Title The role of ATP13A2/PARK9 protein in the lysosomal degradation pathway in neurodegeneration Title (croatian) Uloga proteina ATP13A2/PARK9 u lizosomskom putu razgradnje u neurodegeneraciji Author Marija Usenović305793250 Mentor Dimitri Krainc (mentor)Committee member Janoš Terzić (predsjednik povjerenstva)Committee member Siniša Volarević (član povjerenstva)Committee member Zoran Đogaš (član povjerenstva)Granter University of Split Defense date and country 2012, Croatia Scientific / art field, BIOMEDICINE AND HEALTHCARE Universal decimal classificationUDC ) 616 - Pathology. Clinical medicine Abstract Lysosomes are essential for maintaining neuronal homeostasis through degradation of damaged organelles and misfolded and accumulated proteins. Increasing evidence implicates lysosomal dysfunction in several neurodegenerative disorders, including Parkinson, Alzheimer and Huntington disease. In addition, more than two-thirds of lysosomal storage diseases are exhibiting dysfunction in the central nervous system, emphasizing how neurons are particularly vulnerable to lysosomal impairment. In order to more directly examine the lysosomal function in neurodegeneration it is particularly informative to study neurodegenerative diseases that are caused by mutations in lysosomal proteins. One such disease is Kufor-Rakeb syndrome that is caused by loss-of-function mutations in the lysosomal protein ATP13A2/PARK9 and characterized by early-onset parkinsonism with pyramidal degeneration and dementia. While previous data implicate ATP13A2 in α-synuclein misfolding and toxicity (a protein involved in pathogenesis of Parkinson disease and related synucleinopathies), the underlying mechanism and biological function of ATP13A2 have not been established. We found that loss of ATP13A2 function leads to accumulation of enlarged lysosomes, impaired lysosomal turnover of autophagic vesicles and impaired lysosomal degradation capacity. This lysosomal dysfunction results in preferential accumulation of α-synuclein and toxicity in neurons. Importantly, depletion of endogenous α-synuclein attenuated the toxicity in ATP13A2-deficient neurons, suggesting that loss of ATP13A2 mediates neurotoxicity at least partially via lysosomal dysfunction and consequent accumulation of α-synuclein. In addition, silencing of ATP13A2 in the Caenorhabditis elegans model of Parkinson disease has enhanced α-synuclein mediated degeneration of dopaminergic neurons, further underscoring the functional link between ATP13A2 and α-synuclein in neurodegeneration. Furthermore, in order to elucidate a normal biological function of ATP13A2 protein we identified its interacting partners that revealed putative role for ATP13A2 in vesicular trafficking and fusion. Importantly, a subset of these interactors was modifiers of α-synuclein aggregation and neurotoxicity in Caenorhabditis elegans, further supporting a functional link between ATP13A2 and α-synuclein.
Our findings implicate lysosomal dysfunction and α-synuclein accumulation in the pathogenesis of Kufor-Rakeb syndrome and suggest that upregulation of lysosomal function and downregulation of α-synuclein represent promising therapeutic strategies for this disorder.
Abstract (croatian) Lizosomi su važni za održavanje neuronske homeostaze kroz razgradnju oštećenih organela i nakupljenih proteina. Brojni dokazi ukazuju na postojanje lizosomske disfunkcije u nekoliko neurodegenerativnih bolesti, uključujući Parkinsonovu, Alzheimerovu i Huntingtonovu bolest. Nadalje, više od dvije-trećine lizosomskih bolesti odlaganja okarakterizirane su poremećajima središnjeg živčanog sustava, što pokazuje da su neuroni posebno osjetljivi na lizosomske nepravilnosti. Kako bi smo što detaljnije ispitali lizosomsku funkciju u neurodegeneraciji vrlo je značajno istražiti neurodegenerativne bolesti uzrokovane mutacijama u lizosomskim proteinima. Jedna od tih bolesti je i Kufor-Rakeb sindrom koji je uzrokovan mutacijama u lizosomskom proteinu ATP13A2/PARK9 i okarakteriziran kao juvenilni parkinsonizam s piramidalnom degeneracijom i demencijom. Prijašnja otkrića sugeriraju da ATP13A2 ima važnu ulogu u nepravilnom smatanju i toksičnosti α-sinukleina (proteina uključenog u Parkinsonovu bolest i slične sinukleinopatije), no biološka funkcija proteina ATP13A2 kao ni mehanizam povezanosti proteina ATP13A2 i α-sinukleina još nisu poznati. Našim istraživanjem otkrili smo da gubitak funkcije ATP13A2 dovodi do nakupljanja povećanih lizosoma, poremećene lizosomske razgradnje proteina i autofagosoma. Ova lizosomska disfunkcija rezultira nakupljanje α-sinukleina i smrću neurona. Ujedno, utišavanje endogenog α-sinukleina smanjilo je toksičnost u neuronima s utišanim ATP13A2 genom, što sugerira da je neurotoksičnost uzrokovana gubitkom ATP13A2 jednim dijelom posredovana disfunkcijom lizosoma i akumulacijom α-sinukleina. Osim toga, utišavanje ATP13A2 u Caenorhabditis elegans modelu za Parkinsonovu bolest pojačalo je α-sinuklein-posredovanu degeneraciju dopaminskih neurona, što dodatno upućuje na funkcionalnu povezanost između ATP13A2 i α-sinukleina u procesu nerodegeneracije. Nadalje, kako bismo rasvijetlili znanje o normalnoj biološkoj funkciji ATP13A2 proteina, identificirali smo njegove inter-reagirajuće partnere koji su pokazali da ATP13A2 igra ulogu u procesima prijenosa i stapanja vezikula. Značajno je spomenuti i da su pojedini interaktori povećali nakupljanje i neurotoksičnost α-sinukleina u Caenorhabditis elegans, što je pružilo daljne dokaze o funkcionalnoj povezanosti ATP13A2 i α-sinukleina.
Naša otkrića impliciraju lizosomsku disfunkciju i nakupljanje α-sinukleina kao važne elemente u patogenezi Kufor-Rakeb sindroma te ukazuju na to da pojačavanje funkcije lizosoma i smanjivanje razine α-sinukleina predstavljaju obećavajuće terapijske strategije za ovu bolest.
Keywords
Autophagy
Lysosomes
Nerve Degeneration
Adenosine Triphosphate
Keywords (croatian)
Autofagija
Lizosomi
Degeneracija živaca
Adenozin trifosfat
Language english URN:NBN urn:nbn:hr:171:031687 Study programme Title: Biology of Neoplasms Type of resource Text File origin Born digital Access conditions Open access Terms of use Created on 2023-06-06 08:10:25
