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The demand for islet cells for treatment of
diabetes and lack of pancreata and the
problem of immunosuppression with the
allogenic transplantation directed our thoughts
towards stem cell therapy. Stem cell therapy
can be defined as group of new techniques or
technologies that relay on replacing diseased
or disfunctioning cells with healthy functioning
one.
Stem cells could be obtained from human fetuses,
umbilical cords, or embryonic tissues derived from
fertilized eggs. However these sources of stem cells
raise ethical and legal questions, pose a risk of
transmitting infections, and/or may be ineffective
because of immune rejection.
Aim of The WorkAim of The Work
In the present study, we have described the
characterization and differentiation in vitro of a
subset of human peripheral blood monocytes that
behave as stem cell. The ability to obtain these stem
cells from an easily accessible source such as
peripheral blood should make them valuable
candidates for autologus transplantation.
I- Generation of Neoislet Cells .
Mononuclear layer was obtained from peripheral blood
of healthy donors by density gradient centrifugation
and further purified by MACS technology to obtain
monocytes [Miltenyi Biotic - Germany].
The purity of the monocytes was tested by flow
cytometry analysis of CD14 , also CD34 was done.
Monocytes are then cultured for 6 days in dedifferentiation culture media; RPMI 1640 based medium containing 10% fetal calf serum,L-glutamine, penicillin , streptomycin and specific growth factor: macrophage colony stimulating factor (M-CSF), human interleukin 3 (IL3).
These cells are now termed programmable cells of monocytic origin (PCMO) and flow cytometry analysis for CD14 and CD34 was performed again. PCMO were then cultured in islet cell conditioning medium [ICM] containing epidermal growth factor, hepatocyte growth factor, nicotinamide and glucose for 21 days to be differentiated into neoislet cells.
II- Analysis of Neoislet Cells.II- Analysis of Neoislet Cells.
After 7,14 and 21 days differentiated PCMO were
subjected to real time RT-PCR and
immunohistochemistry. Glucose challenge test was
done on day 21 and insulin and C-peptide were
assayed by radioimmunoassay .
I. Flow Cytometry Analysis:I. Flow Cytometry Analysis:
Monocytes were tested by flow cytometry before
culturing for CD14 and CD34. They showed that
CD14 (specific for monocytes) was (82% + 6%) and
CD34 ( marker of stem cell) was (0% + 3%) .
II. Neoislet Cell Markers by RT-PCR:II. Neoislet Cell Markers by RT-PCR:
We confirmed neoislet differentiation by real time RT-
PCR at day 7, 14 and 21 of culturing in ICM for
common islet cell markers; β - actin, Pdx-1, insulin
and glucagon.
At day 7 (as shown in fig 1), weak amplification signal
for β - actin and Pdx-1 was detected. No insulin or
glucagon expression was found.
After 14 days we got good amplification signals for
Pdx-1, insulin and glucagon gene.
While after 21 days (as show in fig2) maximum
expression of gene Pdx-1, β - actin, insulin and
glucagon was found. ( We found no amplification
signals for Pdx-1, insulin , glucagon in PCMO which
was used as control).
Pdx-1 gene expressed in our Total Reference RNA, HUMAN
Insulin gene expressed in our Total Reference RNA, HUMAN
Glucagon gene expressed in our Total Reference RNA, HUMAN
ß-actin gene expressed in our Total Reference RNA, HUMAN
After 21 Days in ICM Culture
III. Immunohistochemistry :III. Immunohistochemistry :
Neoislets cells were subjected to
immunohistochemistry against insulin and glucagon.
In day 7 positive staining for glucagon
(as shown in fig 3) and negative for insulin was found
while positive for both insulin and glucagon in day 21
(as shown in fig 4a & 4b). Immunohistochemistry
staining was found to be negative for both insulin and
glucagon in PCMO.
Positive For Both Insulin and Glucagon Positive For Both Insulin and Glucagon On Day 21 After Culture in ICM On Day 21 After Culture in ICM
InsulinInsulin GlucagonGlucagon
IV. Results of Insulin and C – IV. Results of Insulin and C –
Peptide:Peptide:
Supernatant collected from the glucose challenge
performed to the neoislet cells was assayed by RIA
for insulin and C-peptide. The results showed that
insulin was (3.2, 5.7 and 6.8 µIU/ ml) and C-peptide
results were (0.8, 1.4 and 1.5 ng/ml) for glucose
concentrations: 50, 300 and 400 mg/dl respectively.
(as shown in fig 5).
0
1
2
3
4
5
6
7
50 300 400
IV. Results of Insulin and C – IV. Results of Insulin and C – Peptide After Glucose ChallengePeptide After Glucose Challenge
InsulinInsulin
C-peptideC-peptide
In the present study, the in-vitro differentiated
monocytes derived neo-islet cells resembles primary
human counterpart in several aspects:
1- Genetic Markers of Neoislet Cells1- Genetic Markers of Neoislet Cells
by real time RT-PCR showed expression of Pdx-1
which is a regulatory gene important for β-cell function
detected early after 1 week of culture in ICM.
Real time RT-PCR analysis of our results revealed
endogenous de novo expression of insulin and
glucagon at high amplification signals at day 21 of ICM
culture.
2- Immunohistochemichal2- Immunohistochemichal assay in our
work provides positive glucagon granules at day 7 in
ICM while at day 21, it provides positive results for
both insulin and glucagon which mimics the normal
embryological development of the islet cells. As during
embryonic life, β-cells are recognized 2 weeks after
alpha cells development.
3- Metabolic Function3- Metabolic Function by performing glucose
challenge test , Neoislet cells appears to resemble
pancreatic islet cells in metabolic activity by secreting
insulin and C-peptide in a glucose dependent fashion.
Aim of The Work:Aim of The Work:Autologus implantation of Neoislet Cells generated
from stem cell of monocytic origin in canine.
Methods and Results:Methods and Results:Preparation of Dogs Preparation of Dogs Seven male mongrel dogs were chosen. 6 dogs
were prepared for implantation and 1 for control.
Each dog was subjected to single IV injection of
alloxan to induce diabetes.
Generation of Neoislet Cells :Generation of Neoislet Cells :30 ml of peripheral blood was taken from each dog
separately . The peripheral blood monocytes were
cultured for 28 days by the above technique to
generate neoislets cells.
Implantation :Implantation : Six dogs were injected by neoislet cells suspended in
1 ml ICM in the deltoid muscle and injected between
the muscle fibers. The seventh dog (control dog)
was injected by 1 ml ICM only. All dogs were off of
insulin at the day of implantation.
Evaluation of graft functionEvaluation of graft functionA- Fasting Blood Glucose ofA- Fasting Blood Glucose of (FBG) of 3
dogs were normalized. The FBG of 4th and 5th dogs
were ameliorated; the 4th didn’t need insulin (135 + 5
mg/dl) while the 5th dog need a small dose of insulin
(200 + 5 mg/dl). The 6th dog died one day after
implantation and the cause of death was unexplained.
FBG of the control dog remained high.
B- To Assess The Ability ofB- To Assess The Ability of the implanted
dogs for glucose load disposal, an oral glucose
tolerance test was performed for the first 4 dogs.
Oral Glucose Tolerance Test (OGTT)
0
50
100
150
200
250
0 30 60 90 120 150
Time
Glu
cose
Lev
el
Normal GTT
Impiared GTT
3 dogs showed normal pattern of oral glucose tolerance curve. The 4th dog showed a pattern of impaired glucose tolerance.
C- ImmunohistochemistryC- Immunohistochemistry
After 50 days, the grafts were removed from all
dogs for immunohistochemical study. In the 5
recipient dogs, the cells were viable and showed
the presence of positive insulin and glucagon
granules between the muscle fibers as shown in fig
(7a and 7b).
The graft of the control dog was negative for both
insulin and glucagon granules.
DISCUSSION DISCUSSION In our study, autologus implantation of neo-islet
cells into diabetic dogs was capable of
regulating or ameliorating blood glucose level
post implantation up to 50 days
Despite that the intramuscular implantation
might not be the ideal site for islet
implantation, it has been chosen for its high
neovascularization capability and its easy
accessability (*).
(*) Mahgoub M, Ammar A., Ashmawi H., Akl M., Hammam O. The deltoid muscle could be a suitable site for islet
transplantation 2005; poster presentation in the 10th IPITA congress, Geneva, Switzerland.
After removal of the graft from the deltoid
muscle, the dog recurred to hyperglycemic
state as pre implantation compared to the
control diabetic dog which remained
hyperglycemic throughout the study.
The most exciting perspective in this study is the
potential use of stem cell of monocytic origin for
treatment of diabetes mellitus.
In possible future clinical applications, islet cells may
first be generated in vitro and upon autologus
transplantation into patients may substitute for their
endogenous counterparts.