Relationships between the Circadian System and Alzheimer's Disease-Like Symptoms in Drosophila

Drosophila melanogaster were reared on diet containing 1% agar, 6.25% cornmeal, 6.25% molasses, and 3.5% Red Star yeast at 25°C. Flies were entrained to 12-hour light:dark (LD, 12∶12) cycles (with an average light intensity of ∼1500 lx). All experiments were performed on mated male flies of different ages, as specified in the results. To obtain AD model flies expressing human Aβ peptides, transgenic males carrying different UAS-Aβ constructs [15] were crossed to females carrying the pan-neuronal driver elav-GAL4 in the per⁺ or per¹ (null-mutant) background. For controls, elav or elav-per¹ females were crossed to UAS-GFP males.

Lifespan was measured using at least two bioreplicates of 4 cohorts of 50 mated males. Males of a given genotype were housed in 8 oz. round bottom polypropylene bottles (Genesee Scientific, San Diego, CA) inverted on 60 mm Falcon Primaria Tissue culture dishes (Becton, Dickinson and Company) containing 15 µL of diet. Flies were tapped to the bottom of the bottles without anesthesia for diet exchange and mortality recording every 2–3 days.

Vertical climbing abilities of male flies were measured using the RING assay following an established protocol [18]. For each genotype tested, 3 groups of 25 flies were transferred without anesthesia into empty vials and placed in the RING apparatus. The apparatus was tapped 3 times in rapid succession to initiate a negative geotaxis response. Movements of the flies in the tubes were videotaped, and digital images were captured at the 4 second mark after the tapping was completed. Using ImageJ software (NIH), the height climbed by each fly was calculated in centimeters for the snapshot at the 4 sec interval. The average of 5 successive trials, separated by 30 second rest periods, was used to calculate the performance of the flies in a single vial.

Flies of each genotype were aged to 20 days and heads were processed as previously described [19], [20]. Briefly, heads were cut in 7 µm serial sections, the paraffin was removed in SafeClear (Fisher Scientific), sections were embedded in Permount, and analyzed with a Zeiss Axioscope 2 microscope using the auto-fluorescence caused by the eye pigment (no staining was used). Experimental and control flies were put next to each other in the same paraffin block, cut, and processed together. Microscopic pictures were taken at the same level of the brain, the vacuoles (identified by being unstained and exceeding 50 pixels in size) were counted and the vacuolized area was calculated using our established methods [19], [20].

Locomotor activity patterns were monitored as described [21] using the Trikinetics Drosophila Activity Monitoring System (DAMS; Waltham, MA). Individual flies were recorded for 3 days in LD conditions and then for 7 days in constant darkness (DD). Average activity graphs were generated using GraphPad based on activity data from three consecutive 24-h periods of 12∶12 LD at 25°C. ClockLab software (Actimetrics, Coulbourn Instruments) was used to generate actograms and periodograms for the analysis of free running rhythms including period length in DD. Overall rhythm strength of individual flies was determined using a Fast Fourier Transformation (FFT) and averaged for each genotype and age. Flies with a FFT value greater than 0.04 and/or a periodogram with a peak that breaks the significance line were considered rhythmic.

To determine the functional integrity of the central clock, we measured levels of the clock protein PER in brain whole-mounts. Co-staining with PDF was used to identify specific central clock cells. Flies over-expressing Aβ₄₂arc via the pan-neuronal driver elav-GAL4 were tested along with driver (elav-GAL4/+) or responder (UAS-Aβ₄₂arc/+) controls at days 5 and 15. Samples were collected at Zeitgeber time (ZT) 22 and ZT10, which correspond, to high and low levels of PER protein in wild type flies, respectively. Whole flies were fixed in freshly prepared 4% paraformaldehyde in Phosphate Buffer Saline (PBS) with 0.1% Triton-X100 (PBS-T 0.1%) for 30 min. Fly brains were then dissected in PBS-T 0.1% and placed in wells containing PBS-T 0.1%. After dissection, the brains were fixed in 4% paraformaldehyde for 10 min, rinsed with PBS with 0.5% Triton X100 (PBS-T 0.5%), and blocked overnight in 5% Normal Goat Serum (NGS) in PBS-T 0.5%. Brains were then incubated for 48 hours in primary 1∶500 mouse nb33 monoclonal anti-PDF (Developmental Studies Hybridoma Bank) and 1∶10,000 pre-absorbed rabbit anti-PER (gift from Dr. R. Stanewsky), rinsed 6 times in PBS-T 0.5% and incubated overnight in secondary Alexa Fluor 555 anti-mouse (1∶500) and Alexa Fluor 488 anti-rabbit (1∶1000) (Life Technologies). Samples were rinsed 6 times with PBS-T 0.5% and mounted on microscope slides in Vectashield mounting media with DAPI (Vector Laboratories, Burlingame, California). Images were taken with an Olympus FV300 confocal microscope with all laser parameters held constant throughout. PER levels were evaluated by measuring the fluorescence intensity in pacemaker cell nuclei after converting the mean level of fluorescence to the Mean Gray Value that was quantified using Fiji software [22].

Lifespan graphs were plotted using survival curves and statistical significance between the curves determined using the Log-Rank (Mantel-Cox) test (GraphPad Prism v5.0;GraphPad Software Inc. San Diego, CA). Statistical significance in climbing ability across different ages and genotypes was determined using two-way ANOVA with Bonferroni's post-test using GraphPad Prism5 software. For neurodegeneration, average vacuole size and count were completed using Photoshop software with statistical significance determined by one-way ANOVA and Dunett's post-test using Graphpad Prism5 software. Statistical significance for average FFT and intensity of PER staining was calculated by unpaired t-test with Welch's correction using GraphPad Prism5.

To determine whether disruption of the clock affects longevity in AD model flies, we compared the lifespan of flies expressing various Aβ peptides in wild type (per⁺) and clock-disrupted (per¹) mutant backgrounds. Pan-neuronal expression of Aβ₄₀ peptides did not significantly shorten lifespan compared to control elav>gfp flies expressing GFP, therefore, Aβ₄₀ was considered as another control. Expression of Aβ₄₂ in flies with normal or disrupted clocks had no effect on lifespan (Fig 1A–B). Dramatic lifespan shortening (p<0.0001) was observed in flies expressing the strongly pathogenic Aβ₄₂arc but the loss of per function did not worsen this phenotype (Fig 1C).

To investigate effects of per¹ on motor impairments associated with Aβ peptides, we monitored age-specific climbing performance using RING assays. There was no significant difference in the average distance climbed between elav>Aβ₄₀ or elav-per¹>Aβ₄₀ flies, and their respective controls expressing GFP (Fig. 2A). Interestingly, the climbing ability was significantly impaired (p<0.05) at day 5 in flies expressing Aβ₄₂ in the per¹ background compared to those with normal clock. However, this difference was not observed in older flies, rather, all genotypes showed similar climbing performance on days 15, 35, and 50 (Fig 2B). Young 5-days old flies expressing the most pathogenic Aβ₄₂arc peptide showed a modest reduction in vertical climbing ability relative to elav>Aβ40 controls on day 5 (Fig 2C). Climbing ability rapidly declined in 15-days old elav>Aβ₄₂arc and elav-per¹>Aβ₄₂arc flies compared to their respective controls (p<0.0001) and was essentially lost in a few flies that survived for 25-days (Fig 2C).

We reported recently that the loss of per function accelerated brain vacuolization in neurodegeneration prone fly mutants [6]. Therefore, we examined brain health in 20-days old elav>Aβ₄₂arc and elav-per¹>Aβ₄₂arc flies and their respective controls. Control elav>gfp flies often showed a single vacuole which was however quite small (arrow, Fig. 3A). Similarly, elav-per¹>gfp (not shown) and per¹ (Fig. 3B) control flies showed some small vacuoles. Age-matched elav>Aβ₄₂arc flies showed a significant increase in vacuole number as well as size (p<0.01 to controls for both). However, the average number and size of vacuoles was not further increased when elav>Aβ42arc was combined with per¹ (Fig 3D). A quantification of this phenotype is shown in figure 3E and F.

To test whether circadian rhythms are affected by amyloidogenic peptides, daily locomotor activity patterns were compared between elav>gfp, elav>Aβ₄₀, and elav>Aβ₄₂ flies that were 5, 35, and 50 days old. Average daily activity patterns in LD were similar in all genotypes, showing morning and evening activity peaks that were attenuated with age (Fig 4A). Analysis of locomotor activity in constant darkness (DD) revealed that the endogenous activity rhythms were not significantly impaired in 5- or 35-days old elav> Aβ₄₂ or elav>Aβ₄₀ flies compared to age-matched elav>gfp controls (Table 1). However, 50-days old flies expressing Aβ₄₂ exhibited a substantial decrease in rhythm strength (Fig 4B) and the fraction of flies that remained rhythmic was only 27% compared to 67% in controls (Fig 4 C and Table 1). Representative examples of activity rhythms in 50-day old individuals are shown in Fig 4D.

We also measured locomotor activity of flies expressing Aβ₄₂arc but due to their decreased survival (Fig 1), we tested them at ages 5 and 15 days only. While, control elav>gfp flies showed strong bimodal activity rhythms in LD with morning and evening peaks preceded by anticipatory mobility increase, elav>Aβ₄₂arc flies showed an impaired activity rhythm with a reduced morning peak already on day 5 (Fig. 5A). Loss of rhythmicity was even more severe in 15-days old elav>Aβ₄₂arc flies such that the activity was distributed evenly around the clock without distinct morning and evening peaks or nighttime rest (Fig. 5A). Analysis of activity in DD revealed that the average rhythm strength was significantly decreased at both day 5 and 15 (Fig. 5B) and the percentage of rhythmic individuals was markedly reduced in Aβ₄₂arc expressing flies (Fig. 5 C; Table 1). Most of these flies were active around the clock (Fig. 5D, middle panels) and the remaining flies showed weaker rhythms (Fig. 5D, right panels) compared to well-defined rhythms recorded in age-matched controls (Fig. 5D, left panels).

The loss of behavioral rhythms in elav>Aβ₄₂arc flies could be caused by disruptions in the central clock mechanism or in the output pathways. The central clock is comprised of several groups of neurons that contribute to the control of behavioral rhythms [23]. These include two groups of neurons expressing the pigment dispersing factor (PDF); the small lateral neurons (s-LN_v) that are critical for free-running activity rhythms and the large lateral neurons (l-LN_v) important in overall arousal, as well as the PDF-negative dorsal lateral (LN_d) neurons and the 5^th s-LN_v neuron. To investigate whether the loss of behavioral rhythms in flies expressing Aβ₄₂arc was caused by defects in the central clock mechanism, we measured PER expression in these neurons using immunocytochemistry. PDF-expressing s-LN_v and l-LN_v were identified using an anti-PDF antibody. We observed strong PDF signals in both control and elav>Aβ₄₂arc flies, furthermore, the morphology and number of PDF-positive neurons (4+4) were not altered in elav>Aβ₄₂arc flies (not shown). We determined that the PER protein shows oscillations in these pacemaker neurons of elav>Aβ₄₂arc flies similar to controls with high levels of nuclear PER at ZT22 and absence of the signal at ZT10 (Fig 6A). This suggests that the pattern normally found in functional clock cells is not disturbed in elav>Aβ₄₂arc flies, although they were behaviorally arrhythmic. Quantification of the signals confirmed a lack of significant differences in relative PER fluorescence between control and experimental flies (Fig. 6B).

The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper and its Supporting Information files.