FB2026_02 , released June 18, 2026
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Pech, U., Janssens, J., Schoovaerts, N., Kuenen, S., Calatayud Aristoy, C., Gallego, S.F., Makhzami, S., Hulselmans, G.J., Poovathingal, S., Davie, K., Bademosi, A.T., Swerts, J., Vilain, S., Aerts, S., Verstreken, P. (2025). Synaptic deregulation of cholinergic projection neurons causes olfactory dysfunction across five fly Parkinsonism models.  eLife 13(): RP98348.
FlyBase ID
FBrf0262044
Publication Type
Research paper
Abstract
The classical diagnosis of Parkinsonism is based on motor symptoms that are the consequence of nigrostriatal pathway dysfunction and reduced dopaminergic output. However, a decade prior to the emergence of motor issues, patients frequently experience non-motor symptoms, such as a reduced sense of smell (hyposmia). The cellular and molecular bases for these early defects remain enigmatic. To explore this, we developed a new collection of five fruit fly models of familial Parkinsonism and conducted single-cell RNA sequencing on young brains of these models. Interestingly, cholinergic projection neurons are the most vulnerable cells, and genes associated with presynaptic function are the most deregulated. Additional single nucleus sequencing of three specific brain regions of Parkinson's disease patients confirms these findings. Indeed, the disturbances lead to early synaptic dysfunction, notably affecting cholinergic olfactory projection neurons crucial for olfactory function in flies. Correcting these defects specifically in olfactory cholinergic interneurons in flies or inducing cholinergic signaling in Parkinson mutant human induced dopaminergic neurons in vitro using nicotine, both rescue age-dependent dopaminergic neuron decline. Hence, our research uncovers that one of the earliest indicators of disease in five different models of familial Parkinsonism is synaptic dysfunction in higher-order cholinergic projection neurons and this contributes to the development of hyposmia. Furthermore, the shared pathways of synaptic failure in these cholinergic neurons ultimately contribute to dopaminergic dysfunction later in life.
PubMed ID
PubMed Central ID
PMC11968104 (PMC) (EuropePMC)
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    Language of Publication
    English
    Additional Languages of Abstract
    Parent Publication
    Publication Type
    Journal
    Abbreviation
    eLife
    Title
    eLife
    ISBN/ISSN
    2050-084X
    Data From Reference
    Alleles (35)
    Chemicals (2)
    Genes (10)
    Human Disease Models (5)
    Insertions (18)
    Experimental Tools (1)
    Transgenic Constructs (10)