Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-19T12:16:43.630Z Has data issue: false hasContentIssue false
  • English
  • Français

Effect of a novel proteoglycan PTP1B inhibitor from Ganoderma lucidum on the amelioration of hyperglycaemia and dyslipidaemia in db/db mice

Published online by Cambridge University Press:  27 March 2012

Chen-Dong Wang ,
Bao-Song Teng ,
Yan-Ming He ,
Jia-Sheng Wu ,
Deng Pan ,
Luan-Feng Pan ,
Dan Zhang ,
Zhao-Hua Fan ,
Hong-Jie Yang  and
Ping Zhou
Chen-Dong Wang
Affiliation:
Department of Macromolecular Science, Key Laboratory of Molecular Engineering of Polymers, Fudan University, Shanghai200433, People's Republic of China
Bao-Song Teng
Affiliation:
Department of Macromolecular Science, Key Laboratory of Molecular Engineering of Polymers, Fudan University, Shanghai200433, People's Republic of China
Yan-Ming He
Affiliation:
Yueyang Hospital of Integrated Traditional Chinese and Western Medicine, Shanghai University of Traditional Chinese Medicine, Shanghai200437, People's Republic of China
Jia-Sheng Wu
Affiliation:
Pharmacy College, Shanghai University of Traditional Chinese Medicine, Shanghai201203, People's Republic of China
Deng Pan
Affiliation:
Department of Macromolecular Science, Key Laboratory of Molecular Engineering of Polymers, Fudan University, Shanghai200433, People's Republic of China
Luan-Feng Pan
Affiliation:
Laboratory of Molecular Biology, Shanghai Medical College, Fudan University, Shanghai200032, People's Republic of China
Dan Zhang
Affiliation:
Yueyang Hospital of Integrated Traditional Chinese and Western Medicine, Shanghai University of Traditional Chinese Medicine, Shanghai200437, People's Republic of China
Zhao-Hua Fan
Affiliation:
Yueyang Hospital of Integrated Traditional Chinese and Western Medicine, Shanghai University of Traditional Chinese Medicine, Shanghai200437, People's Republic of China
Hong-Jie Yang*
Affiliation:
Yueyang Hospital of Integrated Traditional Chinese and Western Medicine, Shanghai University of Traditional Chinese Medicine, Shanghai200437, People's Republic of China
Ping Zhou
Affiliation:
Department of Macromolecular Science, Key Laboratory of Molecular Engineering of Polymers, Fudan University, Shanghai200433, People's Republic of China
*
*Corresponding authors: P. Zhou, fax +86 21 55664038, email [email protected] and H.-J. Yang, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Protein tyrosine phosphatase 1B (PTP1B) is implicated in the negative regulation of the insulin signalling pathway by dephosphorylating the insulin receptor (IR) and IR substrates. Ganodermalucidum has traditionally been used for the treatment of diabetes in Chinese medicine; however, its anti-diabetic potency and mechanism in vivo is still unclear. Our previously published study reported a novel proteoglycan PTP1B inhibitor, named Fudan-Yueyang-Ganoderma lucidum (FYGL) from G. lucidum, with a half-maximal inhibitory concentration (IC50) value of 5·12 (sem 0·05) μg/ml, a protein:polyglycan ratio of 17:77 and 78 % glucose in polysaccharide, and dominant amino acid residues of aspartic acid, glycine, glutamic acid, alanine, serine and threonine in protein. FYGL is capable of decreasing plasma glucose in streptozotocin-induced diabetic mice with a high safety of median lethal dose (LD50) of 6 g/kg. In the present study, C57BL/6 db/db diabetic mice were trialed further using FYGL as well as metformin for comparison. Oral treatment with FYGL in db/db diabetic mice for 4 weeks significantly (P < 0·01 or 0·05) decreased the fasting plasma glucose level, serum insulin concentration and the homeostasis model assessment of insulin resistance. FYGL also controlled the biochemistry indices relative to type 2 diabetes-accompanied lipidaemic disorders. Pharmacology research suggests that FYGL decreases the plasma glucose level by the mechanism of inhibiting PTP1B expression and activity, consequently, regulating the tyrosine phosphorylation level of the IR β-subunit and the level of hepatic glycogen, thus resulting in the improvement of insulin sensitivity. Therefore, FYGL is promising as an insulin sensitiser for the therapy of type 2 diabetes and accompanied dyslipidaemia.

Keywords

Ganoderma lucidumProtein tyrosine phosphatase 1BDiabetesdb/db Mice
Type
Full Papers
Information
British Journal of Nutrition , Volume 108 , Issue 11 , 14 December 2012 , pp. 2014 - 2025
Copyright
Copyright © The Authors 2012

Diabetes is recognised as a group of metabolic disorders with the common elements of hyperglycaemia and glucose intolerance, due to insulin deficiency or impaired insulin action(Reference Harris and Zimmet1). As such, enhancing insulin sensitivity is a primary strategy to improve metabolic control in subjects with type 2 diabetes. Insulin acts as a ligand that binds to insulin receptors (IR) of insulin-sensitive tissues such as liver, skeletal muscle and adipose tissue. The coordinated tyrosine phosphorylation of receptors is essential for signalling pathways regulated by insulin and leptin. Protein tyrosine phosphatases (PTP) are the regulators of tyrosine phosphorylation-dependent cellular events that govern numerous critical physiological processes(Reference Barr, Ugochukwu and Lee2, Reference Valentino and Pierre3). Among the PTP family members, PTP1B first purified from the PTP family in the human placenta(Reference Tonks, Diltz and Fischer4) is known to be a key negative regulator of the IR signal transduction pathway(Reference Goldstein5). Vast amounts of studies on chemical, biochemical, cellular, animal and human genetic levels have identified the importance of PTP1B for both insulin and leptin signalling(Reference Goldstein5Reference Elchebly, Payette and Michaliszyn12). As an enzyme dephosphorylating the IR in the liver and skeletal muscle, PTP1B acts as an important mediator for the control of blood glucose levels and body weight through regulating IR and leptin signalling(Reference Seely, Staubs and Reichart6Reference Cromlish, Tang and Kyskan8). PTP1B interacts with and dephosphorylates the IR as well as the IR substrate (IRS). If PTP1B did not dephosphorylate the IRS, the phosphorylated IRS would serve as an adaptor protein and recruit phosphatidylinositol 3-kinase (PI3K) via the regulatory subunit; PI3K would then catalyse the conversion of phosphatidylinositol to 3,4-bis- and 3,4,5-trisphosphate that would stimulate the activity of phosphoinositide-dependent kinase-1. Together with phosphoinositide-dependent kinase-2, phosphoinositide-dependent kinases activate serine/threonine protein kinase (Akt or protein kinase B (PKB)), via the phosphorylation of a critical serine and threonine residue(Reference Asante-Appiah and Kennedy9). If PTP1B were overexpressed, then most of the IRS would be dephosphorylated and a series of enzymes such as PI3K and PKB participating in the process of glucose uptake would be inactivated since the insulin transduction pathway is blocked(Reference Saltiel10). Insulin-resistant states show the increase in PTP1B activity(Reference Ahmad, Azevedo and Cortright11). Mice that lack PTP1B display an enhanced sensitivity to insulin, with increased or prolonged tyrosine phosphorylation of the IR in the liver and muscle(Reference Elchebly, Payette and Michaliszyn12). In addition, PTP1B deficiency for PTP1B knockout suckling mice increases the content of glycogen and serum TAG in the liver, compared with that for wild-type controls(Reference Escriva, Rodriguez and Millan13). On the basis of these findings, the inhibition of PTP1B has emerged as an attractive therapeutic strategy to treat type 2 diabetes and obesity. The dependence of diabetes and obesity on PTP1B has increased research interest for searching more efficient PTP1B inhibitors during the last decade(Reference Van Huijsduijnen, Bombrun and Swinnen14Reference Combs16). Unfortunately, most of the small-molecule inhibitors of PTP1B have been proven difficult to be developed into effective drugs due to their low cell permeability and bioavailability(Reference Park, Bhattarai and Ham15, Reference Combs16); efforts on finding more efficient PTP1B inhibitors are still undergoing.

Ganoderma lucidum is one of the oldest mushrooms used to treat many ailments including endocrine-related diseases in traditional Chinese medicine. Scientific investigations have confirmed the beneficial effects of bioactive components isolated from G. lucidum on the prevention and treatment of human diseases(Reference Wasser and Weis17Reference Hikino and Mizuno22). Antihyperglycaemic effects of the active extracts from G. lucidum in vivo have already been reported(Reference Seto, Lam and Tam19Reference Hikino and Mizuno22). As an important biologically active component in G. lucidum, polysaccharide is now arousing a great interest for its essential role in metabolism(Reference Meng, Zhu and Yang20, Reference Hikino and Mizuno22, Reference Wachtel-Galor, Tomlinson and Benzie23). It is reported that the polysaccharide of G. lucidum exerts its antihyperglycaemic function by influencing the metabolic pathway of hepatic glycogen(Reference Yang, Jeong and Park21). Studies(Reference Meng, Zhu and Yang20, Reference Hikino and Mizuno22) have indicated that the polysaccharide of G. lucidum can promote the release of serum insulin by mediating the activity of various enzymes participating in glucose metabolism, and then decrease plasma glucose in vivo. In our previously published study(Reference Teng, Wang and Yang24), a novel proteoglycan, named Fudan-Yueyang-G. lucidum (FYGL), from the fruiting bodies of G. lucidum was also reported to be capable of decreasing plasma glucose in streptozotocin-induced mice with a high safety of median lethal dose (LD50) of 6 g/kg. FYGL shows an efficient PTP1B inhibitory potency with a half-maximal inhibitory concentration (IC50) value of 5·12 (sem 0·05) μg/ml and competitive inhibition kinetics with the substrate of PTP1B in vitro. FYGL is a water-soluble proteoglycan covalently bonded with protein and polyglycan in a ratio of 17:77. Among six monosaccharides (glucose, arabinose, xylose, rhamnose, galactose and fructose) involved in FYGL, the major monosaccharide is glucose in contents of 78 %, while among twenty natural amino acids, the major amino acids involved are aspartic acid, glycine, glutamic acid, alanine, serine and threonine in contents of 13, 11, 10, 9, 9 and 8, respectively. The viscosity-averaged molecular weight of FYGL is 2·6 × 105. Although FYGL properties have been investigated, its antihyperglycaemic mechanism in vivo is still unclear and further research is necessary. In the present study, we used the C57BL/6 db/db mouse, which is a useful model of type 2 diabetes associated with dyslipidaemia(Reference Kobayashi, Forte and Taniguchi25) and insulin resistance(Reference Kodama, Fujita and Yamaguchi26) to evaluate pharmacological potencies of FYGL such as plasma glucose level, serum insulin concentration and lipid profiles in the serum and liver. In addition, the expression and activity of PTP1B, the levels of tyrosine phosphorylation of IR β-subunit and hepatic glycogen were also investigated to reveal antihyperglycaemic mechanisms of FYGL in vivo.

Materials and methods

Materials and chemicals

All the dried fruiting bodies of G. lucidum were purchased from Shanghai Leiyunshang Pharmaceutical Company Limited. The kit for the analysis of insulin was purchased from Beifang Biotech Research Center. The kits for the analysis of TAG, total cholesterol (TC), LDL-cholesterol (LDL-C), HDL-cholesterol (HDL-C), NEFA and hepatic glycogen were purchased from Nanjing Jianchen Bioengineering Institute. Metformin, bovine serum albumin, porcine insulin, p-nitrophenyl phosphate, Tris, Nonidet P-40 and nitrocellulose (NC) membranes were purchased from Sigma Chemical Company. The reagents for SDS-PAGE and immunoblotting experiments were purchased from BioVision and the necessary apparatus from Bio-Rad. Protein A-Sepharose was from Pharmacia. α-PTP1B polyclonal antibody, rabbit polyclonal anti-IR β-subunit antibody and monoclonal anti-phosphotyrosine antibody (PY99) were purchased from Santa Cruz Biotechnology, Inc. Anti-rabbit IgG (IgG) conjugated with horseradish peroxidase and enhanced chemiluminescence detection reagents were from GE, Inc. Bradford protein assay reagent was purchased from Bio-Rad. All other chemicals were of the highest analytical grade.

Preparation of Fudan-Yueyang-Ganoderma lucidum from Ganoderma lucidum

FYGL was extracted from the dried fruiting bodies of G. lucidum with optimised techniques as described in Fig. 1(Reference Teng, Wang and Yang24). Briefly, 160 g dried fruiting bodies of G. lucidum were milled and then degreased with 2 litres of 95 % boiling ethanol for 30 min. The residues were dried and then decocted with stirring in 3 litres of boiling water for 2 h. After filtration, the residues were treated with 2 litres of 2 m-NH3 aqueous solution at room temperature for 24 h, then the supernatant was neutralised by 2 m-acetic acid and then dialysed, concentrated and precipitated with 80 % (v/v) ethanol. The supernatant was subjected to Sephadex G75 column chromatography with 2m-NaCl solution as the eluent. The eluates were collected and characterised by the phenol–sulphuric acid method with UV absorption at a wavelength of 490 nm. In this analysis, three fractions were collected, and then dialysed and lyophilised. The fraction having the best PTP1B inhibition was named as FYGL. The yield of FYGL is about 0·96 % from raw material and the purity of FYGL obtained is 91 % measured by gel permeation chromatography with double detectors of UV (λ = 254 nm) and refractive index.

Fig. 1 Screening procedure of Fudan-Yueyang-Ganoderma lucidum (FYGL) from Ganoderma lucidum.

In vivo experimental design

A total of ten C57BL/6 mice and twenty-eight type 2 diabetic C57BL/6 db/db mice (male, 5–8 weeks old) were bought from Shanghai Institute of Materia Medica, Chinese Academy of Sciences. All animal trial procedures instituted by the Ethical Committee for the Experimental Use of Animals and for Drug Safety Evaluation in Shanghai University of Traditional Chinese Medicine were followed. The ten C57BL/6 mice were set as group I, normal mice. The twenty-eight type 2 diabetic db/db mice were divided into four groups: group II, diabetic control mice; group III, diabetic mice treated with 75 mg/kg low dose of FYGL; group IV, diabetic mice treated with 225 mg/kg high dose of FYGL; group V, diabetic mice treated with 200 mg/kg dose of metformin. The mice were distributed based on the mean initial blood glucose levels within the four diabetic groups. All drugs were dissolved in 0·9 % saline and administered intragastrically for 4 weeks. During the experimental period, the body weight and blood glucose of 12 h fasted mice were measured every week. The dosage was adjusted every week according to any change in body weight to maintain a similar dose per kg of mice over the entire period of study for each group.

At the end of the treatment, mice were fasted overnight, anaesthetised and killed by cervical decapitation. Before killing, all the animals were administered intraperitoneally with insulin (3 U/kg in saline with 0·1 % bovine serum albumin). After killing, the liver, soleus muscle and adipose tissue were also immediately removed from all the animals in 10 min after the insulin injection and quickly frozen in liquid N2, and then the tissues were stored in a freezer at − 70°C for analysis. In the present study, all procedures used for animal trials were in accordance with the Regulations of Experimental Animal Administration issued by State Committee of Science and Technology of the People's Republic of China on 14 November 1988. The study was approved (no. SYXK (Shanghai) 2009-0065; SCXK (Shanghai) 2007-0005) by the Ethical Committee on Animal Experimentation in the Shanghai University of Traditional Chinese Medicine.

Measurements of plasma glucose and insulin levels

Plasma samples were obtained from the tail vein 2 h before the oral administration of the drugs every week for plasma glucose analysis. The glucose level in the plasma was measured using the glucose oxidase method (sensitivity of 0·1 mm; Sigma Diagnostics). The final fasting plasma samples were obtained by celiac puncture under halothane anaesthesia before mice were killed, and then centrifuged (3000 g, 15 min) at 4°C for the separation of serum insulin, which was measured by the RIA method.

Lysate preparation and protein assay in vivo

Briefly, 50 mg of the frozen liver sample were homogenised in 2 ml ice-cold lysis buffer containing 50 mm-N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid (pH 7·4), 100 mm-sodium fluoride, 10 mm-sodium pyrophosphate, 4 mm-EDTA, 2 mm-sodium orthovanadate and 1 % Triton X-100, and the homogenate was centrifuged (12 000 g, 15 min) at 4°C to remove the insoluble material. Similarly, 50 mg of the frozen muscle sample were homogenised in 50 mmol/l ice-cold HEPES buffer (pH 7·4) containing 150 mm-NaCl, 10 mm-sodium pyrophosphate, 2 mm-Na3VO4, 10 mm-NaF, 2 mm-edetic acid, 2 mm-phenylmethylsulfonyl fluoride, 10 μm-leupeptin, 1 % (v/v) Nonidet P-40 and 10 % (v/v) glycerol, and the homogenate was centrifuged (12 000 g, 15 min) at 4°C. The supernatant homogenate from the trialed mice tissue was collected individually, and the protein concentration in the homogenate was measured with Bradford protein assay reagent, using bovine serum albumin as the standard.

Western blotting for protein tyrosine phosphatase 1B expression analysis in vivo

Liver or muscle supernatant homogenate containing 20 μg protein was run on SDS-PAGE (10 % gel) and transferred electrophoretically onto the NC membrane for 5 h. The NC membrane was then blocked for 2 h at room temperature with the block solution provided in enhanced chemiluminescence kits. The NC membrane was incubated with anti-α-PTP1B polyclonal antibody overnight at 4°C, and then with anti-rabbit IgG conjugated with horseradish-peroxidase in block solution for 1 h, and washed for 30 min with wash solution (provided in enhanced chemiluminescence kits). The immunoreactive lanes on the NC membrane were detected by the enhanced chemiluminescence method and digitalised by the Gel Documentation System. Each membrane was blotted with ten lanes, and two mice from the same group were analysed in two adjacent lanes in one NC membrane. In total there were four NC membranes for all trialed mice and the results are averaged by ten (for the normal group) or seven (for the other groups) mice data in one group.

The PTP1B expressions in adipose tissue were not analysed because not enough samples were obtained.

Protein tyrosine phosphatase 1B activity in vivo

Briefly, 100 mg of the frozen tissue sample were homogenised in 1 ml ice-cold buffer containing 50 mm-Tris and 150 mm-NaCl, and the homogenates were centrifuged (12 000 g, 15 min for liver, 20 min for muscle and 30 min for adipose tissue) at 4°C to remove the insoluble material. The supernatant homogenate from the trialed mice tissue was collected individually, and the protein concentration in the homogenate was measured with Bradford protein assay reagent, using bovine serum albumin as the standard.

The assay protocol of PTP1B activity in the tissue homogenate followed the kit's instruction. Briefly, PTP1B activity was measured by adding 50 μl of 1 mm-p-nitrophenyl phosphate (p-nitrophenyl phosphate as the substrate) buffer solution (pH 8·0, containing 50 mm-Tris and 150 mm-NaCl) into 50 μl of tissue supernatant homogenate containing 20 μg protein. After incubation for 30 min at 37 °C, the PTP1B enzyme reaction was terminated by the addition of 200 μl of 3 m-NaOH. The amount of p-nitrophenol produced was measured by UV absorption at a wavelength of 405 nm with a microplate reader.

Tyrosine phosphorylation level of insulin receptor β-subunit in vivo

Liver or muscle supernatant homogenate containing 1 mg protein was immunoprecipitated overnight with 2 μg anti-IR β-subunit antibody coupled to protein A-Sephrose at 4°C. The immune complex was washed twice with PBS (pH 7·4) containing 1 % Nonidet P-40 and 2 mm-Na3VO4, and resuspended in Laemmli buffer, and boiled for 5 min. The protein was quantified and run on SDS-PAGE (10 % gel), and then electrotransferred from the gel to the NC membrane. The NC membrane was incubated with 1 mg/l PY99 overnight at 4°C. The following steps were performed as described in the section ‘Western blotting for PTP1B expression analysis in vivo’.

The tyrosine phosphorylation levels of the IR β-subunit in adipose tissue were also not analysed because not enough samples were obtained.

Measurement of the lipid profile in the serum

Plasma samples for lipid profile analysis were obtained from mice killed at the end of the treatment. TAG, TC, LDL-C and HDL-C levels in the serum were measured following the commercial kit's instructions.

Assay of the lipid profile and glycogen in the liver

Briefly, 100 mg of the frozen liver sample were homogenised in 1 ml of 0·9 % saline and shaken for 30 min at 4°C. The homogenate was centrifuged (12 000 g) for 15 min at 4°C and total lipids of the liver homogenates were extracted with a mixture of chloroform and methanol (2:1, v/v) on the basis of the method of Folch et al. (Reference Folch, Lees and Sloane Stanley27), and the supernatant homogenate was collected. NEFA, TAG and TC levels in the liver were measured according to the commercial kit's instructions.

Then, 50 mg of the frozen liver sample were digested in 500 μl of 30 % KOH in boiling water for 15 min, and then glycogen in the liver was measured following the commercial kit's instructions.

The lipid profile and glycogen in the skeletal muscle were not analysed because not enough samples were obtained.

Statistical analysis

Data are expressed as means with their standard errors. The statistical differences between the mean values in the two groups were analysed by Student's t test and one-way ANOVA using Origin 7 Software (MicroCal Software). A P value less than 0·05 or 0·01 is considered as a significant or very significant difference between the means.

Results

Plasma glucose levels, homeostasis model assessment of insulin resistance and insulin concentration in vivo

The antihyperglycaemic potency of FYGL showed dose-dependency against diabetic control mice, as shown in Fig. 2. The results of the drug treatments for 4 weeks are summarised in Table 1. As can be observed from Table 1, the fasting plasma glucose level was significantly higher (P < 0·001) in diabetic control mice (27·5 (sem 2·8) mmol/l) than in normal mice (6·9 (sem 0·4) mmol/l). The level of fasting plasma glucose in diabetic mice treated with a high dose of FYGL daily for 4 weeks was significantly decreased (19·5 (sem 2·1) mmol/l, P < 0·01), compared with diabetic control mice (27·5 (sem 2·8) mmol/l) and metformin-treated mice (13·9 (sem 1·4) mmol/l) without any statistically significant difference.

Fig. 2 Potencies of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on plasma glucose in vivo. The drugs were administered orally once per d for 4 weeks. Values are means, with their standard errors represented by vertical bars. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the normal group: ** P < 0·01, *** P < 0·001. Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01, ††† P < 0·001. , 1 Week; , 2 weeks; , 3 weeks; , 4 weeks.

Table 1 Characteristics of the trialed animals after 4 weeks of drug treatments (Mean values with their standard errors)

HOMA-IR, homeostasis model assessment of insulin resistance; HOMA-β, homeostasis model assessment of β-cell function; FYGL, Fudan-Yueyang-Ganoderma lucidum.

*** Mean values were significantly different from those of the normal group (P < 0·001).

Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01, ††† P < 0·001.

The statistical differences between the mean values in the two groups were analysed by Student's t test and one-way ANOVA.

§ HOMA-IR = (plasma insulin level (μIU/ml) × plasma glucose level (mmol/l))/22·5.

HOMA-β = (20 × plasma insulin level (μIU/ml))/(plasma glucose level (mmol/l) − 3·5).

It was also noted that the homeostasis model assessment of insulin resistance (HOMA-IR) was significantly higher (P < 0·001) in diabetic control mice (15·8 (sem 0·9)) than in normal mice (3·8 (sem 0·3)), while homeostasis model assessment of β-cell function (HOMA-β) was significantly lower (P < 0·001) in diabetic control mice (10·8 (sem 0·5)) than in normal mice (72·4 (sem 1·6)). After the mice were treated with FYGL and metformin for 4 weeks, serum insulin concentration and HOMA-IR were significantly lower in diabetic mice treated with a high dose of FYGL (9·7 (sem 1·0) μIU/ml, P < 0·05 and 8·4 (sem 0·9), P < 0·01, respectively) than in diabetic control mice (13·0 (sem 0·7) μIU/ml and 15·0 (sem 1·5), respectively) while FYGL had no effect on HOMA-β. HOMA-IR (9·3 (sem 0·9), P < 0·001) in metformin-treated diabetic mice was significantly reduced and HOMA-β (28·8 (sem 1·2)) was significantly higher (P < 0·001) than that in diabetic control mice (10·8 (sem 0·5)). In addition, there was no significant difference in the final body weight and body-weight growth trend among the diabetic control mice and the FYGL- and metformin-treated diabetic mice (see Table 1 and Fig. 3).

Fig. 3 Potencies of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on body weight in vivo. The drugs were administered orally once per d for 4 weeks. Values are means, with their standard errors represented by vertical bars. , Normal; , diabetic control; , 75 mg/kg FYGL; , 225 mg/kg FYGL; , 225 mg/kg metformin.

Effects of Fudan-Yueyang-Ganoderma lucidum on protein tyrosine phosphatase 1B expression in the liver and skeletal muscle

PTP1B content in the tissues of normal mice is referred to as 100 %. As can be seen from Fig. 4, PTP1B levels in the liver and skeletal muscle of the diabetic control were increased by 21 and 62 % (P <0·01), respectively, compared with those of normal mice. In contrast, in diabetic mice treated with a high dose of FYGL, the PTP1B level was significantly reduced by 34 % (P <0·05) in the liver (Fig. 4(a) and (a′)) and 38 % (P <0·001) in the skeletal muscle (Fig. 4(b) and (b′)), compared with that of diabetic control mice, but metformin had no significant effect on the PTP1B content in the tissues.

Fig. 4 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on protein tyrosine phosphatase 1B (PTP1B) expression in (a, a′) the liver and (b, b′) skeletal muscle. Values are means, with their standard errors represented by vertical bars, in the normal group referred to as 100 %. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the normal group: *** P < 0·001. Mean values were significantly different from those of the diabetic control group: † P < 0·05, ††† P < 0·001. The images (a) and (b) on the nitrocellulose (NC) membranes represent the results of the analysis of the liver and skeletal muscle, respectively, on one of four NC membranes.

Effects of Fudan-Yueyang-Ganoderma lucidum on protein tyrosine phosphatase 1B activity in the liver, muscle and adipose tissue

PTP1B activity in the tissues of normal mice is referred to as 100 %. It can be observed from Fig. 5 that PTP1B activities in the liver, skeletal muscle and adipose tissue of the diabetic control were increased by 47 % (Fig. 5(a)), 25 % (Fig. 5(b)) and 50 % (Fig. 5(c)), respectively, compared with that in the normal group. When diabetic mice were treated with a high dose of FYGL, PTP1B activities were significantly decreased by 49 % in the liver (Fig. 5(a)), 55 % (P < 0·01) in the skeletal muscle (Fig. 5(b)) and 19 % in the adipose tissue (Fig. 5(c)), compared with that in the diabetic control. It was found that FYGL shows a dose-dependency against PTP1B activity in the tissues of db/db mice. The 200 mg/kg dose of metformin reduces PTP1B activity in the liver and skeletal muscle while no effect was found on PTP1B activity in the adipose tissue of diabetic mice.

Fig. 5 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on protein tyrosine phosphatase 1B (PTP1B) activities in (a) liver, (b) skeletal muscle and (c) adipose tissue. Values are means, with their standard errors represented by vertical bars, in the normal group referred to as 100 %. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the diabetic control group: †† P < 0·01.

Effects of Fudan-Yueyang-Ganoderma lucidum on the relative active ratio of protein tyrosine phosphatase 1B in the liver and skeletal muscle

When considering the active ratio of PTP1B which is calculated by PTP1B activity over the PTP1B expression, we found that 225 mg/kg FYGL significantly decreased the relative active ratio of PTP1B by 22 % (P < 0·01) in the liver (Fig. 6(a)) and 41 % (P < 0·01) in the skeletal muscle (Fig. 6(b)), compared with that in the diabetic control.

Fig. 6 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on the relative active ratio of protein tyrosine phosphatase 1B (PTP1B) in (a) the liver and (b) skeletal muscle. Values are means, with their standard errors represented by vertical bars. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the normal group: ** P < 0·01. Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01, ††† P < 0·001.

Effects of Fudan-Yueyang-Ganoderma lucidum on the tyrosine phosphorylation level of the insulin receptor β-subunit in the liver and skeletal muscle

The tyrosine phosphorylation level of the IR β-subunit in normal mice is referred to as 100 %. It was observed that the tyrosine phosphorylation levels of the IR β-subunit in the diabetic control were 89 % in the liver (Fig. 7(a) and (a′)) after stimulation with insulin. The tyrosine phosphorylation level (129 %) in the liver of diabetic mice treated with a high dose of FYGL was significantly higher (P < 0·05) than that (89 %) of control mice, as shown in Fig. 7(a) and (a′). Similarly, the tyrosine phosphorylation level (130 %) in the skeletal muscle of mice treated with a high dose of FYGL was significantly higher (P < 0·01) than that (82 %) of control mice, as shown in Fig. 7(b) and (b′). The effect of FYGL on the tyrosine phosphorylation level of the IR β-subunit in vivo was dose-dependent; in contrast, metformin had no effect on the tyrosine phosphorylation level of the IR β-subunit in vivo.

Fig. 7 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on the insulin-stimulated tyrosine phosphorylation levels of insulin receptor (IR) β-subunit in (a) the liver and (b) skeletal muscle. The quantitative analysis of the relative IR β-subunit tyrosine phosphorylation levels in (a′) the liver and (b′) skeletal muscle of drug-treated mice is referred to that of the insulin-stimulated normal mice. Values are means, with their standard errors represented by vertical bars, in the normal group referred to as 100 %. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01. The images (a) and (b) on the nitrocellulose (NC) membranes represent the results of the analysis of the liver and skeletal muscle, respectively, on one of four NC membranes.

Effects of Fudan-Yueyang-Ganoderma lucidum on the serum lipid profile in vivo

The effects of the drugs including FYGL and metformin on the serum lipid profile in vivo after 4 weeks of treatment are summarised in Table 2. The TAG, TC, LDL-C and HDL-C levels were significantly decreased by 52·8 % (P < 0·01), 65·9 % (P < 0·001), 75·2 % (P < 0·001) and 41·7 % (P < 0·05), respectively, in db/db diabetic mice treated with a high dose of FYGL, compared with those for the diabetic control, and the potency of FYGL was dose-dependent. However, metformin had no obvious effect on the serum lipid profiles of db/db diabetic mice.

Table 2 Effects of the drugs on the serum lipid profile in vivo after 4 weeks of treatment (Mean values with their standard errors)

TC, total cholesterol; LDL-C, LDL-cholesterol; HDL-C, HDL-cholesterol; FYGL, Fudan-Yueyang-Ganoderma lucidum.

Mean values were significantly different from those of the normal group: ** P < 0·01, *** P < 0·001.

Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01, ††† P < 0·001.

The statistical differences between the mean values in the two groups were analysed by Student's t test and one-way ANOVA.

Effects of Fudan-Yueyang-Ganoderma lucidum on the lipid profile and glycogen in the liver

The effects of the drug treatments on the lipid profile and glycogen in the liver are summarised in Table 3. As can be observed from Table 3, the TAG, TC, NEFA and glycogen levels in the liver were significantly increased (P < 0·05) in diabetic control mice, compared with that in normal mice. After 4 weeks, the TAG, TC and NEFA levels were significantly decreased by 65·6 % (P < 0·001), 60·7 % (P < 0·001) and 31·5 % (P < 0·05), respectively, while the hepatic glycogen level was significantly increased by 109·6 % (P < 0·001) in diabetic mice treated with a high dose of FYGL, compared with that of the diabetic control, and the potency of FYGL was dose-dependent. It was also observed that the TAG and hepatic glycogen levels were decreased by 60·2 % (P < 0·001) and 19·1 %, respectively, while the TC and NEFA levels were increased by 21·4 and 8·2 %, respectively, in metformin-treated diabetic mice, compared with those of the diabetic control.

Table 3 Effects of the drugs on TAG, total cholesterol (TC) and NEFA levels in the liver and hepatic glycogen in vivo after 4 weeks of treatment (Mean values with their standard errors)

FYGL, Fudan-Yueyang-Ganoderma lucidum.

Mean values were significantly different from those of the normal group: * P < 0·05, ** P < 0·01, *** P < 0·001.

Mean values were significantly different from those of the diabetic control group: † P < 0·05, ††† P < 0·001.

The statistical differences between the mean values in the two groups were analysed by Student's t test and one-way ANOVA.

Discussion

Type 2 diabetes is a metabolic disorder characterised by insulin resistance, hyperglycaemia and dyslipidaemia. PTP1B is a 50 kDa cytosolic tyrosine dephosphorylase consisting of 435 amino acids that is widely expressed in human organs(Reference Chernoff, Schievella and Jost28). It is well known that PTP1B dephosphorylates both the phosphorylated IR β-subunit and the phosphorylated IRS to regulate negatively the insulin signal transmission(Reference Asante-Appiah and Kennedy9). PTP1B inhibitors can be divided into two types: competitive inhibitors and non-competitive inhibitors. Most of the small-molecule competitive inhibitors mimic the phosphorylated tyrosine IR, while most of the non-competitive inhibitors act via oxidation of the catalytic cysteine Cys215 or by preventing the closure of the WPD loop(Reference Bialy and Waldmann29). Unfortunately, most of the small-molecule inhibitors fail to succeed in vivo. To date, finding a selective small-molecule phosphatase inhibitor with good cell permeability and oral bioavailability in vivo is difficult mainly due to the highly polar phosphatase active site and the shallowness of the surrounding protein surface, which do not allow for the productive bindings of the typical lipophilic membrane with the permeable small-molecule phosphatase inhibitor(Reference Park, Bhattarai and Ham15, Reference Combs16). Significantly, FYGL, a water-soluble macromolecular proteoglycan(Reference Teng, Wang and Yang24) different from those small-molecule PTP1B inhibitors, does successfully inhibit the PTP1B activity and decrease the plasma glucose in vivo.

Possible interaction sites of protein tyrosine phosphatase 1B with Fudan-Yueyang-Ganoderma lucidum

There exist various interactions between PTP1B and its inhibitors. Seiner et al. (Reference Seiner, Labutti and Gates30) found an acrolein PTP1B inhibitor binding to PTP1B via the conjugation of the carbon–carbon double bond of acrolein to the catalytic cysteine residue. Liu et al. (Reference Liu, Gao and Voigt31) reported a PTP1B analogue of 6-(phosphonodifluoromethyl)-2-naphthoic acid binding to PTP1B with its 2-carboxyl group through a bridge of a water molecule. Liu et al. (Reference Liu, Tan and Niu32) designed a bidentate PTP1B inhibitor called SNA. The authors proposed that electrostatic interactions are more likely to be present between PTP1B and SNA than van der Waals interactions, and amino acid residues of Lys41, Arg47 and Asp48 play important roles in the determination of the SNA conformation, potency and selectivity. Asante-Appiah et al. (Reference Asante-Appiah, Patel and Dufresne33) designed a peptide PTP1B inhibitor, N-benzoyl-l-glutamyl-(4-phosphono-(difluoromethyl))-l-phenylalanine-(4-phosphono-(difluoro-methyl))-l-phenylalanineamide (BzN-EJJ-amide). The crystal structure of PTP1B in the complex of PTP1B with BzN-EJJ-amide showed that the hydrogen bond between BzN-EJJ-amide and Asp48 in PTP1B is of particular significance.

FYGL is constructed covalently by protein and polysaccharide. Generally, proteoglycan is formed by the protein backbone and polysaccharide side chains(Reference Bartlett and Park34). The protein is linked with polysaccharide by either O-linkages or N-linkages. The biological activities of proteoglycan are controlled by the interactions of polysaccharide side chains with the surrounding proteins through secondary bonding(Reference Bartlett and Park34). Although proteoglycans are difficult to pass through the cell membranes, they could be dissociated by the glycosidase(Reference Bach-Knudsen and Jørgensen35) to enter through the cells. Actually, we found that FYGL can interact with glycosidase in vitro (data not shown), suggesting that FYGL could be hydrolysed by the glycosidase into polysaccharide and protein in the stomach and small intestine in vivo; consequently, the dissociated protein motifs in FYGL might enter into the plasma through pinocytosis in the terminal position of the small intestine and then interact with PTP1B to inhibit the PTP1B activity in the insulin target tissues in vivo.

The viscosity-averaged molecular weight of FYGL (2·6 × 105) is larger than the molecular weight of PTP1B (50 kDa). However, the molecular weight of the protein motif in FYGL might be about 44 kDa evaluated on the protein:polysaccharide ratio of 17:77. On the other hand, the molecular weight of the PTP1B native substrate, IR β-subunit, is 95 kDa compared with that of the protein motif of FYGL. Therefore, the protein motif of FYGL might possibly interact with PTP1B in vivo by hydrogen bonding between the carboxyl groups of aspartic acid and glutamic acid in FYGL and Tyr20, Arg24 and Arg254 in PTP1B active sites(Reference Liu, Xin and Liang36), competing with the IR β-subunit. Glover & Tracey(Reference Glover and Tracey37) designed an IR kinase (IRK), IRK1154, sulfotyrosine eight-amino-acid-residue peptide (Thr1154Arg1155 Asp1156Ile1157sTyr1158Glu1159Thr1160Asp1161), based on the residues 1154–1161 in the kinase domain A-loop. In the molecular dynamics simulations of a fully hydrated model, IRK1154 binds to PTP1B in an extended β-strand conformation that is twisted about sTyr1158 and Thr1160. The sulfotyrosine moiety of IRK1154 is buried within the phosphotyrosine recognition pocket and held in position by a number of hydrogen bonds and ion pairs formed with PTP1B active residues. This result was strongly supported by two-dimensional NMR spectroscopy and X-ray crystal structures of PTP1B and IRK(Reference Glover and Tracey37). A similar event was also found in an epidermal growth factor-derived peptide(Reference Glover and Tracey38). In the present study, the protein motifs in FYGL might interact with PTP1B in a similar model such as IRK1154 in vivo. The detailed interaction mechanism of FYGL will be investigated in a further study.

Influence of Fudan-Yueyang-Ganoderma lucidum targeting on protein tyrosine phosphatase 1B in the insulin signal transduction pathway

In the present study, we used the type 2 diabetic C57BL/6 db/db mouse model to evaluate the antihyperglycaemic potency of FYGL in vivo. Figs. 4 and 5 show an increase in PTP1B expression and activity. As can be seen from Fig. 7, there is a decrease in the tyrosine phosphorylation levels of the IR β-subunit in the liver and skeletal muscle of diabetic mice, implying the PTP1B role in diabetic db/db mice. Similarly, Tagami et al. (Reference Tagami, Sakaue and Honda39, Reference Tagami, Honda and Yoshimura40) found that PTP1B activity was increased in the skeletal muscle and adipose tissue of Otsuka Long–Evans Tokushima fatty rats. Haj et al. (Reference Haj, Zabolotny and Kim41) found that liver-specific overexpression of PTP1B showed insulin resistance not only in the liver but also in other tissues in PTP1B knockout mice. Accordingly, PTP1B plays an important role in diabetic mice. When PTP1B is activated, the insulin signalling transduction pathway is blocked and the metabolism of plasma glucose is disturbed, resulting in the increase in the plasma glucose level. The increase in the tyrosine phosphorylation level of the IR β-subunit in the liver and skeletal muscle of FYGL-treated diabetic mice indicates the improvement of insulin sensitivity.

To date, only a few small-molecule PTP1B inhibitors synthesised have been demonstrated to be potential for application. For instance, Fukuda et al. (Reference Fukuda, Ohta and Sakata42) synthesised monosodium ({[5-(1,1-dimethylethyl)thiazol-2-yl]methyl}{[(4-{4-[4-(1-propylbutyl)phenoxy]methyl}phenl)thiazol-2-yl]methyl}amino)acetate (named JTT-551), a small-molecule PTP1B inhibitor, which shows a good selectivity against other PTP. JTT-551 can enhance IR phosphorylation in the liver and decrease the glucose level without any gain in body weight in both ob/ob and db/db mice. Also, there are some reports about natural PTP1B inhibitors. Wang et al. (Reference Wang, Ribnicky and Zhang43) found an ethanol extract of Artemisia dracunculus L. (PMI 5011), which can decrease the blood glucose and insulin levels in KK-Ay mice through the inhibition of PTP1B activity in the skeletal muscle. Also, Astragalus polysaccharide exerts insulin-sensitised and antihyperglycaemic activities in type 2 diabetic rats through the inhibition of PTP1B in the liver(Reference Mao, Yu and Wang44) and skeletal muscle(Reference Wu, Ou-Yang and Wu45).

Therefore, we suggest that FYGL decreases the expression and activities of PTP1B in the insulin-sensitive tissues of the liver and skeletal muscle due to the reduction in both the expression and the relative active ratio, leading to the increase in the tyrosine phosphorylation level of the IR β-subunit and the improvement of insulin sensitivity. So far, no PTP1B inhibitor such as FYGL has been found to be effective in multi-tissues in vivo.

Beneficial effects of Fudan-Yueyang-Ganoderma lucidum on the serum glucose level and insulin sensitivity through the inhibition of protein tyrosine phosphatase 1B

As can be observed from Table 1, a high dose of FYGL decreases considerably the serum glucose levels of diabetic mice, while there are no significant differences in serum insulin concentration between the diabetic control mice and normal mice. In general, the serum glucose level is maintained within a very narrow range through the tightly coordinated secretion of insulin and glucagon in normal physiology(Reference Bosch, Pujol and Valera46). Hyperglycaemia can be induced by the overexpression of glucagon because the development of hyperglycaemia is positively dependent on the glucagon:insulin ratio(Reference Kodama, Fujita and Yamaguchi26). In addition, the serum insulin concentration and HOMA-IR are significantly lower in diabetic mice treated with a high dose of FYGL than those in control mice, while FYGL has no effect on HOMA-β. There are also some reports about synthetic and natural insulin sensitisers that can decrease both plasma insulin concentrations and HOMA-IR. For example, Kim et al. (Reference Kim, Chae and Son47) reported that selective agonists of PPARα/γ, PAR-5359, reduced plasma insulin and HOMA-IR in high-fat diet-induced obese mice. Bhavsar et al. (Reference Bhavsar, Singh and Giri48) isolated saponins from Helicteres isora. Saponins can decrease serum insulin and enhance insulin sensitivity in C57BL/KsJ-db/db mice through increasing the expressions of adipsin, PPARγ and GLUT4. These reports indicate that insulin resistance is associated with insulin signal transduction factors including PPAR, GLUT and PTP1B. Insulin sensitivity can be improved through either the inhibition of negative factors such as PTP1B or the activation of positive factors such as PPAR and GLUT. In the present study, the extent of the reduction in HOMA-IR (47 %) and the increase in the tyrosine phosphorylation level of the IR β-subunit (45 % in the liver and 58 % in the skeletal muscle) are identical with those of the decrease in PTP1B activities (49 % in the liver and 55 % in the skeletal muscle) in the insulin-sensitive tissues of FYGL-treated diabetic mice and diabetic control mice, therefore leading to a 29 % reduction in plasma glucose. Accordingly, it has been supposed that FYGL improves insulin sensitivity in vivo through the inhibition of PTP1B in insulin-sensitive tissues. On the other hand, it has been found that HOMA-IR in metformin-treated db/db mice is increased, and the serum insulin concentration and HOMA-β are also higher than those in diabetic control mice, indicating that metformin can improve insulin sensitivity as well as insulin secretion. The results are identical with those reported by Matveyenko et al. (Reference Matveyenko, Dry and Cox49) who found that metformin was capable of inhibiting pancreatic β-cell apoptosis and preserving β-cell function. It is generally known that metformin is an insulin secretagogue which is better than an insulin sensitiser. Nevertheless, it has been supposed that FYGL acts as an insulin sensitiser through the inhibition of PTP1B instead of an insulin secretagogue through the recovery of pancreatic β-cells in db/db diabetic mice.

Effect of Fudan-Yueyang-Ganoderma lucidum on obesity, dyslipidaemia and glycogen synthesis

As has also been observed from Table 1 and Fig. 3, there is no significant difference in the final body weight and body-weight growth trend between the diabetic control mice and the FYGL-treated diabetic mice, indicating that FYGL would not result in overweight gain perhaps due to its decreasing effect on lipogenic enzyme activity such as fatty acid and glucose 6-phosphate dehydrogenase. The anti-obesity result is similar to that of those mono- and disalicylic acid derivatives which are potential PTP1B inhibitors as the anti-obesity drugs that suppress the weight gain by the inhibition of IκB kinase-β and PTP1B activity(Reference Bhattarai, Ko and Shrestha50).

For diabetic patients, hyperglycaemia is often accompanied with dyslipidaemia(Reference Garber51), which increase TAG, TC, LDL-C and decrease HDL-C. These serum lipid profiles are important plasma biochemistry indices for metabolic disorders. Abnormal values of these indices result in a series of complications. From Table 2, we found that there are higher values for TAG, TC, LDL-C and HDL-C in diabetic control mice, and Kobayashi et al. (Reference Kobayashi, Forte and Taniguchi25) also observed that those indices increased in db/db mice, but FYGL significantly reduced serum lipid profiles, and the reduction potency of FYGL on LDL-C, which is highly responsible for dyslipidaemia, is about 2-fold stronger than that on HDL-C, which is an anti-arteriosclerosis factor, leading to an efficient treatment for dyslipidaemia. Unlike FYGL, metformin has no effect on those plasma biochemistry indices in vivo, indicating that the signal transduction pathway of metformin is different from that of FYGL.

There are some extracts from natural plants that have also been reported to have an antihyperlipidaemic effect on serum in vivo. For instance, Tao et al. (Reference Tao, Ye and He52) isolated a polyphenol from Balanophora polyandra Griff. The extract from Balanophora polyandra Griff ameliorated hyperlipidaemia through reversing the defect expressions of anti-IR β-subunit, IRS-1, PTP1B and acetyl-CoA carboxylase β and increasing the phosphorylated AMP kinase. Therefore, dyslipidaemia can be ameliorated by the inhibition of PTP1B.

In addition, it has been observed from Table 3 that hepatic lipid profiles in the liver of diabetic control mice are several fold higher than those in normal mice, and decreased considerably by FYGL, implying the presence of dyslipidaemia in the liver of diabetic control mice and the effect of FYGL on hyperlipidaemia. Similarly, some natural plant extracts have also been reported that are able to reduce hepatic lipid profiles in vivo. Yamabe et al. (Reference Yamabe, Noh and Park53) evaluated loganin, an iridoid glycoside from Corni fructus. Loganin (100 mg/kg) led to a marked decrease in glucose, TAG and TC levels in the liver of db/db mice through the alleviation of oxidative stress and PPAR activation. Actually, we found that FYGL also possessed antioxidant potency (data not shown), implying that FYGL reduces hepatic lipid profiles via a multi-target mechanism including alleviation of oxidative stress and inhibition of PTP1B in db/db mice.

Besides lipid profiles, hepatic glycogen level is also an important biochemistry index in the liver. The acceleration of hepatic glycogen synthesis is one of the factors for decreasing blood glucose. The elevation of hepatic glucokinase activity and insulin sensitivity could increase the utilisation of blood glucose for glycogen storage in the liver. Table 3 shows the effect of the drug treatments on hepatic glycogen. FYGL improves the hepatic glycogen content, maybe resulting from increasing the activity of glycogen synthase via PKB and glycogen synthase kinase-3 as well as decreasing the transcription of gluconeogenic enzymes via PI3K and PKB like PTP1B antisense oligonucleotides(Reference Gum, Gaede and Koterski54), therefore increasing glycogen synthesis.

Conclusion

In the present study, we demonstrated in vivo pharmacological profiles of FYGL, which is a novel proteoglycan extract from the fruiting bodies of G. lucidum, and efficient in PTP1B inhibition. After 4 weeks of oral treatment in type 2 diabetic db/db mice, FYGL could decrease considerably the plasma glucose values (P < 0·01), serum insulin concentration and HOMA-IR (P < 0·001), which in turn could decrease the TAG, TC, LDL-C and HDL-C levels in the serum as well as the TAG, TC and NEFA levels in the liver, indicating the improvement of hyperlipidaemia. The mechanism of plasma glucose lowered by FYGL is on the basis of inhibiting the PTP1B expression and activity, consequently regulating the tyrosine phosphorylation level of the IR β-subunit and the hepatic glycogen level. Thus, FYGL is a potential candidate for the treatment of diabetes mellitus and the accompanying metabolic disorders.

Acknowledgements

This study was supported by the Natural Science Foundation of China (no. 20673022 and 21074025), the Soft Science Program of Jing-An district in Shanghai (no. 2008RZ002), the Scientific Program of Shanghai Municipal Public Health Bureau (no. 2008220 and 2010231), the Science and Technology Innovation Program of STCSM (no. 11DZ1971802) and the Innovation Program of Shanghai Municipal Education Commission (no. 12ZZ009). C.-D. W., B.-S. T., D. P. and P. Z. designed and performed the study. J.-S. W. and L.-F. P. performed the animal trial including preparation of the diet. Y.-M. H., D. Z., Z.-H. F. and H.-J. Y. performed the Western blot analyses. All authors were involved in the preparation of the manuscript. The authors declare that there are no conflicts of interests.

References

1Harris, M & Zimmet, P (1997) Classification of diabetes mellitus and other categories of glucose intolerance. In International Textbook of Diabetes Mellitus, 2nd ed., pp. 923 [, editors]. Chichester: John Wiley and Sons Limited.Google Scholar
2Barr, AJ, Ugochukwu, E, Lee, WH, et al. (2009) Large-scale structural analysis of the classical human protein tyrosine phosphatome. Cell 136, 352363.CrossRefGoogle ScholarPubMed
3Valentino, L & Pierre, J (2006) JAK/STAT signal transduction: regulators and implication in hematological malignancies. Biochem Pharmacol 71, 713721.Google Scholar
4Tonks, NK, Diltz, CD & Fischer, EH (1988) Purification of the major protein-tyrosine-phosphatases of human placenta. J Biol Chem 263, 67226730.CrossRefGoogle ScholarPubMed
5Goldstein, BJ (2002) Protein-tyrosine phosphatase 1B (PTP1B): emerging targets for therapeutic intervention in type 2 diabetes and related states of insulin resistance. J Clin Endocr Metab 87, 24742480.Google Scholar
6Seely, BL, Staubs, PA, Reichart, DR, et al. (1996) Protein tyrosine phosphatase 1B interacts with the activated insulin receptor. Diabetes 45, 13791385.Google Scholar
7Zabolotny, JM, Haj, FG, Kim, YB, et al. (2004) Transgenic overexpression of protein-tyrosine phosphatase 1B in muscle causes insulin resistance, but overexpression with leukocyte antigen-related phosphatase does not additively impair insulin action. J Biol Chem 279, 2484424851.Google Scholar
8Cromlish, WA, Tang, M, Kyskan, R, et al. (2006) PTP1B-dependent insulin receptor phosphorylation/residency in the endocytic recycling compartment of CHO-IR cells. Biochem Pharmacol 72, 12791292.Google Scholar
9Asante-Appiah, E & Kennedy, BP (2003) Protein tyrosine phosphatases: the quest for negative regulators of insulin action. Am J Physiol Endocrinol Metab 284, E663E670.Google Scholar
10Saltiel, AR (1996) Diverse signaling pathways in the cellular actions of insulin. Am J Physiol Endocrinol Metab 270, E375E385.CrossRefGoogle ScholarPubMed
11Ahmad, F, Azevedo, JJ, Cortright, R, et al. (1997) Alterations in skeletal muscle protein-tyrosine phosphatase activity and expression in insulin-resistant human obesity and diabetes. J Clin Invest 100, 449458.CrossRefGoogle ScholarPubMed
12Elchebly, M, Payette, P, Michaliszyn, E, et al. (1999) Increased insulin sensitivity and obesity resistance in mice lacking the protein tyrosine phosphatase-1B gene. Science 283, 15441548.Google Scholar
13Escriva, F, Rodriguez, AG, Millan, EF, et al. (2010) PTP1B deficiency enhances liver growth during suckling by increasing the expression of insulin-like growth factor-I. J Cell Physiol 225, 214222.Google Scholar
14Van Huijsduijnen, RH, Bombrun, A & Swinnen, D (2002) Selecting protein tyrosine phosphatases as drug targets. Drug Discov Today 7, 10131019.Google Scholar
15Park, H, Bhattarai, BR, Ham, SW, et al. (2009) Structure-based virtual screening approach to identify novel classes of PTP1B inhibitors. Eur J Med Chem 44, 32803284.Google Scholar
16Combs, AP (2010) Recent advances in the discovery of competitive protein tyrosine phosphatase 1B inhibitors for the treatment of diabetes, obesity, and cancer. J Med Chem 53, 23332344.Google Scholar
17Wasser, SP & Weis, AL (1999) Therapeutic effects of substances occurring in higher Basidiomycetes mushrooms: a modern perspective. Crit Rev Immunol 19, 6596.Google Scholar
18Wasser, SP (2011) Current findings, future trends, and unsolved problems in studies of medicinal mushrooms. Appl Microbiol Biotechnol 89, 13231332.Google Scholar
19Seto, SW, Lam, TY, Tam, HL, et al. (2009) Novel hypoglycemic effects of Ganoderma lucidum water-extracct in obese/diabetic (+ db/+db) mice. Phytomedicine 16, 426436.Google Scholar
20Meng, GL, Zhu, HY, Yang, SL, et al. (2011) Attenuating effects of Ganoderma lucidum polysaccharides on myocardial collagen cross-linking relates to advanced glycation end product and antioxidant enzymes in high-fat-diet and streptozotocin-induced diabetic rats. Carbohydr Polym 84, 180185.Google Scholar
21Yang, BK, Jeong, SC, Park, JB, et al. (2001) Swimming endurance capacity of mice after administration of exo-polymer produced from submerged mycelia culture of Ganoderma lucidum. J Microbiol Biotechn 11, 902905.Google Scholar
22Hikino, H & Mizuno, T (1989) Hypoglycemic actions of some heteroglycans of Ganoderma lucidum fruit bodies. Planta Med 55, 385385.Google Scholar
23Wachtel-Galor, S, Tomlinson, B & Benzie, IFF (2004) Ganoderma lucidum (‘Lingzhi’), a Chinese medicinal mushroom: biomarker responses in a controlled human supplementation study. Brit J Nutr 91, 263269.Google Scholar
24Teng, BS, Wang, CD, Yang, HJ, et al. (2011) A protein tyrosine phosphatase 1B activity inhibitor from the fruiting bodies of Ganoderma lucidum (Fr.) Karst and its hypoglycemic potency on streptozotocin-induced type 2 diabetic mice. J Agr Food Chem 59, 64926500.Google Scholar
25Kobayashi, K, Forte, TM, Taniguchi, S, et al. (2000) The db/db mouse, a model for diabetic dyslipidemia: molecular characterization and effects of Western diet feeding. Metabolism 49, 2231.Google Scholar
26Kodama, H, Fujita, M & Yamaguchi, I (1994) Development of hyperglycaemia and insulin resistance in conscious genetically diabetic (C57BL/KsJ-db/db) mice. Diabetologia 37, 739744.Google Scholar
27Folch, J, Lees, M & Sloane Stanley, GH (1957) A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem 226, 497509.CrossRefGoogle ScholarPubMed
28Chernoff, J, Schievella, AR, Jost, CA, et al. (1990) Cloning of a cDNA for a major human protein-tyrosine-phosphatase. Proc Natl Acad Sci U S A 87, 27352739.Google Scholar
29Bialy, L & Waldmann, H (2005) Inhibitors of protein tyrosine phosphatases: next-generation drugs? Angew Chen Int Ed Engl 44, 38143839.Google Scholar
30Seiner, DR, Labutti, JN & Gates, KS (2007) Kinetics and mechanism of protein tyrosine phosphatase 1B inactivation by acrolein. Chem Res Toxicol 20, 13151320.Google Scholar
31Liu, DG, Gao, Y, Voigt, JH, et al. (2003) Acylsulfonamide-containing PTP1B inhibitors designed to mimic an enzyme-bond water of hydration. Bioorg Med Chem Lett 13, 30053007.Google Scholar
32Liu, GX, Tan, JZ, Niu, CY, et al. (2006) Molecular dynamics stimulations of interaction between protein-tyrosine phosphatase 1B and a bidentate inhibitor. Acta Pharmacol Sin 27, 100110.Google Scholar
33Asante-Appiah, E, Patel, S, Dufresne, C, et al. (2002) The structure of PTP1B in complex with a peptide inhibitor reveals an alternative binding mode for bisphosphonates. Biochemistry 41, 90439051.Google Scholar
34Bartlett, AH & Park, PW (2010) Proteoglycans in host–pathogen interactions: molecular mechanism and therapeutic implications. Exp Rev Mol Med 12, 122.Google Scholar
35Bach-Knudsen, KE & Jørgensen, H (2007) Impact of wheat and oat polysaccharides provided as rolls on the digestion and absorption processes in the small intestine of pigs. J Sci Food Agr 87, 23992408.Google Scholar
36Liu, G, Xin, ZL, Liang, H, et al. (2003) Selective protein tyrosine phosphatase 1B inhibitors: targeting the second phosphotyrosine binding site with non-carboxylic acid-containing ligands. J Med Chem 46, 34373440.CrossRefGoogle ScholarPubMed
37Glover, NR & Tracey, AS (1999) Modeling studies of the interaction between the insulin receptor kinase domain and protein tyrosine phosphatase 1B. J Am Chem Soc 121, 35793589.Google Scholar
38Glover, NR & Tracey, AS (1999) Nuclear magnetic resonance and restrained molecular dynamics studies of the interaction of an epidermal growth factor-derived peptide with protein tyrosine phosphatase 1B. Biochemistry 38, 52565271.Google Scholar
39Tagami, S, Sakaue, S, Honda, T, et al. (2002) Effects of troglitazone on skeletal muscle and liver protein tyrosine phosphatase activity in insulin-resistant Otsuka Long-Evans Tokushima fatty rats. Curr Ther Res 63, 572586.Google Scholar
40Tagami, S, Honda, T, Yoshimura, H, et al. (2002) Triglitazone ameliorates abnormal activity of protein tyrosine phosphatase in adipose tissues of Otsuka Long-Evans Tokushima fatty rats. Tohoku J Exp Med 197, 169181.Google Scholar
41Haj, F, Zabolotny, JM, Kim, Y, et al. (2006) Liver-specific protein tyrosine phosphatase 1B (PTP1B) re-expression alters glucose homeostasis of PTP1B− / − mice. J Biol Chem 280, 1503815046.Google Scholar
42Fukuda, S, Ohta, T, Sakata, S, et al. (2010) Pharmacological profiles of a novel protein tyrosine phosphatase 1B inhibitor, JTT-551. Diabetes Obes Metab 12, 299306.Google Scholar
43Wang, ZQ, Ribnicky, D, Zhang, XH, et al. (2011) An extract of Artemisia dracunculus L. enhances insulin receptor signaling and modulates gene expression in skeletal muscle in KK-Ay mice. J Nutr Biochem 22, 7178.Google Scholar
44Mao, XQ, Yu, F, Wang, N, et al. (2009) Hypoglycemic effect of polysaccharide enriched extract of Astragalus membranaceus in diet induced insulin resistant C57BL/6J mice and its potential mechanism. Phytomedicine 16, 416425.Google Scholar
45Wu, Y, Ou-Yang, JP, Wu, K, et al. (2005) Hypoglycemic effect of Astragalus polysaccharide and its effect on PTP1B. Acta Pharmacol Sin 26, 345352.Google Scholar
46Bosch, F, Pujol, A & Valera, A (1998) Transgenic mice in the analysis of metabolic regulation. Annu Rev Nutr 18, 207232.CrossRefGoogle ScholarPubMed
47Kim, MK, Chae, YN, Son, MH, et al. (2008) PAR-5359, a well-banlanced PPARα/β dual agonist, exhibits equivalent antidiabetic and hypolidemic activities in vitro and in vivo. Eur J Pharmacol 595, 119125.Google Scholar
48Bhavsar, SK, Singh, S, Giri, S, et al. (2009) Effect of saponins from Helicteres isora on lipid and glucose metabolism regulating genes expression. J Ethnopharmacol 124, 426433.Google Scholar
49Matveyenko, AV, Dry, S, Cox, HI, et al. (2009) Beneficial endocrine but adverse exocrine effects of sitagliptin in the human islet amyloid polypeptide transgenic rat model of type 2 diabetes interactions with metformin. Diabetes 58, 16041615.Google Scholar
50Bhattarai, BR, Ko, JH, Shrestha, S, et al. (2007) Inhibition of IKK-β: a new development in the mechanism of the anti-obesity effects of PTP1B inhibitors SA18 and SA32. Bioorg Med Chem 20, 10751077.Google Scholar
51Garber, AJ (2002) Attenuating CV risk factors in patients with diabetes: clinical evidence to clinical practice. Diabetes Obes Metab 4, S5S12.Google Scholar
52Tao, R, Ye, F, He, YB, et al. (2009) Improvement of high-fat-diet-induced metabolic syndrome by a compound from Balanophora polyandra Griff in mice. Eur J Pharmacol 616, 328333.CrossRefGoogle ScholarPubMed
53Yamabe, N, Noh, JS, Park, CH, et al. (2010) Evaluation of lognan, iridoid glycoside from Corni fructus, on hepatic and renal glucolipotoxicity and inflammation in type 2 diabetic db/db mice. Eur J Pharmacol 648, 179187.Google Scholar
54Gum, RJ, Gaede, LL, Koterski, SL, et al. (2003) Redution of protein phosphatase 1B increase insulin-dependent signaling in ob/ob mice. Diabetes 52, 2128.Google Scholar
Figure 0

Fig. 1 Screening procedure of Fudan-Yueyang-Ganoderma lucidum (FYGL) from Ganoderma lucidum.

Figure 1

Fig. 2 Potencies of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on plasma glucose in vivo. The drugs were administered orally once per d for 4 weeks. Values are means, with their standard errors represented by vertical bars. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the normal group: ** P < 0·01, *** P < 0·001. Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01, ††† P < 0·001. , 1 Week; , 2 weeks; , 3 weeks; , 4 weeks.

Figure 2

Table 1 Characteristics of the trialed animals after 4 weeks of drug treatments‡ (Mean values with their standard errors)

Figure 3

Fig. 3 Potencies of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on body weight in vivo. The drugs were administered orally once per d for 4 weeks. Values are means, with their standard errors represented by vertical bars. , Normal; , diabetic control; , 75 mg/kg FYGL; , 225 mg/kg FYGL; , 225 mg/kg metformin.

Figure 4

Fig. 4 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on protein tyrosine phosphatase 1B (PTP1B) expression in (a, a′) the liver and (b, b′) skeletal muscle. Values are means, with their standard errors represented by vertical bars, in the normal group referred to as 100 %. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the normal group: *** P < 0·001. Mean values were significantly different from those of the diabetic control group: † P < 0·05, ††† P < 0·001. The images (a) and (b) on the nitrocellulose (NC) membranes represent the results of the analysis of the liver and skeletal muscle, respectively, on one of four NC membranes.

Figure 5

Fig. 5 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on protein tyrosine phosphatase 1B (PTP1B) activities in (a) liver, (b) skeletal muscle and (c) adipose tissue. Values are means, with their standard errors represented by vertical bars, in the normal group referred to as 100 %. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the diabetic control group: †† P < 0·01.

Figure 6

Fig. 6 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on the relative active ratio of protein tyrosine phosphatase 1B (PTP1B) in (a) the liver and (b) skeletal muscle. Values are means, with their standard errors represented by vertical bars. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the normal group: ** P < 0·01. Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01, ††† P < 0·001.

Figure 7

Fig. 7 Effects of Fudan-Yueyang-Ganoderma lucidum (FYGL) and metformin on the insulin-stimulated tyrosine phosphorylation levels of insulin receptor (IR) β-subunit in (a) the liver and (b) skeletal muscle. The quantitative analysis of the relative IR β-subunit tyrosine phosphorylation levels in (a′) the liver and (b′) skeletal muscle of drug-treated mice is referred to that of the insulin-stimulated normal mice. Values are means, with their standard errors represented by vertical bars, in the normal group referred to as 100 %. The statistical differences between the mean values in the two groups were analysed by one-way ANOVA. Mean values were significantly different from those of the diabetic control group: † P < 0·05, †† P < 0·01. The images (a) and (b) on the nitrocellulose (NC) membranes represent the results of the analysis of the liver and skeletal muscle, respectively, on one of four NC membranes.

Figure 8

Table 2 Effects of the drugs on the serum lipid profile in vivo after 4 weeks of treatment‡ (Mean values with their standard errors)

Figure 9

Table 3 Effects of the drugs on TAG, total cholesterol (TC) and NEFA levels in the liver and hepatic glycogen in vivo after 4 weeks of treatment‡ (Mean values with their standard errors)