Table 2.
Drosophila model of Parkinson’s disease.
| DROSOPHILA MODEL | STAGE OF NEUROPATHOLOGICAL ASSESMENT | ASSAY EMPLOYED FOR NEUROPATHOLOGICAL ASSESSMENT | KEY ACHIEVEMENTS | REFERENCES | ||
|---|---|---|---|---|---|---|
| DROSOPHILA ORTHOLOGS OF HUMAN GENES | Mutants with alterations in the PINK1 gene and reduction of PINK1 expression specifically in dopamine neurons | Adult | Measurement of lifespan, immunostaining for tyrosine hydroxylase (TH), chemotaxis assay, dopamine enzyme immunoassay, high-performance liquid chromatography (HPLC) for dopamine tissue and dopamine levels | Showed the link between PINK1 mutations and dopamine neuron degeneration, mimicking Parkinson’s disease pathology | [100], [101] | |
| Mutants with alterations in the parkin gene | Adult | Immunostaining for TH and conducting a climbing assay | Established the effects of parkin gene alterations on dopaminergic neuron health and motor function, aiding in Parkinson’s disease studies | [102] | ||
| LRRK2 mutants | Adult | Assessment of climbing ability and immunostaining for TH | Explored the impact of LRRK2 mutations on dopaminergic neuron function and motor deficits relevant to Parkinson’s disease | [103] | ||
| Reduction of HtrA2 expression specifically in dopamine neurons and photoreceptor cells | Adult | Assessment of lifespan, climbing ability, and scanning electron microscopy (SEM) for eye morphology | Highlighted HtrA2’s role in maintaining dopaminergic and photoreceptor cell health, contributing to insights on neurodegenerative diseases | [104] | ||
| Mutations in both CG31414 and CG31148 genes, known as double heterozygous GBA mutants | Adult | Measurement of lifespan, immunostaining for TH, and climbing assay. | Demonstrated the effects of GBA mutations on lifespan and dopaminergic function, linking to Parkinson’s disease | [105] | ||
| Mutations in the DJ-1 gene subjected to exposure to rotenone, hydrogen peroxide, and paraquat | Adult | Measurement of lifespan and immunostaining for TH | Established the role of DJ-1 in oxidative stress responses and dopaminergic neuron survival, aiding in Parkinson’s disease research | [106] | ||
| Overexpression of dUCH specifically in photoreceptor cells and knockdown of dUCH specifically in dopamine neurons | Larva, Pupa, Adult | SEM for examining eye morphology, immunostaining for activated-Caspase 3 and TH | Examined the effects of dUCH expression alterations on neurodegeneration in dopaminergic and photoreceptor cells | [107] | ||
| OVEREXPRESSION OF HUMAN TRANSGENES | Simultaneous expression of Tau and Alpha-Synuclein (α-syn) | Larva, Adult | Immunostaining for activated-caspase 3, NMJ morphology, immunostaining for TH, SEM for adult eye morphology | Showed the synergistic effects of Tau and α-syn on neurodegeneration, providing a model for studying combined pathologies | [108] | |
| Expression of LRRK2 and LRRK2-G2019S-2 in pan-neuronal cells, photoreceptor cells and dopamine neurons | Adult | Lifespan measurement, climbing assay, photoreceptor morphology, TEM, immunostaining for TH, actometer test | Identified the role of LRRK2 mutations in dopaminergic neurodegeneration, aiding in understanding Parkinson’s disease | [109] | ||
| Increased expression of Pael-R specifically in dopamine neurons | Adult | Immunostaining for TH | Established the link between Pael-R overexpression and dopaminergic neuron degeneration, providing a model for Parkinson’s disease | [109] | ||
| EXPOSURE TO TOXINS | Rotenone | Adult | Immunostaining for TH, climbing assay | Demonstrated the role of environmental toxins like Rotenone in Parkinson’s disease pathogenesis | [110] | |
| Paraquat | Adult | Immunostaining for TH, climbing assay, lifespan, jumping assay, dopamine levels | Confirmed the role of oxidative stress in Parkinson’s disease, showing how Paraquat induces dopaminergic neuron degeneration | [111]; [112] | ||