HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) All Versions of this Article: db08-0206v1 57/8/2061    most recent Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Google Scholar Articles by Ross, R. Articles by Lam, T. K.T. PubMed PubMed Citation Articles by Ross, R. Articles by Lam, T. K.T. Social Bookmarking                What's this?

Hypothalamic Protein Kinase C Regulates Glucose Production

¹ Departments of Molecular Pharmacology, Medicine, and Neuroscience, Albert Einstein College of Medicine, Bronx, New York
² Toronto General Hospital Research Institute, University Health Network, Toronto, Canada
³ Departments of Physiology and Medicine, University of Toronto, Toronto, Canada
⁴ Department of Pharmacology, University of Alberta, Edmonton, Canada

Corresponding author: Dr. Tony Lam, tony.lam{at}uhnres.utoronto.ca

	ABSTRACT

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
OBJECTIVE—A selective rise in hypothalamic lipid metabolism and the subsequent activation of SUR1/Kir6.2 ATP-sensitive K⁺ (K_ATP) channels inhibit hepatic glucose production. The mechanisms that link the ability of hypothalamic lipid metabolism to the activation of K_ATP channels remain unknown.

RESEARCH DESIGN AND METHODS—To examine whether hypothalamic protein kinase C (PKC) mediates the ability of central nervous system lipids to activate K_ATP channels and regulate glucose production in normal rodents, we first activated hypothalamic PKC in the absence or presence of K_ATP channel inhibition. We then inhibited hypothalamic PKC in the presence of lipids. Tracer-dilution methodology in combination with the pancreatic clamp technique was used to assess the effect of hypothalamic administrations on glucose metabolism in vivo.

RESULTS—We first reported that direct activation of hypothalamic PKC via direct hypothalamic delivery of PKC activator 1-oleoyl-2-acetyl-sn-glycerol (OAG) suppressed glucose production. Coadministration of hypothalamic PKC- inhibitor rottlerin with OAG prevented the ability of OAG to activate PKC- and lower glucose production. Furthermore, hypothalamic dominant-negative Kir6.2 expression or the delivery of the K_ATP channel blocker glibenclamide abolished the glucose production-lowering effects of OAG. Finally, inhibition of hypothalamic PKC eliminated the ability of lipids to lower glucose production.

CONCLUSIONS—These studies indicate that hypothalamic PKC activation is sufficient and necessary for lowering glucose production.

The hypothalamus senses nutrients and hormones to regulate energy and glucose homeostasis (1–9), but the associated central nervous system (CNS) sensing mechanisms remain unclear. A selective increase in long-chain fatty acyl-coenzyme A (LCFA-CoA) level in the hypothalamus leads to the activation of SUR1/Kir6.2-containing ATP-sensitive K⁺ (K_ATP) channels and lowers glucose production (10). In contrast, an elevation of LCFA-CoA level in the liver actually increases glucose production during hyperinsulinemia (1). These observations led us to hypothesize that lipid-sensing mechanisms share similar biochemical (i.e., LCFA-CoA accumulation) but have opposing physiological mechanisms (i.e., glucose production regulation) in operation (1).

In the peripheral tissues such as the liver and muscle, an elevation of lipids (especially the long-chain fatty acids [LCFAs]) activates the novel isoforms of protein kinase C (PKC) (i.e., -, -, and -) to induce insulin resistance during hyperinsulinemic-euglycemic clamps (11–16). Although novel isoforms of PKC (especially - and -) are expressed in the brain (17), it is currently unknown whether LCFAs activate hypothalamic, novel isoforms of PKC to regulate glucose production. It has been reported that activation of PKC leads to phosphorylation of the conserved threonine residue (T180) in the pore-forming subunit Kir6.2 of the K_ATP channels in the pancreatic β-cells (18). These channels are expressed in both β-cells and neurons (18,19), and direct activation of the hypothalamic K_ATP channels has been shown to lower glucose production (19). Both the PKC-induced K_ATP channel activation (18) and hypothalamic K_ATP channels’ regulation of glucose production (19) are blocked by pretreatment with the K_ATP channel blocker glibenclamide (18,19). It is possible that the mechanism of activation of K_ATP channels in the β-cells by PKC is also found in the hypothalamus.

Based on these independent yet parallel findings, we tested the hypothesis that activation of hypothalamic PKC is sufficient and necessary for CNS lipid-sensing mechanisms to lower glucose production and regulate glucose homeostasis (Fig. 1A).

View larger version (26K): [in this window] [in a new window]   FIG. 1. Hypothalamic PKC activation lowers glucose production. A: Working hypothesis: lipids activate hypothalamic PKC to phosphorylate and activate the hypothalamic Kir6.2/SUR1-containing KATP channels to lower glucose production. Direct MBH administration of PKC activator OAG increased glucose infusion rate (B) and lowered glucose production (C) during the clamps. MBH OAG coinfused with general PKC inhibitor BIM (n = 5), specific PKC- inhibitor Rot (n = 6), or KATP channel blocker glibenclamide (n = 5) or in MBH DN Kir6.2 AAA-injected rats (n = 5) failed to increase glucose infusion rate (B) and lower glucose production (C). D: Glucose uptake was comparable in all groups. MBH vehicle (VEH) (n = 6) consisted of MBH saline (n = 3) and MBH 5% DMSO (n = 3). MBH OAG (n = 7) consisted of MBH OAG in normal rats (n = 4) and in MBH GFP-injected rats (n = 3). *P < 0.001 (ANOVA) and P < 0.01 vs. other individual groups.

	RESEARCH DESIGN AND METHODS

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

Clamp procedure.
All the rats were restricted to 20 g of food the night before the experiments to ensure the same nutritional status. Infusion studies lasted a total of 360 min. At 0 min, MBH infusion of the various study solutions was initiated and maintained at a rate of 0.33 µl/h for 6 h. Study solutions consisted of 250 µmol/l PKC activator 1-oleoyl-2-acetyl-sn-glycerol (OAG) (dissolved in 5% DMSO), 250 µmol/l OAG plus 60 µmol/l bisindolylmaleimide (BIM) (general PKC inhibitor), 250 µmol/l OAG plus 60 µmol/l rottlerin (Rot) (specific PKC- inhibitor), 250 µmol/l OAG plus 100 µmol/l K_ATP channel blocker glibenclamide (dissolved in 5% DMSO), vehicle (either saline or 5% DMSO), 60 µmol/l BIM, 60 µmol/l Rot, or 100 µmol/l glibenclamide. After 2 h of MBH infusion, a primed continuous intravenous infusion of 3-³H-glucose (40 µCi bolus, 0.4 µCi/min; Perkin Elmer) was begun and maintained throughout the study to assess glucose kinetics in vivo.

In a different group of rats, intravenous saline or 20% Intralipid (mixed with 20 units/ml of heparin, 0.4 ml/h; Baxter Healthcare Corporation) infusion was initiated at 120 min and maintained throughout the experiments. Intralipid infused at this rate elevates plasma free fatty acid and hypothalamic LCFA-CoA levels by 1.5- to 2.0-fold (10). Samples for determination of ³H glucose–specific activity were obtained at 10-min intervals. For the final 2 h of the infusion study, a pancreatic-euglycemic clamp was performed to evaluate the effect of MBH treatments on glucose metabolism independent of changes in glucoregulatory hormones. This involved continuous infusions of insulin (0.8 mU · kg^–1 · min^–1 for MBH OAG studies and 1.5 mU · kg^–1 · min^–1 for intravenous intralipid infusion studies) and somatostatin (3 µg · kg^–1 · min^–1) to inhibit endogenous insulin and glucagon secretions and a variable infusion of a 25% glucose solution that was started and periodically adjusted to maintain the plasma glucose concentration similar to the basal levels (210–240 min).

The data for glucose infusion rate, glucose production, and glucose uptake were presented as an average of values obtained from the final 30 min (300–360 min) of the clamp studies. MBH Rot, BIM, and glibenclamide alone did not affect glucose kinetics (data not shown). In a separate set of experiments, we performed clamps infused with a higher dose of insulin (1.2 instead of 0.8 mU · kg^–1 · min^–1) and administered vehicle (n = 5) or OAG (n = 4) into the MBH. We found that insulin clamped at 1.2 mU · kg^–1 · min^–1 normally suppressed glucose production from 11 to mean ± SD 7.3 ± 0.4 mg · kg^–1 · min^–1 in MBH vehicle–treated rats. MBH OAG further suppressed glucose production to 2.9 ± 0.9 mg · kg^–1 · min^–1 (P < 0.01 vs. MBH vehicle) during the clamps infused with the higher dose of insulin. The effects of MBH OAG on glucose production suppression was additive to peripheral insulin's effect on the liver, although the magnitude of the drop (4.5 mg · kg^–1 · min^–1) was similar compared with that observed during the pancreatic basal insulin clamps (Fig. 1C). We also performed additional pancreatic basal insulin clamps with intracerebroventricular (icv) OAG (n = 4) versus vehicle (n = 5). The data indicated that icv OAG suppressed glucose production (5.9 ± 0.4 [icv OAG, n = 4] vs. 10.8 ± 0.8 mg · kg^–1 · min^–1 [icv vehicle, n = 5], P < 0.01) to a similar extent as it was suppressed MBH OAG (Fig. 1C). At the end of all studies, rats were anesthetized (ketamine 150 mg/kg) and tissue samples were freeze-clamped with precooled aluminum tongs in situ. All tissue samples were stored at –80°C for further analysis. Harvard Apparatus PHD 2000 infusion pumps were used for all infusions during the clamps.

Mediobasal hypothalamic wedge sampling.
The MBH was sampled by dissecting a wedge of tissue including the entire mediolateral and dorsoventral extent of the arcuate nuclei while minimizing ventromedial nucleus tissue.

Adenovirus injection.
Immediately poststereotaxic surgery, MBH cannulated rats were administered 3 µl of adenovirus containing dominant-negative (DN) Kir6.2 AAA-AV (21) (3.1 x 10¹⁰ plaque-forming units/ml) or green fluorescent protein (GFP) (3.0 x 10¹⁰ plaque-forming units/ml) per side of cannula, as previously described (22). Five days later, the rats underwent vascular surgeries and clamp studies, with MBH OAG administrations performed 4 days later. Preliminary studies (n = 3) indicate that MBH OAG similarly lowered glucose production in GFP-injected rats compared with noninjected rats (n = 4). Thus, the studies were combined and presented as a single MBH OAG group in Fig. 1B and C.

Hypothalamic PKC isoform translocation.
The plasma translocation of the novel isoforms of PKC was assessed by comparing immunoblots of the cytosolic- and membrane-associated fractions obtained 5 min after the MBH DMSO, OAG, OAG + Rot, and Rot treatments in vivo. It is important to point out that Rot has previously been shown to inhibit PKC- translocation in neuronal cells (23). MBH wedges (8 mg) were homogenized using a handheld glass homogenizer in lysis buffer A (20 mmol/l 3-(N-morpholino) propanesulfonic acid [MOPS], 2 mmol/l EDTA, 0.32 mmol/l sucrose, 30 mmol/l sodium fluoride, 10 mmol/l sodium pyrophosphate, 2 mmol/l sodium orthovanadate, 1 mmol/l phenylmethylsulfonylfluoride, 3 mmol/l benzamidine, 5 µmol/l pepstatin A, and 10 µmol/l leupeptin). The samples were centrifuged at 500g to pellet out the nuclear fraction, and the supernatant was then cetrifuged at 100,000g for 60 min at 4°C. The supernatant was retained as the cytosolic fraction. The pellet fraction was washed in lysis buffer A and then resuspended in lysis buffer B (lysis buffer A plus 1% Triton X-100). The samples were incubated for 60 min on ice and then centrifuged at 100,000g for 60 min at 4°C. The supernatant provided the solubilized membrane fraction.

The protein concentration of all samples was determined by detergent-compatible microbicinchoninic acid assay (microBCA, Pierce) using serum albumin as the standard. Eight micrograms of protein in all samples were mixed with LDS sample loading buffer and sample reducing agent (Invitrogen) and heated to 70°C for 10 min. The mixture was then subjected to electrophoretic separation (4–12% bis-tris) and transferred to polyvinylidine fluoride membranes. The membranes were incubated for 1 h in Li-cor blocking buffer at room temperature and then incubated overnight at a concentration of 1:1,000 with affinity-purified polyclonal antibodies specific for the various novel isoforms of PKC (Santa Cruz). Consistent with previous findings (17), no bands for PKC- in the MBH wedges were detected using high or low dilution of the antibody. Membranes were washed with Tris-buffered saline plus Tween and then incubated for 1 h at room temperature with immunoreactive-dye–conjugated IgG (Rockland). The membranes were washed again with Tris-buffered saline-Tween and then rinsed with PBS and scanned on the Odyssey Infrared imaging system (Li-Cor). The immunoreactive bands were quantified using the analytical programs on the Odyssey system.

Statistical analysis.
Statistical analysis was done by ANOVA to compare across the groups followed by Tukey post hoc test to compare between groups. Statistical analysis was accepted as significant with a P value <0.05. Data are presented as means + SE.

	RESULTS

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
To examine the glucoregulatory effects of hypothalamic PKC activation, we infused PKC activator OAG (250 µmol/l) into the MBH of conscious unrestrained rats in vivo. The effects on glucose production and glucose uptake induced by MBH OAG administration were assessed by the tracer-dilution methodology and the pancreatic basal insulin clamp technique as previously described (2). During the clamps, MBH OAG increased exogenous glucose infusion rate by 2.5-fold, compared with MBH vehicle, which maintained euglycemia (Fig. 1B). The increase in glucose infusion rate was fully accounted for by an inhibition of glucose production (Fig. 1C) because the rate of glucose uptake remained unchanged (Fig. 1D), indicating that direct hypothalamic PKC activation lowered glucose production.

We then coinfused MBH OAG with the general PKC inhibitor BIM (60 µmol/l) or with the specific PKC- inhibitor Rot (60 µmol/l). We found that inhibition of hypothalamic PKC, or more specifically PKC-, with both inhibitors diminished the ability of MBH OAG to increase exogenous infusion rate and to lower glucose production (Fig. 1B and C). We administered OAG into the MBH in a different group of rats at the same concentration that was used in the clamp studies, and we found that MBH OAG selectively induced hypothalamic PKC- plasma membrane translocation (an accepted marker for PKC activation [24,25]) (Fig. 2A). Importantly, MBH OAG–induced PKC- membrane translocation was blocked by the coadministration of PKC- inhibitor Rot at the same concentration that blocked the ability of MBH OAG to lower glucose production (Fig. 1C). MBH OAG (with or without Rot) decreased PKC- content in the cytosolic fraction but with no parallel increase in the membrane fraction (Fig. 2B). Because we hypothesized that the activation of hypothalamic PKC leads to the activation/phosphorylation of the K_ATP channels that are located in the plasma membrane, we postulate that hypothalamic PKC- but not PKC- regulates glucose production. However, this remains to be proven. Together, these data suggest that hypothalamic PKC- activation lowered glucose production.

View larger version (20K): [in this window] [in a new window]   FIG. 2. Lipids activate hypothalamic PKC to lower glucose production. A: MBH OAG administration selectively induced hypothalamic PKC- plasma membrane translocation (n = 5 per group; *P < 0.05 vs. other individual groups; *P < 0.05 [ANOVA]), and this MBH OAG-induced hypothalamic PKC- translocation was reversed by coadministration of MBH PKC- inhibitor Rot. B: MBH OAG (with or without Rot) decreased the cytosolic content but did not increase the membrane content of hypothalamic PKC-. MBH BIM (n = 5) or Rot (n = 6) administration decreased the glucose infusion rate (C) and increased glucose production (D) in intravenous (IV) intralipid-infused rats. MBH VEH plus intravenous saline (n = 6); MBH vehicle (VEH) plus intravenous lipid (n = 6). E: Glucose uptake was comparable in all groups. *P < 0.001 (ANOVA) and P < 0.001 vs. the corresponding controls.

During the pancreatic basal insulin clamps, an elevation of plasma LCFA increases gluconeogenesis but not glucose production because of an inhibition of glycogenolysis (10,26,27). The activation of hypothalamic K_ATP channels by an approximately twofold elevation of circulating LCFA (induced by intravenous intralipid infusion) was recently demonstrated to inhibit glycogenolysis and compensate for the induction in gluconeogenesis (10). In light of the fact that 1) LCFAs activate PKC in liver and muscle (11–16) and 2) hypothalamic PKC-K_ATP channel activation lowers glucose production (demonstrated in the current study), we tested, using the same intravenous intralipid-infused model (10), whether activation of hypothalamic PKC is required for circulating LCFA to lower glucose production. We inhibited hypothalamic PKC activation with either MBH BIM (60 µmol/l) or Rot (60 µmol/l) administration to rats that received intravenous intralipid. MBH BIM or Rot decreased the exogenous glucose infusion rate required to maintain euglycemia in rats that received lipid infusion (Fig. 2C). The decrease in glucose infusion rate was fully accounted for by an elevation of glucose production, since glucose uptake was unchanged (Fig. 2D and E). Together, these data indicate that hypothalamic PKC activation is required for circulating lipids to lower glucose production.

Finally, we tested whether activation of hypothalamic PKC lowers glucose production in an early-onset (3 days of high-fat feeding) diet-induced hepatic insulin resistance model (2,28,29). We found that during the pancreatic basal insulin clamps, MBH OAG suppressed glucose production in high-fat–fed rats (5.7 + 0.7 mg · kg^–1 · min^–1 [MBH OAG; n = 5] vs. 11.5 + 0.5 mg · kg^–1 · min^–1 [MBH vehicle; n = 5], P < 0.001) to a similar extent as that observed in rats given a regular diet (Fig. 1C). These data indicate that direct PKC activation bypasses lipid-sensing defect(s) in the hypothalamus (28) to lower glucose production in the early onset of diet-induced insulin resistance.

	DISCUSSION

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
Our data first support the notion that activation of hypothalamic PKC is sufficient and necessary for CNS lipid-sensing mechanisms to lower glucose production through the activation/phosphorylation of hypothalamic Kir6.2/SUR1-containing K_ATP channels. However, much work is needed to further dissect the mechanisms in the hypothalamus or in other parts of this brain-liver axis that regulates glucose production. Second, these data support the working hypothesis that lipid-sensing mechanisms in the brain and liver share biochemical mechanisms but have opposing physiological mechanisms that regulate glucose production (1). Finally, our findings reveal hypothalamic PKC as a potential therapeutic target for lowering glucose levels in diabetes and obesity.

	ACKNOWLEDGMENTS

 
This work was supported by research grants to T.K.T.L. from the Canadian Institute of Health Research (MOP-86554) and the Banting and Best Diabetes Centre at the University of Toronto. R.R. is supported by the Ruth L. Kirschstein National Research Service Award Individual Fellowship (1F30AG029713-01). C.K.L.L. is supported by the Tamarack Graduate Studentship from the Banting and Best Diabetes Centre at the University of Toronto. R.G.-J. is supported by the National Institutes of Health (DK45024). G.J.S. is supported by the National Institutes of Health (DK47208) and the Skirball Institute. T.K.T.L. holds the John Kitson McIvor Endowed Chair in Diabetes Research at the University Health Network and University of Toronto.

	FOOTNOTES

 
Published ahead of print at http://diabetes.diabetesjournals.org on 28 May 2008.

Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered. See http://creativecommons.org/licenses/by-nc-nd/3.0/ for details.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received for publication February 13, 2008 and accepted in revised form May 16, 2008

	REFERENCES

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Caspi L, Wang PY, Lam TK: A balance of lipid-sensing mechanisms in the brain and liver. Cell Metab 6:99–104, 2007[CrossRef][Medline]
2. Chari M, Lam CK, Wang PY, Lam TK: Activation of central lactate metabolism lowers glucose production in uncontrolled diabetes and diet-induced insulin resistance. Diabetes 57:836–840, 2008[Abstract/Free Full Text]
3. Coll AP, Farooqi IS, O'Rahilly S: The hormonal control of food intake. Cell 129:251–262, 2007[CrossRef][Medline]
4. Coppari R, Ichinose M, Lee CE, Pullen AE, Kenny CD, McGovern RA, Tang V, Liu SM, Ludwig T, Chua SC, Lowell BB, Elmquist JK: The hypothalamic arcuate nucleus: a key site for mediating leptin's effects on glucose homeostasis and locomotor activity. Cell Metab 1:63–72, 2005[CrossRef][Medline]
5. Gelling RW, Morton GJ, Morrison CD, Niswender KD, Myers MG Jr, Rhodes CJ, Schwartz MW: Insulin action in the brain contributes to glucose lowering during insulin treatment of diabetes. Cell Metab 3:67–73, 2006[CrossRef][Medline]
6. Inoue H, Ogawa W, Asakawa A, Okamoto Y, Nishizawa A, Matsumoto M, Teshigawara K, Matsuki Y, Watanabe E, Hiramatsu R, Notohara K, Katayose K, Okamura H, Kahn CR, Noda T, Takeda K, Akira S, Inui A, Kasuga M: Role of hepatic STAT3 in brain-insulin action on hepatic glucose production. Cell Metab 3:267–275, 2006[CrossRef][Medline]
7. Konner AC, Janoschek R, Plum L, Jordan SD, Rother E, Ma X, Xu C, Enriori P, Hampel B, Barsh GS, Kahn CR, Cowley MA, Ashcroft FM, Bruning JC: Insulin action in AgRP-expressing neurons is required for suppression of hepatic glucose production. Cell Metab 5:438–449, 2007[CrossRef][Medline]
8. Obici S, Zhang BB, Karkanias G, Rossetti L: Hypothalamic insulin signaling is required for inhibition of glucose production. Nat Med 8:1376–1382, 2002[CrossRef][Medline]
9. Schwartz MW, Porte D Jr: Diabetes, obesity, and the brain. Science 307:375–379, 2005[Abstract/Free Full Text]
10. Lam TK, Pocai A, Gutierrez-Juarez R, Obici S, Bryan J, Aguilar-Bryan L, Schwartz GJ, Rossetti L: Hypothalamic sensing of circulating fatty acids is required for glucose homeostasis. Nat Med 11:320–327, 2005[CrossRef][Medline]
11. Boden G, She P, Mozzoli M, Cheung P, Gumireddy K, Reddy P, Xiang X, Luo Z, Ruderman N: Free fatty acids produce insulin resistance and activate the proinflammatory nuclear factor-B pathway in rat liver. Diabetes 54:3458–3465, 2005[Abstract/Free Full Text]
12. Chen S, Lam TK, Park E, Burdett E, Wang PY, Wiesenthal SR, Lam L, Tchipashvili V, Fantus IG, Giacca A: Oleate-induced decrease in hepatocyte insulin binding is mediated by PKC-delta. Biochem Biophys Res Commun 346:931–937, 2006[CrossRef][Medline]
13. Collins QF, Xiong Y, Lupo EG Jr, Liu HY, Cao W: p38 Mitogen-activated protein kinase mediates free fatty acid-induced gluconeogenesis in hepatocytes. J Biol Chem 281:24336–24344, 2006[Abstract/Free Full Text]
14. Griffin ME, Marcucci MJ, Cline GW, Bell K, Barucci N, Lee D, Goodyear LJ, Kraegen EW, White MF, Shulman GI: Free fatty acid–induced insulin resistance is associated with activation of protein kinase C theta and alterations in the insulin-signaling cascade. Diabetes 48:1270–1274, 1999[Abstract]
15. Lam TK, Yoshii H, Haber CA, Bogdanovic E, Lam L, Fantus IG, Giacca A: Free fatty acid-induced hepatic insulin resistance: a potential role for protein kinase C-delta. Am J Physiol Endocrinol Metab 283:E682–E691, 2002[Abstract/Free Full Text]
16. Samuel VT, Liu ZX, Qu X, Elder BD, Bilz S, Befroy D, Romanelli AJ, Shulman GI: Mechanism of hepatic insulin resistance in non-alcoholic fatty liver disease. J Biol Chem 279:32345–32353, 2004[Abstract/Free Full Text]
17. Tanaka C, Nishizuka Y: The protein kinase C family for neuronal signaling. Annu Rev Neurosci 17:551–567, 1994[CrossRef][Medline]
18. Light PE, Bladen C, Winkfein RJ, Walsh MP, French RJ: Molecular basis of protein kinase C-induced activation of ATP-sensitive potassium channels. Proc Natl Acad Sci U S A 97:9058–9063, 2000[Abstract/Free Full Text]
19. Pocai A, Lam TK, Gutierrez-Juarez R, Obici S, Schwartz GJ, Bryan J, Aguilar-Bryan L, Rossetti L: Hypothalamic KATP channels control hepatic glucose production. Nature 434:1026–1031, 2005[CrossRef][Medline]
20. Lam TK, Gutierrez-Juarez R, Pocai A, Rossetti L: Regulation of blood glucose by hypothalamic pyruvate metabolism. Science 309:943–947, 2005[Abstract/Free Full Text]
21. Baczko I, Jones L, McGuigan CF, Manning Fox JE, Gandhi M, Giles WR, Clanachan AS, Light PE: Plasma membrane KATP channel-mediated cardioprotection involves posthypoxic reductions in calcium overload and contractile dysfunction: mechanistic insights into cardioplegia. FASEB J 19:980–982, 2005[Abstract/Free Full Text]
22. He W, Lam TK, Obici S, Rossetti L: Molecular disruption of hypothalamic nutrient sensing induces obesity. Nat Neurosci 9:227–233, 2006[CrossRef][Medline]
23. Jung YS, Lee BK, Park HS, Shim JK, Kim SU, Lee SH, Baik EJ, Moon CH: Activation of protein kinase C-delta attenuates kainate-induced cell death of cortical neurons. Neuroreport 16:741–744, 2005[CrossRef][Medline]
24. Kraft AS, Anderson WB: Phorbol esters increase the amount of Ca2+, phospholipid-dependent protein kinase associated with plasma membrane. Nature 301:621–623, 1983[Medline]
25. Qi X, Inagaki K, Sobel RA, Mochly-Rosen D: Sustained pharmacological inhibition of deltaPKC protects against hypertensive encephalopathy through prevention of blood-brain barrier breakdown in rats. J Clin Invest 118:173–182, 2008[CrossRef][Medline]
26. Chen X, Iqbal N, Boden G: The effects of free fatty acids on gluconeogenesis and glycogenolysis in normal subjects. J Clin Invest 103:365–372, 1999[Medline]
27. Chu CA, Sherck SM, Igawa K, Sindelar DK, Neal DW, Emshwiller M, Cherrington AD: Effects of free fatty acids on hepatic glycogenolysis and gluconeogenesis in conscious dogs. Am J Physiol Endocrinol Metab 282:E402–E411, 2002[Abstract/Free Full Text]
28. Pocai A, Lam TK, Obici S, Gutierrez-Juarez R, Muse ED, Arduini A, Rossetti L: Restoration of hypothalamic lipid sensing normalizes energy and glucose homeostasis in overfed rats. J Clin Invest 116:1081–1091, 2006[CrossRef][Medline]
29. Wang PY, Caspi L, Lam CK, Chari M, Li X, Light PE, Gutierrez-Juarez R, Ang M, Schwartz GJ, Lam TK: Upper intestinal lipids trigger a gut-brain-liver axis to regulate glucose production. Nature 452:1012–1016, 2008[Medline]

CiteULike

Del.icio.us

Digg

Reddit

Technorati

This Article Abstract Full Text (PDF) All Versions of this Article: db08-0206v1 57/8/2061    most recent Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Google Scholar Articles by Ross, R. Articles by Lam, T. K.T. PubMed PubMed Citation Articles by Ross, R. Articles by Lam, T. K.T. Social Bookmarking                What's this?