Poster Session 3.J - Theoretical and Translational Medicine
Zsoldos, Roland
HCEMM-SU Neurobiology and Neurodegenerative Diseases Research Group, Institute of Clinical Pathophysiology Semmelweis University
Roland Zsoldos1, Kinga Vörös1, Zsófia Koltai1, Chandramouli Muralidharan2, Anikó Göblös3, Idris J. Jimoh4, Bence Király5, Anna Anoir Abbas1, Balázs Kis1, Ágnes Varga1, Csaba Kerepesi5, Johan Jakobsson2, Mária Judit Molnár4, Lajos Kemény3, Karolina Pircs1
1: HCEMM-SU Neurobiology and Neurodegenerative Diseases Research Group, Institute of Clinical Pathophysiology Semmelweis University
2: Laboratory of Molecular Neurogenetics, Lund University, Lund, Sweden
3: HCEMM-Szeged University, Szeged, Hungary
4: Institute of Genomic Medicine and Rare Disorders, Faculty of Medicine, Semmelweis University, Budapest, Hungary,
5: HUN-REN-SZTAKI-SU Rejuvenation Research Group, Budapest, Hungary
Age is the greatest risk factor for neurodegenerative diseases (NDDs), yet the
molecular links between physiological aging and NDD pathogenesis remain poorly
understood. Autophagy- a lysosomal degradation pathway essential for maintaining cytoplasmic homeostasis- declines with age and contributes to neuronal dysfunction.
To investigate aging alters autophagic flux in human neurons, we utilized direct
reprogramming of human dermal fibroblasts, generating induced neurons (iNs), a method that retains donor-specific genetic and epigenetic signatures. We generated iNs from a cohort of 54 healthy donors ranging in age from 24 to 86 years. Neuronal identity was verified by immunocytochemistry and high-content automated microscopy using neuronal (TAU) and autophagy-specific markers (BECLIN1, LC3, P62, LAMP1) under both basal and stress-induced conditions. Our results indicate donor specific alterations in autophagy. We identified distinct clusters of stress-induced autophagic flux in the case of both young and old donor groups. These variations were observed in autophagosome formation, turnover, as well as in the lysosomal degradation step. These findings suggest different trajectories of age-related decline in neuronal homeostasis, which may contribute to increased vulnerability to age-related neurodegeneration. Currently, we are validating these findings across the full
donor cohort. In parallel, we are conducting multi-omic autophagy profiling using a
range of molecular assays including genome-wide DNA methylation arrays, bulk RNA- sequencing, mass spectrometry, and metabolomics to compare young and old iNs.
Our long-term goal is to identify key regulators of autophagy and explore
rejuvenation strategies. This approach could inform future therapies for NDDs, where impaired autophagy and accelerated aging are often observed.
This work was also supported by the SE 250+ PhD Excellence Grant, SE250-2026-04 by Semmelweis University.