Neda Ranjbar Kohan1, Saeed Nazifi1, Mohammad Reza Tabandeh2,3, Maryam Ansari Lari4. 1. Department of Clinical Studies, School of Veterinary Medicine, Shiraz University, Shiraz, Iran. 2. Department of Biochemistry and Molecular Biology, Faculty of Veterinary Medicine, Shahid Chamran University of Ahvaz, Ahvaz, Iran. 3. Stem Cells and Transgenic Technology Research Center, Shahid Chamran University of Ahvaz, Ahvaz, Iran. Electronic Address:m.tabandeh@scu.ac.ir. 4. Department of Food Hygiene, School of Veterinary Medicine, Shiraz University, Shiraz, Iran.
Obesity is associated with a variety of inflammatory-
related diseases, such as insulin resistance (IR), type 2
diabetes and cardiovascular diseases (CVD) (1). Risk of
coronary heart disease (CHD) and stroke is reported to be
higher in obese subjects in comparison to normal weight
people (2). The pathogenesis of CVD in obese patient
is very complex; however, adipose tissue dysfunction
is considered to be the central mechanism involved in
the development of CVD including atherosclerosis and
cardiomyopathy (3, 4).Adipocytokines or adipokines are adipose tissue-derived
hormones that act as pro-inflammatory, vasoactive, and
cytokine-like hormones (5-8). It has been shown that
these immunomodulatory proteins act as modulators of
metabolic and cardiovascular processes (5, 7). Based
on both animal and human studies, it has been reported
that dysregulation of adipocytokine secretion caused
by excess adiposity and dysfunctional adipocytes, can
play a pivotal role in obesity-related CVDs. Though
adipocytokines are mainly secreted by adipose tissue, they
are also expressed and secreted by various cardiovascular
tissues such as cardiomyocytes and endothelial cells and
regulate cardiacovascular function
via a distinct paracrine
mechanism (3, 4).Apelin is a novel adipokine which is produced from
a 77-amino acid precursor. Different active forms of
Apelin including Apelin-12, Apelin-13, Apelin-17,
Apelin-19 and Apelin-36 have been reported. In different
tissues, Apelin-36 is the most widely expressed form,
while Apelin-13 is more potent and more abundant in
the circulation (8, 9). It is the endogenous ligand of the
orphan receptor angiotensin like-receptor 1 (AGTRL1),
a G-protein-coupled receptor that has been found to be
involved in various physiologic events, such as insulin
sensitivity, glucose homeostasis and regulation of the
cardiovascular function (10, 11).
Apelin is upregulated by insulin and inhibits pancreatic
insulin secretion (9, 12-14). In clinical and experimental
studies, serum levels of Apelin or its adipose tissue
expression are increased in case of obesity and insulin
resistance (5, 15, 16). It is also involved in inflammatory
responses in obese subjects and its expression is positively
associated with some inflammatory markers such as tumor
necrosis factor-α (TNF-α), interleukin-1ß (IL-1ß) (17, 18).Recent findings have shown the role of Apelin
in cardiovascular functions. A high level of Apelin
expression has been reported in cardiac muscles of rats
and humans (19). Apelin stimulates inotropic potential of
cardiac muscle cells and increases coronary blood flow
by vascular dilation (20). Protective effect of Apelin has
been reported against age-related progressive cardiac
dysfunction in Apelin-deficient mice (21). Moreover,
Apelin expression increases in the arteries of patients with
atherosclerosis and chronic heart failure (22, 23).Although application of lipotropic agents for prevention
of cardiovascular disease has been confirmed in previous
research, data about their effects on adipokine expression
in cardiovascular system is limited (5). L-carnitine (L-bhydroxy-
4-N-trimethylaminobutyric acid) (LC) is an
amino acid derivative that plays an important role in
energy production in the myocardium and is considered
an essential cofactor for fatty acid ß-oxidation in the heart
(24, 25). It has been found that LC has favorable effects in
patients with severe insulin resistance and cardiovascular
disorders, such as CHD, chronic heart failure and
peripheral vascular disease. In patients with ischemic heart
disease, LC reduces the myocardial injury mainly through
improving carbohydrate metabolism and reducing the
toxicity of high levels of free fatty acid (25, 26).Currently, it is not clear that LC improves obesity-
associated cardiovascular complications through local
alteration of Apelin system in myocardial tissue, or via
an endocrine adaptation that is reflected by a change in
serum levels of Apelin. The aim of the present study was
to evaluate the gene expressions of Apelin and Apelin
receptor in cardiac muscle of high-fat diet treated diabetic
rats and their association with inflammatory and insulin
resistance markers.
Materials and Methods
To perform this experimental study, 60 male Wistar rats
(200 ±12 g) were obtained from the center of laboratory
animals of the Faculty of Veterinary Medicine of Shahid
Chamran University, Ahvaz, Iran. They were housed in a
temperature-controlled room (at 23 ± 1°C) with 12 hour
light/dark cycles and they had free access to rat chow
(Pars, Iran) and water at libitum. The rats experienced 7
days of acclimatization before initiation of the experiment.This experiment was accomplished under the approval of
the State Committee on Animal Ethics, Shiraz University,
Shiraz, Iran. The recommendations of European Council
Directive (86/609/EC) of November 24, 1986, regarding
protection of animals used for experimental purposes,
were also followed.
Experimental design
Animals (n=60) were randomly divided into four groups
(n=15). Two groups were fed with high-energy diet
[prepared by adding 20% sucrose (w/w) and 10% beef
tallow (w/w) into diets] for 5 weeks and called as High
fat/High carbohydrate (HF/HC) (n=30), whereas the other
ones consumed normal diets for the same period and served
as control groups (n=30). After 5-week administration of
HF/HC diets, animals were treated with a single injection
of streptozotocin (STZ, Sigma, Germany) 30 mg/kg
body weight. Five days after STZ treatment, glucose was
measured by a glucometer (EasyGluco, South Korea) and
diabetes induction was confirmed if serum glucose was
above 7.5 mmol/l. The day after diabetes confirmation,
was considered day 0 of LC treatment. One diabetic group
was treated with 300 mg/kg/day LC (n=15) in drinking
water concomitant with HF/HC diets for 28 days, while
the other diabetic group (n=15) (diabetic control) was fed
only with HF/HC diets for the same period. One control
group (n=15) received normal diet and the other control
group (n=15) (LC-treated control) consumed 300 mg/kg
LC in drinking water for 28 days.
Sampling
Serum and tissues were taken on days 0, 14 and 28
after diabetes induction and LC treatment. Animals
were euthanized with a combination of 100 mg/kg of
ketamine and 10 mg/kg of xylazine. Blood samples were
collected immediately, and sera were separated and stored
at -20°C until used. Cardiac muscles were separated,
surrounding tissues were removed and kept at -70°C until
used. Absolute body weight of each rat from each group
was measured at the end of the HF/HC feeding and LC
treatment period.
Plasma biochemical assays
The plasma glucose, triglyceride (TG), cholesterol, high
density lipoprotein-cholesterol (HDL-C) and low density
lipoprotein-cholesterol (LDL-C) levels were determined
using commercially available kits (Pishtazteb, Iran).
Serum levels of Apelin (EastBiopharm, Mainland, China)
and insulin (KOMA BIOTECH INC, South Korea) were
measured by rat specific ELISA kits using a multiplate
ELISA reader (BioTek, CA, USA). The sensitivity of
the assays for insulin was 0.75 µIU/ml. TNF-α and IL1ß
levels in the serum were determined using ELISA kits
specific for rat (KOMA BIOTECH INC, South Korea).
The sensitivities of the assays for TNF-α and IL-1ß were
45 pg/ml and 15 pg/ml, respectively.
Insulin resistance estimation
The homeostasis model assessment of basal insulin
resistance (HOMA-IR) was used to calculate an
index from the product of the fasting concentrations
of plasma glucose (mmol/l) and plasma insulin (µU/
ml) divided by 22.5 (23). Lower HOMA-IR values
indicated greater insulin sensitivity, whereas higher
HOMA-IR values indicated lower insulin sensitivity
(i.e. insulin resistance) (26).
Isolation of total RNA and synthesis of cDNA
Total RNA was isolated from 100 mg of cardiac
muscles using RNX TM isolation reagent according to
the manufacturer’s procedure (CinaClon, Iran). Possible
DNA contamination was removed by treatment of
RNA (1 µg) with DNase I (2 U/µl) for 1 hour at 37oC
(Vivantis, Malaysia). Concentration of extracted RNA
was calculated at the wavelength of 260 nm using
NanoDrop spectrophotometer (Eppendorf, Germany). To
detect the purity of RNA, its optical density (OD) ratio at
260/280 nm was determined and samples having a ratio
>1.8 were used for cDNA synthesis. Reverse transcription
was carried out using the RocketScript RT PreMix kit
using 1 µg of RNA and random hexamer primers based
on manufacturer’s protocol (Bioneer Corporation, South
Korea). Reverse transcription was carried out at 42°C for
90 minutes followed by incubation at 70°C for 5 minutes.
cDNAs were stored at -20°C until used for real-time
polymerase chain reaction (PCR).
Real time polymerase chain reaction analysis
Relative quantitative analysis of target genes (Apj and
Apelin) and an internal reference gene (Gapdh) was done
using the realtime PCR system (Light-Cycler 480, Roche,
Germany). Specific sets of primers (Bioneer, South
Korea) designed for this study were:Apelin (GenBank accession NO: NM_031612.3):F: 5'-TGGAAGGGAGTACAGGGATG-3'R: 5'-TCCTTATGCCCACT-3'Apj (GenBank accession NO: NM_031349.2):F: 5'-GGACTCCGAATTCCCTTCTC-3'R: 5'-CTTGTGCAAGGTCAACCTCA-3'Gapdh (GenBank accession NO: NM_NM-001034055):F: 5'-CTCATCTACCTCTCCATCGTCTG-3'R: 5'-CCTGCTCTTGTCTGCCGGTGCTTG-3'.Final reaction volume for the analysis of Apelin and Apj
gene expression was 12.5 µL (containing 6.25 µl qPCRTM
Green Master Kit for SYBR Green I® (Jena Biosciense,
Germany), 0.25 µl of each primer (200 nM), 3 µl cDNA
(~100 ng), and 2.25 µl nuclease-free water). The cycling
conditions were 95°C for 5 minutes, followed by 45
cycles at 95°C for 15 seconds and 60°C for 30 seconds.
Reactions were performed in triplicate. All runs included
one negative-template control consisting of PCR-grade
water instead of cDNA. Relative quantification was
performed according to the comparative 2-ΔΔCt method
and using Lightcycler 96® software. Validation of assay
to ensure that the primer used for the target and internal
reference genes had similar amplification efficiencies,
was performed. All qPCR analysis was performed
according to The Minimum Information for Publication
of Quantitative Real-Time PCR Experiments (MIQE)
guideline (27).
Cell lysis and Western blot analysis
The levels of Apelin and Apj proteins in the heart of
treated and untreated rats on day 28 were determined
using Western blot analysis. Briefly, 50 mg of tissues were
incubated for 30 minutes at 4°C in 1 ml homogenization
buffer (pH=7.4) containing 255 mM sucrose, 2 mM EDTA
and 20 mM HEPES supplemented with protease inhibitor
cocktail (Roche, Laval, Canada) and homogenized with
homogenizer (Silent Crusher, Heidolph, Germany) on ice.
Homogenates were centrifuged at 12000 g for 15 minutes at
4°C, supernatants were collected and protein contents were
determined using Bradford assay kit (Pars Azma, Iran). Next,
25 µl of cell lysate was mixed with 25 µl sodium dodecyl
sulphate (SDS) sample loading buffer (0.5 M Tris, pH=6.8,
50% glycerol, 10% SDS, 7.5% 2-ß mercaptoethanol, and
0.2% bromophenol blue). The final concentration of protein
in each sample was about 5 µg/µl. The samples were boiled
for 10 minutes at 65°C, loaded on 10% SDS-polyacryleamide
gel electrophoresis (SDS-PAGE) and electrotransferred onto
a nitrocellulose membrane. (Schleicher & Schuell, Inc.,
Keene, NH). The membranes were blocked (for 1 hour)
in Tris buffered saline (TBS) containing 0.05% Tween 20
(TBST, pH=7.4) and nonfat dry milk (5%). Blots were then
washed in TBS and incubated with primary antibodies (anti
Apelin, anti APJ, and anti GAPDH, Abcam, Cambridge, UK)
at 1:200 dilution. Primary antibodies were detected by using
goat anti-rabbit horseradish peroxidase conjugated antibody
(Abcam, Cambridge, UK, 1:1000 dilution) and DAB reagent
(Sigma Aldrich, Germany).
Statistical analysis
Statistical analysis was conducted using SPSS 18
software. Descriptive statistics were presented as means ±
SE. Means of each variable in the treatment groups and at
various time points were compared using two-way analysis
of variance. Group, time and their interaction term were
considered as fixed effects in the model. In significant
cases, adjusted comparison of means was undertaken using
Sidak post-hoc test. In case of high variability among data
and non-homogenous variance, transformation of data was
performed. For most factors, variance became homogenous
after logarithmic transformation. However, comparison of
weight of animals among experimental groups on each day,
was performed using non-parametric analysis of variance
(Kruskal-Wallis test) followed by Mann-Whitney U test. In
all analysis, a P<0.05 was considered statistically significant.
Results
L-carnitine supplementation and insulin resistance
markers
Serum glucose level showed no significant changes after 5weeks of feeding with HF/HC, while it significantly increasedafter STZ treatment (Fig .1A). Higher levels of insulin andHOMA-IR were found in diabetic group after diabetesinduction as compared to control group (P<0.05, Fig .1B, C).
These results showed that HF/HC diet and STZ treatment ledto obvious insulin resistance with higher insulin, glucose andHOMA-IR levels compared to control animals. Treatmentof diabetic rats with LC for 14 or 28 days could improvehyperglycemia, hyperinsulinemia and elevated HOMA-IR,
in particular, 28 days after LC supplementation (Fig .1A-C).
Fig.1
Effect of LC on glucose, insulin and HOMA-IR levels in HF/HC diet
fed diabetic rats. Rats were fed with regular chow diet (control) or HF/
HC diet for 5 weeks (diabetic). HF/HC fed rats were treated with LC (300
mg/kg/day) from the first day of diabetes confirmation for 14 or 28 days
(Diabetic+LC, n=5/group). A. Serum glucose levels, B. Serum insulin level,
and C. HOMA-IR levels. Data are expressed as means ± SE. Different
letters (a, b and c) demonstrate significant differences between groups on
each day at P<0.05.
LC; L-carnitine, HOMA-IR; Homeostatic model assessment of insulin
resistance, and HF/HC; High fat/high carbohydrate.
Effect of LC on glucose, insulin and HOMA-IR levels in HF/HC diet
fed diabetic rats. Rats were fed with regular chow diet (control) or HF/
HC diet for 5 weeks (diabetic). HF/HC fed rats were treated with LC (300
mg/kg/day) from the first day of diabetes confirmation for 14 or 28 days
(Diabetic+LC, n=5/group). A. Serum glucose levels, B. Serum insulin level,
and C. HOMA-IR levels. Data are expressed as means ± SE. Different
letters (a, b and c) demonstrate significant differences between groups on
each day at P<0.05.
LC; L-carnitine, HOMA-IR; Homeostatic model assessment of insulin
resistance, and HF/HC; High fat/high carbohydrate.
L-carnitine supplementation and body weight change
Significant difference was observed in body weight
between the HF/HC-fed group and the group fed with
regular diet. Feeding of rats with high calorie diet
for five weeks resulted in elevation of body weight
compared to the control group in a time-dependent
manner (P<0.05, Fig .2). Diabetic rats treated with LC
for 14 or 28 days showed no significant changes in body
weight (P>0.05, Fig .2). Also, 28-day treatment with LC
did not change the body weight of healthy rats.
Fig.2
Effect of LC on body weight change in HF/HC diet fed diabetic rats.
Rats were fed with regular chow diet (control) or HF/HC diet for 5 weeks
(diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the
first day of diabetes confirmation for 14 or 28 days (Diabetic+LC, n=5/
group). Data are presented as means ± SE. Different letters (a, b and c)
demonstrate significant differences among groups on each day at P<0.05.
LC; L-carnitine and HF/HC; High fat/high carbohydrate.
Effect of LC on body weight change in HF/HC diet fed diabetic rats.
Rats were fed with regular chow diet (control) or HF/HC diet for 5 weeks
(diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the
first day of diabetes confirmation for 14 or 28 days (Diabetic+LC, n=5/
group). Data are presented as means ± SE. Different letters (a, b and c)
demonstrate significant differences among groups on each day at P<0.05.
LC; L-carnitine and HF/HC; High fat/high carbohydrate.
L-carnitine supplementation and alteration of serum
levels of Apelin
Compared to the control group, HF/HC diet caused a
significant increase in plasma levels of Apelin on all days
of the experiment. Treatment of diabetic rats with LC for
14 days had no obvious effect on serum levels of Apelin,
while diabetic rats treated with LC for 28 days, showed
significantly reduced serum levels of Apelin (P<0.05). LC
administration for 14 or 28 days did not change the serum
levels of Apelin in healthy rats (Fig .3).
Fig.3
Effect of LC on serum Apelin level in HF/HC diet fed diabetic rats.
Rats were fed with regular chow diet (control) or HF/HC diet for 5 weeks
(diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the
first day of diabetes confirmation for 14 or 28 days (Diabetic+LC, n=5/
group). Data are expressed as means ± SE. Different letters (a, b and c)
demonstrate significant differences among groups on each day at P<0.05.
LC; L-carnitine and HF/HC; High fat/high carbohydrate.
Effect of LC on serum Apelin level in HF/HC diet fed diabetic rats.
Rats were fed with regular chow diet (control) or HF/HC diet for 5 weeks
(diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the
first day of diabetes confirmation for 14 or 28 days (Diabetic+LC, n=5/
group). Data are expressed as means ± SE. Different letters (a, b and c)
demonstrate significant differences among groups on each day at P<0.05.
LC; L-carnitine and HF/HC; High fat/high carbohydrate.
L-carnitine influenced Apelin and Apj expression in
cardiac muscle of diabetic rats
The expression level of myocardial Apelin was significantlyincreased in diabetic rats on days 14 and 28 after diabetesinduction compared to rats that were fed with normal diet(P<0.05, Fig .4A, B). LC treatment for 14 days did not affectthe expression of Apelin in cardiac muscle of diabetic rats,
while myocardial Apelin expression was down regulated
in diabetic animals that received LC for 28 days (P<0.05,
Fig .4A, B).
Fig.4
Effect of LC on expression of Apelinand ApjmRNA (on days 0, 14 and
28 of experiment) and protein (on day 28 of experiment) in cardiac muscle
of HF/HC diet fed diabetic rats. Rats were fed with regular chow diet
(control) or HF/HC diet for 5 weeks (diabetic). HF/HC fed rats were treated
with LC (300 mg/kg/day) from the first day of diabetes confirmation
for 14 or 28 days (Diabetic+LC, n=5/group). A. ApelinmRNA level, B.
Apelin protein level, C. ApjmRNA level, and D. Apj protein level. Data
are expressed as means ± SE. Different letters (a, b and c) demonstrate
significant differences among groups on each day at P<0.05.
LC; L-carnitine and HF/HC; High fat/high carbohydrate.
Apj expression was increased in cardiac muscle of
diabeticrats 14 days after diabetes induction compared to controlanimals,
while after day 14, it reduced to levels similar tothose of control healthy
rats. LC treatment significantlyreduced the expression of myocardial
Apj in diabetic rats
(P<0.05, Fig. 4C, D). These results indicated that the LCtreatment efficiently reduced the myocardial over-expressionof Apelin and Apj caused by the HF/HC diet. Treatment ofhealthy rats with LC had no significant effect on myocardial
expression of Apelin and Apj genes
(P>0.05, Fig .4A-D).Effect of LC on expression of Apelinand ApjmRNA (on days 0, 14 and
28 of experiment) and protein (on day 28 of experiment) in cardiac muscle
of HF/HC diet fed diabetic rats. Rats were fed with regular chow diet
(control) or HF/HC diet for 5 weeks (diabetic). HF/HC fed rats were treated
with LC (300 mg/kg/day) from the first day of diabetes confirmation
for 14 or 28 days (Diabetic+LC, n=5/group). A. ApelinmRNA level, B.
Apelin protein level, C. ApjmRNA level, and D. Apj protein level. Data
are expressed as means ± SE. Different letters (a, b and c) demonstrate
significant differences among groups on each day at P<0.05.
LC; L-carnitine and HF/HC; High fat/high carbohydrate.
Effect of L-carnitine supplementation on serum lipids
Changes in serum lipids including TG, cholesterol,
HDL and LDL on days 0, 14 and 21 after treatment
of diabetic rats with LC are shown in Figure 5A-D.
Significantly higher levels of serum levels of TG and LDL
were observed in HF/HC fed group when compared to
the regular diet-fed control at the end of HF/HC feeding
period (P<0.05). However, cholesterol and HDL levels
in diabetic rats were similar to those in control animal.
On days 14 and 28 after diabetes induction, serum levels
of TG, cholesterol and LDL were elevated, while HDL
level were reduced in the HF/HC fed group compared
to the control ones (P<0.05, Fig . 5A-D). In diabetic rats
that were treated with LC for 14 days, serum levels of TG
and LDL were reduced, while those were treated for 28
days showed reduced level of serum TG and LDL, and
increased levels of HDL compared to untreated diabetic
animals (P<0.05, Fig .5A-D).
Fig.5
Effect of LC on serum and cardiac muscle levels of TNF-α and IL-1ß of HF/HC diet induced diabetic rats. Rats were fed with regular chow diet (control)
or HF/HC diet for 5 weeks (diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the first day of diabetes confirmation for 14 or 28 days
(Diabetic+LC, n=5/group). A. Serum TNF-α, B. Cardiac muscle TNF-α, C. Serum IL-1ß, and D. Cardiac muscle IL-1ß. Data are means ± SE. Different letters
(a, b and c) demonstrate significant differences between groups in each day at P<0.05.
LC; L-carnitine, HF/HC; High fat/high carbohydrate, TNF-α; Tumor necrosis factor-α, and IL-1ß; interleukin-1ß.
Effect of LC on serum and cardiac muscle levels of TNF-α and IL-1ß of HF/HC diet induced diabetic rats. Rats were fed with regular chow diet (control)
or HF/HC diet for 5 weeks (diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the first day of diabetes confirmation for 14 or 28 days
(Diabetic+LC, n=5/group). A. Serum TNF-α, B. Cardiac muscle TNF-α, C. Serum IL-1ß, and D. Cardiac muscle IL-1ß. Data are means ± SE. Different letters
(a, b and c) demonstrate significant differences between groups in each day at P<0.05.LC; L-carnitine, HF/HC; High fat/high carbohydrate, TNF-α; Tumor necrosis factor-α, and IL-1ß; interleukin-1ß.
Alterations of serum tumor necrosis factor-α and
interleukin-1ß in diabetic rats treated with L-carnitine
To investigate whether LC could improve inflammation
caused by feeding with HF/HC diets, serum levels of
TNF-α and IL-1ß were measured in treated and non-
treated animals. Serum and tissue levels of TNF-α
in all four groups after receiving their respective
treatment, are shown in Figure 6A, B. Serum TNF-α
level in rats fed with HF/HC diet was higher than that
of rats fed with the normal diet on days 0 (2.35 fold),
14 (2.92 fold) and 28 (3.7 fold) (P<0.05, Fig .6A).
Cardiac TNF-α level was also higher in diabetic
rats compared to control rats on different days after
diabetes induction (P<0.05, Fig .6B). LC treatment
significantly suppressed serum and tissue levels of
TNFa in HF/HC fed rats on days 14 and 28 compared
to untreated diabetic animals (P<0.05, Fig .6A, B). LC
treatment had no obvious effect on serum and tissue
concentrations of TNFa in healthy rats (P>0.05).
Fig.6
Effect of LC on serum and cardiac muscle levels of TNF-α and IL-1β of HF/HC diet induced diabetic rats. Rats were fed with regular chow diet (control)
or HF/HC diet for 5 weeks (diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the first day of diabetes confirmation for 14 or 28 days
(Diabetic+LC, n=5/group). A. Serum TNF-α, B. Cardiac muscle TNF-α, C. Serum IL-1β, and D. Cardiac muscle IL-1β. Data are means ± SE. Different letters
(a, b and c) demonstrate significant differences between groups in each day at P<0.05.
LC; L-carnitine, HF/HC; High fat/high carbohydrate, TNF-α; Tumor necrosis factor-α, and IL-1β; interleukin-1β.
Serum levels of IL-1ß were increased in HF/HC fed
rats by 1.85, 2.43 and 2.54 fold on days 0, 14 and 28
after feeding, respectively (P<0.05, Fig .6C). Cardiac
IL-1ß level was also increased in a time-dependent
manner in diabetic animals compared to healthy rats
(P<0.05, Fig .6D). Treatment of diabetic rats with LC
for 14 or 28 days significantly reduced the serum and
cardiac levels of IL-1ß compared to untreated diabetic
rats (P<0.05, Fig .6C, D).Effect of LC on serum and cardiac muscle levels of TNF-α and IL-1β of HF/HC diet induced diabetic rats. Rats were fed with regular chow diet (control)
or HF/HC diet for 5 weeks (diabetic). HF/HC fed rats were treated with LC (300 mg/kg/day) from the first day of diabetes confirmation for 14 or 28 days
(Diabetic+LC, n=5/group). A. Serum TNF-α, B. Cardiac muscle TNF-α, C. Serum IL-1β, and D. Cardiac muscle IL-1β. Data are means ± SE. Different letters
(a, b and c) demonstrate significant differences between groups in each day at P<0.05.LC; L-carnitine, HF/HC; High fat/high carbohydrate, TNF-α; Tumor necrosis factor-α, and IL-1β; interleukin-1β.
Discussion
Obesity is one of the most important causes of CVDs.
Obesity can disrupt secretion of adipose-derived
adipokines and lead to systemic metabolic dysfunction,
inflammation and cardiovascular complications (2-4).
According to recent studies, Apelin and its receptor, Apj,
have dysregulated expression or secretion patterns in
cardiovascular system of obese diabetic rats (28). In the
present study, high-fat fed rats with obesity and diabetes
were used to investigate the potential effects of LC on
Apelin system expression in cardiac muscle.The results of the present study demonstrated that rats fed
with a HF/HC diet showed increased levels of body weight,
blood cholesterol, TG, LDL-C and glucose along with
hyperinsulinemia and insulin resistance when compared to
control animals. In accordance with our results, previous
works showed that plasma Apelin level is elevated in patients
or animals with type II diabetes and insulin resistance (5, 9,
11, 15, 16). The increased Apelin expression may be due
to hyperinsulinemia, since it has been reported that lack of
insulin in STZ-treated mice is associated with a decreased
expression of Apelin in adipocytes (29).Our results showed that Apelin and its receptors
were upregulated in cardiac muscle of obese diabetic
rats. Recently, Alfarano et al. (28) showed that Apelin
treatment of obese animals with heart failure accelerates
myocardial fatty acid oxidation and improves glucose
tolerance. Several studies have provided convincing
evidence indicating that mitochondrial dysfunction may
be an important event in the development of heart failure in
diabetic patients (30). Apelin can attenuate mitochondrial
damage in cardiac muscle by increasing mitochondrial
DNA content and citrate synthase activity (28). Increased
Apelin secretion or expression in diabetic rats, along with
hyperinsulinemia, may be a compensatory mechanism to
enhance insulin sensitivity and glucose uptake in target
tissues such as cardiac muscle. In this regard, recent
studies have shown that Apelin stimulates glucose uptake
in myotubes, resulting in increased insulin sensitivity and
suppression of lipid accumulation in myotubes (31-34).Our results showed that changes in metabolic indices
were associated with increased serum and tissue
inflammatory markers including TNFa and IL-1ß. These
factors have important roles in cardiovascular dysfunctions
in animals and humans with obesity, diabetes and insulin
resistance (30,
33).
Recent in vivo and in vitro findings
have shown that TNF-α induces Apelin gene expression in
obese mice. Furthermore, short-term exposure to an intra
peritoneal.injection of TNF-α in C57Bl6/J mice increased
Apelin expression in adipose tissue and enhanced Apelin
plasma levels (33).
These results support our hypothesis
that inflammatory factors such as TNF-α upregulates
the Apelin axis which, in turn, modulates multiple
physiological processes and may contribute to Apelinmediated
attenuation of cardiac dysfunction. Based on the
above findings, it might be concluded that up regulation
of Apelin in cardiac muscle of diabetic rats may improve
the function of cardiac muscle in this condition and may
attenuate the pathophysiological complications in patients
with heart failure.Our results showed that LC, when added to the
drinking water, attenuates increased Apelin and Apj gene
expression in cardiac muscle and reduces serum levels
of Apelin diabetic rats; these changes were associated
with reduced insulin resistance indices and serum
inflammatory markers. To the best of our knowledge, this
is the first report showing cardioprotective effects of LC
in diabetes and obesity conditions and its association with
modulation of Apelin axis in cardiac muscle.LC supplementation may be beneficial in obesity and
diabetes conditions as in obese rats with insulin resistance,
it was shown that LC supplementation improves glucose
tolerance and increases total energy expenditure (35). The
molecular mechanism through which LC down regulates
Apelin and Apj expression in cardiac muscle of diabetic
rats, is unknown.Previous study has shown that weight loss can lead to
significant reduction of adipose tissue Apelin expression; in
the present study, LC treatment led to a weight loss in diabetic
rats compared to untreated ones (36). These findings support
the possible role of weight reduction on Apelin expression
in cardiac muscle. Furthermore, treatment of diabetic rats
with LC significantly reduced the serum levels of IL-1ß and
TNF-α (37). Because elevated inflammatory cytokines in
obesity can accelerate the expression and secretion of Apelin,
it is hypothesized that down regulation of cardiac Apelin in
obese diabetic rats treated with LC may be associated with
anti-inflammatory action of LC.In previous studies, the relationship between
cardiomyopathy, cardiac arrhythmia and heart failure due toaccumulation of long-chain fatty acids in the absence of LCor its functional derivatives has been proven (38). In obesepatients died with insulin resistance, severe heart failure andmyocardial infarction have been reported concomitant withvery low levels of serum LC (39). Apelin axis can improvemetabolic and inflammatory disturbances in cardiac muscleof patients with CVDs. Thus, it seems that following LCtreatment, by improving the metabolic and inflammatorycomplications, Apelin expression was reduced, suggestingthat an increase in Apelin axis expression may reflect acompensatory mechanism against development of insulin
resistance complications in cardiac muscle of obese patients.
Conclusion
The results of the current study revealed that cardiac
Apelin and Apj expression were increased in the HF/HC
fed rats and these changes were significantly correlated
with increased serum levels of Apelin and insulin, body
weight, insulin resistance, inflammatory markers and the
atherogenic lipid profile. Treatment of diabetic rats with
LC resulted in down regulation of Apelin axis in diabetic
rats concomitant with improving insulin resistance and
inflammatory markers and weight loss. These results
suggest that LC acts as novel regulator of Apelin axis in
cardiac muscle that can improve cardiac complications in
diabetic patients.
Authors: C Alfarano; C Foussal; O Lairez; D Calise; C Attané; R Anesia; D Daviaud; E Wanecq; A Parini; P Valet; O Kunduzova Journal: Int J Obes (Lond) Date: 2014-07-16 Impact factor: 5.095
Authors: Joanna Krist; Katharina Wieder; Nora Klöting; Andreas Oberbach; Susan Kralisch; Tobias Wiesner; Michael R Schön; Daniel Gärtner; Arne Dietrich; Edward Shang; Tobias Lohmann; Miriam Dreßler; Mathias Fasshauer; Michael Stumvoll; Matthias Blüher Journal: Obes Facts Date: 2013-02-21 Impact factor: 3.942
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