1Department of Biochemistry and Biotechnology, Faculty of Science, Annamalai University, Annamalainagar 608002, Tamil Nadu, India, 2Ashram Siddha Yoga Research Institute, Salem 636004, Tamil Nadu, India.
Email: cpkbiotech@yahoo.com
Received: 14 Aug 2014 Revised and Accepted: 15 Sep 2014
ABSTRACT
Objective: A number of large randomized clinical trials demonstrated that lipid lowering successfully reduced cardiovascular events and death in patients with diabetes. Recent studies have reported that multiple transcription factors are involved in regulation of lipid metabolism in diabetic subjects. Numerous plant extracts and formulations have been shown to regulate the expression of transcription factors which in turn normalize lipid abnormalities in diabetic patients. In this series, sugnil, a traditional anti-diabetic polyherbal formulation was assessed for its regulatory effect on the expression of transcription factors in lipid metabolism of streptozotocin induced diabetic rats.
Methods: The mRNA expressions of fatty acid synthesis related genes such as SREPB-1 and SREPB-2 and fatty acid decomposition related gene PPARα were measured by real-time RT-PCR using an appropriate primers and thermal cycler conditions.
Results: Oral administration of sugnil to diabetic rats for 42 consecutive days effectively normalized the expression of these transcription factors to near normal as in control rats. Expression of PPAR-α was found to be up-regulated that leads to diminished expression of SREBP-2 in the liver of diabetic rats treated with sugnil. Treatment with sugnil also down regulated the SREBP-1 expression in the kidney of diabetic rats.
Conclusion: The molecular mechanisms of action of sugnil in the regulation the lipid profile in diabetic rats might be normalizing the expression of these transcription factors.
Keywords: Transcription factors, PPARα, SREPB-1, SREPB-2.
INTRODUCTION
Lipid abnormalities in diabetes mellitus results in increased risk of cardiovascular diseases, coronary insufficiency, myocardial infarction. Cardiovascular complications especially atherosclerosis has become a predominant cause of death in diabetic patients. Lipid management has been considered as an effective approach to reduce cardiovascular risk in diabetes subjects [1]. Thus, to reduce the risk of late complications and negative outcome of diabetes mellitus, not only the control of blood glucose levels, but also lipid levels is necessary. A traditional antidiabetic polyherbal formulation, marketed in the brand name of sugnil is selected for current investigation. Sugnil consists of ingredients from nine medicinal plants viz Aristolochia bracteata, Balsamodendron mukul, Casearia esculanta, Cassia auriculata, Coscinium fenestratum, Curcuma longa, Eugenia jambolana, Gymnema sylvestre, and Triphala. Preparation of Sugnil is based on traditional methods in accordance with the procedure suggested in the antique literature (Table 1). Our previous study has reported the antihyperlipidemic potency of sugnil in streptozotocin induced diabetic rats [2]. In this study, an attempt has been made to investigate the molecular mechanism of sugnil action in lowering lipid levels in experimental animals.
Changes in gene expression are an important component of the pathogenesis of diabetes [3,4]. Multiple transcription factors are involved in the regulation of both carbohydrate and lipid metabolism either directly or through interaction with insulin and a large number of insulin-regulated genes have been identified in liver and adipose tissue [5]. Transcription factors are soluble proteins that are able to bind to DNA. Their binding to promoter sites of genes influences the transcription of genes, leading to up- or down-regulation of gene expression. In recent years, numerous plant extracts and plant formulations have been shown to regulate the expression of transcription factors and genes in metabolic pathways of different diabetic animal models [6-8]. In the present study, the effect of sugnil on the expression of transcriptional factors such as peroxisome proliferator-activated receptor-α (PPAR-α), sterol regulatory element-binding protein-2 (SREBP 2) and sterol regulatory element-binding protein-1 (SREBP 1) were assessed in streptozotocin induced diabetic rats using RT-PCR assay.
Peroxisome proliferator-activated receptor (PPAR) belong to a superfamily of nuclear, ligand-activated transcription factors, which play an important role in the transcriptional regulation of genes responsible for the control of lipid utilization and storage, and modulation of lipoprotein metabolism, adipocyte differentiation and insulin action [9]. PPARs consist of three nuclear receptor isoforms, PPAR alpha, PPAR delta and PPAR gamma, encoded by separate genes [10]. PPAR-α isoform is predominantly expressed in the liver and regulates the transcription of genes involved in hepatic fatty acid uptake and oxidation [11]. PPAR-α agonists have been used for over 40 years in the treatment of dyslipidemia, mainly due to their hypolipidemic actions, such as lowering triglyceride (TG) and raising high density lipoprotein levels [12]. However, these agents also produce hepatic peroxisome proliferation, hypertrophy and hyperplasia in rodents [13]. Alternatively, numerous plant extracts and traditional plant formulations have been reported to have PPAR-α modulatory activity in different diabetic animal models [14].
Sterol regulatory element-binding proteins (SREBPs) are transcription factors that regulate fatty acid and cholesterol synthesis. SREBPs belong to basic helix-loop-helix-leucine zipper family and activate the entire program of fatty acid and cholesterol synthesis in liver [15,16]. Three isoforms of SREBP are known in mammals, SREBP- 1a, SREBP-1c and SREBP-2. In most animal tissues, SREBP-1c is the predominant SREBP-1 isoform [17]. Multiple lines of evidence suggest that SREBP-1 and SREBP-2 have different relative effects on target genes. SREBP-1 preferentially activates genes involved in fatty acid synthesis, including acetyl CoA carboxylase and fatty acid synthase (FAS), whereas SREBP-2 preferentially activates genes involved in cholesterol biosynthesis such as hydroxymethylglutaryl CoA synthase, hydroxyl methylglutaryl CoA reductase, farnesyl diphosphate synthase, and squalene synthase [18].
Table 1: Description of sugnil constituents
S. No. | Botanical name | Common name | Part used | Concentration
(mg/100mg) |
1. | Aristolochia bracteata | Birth wort | Whole plant | 10 |
2. | Balsamodendron mukul | Indian bdellium tree | Gum | 10 |
3. | Cassia auriculata | Tenners cassia | Flower | 12.5 |
4 | Casearia esculanta | Kadala-zhinjill | Stem | 10 |
5. | Coscinium fenestratum | Tree turmeric | Bark | 12.5 |
6. | Curcuma longa | Turmeric | Tubers | 10 |
7. | Eugenia jambolana | Jamun | Seeds | 12.5 |
8. | Gymnema sylvestre | Gurmar | Leaves | 12.5 |
9. | Triphala | Indian goose berry | ||
Emblica officinalis
Terminalia bellirica Terminalia chebula |
Emblic myrobalan
Belleric myrobalan Chebulic myrobalan |
Fruits | 10 |
MATERIALS AND METHODS
Animals
Male albino Wistar rats of body weight ranging from 150-180 g were procured from the Central Animal House, Rajah Muthiah Medical College, Annamalai Nagar. Six rats were allocated per polypropylene cage at a temperature of 22-24°C and humidity 30 - 35 % in a controlled room. The rats were maintained under 12h,12h light,dark cycle. Food [Amrut Laboratory Animal Feed, Pranav Agro Industries Ltd., Bangalore, India] and water were available ad libitum to animals. The experiments were designed and conducted according to the ethical norms approved by the Institutional Animal Ethics Committee [IAEC] of Annamalai University. [No.160/1999/CPCSEA/552]. The animals were maintained in accordance with the Indian National Law on Animal Care and use.
Chemicals
Streptozotocin and primers for RT-PCR analysis were purchased from Sigma-Aldrich Pvt. Ltd., MO, USA. TriZol reagent and cDNA conversion kits were purchased from Invitrogen, Life Technologies, USA. Biochemicals, chemicals and solvents of analytical grade were purchased from Himedia Laboratories Pvt. Ltd., Mumbai, India or from Sisco Research Laboratories Pvt Ltd., Mumbai, India.
Induction of experimental diabetes
Rats were fasted for 16 h prior to induction of diabetes. Rats received single intraperitoneal injection of 55mg/kg body weight STZ (Sigma, St Louis, MO, USA) freshly dissolved in 0.1 mol/L cold sodium citrate buffer, pH 4.5 [19]. Control rats received equivalent amount of buffer intraperitoneally. Animals were allowed to drink 5% glucose solution overnight to overcome drug-induced hypoglycemia. Hyperglycemia was confirmed 3 days after induction by assessing fasting blood glucose level. Animals with a fasting blood glucose level greater than 250 mg/dL were considered diabetic and included in the study.
Animal groups for experimental studies
Rats were acclimatized to the laboratory conditions at least for a week and they were divided into four groups of with four rats in each group as follows,
Group I: Control rats administered 0.5 ml of saline for 42 days.
Group II: STZ-induced diabetic control rats administered 0.5 ml of saline for 42 days.
Group III :STZ–induced diabetic rats administered sugnil (100 mg/kg body weight) for 42 days.
Group IV: Control rats administered sugnil (100 mg/kg body weight) for 42 days.
Analysis of mRNA expressions
The STZ-induced diabetic rats were administered with sugnil for 42 consecutive days. At the end of treatment schedule, two rats from four different experimental groups were sacrificed under mild anesthesia (non-fasted condition), the liver and kidney tissues were immediately removed, instantly soaked in liquid nitrogen and stored at -800C for study of mRNA using RT-PCR.
I - RNA Extraction from tissue samples
Total mRNA was prepared separately from the tissues of individual rats in different experimental groups using TRIzol reagent.
Homogenization
About 15 mg of frozen liver tissue and 75 mg of frozen kidney tissue were homogenized separately in 1 ml of TRIzol reagent using a glass–Teflon homogenizer.
Phase separation
The homogenized tissue samples were incubated for 5 minutes at room temperature (300C) for complete dissociation of nucleoprotein complexes. After incubation, 0.2 ml of choloroform was added and the tubes were shaken vigorously by hand for 15 seconds. The entire content was then centrifuged at 12,000 x g for 15 minutes at 80C. Followed by centrifugation, the mixture was separated into a lower red, phenol–choloroform phase, an interphase and a colorless upper aqueous phase. RNA was present exclusively in an aqueous phase and was transferred to a fresh tube.
RNA precipitation
RNA from the aqueous phase was precipitated by mixing with 0.5 ml isopropyl alcohol. The samples were incubated at room temperature for 10 minutes and then centrifuged at 12,000 x g for 10 mintues at 80C. After centrifugation RNA precipitate was formed as gel like pellet on the side and bottom of the tube.
RNA wash
The pellet was collected and 1 ml of 75% ethanol was added. The samples were vortexed and then centrifuged at 7,500 x g for 5 minutes at 80C.
Redissolving the RNA
At the end of the procedure, RNA pellet was air dried, and dissolved in RNase – free water. The concentration and purity of RNA preparation were checked by measuring the absorbance at 260 nm and 280 nm.
The above mentioned RNA extraction procedure was performed individually to all the tissue samples dissected from rats in four different experimental groups. The extracted RNA’s were used as a template for the synthesis of first-strand of cDNA.
II - First Strand cDNA Synthesis
cDNA Synthesis was performed using superscript III first–strand synthesis system for RT-PCR (Invitrogen, USA) following manufacturer’s protocol as follows;
As a first step, the following components were added into a thin-walled 0.5 ml PCR tube to prepare cDNA synthesis mix. 1µg total RNA (extracted separately from tissues of rats in four different experimental groups), 1 µl 50 mM oligo (dT)20, 1 µl 10 mM dNTP mix [10 µl dATP (100 mM), 10 µl dCTP (100 mM), 10 µl dGTP (100 mM), 10 µl dTTP (100 mM)] and DEPC (diethyl pyrocarbonate) treated water to bring to volume of 10 µl.
The above mix was incubated at 650C for 5 minutes and placed on ice for 1 minute. Then the following components were added in the order indicated below (as recommended by the manufacturer). The amount for each component is for 1 reaction only which can be scaled up according to need. 2 µl 10X RT buffer, 4 µl 25 mM Mgcl2, 2 µl 0.1m DTT, 1 µl RNase OUT (40U/µl), 1 µl superscript III RT (200U/µl), and 10 µl of cDNA synthesis mix from above.
The above mix was briefly centrifuged and incubated at 50C for 50 minutes. The reaction was completed with incubation at 850C for 5 minutes, followed by incubation in ice for 1 minute. The reaction mix was briefly centrifuged and 1 µl of RNaseH was added to the tube and incubated at 370C for 20 minutes. The synthesized cDNAs were stored at -20 0C for PCR amplification using gene specific primers.
III - Primer Design
For PCR amplification, the following genes were selected from previous work by scientists and from Gene bank database (http: //www. ncbi. nlm. nih. gov/).
Fatty acid synthesis related genes – SREPB-1 and SREPB-2
Fatty acid decomposition related gene – PPARα
The house keeping gene _ β Actin
The sequences of these genes were used to design primer for the RT PCR. The primers were ordered from GeNei, Bangalore. 1 µl of cDNA was used as a template for RT-PCR. The Primer sequences for the above mentioned genes are as follows;
SREBP-1 – Sterol Regulatory Element Binding Protein 1
Forward primer: TCCCAGAGTAGCCCCTTGTCC (51→31)
Reverse primer: CCAGTCCCCATCCACGAA (31→51)
SREBP-2 - Sterol Regulatory Element Binding Protein 2
Forward primer: ATCCGCCCACACTCACGCTCCTC (51→31)
Reverse primer: GGCCGCATCCCTCGCACTG (31→51)
PPARα – Peroxisome Proliferator Activated Receptor-α
Forward primer: GACAAGGCCTCAGGATACCA (51→31)
Reverse primer: GTCTTCTCAGCCATGCACAA (31→51)
β actin - House keeping gene
Forward primer: AGCCATGTACGTAGCCATCC(51→31)
Reverse primer: CTCTCAGCTGTGGGTGGTGAA (31→51)
IV - Reverse Transcriptase PCR
The cDNAs synthesized from tissues of individual rats in four different experimental groups were amplified using the primers mentioned above. Polymerase chain reaction was performed in 40 µl reactions containing 84 pmol of each of two primers, 4 µl of 10 mM dNTP mix [10 µl dATP (100 mM), 10 µl dCTP (100 mM), 10 µl dGTP (100 mM), 10 µl dTTP (100 mM)], 4 µl of Mg free 10X buffer (100 mM Tris pH 9.0 at 250C, 500 mM Kcl, 1% tritonX-100), 4 µl of 25 mM Mgcl2 and 2 units of Taq DNA polymerase enzyme. The PCR reagents were assembled as a master mix that was split into reactions that received 1 µl of cDNA as template. PCR was performed with the reaction conditions mentioned in table.2. At the end, aliquots of the reactions were removed after a determined number of cycles and the reaction products were subjected to electrophoresis on agarose gel.
Table 2: Thermal cycler conditions for selected genes
Genes | Denaturation temperature | Annealing temperature | Extension temperature | No. of cycles | Final extension | Amplicon size |
SREPB-1 | 950C for 15s | 640C for 40s | 720C for 30s | 30 | 720C for 10m | 728bp |
SREBP-2 | 940C for 1m | 650C for 1m | 720C for 1m | 30 | 720C for 10m | 416bp |
PPARα | 940C for 30s | 640C for 30s | 720C for 1m | 35 | 720C for 10m | 425bp |
β ACTIN | 940C for 30s | 600C for 30s | 720C for 1m | 35 | 720C for 10m | 357bp |
V - Gel Electrophoresis and data acquisition
The PCR amplified products of the selected genes were electrophorised using 1.0% agarose gel prepared in 1X Tris acetic acid EDTA buffer [0.5g of agarose dissolved by heating in 50 ml of 1X TAE buffer (40 mM Tris, 1 mM EDTA, pH 8.0)]. A dye solution consisting of bromophenol blue (0.25%), Xylene cyanol FF (0.25%) and 40% sucrose in water was added at 3 µl per DNA sample prior to electrophoresis. Electrophoresis was carried out in a horizontal electrophoresis unit. The agarose gel was formed using a gel caster and the dimensions of the gel were adjusted to 9.6 by 14.2 by 0.6 cm. The wells were made by using comb, the ladder DNA (10 µl) and samples (10 µl each) were loaded at wells using micropipette in the following manner.
Lane 1 – DNA ladder sequence (1000 bp).
Lane 2 – Amplicon of selected gene from control rats.
Lane 3 – Amplicon of selected gene from diabetic control rats.
Lane 4 – Amplicon of selected gene from control rats treated with sugnil (100 mg/kg).
Lane 5 – Amplicon of selected gene from control rats treated with sugnil (100 mg/kg).
The gel was allowed to run at 85 V, maximum Amp and maximum Watts for 1 hour 20 minutes or till the dye neared at the bottom of the gel using the high voltage power supply unit. The gel was then placed in the ethidium bromide staining solution (0.01 g/L) for 20 minutes and transferred to destaining solution (1X TAE) for 30 minutes. The resolved DNA in the gel was visualized under UV trans-illuminator. Electrophoresis was carried out individually for all the selected genes to separate their PCR amplicons. At the end, the gels were photographed using a gel documentation system (Bio Rad, CA, USA) and the density of the PCR products was measured using a GS-700 imaging densitometer. The housekeeping gene, β actin was amplified as a control gene (Fig. 1b, 2b & 3b). The level of mRNA was expressed as the ratio of signal intensity for each gene relative to that of β actin. All results were confirmed with at least three independent experiments.
RESULTS
Expression of mRNA in Liver
In the liver, expressions of fatty acid decomposition related gene PPAR-α and fatty acid synthesis-related gene SREBP-2 were measured by real-time RT-PCR. The mRNA expression of PPAR-α was found to be decreased, where as the expression of SREBP-2 was significantly increased in streptozotocin induced diabetic rats when compared to normal control rats. Oral administration of sugnil for 42 consecutive days effectively reversed the expression pattern of these genes to near normal as in the control rats. However, no significant difference was found in the expression pattern of these genes in control rats treated with sugnil (Fig.1a & 1c and 2a & 2c).
Expression of mRNA in kidney
In the kidney, the mRNA expression of SREBP-1 was significantly increased in streptozotocin induced diabetic rats when compared to normal control rats. Oral administration of sugnil for 42 consecutive days significantly decreased the expression of this gene to near normal as in control rats. However, no significant difference was found in the renal expression of SREBP-1 in control rats treated with sugnil (Fig 3a&3c).
Fig. 1(a): Expression of PPAR-α in liver
Fig. 1(b): Expression of β-ACTIN
Fig: 1(c): Densitometry data analysis
Fig. 1a, 1c: RT-PCR analysis of PPAR-α in liver. The band intensities of gene are normalized with that of a house keeping gene (β-actin) and the values are expressed as ratio of band intensity relative to β-actin. Values are mean ± SD of three independent experiments. Lane 1-Base pairs marker; Lane 2-Control; lane 3-Diabetic control; lane 4-Diabetic+SUGNIL; lane 5-Control+SUGNIL. *Significant as compared to Control. **Significant as compared to Diabetic control (p<0.05, one way ANOVA followed by DMRT).
Fig. 2a: Expression of SREBP-2 in liver
Fig. 2b: β-ACTIN
Fig. 2c: Densitometry data analysis
Fig. 2a, 2c: RT-PCR analysis of SREBP-2 in liver. The band intensities of gene are normalized with that of a house keeping gene (β-actin) and the values are expressed as ratio of band intensity relative to β-actin. Values are mean ± SD of three independent experiments. Lane 1-Base pairs marker; Lane 2-Control; lane 3-Diabetic control; lane 4-Diabetic+SUGNIL; lane 5-Control+SUGNIL. *Significant as compared to Control. **Significant as compared to Diabetic control (p<0.05, one way ANOVA followed by DMRT).
Fig. 3a: Expression of SREBP-1 in kidney
Fig. 3b: β-ACTIN
DISCUSSION
To investigate the lipid lowering effects of sugnil changes in the expression of transcriptional factors involved in hepatic lipogenesis were examined using RT-PCR assay. Peroxisome proliferator-activated receptor (PPAR), a ligand activated transcription factor, is highly expressed in liver, heart, and skeletal muscle [20]. PPAR-α mediated responses have been traditionally studied in the liver. PPAR-α activation mediates expression of genes regulating lipid oxidation [21]. Both, natural and synthetic ligands are found to activate PPAR-α and thereby regulate the lipid metabolism in man and animals [6,14]. In recent years, many plant extracts and traditional plant formulations have been shown to possess PPAR-α modulatory activity in different diabetic models [14].
Fig. 3c: Densitometry data analysis
Fig. 3a, 3c: RT-PCR analysis of SREBP-1 in kidney. The band intensities of gene are normalized with that of a house keeping gene (β-actin) and the values are expressed as ratio of band intensity relative to β-actin. Values are mean ± SD of three independent experiments. Lane 1-Base pairs marker; Lane 2-Control; lane 3-Diabetic control; lane 4-Diabetic+SUGNIL; lane 5-Control+SUGNIL. *Significant as compared to Control. **Significant as compared to Diabetic control (p<0.05, one way ANOVA followed by DMRT).
In this context, sugnil, a traditional antidiabetic polyherbal formulation was examined for its PPAR-α modulatory effect in streptozotocin induced diabetic rats. Results of this study showed that the expression of PPAR-α was decreased in streptozotocin induced diabetic rats. This effect may be due to the hyperglycemic condition caused by streptozotocin and/or loss of insulin signaling. However, oral administration of sugnil for 42 consecutive days effectively increased the expression of PPAR- α in the liver of STZ-induced diabetic rats. This possible effect of sugnil may be due to the presence of bioactive compound(s), which could act as a ligand for PPAR-α activation. The activated transcription factor PPAR-α induces the mRNA expressions of target genes responsible for fatty acid β oxidation. This was evidenced by normal levels of triglycerides and high density lipoproteins observed in sugnil treated diabetic rats [2]. Further, it has been reported that PPAR-α activation lowers the cholesterol concentration in rat liver, plasma and lipoproteins by reducing the amount of nuclear SREBP-2 thereby decreasing cholesterol synthesis and uptake [22]. Consistent with this finding, the present study results also showed that the activated PPAR-α decreased the expression of SREBP-2 in the liver of sugnil treated diabetic rats. This might be a reason behind the decreased concentrations of total cholesterol observed in the liver and plasma of sugnil treated diabetic rats [2].
. Over all, these results strongly suggest that sugnil behave like natural ligand for PPAR-α activation. This leads in turn to the diminished expression of SREBP-2. Hence, the molecular mechanism of sugnil action in the regulation of circulatory and hepatic lipid metabolism in diabetic rats might be modulation of PPAR-α and SREBP-2 gene expression.
SREBP-1 plays an important role in the regulation of lipid homeostasis in kidney; an altered regulation of this transcription factor may be involved in diabetic nephropathy by modulating renal lipid metabolism. A previous study has shown that the expression of SREBP-1 was increased in the kidney cortex of STZ-induced diabetic rats, resulting in up-regulation of enzymes responsible for fatty acid synthesis and, as a consequence, high renal triglyceride content, and was associated with mesangial expansion and glomerulosclerosis. Treatment of diabetic rats with insulin to correct the hyperglycemia prevented the increase in renal expression of SREBP-1 and the renal accumulation of triglyceride [23]. The result of the present study showed that the expression of SREBP-1 was found to be increased in the kidney cortex of STZ-induced diabetic rats. Hyperglycemic condition caused by streptozotocin might be responsible for this effect. However, oral administration of sugnil for 42 consecutive days effectively decreased the expression of SREBP-1 in the kidney of STZ-induced diabetic rats. This possible effect of sugnil might be due to the stimulation of insulin secretion from pancreatic β cells, since insulin was reported to normalize SREBP-1 expression in STZ-induced diabetic rats [23]. Insulin stimulatory effect was directly witnessed by increased concentration of serum insulin reported in sugnil treated diabetic rats [24]. Therefore, the results suggest that down-regulation of renal SREBP-1 through insulin stimulation might be the mechanism of sugnil action in lowering renal lipid contents.
CONCLUSION
The regulation of lipid metabolism by sugnil might involve up-regulation of PPARα and diminished expression of SREBP-2 in liver and SREBP-1 in kidney of diabetic rats. The bioactive compound(s) present in sugnil might act as a natural ligand and normalized the expression of these transcription factors. These possible effects of sugnil may arrest the development and progression of atherosclerosis and related cardiovascular complications in diabetes mellitus. Hence, its therapeutic usage can improve the quality of life in diabetic patients.
CONFLICT OF INTERESTS
Declared None
REFERENCES