1 Institut National de la Santé et de la Recherche Médicale (INSERM) U457, Hôpital Robert Debré, Paris, France
2 Centre National de la Recherche Scientifique FRE 2401, Collège de France, Paris, France
3 Department of Morphology, University of Geneva Medical School, Geneva, Switzerland
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ABSTRACT |
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Increasing evidence from epidemiological studies led to the concept of the early-life origins of adult diseases, suggesting that late-onset disorders such as type 2 diabetes, glucose intolerance, or hypertension may be programmed by nutritional inadequacy in utero (15). Excess glucocorticoids also retard fetal growth, and overexposure to these hormones during intra-uterine life has been shown to play a role in fetal programming in both humans (6) and rodents (7). The link between glucocorticoid overexposure in utero and the occurrence of metabolic diseases in adulthood has been well documented in rats. Maternal treatment with dexamethasone (DEX), a glucocorticoid agonist, induces in the offspring growth retardation at birth as well as hyperglycemia and increased systolic blood pressure at adult age (810). Similarly, inhibition of the placental 11ß-hydroxysteroid dehydrogenase type 2, the enzyme that protects the fetus from maternal glucocorticoids, induces intrauterine growth retardation as well as glucose intolerance and hypertension in adults (11).
We have previously shown that maternal general food restriction during late pregnancy decreased the ß-cell mass of newborn rats (12). This reduction was irreversible and persisted in adults despite restoration of normal nutrition from weaning (13), ultimately leading to impaired glucose tolerance associated with aging (14) or pregnancy (15). These results sustain the notion that some of the late alterations observed in humans born with intrauterine growth retardation may result from altered ß-cell development in utero, as initially suggested by Hales and Barker (2). Additionally, we have recently demonstrated that maternal general food restriction in the rat induced a rise in both maternal and fetal corticosterone levels, which in turn was responsible for the decreased ß-cell mass and islet numbers observed in the undernourished fetus (16). These data suggested that glucocorticoids might play a role in pancreas development.
Studies of pancreatic gene expression as well as genetically modified mice have identified a large number of transcription factors that control the development of the endocrine pancreas. Several homeodomain, paired-box, and helix-loop-helix transcription factors such as Nkx6.1, Pax4, Pax6, and Ngn3 are expressed at early stages of development, and their absence leads to alterations in endocrine cell differentiation. Besides, the bHLH transcription factor Ptf1-p48, which is required for exocrine cell differentiation, and the homeodomain protein pancreas duodenum homeobox (Pdx)-1, the earliest marker of pancreatic cells and whose absence results in pancreatic agenesis, are required for the early steps of pancreas development (1719).
The aims of the present study were 1) to investigate whether the association between developmental injury of the ß-cells and type 2 diabetes may be attributed to a direct effect of glucocorticoids on fetal pancreatic tissue and, if so, 2) to decipher the cellular and molecular mechanisms by which glucocorticoids could modulate pancreatic development or differentiation. We hypothesized that glucocorticoids act directly on the pancreas and that the transcription factors controlling its normal development and differentiation could be the targets of these hormones. We addressed this hypothesis by combining in vitro and in vivo approaches. First, we used a model of embryonic rat pancreas cultured in vitro in the presence of DEX to study the effect of glucocorticoids on pancreatic differentiation. We then analyzed the consequences of glucocorticoid receptor (GR) inactivation on pancreas development and organization, in mice lacking the GR either in pancreatic precursor cells (Pdx-Cre GRlox/lox mice, denominated GRPdx-Cre thereafter) or in cells transcribing the insulin gene, whether immature or fully differentiated ß-cells (RIP-Cre GRlox/lox mice, denominated GRRIP-Cre thereafter).
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RESEARCH DESIGN AND METHODS |
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Dissection and culture of rat pancreatic buds at embryonic day 15.5.
Pancreatic buds from Wistar rats at embryonic day 15.5 (E15.5) were dissected under the microscope. They were cultured for 3 days in RPMI 1640 (Invitrogen, Cergy Pontoise, France) with 10% FCS in the presence or absence of 100 nmol/l DEX in multiwell culture plates equipped with a 0.4-µm filter insert (Millipore, Bedford, MA). For morphometrical and proliferation rate measurements, the cultured buds were treated with bromodeoxyuridine (BrdU) (10 µmol/l) during the last hour of incubation.
The experiments on mice and rats were carried out according to the Principles of Laboratory Animal Care, National Institutes of Health, and the French laws, authorization number 7612, delivered to B.B. by the French Agricultural Ministry.
RNA extraction and reverse transcription.
RNA extraction was performed on batches of eight rat embryonic pancreata cultured as described above using Trizol Reagent (Invitrogen), according to the manufacturers procedure. After spectrophotometry quantification, 2 µg total RNA was used for reverse transcription in a 20-µl final volume using Superscript II Rnase H reverse transcriptase (Invitrogen). For each experiment, a negative control without reverse transcriptase was performed. cDNA was diluted 10 times in sterile water, and PCR was performed on 1.5 µl of this dilution.
Semiquantitative radioactive duplex PCR.
PCR was performed in 25 µl final volume containing 1.5 µl cDNA (15 ng RNA equivalent), 1.5 mmol/l MgCl2, 80 µmol/l cold dNTP, 1.3 µCi [-32P]dCTP, 1x GeneAmp PCR Buffer II, and 1.25 U AmpliTaq Gold "hot start" polymerase (Applied Biosystems, Foster City, CA). The sequences of the primers were as follows: Ngn3 sense, 5'-TGGCGCCTCATCCCTTGGATG; antisense, 5'-CAGTCACCCACTTCTGCTTCG; Hes1 sense, 5'-TCAACACGACACCGGACAAACC; antisense, 5'-GGTACTTCCCCAACACGCTCG; Ptf1-p48 sense, 5'-ATTAACTTCCTCAGCGAGCTGGT; and antisense, 5'-GTTGAGTTTTCTGGGGTCCTCTG. Primer sequences for Pdx-1, Foxa2, Nkx6.1, Hnf1
, Pax6, cyclophilin,
-tubulin, TBP, and RRPPO were previously described (23). PCR was performed in triplicate by amplifying each transcription factor with an internal control gene. Duplex PCR conditions were set up for each couple of genes and considered satisfactory when similar, and linear amplifications were obtained in simplex and duplex for both genes. PCR products were separated on a 6% acrylamide gel in Tris-borate EDTA buffer. The gel was dried, and the [
-32P]dCTP incorporated in each PCR product was measured on storage phosphor screens by the Packard Cyclone system and quantified by ImageQuant software. The radioactive background was quantified and subtracted from each measurement. The amount of each transcription factor product was normalized to its specific internal control gene, and this average ratio was then expressed as a percent of the mean ratio obtained in the control group tested in the same PCR.
Fixation and tissue processing for immunohistochemistry.
Rat pancreatic buds or adult mice pancreata were fixed in 3.7% formalin solution, dehydrated, and embedded in paraffin. Tissues were entirely cut into 5-µm thick sections, which were collected on poly-L-lysincoated slides. The slides were left at 37°C overnight and stored at 4°C until processed for immunohistochemistry.
Immunohistochemistry.
Tissue slides were submitted to a 10-min microwave treatment in a citrate buffer, permeabilized for 20 min with 0.1% Triton X-100 in Tris-buffered saline, and incubated 30 min with a blocking buffer (0.1% Tween20/3% BSA in Tris-buffered saline) before a 4°C overnight incubation with primary antibodies. Secondary antibodies (1:200) were incubated 14 h at room temperature. Double immunohistochemistry was performed using fluorescent dyecoupled secondary antibodies visualized under a Leica DMB microscope or, alternatively, using enzyme-linked secondary antibodies revealed by diaminobenzidine (Vector Laboratories, Compiegne, France) or Fast Red (Dako, Carpinteria, CA) substrates. Antibodies used are described below.
Primary antibodies were rabbit antiPdx-1 (a gift from Dr O.D. Madsen), mouse anti-insulin (Sigma, St. Louis, MO), mouse anti-BrdU (Amersham Pharmacia Biotech Europe, Saclay, France), rabbit anti-glucagon (Diasorin, Stillwater, MN), rabbit anti-amylase (Sigma), guinea pig anti-insulin (Dako), and rabbit anti-GR (Santa Cruz Biotechnology, Santa Cruz, CA). Secondary antibodies were fluorescein isothiocyanate antiguinea pig, fluorescein isothiocyanate anti-rabbit, Texas Red anti-mouse, Texas Red anti-rabbit, peroxidase antiguinea pig, biotin conjugated anti-rabbit (Jackson ImmunoResearch Laboratories, West Grove, PA), peroxidase-conjugated anti-rabbit (Promega, Madison, WI), alkaline phosphatase-conjugated streptavidin (BioGenex, San Ramon, CA), and peroxidase-conjugated streptavidin (Amersham Pharmacia Biotech Europe).
Cell numbers, area, and morphometrical measurements.
On E15.5 rat pancreatic buds treated or not treated with DEX, cells coexpressing Pdx-1 and insulin, and cells expressing only Pdx-1 were counted on every other section throughout the bud; amylase-positive area was morphometrically measured on the other sections. A total of four control and five DEX-treated buds were analyzed. Acinar cell proliferation was studied on 3,0006,000 amylase-positive cells per bud.
Amylase area on E15.5 rat pancreatic buds was determined by computer-assisted measurements using a DMRB microscope (Leica, Deerfield, IL) equipped with a color video camera coupled with a Q500IW computer (screen magnification, x24), as previously described (13). Pancreatic tissue area and insulin-positive or glucagon-positive cell area on adult transgenic mice were similarly measured. Briefly, the number of islets (defined as insulin-positive aggregates at least 25 µm in diameter) was scored and used to calculate the islet numerical density (number of islets per square centimeter of tissue). Islets ranging from 25 to 100 µm in diameter were defined as small, those ranging from 101 to 150 µm as medium, and those >150 µm as large. The percent ß-cell fraction was measured as the ratio of the insulin-positive cell area to the total tissue area on the entire section. Mean ß-cell fraction per pancreas was calculated as the ratio of the sum of insulin-positive area to the sum of pancreatic tissue area. The ß-cell mass was obtained by multiplying the ß-cell fraction by the weight of the pancreas. -Cell fraction and mass were similarly measured. Morphometrical analysis was performed on eight sections throughout the pancreas from four GRRIP-Cre mice or six GRlox/lox and six GRPdx-Cre mice.
Statistical analysis.
All results are expressed as means ± SE. The statistical significance of variations was evaluated with Statview 4.5 software. Transcription factor mRNA levels were expressed as the percent of their respective control in each experiment and analyzed by a Wilcoxons nonparametric test. Cell number, amylase cell area, cell proliferation, ß-cell and -cell fraction and mass, islet number, or repartition per size were tested by a Mann-Whitney nonparametric test. P values <0.05 were considered significant.
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RESULTS |
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Disruption of GR in pancreatic precursor cells increases ß-cell mass.
Mice carrying the GRlox allele (21) were crossed with mice expressing the Cre recombinase either in pancreatic precursor cells (Pdx1-Cre) or specifically in cells expressing the insulin gene (rat insulin promoter, RIP-Cre). The efficiency and specificity of GR gene recombination (i.e., inactivation) were assessed by immunohistochemistry with anti-GR antibodies on pancreatic sections (Fig. 4). In GRPdx-Cre mice, GR staining was almost totally absent in all pancreatic cell types, although a faint labeling was sometimes detected in islets (Figs. 4B and E). In GRRIP-Cre mice, the GR was specifically deleted in all differentiated ß-cells but remained well expressed in all other pancreatic cell types, as expected (Figs. 4C and F). Female mice were analyzed at adult age (34 months) and compared with age-matched control females (Table 1). GR deletion in ß-cells did not alter body or pancreatic weight, but a tendency to decreased fasted glycemia was observed. GR deletion in Pdx-1expressing cells did not alter the glycemia or the body weight but slightly increased pancreatic weight (Table 1).
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DISCUSSION |
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In the present work, we show that in vitro treatment of the embryonic rat pancreas with DEX did not affect the number of precursor cells but decreased the number of differentiated ß-cells and increased the differentiated acinar cell area. These results suggest that glucocorticoids decreased the differentiation of the embryonic pancreas into ß-cells while favoring its differentiation into acinar cells. This conclusion was further sustained by the finding of decreased proliferation of amylase-expressing cells upon DEX treatment, a result suggesting that glucocorticoids could also control the proliferation of already differentiated acinar cells and thereby prevent their overgrowth. Taken together, our in vitro data suggest that the differentiation process from precursor to differentiated endocrine or exocrine cell is altered, suggesting that the precursor cells but not the differentiated ß-cells are potential targets for glucocorticoids. Whether this in vitro situation also applies in vivo remains to be fully investigated. In line with this idea, rats undernourished during their perinatal life and thereby exposed to increased corticosterone levels in utero show increased pancreatic weight at adult age (14,15).
The finding that ß-cell differentiation is impaired in glucocorticoid excess situations is reinforced in the mirror situation found in conditional mutant mice where the GR signaling is absent, such that the deletion of the GR in Pdx-1expressing precursor cells (GRPdx-Cre) led to a twofold increase of ß-cell mass, with increased islet numbers. This increased ß-cell mass in GRPdx-Cre animals was already observed in neonates, although to a lesser extent than in adults. Surprisingly, the decreased exocrine cell differentiation, which would have been expected from the in vitro data, was not observed in the GRPdx-Cre mutants, since their pancreatic weight was on the contrary slightly increased. Other factors, coming either from maternal environment or adjacent tissue interactions might modulate this effect in vivo. Interestingly, while the deletion of the GR in pancreatic precursor cells led to increased ß-cell mass, -cell mass remained unaffected, indicating that glucocorticoid action was restricted to the ß-cell lineage. On the other hand, the specific GR deletion in differentiated ß-cells in GRRIP-Cre mice had no measurable consequences on ß-cell or
-cell mass. Taken together, these findings support the idea that glucocorticoids act on undifferentiated endocrine pancreatic cells having expressed the proendocrine marker Ngn3, but before insulin gene expression onset.
During the last decade, cell lineage studies in the pancreas have shown the requirement of a group of transcription factors for normal pancreatic development (19,24,25) even though their chronology of action is not fully understood yet. Pdx-1 is acknowledged as the earliest, because Pdx-1expressing cells give rise to all types of adult pancreatic cells (26,27) before being restricted to mature ß-cells also expressing Nkx6.1, Pax6, and other markers. Ngn3 is the common endocrine precursor cell marker (27,28), whereas Ptf1-p48, despite its early expression in pancreatic precursor cells (29), is an absolute prerequisite to drive exocrine cell differentiation (30). Moreover, Hes1 can also be considered a proexocrine transcription factor because it inhibits Ngn3 in the delta/notch pathway (25,31,32).
To further characterize the mechanisms by which glucocorticoids act on pancreas development, and hypothesizing that the hormonal steroid imbalance affects the developmental programming by modifying the level of the genes modulating pancreas development, we studied the expression of these transcription factors after in vitro treatment with DEX. Interestingly, the transcription factors implicated in ß-cell differentiation, such as Pdx-1, Pax6, and Nkx6.1, were downregulated, whereas the exocrine-specific transcription factors Ptf1-p48 and Hes1 were upregulated upon glucocorticoid treatment. These results suggest that glucocorticoids impair ß-cell development by favoring exocrine differentiation and that transcription factors could be their molecular targets.
The modulation of exocrine/endocrine differentiation balance had already been suggested in older in vitro studies of rat pancreatic explants treated with corticosterone, showing a decreased insulin secretion and islet mass while exocrine enzyme contents and acinar mass were enhanced (33,34). Additionally, the AR42J cell line, which shares some characteristics of multipotency with precursor cells, has been shown to differentiate into acinar cells when exposed to DEX (35). The decreased Pdx-1 mRNA levels we observed are also in good agreement with similar findings obtained after treatment of mouse pancreatic buds with DEX (36). However, the latter work argues in favor of a transdifferentiation of ß-cells into hepatocytes without any changes in exocrine tissue. The processes involved in the two studies appear quite different. In the experiments of Shen et al. (36), the treatment begins earlier, when more undifferentiated cells are likely to maintain a multipotency, rendering them more susceptible to de-differentiate into another tissue cell fate, whereas cells at a later stage, such as those used in our model, are more likely committed to a pancreatic cell fate.
The mechanisms by which glucocorticoids modulate the levels of the transcription factors remain to be determined. In HIT-T15 cells, it has been shown that glucocorticoids decreased the expression of Pdx-1 by inhibiting Hnf3ß (37). In our cultured pancreatic buds, as well as in adult rat islets (E.G., unpublished data), DEX treatment decreased Pdx-1 without inducing any changes in Hnf3ß mRNA levels, suggesting that the mechanisms regulating Pdx-1 gene transcription could be slightly different between mature islets and ß-cell lines. Alternatively, the transcription factor or transactivator environment could differ between precursor cells and mature ß-cells, thereby allowing a different transcriptional control of the Pdx-1 gene. Surprisingly, the mRNA levels of the proendocrine marker Ngn3 were unaffected by in vitro DEX treatment, despite increased Hes1 mRNA levels. It is possible that the 1.6-fold increase of Hes-1 was insufficient to inhibit Ngn3; alternatively, other still unknown transcription factors controlling Ngn3 transcription could also operate, thereby interfering with the Hes-1 inhibitory effect. Further studies in the conditional GRPdx-Cre and GRRIP-Cre mutants would help us understand how glucocorticoids affect ß-cell lineage at the molecular level.
The present study shows that glucocorticoids are important modulators of lineage commitment in the pancreas, acting during the differentiation process rather than on mature ß-cells. The increased islet numbers and size observed in GRPdx-Cre mice also shows that glucocorticoids repress signals that normally control ß-cell numbers or islet size. Despite normal ß-cell mass in GRRIP-Cre mice, glucocorticoids could also play a role on differentiated ß-cells or in postnatal life. Many reports have shown the importance of glucocorticoids on ß-cell function: GLUT2 protein has been shown to be decreased (38), glucose-stimulated insulin release is also altered in adult islets treated with DEX (3841), and a negative glucocorticoid response element was identified on the insulin promoter (42).
Taken together, our data show that glucocorticoids have profound effects on ß-cell development and differentiation in vivo. Even though the molecular mechanisms by which glucocorticoids mediate their effects are only partly elucidated at this time, these results demonstrate that glucocorticoids play an important role on pancreatic ß-cell lineage during specific developmental windows, acting before hormone gene expression onset and possibly also modulating the balance between endocrine and exocrine cell differentiation. Glucocorticoid hormones should therefore be considered as major hormones involved in normal pancreatic development. These results, together with the previously demonstrated associations of altered ß-cell development with impaired glucose tolerance at adult age, strongly support the concept that impaired glucose homeostasis in adulthood can be programmed by glucocorticoid-induced alterations in pancreas differentiation.
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ACKNOWLEDGMENTS |
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The authors are grateful to Dr. J.-C. Jonas and Dr. L. Bankir for their help in the semiquantitative PCR experiments and wish to thank Dr. O.D. Madsen for providing us with the antiPdx-1 antibodies.
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FOOTNOTES |
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Address correspondence and reprint requests to Bernadette Breant, INSERM U457, Hôpital Robert Debré, Paris F 75019, France. E-mail: bernadette.breant{at}rdebre.inserm.fr
Received for publication March 15, 2004 and accepted in revised form June 11, 2004
BrdU, bromodeoxyuridine; DEX, dexamethasone; E15.5, embryonic day 15.5; GR, glucocorticoid receptor
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REFERENCES |
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