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Original Article

Exp Neurobiol 2020; 29(4): 273-284

Published online August 31, 2020

https://doi.org/10.5607/en20028

© The Korean Society for Brain and Neural Sciences

L-DOPA-Induced Dyskinesia in a Genetic Drosophila Model of Parkinson’s Disease

Joshua A. Blosser, Eric Podolsky and Daewoo Lee*

Neuroscience Program, Department of Biological Sciences, Ohio University, Athens, OH 45701, USA

Correspondence to: *To whom correspondence should be addressed.
TEL: 1-740-597-1926, FAX: 1-740-593-0300
e-mail: Leed1@ohio.edu

Received: July 11, 2020; Revised: August 27, 2020; Accepted: August 31, 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License
(http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and
reproduction in any medium, provided the original work is properly cited.

Motor symptoms in Parkinson’s disease (PD) are directly related to the reduction of a neurotransmitter dopamine. Therefore, its precursor L-DOPA became the gold standard for PD treatment. However, chronic use of L-DOPA causes uncontrollable, involuntary movements, called L-DOPA-induced dyskinesia (LID) in the majority of PD patients. LID is complicated and very difficult to manage. Current rodent and non-human primate models have been developed to study LID mainly using neurotoxins. Therefore, it is necessary to develop a LID animal model with defects in genetic factors causing PD in order to study the relation between LID and PD genes such as α-synuclein. In this study, we first showed that a low concentration of L-DOPA (100 μM) rescues locomotion defects (i.e., speed, angular velocity, pause time) in Drosophila larvae expressing human mutant α-synuclein (A53T). This A53T larval model of PD was used to further examine dyskinetic behaviors. High concentrations of L-DOPA (5 or 10 mM) causes hyperactivity such as body bending behavior (BBB) in A53T larva, which resembles axial dyskinesia in rodents. Using ImageJ plugins and other third party software, dyskinetic BBB has been accurately and efficiently quantified. Further, we showed that a dopamine agonist pramipexole (PRX) partially rescues BBB caused by high L-DOPA. Our Drosophila genetic LID model will provide an important experimental platform to examine molecular and cellular mechanisms underlying LID, to study the role of PD causing genes in the development of LID, and to identify potential targets to slow/reverse LID pathology.


Keywords: Alpha-Synuclein, Parkinson’s disease, L-DOPA, Dyskinesia, Drosophila melanogaster

There is no cure for Parkinson’s disease (PD) in spite of intensive research for last decades. Nonetheless, several drugs have been used to ameliorate PD symptoms. L-DOPA became a gold standard drug to treat PD symptoms. However, chronic use of L-DOPA for 5~10 years causes uncontrollable movements, called L-DOPA-induced dyskinesia (LID) in the majority of PD patients [1, 2]. LID is very difficult to manage and complicated to understand. Therefore, animal models have been developed to seek the mechanisms involved in LID and identify new drug targets [3, 4]. Current rodent and non-human primate models have been developed mainly using MPTP and 6-OHDA neurotoxins. In addition to neurotoxins, genetic factors (e.g., α-synuclein, parkin, and LRRK2) are involved in PD [5, 6]. Since the discovery of the first PD gene α-synuclein (α-Syn), the genetic PD models have provided key insights into disease mechanisms. Therefore, it is necessary to develop a LID animal model with defects in these PD genes to study the relation between LID and these genes such as α-Syn. However, genetically tractable mouse models are known to poorly recapitulate PD symptoms (e.g., no degeneration of DA neurons) [7, 8], and thus it is urgent and necessary to develop a new genetic PD model showing LID.

The fruit fly Drosophila melanogaster has been a highly useful genetic model of human neural diseases. In addition to the short-generation time and dramatically reduced costs of maintaining large populations, the ability to combine behavioral and biochemical approaches with sophisticated molecular genetics has made Drosophila a ‘model organism of choice’ for identification of genes involved in higher brain function and disease pathogenesis. Perhaps surprisingly to some, gene sequences and function are highly conserved between flies, rodents and humans [9, 10]. About two thirds of human disease gene homologues are found in the Drosophila genome. Furthermore, a humanized fly disease model can be easily created using a transgenic fly expressing a mutant human disease gene (e.g. mutant human α-Syn) [11-13]. Drosophila α-Syn flies replicate all major PD symptoms: selective loss of dopaminergic (DA) neurons, intracellular aggregates called Lewy Bodies, and locomotion defects [11-15]. Therefore, mutant α-Syn Drosophila can be an excellent genetic PD model to study LID.

In order to develop an LID model, it is necessary to confirm that PD symptoms can be rescued by L-DOPA. Next step is to study whether prolonged or high L-DOPA administration causes dyskinetic behavior. In this study, we showed that a low concentration of L-DOPA (100 µM) rescues locomotion defects in Drosophila larvae expressing human mutant α-Syn (A53T). Therefore, this fly larval model of PD was used to further examine dyskinetic behaviors. High concentrations (5 or 10 mM) of chronic L-DOPA administration showed hyperactivity in A53T larva such as body bending behavior (BBB), which resembles axial dyskinesia in rodents [16, 17]. We also developed a method to accurately and efficiently quantify LID behavior via the use of ImageJ plugins and other third party software. Further, dyskinetic BBB by high L-DOPA was rescued by a dopamine agonist pramipexole (PRX). Our LID model developed in a Drosophila genetic model of PD can be a useful experimental platform to study pathophysiological mechanisms underlying LID and also provide a new avenue for developing potential treatments of LID.

Fly strains

Flies were grown in standard cornmeal/agar media with 0.4% propionic acid on a 12-hour light/dark cycle at 25°C. Fly strains used were: wild type w1118 (from Bloomington Stock Center), TH-Gal4 (a kind gift from Dr S. Birman at ESPCI, France) [18], UAS-α-Syn (A53T) (A53T, a gift from Dr. L. Pallanck, University of Washington, USA) [19]. In this study, we used a fly line carrying TH-Gal4 and UAS-α-Syn (A53T) on chromosome 3, designated as A53T. Flies were allowed to lay eggs onto an agar plate for an hour. Each plate had roughly 50 eggs on its surface. The plate was then incubated at 25°C for locomotion assay.

Larval locomotion assay

Larvae were collected at 90~96 hours after egg laying for the locomotion assay as previously described [15]. An assay stage was prepared by boiling 2.5% agar in ddH2O, adding 5 drops of India ink for contrast, and pouring the mixture into a petri dish to solidify. Third instar larvae were loosened from the food using ddH2O and placed individually on the stage to be tested. First, the larvae were allowed to move freely for one minute to let them acclimate to the stage. Next, the larva was recorded using a Moticam3 digital camera recording at approximately 10 frames/sec with the Motic Images Plus 2.0 software. The recording time was 30 seconds, with recording being stopped if the larva left the field of view (FOV). Several drops of ddH2O were periodically added to the stage to keep it from drying.

L-DOPA was added to the melted food in the egg laying plates before solidifying and larvae were incubated in this food for the entire 90-96 hour period or 48 hours during the third instar stage before testing. L-DOPA was administered in food with ascorbic acid (25 mg/100 ml) to prevent oxidation [20]. Stock solutions were prepared monthly and kept at 4°C to ensure freshness. All L-DOPA controls contained matching amounts of ascorbic acid.

Analysis of locomotion parameters

The program ImageJ (http://rsb.info.nih.gov/ij/) was used to analyze the video files. The videos were first imported to produce a stack of images for each frame. The color threshold was then adjusted so that the larva was a distinct object in contrast with the background. In order to determine the locomotion speed of the larvae, the MTrack2 plug-in (http://valelab.ucsf.edu/~nico/IJplugins/MTrack2.html) was used to determine the path length. The length was then converted to mm/min by using the number of seconds in the video file as well as a conversion factor between pixels and millimeters (12.2 pixels/mm), which had been determined to be given the height of the camera as previously adopted [15].

To find the angular speed and pause time of the larvae, software was developed (with the assistance of J. Bury, B.S., Computer Science, University of Toledo, USA) to analyze the raw movement data as exported from MTrack2. The raw data consisted of a set of ordered pairs corresponding to all the points to which the larva moved. To analyze the raw data, the software divided the number of frames in the video by the number of seconds in the video. The resulting number corresponded to the number of frames in one second of video, and the software then sampled the position of the larva at each second. This was done to reduce noise in the video to provide more accurate results. The camera used in this study recorded at 16 frames per second. Lines were then made connecting each of the selected points (Fig. 1A). To determine the angular speed, the angle was determined at the intersection of each pair of lines. To do this, the distance formula (Equation 1) was used to determine the distance of each of the two lines, as well as the distance of a third line that would produce a triangle between the two lines.

Equation 1: d=(x2-x1)2+(y2-y1)2

Given this triangle, the angle of interest (γ) was determined using the law of cosines (Equation 2).

Equation 2: c2=a2b2-2ab*cos(γ)

This angle was then subtracted from 180° to determine how many degrees the larva had deviated from a straight line in that given second. This analysis was done for each second, and the average in degree (°)/sec was subsequently determined by dividing the sum of all of the angles by the number of seconds. The pause time was determined using the same software. For each line indicating a second of movement, the distance was converted to mm/min using the technique described above. A threshold value would determine whether the larva was considered to be “paused” or “in motion” as even a stopped larva registers some movement due to head shaking, rolling, etc. A value of 45 mm/min was found to correlate well with the pause time seen by a human observer for several videos. The number of seconds in which the larva moved at a speed less than the threshold value (45 mm/min) was found, and this was then converted to the number of seconds paused per minute.

Quantifying body bending behavior

Our method involves keeping a larva in a small well (φ=2 mm) that is slightly larger than the length of the larva (Fig. 2A), inhibiting the larvae from any lateral crawling motion, but only allows movement along the body axis of the larva and around the vertical axis of the well. To analyze body bending behavior (BBB), 30 second video was taken of a larva in the well and then imported into ImageJ to create a stack. Sub-stacks were created by selecting every 32nd frame. As the MoticCam shoots 16 frames/second, this created a stack with one frame for every two seconds of video. The subsequent sub-stacks were then analyzed in ImageJ via the ManualTracking plugin. Three points, one on the head, midpoint, and tail, were tracked by manually selecting them on every frame in the sub-stack, reducing the body of the larva to a three-point skeleton (Fig. 2B). The distance formula (Equation 1) was used to compare the entire length of the larva to the distance from the head to the tail. The entire length of the larva was measured as the length of AB+BC, while the distance from head to tail was measured as the length of AC. The rate of body bending was then calculated as a ratio of the length of AB+BC to the length of AC, via Equation 3.

Equation 3: rate of body bending=1-AC/(AB+BC)

As the body of the larva bent and the head was brought down towards the tail, AC decreased while AB+BC stayed the same. As this ratio is a measure of overall straightness, the fraction was subtracted from one to get a measure of the decrease in straightness, or body bending behavior (BBB).

Statistical analysis

Data are shown as mean±SEM. Statistical analysis was performed using Graph-Pad Prism software. Means were compared using an unpaired two-tailed Student’s t-test. p values ≤0.05 were considered significant.

L-DOPA rescues α-Syn-mediated locomotion defects

Our previous study showed that the fruit fly Drosophila larva expressing human α-Syn (A53T) crawls significantly slower compared to wild type fly larva [15]. A53T fly larva (TH-Gal4, UAS-α-SynA53T) also shows reduced number of dopaminergic (DA) neurons in the brain [15]. In addition to the speed, we also analyzed two additional motor behaviors: angular velocity and pause time. Since slow movement (bradykinesia) is only one of the motor symptoms of PD, and other measures of locomotion such as angular velocity and pause time have been measured. Locomotion speed represents bradykinesia, which is one of the major motor symptoms of PD, but angular velocity and pause time are used to see other behaviors related to PD symptoms such as walking difficulties and gait freezing. These three parameters are different ways to examine various PD-like symptoms.

Using UAS x Gal4 binary system [21], a mutant human α-Syn (A53T) was expressed in DA neurons (TH-Gal4 x UAS-A53T). A53T larvae showed locomotion deficits in crawling speed, average angular velocity, and pause time (Fig. 1), demonstrating that A53T larva is a useful genetic animal model for Parkinson’s disease (PD).

Since L-DOPA is a gold standard drug to ameliorate PD symptoms, we examined L-DOPA effects on locomotion defects in A53T larva. When L-DOPA (100 µM) was administered in food, crawling speed of α-Syn (A53T) larvae was significantly increased (Fig. 1A, B). In addition, angular velocity and pause time were also rescued by L-DOPA (Fig. 1C, D). However, 10 µM L-DOPA did not rescue the crawling speed in A53T larva (Table 1). We also observed that rescue effects of 1 mM L-DOPA were slightly reduced compared to 100 µM. Therefore, 100 µM L-DOPA was used in these experiments to rescue locomotive symptoms as it has been determined to have the highest rescue effects in A53T Drosophila larvae. 100 µM L-DOPA rescued speed deficits by 42.2%, average angular velocity deficits by 75.3%, and pause time deficits by 67% (Fig. 1). Our results demonstrated that treatment with 100 µM L-DOPA rescued the locomotion defects of A53T larvae comparable to wild type levels.

L-DOPA-induced dyskinesia in A53T larvae

Because L-DOPA had experimentally shown to rescue Parkinsonian symptoms in Drosophila A53T larvae, it was hypothesized that excessive exposure to L-DOPA would induce dyskinetic behavior. Experiments were designed to induce dyskinetic behavior in Drosophila A53T larvae by overexposure to L-DOPA. We developed a method to quantify dyskinetic behavior in Drosophila larvae (Fig. 2A, B; also refer to Materials & Methods section). In order to simulate the effects of prolonged exposure to L-DOPA, A53T larvae were treated with a high concentration (e.g, 10 mM) of L-DOPA for 92 hours and compared to wild type (WT), A53T and A53T larvae rescued with 100 µM L-DOPA (Fig. 2C). In this study, we used 10 mM L-DOPA to induce dyskinetic behavior, which is 100 times the rescuing amount. Exposing larvae to 10 mM L-DOPA showed body bending behavior (BBB; Fig. 2A), which mimics the axial dyskinesia, a symptom of dyskinetic behavior in mammals [16, 22]. Therefore, BBB was used as a parameter of LID to quantify dyskinetic behavior in this study. Larvae exposed to a high concentration (10 mM) of L-DOPA increased BBB dramatically, but A53T larvae with (A53T+100 µM) or without (A53T Control) a low concentration of L-DOPA did not show changes in BBB, demonstrating dyskinetic behaviors specifically in a genetic Drosophila model of PD exposed to a high concentration of L-DOPA.

Inherent L-DOPA toxicity

Because LID is not a symptom of PD, but rather a symptom of long-term exposure to L-DOPA, we hypothesized that there would be no significant difference in BBB of WT, A53T, or L-DOPA rescued larvae. In order to ensure that the change in body bending behavior is in fact due to L-DOPA-induced dyskinesia, and not due to inherent L-DOPA toxicity, various concentrations of L-DOPA were administered to WT larvae for 92 hours (Fig. 3A). The BBB of the WT larvae were then analyzed. Because WT larvae are not expressing α-synuclein, no PD-related dyskinetic behavior was expected when exposed to any levels of L-DOPA. Despite not expressing α-synuclein, however, WT larvae showed significantly higher levels of body bending behavior when exposed to high concentrations of L-DOPA (5 or 10 mM) although percent of BBB in WT larvae was lower compared to that of A53T+10 mM L-DOPA larvae. The results suggest that BBB observed in Fig. 2C is not in fact due to the isolation of LID, but involves, at least partly due to the inherent L-DOPA toxicity or drug-induced dyskinesia (see Discussion) possibly by an increase of neuronal DA levels.

No inherent toxicity when WT larvae are exposed to L-DOPA for 48 hours

In order for the LID model to reliably isolate and quantify dyskinetic behavior, it was necessary to reduce the amount of time the flies were exposed to L-DOPA. This would minimize the toxic effects seen in WT flies exposed to high concentrations of L-DOPA for 92 hours (Fig. 3B). All eggs were initially laid onto three control food plates. After incubating for the first and second instar stages (~44 hours) without L-DOPA, larvae were then transferred to new food plates: WT, WT+100 µM L-DOPA, and WT+10 mM L-DOPA. The larvae on all three plates were then returned to the incubator for 48 more hours before testing. By limiting the exposure time, L-DOPA-dependent BBB seen in WT larvae with long-term exposure were eliminated (Fig. 3B). Therefore, this L-DOPA treatment protocol can be used to examine dyskinetic behavior in the A53T larval model of PD.

Rescue of locomotion defects in A53T larvae with 48 hour exposure to 100 µM L-DOPA

Because WT larvae have shown no locomotion deficits (speed, angular velocity and pause time) when 100 µM L-DOPA was applied for only 48 hours (data not shown), the next step was to test the rescue effects of 100 µM L-DOPA when applied to A53T larvae for only 48 hours to make sure that L-DOPA could still rescue PD symptoms. The rescue effects of 100 µM of L-DOPA were tested by applying for only 48 hours (Fig. 4). Even when applied for a shorter duration, L-DOPA still rescued the speed deficits of A53T larvae by 30.7%, average angular velocity by 79.9%, and pause time by 58.5%. As far as body bending behavior was concerned, there was no difference between WT Control, A53T Control, and A53T larvae rescued with 100 µM L-DOPA (Fig. 5A). The results prove that any behavior being measured by the BBB model is not a PD symptom, as it is not present in A53T larvae with or without 100 µM L-DOPA.

LID in A53T larvae with 48 hour exposure to 10 mM L-DOPA

In this study, we examined whether the application of high doses of L-DOPA for 48 hours can induce dyskinetic behavior in Drosophila A53T larvae. The A53T larvae rescued with 100 µM L-DOPA were compared to larvae treated with 5 and 10 mM L-DOPA (Fig. 5). Exposure to 5mM L-DOPA increase BBB in A53T larvae by 172%, and exposure to 10 mM L-DOPA increased it in A53T larvae by 252%, when compared to A53T larvae rescued by 100 µM L-DOPA. Our data showed that high L-DOPA (5 or 10 mM) significantly increases involuntary and hyperactive LID behaviors including body bending. In contrast, WT larvae showed no increase in body bending rate with 10 mM L-DOPA for 48 hours (Fig. 3B), confirming the successful development of a genetic LID model using Drosophila A53T larvae. This successful development of a Drosophila genetic LID model is very significant as LID is currently one of most difficult challenges in PD management.

Rescue of LID with a dopamine agonist pramipexole

With high L-DOPA proven to induce dyskinetic behavior in A53T larvae, the next step was to see if the symptoms of LID could be rescued. Pramipexole (PRX), a D2-like receptor agonist, was chosen, as it has been used in clinical settings on humans to treat LID [23, 24]. Larvae were treated with 10 mM L-DOPA and 0.4 mM PRX for 48 hours and compared to A53T larvae exhibiting dyskinetic behavior for 48 hour-exposure to 10 mM L-DOPA alone (Fig. 5). The administration of PRX fully rescued body bending behavior to the level similar to A53T without L-DOPA. PRX also rescued average angular velocity by 36.4% and pause time by 29.3%. Interestingly the crawling speed was not rescued. The increase in angular velocity/pause time and decrease in speed by a high concentration of L-DOPA (10 mM) can be explained by the loss of lateral movement due to BBB. Our results suggest that PRX has potential to be a therapeutic agent for the treatment of L-DOPA-induced dyskinesia in a genetic PD.

The leading treatment for Parkinson’s disease symptoms is L-DOPA, a precursor of dopamine, of which administration increases dopamine levels in the brain. But too much dopamine being present in the brain is expected to cause dysfunctional dopamine signaling. Prolonged exposure to L-DOPA can lead to L-DOPA-induced dyskinesia (LID) [1, 2, 25]. LID consists of involuntary, hyperactive behavior, and is a common occurrence among Parkinson’s disease (PD) patients, yet there is currently no known cure and also no convenient way to screen potential therapeutic drugs. Complications of LID can be reduced by lowering the amount of L-DOPA that is taken, but unfortunately, this decrease in L-DOPA can lead to a return of Parkinsonian symptoms. The current study is significant because it establishes a genetic LID model for the study of dyskinetic behavior. Depending on L-DOPA levels in brain and blood plasma, various patterns of LID have been characterized such as peak-dose LID, diphasic dyskinesia and off-period dystonia [26]. The most common pattern is peak-dose LID which causes involuntary movements when L-DOPA level is high. On the basis of our method to administer L-DOPA, Drosophila larval LID model appears to represent peak-dose LID in mammals. Previously, there were few LID models which can be used to study underlying pathophysiological mechanisms, genetic/molecular targets initiating the development of LID, and potential pharmacological therapies [27], largely due to lack of rich genetic resources. Recently, Gupta et al. [28] has been developed C. elegans LID model expressing human α-synuclein, which shows increase body bending with L-DOPA. Overall, our Drosophila genetic LID model will provide an important experimental platform to examine molecular and cellular mechanisms underlying LID, to study the role of PD causing genes in the development of LID, and to identify potential targets to slow and/or reverse LID pathology. Therefore, this genetic LID model can greatly contribute our efforts to develop better therapeutic strategies and rapidly screen drugs alleviating PD symptoms without causing LID, providing significant translational impacts.

LID occur in 30~80% of PD patients treated with L-DOPA [1,2,54-56]. Two conditions are necessary for their appearance: 1) the loss of DA in the nigrostriatal pathway and 2) treatment with L-DOPA [55, 56]. In order to study LID, it should use a PD model showing the loss of DA neurons. Therefore, it is necessary to start with a PD model showing locomotion defects and degeneration of dopaminergic system, and then study its rescue with L-DOPA. LID can be developed using such PD model. The utilization of Drosophila in this study is particularly practical due to the established PD model available in fruit flies [11, 29]. In addition, the relatively short lifespans of Drosophila make experimentation a quick process. Rather than waiting months to years for a neurodegenerative disease to present in mice, rats, or other animal models, experiments can be performed on larvae only four days after eggs are laid. In addition, the relatively low cost of maintenance and the large quantity in which they can be raised make the Drosophila model particularly accessible to labs across the world. Although adult fly is also widely used to study human neurodegenerative diseases, we used third instar larvae in this study because it is much easier to examine PD symptoms in terms of locomotive behavior. Also it takes less time to observe PD symptoms (4 days) and thus LID can be studied in this time frame.

Because of the longitudinal body shape of Drosophila larvae, axial dyskinesia is easily tracked. Axial dyskinesia has been effectively used to quantify LID in mice models [16], and therefore made sense as a parameter to be used in larva. The nature of the wells in the metal bar used to establish this model made tracking dyskinetic behavior along the longitudinal axis of the larvae particularly easy. The diameter of the wells is not much longer than the length of the larvae. This inhibits the larvae from any lateral crawling motion, but only allows two different degrees of motion. The first motion is rotation about the longitudinal axis of the larva, and the second motion is bending, or deviation, from the longitudinal axis of the larva (=involuntary movement in the fly larva). In future experiments, rotational movement could also be tracked [30]. In this study, axial dyskinesia was tracked, by comparing the distance between the head and the tail was compared to the length of the entire larva. Therefore, as the larva spends more time with its body contorted, bringing its head down to its tail, its percent body bending behavior goes up. This provides an easily identifiable and quantifiable method of measuring body bending behavior (BBB).

LID is an example of drug-induced dyskinesia (DID). Drug-induced dyskinesia (e.g. Tardive dyskinesia or LID) is caused by the long-term use of a certain type of medications including antipsychotic drugs and levodopa [57]. It was interesting to observe that wild type larvae without PD symptoms showed dyskinetic behavior induced by high concentrations of L-DOPA (Fig. 3). It is possible to use wild type larva to study DID, but the current study focusses on LID which should be developed from a PD model with DA neurodegeneration in the brain. DID with wild type larva is certainly an interesting research topic to further explore.

Treatment of LID is still a major challenge. However, several drugs have been used to ameliorate LID including dopaminergic (e.g., DA-R agonist apomorphine) and non-dopaminergic drugs (e.g., NMDA receptor antagonist amantadine). Studies showed that DA receptor agonists can reduce LID [56, 58, 59]. After successfully established fly larval model of LID, we tested a D2/3 agonist pramipexole to rescue LID in fly larvae as it has been shown pramipexole reduces dyskinesia in MPTP-treated primate when it was applied with L-DOPA [23, 60]. Similarly, other known LID drugs (e.g., amantadine, safinamide) can be also studied for their therapeutic potentials on LID. Our model can be also used to screen new potential therapeutic drugs. Since we added pramipexole and L-DOPA concomitantly in the food, it certainly possible that pramipexole may cause neuroprotection against LID instead of rescuing LID. This possibility should be further examined in order to clearly show the rescue effects of pramipexole in the fly larval LID model.

It still remains to completely understand pathological mechanisms underlying LID [31, 32]. Nonetheless, some potential mechanisms are related to alterations in DA signaling. Long-term exposure to L-DOPA alters neural circuits in basal ganglia [2, 4]. It has been suggested that uncontrollable release of dopamine (DA) by L-DOPA results in dyskinetic behaviors [1, 33]. Altered activities of D1 and D2 receptors also cause abnormal movements by excessive cortical stimulation through L-DOPA-dependent disinhibition of thalamus [2]. Therefore, both PD and LID are caused by dysfunctional DA signaling although PD is due to reduced DA signaling while LID is by increased and uncoordinated DA activities. Recently, it has been shown that hyperkinetic activity and altered D1 signaling underlie L-DOPA induced dyskinesia in C. elegans [28], further supporting the notion that uncontrollable DA signaling is a key pathological mechanism of LID. One important factor considering use of Drosophila model for LID is the similarity of DA signaling mechanisms in mammals and Drosophila. DA neurons in Drosophila receive both excitatory and inhibitory synaptic inputs and are spontaneously active. Drosophila DA autoreceptors also known to suppress the excitability [34-36]. Like mammals, excitatory dopamine D1-like and inhibitory D2-like receptors are expressed in Drosophila nervous system. Both Drosophila D1- (i.e. dDA1, DAMB) and D2-like (i.e. DD2R) receptors have been molecularly characterized [37-40]. Like in mammals, DA is known to play important roles in behavior such as locomotion, memory formation and drug addiction in Drosophila [41, 42]. Therefore, Drosophila LID model can be used to study pathological mechanisms underlying LID. One such signaling example is cAMP-PKA-CREB pathway, which has been intensively studied in Drosophila [43]. It is well known that cAMP signaling pathway is downstream of D1R signaling. Indeed, LID models using PD neurotoxins showed over-expression of Gαolf and adenylyl cyclase V [44, 45]. It will be interesting to examine whether increased cAMP-PKA signaling is associated with our genetic LID model. Further, a chemogenetic approach (i.e., DREADD) [46, 47] can be used to manipulate intracellular cAMP levels.

In addition to L-DOPA, D2 agonists (e.g., pramipexole, bromocriptine, ropinirole) have been used clinically to treat PD symptoms [48]. We showed that activation of D2 receptors is critical to rescue dopaminergic (DA) degeneration by a PD toxin MPP+, and that D2 autoreceptors expressed in DA neurons are sufficient for this rescue [36]. For LID, few drugs are available to alleviate its symptoms at present, but clinical studies with PD patients showed that D2 agonists reduce the risk of dyskinesia incidence [24, 49, 50]. Among D2 agonists, pramipexole is known to alleviate symptoms of LID in PD patients treated with L-DOPA [23]. D2 agonists are known to regulate the amount of DA release in the brain as they act mainly on presynaptic D2 receptors and thus inhibit DA release, counterbalancing increased levels of DA. Interestingly, we also observed rescue effects of a D2 agonist pramipexole (PRX) on LID in Drosophila α-Syn larvae (Fig. 5). PRX shows a strong binding affinity to D3 subtype, a type of D2-like receptors. So far, however, only one D2 receptor DD2R has been identified in Drosophila [40]. Therefore, it is assumed that Drosophila DD2R may be a common D2 receptor representing mammalian D2-like receptor subtypes – D2, D3 & D4. Further, it has been shown that PRX improves motor symptoms in PD flies [51]. Therefore, role of D2-like receptor family in LID can be further examined in Drosophila α-Syn model. In addition, our larval LID model can be used to test the rescue effects of neuroprotective drugs, like nicotine and caffeine, on dyskinetic behavior [52]. Smoking and coffee drinking are known to protect against neurodegeneration, and thus prevent PD and Alzheimer’s disease. For these reasons, Drosophila can be an effective and practical model to examine potential drugs for the rescue of LID.

Our study showed that low L-DOPA (100 µM in food) rescues PD motor symptoms in Drosophila larvae expressing mutant human α-Syn (α-Syn larva) while higher L-DOPA (10 mM) causes dyskinetic behaviors including involuntary and continuous body bending (similar to axial dyskinesia in rodents), demonstrating that Drosophila α-Syn larvae can be an excellent genetic LID model. However, our current method is largely based on laborious manual analysis, limiting our quantification only to the bending behavior. It is desirable to automate and optimize the dyskinetic behavior analysis with high resolution images using a recently introduced method called ‘MaggotTracker’ - a single-animal tracking system for Drosophila larval locomotion [30]. This tracker system can quantify uncontrollable rotational behavior and peristalsis movement, which may be relevant to LID. MaggotTracker can also analyze free-moving larvae with high resolution images, instead of analyzing constrained larvae in a small well. In addition, it can analyze more behavioral phenotypes. LID in mammals is typically determined using sums of abnormal involuntary movement (AIM) scales: axial, limb and orolingual dyskinesias [53]. Further automation of LID analysis with more behavioral phenotypes (e.g, head bending, uncoordinated peristaltic movements) will enhance utilities of our Drosophila LID model to study its underlying pathological mechanisms and develop its therapeutic treatments.

In human, it takes several years to develop LID whereas it takes weeks to months for rodent models [17, 61]. Although continuous administration of L-DOPA can induce dyskinesia in preclinical studies [62], most studies have reported an increase in the frequency of LID by extended period of L-DOPA use. Therefore, our fly model dose not exactly recapitulate what happened in mammals including human. However, we believe that our fly LID model is very useful to study molecular and cellular mechanisms underlying LID pathology as the primary cause of LID is initiated from the dysfunctional dopamine signaling. Drosophila has a conserved dopamine neural circuits which is known to play an important role in locomotion [42]. Further, LID in the fly larval model can be developed in 4 days and thus this model can be a very useful genetic platform to screen genes modifying LID pathology and also potential therapeutic LID drugs. There are limitations in the fly LID model but it has other advantages over mammalian LID models.

This work was partially supported by the International Collaboration Grant from Korea Institute of Science & Technology (Brain Science Institute), Seoul, Korea. We thank Jason Bury at University of Toledo for helping us to develop a software for locomotion analysis. JAB was a recipient of Ohio University Provost’s Undergraduate Research Fund.

Fig. 1. L-DOPA rescues locomotion defects in α-Syn (A53T) Drosophila model. Fly larvae expressing α-Syn (A53T) showed locomotion defects quantified with three locomotion parameters: speed, angular velocity, and pause time. (A) Crawling paths were visualized by selecting the 30 second paths that most closely represents the locomotion parameters of each group. Arrows were placed at the end of each pathway to show the direction of motion. When 100 µM L-DOPA were applied to A53T larvae for 92 hours, all three locomotive parameters including speed (B), angular velocity (C), and pause time (D) were rescued. Note that rescue was not complete, as there was still a significant difference between flies treated with L-DOPA and wild type flies. Student t-test, **p<0.01, ***p<0.001. For each group, 30 larvae from 4 separate experiments were examined.
Fig. 2. L-DOPA-induced dyskinesia in A53T Drosophila larvae. (A) Example snapshots of body bending behavior (BBB) in A53T Drosophila larvae treated with high concentration of L-DOPA (A53T+10 mM L-DOPA) or without L-DOPA (A53T Control). A larva was kept in a well (2 mm diameter) to limit free-crawling and thus enable us to analyze body bending behavior (BBB). A well is delineated with a dotted circle. (B) Three points were selected at the head, midpoint, and tail of the larva on every frame in the sub-stack, creating a three point skeleton which can be used to quantify BBB (see Materials and Methods). (C) Larvae exposed to a high concentration (10 mM) of L-DOPA display a higher body bending percentage, but A53T larvae with low concentration of L-DOPA (A53T+100 µM) or without L-DOPA (A53T Control) did not show changes in BBB, demonstrating dyskinetic behaviors in a genetic PD model exposed to high concentration of L-DOPA. Student t-test, ***p<0.001. For each group, 27~32 larvae from 8 separate experiments were examined.
Fig. 3. Inherent toxicity of L-DOPA toxicity in wild type (WT) flies with longer exposure (92 hours), but not with shorter exposure (48 hours). (A) Wild type (WT) larvae treated with 5 or 10 mM L-DOPA showed a significant increase in body bending behavior (BBB) over WT Control when L-DOPA was treated from the first instar (for 92 hours). (B) WT larvae showed no changes in BBB when a high concentration (10 mM) of L-DOPA was exposed only during the third instar stage (48 hours). Student t-test, ***p<0.001. For each group, 18 larvae from 3 separate experiments were examined.
Fig. 4. Rescue of locomotion defects in A53T larvae with 48 hour exposure to 100 µM L-DOPA. When treated with 100 µM of L-DOPA for 48 hours, locomotion deficits in speed (A), angular velocity (B) and pause time (C) were significantly rescued. Locomotion deficits were not completely rescued by L-DOPA as there is still a significant difference between A53T+100 µM L-DOPA and WT Control. Student t-test, *p<0.05; **p<0.01; ***p<0.001. For each group, 9~18 larvae from 3 separate experiments were examined.
Fig. 5. Increased body bending behavior (BBB) in A53T larvae by shorter exposure (48 hours) to high concentrations of L-DOPA but rescued by a dopamine agonist pramipexole (PRX). BBB was increased in A53T larvae by high concentrations (5 or 10 mM) of L-DOPA exposure during the third instar (48 hours), but completely rescued when A53T larvae exposed to high concentrations of L-DOPA were treated with pramipexole (PRX, 0.4 mM). Student t-test, *p<0.05, ***p<0.001. For each group, 18 larvae from 4 separate experiments were examined.
Table. 1.

Locomotion speed of A53T larvae at various concentrations of L-DOPA

L-DOPA conc. (μM)Crawling speed (mm/min, +/-SEM)n
1043.3 +/-2.646
10083.4+/-4.1318
1,00078.8+/-6.736

n, number of larvae tested.


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