Samaneh Karimi1, Jafar Ai2, Layasadat Khorsandi3, Darioush Bijan Nejad1, Ghasem Saki1. 1. Cell and Molecular Research Center, Faculty of Medicine, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran. 2. Tissue Engineering and Applied Cell Sciences, Department-School of Advanced Technologies in Medicine, Tehran University of Medical Sciences, Tehran, Iran. 3. Cell and Molecular Research Center, Faculty of Medicine, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran. Electronic Address: khorsandi_cmrc@yahoo.com.
Diabetes mellitus is one of the most common chronic
diseases, with a progressively increasing number of
people affected by this disease around the world (1). Type
1 diabetes is caused by the loss or destruction of beta
cells. It is difficult to maintain optimal insulin dosage
in diabetic patients, hence insulin administration does
not completely prevent the conditions associated with
diabetes. Therefore, transplantation of insulin-producing
cells (IPCs) is potentially an ultimate cure for type 1
diabetes (2). Pancreatic beta cell failure is also involved
in type 2 diabetes. It is well known that both beta cell
function and mass decline progressively in type 2 diabetes
(3).Numerous researchers have focused on generation IPCs.
These cells may be derived from progenitor cells of the
pancreas, bone marrow-derived mesenchymal stem cells,
skin derived stem cells, adipose derived mesenchymal
stem cells, pluripotent embryonic stem cells, and hepatic
tissue (4-9). However, they have poor efficiency.Glucagon-like peptide 1 (GLP-1) is produced in the
intestine and secreted into the plasma in response to food
intake. GLP-1 reduces gastric emptying time, decreases
food intake and stimulates transcription of the proinsulin
gene in beta cells. Hence, GLP-1 is considered as a
therapeutic agent for type 2 diabetes. GLP-1 enhances the
effects of glucose in stimulating insulin secretion from
the beta cells. It reduces blood glucose concentration
and stimulates insulin secretion in diabetic mice (10).
In addition, GLP-1 increases the beta cell mass by
stimulating the neogenesis and differentiation of ductal
stem cells into endocrine cells (11, 12). On the other hand,
GLP-1 is promptly degenerated by dipeptidyl peptidase
IV (DPP IV). In the past decade DPP IV inhibitors have
been progressively used for treatment of type 2 diabetes,
including vildagliptin, sitagliptin, alogliptin, gemigliptin,
saxagliptin, linagliptin and anagliptin (13). Several studies
have examined the acute and chronic effects of DPP IV
inhibitors on pancreatic islet and beta cell morphology
in animals (14). Chronic administration of DPP IV
inhibitors increased beta cell number via enhancing cell
proliferation and preventing apoptosis (15). Vildagliptin
(VG), a DPP IV inhibitor, covalently binds to the catalytic
site of DPP IV, hence increasing GLP-1 levels (16). Foley
et al. (17) have reported that VG significantly elevates
secretory capacity of beta cells in type 2 diabetic patients.
Akarte et al. (18) have shown that VG ameliorates GLP1
and stimulates beta cell proliferation in streptozotocin
induced diabetes in rats. Duttaroy et al. (19) have reported
that VG increases beta cell mass.To date, most studies have focused on the effects of
VG on hypoglycemia and insulin secretion capacity of
beta cells in diabetic subjects. But, the effects of VG
on differentiation of stem cells into beta cells have not
been investigated. In this study, the effects of VG on
differentiation of IPCs from rat ASCs was evaluated.
Materials and Methods
Healthy adult male Wistar rats (6-8 weeks old, 160180
g) were used in this experimental study. The rats
were purchased from the Research Animal Center of
Jundishapur University. This work was performed
according to the guidelines of the institution’s Animal
Ethics Committee (approval number: IR.AJUMS.REC.
1395.772). Epididymal fat pads were isolated under sterile
conditions. The fat pads were exposed to collagenase
(1.0 mg/ml in DMEM) for 20 minutes at 37°C. Then, the
obtained homogenous cell suspension was centrifuged at
1200 rpm for 10 minutes. The obtained cell pellet was
resuspended in DMEM and then cultured in 25 cm2 flasks.
The ASCs were refed every 3 days and passaged when the
confluency reached to approximately 80% (8).
Characterization of adipose stem cells
Prior to cell treatments, the expression of cell surface
markers of passage 3 ASCs, including CD34 (Santa
Cruz, USA), CD90 (Santa Cruz, USA), CD29 (Abcam,
USA), CD105 (Abcam, USA), CD45 (Abcam, USA) and
CD73 (Abcam, USA), were analyzed by FACSCanto™
flow cytometer (Becton Dickinson, San Jose, CA, USA).
At passage 3, osteogenic and adipogenic differentiation
potentials of ASCs were also evaluated using appropriate
induction media as previously described (8). Oil red O
(Sigma-Aldrich, USA) and Alizarin red (Sigma-Aldrich,
USA) staining were used to determine adipogenic and
osteogenic potentials of the ASCs, respectively (5, 8).
Experimental design
For all experiments passage 3 ASCs were used. In
experimental groups, ASCs were cultured in IPC induction
medium with or without VG (Santa Cruz, USA). The
control group was cultured in serum-free DMEM only.
Induction of ASCs was performed in 3 steps (5, 8). In
the first step, 100,000 cells were cultured for 48 hours in
serum-free, high-glucose DMEM (25 mmol/L) containing
0.5 mmol/L 2-mercaptoethanol (Sigma-Aldrich, USA)
and 10 ng/ml activin A (Sigma-Aldrich, USA). In the
second step, the cells were cultured in medium containing
30 ng/ml fibroblast growth factor (FGF, Sigma-Aldrich,
USA), 2 mmol/L L-glutamine (Sigma-Aldrich, USA),
20 ng/ml epidermal growth factor (EGF, Sigma-Aldrich,
USA), 2% B27 (Invitrogen, USA), and 1% non-essential
amino acids (Invitrogen, USA) for 8 days. Finally, in the
third step, the cells were cultured in a different medium
containing 10 mmol/L nicotinamide (Sigma-Aldrich,
Karimi et al.
USA), 2% B27 and 10 ng/ml betacellulin (Sigma-
Aldrich, USA) for 8 days. In the VG group, 10 ng/ml VG
were added to the differentiation medium at steps 2 and
3. For accuracy in VG addition throughout the study, a
stock solution of 0.01 mg/ml VG/DMEM was prepared
and stored at 4°C. Based on our pilot studies 1 µl of this
stock solution was added to the cells as mentioned above.
Immunofluorescent staining
Newport Green (NG, Invitrogen, USA) dye was used
to determine insulin-containing cells. NG is a fluorescent
molecule that has an affinity for zinc, which is necessary
to form insulin granules in beta cells. The cells were fixed
with 4 % paraformaldehyde (Sigma-Aldrich, USA) for
20 minutes and permeabilized with 0.1 % Triton X-100
(Sigma-Aldrich, USA) in phosphate buffered saline
(PBS) for 10 minutes at room temperature. Cells were
exposed to 25 µM NG in PBS for 30 minutes at 37°C.
After washing in PBS, the cells were analyzed under a
fluorescent microscope (Olympus, Japan) and percentage
of NG-positive cells was determined (20).
Real time polymerase chain reaction
RNeasy Mini kit (Qiagen, Germany), was used to isolate
RNA from the cultured cells. cDNA synthesis kit was used
to generation cDNA from the isolated RNAs (Qiagen,
Germany). The sequences for all primers are shown in
Table 1. Polymerase chain reaction (PCR) amplification
performed over 45 cycles using the Applied Biosystems™
7500 Real-Time PCR System, and the following program:
95°C for 10 minutes, 95°C for 25 seconds, 5°C for 50
seconds and 60°C for 45 seconds. Data were analyzed
using the 2-ΔΔCT method. Expression values were corrected
for the housekeeping gene GAPDH (5, 8).Primer sequences
Radioimmunoassay
The cultured cells in all groups were exposed to glucose-
free Krebs-Ringer bicarbonate (KRB, Sigma-Aldrich,
USA) for 1 hour. Then, the cells of each group were
divided in three groups and exposed to KRB containing
glucose at the concentration of 5.56, 16.7 and 25 mmol/L
for 1 hour, Insulin contents were determined using a RIA
kit (Millipore, Germany) (5, 8).
Statistical analysis
The data were analyzed using one-way ANOVA
followed by Post hoc LSD test and were presented as the
mean ± SD. P<0.05 was considered significant.
Results
Passage 3 ASCs had a spindle-like morphology. Flow
cytometry assessments showed high expression levels of
CD90 (99.4%), CD29 (97.3%), CD105 (96.4%) and CD73
(83.3%), whereas significantly lower expression levels of
CD34 and
CD45 were observed. After the ASCs were
cultured in adipogenic medium for 2 weeks, lipid droplets
were observed in their cytoplasm detected by Oil-red O
staining. On the other hand, osteogenic medium treatment
of ASCs resulted in generation of mineral deposits as
indicated by Alizarin red staining (data not shown).
Morphology
In differentiation medium with VG, however, round
cell morphology at a confluency similar to the pancreatic
islet-like clusters was observed. Interestingly, in the
cells cultured in differentiation medium without VG, the
round morphology was less common. The control ASCs,
at the first of experiment, had elongated morphology.
The control ASCs appeared in various shapes including
spherical, neuron-like cells or glial-like cells at the end of
experiment (Fig .1).
Fig.1
Morphological changes of ASCs. A. ASCs in only DMEM: various features including spherical, spindle fibroblast-like cells, and NLC are observed,
B. ASCs in IPC induction medium in the absence of VG, and C. ASCs in IPC induction medium in the presence of VG. The IPCs show a round morphology
(magnification: ×250).
Very few ASCs showed NG-positive staining in control
group. The number of cells staining positive for NG was
significantly higher in differentiation medium with VG,
compared to the cells cultured in differentiation medium
but in the absence of VG (P<0.001). In the control group
only a few ASCs showed NG-positive staining (P<0.001).
These data are illustrated in Figures 2 and 3.Morphological changes of ASCs. A. ASCs in only DMEM: various features including spherical, spindle fibroblast-like cells, and NLC are observed,
B. ASCs in IPC induction medium in the absence of VG, and C. ASCs in IPC induction medium in the presence of VG. The IPCs show a round morphology
(magnification: ×250).ASCs; Adipose-derived mesenchymal stem cells, NLC; Neuron-like cells, IPC; Insulin-producing cells, and VG; Vildagliptin.Immunofluorescence illustration of NG staining. A. Control ASCs in DMEM only, B. ASCs in IPC induction medium in the absence of VG, and C. ASCs
in IPC induction medium in the presence of VG. Brilliant green indicating NG-positive cells (magnifications: ×400).
NG; Newport green, ASCs; Adipose-derived mesenchymal stem cells, VG; Vildagliptin, and IPC; Insulin-producing cells.Percentage of NG-positive cells in various groups.
Values are expressed as mean ± SD. *; P<0.001, #; P<0.001, * , #; Indicate
comparison with the control and differentiation medium without VG,
respectively, NG; Newport green, and VG; Vildagliptin.
Insulin release in response to glucose stimulation
Insulin secretion at 5.56 mmol/L of glucose increased
approximately 4.3 fold, and 5.6 fold at 25 mmol/L of
glucose (a glucose challenge) (P<0.01) in the ASC-
derived IPCs cultured in VG-free differentiation medium
On the other hand, secretion of insulin was significantly
elevated in VG-treated ASC-derived IPCs at 5.56 mmol/L
of glucose (2 fold) and under a glucose challenge (4.2
fold), compared to the VG-untreated ASC-derived IPCs
(P<0.01). In the control group, however, low levels of
insulin in the absence or presence of the glucose challenge
were observed (Fig .4).
Fig.4
Insulin secretion in response to the low and high concentrations of
glucose.
Values are expressed as mean ± SD. *; P<0.01, **; P<0.01, ***; P<0.001,
#; P<0.05, ##; P<0.001, and * , #; Indicate comparison with control and
differentiation media without Vildagliptin (VG), respectively.
Insulin secretion in response to the low and high concentrations of
glucose.Values are expressed as mean ± SD. *; P<0.01, **; P<0.01, ***; P<0.001,
#; P<0.05, ##; P<0.001, and * , #; Indicate comparison with control and
differentiation media without Vildagliptin (VG), respectively.
Gene expression
Insulin (Ins), glucose transporter 2 (Glut-2) and Pdx-1
showed low expression levels in the control cells. In comparison
to the cells treated without VG, the expression of
Ins, Glut-2 and Pdx-1 genes increased nearly 4.4 fold, 3
fold and 3.3 fold in the VG-treated IPCs (P<0.001), respectively
(Fig .5).
Fig.5
Gene expression in experimental and control groups. Expression
normalized to the average of housekeeping gene (GAPDH).
Values are expressed as mean ± SD. *; P<0.001, #; P<0.001, * , #; Indicate
comparison with control and differentiation medium without Vildagliptin
(VG), respectively.
Gene expression in experimental and control groups. Expression
normalized to the average of housekeeping gene (GAPDH).Values are expressed as mean ± SD. *; P<0.001, #; P<0.001, * , #; Indicate
comparison with control and differentiation medium without Vildagliptin
(VG), respectively.
Discussion
The data presented here indicates that VG considerably
enhances differentiation of ASCs into insulin-
secreting cells. The presence of IPCs was confirmed by
morphological evaluations, assessment of the expression
pattern of islet-specific genes, and generation and
secretion of insulin. The IPCs not only generated
insulin, but also secreted insulin in response to glucose
challenge. These responses were significantly higher in
the presence of VG.We observed that VG significantly enhanced expression
of Pdx-1 gene in ASC-derived IPCs. Expression of Pdx-1
is developmentally essential for both endocrine and
exocrine portions of the pancreas, as it. Pdx-1 regulates
insulin gene transcription in response to glucose (21).
The potential of Pdx-1 to activate gene transcription is
dependent on its ability to interact with other transcription
factors (22). Pdx-1 stimulates expression of several
genes such as Glut-2, glucokinase (GCK) and Ins, which
involves in maturation of beta cells (23). Miyagawa et al.
(24) have shown that VG increases expression of insulin
and Pdx-1 genes, and elevates insulin secretion in a mice
model of diabetes.In VG-treated cells, expression of other genes including
Insulin and Glut-2 was also significantly increased, which
implied that the ASC-derived IPCs have undergone
differentiation and maturation. In the beta cells, glucose
uptake is regulated by Glut-2, which is critical for insulin
secretion in response to glucose (25).In addition, VG significantly enhanced insulin secretion
in glucose challenge condition. The percentage of
insulin-positive cells was elevated in the presence of
VG compared to the VG-free group. These data revealed
that VG effectively enhanced maturation of the ASC-
derived IPCs. In a previous study, Foley et al. (17) have
reported that VG significantly elevates secretory capacity
of beta cells. Mari et al. (26) have also showed that VG
improves beta cell function by increasing the insulin
secretion capacity in diabetic patients. Utzschneider et
al. (27) found that VG improves beta cell function and
postprandial glycemia in patients with impaired fasting
glucose.Previous studies have demonstrated that GLP-1 expands
pancreatic beta cell mass by inducing proliferation
and neogenesis of these cells (11, 12). Hence, VG, by
suppression of DPP IV, may increase beta cell mass and
consequently increase insulin secretion.Duttaroy et al. (19) showed that VG significantly
increased pancreatic beta cell mass in neonatal rats.
In a preclinical study, VG and other DPP IV inhibitors
were shown to expand beta cell mass (28). Shimizu et
al. (29) have reported that VG protects beta cells against
endoplasmic reticulum stress in C/EBPB transgenic mice.In contrast, Gudipaty et al. (30) showed that sitagliptin,
another DPP IV inhibitor, had no effect on the beta
cell number. Hamamoto et al. (31) reported that VG
enhanced beta cell mass by suppressing apoptosis,
oxidative stress and endoplasmic reticulum stress, and
induced proliferation and directly regulating beta cell
differentiation in diabetic mice.To our knowledge, this work is the first to study the
effects of VG on generation of insulin-secreting cells.
Almost all previous studies have reported VG effects on
pancreas of diabetic patients or diabetic animal models.
Conclusion
The present work demonstrated that VG effectively
enhanced differentiation of ASCs into the IPCs. Further
in vitro and in vivo experiments are required to reveal the
mechanisms, by which VG stimulates mesenchymal stem
cell differentiation.
Authors: S Bonner-Weir; M Taneja; G C Weir; K Tatarkiewicz; K H Song; A Sharma; J J O'Neil Journal: Proc Natl Acad Sci U S A Date: 2000-07-05 Impact factor: 11.205
Authors: Kristina M Utzschneider; Jenny Tong; Brenda Montgomery; Jayalakshmi Udayasankar; Fernando Gerchman; Santica M Marcovina; Catherine E Watson; Monica A Ligueros-Saylan; James E Foley; Jens J Holst; Carolyn F Deacon; Steven E Kahn Journal: Diabetes Care Date: 2007-10-01 Impact factor: 19.112
Authors: S Hamamoto; Y Kanda; M Shimoda; F Tatsumi; K Kohara; K Tawaramoto; M Hashiramoto; K Kaku Journal: Diabetes Obes Metab Date: 2012-09-25 Impact factor: 6.577
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Fig.5