. Although the molecular mechanism of function remains to be clarified, its discovery provides direct evidence that <em>Sarm1</em> is the first endogenous gene required for Wallerian degeneration, driving a highly conserved genetic axon death program.</p> <p>The central goals of this thesis were to determine (1) whether post-traumatic axonal integrity is preserved in mice lacking <em>Sarm1,</em> and (2) whether loss of <em>Sarm1 </em>is associated with improved functional outcome after TBI. I show that mice lacking the mouse Toll receptor adaptor <em>Sarm1</em> gene demonstrate multiple improved TBI-associated phenotypes after injury in a closed-head mild TBI model. <em>Sarm1<sup>-/-</sup></em> mice developed fewer beta amyloid precursor protein (βAPP) aggregates in axons of the corpus callosum after TBI as compared to <em>Sarm1<sup>+/+</sup></em> mice. Furthermore, mice lacking <em>Sarm1</em> 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 <em>Sarm1</em><sup>-/-</sup> animals. Finally, using <em>in vivo</em> proton magnetic resonance spectroscopy, I found tissue signatures consistent with substantially preserved neuronal energy metabolism in <em>Sarm1</em><sup>-/-</sup> mice compared to controls immediately following TBI. My results indicate that the <em>Sarm1</em>-mediated prodegenerative pathway promotes pathogenesis in TBI and suggest that anti-<em>Sarm1</em> therapeutics are a viable approach for preserving neurological function after TBI.</p>
dc.identifier.submissionpathgsbs_diss/900
dc.contributor.departmentDepartment of Neurology
dc.description.thesisprogramMillennium PhD
dc.identifier.orcid0000-0002-3883-5623


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