Abstract
Phospholipase D (PLD) is a key player in the modulation of multiple aspects of cell physiology and has been proposed as a therapeutic target for Alzheimer’s disease (AD). Here, we characterize a PLD mutant, pld-1, using the Caenorhabditis elegans animal model. We show that pld-1 animals present decreased phosphatidic acid levels, that PLD is the only source of total PLD activity and that pld-1 animals are more sensitive to the acute effects of ethanol. We further show that PLD is not essential for survival or for the normal performance in a battery of behavioral tests. Interestingly, pld-1 animals present both increased size and lipid stores levels. While ablation of PLD has no important effect in worm behavior, its ablation in an AD-like model that overexpresses amyloid-beta (Aβ), markedly improves various phenotypes such as motor tasks, prevents susceptibility to a proconvulsivant drug, has a protective effect upon serotonin treatment and reverts the biometric changes in the Aβ animals, leading to the normalization of the worm body size. Overall, this work proposes the C. elegans model as a relevant tool to study the functions of PLD and further supports the notion that PLD has a significant role in neurodegeneration.
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Introduction
Alzheimer’s disease (AD) is the most common form of late-onset dementia. One of the main pathological hallmarks of AD is the accumulation of amyloid-beta (Aβ) plaques in the brain, derived from the sequential cleavage of the amyloid precursor protein (APP) by beta and gamma secretases1. Presently, there are no effective therapeutical options for AD and one potential strategy being pursued is to block Aβ pathological signaling. Remarkably, using amyloidogenesis AD mouse models, it was shown that the genetic ablation of a myriad of putative Aβ signaling downstream players, such as tau2, PrP3, GIVA-phospholipase A2 (GIVA-PLA2)4 or phospholipase D2 (PLD2)5 ameliorates rodent behavioral cognitive deficits, independently of APP processing or Aβ levels modulation.
Lipids are a major constituent of the brain and specifically signaling lipids have been shown to regulate brain functioning and to modulate various neurodegenerative processes6. Indeed, Aβ has been shown to activate a group of lipid modulating enzymes, such as PLC7, GIVA-PLA24 and PLD8. While the PLC and PLA2 pathways are well studied, less is known about the PLD pathway. In mammals, six members of the PLD superfamily have been identified9. From these, there are two canonical PLD isoenzymes, PLD1 and PLD2, which are structurally similar and enzymatically both convert phosphatidylcholine (PC) to phosphatidic acid (PA), but differ in their intracellular localization and mechanisms of regulation8,10. Interestingly, in the presence of primary alcohols, such as ethanol, PLD preferentially uses it as a substrate, producing a specific lipid, phosphatidylethanol (PEtOH), which is often used to measure PLD activity8. Even though PLD2 has been shown to be involved in Aβ signaling5, PLD1 has been proposed to modulate APP trafficking and processing11,12. As an approach to understand the role of the PLD pathway in physiology and in a pathological context, the study of PLD mutant associated phenotypes in several model organisms, such as nematodes, drosophila13,14 and mice5,15, can give key insights. Importantly, while in mice there are two PLD isoenzymes, in drosophila and in nematodes there is only one PLD enzyme16.
The study of neurodegenerative diseases in simple organisms, such as Caenorhabditis elegans, when appropriately adapted to the nematode physiology, provides a powerful tool in the identification of relevant pathological pathways17. For instance, the strain CL2355, which overexpresses human Aβ in neurons and presents multiple aberrant behaviors18,19,20, has been proposed to be an effective model to study Aβ pathological signaling.
Here, we studied the impact of PLD genetic ablation in C. elegans in a physiological context and upon crossing it with an AD-like model. We showed that PLD ablation leads to a decrease in PA levels and that PLD is the only source of PEtOH upon ethanol treatment. While we found no major behavioral deficits, we observed a small increase in the worm volume. Remarkably, PLD ablation restored not only worm volume in an AD-like model, but also had a protective effect in motor behaviors and in sensitivity to serotonin and pharmacologically-induced seizures, suggesting a disease-modifying role for PLD in C. elegans.
Results
pld-1 worms present decreased PA levels and PLD activity
In order to address the role of PLD in C. elegans lipid metabolism (Supplementary Fig. S1), we performed a lipidomic analysis to biochemically characterize the pld-1 C. elegans model. Since PLD converts PC to PA, we measured the levels of PA in N2 and pld-1 worms, using liquid chromatography-mass spectrometry (LC-MS). We found that PLD mutants present a ~50% decrease in total PA levels (Fig. 1A). Specifically, six molecular species of PA (based on their different fatty acyl composition), namely PA 32:1, PA 34:1, PA 36:1, PA 38:1, PA 38:4 and PA 40:6 were diminished, while a trend for a decrease was observed for the other species (Fig. 1B). Since PLD is not the only source of PA, we developed an in vivo PLD activity assay, relying on the incubation of worms for 1 hour with 1% ethanol and subsequent measurement of phosphatidylethanol (PEtOH), a lipid uniquely produced by PLD. We found a major decrease in multiple PEtOH species in pld-1 comparing with N2 worms (Fig. 1D), which indicates that PLD is the only source of PEtOH in C. elegans. Next, we performed an ethanol susceptibility assay, since PLD uses ethanol as a substrate to produce PEtOH. Animals were exposed to different doses of ethanol and their mean speed was evaluated. An aldehyde dehydrogenase mutant (alh-6) was used as an ethanol-sensitive control strain and we observed that in two doses (100 and 200 mM), pld-1 worms were more susceptible than N2 animals to the acute ethanol effects, similarly to alh-6 animals (Fig. 1F). Moreover, in order to test if the fraction of ethanol metabolized by PLD would be significant in the context of total levels of ethanol, we compared total ethanol levels in N2 animals and with pld-1 animals after one hour of treatment and we observed no significant differences (1.00 ± 0.10 and 0.98 ± 0.08, in N2 vs. pld-1, resp. as relative levels to control, from three independent experiments n = 250 animals per experiment). Taken together, these results show that PLD ablation in worms leads to decreased PA levels, decreased total PLD activity and impacts the sensitivity to ethanol acute effects.
PLD ablation causes no gross phenotypes in C. elegans
In order to perform a characterization of pld-1 animals, we ran a battery of tests. We first found that the number of progeny (Fig. 2A) and subsequent development (Fig. 2B), assessed by the percentage of adult worms in the total population, was unchanged. Additionally, motor behavior, which was evaluated by assessing locomotion defects, was not affected in pld-1 worms (Fig. 2C). Considering that C. elegans has different types of sensory neurons, we performed chemotaxis assays to evaluate the ability of pld-1 worms to approach or avoid a compound, and we observed no differences in the chemotactic responses for all tested chemicals (Fig. 2D and E). Moreover, we performed an associative learning task and no deficits were observed in pld-1 worms (Fig. 2F). In order to evaluate the effect of PLD ablation on survival, we performed a lifespan assay. No differences were observed in the median lifespan of pld-1 worms when compared to N2 (Fig. 2G) (Supplementary Table S2). Furthermore, in order to explore the role of PLD in PA-mediated cell signaling, we performed a dopamine susceptibility assay. Dopamine binds to dopaminergic receptors coupled to a G-protein, activating several effectors, including PLC. The activation of PLC leads to an increase in diacylglycerol (DAG) that could then be converted to PA. As previously described, DAG kinase 1 mutant worms (dgk-1) were shown to be resistant to dopamine21. However, even though DGK and PLD are both sources of PA, pld-1 animals presented no differences in the susceptibility to dopamine induced locomotion impairment (Fig. 2H). Thus, our observations suggest that PLD ablation has no impact in worm lifespan and causes no gross behavioral alterations.
PLD modulates the body size of C. elegans
As part of our characterization of PLD mutants, we performed a biometric analysis and interestingly we observed that pld-1 animals consistently presented an increase (~10%) volume of the body when compared to N2 worms (Fig. 3A and B). Importantly, we saw no differences in the defecation cycles (Fig. 3C) and the pharyngeal pumping rates (Fig. 3D) of well-fed mutants. Using Nile red fluorescence, an indicator of neutral lipid content, we showed that pld-1 animals presented an increase (~30%) in lipid accumulation (Fig. 3E and F). It was previously shown that cholesterol deprivation leads to developmentally-induced volume reduction in the F2 generation22,23. We evaluated the impact of PLD ablation in this lipid induced developmental volume deficit and we observed that pld-1 animals had no volume differences compared to N2 in cholesterol-deprived F2 generation animals (Fig. 3G). These results suggest that PLD regulates worm body size and lipid stores.
PLD functional ablation ameliorates Aβ phenotypes in an AD-like model
We had previously observed that the CL2355 strain (Aβ), which has a pan-neuronal expression of Aβ after induction by temperature up-shift to 23 °C, presented a major decrease (~40%) in worm volume (Fig. 4A). We then crossed the pld-1 strain with the Aβ strain to test the impact of PLD functional ablation in an AD-like model. Remarkably, pld-1; Aβ animals presented significantly higher volumes than Aβ worms (Fig. 4B). Taking into account our previous work showing that Pld2 genetic ablation had a protective effect in synaptic and behavioral deficits in an AD amyloidogenesis mouse model5, we tested if the functional ablation of PLD in worms had not only an effect in the volume of Aβ worms but also in other phenotypes. First, we performed a lifespan assay, conducted at 23 °C, in order to evaluate the effect of neuronal Aβ expression on overall survival. We observed a significant decrease in the median life span of Aβ worms compared to N2 and interestingly pld-1; Aβ animals presented increased median survival relative to Aβ worms (Fig. 4C) (Supplementary Table S3). Moreover, while we observed diminished egg-laying in Aβ animals (Fig. 4D), the ablation of PLD in the Aβ background resulted in an increase in the number of laid eggs (Fig. 4D) (Supplementary Fig. S3). Egg viability was not affected by either Aβ or PLD ablation (Fig. 4E). Concerning motor task assessment, both crawling and swimming were shown to be impaired in Aβ worms and, again, PLD ablation partially restored these deficits in pld-1; Aβ worms (Fig. 4F and G). We also evaluated the sensitivity of animals to serotonin, since it was previously shown that Aβ transgenic worms are more sensitive to this neurotransmitter18. Notably, pld-1; Aβ worms presented reduced sensitivity to serotonin-induced impairments when comparing with Aβ worms (Fig. 4H). Finally, we performed a pharmacologically-induced pro-excitatory assay using pentylenetetrazol (PTZ), a GABA receptor antagonist that increases neuronal excitability by disrupting the normal excitatory/inhibitory balance24. We exposed worms to different doses of PTZ and measured seizure severity. We showed that while Aβ transgenic worms have increased susceptibility to the effects of PTZ, PLD functional ablation confers a protective effect in PTZ-susceptibility induced by Aβ expression (Fig. 4I) (Supplementary Table S5). Taken together, these observations indicate that PLD ablation protects from Aβ-induced deficits.
Discussion
PLD is a lipid modulatory enzyme involved in multiple aspects of cell physiology, such as signaling and membrane trafficking processes. Furthermore, it has been implicated in pathologic conditions like cancer and neurodegenerative diseases8,25. To understand the role of PLD, mutant models have been developed using different organisms, such as mice5,15 and flies13,14. While in mammals there are two canonical isoenzymes, PLD1 and PLD2, in flies and nematodes there is only one PLD ortholog16.
Here, we present an extensive characterization of the effects of PLD ablation using a C. elegans model. We show that PLD mutants, pld-1, have decreased levels of PA (Fig. 1A) and that PLD is the only source of PEtOH (a specific product of PLD activity) (Fig. 1C). This is in accordance with the results from another model organism, showing that with the genetic ablation of PLD in drosophila, PLD was the only source of PLD activity13. In mammals, the contribution to total PLD activity by either PLD1 or PLD2 depends on the tissue or cell type. For instance, it was previously shown in the brain that while PLD2 ablation leads to decreased total PLD activity5, no changes are observed in total PA levels5,26. In another study, it was observed that PLD1 ablation led to decreased PLD activity in the liver and while there were no differences in total PA levels, PA supplementation restored autophagy deficits in PLD1 knock-out cells27. Moreover, we show that PLD metabolizes ethanol, producing PEtOH, and that pld-1 animals are more sensitive to ethanol-induced slowing (Fig. 1F). While PEtOH measurements provide direct evidence that PLD metabolizes ethanol acutely, we observed no differences in total ethanol levels after one hour treatment, suggesting, at least in C. elegans, PLD has a minor role for ethanol elimination. The increased sensitivity of pld-1 animals to acute ethanol effects could be explained alternatively by a diversion of PA synthesis or due to potential protective effects by PEtOH. Accordingly, previous reports showed that, not only chronic ethanol exposure, with associated production of PEtOH28,29, but also PEtOH itself30, induce resistance to acute ethanol effects on membranes, which suggests that PEtOH could have a protective role in acute ethanol exposure. Since in mammals there are two PLDs, the specific role of either PLD1 or PLD2 in ethanol-induced toxicity should be differentially studied.
Our results show that PLD is not essential for the survival or for the normal functioning of various behavioral tasks in a C. elegans model (Fig. 2). In mice, both PLD1 and PLD2 knock-out animals are viable5,15. Even though it was reported that PLD1 or PLD2 ablation led to decreased juvenile brain volume and to social and object recognition deficits31, no major behavioral deficits were observed by other research groups in PLD2 knock-out adult mice8,26, apart from olfaction deficits in aged animals26.
Concerning biometric and metabolic parameters, deletion of either of the PLD enzymes led to elevated body weight and increased adipose tissue content in aged animals32. However, while others did not observe elevated body weight in PLD2 knock-out animals33, PLD1 knock-out animals presented not only increased hepatic weight, but also increased triacylglycerol levels and increased cholesterol levels27. Here, in a C. elegans model, we observe that pld-1 animals present both increased size and lipid stores (Fig. 3). We show that PLD is a main source of PA in C. elegans (Fig. 1A), so it is possible that the effects of PLD perturbation could be due to altered PA metabolism. Therefore, other enzymes, which modulate PA levels, such as lipin (i.e., a phosphatic acid phosphatase), could potentially be involved in the regulation of convergent physiologic mechanisms. Curiously, it was previously shown that silencing of the C. elegans homolog of lipin (lpin-1) leads to reduced body size and defects in lipid storage34. It was also observed in C. elegans that depletion of PC synthesis enzymes stimulates sterol regulatory element binding protein (SREBP) transcription factors, increases both fat-7 levels and lipid stores35 and in a follow-up study lpin-1/Lipin-1 knock-down reduced the effects of PC-depleted conditions in a PA dependent way36. Since lipin-1 converts PA to DAG, our data raises the possibility that in C. elegans, the PA species derived from PLD, could be involved in the mechanism of lipid stores regulation observed upon lpin-1 knock-down. Moreover, lipid stores have been previously shown to be consumed through a specialized form of macroautophagy called macrolipophagy37. Since, previous reports have shown a role for PLD1 in macroautophagy38 and in the regulation of lipid stores27 we hypothesize that this could be an alternate explanation for this phenotype.
To understand the impact of PLD ablation in a neurodegenerative disease C. elegans model, we crossed pld-1 animals with the CL2355 strain, which overexpresses human Aβ in neurons. This Aβ strain was shown to present multiple behavioral deficits and decreased survival18,19,20. We had previously observed that C. elegans expressing Aβ presented decreased worm size, and remarkably, pld-1; Aβ animals had a significant recovery in animal volume (Fig. 4B), with a major impact in worm survival (Fig. 4C). Additionally, PLD ablation in pld-1; Aβ animals had a protective effect in motor behaviors (Fig. 4F and G) and in the defective responses to serotonin (Fig. 4H) and PTZ (Fig. 4I). This is in line with previous results showing that Aβ leads to increased total PLD activity and that PLD2 genetic ablation ameliorates synaptic and behavioral deficits in an amyloidogenesis AD mouse model, independently of an effect on APP processing5. Interestingly, in an unbiased gene expression study, it was observed in another C. elegans strain expressing human Aβ that the toxic peptide leads to gene expression changes that overlap with changes induced by the membrane pore-inducing toxin, Cry5B39, suggesting that membrane damage mechanisms could be important pathways induced by Aβ. In fact, PLD has been shown to be involved in membrane damage pathways40. Moreover, fly PLD was shown to be required to support rhabdomere volume during illumination, a task that relies on active membrane turnover13. Previously it had been shown that PLD overexpression also has a deleterious impact, leading to degeneration of rhabdomeres14,16. These reports in drosophila, show that either a decrease or increase in PLD levels can have a functional impact in fly rhabdomeres, which highlights the importance of tightly regulating PLD activity in physiologic processes with high membrane turnover.
To our knowledge, this is the first report evaluating the impact of PLD ablation in C. elegans. We further present observations that support PLD as a downstream pathway of Aβ’s interaction with membranes or a putative membrane receptor. Overall, we observe multiple phenotypes that somewhat phenocopy previous observations in other PLD genetic models. Future studies will be able to benefit from C. elegans PLD models as relevant tools to study the role of PLD in physiologic and pathologic mechanisms.
Methods
Nematode Strains and culture conditions
Strains used in this work were acquired from the Caenorhabditis Genetics Center, namely Bristol N2; RB1737, pld-1(ok2222) II; CB1370, daf-2(e1370) III; CF1038, daf-16(mu86) I; PS2627, dgk-1 (sy428) X; PR811, osm-6 (p811) V; PR696, che-1 (p696) I, and CL2355, smg-1(cc546) dvIs50 I, dvIs50 [pCL45 (snb-1: Abeta 1–42::3’ UTR(long) + mtl-2::GFP]. The CL2355 strain has a pan-neuronal expression of Aβ1–42, which is inducible by temperature up-shift to 23 °C. The transgenic strain is referred to as neuronal Aβ strain. All the strains were backcrossed to Bristol strain N2 eight times. Strain CL2355 was crossed with strain RB1737 using standard procedures, generating pld-1; Aβ animals. Worms were grown in agar plates with nematode growth media (NGM) at 20 °C as previously described41. In the experiments where the Aβ strain was used, the animals grew 36 h at 16 °C followed by temperature upshift to 23 °C. Synchronized cultures were used for all assays and obtained through egg laying, by collecting embryos laid by adult animals during 3 h or using a bleaching procedure, by treating animals with an alkaline hypochlorite solution (0.5 M NaOH, 2.6% NaClO) for 7 min42.
Lipid analysis
N2 and pld-1 animals were incubated in the presence or absence of ethanol (1%) for 1 h and all samples were immediately collected, frozen in liquid nitrogen and stored at −80 °C until further processing. Approximately 100 animals were used per sample. Lipids were subsequently extracted by a chloroform/methanol extraction, as previously described43,44. Lipid species were analyzed using a 6490 Triple Quadrupole LC/MS system (Agilent Technologies, Santa Clara, CA) operated in multiple reactions mode (MRM). PA and PEtOH levels were quantified by comparing to spiked internal standards diC17-PA and diC16-PEtOH (Avanti Polar Lipids). Lipid concentration was normalized by molar concentration across all species for each sample, and the final data is presented as the mean mol %43,44.
Ethanol susceptibility assay
Plates (60 mm) with 8,5 mL NGM and 1 mL of ethanol at final concentrations ranging from 100 to 500 mM (adjusted to the volume of the agar) were freshly prepared. Plates were then sealed for 2 h at room temperature (RT) and copper rings (10 mm diameter) were melted onto the agar surface. Day three synchronized worms were placed in plates in the absence of food for 30 min prior to the assay, and then transferred to the ethanol plates. After 20 min of exposure, one-min videos were taken with an Olympus PD72 digital camera attached to an Olympus SZX16 stereomicroscope. Mean worm speed was quantified using the dVision software (Delta Informatika ZRt, Budapest, Hungary)45.
Ethanol Assay Kit
Worms were synchronized by egg laying and grown at 20 °C until they reached the adult stage (day three post-hatching). Ethanol levels were assayed using the ethanol assay kit (MAK076, Sigma). Briefly, nematodes were washed in M9 buffer and 50 worms were placed per well to a final volume of 50 µL with the ethanol assay buffer. The master reaction mix was prepared according to the specifications of kit. To each well, 50 µL of the master reaction mix were added, and incubated for 60 min at room temperature, after which the absorbance at 570 nm (A570) was measured. The concentration of ethanol was determined based on the A570 of standards provided in the kit.
Fecundity and Egg Viability Assay
Animals were synchronized by egg-laying. At day three, animals were individually transferred into 30 mm plates (10 animals per strain) with a bacterial lawn of 10 mm of diameter. After 5 h, all worms were removed and the total number of eggs in each plate was counted. The plates were maintained at 4 °C in order to delay egg hatching, while counting them. Egg viability was determined as the percentage of eggs that were able to hatch over the following 24 h.
Brood Size
Brood size evaluation was performed as previously described46. Briefly, 15 L4 animals, per strain, were kept at 23 °C in individual plates (30 mm) with a bacterial lawn of 10 mm of diameter and allowed to lay eggs. Animals were transferred to fresh plates daily and total progeny counted every day for 8 days.
Development
Synchronized worms through hypochlorite treatment were placed in a freshly seeded NGM plate (50 animals per strain). After 48 h, the percentage of animals which were in the L4 to adult stage was scored.
Motility assay
The motility assay was performed as previously described47 at RT (~20 °C), using day three synchronized animals grown at 20 °C. Five animals were placed simultaneously in the middle of a freshly seeded plate, equilibrated at 20 °C. Animals remaining inside a 10 mm circle after 1 min were scored as locomotion-defective. At least 150 animals were scored for each strain in three independent assays.
Chemotaxis assay
Chemotaxis assays were performed based on the assays previously developed48,49. Well-fed, synchronized adult day three animals (through bleaching) were collected and washed with S-Basal buffer three times to remove all the food. The assay plates (20 g/L agar-agar; 5 mM KH2PO4; 1 mM CaCl2; 1 mM MgSO4) were prepared by adding 1 µL of 5 M NaCl or 0.1 M isoamyl alcohol (IAA) 10 mm from the center of the plate on one side. On the opposite side of the plate, a 1 µL drop of water or of 100% ethanol was added. Afterwards, 1 µL of 1 M sodium azide was additionally added to the preexisting spots to paralyze the animals. Worms (~100–200) were quickly transferred to the center of the plate and the excess of liquid removed with a filter paper. The assay plates were incubated at 20 °C for 60 min and the chemotaxis index was scored as the (number of animals at attractant - number of animals at counter-attractant)/Total number of animals in assay. Three to four independent assays were conducted with at 100 to 150 animals per assay per plate. For each strain, two to three plates were tested per assay.
Short-term and Long-term Associative Memory Assays
A C. elegans odorant preference assay protocol was adapted from previous reports50. A chemotaxis assay using 1 M diacetyl (Sigma-Aldrich) was performed as described above in order to confirm that the animals’ genotype did not affect the chemotaxis index to diacetyl (naive group). To assess the 1× associative learning, well-fed day three animals were starved for 1 h in the presence of diacetyl and placed on the lid of the plates. Right after the starvation period, the chemotaxis index was scored again to assess learning (represented as starv 1 h in the graph). After conditioning the worms with diacetyl, worms were placed on NGM plates with food for 1 h. To test for short-term associative memory of the food-diacetyl association, the chemotaxis index was again evaluated (short memory). The long term associative memory was performed 24 h later (long memory). As a control, the same conditions were tested in fed animals to test for habituation.
Lifespan
Synchronized adult animals were placed on 60 mm NGM plates at 20 °C, examined every day and scored as dead if no mechanical response was obtained after gentle touch with a platinum wire. Animals were transferred to fresh plates every 2 days to avoid starvation and progeny contamination. Animals were censored from the analysis if lost, desiccated on the edge of plates, if showing extruded gonad or suffered internal progeny hatching. Evaluations ended after all animals were dead or censored. The lifespan evaluation at 23 °C was performed as described above. Experiments were performed blindly.
Dopamine susceptibility assay
Worms were synchronized by egg laying and grown at 20 °C until they reached the adult stage (day three post-hatching). Different solutions of dopamine hydrochloride (Sigma-Aldrich) (concentrations ranging from 100 to 800 mM) were prepared and 1 mL of the solution was added to NGM plates (60 mm) without OP50 and allowed to dry for 60 min. The adult worms were placed in each plate (10 animals per strain) and after 30 min their motor phenotype was assessed according to the following scores: 0 for normal locomotion, 1 for sluggish/slower movement, 2 for semi-paralysis (body bends without moving), 3 for paralysis (only the head moves after mechanical stimulation) and 4 for death21.
Biometric analysis
Biometric analysis was performed at 72 h after egg laying. Length and diameter measurements were calculated using ImageJ software®, and volume was determined by treating worms as cylinders (v = π*r2*l)51.Biometric analysis of F2 animals was performed using the progeny of synchronized worms grown in NGM plates with or without cholesterol. Pictures were acquired 72 h after hatching. Worms were photographed using an Olympus PD72 digital camera attached to an Olympus SZX16 stereomicroscope.
Nile Red Staining
The Nile red staining protocol was adapted from previously described protocols52. Nile red (Molecular Probes) was dissolved in a 0.5 mg/mL acetone stock solution. On the day of the assay, the stock solution was freshly diluted in 1× PBS to a final concentration of 1 µg/mL. Egg laying synchronized worms were washed 3 times with M9 and transferred to a conical tube containing Nile Red. Worms were incubated at 20 °C for 2 h and washed 3 times to remove the excess of dye before imaging52.
Confocal Imaging
For confocal dynamic imaging and quantification of Nile Red staining, live animals were paralyzed with 3 mM levamisole (Sigma-Aldrich) and mounted on a 3% agarose pad. All images were acquired on an Olympus FV1000 (Japan) confocal microscope, under a 60× oil objective and resolution of 640 × 640. A z-series image was acquired for all treated worms using a 594 nm laser. The pinhole was adjusted to 1.0 Airy unit. The images were analyzed and processed using ImageJ software®.
Thrashing analysis
Single synchronized adult animals were transferred to a 10 µL drop of M9 buffer. After 1 min animals were filmed at a rate of 15 frames-per-second, in a total of 600 frames, using an Olympus PD72 digital camera attached to an Olympus SZX16 stereomicroscope. The number of total body bends per 30 seconds was then quantified using ImageJ software® with the wrMTrck plugin53.
Defecation Motor Program (DMP)
Adult well-fed synchronized worms (10 per strain) were placed on NGM plates (90 mm), freshly seeded with OP50, for 10 min. Each animal was individually evaluated for exactly 10 min and the total number of DPMs was counted in this interval. The results were expressed as the average time (in seconds) between each successive cycle.
Pharyngeal Pumping
Synchronized day three worms were placed on plates (90 mm) freshly seeded with OP50. After 1 h, worms present in the border of the OP50 were selected and recorded with an Olympus PD72 digital camera attached to an Olympus SZX16 stereomicroscope (10 worms per strain). Each movie was recorded for 30s and the total number of pharyngeal contractions was counted in this interval.
Serotonin Sensitivity Assay
The serotonin assay was performed as previously described18. Serotonin (creatine sulfate salt, Sigma-Aldrich) was dissolved in M9 buffer to 1 mM. Synchronized three-day worms underwent temperature upshift to 23 °C to activate transgene expression of the Aβ strain, prior to the assay. Worms were washed with M9 buffer and placed in 200 µL of serotonin 1 mM in a 96-well plate. The animals were scored as active or paralyzed in each well after 5 min.
PTZ susceptibility Assay
The PTZ susceptibility assay was adapted from others24. Plates (30 mm) were prepared with 3 mL NGM each (without food). A stock solution of 100 mg/mL PTZ (Sigma-Aldrich) and the respective dilutions (20, 40, 50, and 80 mg/mL) were prepared. To each plate, 250 µL of PTZ was added. The plates were allowed to dry for 90 min in a flow chamber. Afterwards, 5 times concentrated OP50 was added to the center of each plate. The susceptibility assay was evaluated by placing worms in the bacterial lawn in each plate. After 30 min, each worm’s phenotype was evaluated using the following score: 0 for no major decrease in worm movement, 1 for sluggish/slower movement, 2 for semi-paralysis (body bends without moving), 3 for paralysis (only the head moves after mechanical stimulation) and 4 for death.
Statistical analysis
A confidence interval of 95% was assumed for all statistical tests. Normality was tested using the Kolmogorov-Smirnov test, and was assumed for all tested variables. In all experiments comparing two variables, the data was analyzed with Student’s t-test with the Levene’s test for equality of variances. When more than two variables were analyzed, a one-way analysis of variance with the Levene’s test for equality of variances and a post-hoc Tukey test for multiple comparisons was performed. The ethanol and dopamine susceptibility assays were analyzed using a two-way analysis of variance with the Levene’s test for equality of variances and a post-hoc Tukey test for multiple comparisons. The PTZ susceptibility assay was analyzed using a repeated measures analysis of variance with the Mauchly’s test for sphericity and a post-hoc Games-Howell test for multiple comparisons. Lifespan was evaluated by the log-rank (Mantel-Cox) test and the Hazard Ratio obtained from a Cox regression model, using the strain as a categorical covariate and a simple contrasts analysis. Statistical analysis was performed using GraphPad Prism 6.01 software® and SPSS 22.0 (SPSS Inc.)
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Acknowledgements
We would like to thank members of the Oliveira and Maciel labs for discussions, for critical analysis of data and discussions on the manuscript. Ricardo Rosa for his technical assistance in lifespan assays and Carlos Bessa for his technical suggestions. Thanks to the Caenorhabditis Genetics Center (CGC), which is funded by the National Institutes of Health – National Center for Research Resources, for some of the nematode strains. Costs with acquisition and transfer of genetic C. elegans models were covered by Tiago Gil Oliveira. This work was supported by grants from the Portuguese North Regional Operational Program (ON.2 – O Novo Norte) under the National Strategic Reference Framework (QREN), through the European Regional Development Fund (FEDER), the Portuguese Foundation for Science and Technology PD/BD/52286/2013 (Francisca Vaz Bravo) as well as NIH ADRC grant P50 AG008702 to Scott A. Small (project G.D.P.) and NIH grant R21 AG045020 to G.D.P.
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T.G.O. conceived the idea. F.V.B., A.T.C. and T.G.O. designed and planned the experiments. F.V.B. and J.D.S. performed the experiments. R.B.C. and G.D.P. performed the lipidomic analysis. F.V.B., J.D.S., A.T.C. and T.G.O. analyzed the data. F.V.B. and T.G.O. wrote the paper and all authors reviewed and corrected the manuscript.
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G.D.P. is a full time employee of Denali Therapeutics Inc. G.D.P. and T.G.O. are inventors on the patent number WO2010138869A1 entitled “Modulation of phospholipase D for the treatment of neurodegene-rative disorders”. R.B.C., G.D.P. and T.G.O. are inventors on the patent number US20120302604A1 entitled “Modulation of phospholipase D for the treatment of the acute and chronic effects of ethanol”.
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Bravo, F.V., Da Silva, J., Chan, R.B. et al. Phospholipase D functional ablation has a protective effect in an Alzheimer’s disease Caenorhabditis elegans model. Sci Rep 8, 3540 (2018). https://doi.org/10.1038/s41598-018-21918-5
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DOI: https://doi.org/10.1038/s41598-018-21918-5
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