Signature profile of cyclooxygenase-independent F2 series prostaglandins in C. elegans and their role in sperm motility

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Abstract

We previously discovered that Caenorhabditis elegans synthesizes Cox-independent F-series prostaglandins (PGs). To delineate the Cox-independent prostaglandin pathways and evaluate their role in sperm motility in C. elegans, we developed a novel biochemical method for the rapid production of F-series PGs using arachidonic acid as the substrate and worm lysate as source of enzyme(s). Among the four F2-series PGs produced in the reaction, three of them were identified as 8-isoPGF2α, 5iPF2 VI, and PGF2α based on their retention times and MS/MS spectral comparison with standards using LC-MS/MS. PG production was not markedly affected by specific antioxidants, or Cox, Lox, and Cyp inhibitors, suggesting that these PGs are formed through a novel, biologically regulated mechanism in C. elegans. This study also assessed the ability of 8-isoPGF2α, 5iPF2 VI, PGF2α, and a mixture containing these PGs in a 0.5/0.08/1 ratio that reflects their synthetic composition to modulate sperm motility in fat-2 mutants. PGF2α and the PG mixture at 25 μM concentration significantly stimulated sperm velocity by 28% and 38%, whereas 8-isoPGF2α and 5iPF2 VI reduced the velocity by 21% and 30%, respectively, compared to vehicle control. These results indicate that the sperm motility effects of PGs are structure- and composition-dependent in C. elegans.

Introduction

Prostaglandins (PGs) are lipid signaling molecules derived from 20 carbon polyunsaturated fatty acids (PUFAs) such as arachidonic acid (AA), dihomo-gamma-linolenic acid (DGLA) and eicosapentanoic acid (EPA)1. They are known to impact many biological processes including development, reproduction, immunity, inflammatory diseases, and cancer2,3. Classically, these bioactive PGs are synthesized via the cyclooxygenase (Cox) enzymes, which convert AA to PGH21,4,5. Various PG synthases further convert this PGH2 to PGD2, PGE2, and PGF2 in specific tissues1. The canonical Cox mediated pathway of PG synthesis has been extensively studied in many organisms. However, other non-Cox mediated pathways have also been reported, including both enzymatic and non-enzymatic mechanisms. For example, the coral Plexaura homomalla synthesizes 15R-PGs through a novel 15R-Cox isozymes6,7,8. The insect firebrat Thermobia domestica and tobacco hornworm Manduca sexta synthesize PG-like compounds via lipoxygenase (Lox) enzyme9,10. PGs derived from non-enzymatic mechanisms generate a broad spectrum of PGs (also known as isoprostanes) and are mediated through the free radical-induced peroxidation of PUFA precursors11. These PGs can be differentiated from their biosynthetic isomers based on their unique stereochemistries. In addition to the above pathways, alternative pathways for specific PG synthesis are also reported in lower organisms such as nematodes, arthropods and yeasts12,13.

The nematode, C. elegans synthesizes PGs via an uncharacterized, Cox-independent mechanism14,15. To date, no Cox-like enzyme has been identified in the C. elegans genome, yet these nematodes synthesize abundant levels of a specific class of F-series prostaglandins (PGFs)15. In C. elegans, these PGFs are synthesized in the oocytes and play a critical role in sperm chemotaxis and motility14,16. Previous results from our lab demonstrated that this Cox-independent pathway may be conserved in mammals. Cox-1/Cox-2 double knockout mice and human follicular fluid showed distinct PG profiles that match that of C. elegans16,17. Furthermore, these PG profiles differed significantly from that of Cox- and ROS-derived PGs. The identification of this novel Cox-independent pathway may have strong clinical implications as this pathway is refractory to NSAIDs, whose effect on PG levels play a major role in regulating many biological processes including fertility and cancer18,19.

In this study, an in vitro assay was developed to facilitate the identification of key players in this pathway and to provide further insights into this Cox-independent PG synthesis mechanism. We show that Cox-independent PGs could be produced in vitro with a small volume of worm lysate (WL) and have functional consequences for sperm motility in C. elegans.

Results

In vitro non-Cox mediated PG production

Previous studies from our lab demonstrated that C. elegans produces three F-class PGs despite the lack of Cox encoding genes in its genome14,15. These PGs, PGF1, PGF2, and PGF3, are derived from DGLA, AA, and EPA PUFA precursors, respectively. The mechanism for PG synthesis in C. elegans has yet to be identified. To facilitate the identification of the key components of this pathway, we first developed an in vitro assay. To this end, we initially examined whether WL can produce PGs when exogenous PUFAs are added to the reaction. Crude WL was incubated with or without 100 µM DGLA, AA, or EPA in Tris-Cl buffer (pH 8, 100 mM) for 10 min at room temperature. The reaction products were extracted and analyzed by LC-MS/MS operated in multiple reaction monitoring (MRM) mode. In MRM, mass transitions m/z 355/311, 353/193 and 351/193 are indicative of PGF1α, PGF2α, and PGF3α, respectively. When WL was incubated with DGLA or AA, MRM analysis of the reaction products showed significant peaks at retention time (Rt) 11.8 and 11.7 min (Supplemental Fig. 1D,E) that correspond to PGF1α (Rt 11.8 min) and PGF2α (Rt 11.7 min) standards (Supplemental Fig. 1A,B), respectively. However, incubation of WL with EPA did not yield detectable levels of PGF3α. This suggests that the WL is enzymatically active in this in vitro reaction and can convert exogenous DGLA and AA into its corresponding PGs (Supplemental Fig. 1F). We next examined whether endogenous PUFA levels in the WL would be sufficient to produce detectable amounts of PGs. LC-MRM analysis with the mass transition m/z 353/193 showed detectable levels of PGF2α in WL without the addition of exogenous AA, indicating that sufficient AA is present in the WL (Supplemental Fig. 1H). However, F1 and F3 class PGs were not detected in the WL without the addition of exogenous DGLA and EPA (Supplemental Fig. 1G,I).

Next, we hypothesized that the PGs synthesis is enzymatic under in vitro condition and denaturing the WL would abolish the conversion of AA to PGF2α. To test this, we boiled the WL before incubating with AA. MRM analysis of boiled WL, incubated with AA, showed approximately 79% reduction in PG production when compared to control (Supplemental Fig. 2), suggesting the PGs produced in the in vitro reaction is mediated by an enzymatic mechanism.

A long-term goal of this study is to use an in vitro approach to identify the enzyme(s) responsible for PG production. Understanding where this enzyme(s) is localized can provide insight into the identity of this protein(s). To identify the cellular compartment that is reponsible for the maximal PG synthesizing activity, we fractionated the WL into the soluble (cytosolic) and particulate (membrane) fractions by differential centrifugation. MRM chromatograms (mass transition m/z 353/193) showed that each of the subcellular fractions obtained after differential centrifugation can convert AA to PGF2α. However, the maximum PGF2α level was produced with the soluble fraction (Supplemental Fig. 3).

On reacting the soluble fraction with 100 µM AA for 10 min, four major peaks appeared at Rt 11.2, 11.5, 11.7 and 11.9 min in the MRM chromatograms (mass transition m/z 353/193) (Fig. 1). Among the four MRM peaks, Rt 11.2, 11.5 and 11.7 min corresponded to 8-isoPGF2α, 5iPF2 VI and PGF2α, respectively, based on matches with synthetic standards (Fig. 1A–C). We could not find a matching standard for the MRM peak eluting at Rt 11.9 min, so it remains unidentified. Each experiment was performed in triplicate along with controls (WL alone and AA alone). PGF2α-d9 was used as an internal standard to examine the extraction and ionization efficiency of the products. Together, these experiments showed that WL converted AA into four isomers of PGF2α via enzyme(s) and the soluble fraction exhibited major activity. Therefore, the soluble fraction was used for all subsequent experiments.

Figure 1
figure1

MRM chromatograms with the mass transition m/z 353/193 showing synthesis of four isomers of F2-series PGs after incubating AA with WL. Peaks eluted at Rt 11.2, 11.5 and 11.7 min corresponded to the standards 8-isoPGF2α, 5iPF2 VI and PGF2α, respectively; however, peak eluting at Rt 11.7 min remained unidentified. (A) 8-isoPGF2α, PGF2α standards (1 ng/ml) eluted at Rt 11.2 and 11.7 min, respectively. (B) 5iPF2 VI (10 ng/ml) eluted at Rt 11.4 min. (C) In vitro reaction product showing four major peaks eluted at Rt 11.2, 11.5, 11.7 and 11.9 min.

Optimization

To obtain better yield under in vitro conditions, we optimized the reaction conditions for PGF2α synthesis by altering the amounts of WL protein, AA and incubation time. PGF2α production increased with increasing concentrations of WL (Fig. 2A) and the reaction plateaued at a maximum yield of 690 ± 11.0 pg/ml/min obtained with 430 ± 20 μg of lysate protein. Further increase in WL protein did not increase the amount of PGF2α synthesized. Therefore, 430 ± 20 μg of lysate protein was selected for subsequent experiments with various concentrations of AA, over the range 1–100 μM (Fig. 2B). Increasing concentration of AA resulted higher levels of PGF2α and the maximum yield (626 ± 28.0 pg/ml/min) was obtained with 100 μM AA (Fig. 2B). PGF2α synthesis was found to be rapid, yielding 3,539 ± 595 pg/ml/min in the first min of incubation with AA (Fig. 2C); the rate was reduced to 822.3 ± 79.0 pg/ml/min after 5 min. We found that when the incubation time was increased to 30–45 min, the rate of PGF2α synthesis was reduced significantly. These experiments suggest that in vitro PGF2α synthesis is rapid and depends on protein and substrate availability.

Figure 2
figure2

PGF2α synthesis is rapid and depends on WL and AA concentrations. (A) Different concentrations of WL (90–1700 µg protein) in reaction with 100 µM AA. (B) AA concentration range 1–100 µM in reaction with 450 µg WL soluble protein. (C) Incubation of 450 µg of WL soluble protein with AA for 0–45 min. All the experiments were done in triplicates and average was plotted. Error bars are SD (±).

Characterization of PGs

Although MRM is considered a gold standard for quantitative analysis of known compounds, isobaric overlap can be a problem due to the low mass resolution of quadrupole mass analyzers. Therefore, we used high resolution and accurate mass measurement using a TripleTOF 5600 system, a hybrid quadrupole time-of-flight mass spectrometer (Qtof) to analyze the reaction products using LC-MS/MS. Furthermore, to ascertain that the added AA is the substrate that is converted in the in vitro reactions, 13C-AA (AA 1,2,3,4,5-13C) was incubated with WL and the products were analyzed. The molecular masses of 13C-AA derived PGF2s are 5 amu higher than that of its unlabeled counterparts. In the case of 13C PGF2α, the parent ion mass is m/z 358.249 and the major product ion mass is m/z 198.138.

An extracted ion chromatogram for m/z 358.249 (deprotonated precursor ion) and its product ion m/z 198.138 showed three major peaks eluting at Rt 10.3, 10.7 and 11.0 min and a minor peak at Rt 10.5 min in the reaction products of WL and 13C-AA (Fig. 3A). These peaks were not detected in the control (13C-AA alone). MS/MS spectra of the precursor ion m/z 358.249 at Rt 10.3 and 10.7 min showed major fragment ions such as m/z 198.140, 296.210, and 314.225 (Fig. 3B,C), which are 5 amu higher than those of the unlabeled counterparts as well as the major fragments from the 8-iso PGF2α and PGF2α standards. These analyses suggest that the peaks at Rt 10.3 and 10.7 correspond to 1,2,3,4,5-13C-8-isoPGF2α and 1,2,3,4,5-13C-PGF2α, respectively. The peak at Rt 10.5 min had a product ion base peak m/z 120.056 (cal. m/z 120.057 for C5H8O3 1,2,3,4,5-13C or m/z 115.040 from its unlabeled counterpart m/z 353.230) together with other product ions, such as m/z 296.211 and 314.224 (Fig. 3D). These ions are 5 amu higher than those of the unlabeled 5iPF2 VI standard, suggesting the peak at Rt 10.5 min is 1,2,3,4,5-13C-5iPF2 VI.

Figure 3
figure3

The accurate-mass precursor ion m/z 358.249 and its product ion m/z 198.139  showed  four iomers of 13C-F2-series PGs eluted at Rt 10.3, 10.5, 10.7 and 10.9 min  and fragmentation patterns of product ions allowed confirmation of the structures of three of them, namely, 13C-labeled 8-isoPGF2α, 5iPF2 VI and PGF2α. (A) Extracted ion chromatogram for m/z 358.249 and its production ion m/z 198.139.  MS/MS spectra  of m/z 358.249 at  Rt 10.3 min  (B);  Rt 10.7 min  (C);Rt 10.5 min  (D); and  Rt 10.9 min  (E).

The LC-MS/MS peak m/z 358.249 eluting at Rt 10.9 min also generated the m/z 120.059 product ion, but with lower intensity than that of the Rt 10.5 min peak (Fig. 3E). Although the MS/MS spectra of this peak (Rt 10.9  min) showed many product ions that are characteristic of PGF2-like structures, we have yet to find a matching standard; therefore, the product remains unidentified.

Effects of inhibitors on PG production

We sought to identify the enzyme(s) potentially involved in PGF2α production in C. elegans. For this, we examined a number of inhibitors for their effects on PGF2α production. Antioxidants and Cox, Lox, and Cyp inhibitors were individually incubated with WL for 30 min prior to the addition of AA. Cox-specific inhibitors (DU-697, SC-560 and indomethacin) had no marked effects on PGF2α production, compared to the control (Fig. 4). Likewise, Cyp inhibitors 17-octadecynoic acid (17-ODA), and 2-(2-propynyloxy)-benzenehexanoic acid (PPOH) did not inhibit PGF2α production in our in vitro experiments. Specific Lox inhibitors (nordihydroguaiaretic acid (NDGA), 3,4 dihydroxyphenyl ethanol (3,4 DHPE), zileuton and PD146176) also had no effect on PGF2α production. To investigate whether PG production in C. elegans is mediated by free radicals, antioxidant (BHT, 100 µM) was incubated with WL. MRM analysis suggest that the addition of BHT had no effect on PGF2α synthesis. These data suggest that this non-Cox pathway in C. elegans is unique and not affected by any of the tested antioxidants or Cox, Lox, Cyp inhibitors.

Figure 4
figure4

MRM-based quantification of PGF2α indicated that its levels were not markedly affected by antioxidants, Cox, Cyp and Lox inhibitors. Control reflects WL with AA, in the presence of DMSO (5.0% v/v) and PGF2α production in the reaction is considered as 100%. The values represent the average of three independent experiments. Error bars are SD (±).

Differences between Cox- and Cox-independent pathways

One defining characteristic of the classical Cox pathway of synthesizing PGs is the production of a prostacyclin metabolite 6-keto PGF1α from the AA precursor. We were interested to know whether 6-keto PGF1α (m/z 369, deprotonated precursor ion) was synthesized in our in vitro experiments. To test this, AA was incubated with WL in the presence or absence of ovine Cox 1, and the reaction products were assessed by MRM. MRM chromatograms with the mass transition m/z 369/163 showed no detectable 6-keto PGF1α peak in the absence of Cox enzyme. This result coincides with our previous findings showing that 6-keto PGF1α is absent from whole worm lipid extracts15. However, a peak eluting at Rt 10.47 min, corresponding to 6-keto PGF1α standard, was detected when ovine Cox 1 was present in the reaction of WL with AA (Supplemental Fig. 4). Taken together, these results suggest that the enzyme(s) responsible for PG synthesis in C. elegans is characteristically different from the Cox proteins.

Effect of PGs on sperm motility

Previously our group has reported that PGF2α can alter sperm velocity14,20. In the current study we established that C. elegans synthesize 8-isoPGF2α, 5iPF2 VI and PGF2α; however, it is unknown whether 8-isoPGF2α and 5iPF2 VI also modulate sperm motility. To test this, we utilized fat-2 mutant worms that lack PUFA synthesis. These animals have low AA levels and well as low PGF levels. Based on our earlier published protocol14,16,21, we first mated fat-2 mutant hermaphrodites with MitoTracker CMXRos-stained males. We then injected 25 µM of each compound individually or as a mixture containing 8-isoPGF2α, 5iPF2 VI and PGF2α (ratio 0.5/0.08/1 w/w, based on MRM analysis) through the vulva of the hermaphrodite. Injected worms were then rapidly mounted for time-lapse microscopy to measure sperm motility. Injected PGs showed differential effects on sperm motility. PGF2α and the PG mixture showed significant (p < 0.001) stimulatory effects, increasing sperm velocity by 28% and 38%, respectively, whereas 8-isoPGF2α and 5iPF2 VI reduced sperm motility by 21% and 30%, respectively, compared to vehicle control (Fig. 5). These data showed that 8-iso PGF2α and 5iPF2 VI had a negative impact on sperm velocity when they are used individually at high concentrations. However, when these PGs were injected as a mixture with PGF2α, their inhibitory role is not observed.

Figure 5
figure5

Sperm motility in the uterus of fat 2 mutant hermaphrodites is modulated by PGs. fat-2(wa17) mutant hermaphrodites were mated with fog-2(q71) males. PGs were injected through the vulva of the mated hermaphrodites. Sperm in the uterus of fat-2 mutant hermaphrodites are measured using time-lapse imaging. The numbers of sperm analyzed ranged between 86–121; means values are plotted and ±SEM are shown as error bars. P values (*P < 0.05) were calculated using a one-tailed student’s t test for PGF2α, and two-tailed test for 8-isoPGF2α, 5iPF2 VI and the PG mixture.

Discussion

C. elegans synthesizes specific F-series PGs via an unidentified enzymatic pathway that acts independently of the classical Cox enzymes. We previously reported that this novel pathway, which is refractory to NSAIDs, may be conserved in mammals, including humans16,17. Since PGs regulate many physiologic and pathologic processes in the human body, the unconventional PG synthesis pathway identified in C. elegans may have significant clinical implications17. In order to identify the key players that are responsible for the Cox-independent PG synthesis, we develped an in vitro assay that will facilitate further downstream applications, such as target protein identification.

We first established that whole WL can convert free AA to specific F-series PGs in the in vitro assay. The MRM profiles of the synthesized PG products were similar to that of endogenous PGs extracted from whole worms16, indicating that the protein(s) is behaving similarly in vitro and in vivo. To localize where the activity is most robust, we separated whole WL into the cytosolic/soluble and membrane/particulate fractions by differential centrifugation. Compared to other fractions, incubation of free AA with the cytosolic fraction yielded the most PGF2α and other specific PGF2 isomers. This suggests that the protein(s) in this Cox-independent PG synthesis pathway is predominantly cytosolic. Although Cox-mediated PG synthesis is predominantly membrane bound5, cytosolic activity has also been reported22. A possible limitation to this finding is that the fractionation protocol was not fully optimized to obtain completely pure subcellular fractions, so the activity may be partly contributed by contaminents from broken membranes or organelles. However, the robust activity from the cytosolic fraction, in comparison to the insoluble fractions, minimizes this possiblity and suggests that the Cox-independent PG synthesis activity is mainly distributed in the cytosolic fraction.

Next, we confirmed that the reaction is indeed driven by an enzymatic mechanism, as opposed to ROS-mediated free radical oxidation. To this end, we boiled the WL and incubated the boiled WL with AA. MRM analysis of the resulting products showed significantly reduced levels of PGs, compared to that of unboiled WL, indicating the presence of a denaturable, presumably, enzymatic pathway for PG production in C. elegans. Our optimization studies also supported this observation. Increasing WL proteins yielded increasing levels of PGF2α, reaching a plateau at the higher WL concentrations, which is a typical characteristics of enzymatic reaction. Furthermore, PG production was also increased with increasing substrate (AA) concentration and the reaction is rapid, producing significant amounts of PGF2α within one min consistent with the presence of active enzyme. Under in vitro conditions, the autooxidation process is very slow and needs initiators to get detectable levels of PGs23.

Furthermore, our MRM data showed four specific isomers in the reaction product when AA was incubated with WL. To confirm that these isomers are derived from the AA and to help distinguish contaminant products in the reaction, we used stable isotope labelled 13C-AA (AA 1,2,3,4,5-13C) as the substrate for the reaction. The resulting mass shifts by 5 units (m/z 353.230 to 358.249) in the PG products indicated that 13C-AA was readily metabolized into 13C-PGs. These specific products further suggest that these reactions are not a result of auto-oxidation. In ROS-mediated mechanisms, a nonspecific spectrum of PG isomers, or isoprostanes, is formed and esterified to phospholipids. ROS-mediated isoprostanes are composed of 5-, 12-, 8-, or 15-series regioisomers, depending on the carbon atom to which the side chain hydroxyl is attached24,25. The formation of nonspecific, esterified PG species in racemic mixtures is considered a hallmark of non-enzymatic PG synthesis. The presence of specific products generated from the WL suggests that a novel, Cox-independent biochemical pathway is likely to be involved in their synthesis. Of particular interest is the possibility that the isoprostanes 8-isoPGF2α and 5iPF2 VI can also be produced via an enzymatic pathway. Much of the conventional literature have reported the use of these isoprostanes as markers of oxidative stress21,22. However, our data suggest that these compounds may be enzymatically regulated and may have novel developmental functions and regulatory mechanisms.

This Cox-independent PG synthesis pathway shows PUFA (substrate) specificity. While DGLA appeared to be the substrate for PGF1α, EPA did not generate identifiable PGF3α, though various other isomers sharing the same mass but different retention times were detected (mass transition m/z 351/193). These results are consistent with our earlier finding using whole worm lipid extracta15. Taken together, our data support the idea that the PG synthesis pathway in C. elegans is enzyme-mediated and not a result of free radical oxidation.

Classically, PG-endoperoxide synthase (a.k.a. cyclooxygenase or Cox) mediated PG synthesis is responsible for the bulk of PG production in many animals. Cox acts on AA to generate the bicyclic intermediate PGH2, which is further reduced to PGF2α, and its analogs4,26. A hallmark of Cox-mediated PG synthesis is the production of the PGI2 metabolite 6-keto PGF1α14,15. However, an interesting feature we observe in our in vitro data is the absence of the 6-keto PGF1α metabolite, suggesting that the pathway functions independently of Cox.

Specificity in product formation is a key in any biochemical reactions. We previously demostrated that C. elegans specifically synthesizes three major F-series PGs independent of Cox enzymes15. Interestingly, in this in vitro study, three major and one minor peaks corresponding to various F2-PGs (PGF2α, 8-isoPGF2α, 5iPF2 VI) derived from AA were detected with a peak ratio of 1/0.5/0.08. Our previous studies in human ovarian follicular fluid (HFF) from IVF patients and a Cox 1/Cox 2 knockout mouse showed a similar PG profile to those in C. elegans in terms of chromatographic retention times and MS/MS spectra16,17. This suggests that this novel Cox-independent pathway may be conserved in higher animals.

Next, to investigate whether the Cox-independent de novo pathways for PG synthesis are affected by other enzymes that have been reported to have PG synthesis activity, we evaluated the effects of a number of inhibitors on the C. elegans PGF2α production. The Cox inhibitors, indomethacin, DUP-696, SC-560, had no effect on PGF2α production. These results corroborate our earlier finding that C. elegans PG synthesis is refractory to NSAIDs, such as indomethacin, acetylsalicylic acid, CAY-10404 (specific Cox-2 inhibitor), and SC-560 (specific Cox-1 inhibitor), even at concentrations 10–500 times higher than reported IC50 values11. Other than Cox, Lox and Cyp enymes have also been reported to metabolize PUFAs to eicosanoids9,10,27. Therefore, we also tested the effects of Lox and Cyp inhibitors on PGs production. Similar to Cox inhibitors, Lox inhibitors, namely NDGA, 3, 4 DHPE, zileuton and PD146176, and Cyp inhibitors, 17, ODA and PPOH, showed no effect on PG synthesis, excluding the potential contribution of Lox and Cyp enzymes to C. elegans PGs synthesis. To further rule out the possiblity of an ROS-mediated mechanism for PGF2α synthesis in vitro, we included the antioxidant BHT (100 μM) in the in vitro reaction and showed it had no marked effect on PG production. Overall, these results suggest that PGs in C. elegans are formed through a novel, biologically regulated mechanism.

We previously reported that the PGF2α in C. elegans is important for sperm motility and guiding sperm to the oocytes14,20. However, little is known about the roles of the other F2 isomers produced in C. elegans. In this study, we injected three PGs (8-isoPGF2α, 5iPF2 VI and PGF2α) individually and as a mixture containing all three PGs in a 0.5/0.08/1 ratio into the vulva of PUFA deficient fat-2 mutants. Since fat-2 mutants lack the ability to produce PGs, sperms move to the spermatheca, or fertilization site, with reduced velocity14,16. It is important to note that we didn’t test the unidentified PGF2, eluting after PGF2α, due to lack of matching standards.

The reduced sperm velocity in fat-2 mutants was rescued by injections of exogenous PGF2α and the PG mixture. However, injections of 8-isoPGF2α and 5iPF2 VI reduced the sperm velocity, compared to vehicle control. While the underlying mechanisms by which PGs influence sperm motility in C. elegans are unclear, the increased stimulatory effect of PGF2α in combination with the other PGs suggests that the combination of these compounds seems to have synergistic effects. A small caveat to the experiment is the backflow of injected PGs. While the injected concentration is 25 μM, some of the PGs may be lost through the vulva, rendering the working concentration to be less than the injected amounts.

Although the C. elegans genome does not encode Cox enzymes, a wide range of proteins with homology to mammalian PG synthases, PG transporters, PG reductases, cytochrome P450s, and phospholipases are present in its genome. Developing a reliable and reproducible assay for target identification is an important step. Our long-term aim is to identify the enzyme(s) required for Cox-independent PG metabolism and this study offers potential to help identify them using a small amount of lysate protein from C. elegans. Identifying the non-Cox enzyme(s) that catalyze PG metabolism may offer potential for discovering new PG functions in humans.

Material and Methods

Materials

The arachidonic acid (AA), eicosapentaenoic acid (EPA), dihomo-gamma-linoleic acid (DGLA) and PGs standards were purchased from Cayman Chemical Co. (Ann Arbor, MI, USA). 5-bromo-2-(4-fluorophenyl)-3-(4-(methylsulfonyl)phenyl)-thiophene (DUP-697), 5-(4-chlorophenyl)-1-(4-methoxyphenyl)-3-(trifluoromethyl)-1H-pyrazole  (SC-560), 17-octadeynoic acid (17, ODA), 2-(2-propynyloxy)-benzenehexanoic acid (PPOH), nordihydroguaiaretic acid (NDGA), 3,4-dihydroxyphenyl ethanol (3,4  DHPE), zileuton, 6,11-dihydro-[1]benzothiopyrano[4,3-b]indole  (PD146176) were also purchased from Cayman Chemical Co. (Ann Arbor, MI, USA). Indomethacin, taurine and butylated hydroxy toluene (BHT) were purchased from Sigma Chemical Co. (St. Louis, MO). All HPLC solvents and reagents were purchased from Fisher Scientific Co. (Norcross, GA) and were of HPLC grade.

Worm cultivation and preparation of worm lysate

C. elegans wild-type N2 worms were maintained at 20 °C on nematode growth medium (NGM) plates. and fed with NA22 E. coli. For worm lysate, worms were seeded to 150 mm plates and incubated at 25 °C for 7 days. Concentrated bacteria (NA22 E. coli) were fed to the worms to prevent starvation. Worms were washed off the plates with M9 buffer and 2.5 g worms were aliquotted to polypropylene tubes and stored in −80 °C for lysate preparation.

For the preparation of worm lysate, 1 ml of 0.5 mm zirconium oxide beads and 1 ml of Tris-Cl buffer (100 mM), supplemented with protease inhibitors (Roche Applied Sciences, Germany) were added to 2.5 g of the frozen worms. The mixture was homogenized at speed 9 for 6–8 min using a bullet blender 5 homogenizer (Next Advance Inc., NY, USA). The homogenate was transferred to a 1.5 ml centrifuge tube and centrifuged at 16,000 × g for 10 min at 4 °C. The supernatant was transferred in new centrifuge tube stored at −80 °C until use. Protein concentration of the worm lysate was determined by BCA assay kit (Pierce™ BCA Protein Assay Kit, Thermofisher Scientific Inc. Norcross, GA, USA) following the manufacturer’s protocol.

In vitro assay development and PGs extraction

For the synthesis of PGF2α and its isomers under in vitro conditions, 1 ml of reaction mixture was prepared with 100 mM Tris-Cl buffer (pH 8), 50 µl of 2 mM arachidonic acid (AA) and 50 µl of worm lysate (about 450 µg protein) unless otherwise stated. To determine the substrate specificity, other substrates (DGLA or EPA) were used, instead of AA, and a working 2 mM stock was prepared using 100 µl KOH (0.05%w/v), 100 µl substrate (20 mM stock in methanol) and 800 µl of ultrapure water.

The reaction mixture was incubated at room temperature for 10 min (unless otherwise indicated) and spiked with 10 µl of internal standard (10 ng/ml PGF2α-d9). Next, 4 ml of acidified (0.1% formic acid) methanol was added to the reaction mixture and the reaction was incubated on ice for 10 min to stop the reaction and inactivate the protein. The reaction mixture was centrifuged at 4,000 × g for 10 min at 4 °C, and the supernatant was collected and dried under nitrogen.

For the initial standardization, 50 µl of heme and 50 µl of 10-acetyl-3,7-dihydroxyphenoxazine (ADHP) were added to the reaction to check the requirement of cofactor for the reaction. Results showed that addition of cofactors did not increase PGF2α levels in the reaction and therefore the reactions were performed without adding heme and ADHP to the reaction.

Analysis of PG products

Quantitative analysis of PG products was carried out by liquid chromatography tandem mass spectrometry (LC-MS/MS) using a Prominence 20A HPLC (Shimadzu, Kyoto, Japan) and 6500 Qtrap (Sciex, Framingham, MA) operated in multiple reaction monitoring (MRM) mode. Seperation of analytes was carried out by a gradient over a Synergi Hydro-RP column (Phenomenex, Torrance, CA) at 50 °C using mobile phase A 0.1% formic acid (FA) and B acetonitrile with 0.1% FA with a flow rate of 0.2 ml/min. The gradient started with 10% B and was increased to 80% at 11 min and become 100% B at 14 min. After that, mobile phase B was decreased to 10% at 16 min and allowed to re-equilibrate until 20 min total time had elapsed. Sample injection volume was 20 µl in all analyses. Column effluent was directed to the MS which was operating in negative mode. MS parameters were as follows: IS 4500 V, TEM 600, GS1 40, GS2 60, Curtain 20, and CAD 20. Compound parameters were as follows: Declustering potential (DP), collision energy (CE), and cell exit potential (CXP) are set at −80 V, −35 V and −11 V for F series PGs. In case of 5iPF2 VI, CE was −30. For MRM experiments, the mass transitions m/z 353/193 (PGF2α and its isomers), 351/191 (PGF3α and its isomers), 355/311 (PGF1α and its isomers), (PGF2α-d9, internal standard) and 369/163 (6-keto PGF1α) were used. For quantification of PGF2α, a series of working PGF2α solutions (0.001–20 ng/ml) containing 1 ng/ml internal standard PGF2α-d9 was prepared and analyzed by MRM. The standard curve showed excellent linearity in the 0.01–10 ng/mL range with a correlation coefficient >0.99. Post-acquisition data analysis was performed in Analyst v3.0.1 (Sciex) and PeakView v2.2 (Sciex).

Characterization of 13C-labelled PG products

Analysis of reaction products with high mass accuracy of precursor and product ions was carried out by LC-MS/MS using a Prominence 20A HPLC (Shimadzu, Kyoto, Japan) and 5600 TripleTOF mass spectrometer (Sciex, Framingham, MA). Analyte separations were carried out by a gradient over a Synergi Hydro-RP column (Phenomenex, Torrance, CA) at 50 °C using a flow rate of 0.25 ml/min. Mobile phase A was 0.1% formic acid (FA) and B was acetonitrile 0.1% FA. Gradient starting conditions began at 10% B and was increased to 80% B at 11 min, increased to 100% B at 14 min, decreased to 10% B at 16 min and allow to re-equilibrate until 20 min total elapsed time. Sample injection volume was 20 µl in all analyses.

Column effluent was directed to the MS which was operated in negative mode ESI. MS parameters were as follows: IS 4500 V, TEM 400, GS1 50, GS2 50, and curtain gas of 25 psi. A precursor ion TOF MS Scan from 200–800 m/z for 250 ms and twenty 50 ms product ion scans from 50–1000 m/z were utilized to capture MSMS spectra. Product ion scans were set to a static 35 V CE with a 15 V CE spread for dissociation. Post-acquisition data analysis was carried out using Analyst 1.7 TF (Sciex) and PeakView v2.2 (Sciex).

Differential centrifugation

Differential centrifugation was performed at 4 °C using an ultracentrifuge as shown in Supplemental Fig. 5. Briefly, homogenized WL was centrifuged at relatively low speed (1,300 × g for 5 min). The resulting supernatant 1, after centrifuging at 17,000 × g resulted in supernatant 2 and pellet C. Supernatant 2 was centrifuged at 80,000 × g for 60 min to obtain supernatant 3 and pellet D. Subsequent centrifugation of supernatant 3 at 150,000 × g for 3 h resulted in pellet E and supernatant (S).

Inhibitor assay

Cox inhibitors (indomethacin, Sc560, DU 697), CYP inhibitors (17, ODA, PPOH, and lipoxygenase inhibitors (NDGA, 3,4 DHPE, zileuton, and PD146176) were prepared in DMSO and added to WL 30 min prior to the addition of substrate AA with a final concentration of 5.0% (v/v) DMSO. The antioxidant butylated hydroxy toluene (BHT 10 µM) was added to test for its effect on the inhibition of free radical-initiated PG products.

Sperm motility assay

The effects of PGs on sperm speed was studied following the published protocol with minor modifications14,16,21. Briefly, 50–60 fog-2(q71) adult males were picked and transferred to new plate with a spot of bacteria containing Mitotracker CMXROS dye and incubated overnight at 16 °C to stain the males. Experiments were perfomed following our published protocol21. After 30 min of mating, hermaphrodites were mounted to a microscopic slide and 25 µM of 8-isoPGF2α, 5iPF2 VI or PGF2α were injected individually or as a mixture contaning these PGs in a 0.5/0.08/1 ratio into the vulva of the mated hermaphrodites. Time-lapse images were taken at 15 sec intervals for 5 min and sperm migration distance was measured using the NIS-Elements AR analysis 5.10.01 software. For each compound, experiments were done twice with three rounds of injections each time. Eight worms were injected per round of injection and images were captured from three worms using time-lapse imaging. For the final data, worms were selected from both batches and the average sperm speed and standard error of mean were calculated from 3–4 worms with a total of 86–121 sperm per expeirmental condition. Two-tailed Student’s t-test was performed for 8-isoPGF2α, 5iPF2 VI and the PG mixture. One-tailed Student’s t-test was used for PGF2α; p < 0.05 was considered significant.

Conclusion

Our results suggest that Cox-independent PGs, including 8-isoPGF2α are formed with a signature profile through a biologically regulated mechanism. These PGs are biologically active and exhibit differential sperm motility effects in C. elegans. 8-isoPGF2α and 5iPF2 VI had inhibitory effects, whereas PGF2α and the mixture containing 8-isoPGF2α, 5iPGF2 VI and PGF2α stimulated sperm motility. The in vitro reaction using WL and AA, PGs production, appears to be unaffected by antioxidants and Cox, Lox, and Cyp inhibitors. The reaction exhibits saturation kinetics and is heat-sensitive, consistent with an enzyme-mediated process. A long term goal is to use this new assay to identify enzymes and intermediates involved in this alternate PG synthesis pathway.

References

  1. 1.

    Funk, C. D. Prostaglandins and leukotrienes: advances in eicosanoid biology. Science 294, 1871–5 (2001).

  2. 2.

    Miller, S. B. Prostaglandins in health and disease: an overview. Semin Arthritis Rheum 36, 37–49 (2006).

  3. 3.

    Wang, D. & DuBois, R. N. Prostaglandins and cancer. Gut 55, 115–122 (2006).

  4. 4.

    Bergstrom, S., Danielsson, H., Klenberg, D. & Samuelsson, B. The enzymatic conversion of essential fatty acids into prostaglandins. J Biol Chem 239, 4006–4008 (1964).

  5. 5.

    Smith, W. L. & Lands, W. E. Oxygenation of polyunsaturated fatty acids during prostaglandin biosynthesis by sheep vesicular gland. Biochem 11, 3276–85 (1972).

  6. 6.

    Valmsen, K. et al. The origin of 15R-prostaglandins in the Caribbean coral Plexaura homomalla: molecular cloning and expression of a novel cyclooxygenase. Proc Natl Acad Sci USA 98, 7700–5 (2001).

  7. 7.

    Gerhart, D. J. Prostaglandin A2 in the caribbean gorgonian Plexaura homomalla: Evidence against allelopathic and antifouling roles. Biochem System Eco 14, 417–421 (1986).

  8. 8.

    Bayer, F. M. & Weinheimer, A. J. Prostaglandins from Plexaura homomalla: Ecology, Utilization and Conservation of a Major Medical Marine Resource. Stud Tropical Oceanogr 12 (1974).

  9. 9.

    Ragab, A., Bitsch, C., Thomas, J. M. F., Bitsch, J. & Chap, H. Lipoxygenase conversion of arachidonic acid in males and inseminated females of the firebrat, Thermobia domestica (Thysanura). Insect Biochem 17, 863–870 (1987).

  10. 10.

    Lord, J. C., Anderson, S. & Stanley, D. W. Eicosanoids mediate Manduca sexta cellular response to the fungal pathogen Beauveria bassiana: a role for the lipoxygenase pathway. Arch Insect Biochem Physiol 51, 46–54 (2002).

  11. 11.

    Gao, L. et al. Formation of prostaglandins E2 and D2 via the isoprostane pathway: a mechanism for the generation of bioactive prostaglandins independent of cyclooxygenase. J Biol Chem 278, 28479–89 (2003).

  12. 12.

    Ells, R., Kock, J. L., Albertyn, J. & Pohl, C. H. Arachidonic acid metabolites in pathogenic yeasts. Lipids Health Dis 11, 100 (2012).

  13. 13.

    Lamacka, M. & Sajbidor, J. The occurrence of prostaglandins and related compounds in lower organisms. Prostaglandins Leukot Essent Fatty Acids 52, 357–64 (1995).

  14. 14.

    Edmonds, J. W. et al. Insulin/FOXO signaling regulates ovarian prostaglandins critical for reproduction. Developmental Cell 19, 858–871 (2010).

  15. 15.

    Hoang, H. D., Prasain, J. K., Dorand, D. & Miller, M. A. A heterogeneous mixture of F-series prostaglandins promotes sperm guidance in the Caenorhabditis elegans reproductive tract. PloS Genetics 9, e1003271 (2013).

  16. 16.

    McKnight, K. et al. Neurosensory perception of environmental cues modulates sperm motility critical for fertilization. Science 344, 754–7 (2014).

  17. 17.

    Pier, B. et al. Comprehensive profiling of prostaglandins in human ovarian follicular fluid using mass spectrometry. Prostaglandins Other Lipid Mediat 134, 7–15 (2017).

  18. 18.

    Chan, A. T. et al. Long-term use of aspirin and nonsteroidal anti-inflammatory drugs and risk of colorectal cancer. JAMA 294, 914–23 (2005).

  19. 19.

    Cole, B. F. et al. Aspirin for the chemoprevention of colorectal adenomas: meta-analysis of the randomized trials. J Natl Cancer Inst 101, 256–66 (2009).

  20. 20.

    Kubagawa, H. et al. Oocyte signals derived from polyunsaturated fatty acids control sperm recruitment in vivo. Nature Cell Biology 8, 1143–1148 (2006).

  21. 21.

    Hu, M., Legg, S. & Miller, M. A. Measuring Sperm Guidance and Motility within the Caenorhabditis elegans Hermaphrodite Reproductive Tract. J Vis Exp 148, e59783 (2019).

  22. 22.

    Kobayashi, T. et al. Regulation of cytosolic prostaglandin E synthase by phosphorylation. Biochem J 381, 59–69 (2004).

  23. 23.

    Tallman, K. A., Pratt, D. A. & Porter, N. A. Kinetic products of linoleate peroxidation: rapid beta-fragmentation of nonconjugated peroxyls. J Am Chem Soc 123, 11827–8 (2001).

  24. 24.

    Waugh, R. J., Morrow, J. D., Roberts, I. L. J. & Murphy, R. C. Identification and relative quantitation of F2-isoprostane regioisomers formed in vivo in the rat. Free Radical Biol Med 23, 943–954 (1997).

  25. 25.

    Yin, H. et al. Urinary prostaglandin F2 is generated from the isoprostane pathway and not the cyclooxygenase in humans. J Biol Chem 282, 329–336 (2007).

  26. 26.

    Vane, J. R., Bakhle, Y. S. & Botting, R. M. Cyclooxygenases 1 and 2. Annu Rev Pharmacol Toxicol 38, 97–120 (1998).

  27. 27.

    Oni-Orisan, A. et al. Dual modulation of cyclooxygenase and CYP epoxygenase metabolism and acute vascular inflammation in mice. Prostaglandins Other Lipid Mediat 104–105, 67–73 (2013).

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Acknowledgements

We thank the NIH-supported Caenorhabditis Genetics Center (P40 OD010440) for worm strains. This study was supported by R01 GM118361 to M.A.M. and J.K.P., and F30HD094446 to M.H. The UAB Targeted Metabolomics and Proteomics Laboratory has been supported by the UAB-UCSD O’Brien Acute Kidney Injury Center (P30 DK079337), UAB Lung Health Center (HL114439, HL110950), and UAB Center for Free Radical Biology. We thank Dr. Stephen Barnes for critical reading of the manuscript and Landon Wilson and Taylor Berryhill for their asistance in mass spectrometric work. Purchase of the mass spectrometers in the Targeted Metabolomics and Proteomics Laboratory came from funds provided by the NCRR for the SCIEX 5600 Triple-TOF (S10 RR027822-01) and the UAB Health Services Foundation General Endowment Fund for the SCIEX 6500 Qtrap.

Author information

Michael Miller, Jeevan Prasain and Ekta Tiwary conceived and designed the experiments. Ekta Tiwary cultured C. elegans strains, extracted PGs and prepared samples. Muhan Hu performed microinjections of PGs into fat-2 mutants. Jeevan Prasain and Ekta Tiwary interpreted mass spectrometry data. Ekta Tiwary and Jeevan Prasain wrote the paper. All authors contributed to the paper by critically reviewing it.

Correspondence to Jeevan K. Prasain.

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Tiwary, E., Hu, M., Miller, M.A. et al. Signature profile of cyclooxygenase-independent F2 series prostaglandins in C. elegans and their role in sperm motility. Sci Rep 9, 11750 (2019) doi:10.1038/s41598-019-48062-y

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