Hadis Zeinali1, Mahnaz Azarnia2, Peyman Keyhanvar3,4, Reza Moghadasali5, Somayeh Ebrahimi-Barough6. 1. Faculty of Biological Sciences, Kharazmi University, Tehran, Iran. 2. Faculty of Biological Sciences, Kharazmi University, Tehran, Iran. Email: azarnia@khu.ac.ir. 3. Stem Cell Research Center, Tabriz University of Medical Sciences, Tabriz, Iran. 4. Department of Medical Nanotechnology, School of Advanced Medical Sciences, Tabriz University of Medical Sciences, Tabriz, Iran. 5. Department of Stem Cells and Developmental Biology, Cell Sciences Research Center, Royan Institute for Stem Cell Biology and Technology, ACECR, Tehran, Iran. 6. Department of Tissue Engineering and Applied Cell Sciences, School of Advanced Technologies in Medicine, Tehran University of Medical Sciences, Tehran, Iran.
Acute kidney injury (AKI) is defined as sudden decline
in the function of kidneys for waste removal, which is
due to renal tubular damage (1). Cell death, as well as
functional and morphological changes, occur in sublethal damage caused by AKI (2). About 20% and 33%
of hospitalized adults and children, respectively, suffer
from AKI, and the mortality rate due to AKI in patients
of surgical and medical intensive care units (ICU) is high.
Consequently, AKI has attracted much attention among
nephrologist and intensive care unit care providers (3, 4).
Common treatments used in AKI include pharmacological
therapy, dialysis, and renal replacement therapy, but
each of these treatments still has certain limitations (5).
Dialysis and replacement therapies have no significant
effect on the high rate mortality caused by AKI. Dialysis
is commonly associated with socioeconomic problems.
With regards to replacement therapy, the lack of enough
donors and the use of immunosuppressive drugs following
kidney transplantation may cause issues for the recipients.
Pharmacological therapy has been unsuccessful in terms
of recovering lost cells. Therefore, new therapeutic
strategies for AKI seem to be instantly required (6).Among the common experimental models of AKI are
toxic models, which are caused by nephrotoxins, such as
cisplatin. Cisplatin-induced extensive injury is usually
assessed on days 3-5 post-treatment, whereas earlier time
points may lead to sub-lethal changes (2). Cisplatin or
cis-diamminedichloroplatinum (II) is a chemotherapeutic
drug, which contains platinum, carboplatin or oxaliplatin.
Platinum in cisplatin compound binds to DNA and
results in crosslinking that triggers apoptosis (7). Sodium wasting, disturbance of magnesium reabsorption and water
absorption are among other consequences of cisplatin
therapy. Additionally, prevention of kidney injury is very
important in cisplatin therapy (8, 9). Cisplatin-induced
tubular dysfunction is due to apoptosis and necrosis.
Tubular cell death, resulting from cisplatin, occurs via
multiple signaling pathways and mechanisms that have
been considered as potential targets for various clinical
treatments (10-14). Two signaling pathways of apoptosis
include intrinsic (mitochondrial) and extrinsic (death
receptor) pathways. Apoptosis is initiated by the extrinsic
signaling pathway, which begins with a cell death signal
or death ligand docking on tumor necrosis factor (TNF)
superfamily death receptors (15). The intrinsic pathway
of apoptosis, on the other hand, is regulated by B-cell
lymphoma-2 (Bcl-2) protein family, as the Bcl-2 family
members play different roles in intrinsic death pathway.
For instance, anti-apoptotic Bcl-2 proteins inhibit pro-apoptotic members of the family (BAX and BAK) and
thereby inhibit apoptosis (15, 16).Multiple studies have demonstrated enormous
potentials for mesenchymal stem cells (MSCs) to repair
the damaged tissues via infusion and paracrine signaling
(17-19). Human endometrial stromal/stem cells (HEnSCs)
are MSC-like cells obtained from the endometrium.
HEnSCs can be isolated easily, expand rapidly, have
no major technical and ethical issues, and have a high
clonogenicity; and therefore, are suitable candidates for
therapeutic and tissue engineering purposes (20, 21). The
repair of soft tissue defects is a promising regenerative
capacity of the hEnSCs (22). Transplanted EnSCs in
the peri-infarct area increase cellular proliferation, but
decrease apoptosis via AKT, ERK1/2, STAT3 activation
and p38 inhibition (23). Pabla and Dong have found that
cisplatin exerts its ultimate destructive effects on renal
function through necrosis and apoptosis of renal cells
(8). Therefore, apoptosis reduction in renal tissue is one
of the principal mechanisms that is noteworthy in AKI
treatment.To provide an evidence for the effectiveness of hEnSC transplantation in AKI treatment, the
present study was designed based on the hypothesis that administration of these cells can
modulate the expression levels of Bcl-2 and Tnf-α in the renal tissue from
cisplatin-induced AKI rats. Such changes in transcriptional activities of
Bcl-2 and Tnf-α are related to apoptosis inhibition, which can result in
the improvement of renal pathology and function in rats receiving cell transplants after
cisplatin injection.
Materials and Methods
The experimental study was performed on 48 male
Wistar rats (150-200 g). The animals were kept in plastic
cages. They had unlimited access to water and food, and
were weighed daily. Ethical principles were followed in
accordance with Tabriz University of Medical Sciences
guidelines (IR.TBZMED.VCR.REC.1397.049). AKI was
induced using intraperitoneal (IP) injection of cisplatin
(Mylan, France). Animal care was provided by animal
house of Kharazmi University at 22.0 ± 2.0˚
C.A total of 48 rats were randomly divided into four groups (12 each). Group I (intact group)
received no treatment; group II (model group) received 5 mg/kg of body weight cisplatin
(IP), which was used to induce AKI; group III (PBS group) received 200 µl of
phosphate-buffered saline (PBS, Invitrogen, USA) in caudal vein 3 hours after cisplatin
injection; and group IV (cell group) received about 1 million hEnSCs suspended in PBS (200
µl) in caudal vein 3 hours after cisplatin injection. The rats were anesthetized by IP
injection of 80-100 mg/kg ketamine and 5-10 mg/kg xylazine. The rats were sacrificed on the
3rd and 5th day after cisplatin injection. After anesthesia, blood
collection was performed from the heart and the kidneys were collected rapidly for
subsequent analyses.
Isolation of human endometrial stromal/stem cells
The cell donor was an infertile woman who had referred to the hospital seeking
treatment. A written informed consent form was obtained from her prior to the procedure.
Endometrial biopsies for hEnSC isolation were obtained from the fundal region of the
uterine cavity. First, endometrium was scraped from the myometrium and then washed in PBS.
Mechanical minced tissue was digested using 1 mg/ml collagenase type I (Gibco, USA) and 25
mM 4-(2 hydroxyethyl)-1 piperazineethanesulfonic acid (HEPES) in Hank’s balanced salt
solution (HBSS, Merck, Germany) at 37ºC for 30-45 minutes. Glandular epithelial components
were removed by means of cell strainers (70 and 40 μm, Merck, Germany). Cell suspension
was centrifuged for cellular plaque deposition and plated in DMEM/F12 medium (Merck,
Germany) supplemented with 10% fetal bovine serum (FBS), 1% antibiotic Pen/Strep (Merck,
Germany). Medium change was performed every 2-3 days and cellular passage was carried out
when cultures reached about 80-90% confluency. The 3rd to 5th
passage cells were used for injection.
Flow cytometric analysis of human endometrial
stromal/stem cells
After the 3rd passage, cells were characterized for expression of surface
markers by flow cytometry (BD FACS Calibur, USA). Following hEnSCs fixation (2%
paraformaldehyde in PBS, 4˚ C, 1 hour), cells were washed and incubated using the
following PerCP- or phycoerythrin (PE)- or fluorescein-isothiocyanate (FITC)-conjugated
antibodies (4˚ C, 1 hour): CD73-PerCP (5 µl, BD Pharmingen, USA), CD90-FITC (3 µl, Exbio,
Czechia), CD105-PE (3 µl, Exbio, Czechia), CD146-PE (3 µl, BD Biosciences, USA), CD31-PE
(3 µl, Immunostep, Spain) and CD34-PE (3 µl, Exbio, Czechia). CD31 and CD34 are
endothelial and hematopoietic markers, respectively. Negative control was FITC-conjugated
mouse IgG1. Data were analyzed using FlowJo™ v10.6.1 software.
Renal function
On days 3 and 5 after transplantation of cells, rats were anesthetized and blood samples were collected
from the rat hearts. After 30 minutes, blood samples
were centrifuged (3000 rpm, 10 minutes) and upper
layer or serum was isolated. Samples were stored at
-20˚C until analysis. To access the renal function, we
determined levels of blood urea nitrogen (BUN), serum
creatinine (SCr), serum sodium (Na), and potassium
(K) on days 3 and 5 after cellular therapy. Biochemical
markers of the sera were measured using a Selectra Pro M
(ELITechGroup, USA) and a starlyte electrolyte analyzer
(Diamond Diagnostics Inc., USA).
Histopathological assay by hematoxylin and eosin
staining
Histological examination of the kidneys was performed
on day 5. Kidneys were washed twice with PBS, quickly
fixed in 10% formalin solution (Merck, Germany), then
processed and embedded in paraffin (Merck, Germany).
Finally, 5-µm thick sections were obtained. Histological
examination was performed using hematoxylin (Merck,
Germany) and eosin (Merck, Germany) staining. The
slides were observed under a light microscope (Zeiss,
Germany). The presence of pathologic tubular damage
(including apoptosis, necrosis, lumen dilation, debris
in the lumen and nuclear fragmentation) was scored
in 10 non-overlapping fields (100 tubules) for each
kidney section by a researcher who was blind to the
experimental groups. The score 0 represents no tubular
damage, 1= tubular injury in no more than one third of
the tubule cells, 2= one third to two thirds of the tubular
cell injury, and 3= more than two thirds of the tubular
injury. Finally, total pathologic score was obtained by
adding all 100 scores. The maximum score was 300.
Immunohistochemical analysis
TUNEL assay was performed on paraffin-embedded
tissues using the terminal deoxynucleotidyl transferase–
mediated dUTP nick-end labeling (TUNEL) method
(In Situ Cell Death Detection Kit, Roche, Germany)
according to the manufacturer’s instruction.Paraffin sections (5-μm thick) of kidneys were rehydrated in a series of alcohol and
water after deparaffinization with xylene. Then sections digested by proteinase K solution
(10 minutes, 37˚C) were washed in PBS for 2 minutes, and after blocking (i.e. blocking
endogenous peroxidase, 3% H2 O2 for 30 minutes), were incubated with
TdT enzyme solution (60 minutes, 37˚C). A stop/ wash buffer (30 minutes, 37˚C) was used to
terminate the reaction. The reaction was visualized using a 3, 3′-diaminobenzidine (DAB)
chromogen (Pro Taqs, Cat#300155400) and tissue counterstaining was performed using
hematoxylin. Sections were observed for TUNEL+ cells per high-power field (HPF) under a
light microscope (Zeiss, Germany). For each kidney, 10 fields were selected randomly at
40x magnification, and the number of TUNEL-positive cells and the total number of cells in
the glomeruli and tubules were counted using ImageJ software (LOCI, University of
Wisconsin). The percentage of apoptotic cells was evaluated in a blind manner. Data were
analyzed using GraphPad software.
Real-time polymerase chain reaction
The kidney samples were minced and RNA was extracted using a Maxcell extraction kit
(Iran). Synthesis of cDNA was performed using First Strand cDNA synthesis kit (Maxcell,
Iran). RNA/primer mixture (14 μl) including 1 μl random hexamer, 1 μl of 10 mM dNTP mix,
total RNA (volume based on normalization calculations), and DEPC water (up to 14 μl), was
incubated for 5 minutes at 65˚C and was then placed on ice immediately for 1 minute. Next,
1 μl Dia star (reverse transcriptase, RT), 1 μl of 8 mM DTT and 4 μl of 5X RT buffer were
mixed to prepare reaction master mix. Reaction master mix was added to RNA/ primer mixture
and then placed in the thermal cycler as follows: 50˚C, 60 minutes, and 95˚C, 5 minutes.
Real time-polymerase chain reaction (PCR) was carried to in duplicate. Reaction volume was
25 μl consisting Real Q Plus 2X Master Mix Green (Ampliqon, Denmark), 2 μl of primer
mixture and 2 μl of cDNA under the following thermal cycling: 5 minutes at 50˚C, 5 minutes
at 95˚C and 40 cycles of denaturation for 30 seconds and annealing/extension at 60-62˚C.
Relative expression levels of Bcl-2 and Tnf-α mRNA were
calculated using the 2-ΔΔCT method. Gapdh gene was considered
as internal control. Primer sequences are showed in Table 1.The primer sequences were used in the real-time polymerase chain reaction
Statistical analysis
Data are shown as mean ± SEM. Data analyses were
performed using GraphPad Prism 8.0.2 (GraphPad
Software Inc., USA). We compared the differences
among the groups using One-way analysis of variance
(ANOVA) with Tukey test. Analyses of body weight
between days 1 and 5 were done in each group using
two-way ANOVA. Expression levels of mRNA were
analyzed using the comparative Ct method. P<0.05
were considered as statistically significant.
Results
Human endometrial stromal/stem cells culture and
characterization
Isolation of undifferentiated hEnSCs was easily
performed due to their adherence to plastic flasks. The
results of hEnSCs immunophenotyping at passage 3 are
presented in histograms in Figures 1A and B. HEnSCs
were positive for MSC markers, including CD73, CD90
and CD105, as well as for the marker of endometrial
stem cell, CD146. Although they expressed high levels
of these markers, they did not express CD31 and CD34,
which are endothelial and hematopoietic progenitor
cell markers, respectively (Fig .1A, B). HEnSCs were
spindle-shaped and were relatively elongated (Fig .1C).
These cells were cultured and reached 80-90%
confluency before passage.
Fig.1
Flow cytometry and morphological feature of extracted hEnSCs after the 3rd passage.
A, B. HEnSCs are positive for MSC markers and are negative for
hematopoietic and endothelial markers. Data show the mean of positive cells (%) ± SEM.
C. HEnSCs are spindle-shaped and relatively elongated cells (scale bar:
50 µm). hEnSCs; Human endometrial stromal/ stem cells and MSC; Mesenchymal stem
cell.
Flow cytometry and morphological feature of extracted hEnSCs after the 3rd passage.
A, B. HEnSCs are positive for MSC markers and are negative for
hematopoietic and endothelial markers. Data show the mean of positive cells (%) ± SEM.
C. HEnSCs are spindle-shaped and relatively elongated cells (scale bar:
50 µm). hEnSCs; Human endometrial stromal/ stem cells and MSC; Mesenchymal stem
cell.
Changes of body weight
In the present study, all rats were weighed daily
at the appointed time. Body weights were reduced
until day 5 in all groups except for the intact group.
Body weight for intact group was 150.00 ± 9.55 g
and 172.90 ± 10.30 g on days 1 and 5, respectively.
Cisplatin administration induced weight loss in model
and PBS groups on day 5 as compared to day 1 (172.50
± 8.99 g, and 186.8 0 ± 8.14 g, vs. 164.50 ± 5.57 g, and
172.00 ± 6.70 g, respectively). Interestingly, a lower
body weight loss in cell-transplanted rats (177.50
± 5.18 g on day 5, 182.00 ± 5.174 g on day 1) as
compared to model and PBS groups, may indicate the
therapeutic effects of hEnSCs on the disturbance of
tubular concentration function (Fig .2A).
Fig.2
Body weight and serum biochemical changes after hEnSCs injections. All animals except for the
intact group received cisplatin (5 mg/ kg, IP) on day 1. After 3 hours, the cell group
received 1×106 hEnSCs in 200 µl PBS. A. Mean body weights of
the treated animals. B. The collected serum samples are from days 3 and 5
after cisplatin. Following hEnSCs injections the levels of BUN, SCr, ion Na, and K
were analyzed as shown here. Each column presents mean ± SEM. a-d; Show significant
differences between groups (P˂0.05), hEnSCs; Human endometrial stromal/stem cells, IP;
Intraperitoneal, PBS; Phosphate-buffered saline, BUN; Blood urea nitrogen, SCr; Serum
creatinine, Na; Sodium, and K; Potassium.
Biochemical analysis of renal function
Successful cisplatin-induced AKI was determined by
measuring biochemical markers in blood samples obtained
on days 3 and 5. The observed increase in biochemical
markers indicated the development of AKI.The BUN levels in all groups were almost similar on the 3rd day without a
statistically significant difference. On day 5, the BUN levels in model and PBS groups
were higher (116.60 ± 2.12 and 112.00 ± 1.35 mg/dl, respectively) as compared to those of
the hEnSC-transplanted and intact rats (61.53 ± 3.07 and 24.04 ± 0.89 mg/dl, respectively)
on day 5. The highest level of BUN was observed in the model group, but cell injection
resulted in a significant decrease in BUN levels (Fig .2B).The changes of SCr quantities were similar to those
of BUN levels. SCr increased significantly in model,
PBS, and hEnSC-transplanted groups as compared with
the healthy intact animals (0.65 ± 0.02 mg/dl) on day 5.
Also, a significant decrease (P<0.05) was observed in the
SCr level in the group receiving hEnSCs compared to the
model and PBS groups (0.82 ± 0.03 vs. 1.42 ± 0.06, 1.09
± 0.05 mg/dl respectively) on day 5 (Fig .2B).Serum Na and K levels on day 3 were similar among the
groups (about 150 milliequivalent (meq)/l and 4.5 meq/l,
respectively). On day 5, there were significant decreases
(P<0.05) in the mean values of Na levels in the model,
PBS and the cell groups (131.60 ± 1.61, 134.30 ± 2.37 and
143.00 ± 3.13 meq/l, respectively) as compared to that of
the intact group (153.80 ± 2.92 meq/l), but the difference
between PBS and the cell groups was not significant. Also,
cell treatment resulted in the mild increase of Na level
(Fig .2B). Moreover, on day 5, we observed a significant
decrease (P<0.05) in the mean K levels in the model and
PBS (3.87 ± 0.13 and 4.20 ± 0.19 meq/l, respectively) as
compared to those of the intact and the cell groups (5.41
± 0.23 and 5.00 ± 0.22 meq/l, respectively). In addition,
the quantities of K in rats receiving hEnSCs were not
significantly different compared with those of the intact
group on day 5 (Fig .2B).Body weight and serum biochemical changes after hEnSCs injections. All animals except for the
intact group received cisplatin (5 mg/ kg, IP) on day 1. After 3 hours, the cell group
received 1×106 hEnSCs in 200 µl PBS. A. Mean body weights of
the treated animals. B. The collected serum samples are from days 3 and 5
after cisplatin. Following hEnSCs injections the levels of BUN, SCr, ion Na, and K
were analyzed as shown here. Each column presents mean ± SEM. a-d; Show significant
differences between groups (P˂0.05), hEnSCs; Human endometrial stromal/stem cells, IP;
Intraperitoneal, PBS; Phosphate-buffered saline, BUN; Blood urea nitrogen, SCr; Serum
creatinine, Na; Sodium, and K; Potassium.
Pathologic changes
Examination of renal sections was performed in the
cortex and medulla regions on day 5 (Fig .3, original
magnification:×40). Light microscopic analyses
showed significant changes in the renal tissue on day
5 after cisplatin injection. Histological examination of
the kidney tissues obtained from both model and PBS
groups showed proximal and distal tubular injury with
cell debris in the lumen, lumen dilation, regenerative
changes in tubular cells, nuclear fragmentation, and
apoptosis and necrosis of the epithelial cells (Fig .3C-F).
On day 5 following hEnSC injection, a significant
improvement was observed in renal glomeruli and
tubules, thus the pathologic scores for tubular damage
were 118.8 ± 2.15 for the cell group versus 149.1 ±
7.02 and 141.5 ± 4.68 for the model and PBS groups,
respectively. Similar to the beneficial effects on the
serum biomarkers associated with renal function,
hEnSCs had a significant effect on renal pathology, as
they improved the renal pathologic scores (Fig .3).
Fig.3
Pathologic analyses of kidneys after hEnSCs injection on day 5. A-H. HEnSCs
injection led to significant reduction of pathologic injuries in renal tissue
(original magnification: ×40, scale bar: 50 µm). I. Photomicrograph shows
tubular injuries: cell debris in the lumen (circle), lumen dilation (star),
regenerative change in tubular cells or flattening of the epithelium lining the
tubules (white triangle), nuclear fragmentation (white arrow), apoptosis (black arrow)
and necrosis (black triangle) (original magnification: ×10, scale bar: 100 µm).
J. Histogram shows pathologic scores in different groups. a, b; Show
significant differences between groups (P˂0.05), hEnSCs; Human endometrial
stromal/stem cells, and PBS; Phosphate-buffered saline.
Evaluation of apoptosis in tubular epithelial cells and
glomeruli after cell therapy
Apoptosis in paraffin embedded tissues was detected
using TUNEL kit and data were analyzed via ImageJ
Software. On day 5, the percentage of TUNEL-positive apoptotic cells in tubules and glomeruli
increased significantly in both model and PBS groups
in comparison to the intact group (Fig .4A-F) (33.67
± 1.79, 31.53 ± 1.05 vs. 6.37 ± 1.05 in glomeruli
and 42.33 ± 1.72, 39.23 ± 1.61 vs. 4.67 ± 1.17 in
tubules). HEnSC-transplantation resulted in a marked
reduction of apoptotic cells in the renal tissue (Fig.4G,
H), suggesting an inhibitory effect of the hEnSCs
on cisplatin-induced apoptosis. The results of the
percentage of apoptotic cells in different groups are
shown in histograms Figure 4 I and J.
Fig.4
Results of TUNEL test after hEnSCs injection on day 5. A, B. Intact group, C,
D. Model animals receiving the cisplatin, E, F. PBS group
receiving PBS 3 hours after cisplatin injection, G, H. Cell group
receiving hEnSCs 3 hours after cisplatin injection. TUNEL (+) cells were observed in
tubules and glomeruli (original magnification: ×40, scale bar: 50 µm). I, J.
Histograms showed the percentage of TUNEL (+) cells. Each column presents mean
± SEM. a-c; Show significant differences between groups (P˂0.05), hEnSCs; Human
endometrial stromal/stem cells, and PBS; Phosphate-buffered saline.
Pathologic analyses of kidneys after hEnSCs injection on day 5. A-H. HEnSCs
injection led to significant reduction of pathologic injuries in renal tissue
(original magnification: ×40, scale bar: 50 µm). I. Photomicrograph shows
tubular injuries: cell debris in the lumen (circle), lumen dilation (star),
regenerative change in tubular cells or flattening of the epithelium lining the
tubules (white triangle), nuclear fragmentation (white arrow), apoptosis (black arrow)
and necrosis (black triangle) (original magnification: ×10, scale bar: 100 µm).
J. Histogram shows pathologic scores in different groups. a, b; Show
significant differences between groups (P˂0.05), hEnSCs; Human endometrial
stromal/stem cells, and PBS; Phosphate-buffered saline.Results of TUNEL test after hEnSCs injection on day 5. A, B. Intact group, C,
D. Model animals receiving the cisplatin, E, F. PBS group
receiving PBS 3 hours after cisplatin injection, G, H. Cell group
receiving hEnSCs 3 hours after cisplatin injection. TUNEL (+) cells were observed in
tubules and glomeruli (original magnification: ×40, scale bar: 50 µm). I, J.
Histograms showed the percentage of TUNEL (+) cells. Each column presents mean
± SEM. a-c; Show significant differences between groups (P˂0.05), hEnSCs; Human
endometrial stromal/stem cells, and PBS; Phosphate-buffered saline.
Effects of treatment with hEnSCs on renal mRNA expression of Bcl-2
and Tnf-α
Investigation of direct effect of hEnSC treatment on renal production of
Bcl-2 and Tnf-α was done using real-time PCR. The
expression levels of the mRNA for Bcl-2 (anti-apoptotic and
anti-inflammatory gene, intrinsic apoptotic pathway) and Tnf-α
(pro-apoptotic and pro-inflammatory cytokine gene, extrinsic apoptotic pathway) changed
after cisplatin and hEnSC injection in comparison to those of the intact group on day 5
(Fig .5). The mean Bcl-2 levels in the intact, model, PBS and cell groups
were 1.00 ± 0.28, 1.21 ± 0.12, 2.28 ± 0.22, and 15.74 ± 0.55, respectively. Model, PBS,
and the cell groups showed a meaningful increase (P<0.05), when compared to the
intact group, but the difference between the model and PBS groups was not significant. The
mean Tnf-α levels were 1.00 ± 0.61, 2.35 ± 0.71, 3.16 ± 1.39, and 1.38 ±
0.39 in the intact, model, PBS, and cell groups respectively. Cisplatin treatment caused
an increase in Tnf-α levels but hEnSCs transplantation lead to a decrease
in Tnf-α level in the cell group. The difference between the experimental
groups in terms of Tnf-α level was not significant.
Fig.5
Changes of gene expression in renal tissue after hEnSC transplantation on day 5. A.
Bcl-2 and B. Tnf-α expression
in intact, model, PBS and cell groups on day 5. Values are presented as mean ± SEM.
a-c; Show significant differences between groups (P˂0.05), hEnSC; Human endometrial
stromal/stem cells, and PBS; Phosphate-buffered saline.
Changes of gene expression in renal tissue after hEnSC transplantation on day 5. A.
Bcl-2 and B. Tnf-α expression
in intact, model, PBS and cell groups on day 5. Values are presented as mean ± SEM.
a-c; Show significant differences between groups (P˂0.05), hEnSC; Human endometrial
stromal/stem cells, and PBS; Phosphate-buffered saline.
Discussion
The majority of stem cell therapy studies have focused
on the use of bone marrow (BM)-MSCs. The useful effects
of these cells on the function of kidneys have clearly been
demonstrated in different AKI animal models by various
groups (24).To date, BM has been considered as the most ideal source
of stem cells for transplantation in regenerative medicine;
however, the disadvantages related to BM-MSC such as
the invasive method of extraction, age-related decline of
stemness and proliferative ability, the required anesthesia
for the donors, etc. restrict its applications. Human
endometrium also is considered as a source for stem
cells. In 2010, about 430,000 inpatient hysterectomies
were carried out in the US alone, demonstrating that
it is a significant source of endometrial stem cells.
Fortunately, hEnSCs exist in the superficial layers of this
tissue, so these cells are accessible without impairment of
endometrial function (25-27). In regenerative medicine,
BM-MSCs are more suitable for hard tissue engineering,
such as bone, whereas EnSCs are predicted to be more
suitable candidates for soft tissue engineering including
kidney (22).Obtaining endometrial specimen does not require anesthesia or sedatives and causes minimal
morbidity and pain. One of the clinical limitations of using MSCs is age-related
proliferative ability, whereas, the proliferative capacity of hEnSCs is not impaired in the
elderly (28). The effects of endometrial MSC-like or hEnSCs on renal function and apoptosis
reduction in AKI has not been studied thoroughly so far. To investigate such effects, we
injected hEnSCs after induction of AKI using a single dose of cisplatin. Subsequently, we
determined the levels of serum biomarkers, renal pathology, and apoptotic cell percentage in
renal tubules and glomeruli, as well as expression of Bcl-2 and
Tnf-α genes using real-time PCR.The results of biochemical and histological analyses
showed that 5 mg/kg body weight cisplatin successfully
induces AKI, while hEnSCs infusion leads to the recovery
of the AKI-associated signs. Following cell therapy, the
levels of serum biomarkers were closer to those of the
normal state and the pathologic score was reduced as
well. Several reports in cisplatin-induced AKI model
have shown that MSCs ameliorated the cisplatin effects
on renal tissue (7, 19, 29), nonetheless, beneficial effects
of MSCs on the recovery of cisplatin effects are still
controversial (30).It has previously been shown that cisplatin (5 mg/
kg) results in the increase of urea, creatinine, K level,
and significant changes in monkey renal tissue on day
4. These results demonstrated that intra-renal arterial
injection of autologous BM-MSCs ameliorated the levels
of urea and creatinine. BM-MSCs were not observed
to have a significant influence on pathologic scores of
kidneys, hyaline casts and fibrosis scores on days 4 and
28 after cisplatin injection (30). Similarly, we have shown
that BUN, SCr and Na underwent changes, but the K
level and the renal histologic scores improved after cell
transplantation.Sun et al. investigated therapeutic effects of human urine-derived stem cells (USCs) in
cisplatin-induced AKI in a rat model. They induced AKI using IP injection of 5 mg/kg
cisplatin and at 24 hours later injected 2×106 USCs/ 0.2 ml PBS via tail vein.
One of the criteria to evaluate in their study was histological changes. Tubular damage
score and the number of injured glomeruli decreased markedly after USC injection on day 4
(31). Our histopathologic results were similar to those of their study, because hEnSCs
improved histological scores in our rat model of cisplatin-induced AKI significantly.Ultimate damaging impact of cisplatin on the kidneys,
results from apoptosis and necrosis of renal cells (8).
Different stimuli including intracellular (reactive oxygen
species [ROS]-induced mitochondrial damage) and
extracellular (activation of death receptors) lead to cell
death (32). Cisplatin induces renal cell apoptosis via p53-mediated activations of caspase-2, 3, 8, while TNF-α
synthesis by phosphorylation of p38 MAPK may be the
basis of necrosis in tubular cells (33). Also, it has been
shown that outer mitochondrial membrane damage and
activation of apoptotic intrinsic pathway can be induced
by cisplatin. Bcl-2 family plays a significant role in
nephrotoxicity of cisplatin. Treatment by cisplatin results
in the reduction of Bcl-2 and BAX ratio, upregulation
of apoptotic genes, degradation or decrease of anti-apoptotic proteins, and increase of pro-apoptotic proteins
and inflammatory mediators, such as TNF-α (34-38).
Therefore, reduction of renal cell apoptosis is one of the
important mechanisms to be considered in the treatment
of AKI.Human umbilical cord-derived MSCs (HUC-MSCs) reduce cell apoptosis and help repair tubular
epithelial cells via upregulation of Bcl-2 and Bmp-7 (39).
MSCs attenuate cisplatin-induced nephrotoxicity by modulating renal inflammation. MSCs
significantly recover cisplatin-induced renal failure by apoptosis suppression in
p53-dependent and paracrine manner (29, 40). These results, as reported in previous studies,
support our findings. The present study demonstrated that the transplantation of hEnSCs
result in upregulation of Bcl-2 and downregulation of
Tnf-α, which is consistent with apoptosis decrease and improvement of
renal function. These findings suggest a relationship between the change in the intrinsic
and extrinsic pathways of apoptosis and the infusion of hEnSCs. Administration of hEnSCs
leads to a significant decrease of TUNEL-positive cells after the cisplatin injection. Our
findings suggest that one of the important renoprotective effects of hEnSCs may depend on
the inhibition or reduction of apoptosis.
Conclusion
Endometrium is a potential source of stromal/stem cells. These cells can be extracted
without ethical and technical problems. In the present study, transplantation of hEnSCs
changed the expression of Bcl-2 and Tnf-α in renal tissue
of animals with cisplatin-induced AKI. According to the findings of biochemical assays,
renal pathology evaluation, and gene expression analyses, hEnSCs may be involved in
apoptosis inhibition in kidneys and therefore in the improvement of their function in this
model of AKI. Further research on changes of other biomarkers, such as cystatin c and NGAL,
other pathological and functional aspects of the kidney, and also details of apoptotic
pathways are necessary to confidently consider the clinical application of hEnSCs for the
treatment of renal diseases.
Table 1
The primer sequences were used in the real-time polymerase chain reaction
Authors: David Sheikh-Hamad; William Cacini; Arthur R Buckley; Jorge Isaac; Luan D Truong; Chun Chui Tsao; Bellamkonda K Kishore Journal: Arch Toxicol Date: 2003-10-10 Impact factor: 5.153
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