Sangam: A Confluence of Knowledge Streams

Investigating the disruption of transcriptional homeostatic networks in driving motor neuron specific degeneration in Amyotrophic Lateral Sclerosis

Show simple item record

dc.contributor Bhinge, Akshay
dc.contributor Mill, Jon
dc.contributor Dempster, Emma
dc.creator Moran, J
dc.date 2022-10-05T14:50:53Z
dc.date 2022-10-03
dc.date 2022-10-05T14:30:03Z
dc.date 2022-10-05T14:50:53Z
dc.date.accessioned 2023-02-23T12:17:01Z
dc.date.available 2023-02-23T12:17:01Z
dc.identifier http://hdl.handle.net/10871/131108
dc.identifier.uri http://localhost:8080/xmlui/handle/CUHPOERS/258652
dc.description Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease caused by the progressive loss of upper and lower motor neurons, eventually culminating in patient paralysis and death via asphyxiation. At the time of diagnosis, approximately 50% of patient motor neurons are predicted to have degenerated, resulting in a prognosis of 3-5 years. While most incidences of ALS are sporadic (~90%) with no obvious genetic constituent, approximately 10% of cases are inherited in a dominant manner and are referred to as familial ALS. At the present time there is no cure for ALS and current pharmacological treatments, such as Riluzole, operate with limited efficacy. As such, gaining further insight into pathomechanisms driving ALS is paramount for the development of novel and effective therapeutics. The C9ORF72 hexanucleotide repeat expansion is attributed to 40-50% of familial and approximately 10% of sporadic ALS cases. Investigating pathomechanisms driving familial cases of C9-ALS could elucidate neurodegenerative mechanisms central to both familial and sporadic cases. The aim of this thesis was to investigate transcriptional perturbations in C9-ALS to elucidate de novo candidates rendering motor neurons particularly susceptible to pathology. Evidence from previous studies suggested that nociceptors of ALS patients remain functionally viable due to the presence of non-neuropathic pain in approximately 80% of patients. We subsequently developed a novel protocol to efficiently generate functional sensory neuron cultures predominantly consisting of spinal nociceptors (~75%). Utilizing our protocol, we compared the transcriptomes of C9-ALS nociceptors with C9-ALS motor neurons which elucidated dysregulation of synaptic genes in motor neurons, potentially suggesting increased susceptibility of motor neurons to excitotoxic mechanisms. Finally, we utilised CRISPR systems employing dCas9 fused to epigenetic effectors to selectively demethylate the C9ORF72 repeat expansion and proximally associated regions to investigate epigenetic contributions to pathology. We observed an increase in transcript variant 3 expression and retention of intron 1 was observed upon demethylation of the repeat expansion. While increased expression of C9ORF72 could exacerbate pathomechanisms driven by RNA foci and accumulation of DPR proteins, deficits in synaptic function could be attenuated by reducing C9ORF72 haploinsufficiency. In summary, the work presented in this thesis outlines novel approaches to investigating the mechanisms driving pathology in C9-ALS with the hope of elucidating de novo candidates for therapeutic targeting. Furthermore, the ability to generate functional nociceptors broadens the scope of pain research permitting in vitro experiments to understand the mechanics of pain in human cells.
dc.description Wellcome Trust
dc.publisher University of Exeter
dc.publisher Medical sciences
dc.rights 2024-01-31
dc.rights Sensitive RNA sequencing data and epigenetic editing methodology that myself or supervisor would not like publically available until pubklished in a peer reviewed journal. Some further refinement of methodology and validation of RNA candidates is required. Embargo 31/1/24.
dc.rights http://www.rioxx.net/licenses/all-rights-reserved
dc.subject ALS
dc.subject Amyotrophic lateral sclerosis
dc.subject Nociceptor
dc.subject Motor neuron
dc.subject Stem cell
dc.subject iPSC
dc.subject induced pluripotent stem cell
dc.subject human embryonic stem cell
dc.subject hESC
dc.subject Epigenetics
dc.subject RNA sequencing
dc.subject RNA seq
dc.subject Neuronal culture
dc.subject Calcium imaging
dc.subject CRISPR
dc.title Investigating the disruption of transcriptional homeostatic networks in driving motor neuron specific degeneration in Amyotrophic Lateral Sclerosis
dc.type Thesis or dissertation
dc.type PhD Medical Studies
dc.type Doctoral
dc.type Doctoral Thesis


Files in this item

Files Size Format View
MoranJ.pdf 24.37Mb application/pdf View/Open

This item appears in the following Collection(s)

Show simple item record

Search DSpace


Advanced Search

Browse