HOME HELP CONTACT US SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Asfari, M Articles by Audet, A Search for Related Content PubMed PubMed Citation Articles by Asfari, M Articles by Audet, A

Merck-Santé, Centre de Recherche, 4 Avenue du Président François Mitterand, 91385 Chilly-Mazarin, Cedex, Paris, France

(Requests for offprints should be addressed to M Kergoat; Email: micheline.kergoat{at}merck.fr)

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
One of the major requirements for a successful and life-lasting organ transplant is the access to safe, least toxic and permanent tolerance-inducing drugs. In this study we wished to evaluate the effects of tolerogenic doses of the immunosuppressive drugs mycophenolic acid (MPA) and tacrolimus (Tac) on clonal ß-cell lines, both in vivo and in vitro. Here we demonstrate that combined administration of low-dose MPA and Tac for 23 days induced permanent tolerance in an allogeneic ß-cell line transplant in Wistar rat liver through the portal vein. This short-term treatment of tolerogenic doses of the two drugs was deleterious to the survival of the transplanted cells but a small percentage of the cells could resist the effect and become fully active when the drugs were removed. The surviving cells, retrieved from growth in vivo, did not exhibit increased resistance in comparison to the original cells when tested in vitro at two glucose concentrations, 10 and 20 mM. The presence of a small percentage of resistant cells at the two glucose concentrations was also detected in the in vitro study after a continuous 8-day treatment demonstrating that the in vivo resistance was not related to micro-environmental protection but possibly to a phenotypic cell state that is yet to be determined.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Since the successful Edmonton trial (Shapiro et al. 2000) allo-transplantation of human islets the definitive/long-term treatment of insulin-dependent diabetic patients by islet transplantation has become a matter of reality. The unprecedented success of this trial has been partly due to the prevention of the rejection of transplanted islets by effective and relatively safe immunosuppressive drug treatment. In the transplantations that led to insulin independence, between two and four cadaveric preparations of islets were used. The great hopes of thousands of insulin-dependent diabetic patients, however, are confronted with the serious obstacle of the scarcity of available human islets. The post-Edmonton trial challenge is to access a permanent and easily available source of functional ß-cells on the one hand and to establish a safer and longer-acting immunosuppressive regimen, preferentially of the type that induces permanent tolerance, on the other.

Although the existing functional and stable ever-dividing ß-cell lines could be considered for eventual transplantation the big challenge is to engineer a safe and tight proliferation-controlling protocol for such cells.

We have established highly glucose- and insulin-secretagogue-sensitive clones of a rat insulin-producing cell line, INS-1. The selected clones respond to glucose at physiological concentrations and have a relatively high insulin content. Before further elaborate design and manipulation of the growth control of these cells was carried out we were interested to see if they could survive the deleterious effects of immunosuppressive drugs and to find out what cell mass/insulin content is able to reduce high blood glucose levels following allogeneic transplantation in streptozotocin (STZ) diabetic rats.

As immunosuppressive drugs we chose mycophenolic acid (MPA) and tacrolimus (Tac; FK506; Prograf), known for inducing long-term tolerance in combination with other immunosuppressants. Mycophenolate mofetil (CellCept), a prodrug of MPA, induces activated T-lymphocyte apoptosis by depleting the dGTP pool required for DNA synthesis (Allison & Eugui 2000) and has been shown to induce long-term tolerance alone (Hao et al 1990, 1992, Wennberg et al. 2001) or in combination with other immunosuppressive drugs including Tac (Jones et al. 1999). Tac prevents interleukin-2 production by antigen-activated T-cells through inhibition of T-cell-specific and non-specific transcription factors required for the activation of interleukin-2 gene expression (Siekierka et al. 1994). Tac also has been demonstrated to induce long-term tolerance in combination with other immunosuppressants (Fealy et al. 1994, Vu et al. 1997, Qi et al. 1999, 2000) and is an efficient tolerogen in single injection if accompanied with the pre-sensitization by transfusion of donor splenocytes (Misao et al. 1997). Both of these immunosuppressants have been reported to inhibit insulin secretion and DNA synthesis in pancreatic islets and ß-cell lines in vitro (Metz et al. 1992, Sandberg et al. 1993, Meredith et al. 1995, 1997, Redmon et al. 1996, Li et al. 1998, Sayo et al. 2000, Huo et al. 2002, Paty et al. 2002). Those studies, however, were mostly of short duration and studied each immunosuppressant alone. In this study we demonstrate the effects of tolerogenic doses of the two drugs on INS-1 clone survival both in vivo and in vitro. The in vivo doses of the two drugs in this study were taken from the previous studies in rodents and primates that induced long-term tolerance (Iwasaki et al. 1991, Sugioka et al. 1996, Mourad et al. 2001, van Gelder et al. 2001) and the in vitro doses matched the plasma concentrations of the same doses used in vivo according to pharmacokinetic studies (Arima et al. 2001, van Gelder et al. 2001).

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
MPA, STZ, Glybenclamide, glucagon-like peptide-1 (GLP-1), isobutylmethylxanthine (IBMX), forskolin and Percoll were from Sigma. Tac (Prograf; 5 mg capsules) was purchased from Fujisawa (Celle St Cloud, France), carboxymethylcellulose was from Merck VWR (Fontenay sous Bois, France) and Nateglinide was synthesized in our laboratory. Fetal calf serum (FCS), Hepes, pyruvate, RPMI 1640, glutamine, glucose-free medium and bicarbonate were purchased from Invitrogen.

Diabetic animals

Outbred Wistar male rats weighing 350–450 g (2–3 months old) were purchased from Janvier (Le Genêt-St-Isle, France). For induction of diabetes the animals were injected intraperitoneally with a STZ solution (freshly dissolved in citric acid and sodium citrate, at 100 mM and pH 7.5) at 55 mg/kg. After 48 h the glycemia was measured by glucometer (Glucotrend; Roche) in 10 µl blood samples collected from the tails of the animals. The rats were kept in groups of five per cage and had free access to water and food (A04; UAR, Augy, France).

Cell culture and preparation of cell aggregates for transplantation

INS-1 clones 327 and 368 (at passages 50–54) were cultured to full growth as explained by Asfari et al. (1992). 1 day before transplantation cells were trypsinized and cultured overnight in non-adhering 100 mm bacterial plates at 20 x 10⁶ cells in 15 ml medium. This way the cells were clustered into aggregates of 5–50 cells per aggregate. The culture medium for preparation of aggregated cells was similar to complete medium (CM) except that FCS was replaced with heat-inactivated rat serum. Rat serum was prepared from blood taken from the abdominal artery of anesthetized outbred normal Wistar rats. Immediately before transplantation cells were centrifuged at 800 r.p.m. and 4 °C for 5 min and the cell pellets were resuspended gently in 0.8 ml CM with 10% heat-inactivated rat serum and kept on ice until the time of transplantation.

Transplantation

Diabetic rats with glycemia of 450–550 mg/dl were anesthetized with isoflurane (Florene, Abbott France, Rungis, France) inhalation for 3 min at 5%, which was then reduced to 2 and 1.5% in O₂/CO₂ (95:5) during surgery, which lasted 15 min. The animals received 30 x 10⁶ cells in a total of 0.8 ml CM containing 10% rat serum (CM-R) instead of FCS by a 25-guage needle through the hepatic portal vein. After surgery the animals were injected with 1 ml 1% Xylocain/adrenaline (Astra-Zeneca) subcutaneously at the site of the sutures to reduce the eventual pain. Each transplanted rat also received a dose of 100 mg antibiotic i.m. (Clamoxyl; Smithkline Beecham).

All experiments conformed to the relevant guidelines of the French Ministry of Agriculture for scientific experimentation on animals, and our laboratory and personnel are authorized to conduct such investigation according to the Ministry’s Executive Order no. 00764. The investigation conformed to the Guide for the Care and Use of Laboratory Animals (National Institutes of Health 1996).

In vivo immunosuppressive drug treatment

Both Tac powder (from Prograf, 5 mg/capsule) and MPA were dissolved at 5 and 4 mg/10 ml, respectively, in 0.5% carboxymethylcellulose in water (v/v). The animals received a mixture of MPA (at 5 mg/kg of rat body weight) and Tac (at 4 mg/kg of rat body weight) in volumes according to each animal’s weight, by gavage on the same day before transplantation. The same dose and route of MPA and Tac administration continued for 23 days.

Control of blood glucose and insulin

Immediately before transplantation and at different time intervals after transplantation, the animals’ tail-blood glucose was measured by Glucotrend (Roche). For insulin measurement 0.3 ml blood was taken from the tail at different time periods after transplantation and measured by ELISA (INSRAT 00-C1; Eurobio, Les Ulis, France).

Retrieval of the transplanted cells

At the time when glycemia was reduced to below normal levels, the animals were opened up and the developed tumor was excised from the surrounding hepatic tissue and made into a single cell suspension for further study. The tumors were cut into small pieces in the culture medium and the suspended cells were washed and separated on a Percoll gradient of 35, 45, 55 and 65% in RPMI 1640 medium with 1% heat-inactivated fetal serum as explained by Asfari et al. (1992).

In vitro proliferation and viability analysis of MPA-/Tac-treated cells

Proliferation and survival were measured by two methods, as follows.

Colorimetric microtitration assay  A colorimetric assay using a tetrazolium-dye-based microtitration assay (WST-1; Roche) was employed. Cell aggregates, prepared as indicated above, were cultured at a cell density of about 2 x 10⁴ cells/500 µl CM in each well of 24-transwell plates (catalogue no. 7959601; Merck VWR) before addition of the test medium. The test medium containing 10 or 20 mM glucose and different concentrations of Tac and MPA were added on day 2 of culture, renewing the test medium daily for 4 days.

Trypan blue dye-exclusion assay  The number of live cells was identified by trypan blue dye-exclusion assay and the percentage of the dividing cells was assessed by bromo-deoxyuridine incorporation assay (kit RPN20; Amersham Biosciences). Cell aggregates were cultured on to the 24-transwell plates (catalogue no. 7959601; Merck VWR) at 10⁵ cells/well in a total volume of 800 µl CM containing Tac and MPA and the test medium renewed daily. At different time points the cells of two separate wells from each culture condition were incubated for 1 h in the presence of BrdU, then trypsinized and washed. One-third of the washed cells were used for the viability count by trypan blue-exclusion assay, and the rest were cytospinned for BrdU staining according to the manufacturer’s protocol.

In vitro immunosuppressive drug treatment

Both Tac and MPA powder were dissolved in DMSO at 1000 times the highest final concentration of the tests. The dilution was made in the test medium and the control medium contained 0.1% DMSO.

Measurement of insulin secretion and content

The secretory response of the INS-1 cells and the selected clones to glucose and other insulin secretagogues was tested in static incubation. Cells were cultured at 10⁵ cells/well on 24-well culture plates in 1 ml CM for 48 h with a medium change to 5 mM glucose on the evening before the experiment. The cells were then washed with glucose-free Krebs–Ringer bicarbonate Hepes buffer (KRBH; 135 mM NaCl, 3.6 mM KCl, 5 mM NaHCO₃, 0.5 mM NaH₂PO₄, 0.5 mM MgCl₂, 1.5 mM CaCl₂ and 10 mM Hepes, pH 7.4) with 0.1% BSA and preincubated in the same buffer for 30 min. The cells were then washed twice with the same buffer and incubated in 1 ml KRBH buffer containing glucose and other secretagogues at the indicated concentrations for 1 h. Insulin was measured by ELISA (INSRAT 00-C1) as indicated above.

For measurement of insulin content islets of four normal adult male Wistar rats, weighing about 350–450 g, were pooled into multiple groups of 30–40 islets and extracted in acid/ethanol (Gotoh et al. 1987). For the cell lines approximately 3 x 10⁶ trypsinized cells were extracted in 1 ml acid/ethanol and the insulin was measured by the same method indicated above.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Insulin content and secretion of INS-1 clones

The INS-1 clones were selected for their superior response to glucose and other physiological and pharmacological insulin secretagogues. As indicated in the Fig. 1A these cells responded with better sensitivity to high glucose concentrations and their insulin content was comparable to that of INS-1 cells. By ELISA the insulin content of INS-1 cells after 48 h of incubation in CM at 5 mM glucose was 1.574 ± 0.08 µg/10⁶ cells and that of clones 327 and 368 was 1.318 ± 0.104 and 0.829 ± 0.056 µg/10⁶ cells respectively. With the same method the insulin content of islets from normal Wistar adult male rats of 350–450 g was found to be approximately 4.3 µg/10⁶ cells (13.048 ± 0.174 ng/islet from eight separate pools of 30–40 islets from four animals).

View larger version (20K): [in this window] [in a new window]   Figure 1 Glucose-induced insulin secretion of INS-1 and the two selected clones, 327 and 368. Cells were cultured for the insulin-secretion test as indicated in the Materials and Methods section. (A) Insulin secretion at 2.8 and 10 mM glucose alone and in the presence of a mixture of forskolin and IBMX (FI*) at 1 and 100 µM, final concentrations, respectively. (B) Insulin secretion of clone 368 in response to GLP-1 (10–6 M), Glybenclamide (10–6 M) and Repaglinide (10–6 M) at 4.2 mM glucose. Results are expressed as the percentage of induction over 4.2 mM glucose alone.

Transplantation

The outbred Wistar STZ diabetic rats with a glycemia of 350–570 mg/dl had approximately 50 x 10⁶ cells/kg transplanted into the liver through portal vein. Control rats received the same volume of the medium, CM-R, alone. The oral MPA/Tac treatment started the same day and before transplantation. About 18 h after transplantation there was a reduction in blood glucose level that lasted for a short time (2–3 days). This was certainly due to the insulin release from the transplanted cells since no such reduction was detected in the control, sham-operated animals. Blood glucose rose rapidly afterwards to above pre-transplantation levels and remained high; approximately 593 ± 15 mg/dl during the whole period of drug treatment, which lasted 23 days (Fig. 2A). After discontinuation of MPA/Tac administration a gradual decrease in blood glucose level and a rise in blood insulin were detected only in the transplanted animals. The decrease in blood glucose continued to very low levels and the animals died due to hypoglycemic shock. Out of the 17 transplanted animals, nine with clone 327 and eight with clone 368, 16 followed the same pattern, albeit at different intervals, after the termination of drug administration. One animal died within 48 h of transplantation for unidentified reasons. The period of the concomitant rise in blood insulin and reduction in blood glucose varied between the rats and it was not dependent on the level of glycemia on the day of the transplantation (Fig. 2B) nor on the type of the cells they received. No changes in blood glucose or insulin were observed in the seven diabetic sham-operated control animals that remained highly glycemic (601 mg/dl) with an average blood insulin of 38.1 ± 11.0 pM. The majority of control animals died around day 60 post-transplantation; the last animal survived until day 117. It should be noted here that with the same method of quantification the level of blood glucose of normal male Wistar rats of about 350–450 g was 100–140 mg/dl and blood insulin was 200–300 pM.

View larger version (31K): [in this window] [in a new window]   Figure 2 Glycemia and insulinemia of the transplanted and control rats. The STZ diabetic animals were transplanted with 50 x 106 aggregated INS-1 clone 327 cells per kg of rat body weight, through the portal vein as described in Materials and Methods section. Blood glucose and insulin from the tail were measured at different intervals post-transplantation. (A) Blood glucose of the transplanted and sham-operated control rats. (B) Blood insulin of the transplanted and sham-operated control rats.

At the time when the glycemia was reduced to normal levels, three animals were examined to evaluate the growth of the transplanted cells and their eventual recovery. All the examined transplanted rats developed a tumor, confined to the small lobe of the liver, of about 1.7 ± 0.7 ml in volume. A total number of (149.3 ± 48.9) x 10⁶ cells was obtained from each dissected tumor and no detectable metastasis was observed in the transplanted animals.

The recovered cells grew under the in vivo conditions of high glucose concentration (601 mg/dl=33 mM) and the presence of MPA and Tac, known to inhibit insulin secretion and cell proliferation in islets and ß-cells. It was of interest, therefore, to see if the recovered cells that had grown under such unfavorable conditions had retained their sensitivity to MPA and Tac. So the recovered transplanted cells were tested for growth and survival under the high concentration of glucose and at the two relevant pharmacological doses of Tac and MPA; a minimum of 3.1 µM MPA and 3 nM Tac and a maximum of 46 µM MPA and 30 nM Tac. As indicated in Fig. 3, there were no differences in the sensitivity of the original clones and their respective derived tumors to the proliferation-inhibitory effects of the two drugs. Furthermore, both clones and their respective derived tumors were equally affected at high and low concentrations of the two immunosuppressants and at the two concentrations, 10 and 20 mM, of glucose.

View larger version (28K): [in this window] [in a new window]   Figure 3 In vitro effects of Tac and MPA on INS-1 clones 327 (A) and 368 (B) and their in vivo derived tumors after 4 days treatment. Both the original clones and the in vivo-derived tumors were cultured as described in the Materials and Methods section and the cells were treated with two different concentrations of Tac and MPA at 10 and 20 mM of glucose for 4 days. Proliferation/survival was measured by colorimetric assay with WST-1 cell-proliferation reagent kit (Roche) according to the manufacturer’s protocol. Culture conditions: A, 10 mM glucose; B, 20 mM glucose; C, 10 mM glucose with 3 nM Tac and 3.1 µM MPA; D, 20 mM glucose with 3 nM Tac and 3.1 µM MPA; E, 10 mM glucose with 30 nM Tac and 46 µM MPA; F, 20 mM glucose with 30 nM Tac and 46 µM MPA.

Previous studies have reported a certain degree of reversibility of the effects of Tac and MPA on ß-cells (Sandberg et al. 1993, Redmon et al. 1996). In those studies, however, the treatments were performed separately for each drug and the period of treatment was short; 72 h at most. We studied the survival of the clones under an 8-day in vitro treatment with both drugs at a mean concentrations of 15 and 21.85 nM for MPA and Tac respectively, used in our previous in vitro study, and in the presence of 10 and 20 mM glucose. Cells were cultured on to transwells and the culture medium was renewed daily. At day 8 the cells were transferred into drug-free culture medium, after which there was daily medium change up to 26 days. Under these conditions the number of live cells at both glucose concentrations was reduced dramatically during the treatment with the two drugs, as determined by trypan blue-exclusion test (Fig. 4A). At day 8, out of 2000 counted cells, only 1.3 and 2.1% live cells were detected at 10 and 20 mM glucose, respectively, and live cells were less than 0.5% on day 12. From day 22 the percentage of living cells showed a slight increase and at day 26 there was a net increase of the live cells at both glucose concentrations. In order to indicate that the live cells were indeed the result of newly dividing cells we identified, in parallel, the actively proliferating cells by BrdU-incorporation immunocytometric assay. At day 8 of treatment there were 18 ± 2.3% and 12 ± 4% BrdU-incorporating cells at 10 and 20 mM glucose, respectively, in the control cultures. No BrdU-incorporating cells, however, were detected in Tac- and MPA-treated cultures on day 8 at either glucose concentration. From day 22 – that is, 14 days after Tac and MPA removal – the scarce and isolated cell aggregates at both glucose concentrations were detected, with a majority of cells in the aggregates stained positively for BrdU (Fig. 4B). This was more prevalent at day 26, corresponding closely to the results of viability tests, indicating that a very low percentage of the cells could resist 8-day Tac and MPA treatment and regain cell proliferation when the drugs were removed.

View larger version (48K): [in this window] [in a new window]   Figure 4 Viability and cell division of Tac- and MPA-treated cells in vitro. Cells were cultured on to 24-well transwells as described in the Materials and Methods section in CM with 10 and 20 mM glucose and in the presence of Tac (7 nM=5.6 ng/ml) and MPA (46 µM = 15 µg/ml) for 8 days, with a change of the drug-containing medium every day. The medium was then changed to CM with 10 and 20 mM glucose on day 8 and the cells were kept for another 18 days with daily medium change. At different time intervals the cells of two transwells from the same culture conditions were tested (A) for viability by trypan blue dye-exclusion assay and (B) for visualization of the BrdU-incorporating (dividing) cells. (BI) Control and (BII) Tac- and MPA-treated cells at 10 mM glucose on culture day 22. The arrowhead in (BI) points to the immunostained BrdU-incorporating cell nuclei. (BIII) 20 mM glucose with Tac and MPA on culture day 26; (BIV) 1000x magnification of (BIII).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The short-term therapy with long-term tolerance to different organ transplants, including islets, in rodents and primates has been reported previously (Koulmanda et al. 1997, Levisetti et al. 1997, Thomas et al. 1999, Contreras et al. 2000, Buhler et al. 2002). Hao et al. (1990, 1992) reported on the induction of long-term tolerance with short-term therapy with classical immunosuppressive drugs in rats and mice. In those studies a very high dose of MPA, 80 mg/kg per day in mice and 40 mg/kg per day in rats, for a continuous 30-day administration, led to a more than 100-day islet allo- and xenograft acceptance in 70% of the animals with specific tolerance induction. In our study we used a much lower dose of MPA, 5 mg/kg per day, in combination therapy with 4 mg/kg per day of Tac for a period of 23 days. This short-term treatment resulted in long-term tolerance in almost 100% of the transplanted rats. It should be mentioned, however, that induction of tolerance at such a low dose of MPA with Tac might be possible only in this allogenic ß-cell transplantation where the genetic differences between the host and transplanted cells are quite limited. INS-1 cells are derived from an islet tumor of NEDH rat (Asfari et al. 1992), which is an inbred strain with the Wistar genetic background.

The lack of blood glucose reduction during drug administration and long time after arrest of drug application evidently was due to the deleterious effects of the two drugs on survival and function of transplanted cells, as was supported by the experiments performed in vitro. Nevertheless, the insulin levels of the transplanted animals during the 23 days of treatment were significantly higher than the controls. This could be due to either the very low levels of activity of the transplanted cells or to full activity of a few surviving cells that were resistant or were protected from the deleterious effects of the immunosuppressive drugs. To test this we compared the sensitivity of the recovered cells from the transplanted animals with those of the original cell lines, in vitro, and found that indeed they were equally sensitive to the drugs, even at high glucose concentrations. On the other hand when the cells were treated with the two drugs in vitro for 8 days very few cells were resistant or gained full proliferation activity when the drugs were removed. These results suggested that the resistance was neither a genetic modification as a result of selection pressure, nor due, or only due, to liver micro-environmental protection or high glucose concentration, but most probably due to some other inherent property of the cell aggregates. So, the very low levels of insulin in the transplanted animals were secreted from the few remaining resistant cells. This may suggest that MPA and Tac can affect only the cells that are on the periphery of the cell aggregates and can’t diffuse through the cell mass reaching, at least in effective concentrations, to the cells in the center of the aggregates. So, depending on how long the drugs are present and the size of the aggregate, the number of surviving cells, for a defined drug dose, may vary. This can be determined by histological studies and identification of the state of proliferation/apoptosis of the cells in the aggregates. Whether the normal ß-cells also exhibit such a property remains to be determined but if this hypothesis is true then the islets should be more resistant to the drugs because of their topographical structure.

A significant reduction of blood glucose in the transplanted rats was observed when blood insulin reached about five times the basal level in normal rats. This may reflect the development of insulin resistance in these STZ-induced diabetic rats due to STZ and prolonged hyperglycemia (Blondel & Portha 1989). It was also found that in these animals around 150 x 10⁶ INS-1 clone cells, having a total insulin content of about 130 µg, are required to establish a considerable reduction in blood glucose, as was determined from the tissue mass retrieved from the transplanted animals at the stage of blood glucose reduction.

In conclusion the present study demonstrates that a short-term administration of MPA and Tac could induce long-term/permanent tolerance to INS-1 cell clones in an allogenic transplantation and that the resistance seems to be a phenotypic property of the cells, possibly related to the topographical position of the cells in the cell aggregates.

	Acknowledgements

 
The authors declare that there is no conflict of interest that would prejudice the impartiality of this scientific work.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 
Allison AC & Eugui EM 2000 Mycophenolate mofetil and its mechanisms of action. Immunopharmacology 47 85–118.[CrossRef][ISI][Medline]

Arima H, Yunomae K, Miyake K, Irie T, Hirayama F & Uekama K 2001 Comparative studies of the enhancing effects of cyclodextrins on the solubility and oral bioavailability of tacrolimus in rats. Journal of Pharmaceutical Sciences 90 690–701.[Medline]

Asfari M, Janjic D, Meda P, Li G, Halban PA & Wollheim CB 1992 Establishment of 2-mercaptoethanol-dependent differentiated insulin-secreting cell lines. Endocrinology 130 167–178.[Abstract]

Blondel O & Portha B 1989 Early appearance of in vivo insulin resistance in adult streptozotocin-injected rats. Diabete et Metabolisme 15 382–387.

Buhler L, Deng S, O’Neil J, Kitamura H, Koulmanda M, Baldi A, Rahier J, Alwayn IP, Appel JZ, Awwad M et al. 2002 Adult porcine islet transplantation in baboons treated with conventional immunosuppression or a non-myeloablative regimen and CD154 blockade. Xenotransplantation 9 3–13.[CrossRef][ISI][Medline]

Contreras JL, Eckhoff DE, Cartner S, Bilbao G, Ricordi C, Neville Jr DM, Thomas FT & Thomas JM 2000 Long-term functional islet mass and metabolic function after xenoislet transplantation in primates. Transplantation 69 195–201.[CrossRef][ISI][Medline]

Fealy MJ, Umansky WS, Bickel KD, Nino JJ, Morris RE & Press BH 1994 Efficacy of rapamycin and FK 506 in prolonging rat hind limb allograft survival. Annals of Surgery 219 88–93.[Medline]

van Gelder T, Klupp J, Barten MJ, Christians U & Morris RE 2001 Comparison of the effects of tacrolimus and cyclosporine on the pharmacokinetics of mycophenolic acid. Therapeutic Drug Monitoring 23 119–128.[CrossRef][ISI][Medline]

Gotoh M, Maki T, Satomi S, Porter J, Bonner-Weir S, O’Hara CJ & Monaco AP 1987 Reproducible high yield of rat islets by stationary in vitro digestion following pancreatic ductal or portal venous collagenase injection. Transplantation 43 725–730.[ISI][Medline]

Hao L, Lafferty KJ, Allison AC & Eugui EM 1990 RS-61443 allows islet allografting and specific tolerance induction in adult mice. Transplantation Proceedings 22 876–879.[ISI][Medline]

Hao L, Wang Y, Chan SM & Lafferty KJ 1992 Effect of mycophenolate mofetil on islet allografting to chemically induced or spontaneously diabetic animals. Transplantation Proceedings 24 2843–2844.[ISI][Medline]

Huo J, Luo RH, Metz SA & Li G 2002 Activation of caspase-2 mediates the apoptosis induced by GTP-depletion in insulin-secreting (HIT-T15) cells. Endocrinology 143 1695–1704.[Abstract/Free Full Text]

Iwasaki K, Shiraga T, Nagase K, Hirano K, Nozaki K & Noda K 1991 Pharmacokinetic study of FK 506 in the rat. Transplantation Proceedings 23 2757–2759.[Medline]

Jones Jr JW, Ustuner ET, Zdichavsky M, Edelstein J, Ren X, Maldonado C, Ray M, Jevans AW, Breidenbach WC, Gruber SA & Barker JH 1999 Long-term survival of an extremity composite tissue allograft with FK506-mycophenolate mofetil therapy. Surgery 126 384–388.[ISI][Medline]

Koulmanda M, Kovarik J & Mandel TE 1997 Effect of mycophenolate mofetil with and without anti-CD4 (GK1.5) on fetal islet iso-, allo-, and xenografts in NOD/Lt female mice. Transplantation Proceedings 29 2161–2162.[Medline]

Levisetti MG, Padrid PA, Szot GL, Mittal N, Meehan SM, Wardrip CL, Gray GS, Bruce DS, Thistlethwaite Jr JR & Bluestone JA 1997 Immunosuppressive effects of human CTLA4Ig in a non-human primate model of allogeneic pancreatic islet transplantation. Journal of Immunology 159 5187–5191.[Abstract]

Li G, Segu VB, Rabaglia ME, Luo RH, Kowluru A & Metz SA 1998 Prolonged depletion of guanosine triphosphate induces death of insulin-secreting cells by apoptosis. Endocrinology 139 3752–3762.[Abstract/Free Full Text]

Meredith M, Rabaglia ME & Metz SA 1995 Evidence of a role for GTP in the potentiation of Ca(2+)-induced insulin secretion by glucose in intact rat islets. Journal of Clinical Investigation 96 811–821.

Meredith M, Li G & Metz SA 1997 Inhibition of calcium-induced insulin secretion from intact HIT-T15 or INS-1 beta cells by GTP depletion. Biochemical Pharmacology 53 1873–1882.[CrossRef][ISI][Medline]

Metz SA, Rabaglia ME & Pintar TJ 1992 Selective inhibitors of GTP synthesis impede exocytotic insulin release from intact rat islets. Journal of Biological Chemistry 267 12517–12527.[Abstract/Free Full Text]

Misao T, Udaka T, Aoe M, Date H, Andou A & Shimizu N 1997 Efficacy of combining donor-specific presensitization with a simultaneous single injection of tacrolimus on pulmonary allografts. Journal of Heart and Lung Transplantation 16 1099–1105.

Mourad M, Malaise J, Chaib ED, De Meyer M, Konig J, Schepers R, Squifflet JP & Wallemacq P 2001 Pharmacokinetic basis for the efficient and safe use of low-dose mycophenolate mofetil in combination with tacrolimus in kidney transplantation. Clinical Chemistry 47 1241–1248.[Abstract/Free Full Text]

National Institutes of Health 1996 Guide for the Care and Use of Laboratory Animals. NIH Publication no. 85–23. Bethesda, MD: National Institutes of Health.

Paty BW, Harmon JS, Marsh CL & Robertson RP 2002 Inhibitory effects of immunosuppressive drugs on insulin secretion from HIT-T15 cells and Wistar rat islets. Transplantation 73 353–357.[CrossRef][ISI][Medline]

Qi Z, Simanaitis M & Ekberg H 1999 Malononitrilamides and tacrolimus additively prevent acute rejection in rat cardiac allografts. Transplant Immunology 7 169–175.[Medline]

Qi S, Xu D, Peng J, Vu MD, Wu J, Bekersky I, Fitzsimmons WE, Peets J, Sehgal S, Daloze P & Chen H 2000 Effect of tacrolimus (FK506) and sirolimus (rapamycin) mono- and combination therapy in prolongation of renal allograft survival in the monkey. Transplantation 69 1275–1283.[ISI][Medline]

Redmon JB, Olson LK, Armstrong MB, Greene MJ & Robertson RP 1996 Effects of tacrolimus (FK506) on human insulin gene expression, insulin mRNA levels, and insulin secretion in HIT-T15 cells. Journal of Clinical Investigation 98 2786–2793.[ISI][Medline]

Sandberg JO, Andersson A & Sandler S 1993 Exposure of rat pancreatic islets to RS-61443 inhibits beta-cell function. Transplantation 56 1197–1201.[Medline]

Sayo Y, Hosokawa H, Imachi H, Murao K, Sato M, Wong NC, Ishida T & Takahara J 2000 Transforming growth factor beta induction of insulin gene expression is mediated by pancreatic and duodenal homeobox gene-1 in rat insulinoma cells. European Journal of Biochemistry 267 971–978.[ISI][Medline]

Shapiro AM, Lakey JR, Ryan EA, Kobutt GS, Toth E, Warnock GL, Kneteman NM & Rajotte RV 2000 Islet transplantation in seven patients with type 1 diabetes mellitus using a glucocorticoid-free immunosuppressive regimen. New England Journal of Medicine 343 230–238.[Abstract/Free Full Text]

Siekierka JJ 1994 Probing T-cell signal transduction pathways with the immunosuppressive drugs, FK-506 and rapamycin. Immunologic Research 13 110–116.[Medline]

Sugioka N, Koyama H, Ohta T, Kishimoto H, Yasumura T & Takada K 1996 Pharmacokinetics of mycophenolate mofetil, a new immunosuppressant, in rats. Journal of Pharmaceutical Sciences 85 335–338.[CrossRef][Medline]

Thomas FT, Ricordi C, Contreras JL, Hubbard WJ, Jiang XL, Eckhoff DE, Cartner S, Bilbao G, Neville Jr DM & Thomas JM 1999 Reversal of naturally occurring diabetes in primates by unmodified islet xenografts without chronic immunosuppression. Transplantation 67 846–854.[CrossRef][ISI][Medline]

Vu MD, Qi S, Xu D, Wu J, Fitzsimmons WE, Sehgal SN, Dumont L, Busque S, Daloze P & Chen H 1997 Tacrolimus (FK506) and sirolimus (rapamycin) in combination are not antagonistic but produce extended graft survival in cardiac transplantation in the rat. Transplantation 64 1853–1856.[Medline]

Wennberg L, Song Z, Bennet W, Zhang J, Nava S, Sundberg B, Bari S, Groth CG & Korsgren O 2001 Diabetic rats transplanted with adult porcine islets and immunosuppressed with cyclosporine A, mycophenolate mofetil, and leflunomide remain normoglycemic for up to 100 days. Transplantation 71 1024–1033.[ISI][Medline]

Received 15 December 2004
Accepted 28 April 2005

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Asfari, M Articles by Audet, A Search for Related Content PubMed PubMed Citation Articles by Asfari, M Articles by Audet, A