We describe the first endurance training protocol for an important genetic model species, Drosophila melanogaster, and outline several assays to chart improvements in mobility following training.
One of the most pressing problems facing modern medical researchers is the surging levels of obesity, with the consequent increase in associated disorders such as diabetes and cardiovascular disease 1-3. An important topic of research into these associated health problems involves the role of endurance exercise as a beneficial intervention.
Exercise training is an inexpensive, non-invasive intervention with several beneficial results, including reduction in excess body fat 4, increased insulin sensitivity in skeletal muscle 5, increased anti-inflammatory and antioxidative responses 6, and improved contractile capacity in cardiomyocytes 7. Low intensity exercise is known to increase mitochondrial activity and biogenesis in humans 8 and mice, with the transcriptional coactivator PGC1-α as an important intermediate 9,10.
Despite the importance of exercise as a tool for combating several important age-related diseases, extensive longitudinal genetic studies have been impeded by the lack of an endurance training protocol for a short-lived genetic model species. The variety of genetic tools available for use with Drosophila, together with its short lifespan and inexpensive maintenance, make it an appealing model for further study of these genetic mechanisms. With this in mind we have developed a novel apparatus, known as the Power Tower, for large scale exercise-training in Drosophila melanogaster 11. The Power Tower utilizes the flies’ instinctive negative geotaxis behavior to repetitively induce rapid climbing. Each time the machine lifts, then drops, the platform of flies, the flies are induced to climb. Flies continue to respond as long as the machine is in operation or until they become too fatigued to respond. Thus, the researcher can use this machine to provide simultaneous training to large numbers of age-matched and genetically identical flies. Additionally, we describe associated assays useful to track longitudinal progress of fly cohorts during training.
1. Power Tower Setup and Operation
2. Exercise Protocol
3. Exercise and Locomotor Fatigue
4. Exercise, Age, and Locomotor Ability
5. Representative Results
Wild-type flies respond to an endurance protocol with a diminished age-related decrease in climbing ability that persists following the end of training, as reflected in longitudinal RING assays across five weeks of age (Figure 3A). This delayed decline in negative geotaxis is a standard phenotypic response that can serve as a positive control to ensure that wild-type exercise response is occurring normally. This data set is presented as an example of how the induction of exercise by the Power Tower program can be used as a behavioral input. The ability of various genetic or environmental factors to modulate this effect can then be assessed.
Conversely, the Power Tower can also be used as an output in various experimental designs. For example, genotype, diet, or other conditions can be varied. Then, the effect of these variations on exercise physiology can be tested using the Power Tower. Here, we show an example of this approach. When flies with a varying percentage of sucrose in their diets were tested for time to fatigue, increased sucrose content correlated with increased endurance capacity (Figure 3B).
Figure 1. Operation of the Power Tower. (A-C) The motorized bent arm with attached roller rotates clockwise until it comes into contact with the bent square tube. (D,E) The arm pushes down on the bent square tube, causing the platform that is laden with vials of flies to lift. (F) As the arm clears the tube the platform is allowed to fall back down, forcing the flies to return to the bottom of the vial.
Figure 2. Suggested Exercise Protocol. Flies subjected to the training protocol are made to exercise for five days each week under a three-week long ramped regimen that progressively increases the duration of exercise from the initial 2 hours by 30 minutes each week. Standard analyses include fatigue assays before and following the exercise program and RING assays from week 1 through week 5. All assays are performed in duplicate on an equal number of unexercised flies as a negative control. Other various physiological or biochemical tests can be conducted as determined by the researcher.
Figure 3. Endurance exercise alters multiple aspects of mobility. (A) RING assays performed longitudinally across ages in a single pair of male Y1W67C23 cohorts. Age-matched, genetically identical exercised and unexercised control flies were measured daily for average climbing speed. Results are expressed in terms of a climbing index that is normalized to the average climbing height across the first three days of measurement. Exercise-trained flies displayed a diminished age-related decline in negative geotaxis ability compared to age-matched unexercised siblings across ages (2-way ANOVA, p < 0.005). (B) Fatigue assays conducted for 8 hours on age-matched female Canton S flies show a significant effect of dietary sucrose content on time to fatigue (Log-rank, p < 0.0001). Prior to experiment, flies were fed a yeast/sucrose/agar diet, with 10% weight/volume yeast concentration, and a varying percentage of dietary sucrose. Five vials of 20 flies each were tested for each diet. Graph displays how many vials still have five or more flies running at a given time point. These results can be treated statistically and graphically as a survival (or time to failure) curve, with “failure” for a vial being defined as a point in time when less than five flies continue to respond to negative geotaxis stimulus. Note that many other possible study designs and statistical treatments are possible, and data treatment and measurement should be tailored to fit individual purposes.
The general protocol presented here has been successful in documenting physiological effects following training. However, several areas in this protocol are subject to modification to fit particular experimental needs. For example, the length of training and number of bouts could potentially be varied to make the program more or less challenging, as desired. The height of the container in which negative geotaxis ability is measured could be altered to increase the available area for improvement to be documented. Various methods of automating quantitation of climbing speed may also be applicable. In principle, any software program capable of distinguishing a fly from background can be used to speed the data gathering process.
Some aspects of the protocol should be modified only with great caution, however. For example, preliminary experiments strongly indicate that at least one day of rest per week tends to facilitate greater improvement than relentless daily exercise. Additionally, circadian rhythms and temperature are known to affect the movement of cold-blooded animals. The time of day that training takes place can be varied, but should always be consistent within particular groups under comparison, in order to avoid the possibility of confounding effects of circadian rhythms. Temperature control is also essential, and we recommend a dedicated room at constant temperature to house exercise equipment. Lastly, males and females must be reared and measured separately, in order to avoid the potential of confounding effects of fertility and sex differences in exercise capacity.
Potential applications of this methodology are limited only by the imagination of the researcher. In preliminary work, we have utilized this methodology in three broad applications:
Each of these applications encompasses a wide variety of specific possibilities. Based on our preliminary experience, mutant phenotypes tend to vary with exercise level as much as they vary with diet. The use of invertebrate models to better understand the relationship between diet, exercise, and aging physiology is perhaps the most important general application of this protocol.
The authors have nothing to disclose.
This work was supported by a grant from the NHLBI to RW.
Name of the reagent | Company | Catalogue number | Yorumlar |
Dayton Gearmotor | Grainger | 1LRA6A | |
Raco Electrical Box | Grainger | 5A052 | |
Raco Cover | Grainger | 5A053 | |
Cooper Bussmann Fuse | Grainger | 6F043 | |
Cooper Bussmann Fuse Holder | Grainger | 1DD33 | |
Carling Technologies Switch | Grainger | 2X464 | |
Dayton Control, AC/DC Speed | Grainger | 4X796 | |
Flugs for Narrow Plastic Vials | Genesee Scientific | 49-102 |