Lysophosphatidylcholine Activates Adipocyte Glucose Uptake and Lowers Blood Glucose Levels in Murine Models of Diabetes*

Glucose homeostasis is maintained by the orchestration of peripheral glucose utilization and hepatic glucose production, mainly by insulin. In this study, we found by utilizing a combined parallel chromatography mass profiling approach that lysophosphatidylcholine (LPC) regulates glucose levels. LPC was found to stimulate glucose uptake in 3T3-L1 adipocytes dose- and time-dependently, and this activity was found to be sensitive to variations in acyl chain lengths and to polar head group types in LPC. Treatment with LPC resulted in a significant increase in the level of GLUT4 at the plasma membranes of 3T3-L1 adipocytes. Moreover, LPC did not affect IRS-1 and AKT2 phosphorylations, and LPC-induced glucose uptake was not influenced by pretreatment with the PI 3-kinase inhibitor LY294002. However, glucose uptake stimulation by LPC was abrogated both by rottlerin (a protein kinase Cδ inhibitor) and by the adenoviral expression of dominant negative protein kinase Cδ. In line with its determined cellular functions, LPC was found to lower blood glucose levels in normal mice. Furthermore, LPC improved blood glucose levels in mouse models of type 1 and 2 diabetes. These results suggest that an understanding of the mode of action of LPC may provide a new perspective of glucose homeostasis.

Glucose homeostasis is maintained by the orchestration of peripheral glucose utilization and hepatic glucose production, mainly by insulin. In this study, we found by utilizing a combined parallel chromatography mass profiling approach that lysophosphatidylcholine (LPC) regulates glucose levels. LPC was found to stimulate glucose uptake in 3T3-L1 adipocytes dose-and time-dependently, and this activity was found to be sensitive to variations in acyl chain lengths and to polar head group types in LPC. Treatment with LPC resulted in a significant increase in the level of GLUT4 at the plasma membranes of 3T3-L1 adipocytes. Moreover, LPC did not affect IRS-1 and AKT2 phosphorylations, and LPC-induced glucose uptake was not influenced by pretreatment with the PI 3-kinase inhibitor LY294002. However, glucose uptake stimulation by LPC was abrogated both by rottlerin (a protein kinase C␦ inhibitor) and by the adenoviral expression of dominant negative protein kinase C␦. In line with its determined cellular functions, LPC was found to lower blood glucose levels in normal mice. Furthermore, LPC improved blood glucose levels in mouse models of type 1 and 2 diabetes. These results suggest that an understanding of the mode of action of LPC may provide a new perspective of glucose homeostasis.
Glucose is the most important metabolic fuel, and glucose homeostasis is maintained predominantly by insulin by balancing peripheral glucose uptake and hepatic glucose production (1,2). However, if whole body glucose homeostasis is disrupted, hyperglycemia and various physiopathologies associated with metabolic disturbances may occur. The removal of excess glucose from the circulation involves the stimulation of glucose transport into metabolic tissues, and it has become clear that glucose intolerance in type 2 diabetes is manifested by defects in glucose transport into these metabolic tissues (3). Moreover, for many years, adipose tissue was believed to play key roles in glucose homeostasis (4).
In addition to insulin, various hormones and physiological conditions are capable of stimulating glucose uptake (5)(6)(7)(8)(9)(10). For example, the activation of ␣ 1 -adrenergic or endothelin A receptors results in enhanced glucose uptake rates independently of insulin levels, and physical exercise also plays an important role in the metabolism of glucose by skeletal muscle (10 -13). Furthermore, some of the signaling mechanisms that mediate these metabolic responses are similar to those utilized by insulin, whereas others are clearly distinct (5). The abovementioned processes illustrate that glucose regulation is not a simple event wholly attributable to insulin but rather a complex process that involves many glucose regulators. However, although the significance of insulin-independent glucose regulation has been recognized, no systematic search has been conducted to identify novel glucose regulators.
Over the past few years, lysophospholipids have been increasingly recognized to be important cell signaling molecules (14), and one of these, lysophosphatidylcholine (LPC), 2 which is produced during both physiological and pathological conditions, has been shown to be involved in many cellular processes (15)(16)(17). For example, it is known that LPC is a major plasma lipid component that transports fatty acids and choline to tissues (18). Moreover, although the mechanisms of LPC synthesis are not completely understood, the hydrolysis of phosphatidylcholine by plasma lecithin-cholesterol acyltransferase is a possible mechanism of the in vivo synthesis of LPC (14). LPC exhibits diverse biological functions and has been reported to be involved in cellular proliferation, tumor cell invasiveness, and inflammation (14,19 glucose. To identify novel serum factors that stimulate glucose uptake in 3T3-L1 adipocytes, we developed a new analytical technique based on parallel HPLC, protease digestion, and mass spectrometry. Using this modality, we found that LPC activates glucose uptake and effectively lowers blood glucose levels in mouse models of Type 1 and 2 diabetes.

EXPERIMENTAL PROCEDURES
Materials-Synthetic 14:0, 18:0, 18:1 LPC, insulin, Ki16425, and streptozotocin (STZ) were obtained from Sigma. Other lysophospholipids were purchased from Avanti polar lipids (Alabaster, AL). All of the lipids were dissolved in MeOH as 50 mM stock solutions and stored for at most a month under nitrogen at Ϫ70°C in glass vials. Gö6976 and rottlerin were purchased from Calbiochem, and antibodies were purchased from the following sources: anti-phospho-Ser473 AKT2 antibody from Sigma; and the ␣1 subunit of Na ϩ /K ϩ -ATPase antibody from Upstate Biotechnology (Lake Placid, NY). Anti-phospho-Tyr989 IRS1 was produced in our laboratory. [ 14 C]2-Deoxy-Dglucose (300 mCi/mmol) was purchased from Moravek Biochemicals (Brea, CA), and trypsin was from Roche Applied Science. Tissue culture media and fetal bovine serum were from Invitrogen. All other reagents were of analytical grade.
HPLC Fractionation-Approximately 350 ml of fresh human serum was mixed with 70% (v/v) acetone, 1 M acetic acid, and 20 mM HCl and then centrifuged at 20,000 ϫ g for 30 min at 4°C. The resultant supernatant was collected and extracted three times with diethyl ether, and the aqueous phase so obtained was centrifuged at 20,000 ϫ g for 30 min at 4°C. Supernatant was then precleared by passing it through SepPak C18 (Waters) cartridges. Eluent was directly loaded onto a C18 reverse phase HPLC column (Vydac 218TP1022, 22 mm ϫ 250 mm). Fractions (10 ml) were collected, and ϳ1% of each fraction was assayed for glucose uptake by 3T3-L1 adipocytes. Active fractions were trypsinized for 12 h at 37°C, and equal amounts were applied to a C4 reverse phase HPLC column (Vydac 214TP5215, 2.1 mm ϫ 150 mm) and to a cation exchange HPLC column (Amersham Biosciences; Min-S HR 5/5, 4.6 mm ϫ 50 mm).
Mass Spectrometry and Data Analysis-ESI-MS and tandem mass spectrometry (MS/MS) analyses were performed using a QSTAR PULSAR I hybrid quadrupole time-of-flight MS/MS (Applied Biosystems/PE SCIEX, Toronto, Canada) equipped with a nano-ESI source. The samples were dissolved in 0.1% trifluoroacetic acid and delivered into the ESI source using a Protana nanospray tip (Odense, Denmark). All of the masses detected were calculated using Analyst QS software provided by Applied Biosystems. Quadrupole time-of-flight MS/MS was performed at a resolution of 8,000 -10,000 with a mass accuracy of 10 -30 ppm using external calibration. The voltage of the spray tip was set at 2300 V. A combined online-data base (Dictionary of Natural Products, Chapman & Hall/CRC) was used to identify the masses.
Protease Digestion of Active Fractions-For protease digestion, C18 reverse phase HPLC fractions were lyophilized, and then 50 mg/g (enzyme/substrate) of sequencing grade trypsin (Promega Ltd.) in 50 mM ammonium bicarbonate was added. Digestion was carried out at 37°C overnight.
Cell Culture-3T3-L1 fibroblasts were grown in DMEM containing a high glucose concentration, 10% fetal bovine serum, 50 units of penicillin per milliliter, and 50 g of streptomycin/ml and maintained in a 5% CO 2 humidified atmosphere at 37°C. 3T3-L1 was induced to differentiate into adipocytes as described previously (20).
Glucose Uptake Measurements-To measure glucose uptake by 3T3-L1 adipocytes, the cells were grown in serum-free DMEM for 16 h, and then serum-free medium was replaced with 1 ml of Kreb's buffer (118 mM NaCl, 25 mM NaHCO 3 , 4.6 mM KCl, 1.2 mM MgSO 4 , 1.2 mM KH 2 PO 4 , 2.5 mM CaCl 2 , pH 7.4). The cells were stimulated with insulin or lysophospholipids for the indicated times at 37°C. Glucose uptake was measured by adding 1 Ci of [ 14 C] 2-deoxy-D-glucose and 3 mM 2-deoxy-D-glucose for 10 min. The assay was terminated with two quick washes of ice-cold phosphate-buffered saline. The cells were lysed in 0.5 ml of lysis buffer containing 0.5 N NaOH and 0.1% SDS. The cell lysates were liquid scintillation counted. Nonspecific glucose uptakes were assayed in the presence of 10 M cytochalasin B (20). Counts of [ 14 C] 2-deoxy-D-glucose were normalized to protein levels measured with the Bradford reagent (Bio-Rad) at 595 nm.
Adenoviral Transfection of PKC Isoforms-The adenovirus (AdV) expression vectors used to transfect wild-type PKC␦, dominant negative PKC␦ (DN-PKC␦), or dominant negative PKC (DN-PKC) recombinant AdV were as previously described (21). After cultured 3T3-L1 adipocytes had differentiated, the culture medium was aspirated, and the cultures were infected with viral medium containing each recombinant AdV for 24 h. The cultures were then washed twice with serum-free DMEM and refed with DMEM supplemented with 10% fetal bovine serum. The cells were subjected to glucose uptake assays at 48 h post-infection. 3T3-L1 adipocytes transfected with AdV for the LacZ gene (LacZAdV) were used as controls (22).
Immunoblotting-To prepare total cell lysates, 3T3-L1 adipocytes were washed with Ca 2ϩ /Mg 2ϩ -free phosphate-buffered saline and then lysed in lysis buffer (50 mM HEPES, pH 7.2, 150 mM NaCl, 50 mM NaF, 1 mM Na 3 VO 4 , 10% glycerol, 1% Triton X-100). The lysates were then centrifuged at 15,000 rpm for 15 min at 4°C, and the proteins were denatured in Laemmli sample buffer (5 min at 95°C) and then separated by SDS-PAGE. The proteins were transferred to nitrocellulose membranes using the Hoefer wet transfer system and blocked in TTBS (20 mM Tris-HCl, pH 7.6, 150 mM NaCl, 0.05% Tween 20) containing 5% skimmed milk powder for 30 min before being incubated with antibodies for 3 h. After washing the membranes several times with TTBS, the blots were incubated with horseradish peroxidase-conjugated anti-mouse or anti-rabbit antibody for 1 h. The membranes were then washed with TTBS and developed by ECL.
GLUT4 Translocation-To obtain membrane fractions from 3T3-L1 adipocytes, the cells were placed in 10 ml of ice-cold HES buffer (250 mM sucrose, 1 mM EDTA, 1 mM phenylmethylsulfonyl fluoride, 1 M pepstatin, 1 M aprotinin, 1 M leupeptin, and 20 mM HEPES, pH 7.4) and homogenized with 30 strokes in a glass Dounce homogenizer at 4°C. After centrifuging at 1,000 ϫ g for 5 min at 4°C to remove unbroken cells, the supernatants were further centrifuged at 16,000 ϫ g for 15 min at 4°C to yield plasma membrane (PM) pellets. Ultracentrifugation was used to obtain low density microsomes, as previously described (7). The PM and low density microsome fractions were denatured in Laemmli sample buffer (5 min at 95°C) and then separated by SDS-PAGE. GLUT4 was detected by polyclonal anti-GLUT4 antibody from Biogenesis Ltd. (Sandown, NH).
Animals-Male ICR mice were purchased from Hyochang Science (Seoul, Korea). C57BLKSJ-db/db mice were purchased from SLC (Japan). After injecting LPC intravenously, the blood glucose levels were monitored using ONETOUCH Ultra TM kits (LifeScan Inc., Milpitas, CA) after tail snipping. Serum insulin levels were determined using insulin-radioimmunoassay kits (LINCO). Insulin-deficient mice were induced by injecting male ICR mice intraperitoneally on two consecutive days with STZ (200 mg/kg) dissolved in 0.1 M sodium citrate (pH 5.5). Age-matched control mice were administered an equivalent volume of citrate buffer. Three days after the second STZ injec-tions, the animals with blood glucose levels greater than 300 mg/dl were considered diabetic. Acute glucose lowering effects were examined after intravenously injecting vehicle, LPC, or insulin, mentioned above. The animals were cared for in accordance with our institution's guidelines.
Statistical Analysis-The data are expressed as the means Ϯ S.E. or the means Ϯ S.D. Statistical analysis was performed using the Student's t test or by one-way analysis of variance and the post hoc test. p values of Ͻ0.05 were considered significant.

Parallel HPLC Separation for the Identification of Novel Glucose
Uptake-stimulating Molecule in 3T3-L1 Adipocytes-To identify the endogenous factors that stimulate glucose uptake in 3T3-L1 adipocytes, we developed a method based on parallel HPLC, protease digestion, and MS analysis (Fig. 1a). The fundamental principle of parallel HPLC is that it uses profiling analysis to identify target molecules instead of traditional sequential purification (23). In addition to parallel HPLC, we used protease digestion to exclude inactive peptides with physicochemical properties similar to active molecules. Although these peptides are not easily removed by sequential chromatography, the cleavages of inactive peptides by protease digestion causes structural changes in these peptides and facilitates their separation from active species by column chromatography. Therefore, protease digestion is particularly useful for purifying nonpeptide molecules, such as, lipids, amines, and carbohydrates.
Using this new method, we first fractionated human serum acetone extracts by C18 reverse phase HPLC, and then 3T3-L1 adipocytes were treated with these HPLC fractions, and glucose uptakes by adipocytes were measured by determining increases in [ 14 C] 2-deoxy-D-glucose uptakes (20). As shown in Fig. 1b, at least four types of fractions were identified that increased glucose uptake by adipocytes (A-D), and these were tested to determine whether their activities were reduced by trypsin digestion. Only the activity of fraction D was found to be unaffected by trypsin digestion (data not shown); thus fraction D was digested with trypsin and further separated by parallel C4 reverse phase (C4) and by cation exchange (SCX) HPLC. All of the C4 and SCX fractions were then screened for the stimulation of glu-FIGURE 1. The isolation of glucose uptake-stimulating molecules from serum. a, schematic representation of the strategy used to identify the serum factor responsible for stimulating glucose uptake in 3T3-L1 adipocytes. b, C18 reverse phase HPLC (Vydac 218TP1022, 22 ϫ 250 mm) serum elution profile. The relative glucose uptakes are expressed as ratios of uptake increases caused by treatments versus that cause by vehicle alone in 3T3-L1 adipocytes. Small amounts of active fractions were tested to determine whether stimulating activity was reduced by trypsin digestion. The trypsin-resistant fraction (fraction D) was selected and trypsinized prior to a second HPLC purification. c, C4 reverse phase HPLC (Vydac 214TP5215, 2.1 ϫ 150 mm) elution profile of fraction D. d, cation exchange HPLC (Amersham Biosciences Mini-S HR 5/5, 4.6 ϫ 50 mm) elution profile of fraction D. DECEMBER 4, 2009 • VOLUME 284 • NUMBER 49 cose uptake in 3T3-L1 adipocytes, and there was single type of active fraction from each HPLC (Fig. 1, c and d).

LPC in Murine Models of Diabetes
Identification of LPC as a Glucose Uptake-stimulating Molecule by Mass Spectrometry-The active fractions from each column system (37 min from the C4 column and 6 min from the SCX column) were analyzed by ESI-quadrupole time-of-flight MS. Initially, to identify common masses in these fractions, mass spectra were compared, and only one common mass was identified at m/z 495.33 (Fig. 2a, top and middle panels). Using this mass information, we searched the combined online-data base (Dictionary of Natural Products), and the unknown was tentatively identified as palmitoyl LPC. To confirm that the target molecule was LPC, we analyzed the fragmentation patterns of standard LPC and of the m/z 495.33 fragment using MS/MS (Fig. 2b). The standard LPC product ion spectrum in positive ion mode displayed several ions that originated from the collision-induced dissociation of the phosphocholine head group of LPC, which produced a maximal peak at m/z 183 (Fig.  2, b, bottom panel, and c). Furthermore, the fragmentation pattern of m/z 495.33 from C4 and SCX exactly matched that of standard LPC (Fig. 2b, top and middle panels). Based on the above information, we concluded that the active substance was LPC.
LPC-induced Glucose Uptake by 3T3-L1 Adipocytes-To investigate the effects of LPC on glucose uptake, 3T3-L1 adipocytes were incubated in the presence of various concentrations of LPC for different times. It was found that LPC stimulated glucose uptake in a time-and dose-dependent manner. LPC was found to have a significant effect of on glucose uptake from a concentration of 1 M and a maximal effect at 20 M (Fig. 3, a and b). Furthermore, LPC was not cytotoxic at this concentration, which was also below the critical micellar concentration of LPC (40 -50 M) (24).
LPC Stimulated GLUT4 Translocation in 3T3-L1 Adipocytes-To assess whether the ability of LPC to enhance glucose transport in 3T3-L1 adipocytes is mediated by LPC-induced changes in glucose transporter protein levels on cell surfaces, the GLUT4 protein levels were measured in PM fractions in the basal state and after treating them with LPC or insulin as control. LPC was found to induce a significant increase in GLUT4 protein levels in PMs, like the insulin control (Fig. 4). These results suggest that LPC stimulates GLUT4 translocation, which is consistent with the findings of our glucose uptake experiments.
LPC Stimulated Glucose Uptake in a PI 3-Kinase-independent and a PKC␦-dependent Manner-Insulin stimulation of glucose transport into adipocytes requires the insulin receptormediated tyrosine phosphorylation of insulin receptor substrate (IRS)-1 and the subsequent activation of PI 3-kinases and AKT2 (protein kinase B2) (25). To determine whether increased glucose uptake in response to LPC is associated with an insulin-dependent signaling pathway, the phosphorylations of IRS1 and AKT2 were checked (25). In contrast to insulin, LPC did not induce changes in the phosphorylations of IRS1 of AKT2 (Fig. 5a) in 3T3-L1 adipocytes. To confirm this, we measured LPC-induced glucose uptake increases after pretreating with LY294002 (20 M, a PI 3-kinase inhibitor). Fig. 5b shows that LY294002 had no effect on glucose uptake stimulation by LPC. Previously, PKCs have been known to be involved in cellular glucose transport. Moreover, because LPC has been shown to activate conventional and novel PKCs in various cells (24), we assessed the involvements of these PKCs on the LPC-induced up-regulation of glucose transport. Glucose uptake was found to be inhibited by the PKC␦ inhibitor rottlerin (5 M) but not by Gö6976 (5 M, a conventional PKC inhibitor) (Fig. 5c) To investigate the roles of PKCs more directly, we used an adenovirus expression system to overexpress specific PKC isoforms in 3T3-L1 adipocytes, and we found that the expression of DN-PKC␦, but not of DN-PKC, significantly reduced LPC-stimulated glucose transport (Fig. 5d). These findings suggest that PKC␦ participates in LPC-induced glucose transport activation.
LPC Lowered Blood Glucose Levels without Affecting Blood Insulin Levels in Mouse-To determine whether LPC affects animals, we tested its blood glucose lowering effect in mice. Acute administration of LPC (at 15 or 30 mol/kg intravenously) to normal ICR mice resulted in a statistically significant dose-dependent drop in blood glucose levels within 30 min (Fig. 6a). To assess whether other lysophospholipids have similar glucose lowering effects, we tested several derivatives of LPC. Palmitoyl-, lauroyl-, and myristoyl LPCs when administered in the same manner also caused reduced blood glucose levels, whereas stearoyl-, oleoyl-, and arachidoyl LPC did not (Fig.  6b). To determine whether this effect of LPC was due to increased insulin levels in blood, we measured insulin levels after LPC administration. It was found that LPC did not induce any change in blood insulin (Fig. 6c). LPA is known to be synthesized from LPC by lysophospholipase D, an autotaxin that attenuates blood glucose levels in mice. To determine whether the glucose lowering effect of LPC was mediated by LPA, we examined the effect of the Ki16425 (an LPA receptor antagonist). However, Ki16425 had no effect on the glucose lowering effect of LPC (Fig. 6d).
LPC Lowered Blood Glucose Levels in Mouse Models of Type 1 and 2 Diabetes-We also examined the in vivo efficacy of LPC in type 1 and type 2 diabetic mouse models. Single intravenous administrations of LPC were found to dose-dependently reduce blood glucose levels in STZ-treated insulin-deficient, type 1  diabetic mice, in a manner similar to intravenous insulin (Fig. 7a). Similar administrations of LPC also affected glycemia in obese db/db type 2 diabetic mice and reduced blood glucose levels to near normal (Fig. 7b).

DISCUSSION
The present study provides evidence that LPC is a blood-derived factor involved in glucose homeostasis. 3T3-L1 adipocytes treated with LPC were found to uptake glucose rapidly via PI 3-kinase-independent PKC␦ activation. Furthermore, when acute intravenous LPC was administered to mouse models of type 1 and 2 diabetes, the blood glucose levels were significantly lowered. Accordingly, we suggest that LPC represents a novel insulinindependent signal that can regulate blood glucose levels in normal and diseased mouse models. Furthermore, our findings suggest that an understanding of the role played by LPC in glucose regulation would enhance our understanding of glucose metabolism.
The stimulation of glucose uptake by 3T3-L1 adipocytes and the blood glucose lowering effect of LPC in mice were found to be sensitive to variations in LPC acyl chain length, i.e. whereas the palmitoyl and myristoyl LPC derivatives (16:0 and 14:0, respectively) enhanced glucose uptake by 3T3-L1 adipocytes, stearoyl, oleoyl, and arachidoyl LPC (18:0, 18:1, and 20:0, respectively) were ineffective. However, when 3T3-L1 adipocytes were treated with several lysophospholipids that differed structurally only in terms of the polar head group of palmitoyl LPC, glucose uptake by adipocytes was not increased (this structural specificity was also confirmed by our mouse model of type 1 and 2 diabetes). These findings suggest that both acyl chain length and the choline head group of LPC are critical for stimulating glucose uptake by 3T3-L1 adipocytes and for lowering blood glucose levels in mice. Based on the rapid onset and structural specificity of LPC, we  . Blood glucose lowering effect of LPC in normal ICR mice. a and b, acute glucose reduction by LPC in ICR mice. 8-week-old male mice were intravenously injected with phosphate-buffered saline, insulin, or various LPCs. Blood glucose levels were monitored for 0 -120 min after injections. c, serum insulin levels in 8-week-old male mice after a single intravenous injection of saline, glucose, or LPC. d, the effect of Ki16425 (an LPA receptor inhibitor) on the blood glucose reduction by LPC. 8-week-old male ICR mice were pretreated with Ki16425 (10 mol/kg) for 30 min and then intravenously administered saline, LPC, or LPA. All of the animals had free access to water and were cared for in accordance with the guidelines issued by our institution. The data shown are the means Ϯ S.D. (n ϭ 5-6). *, p Ͻ 0.05 versus vehicle. NT, not treated. speculate that the biological activity of LPC is possibly due to binding between LPC and a specific cell surface receptor. Several lysophospholipids have been reported to bind to G proteincoupled receptor family members (26 -29). However, recently it was reported that LPC activates these receptors via a mechanism that does not involve direct binding (19), although earlier reports concluded that LPC binds directly to and activates G2A and GPR4. Thus, it remains an open question as to whether LPC stimulates glucose uptake by directly binding G2A and GPR4 or whether it does so indirectly via an as yet unknown mechanism.
The involvement of conventional or atypical PKC activation in the promotion of glucose uptake by adipocytes and muscle cells is well established (30), but the activation of novel PKCs, especially of PKC␦, also controls glucose uptake. Stimulation of the translocation of GLUT4 to the plasma membrane and glucose uptake by insulin were found to be inhibited by rottlerin in rat skeletal muscle cells, and the overexpression of PKC␦ induced by GLUT4 translocation to the plasma membrane was found to increase basal glucose uptake to levels attained by insulin (31). In the present study, LPC-induced glucose uptake was found to be significantly blocked by rottlerin and by the overexpression of DN-PKC␦. In contrast, pretreatment with Gö6976 (a conventional PKC inhibitor) and the expression of DN-PKC were found to have no effect on LPC-induced glucose uptake. These findings suggest that only PKC␦ is required for LPC-induced glucose transport in 3T3-L1 adipocytes. However, it has not been established whether PKC␦ is downstream of LPC receptors like G2A or GPR4, and thus, additional work is needed to further elucidate the natures of the signal mechanisms that trigger specific PKC␦s to participate in LPC-induced glucose transport.
The induction of insulin secretion from pancreatic ␤-cells is a physiological function of LPC (32). Recently, Suga et al. found that LPC induced insulin secretion by a pancreatic ␤-cell line (NIT-1) and by perfused rat pancreas under high glucose conditions (16.6 mM), but not under low glucose (2.8 mM) conditions (32). In the present study, we measured serum insulin levels in fasted mice with blood glucose concentrations of 3-5 mM after LPC administration and found that LPC had no effect. On the other hand, we found that LPC had a blood glucose lowering effect in STZ-treated insulin-deficient mice. Thus, these results obtained in our study potentially support that LPC can directly affect glucose lowering in mice.
It is well known that LPA can be produced abundantly from LPC by autotoxin, which has lysophospholipase D activity (33), and recently, it was reported that LPA has a glucose regulatory function (34). Furthermore, it has been reported that LPA can associate with four types of LPA receptors, enhance glucose uptake by 3T3-L1 adipocytes, and reduce blood glucose levels by interacting with LPA 1 or LPA 3 receptors (34,35). In addition, the authors showed that blood glucose reductions by LPA were significantly inhibited by Ki16425 (a selective LPA 1 and LPA 3 antagonist) (34). Therefore, we examined whether the blood glucose lowering effect of LPC is affected by Ki16425. However, although we found that the glucose lowering effect of LPA was blocked by Ki16425, it had no effect on the glucose reduction induced by LPC (Fig. 6d). Based on this result, we suggest that the LPC-induced glucose level reductions are not caused by LPA metabolized from LPC, but rather that these reductions are due to the direct effects of LPC.
The physiologic concentrations of LPC in body fluids, such as blood and ascites, are substantial (5-180 M) (14). The levels of LPC are elevated in many diseases related to inflammation (15). More recently, elevated LPC levels (in particular, the ratios of palmitoyl-LPC to linoleoyl-LPC) have been reported in ovarian cancer and multiple myeloma. Nevertheless, the changes in LPC concentration by glucose or other metabolic stimuli have not been characterized. Therefore, additional work is required on the regulation of LPC secretion and to confirm the effect of LPC on glucose metabolism.
The present study provides the first evidence that bloodborne LPC is intimately involved in glucose homeostasis. It is our hope that this finding generates interest in the physiological and pathological roles of LPC in glucose metabolism. Finally, we believe that an understanding of the mechanism responsible for the metabolic effects of LPC could lead to the development of a novel means of treating diabetes.