Suchergebnisse

The predominant motor neuron disease in infants and adults is spinal muscular atrophy (SMA) and amyotrophic lateral sclerosis (ALS), respectively. SMA is caused by insufficient levels of the Survival Motor Neuron (SMN) protein, which operates as part of the multiprotein SMN complex that includes the DEAD-box RNA helicase Gemin3/DDX20/DP103. C9orf72, SOD1, TDP-43 and FUS are ranked as the four major genes causing familial ALS. Accumulating evidence has revealed a surprising molecular overlap between SMA and ALS. Here, we ask the question of whether Drosophila can also be exploited to study shared pathogenic pathways. Focusing on motor behaviour, muscle mass and survival, we show that disruption of either TBPH/TDP-43 or Caz/FUS enhance defects associated with Gemin3 loss-of-function. Gemin3-associated neuromuscular junction overgrowth was however suppressed. Sod1 depletion had a modifying effect in late adulthood. We also show that Gemin3 self-interacts and Gem3ΔN, a helicase domain deletion mutant, retains the ability to interact with its wild-type counterpart. Importantly, mutant:wild-type dimers are favoured more than wild-type:wild-type dimers. In addition to reinforcing the link between SMA and ALS, further exploration of mechanistic overlaps is now possible in a genetically tractable model organism. Notably, Gemin3 can be elevated to a candidate for modifying motor neuron degeneration. ; This work was supported by the University of Malta Research Fund to RJC, and the Malta Council for Science & Technology Internationalisation Partnership Award to RJC. RC was supported by the Erasmus+ programme of the EU. ML was supported by an Endeavour Scholarship (Malta), part-financed by the EU – European Social Fund under Operational Programme II – Cohesion Policy 2014–2020, "Investing in human capital to create more opportunities and promote the well-being of society". RMB was supported by a Bjorn Formosa Scholarship for Advanced Research into ALS/MND funded by the non-profit organisation, ALS Malta Foundation, facilitated by the Research Trust (RIDT) of the University of Malta. ; peer-reviewed

Alzheimer's disease is a devastating neurodegenerative disease eventually leading to dementia. An effective treatment does not yet exist. Here we show that oral application of the compound anle138b restores hippocampal synaptic and transcriptional plasticity as well as spatial memory in a mouse model for Alzheimer's disease, when given orally before or after the onset of pathology. At the mechanistic level, we provide evidence that anle138b blocks the activity of conducting Ab pores without changing the membrane embedded A beta-oligomer structure. In conclusion, our data suggest that anle138b is a novel and promising compound to treat AD-related pathology that should be investigated further. ; DZNE; Max Planck Society; Hans and Ilse Breuer Award for Alzheimer's disease; DFG [FI981/9-1, SFB803]; EU (ERC); Hans and Ilse Breuer Foundation; CoEN Initiative [CoEN3018]; Malta Council for Science & Technology through the National Research & Innovation Programme [RI-2008-068]; University of Malta [PHBR06]; Malta Government Scholarship Scheme; National Institute on Aging of National Institutes of Health [AG028709]; [SFB1089 C01] ; Open access journal. ; This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.