A Novel Method to Model Chronic Traumatic Encephalopathy in Drosophila

Podsumowanie

Here, we describe a new approach to inflict closed-head traumatic brain injury in Drosophila melanogaster. Our method has the advantage of directly delivering repetitive impacts with adjustable strength to the head alone. Further exploration of the invertebrate system will help to illuminate the pathogenesis of chronic traumatic encephalopathy.

Streszczenie

Chronic Traumatic Encephalopathy (CTE) is an established neurodegenerative disease that is closely associated with exposure to repetitive mild Traumatic Brain Injury (mTBI). The mechanisms responsible for its complex pathological changes remain largely elusive, despite a recent consensus to define the neuropathological criteria. Here, we describe a novel method to develop a model of CTE in Drosophila melanogaster (Drosophila ) in an attempt to identify the key genes and pathways that lead to the characteristic hyperphosphorylated tau accumulation and neuronal death in the brain. Adjustable-strength impacts to inflict mild closed injury are delivered directly to the fly head, subjecting the head to rapid acceleration and deceleration. Our method eliminates the potential problems inherent with other Drosophila mTBI models (e.g.,animal death might be induced by damage to other parts of the body or to internal organs). The less labor- and cost-intensive animal care, short life span, and extensive genetic tools make the fruit fly ideal to study CTE pathogenesis and make it possible to perform large-scale, genome-wide forward genetic and pharmacological screens. We anticipate that the ongoing characterization of the model will generate important mechanistic insights on disease prevention and therapeutic approaches.

Wprowadzenie

Chronic Traumatic Encephalopathy (CTE) has recently been recognized as a distinct neurodegenerative disorder, separate from other tauopathies such as Alzheimer's disease¹. Unlike Alzheimer's disease and other common tauopathies-whose most important risk factors are advancing age and a family history of dementia, CTE, as indicated by its name, implies a close association with a history of brain trauma, most likely seen in contact sports athletes, such as boxers and football players, as well as in military veterans^2,3,4,5. It is thought to be initiated by repeated concussive and subconcussive blows to the head. Patients may present symptoms and signs such as cognitive deficits, mood and behavior changes, and movement dysfunction, which overlap significantly with Alzheimer's disease, frontotemporal dementia, Lewy body dementia, and Parkinson's disease⁶. In contrast, post-mortem examinations of brain tissue reveal a distinct pattern of hyperphosphorylated tau accumulation surrounding small blood vessels at the depths of the cortical sulci, a pathognomonic feature not observed in the other degenerative conditions⁷. However, so far, very little is known about the pathogenesis leading to disease manifestation. This is in large part due to the lack of a faithful animal model - only recently have rodent models been generated^5,8. These model organisms have the disadvantages of cost-intensive care and a relatively long life span, which are not well-suited for neurodegenerative disease studies.

Compared to mammalian counterparts, invertebrate animals such as Drosophila are an excellent alternative, with their cost-effective maintenance, extensive tools for dissecting genetic determinants, and relatively short lifespan⁹. Remarkably, fly and human brains share evolutionarily conserved molecular and cellular pathways, as well as anatomical similarities^10,11,12. Two ingenious Drosophila models to study traumatic brain injury have been reported previously^13,14. The first "High Impact Trauma" (HIT) device designed by Katzenberger and colleagues contained free-moving flies in a plastic vial that was tied to the free end of a metal spring^13,15. When the plastic vial was tilted upright and released, it hit a polyurethane pad and imparted trauma to the flies as they bounced to the vial wall and rebounded. In contrast, Barekat and colleagues designed a different delivery method using the Omni Bead Ruptor-24 homogenizer platform¹⁴. Flies were incapacitated with CO₂ and placed in a 2 mL screwcap tube that was secured to the homogenizer and subjected to preprogrammed shaking conditions. One benefit of using the tissue homogenizer system is that the experimenter could modulate the intensity of injury, duration of injury, and number of injury bouts. However, both regimes suffer the same drawback: primary injuries to the head are randomly inflicted in terms of impact location and strength. In addition, both methods resulted in considerable mortality, caused by inevitable collateral damage to other parts of the body and internal organs. Here, we describe a novel method to induce mTBI in fruit flies. Our apparatus consists of a gas-propelled ballistic impactor. Compared to the existing Drosophila models^14,15, our method has the unique advantage of delivering measurable impact, directed only at the free-moving fly head, thus allowing for the accurate control of various factors, such as impact severity, the time interval between impacts, and the total number of impacts sustained.

Access restricted. Please log in or start a trial to view this content.

Protokół

1. Assembly of the Strike Device (Figure 1)

1. Remove the plunger from a 1 mL tuberculin syringe. Cut the barrel at the 1 mL mark.
2. Remove an aerosol barrier (3 mm height x 4 mm diameter) from a 200 µL pipette tip and use it as an impactor. Place the impactor inside the syringe barrel. Gently tap the barrel to move the impactor to the tip end, with the flat side covering the nozzle opening.
3. Attach the barrel tip end to plastic tubing that is connected to the carbon dioxide (CO₂) flow regulator of a Drosophila anesthesia station.
4. Hold the barrel vertically and clamp it to a standard clamp holder stand so that the impactor stays at the bottom of the barrel.
5. Modify a 200 µL pipette tip to make the fly holder.
   1. Cut 4 mm from the tip to make a 0.8 mm-diameter opening, allowing only the fly head to be exposed.
      NOTE: The thorax and all the other parts of the fly body will stay inside the pipette tip.
6. Modify a 1,000 µL pipette tip and a 1 mL syringe needle cap to make the connector.
   1. Cut off 44 mm from the opening of the tip. Take a 6 mm length of a 1 mL syringe needle cap and push it tightly into the remaining segment of the 1,000 µL pipette tip.

2. Operation of the Strike Device

1. Anesthetize a single 2-day-old adult female fly using CO₂ on a fly pad.
2. Gently transfer it to the fly holder using a fine brush. Tap the holder gently so that the fly head is seen outside of the tip end. If the fly proboscis is exposed outside the tip, gently tuck it back inside the tip with a blunted 1 mL syringe needle.
   NOTE: Make sure to keep the fly proboscis inside the holder. Otherwise, the fly may die from a sucking proboscis injury.
3. Tighten the fly holder to the syringe barrel with the connector so that the fly head is facing downwards.
4. Set the gas pressure at 100 kPa. Adjust the flow rate according to the experiment design.
5. Quickly turn the flow regulator toggle switch on and off so that the impactor strikes the fly head once.
6. Lift the fly holder and move it over a fly pad. Reverse the fly holder and gently tap the side to let the fly out. Leave the fly in an empty vial to recover.

3. Video-assisted Movement Tracking

1. Fill a 6-cm-diameter Petri dish with transparent silicon elastomer to make the tracking arena. Leave a 3 mm space between the silicon and the dish lid to allow the flies to walk freely but not fly.
2. Anesthetize four flies from either the sham or treated group each time and place them in the arena. Leave the flies at 22 °C for 1 h.
3. Position a Charge-Coupled Device (CCD) camera above the arenas and record for 5 min.
4. Analyze the recorded movement trajectories using Ctrax software (freely available from Caltech)¹⁶. Export the tracked data in a programming language (e.g., Matlab)-compatible format and analyze the data based on distance traveled per frame¹⁷. Calculate the mean walking distance for each fly and combine it with all other recorded flies/group to obtain a mean cumulative distance travelled by the population of files in the same group.

Access restricted. Please log in or start a trial to view this content.

Wyniki

To establish a CTE model using adult Drosophila, we determined the effectiveness of our device at inflicting a single closed-head injury. To eliminate the variations relating to genotype, sex, or age, we used 2-day-old Canton-S WT female flies in the experiment. We could easily control the strength of the impactor by regulating the flow rate of CO₂ at a constant gas pressure of 100 kPa. Flies exposed to a single strike at the highest flow rate (15 L/min) exhibited mini...

Access restricted. Please log in or start a trial to view this content.

Dyskusje

Animal models that faithfully model CTE features, including neurophysiological alterations, neuropathological hallmarks, and neurobehavioral deficits, are essential for uncovering disease mechanisms and for developing diagnostic and therapeutic targets. It is understandable that no animal model of a human disease is perfect at mimicking all clinically relevant endpoints. However, we believe that a robust CTE model should satisfy the following three requirements: (1) the impact must be directly applied to a head that has ...

Access restricted. Please log in or start a trial to view this content.

Materiały

Name	Company	Catalog Number	Comments
Aerosol Barrier	USA Scientific	1120-8810	Used as an impactor
200 μL Pipette Tip	USA Scientific	1111-0706	Used as a fly head holder
1000 μL Pipette Tip	USA Scientific	1122-1830	Used as a connector
1 mL Tuberculin Syringe	Becton Dickinson	309625
60 mm Petri Dishes	Fisher Scientific	FB0875713A	Used as a tracking arenas
Flow Regulator	Genesee Scientific	59-122WC
Standard Clamp Holder/stand	EISCO Scientific	CH0688
Fine Brush	Genesee Scientific	59-204
Flypad	Genesee Scientific	59-114
Sylgard Silicone Elastomer	Dow Corning	4019862
CCD Camera	Microsoft	HD-5000
Ctrax Walking Fly Tracker	Caltech	Ctrax 0.2.11
MATLAB Image Processing Toolbox	MATLAB	R2015b