Here we describe two assays that have been established to study age-dependent neurodegeneration of dopaminergic (DA) neurons in Drosophila: the climbing/startle-induced negative geotaxis assay which allows to study the functional effects of DA neurons degeneration and the tyrosine hydroxylase immunostaining which is used to identify and count DA neurons in whole brain mounts.
Drosophila melanogaster is a valuable model organism to study aging and pathological degenerative processes in the nervous system. The advantages of the fly as an experimental system include its genetic tractability, short life span and the possibility to observe and quantitatively analyze complex behaviors. The expression of disease-linked genes in specific neuronal populations of the Drosophila brain, can be used to model human neurodegenerative diseases such as Parkinson’s and Alzheimer’s 5.
Dopaminergic (DA) neurons are among the most vulnerable neuronal populations in the aging human brain. In Parkinson’s disease (PD), the most common neurodegenerative movement disorder, the accelerated loss of DA neurons leads to a progressive and irreversible decline in locomotor function. In addition to age and exposure to environmental toxins, loss of DA neurons is exacerbated by specific mutations in the coding or promoter regions of several genes. The identification of such PD-associated alleles provides the experimental basis for the use of Drosophila as a model to study neurodegeneration of DA neurons in vivo. For example, the expression of the PD-linked human α-synuclein gene in Drosophila DA neurons recapitulates some features of the human disease, e.g. progressive loss of DA neurons and declining locomotor function 2. Accordingly, this model has been successfully used to identify potential therapeutic targets in PD 8.
Here we describe two assays that have commonly been used to study age-dependent neurodegeneration of DA neurons in Drosophila: a climbing assay based on the startle-induced negative geotaxis response and tyrosine hydroxylase immunostaining of whole adult brain mounts to monitor the number of DA neurons at different ages. In both cases, in vivo expression of UAS transgenes specifically in DA neurons can be achieved by using a tyrosine hydroxylase (TH) promoter-Gal4 driver line 3, 10.
The specificity of the assays described here relies on the use of a Gal4 fly line which exploits the regulatory sequences of the tyrosine hydroxylase gene to achieve specific expression in dopaminergic neurons 3. Tyrosine hydroxylase catalyses the first and rate-limiting step in dopamine synthesis. TH immunoreactivity in the adult fly brain overlaps with that of dopamine, making TH a good candidate to identify DA neurons in vivo (see for example 6). Moreover, the expression pattern of THGal4 is more specific than that of other Gal4 lines such as DdcGal4, which contains regulatory sequences from the dopa decarboxylase gene and drives transgenic expression not only in DA neurons, but also in serotoninergic neurons and subsets of glial cells 3.
Feany and Bender (2000) first observed that pan-neuronal expression of the PD-linked human α-synuclein gene accelerates the progressive loss of startle-induced negative geotaxis behavior in Drosophila. We have observed similar results using the DA-neuron specific THGal4 line to drive the expressionof an α-synuclein transgene 10 and used this functional read-out to study the neuroprotective role of the Nrf2 pathway in this Drosophila model of PD 14. The specific assay described here is adapted from 2 and 3.
The Drosophila brain contains more than 100 DA neurons, arranged in at least 5 different clusters (PPL1, PPL2, PAL, PPM1/2, PPM3) which can be visualized in whole brain mounts by confocal microscopy (see for example 11 and 7). It is still controversial whether or not the number of DA neurons in the Drosophila brain declines with age 9, 11; however, age-dependent neurodegeneration is observed in flies where PD-linked genes have been mutated/overexpressed to model human diseases 5. The expression of human α-synuclein in DA neurons has such an effect and, hence, has been used as a model for PD. Here we describe an assay for DA neurons count in whole brain mounts using TH as a cell marker. This assay has been adapted from 13 and 10.
1. Startle-induced Negative Geotaxis Assay
Note
We perform all our assays at the same time of the day, at RT and under the same light conditions. Keeping the flies in a 12 hr light/dark cycle environment is advisable to control for the effect of circadian rhythms on the flies’ locomotor behavior.
2. Tyrosine Hydroxylase Immunofluorescence Assay of Whole Brain Mounts
Solutions and buffers
Fixative solution: 4% Paraformaldehyde (PFA) in phosphate buffered saline (PBS)
Washing buffer: 0.1% Triton X-100 in PBS
Blocking buffer: 0.1 M Tris-HCl, pH 7.5, 0.15 M NaCl, 0.1% Triton X-100 and 0.5% BSA
Mounting media: Mowiol-Dabco (see protocol described in Harlow E, Lane D., Antibodies- A laboratory manual, Cold Spring Harbor Laboratories Press, Cold Spring Harbor, NY, USA, 10:418 (1988))
Procedimento
We have used the assays described here to study the role of the stress protective Nrf2 pathway in a Drosophila model of PD 14. This model relies on the expression of the human α-synuclein gene in DA neurons using a TH Gal4 driver 2, 10.
Figure 1 shows a representative result of a startle-induced negative geotaxis (climbing) assay in male flies expressing different transgenes under the control of the TH Gal4 driver. All the genotypes tested exhibit a decline in locomotor activity over time; however, flies expressing the PD-linked, human α-synuclein transgene exhibit an accelerated decline relative to age-matched control flies (TH Gal4 driver alone) or flies co-expressing the Nrf2 DNA binding partner Maf-S. Similar results were observed in female flies.
Figure 2 illustrates a representative result for a TH immunofluorescence-based DA neuron count. The effect of different genetic backgrounds on the number of PPL1 neurons in brains from 4 week old male flies is quantified as described in the figure legend. Notice the small but significant loss of PPL1 neurons in brains from flies expressing α-synuclein.
Figure 1. Startle-induced negative geotaxis assay. Cohorts of age-matched flies of the indicated genotypes were tested for locomotor activity at one-week intervals. Climbing activity was calculated by counting the number of flies above the 2 cm mark 10 sec after tapping the vial and expressing this value as a percentage of the total number of flies contained in the vial. Data show means ± s.e.m. of five independent cohorts of 20-30 flies. Significance was assessed with a two-way ANOVA with Bonferroni post-hoc test (P<0.05). The difference between TH,α-Synflies and flies of the other three genotypes tested was significant at 4 and 5 weeks.
Figure 2. Detection and count of DA neurons by TH immunofluorescence. A. Flow diagram illustrating the protocol for preparing brain slides. For a more detailed description of each step see text. B. Representative micrograph of a whole brain mount (right hemibrain, posterior view) immunostained for TH. A set of confocal z-series images was acquired with a Leica SP2 confocal microscope, 40X oil objective (N/A 1.25), frame average 2, step-size 1 μm, in a 1,024 x 1,024 format and compiled as a maximum projection (shown). The position of the PPL1 DA neuron cluster is highlighted. C. Representative results for DA neuron counts obtained using TH immunostaining. The number of neurons in the PPL1 cluster was assessed by inspecting the individual images of each confocal z-series. N represents the number of independent samples analyzed for each genotype. Data are means ± s.e.m. Significance was assessed with the Student’s t test (*P<0.05). Click here to view larger figure.
Genotypes: ‘con’, THGal4/+;THGal4/+; ‘UAS-Syn’, THGal4, UAS
-αSynuclein/+;THGal4,UAS -αSynuclein/+; ‘UAS-Maf-S’, THGal4/UASMaf-S;THGal4/+; ‘UAS-αSyn/UAS-Maf-S’, THGal4, UAS-αSynuclein/UASMaf-S;THGal4, UAS-αSynuclein/+; ‘keap1EY5‘,THGal4/+;THGal4/keap1EY5; ‘UAS-αSyn/keap1EY5‘, THGal4, UAS-αSynuclein/+;THGal4, UAS-αSynuclein/keap1EY5.
[Reproduced from Barone et al. 2011) in agreement with the “Open access” policy of “Disease models and mechanisms”.]
The assays described here provide a useful approach to study the role of specific genes, signaling pathways or small compounds in the maintenance of DA neurons in aging as well as in different disease-linked genetic backgrounds (reviewed in 5).
The startle-induced negative geotaxis behavior of Drosophila has been extensively used as a functional read-out for the functionality of DA neurons in different genetic backgrounds, particularly in the presence of PD-linked mutations. Some discrepancies among different studies have been observed (see 12 for a more detailed discussion). These have been attributed at least in part to different assay set-ups and conditions, including the number of flies tested in each tube (single fly versus flies’ cohort), the time of recovery after CO2-mediated anesthesia and the number of consecutive trials (see 4 and 11 as examples of different assay set-ups). It might therefore be advisable to control for such parameters and, if necessary optimize them for specific assay requirements.
The quantification of DA neurons by TH immunostaining/confocal microscopy has been used interchangeably with the method based on THGal4-driven GFP expression and identification of DA neurons by GFP fluorescence/confocal microscopy. The two methods give comparable results in the majority of cases; however, in general, the TH immunostaining technique is preferred by us and other investigators as it is sensitive to the functional state of DA neurons. For a more detailed comparison see 11 and 10. This assay could be complemented by measuring the dopamine levels in fly heads homogenates [see 1 as an example].
The authors have nothing to disclose.
We thank Leo Pallanck for fly stocks, Christine Sommers for technical assistance and Gerasimos P. Sykiotis for helpful discussions. This work was funded by the NIH training grant T32CA009363 to M.C.B.
Name | Company | Catalogue number | Comments (optional) |
Rabbit anti-tyrosine hydroxylase antibody | Millipore | AB152 | |
Donkey TRITC-labeled anti rabbit IgG antibody | Jackson ImmunoResearch | 711-026-152 | |
Mowiol | Calbiochem | 475904 | |
DABCO | Sigma | D2522 | |
Equipment | |||
Polystyrene vials | VWR | 89092-734 | 28.5 x 95 mm |
Digital camera | Canon | PowerShot A3100IS (model) | 12.1 Megapixels 4X Optical Zoom |
Glass coverslips no. 1.5 | VWR | 48366 205 48393 252 | Sizes: 18 x 18 mm, 24 x 60 mm |
Glass coverslips no. 2 | VWR | 48368-040 | Size: 18 x 18 mm |
Dissection dishes | Electron Microscopy Sciences | 70543-01 | Size: 30 mm O.D. |
Dumostar No. 5 tweezers | Electron Microscopy Sciences | 72705-01 | |
Stereomicroscope | Carl Zeiss | Stemi 2000 (model) | |
Confocal microscope | Leica | SP2 or SP5 (model) |
Materials Table.