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Two lysosomal genes ATP13A2 and GBA1 interact to drive neurodegeneration
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Two lysosomal genes ATP13A2 and GBA1 interact to drive neurodegeneration
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Journal Article
Two lysosomal genes ATP13A2 and GBA1 interact to drive neurodegeneration
2026
Overview
Background
Parkinson’s disease (PD) is a genetically complex disorder in which combinations of heterozygous risk variants may contribute to pathogenesis. Many PD risk loci encode lysosomal genes, such as
GBA1
, a common and potent risk factor, conferring at least a 5-fold increase. However, the mechanisms of
GBA1
penetrance remain poorly understood.
Methods
Using
Drosophila melanogaster
, we performed a genetic interaction screen of lysosomal storage disorder (LSD) genes to identify dominant modifiers of
Gba1b
(fly homolog of
GBA1
). Age-dependent locomotor assessments, electroretinograms (ERG), transmission electron microscopy (TEM) analyses and quantification of dopaminergic (DA) neurons were used to assess the neurodegenerative phenotypes of double heterozygous animals. By combining immunostaining, lipidomics, metabolomics and pharmacological approaches we showed how partial loss of
anne
(fly homolog of
ATP13A2
) and
Gba1b
drives neurodegeneration. By interrogating genetic data from local and international PD cohorts we identified double heterozygous pathogenic variants in
ATP13A2
and
GBA1
in individuals with PD.
Results
We show that
anne
is expressed in neurons, whereas
Gba1b
is expressed in glia. Flies heterozygous for
anne
exhibit mild neurodegenerative phenotypes, and
Gba1b
strongly enhances this haploinsufficiency. Double heterozygous (
Gba1b
T2A
/+;anne
T2A
/+
) flies exhibit a slow and progressive neurodegeneration associated with accumulation and impaired acidification of lysosomes in photoreceptors and other neurons. Obvious morphological defects are first observed in glia at day 15 after eclosion and include vacuolization and neuronal detachment. These defects are accompanied by an elevation of glucosylceramide (GlcCer) and followed by loss of neuronal function and degenerative features by day 30. These phenotypes are neuronal activity-dependent. The neurodegenerative phenotypes are rescued by: ML-SA1, an agonist of the lysosomal TRPML1 channel that has been reported to promote lysosomal membrane trafficking; myriocin, a compound that inhibits GlcCer production; and DFMO, a drug which inhibits polyamine synthesis. Based on surveys of genetic data, we identify multiple PD cases harboring digenic variants in
GBA1
and
ATP13A2
.
Conclusions
Our study reveals that partial loss of
Gba1b
in glia and
anne
in neurons synergistically disrupts lysosomal pH and neuron-glia GlcCer homeostasis, triggering neurodegeneration. Our results provide evidence that
GBA1
penetrance is influenced by additional genetic modifiers, consistent with a putative digenic mechanism for
GBA1
-PD penetrance. These findings highlight lysosomal acidification, sphingolipid clearance, and polyamine regulation as critical intervention points in digenic PD.
