1 Laboratory of Physiopathology of Nutrition, Université Paris, Paris, France
2 Instituto de Bioquimica, Facultad de Farmacia, Ciudad Universitaria, Madrid, Spain
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ABSTRACT |
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INTRODUCTION |
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RESEARCH DESIGN AND METHODS |
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Determination of plasma glucose, insulin, and GH levels.
Plasma glucose was determined with a glucose analyzer (Beckman Instruments, Fullerton, CA). Immunoreactive insulin plasma was estimated as previously described (8). GH was determined in the plasma of fetuses with a rat GH 125I assay system (Biotrak; Amersham Life Science, Amersham, U.K.). The radioimmunoassay was carried out according to the kit protocol. The sensitivity of the assay was 1.6 ng/ml.
Iodination, purification, and determination of serum IGF-1 and -2.
Recombinant human IGF-1 and -2 were labeled by a modified chloramine T method (9,10). The specific activity achieved was 90175 µCi/µg for both peptides. Before IGF-1 and -2 determination, serum IGFBPs were removed by standard acid gel filtration. This method has proved to be the most reliable one for use with rat serum in developing stages (9,10).
The radioimmunoassay for IGF-1 and rat liver membrane receptor assay for IGF-2 were carried out as previously described (9,10). The coefficients of variation within and between assay were 8.0 and 12.4%, respectively. Recombinant human IGF-I and -II (Boehringer Mannheim, Leverkusen, Germany) were used for iodination.
Western immunoblotting and determination of serum IGFBP-1 and -2.
Western immunoblots for enhanced chemiluminescence were performed in polyvinylidene fluoride (PVDF) immobilon-P membranes (Millipore, Madrid). PVDF membranes were blocked with 5% (wt/vol) nonfat dry milk for 60 min in Tris-buffered saline (TBS; 0.01 mol/l Tris and NaCl 0.15 mol/l, pH 8) with 0.05% Tween-20. Membranes were then incubated with a 1:100 dilution (as suggested by the manufacturer) of affinity-purified goat polyclonal anti-rat IGFBP-1 or -rat IGFBP-2 (Santa Cruz Biotechnology, Madrid) in the same buffer (TBS-Tween plus 5% nonfat dry milk) at 4°C overnight, after which the membrane was washed three times for 10 min in TBS-Tween. After a 1-h incubation at room temperature with a 1:1,000 dilution of anti-goat IgG-horseradish peroxidase in TBS-Tween plus 5% nonfat dry milk, the membrane was washed three times with TBS-Tween and finally once with TBS alone. Antigen-antibody complexes were detected after an enhanced chemiluminescence (hyperfilm ECL; Amersham, Madrid).
Preparation of total RNA.
Total RNA was prepared by homogenization of fetal pancreases and livers in guanidinium thiocyanate as originally described (11). RNA concentration was determined by absorbance at 260 nm. Samples were electrophoresed through 1.1% agarose and 2.2 mol/l formaldehyde gels and then stained with ethidium bromide to render the 28S and 18S ribosomal RNA visible and thereby confirm the integrity of the RNA and normalize the quantity of RNA in the different lanes. A pT7 RNA 18S anti-sense (Ambion, Austin, TX) was used for lane loading control.
Riboprobes.
Rat IGF-1 and -2 and IGFBP-1 and -2 cDNAs were kindly provided by Drs. C.T. Roberts Jr. and D. LeRoith (National Institutes of Health, Bethesda, MD). Rat IGF-I cDNA ligated into a pGEM-3 plasmid (Promega Biotech, Madison, WI) was linearized with HindIII, and an anti-sense riboprobe was produced by T7 RNA polymerase. The size of the protected fragment represented in the figures (IGF-Ib) was 386 bp. Rat IGF-II cDNA ligated into a pGEM-3 plasmid was linearized with HindIII and incubated with T7 RNA polymerase to generate a riboprobe that recognized a fragment of 700 bp. Rat IGFBP-1 cDNA, ligated into a pGEM-3 plasmid, was linearized with HindIII and incubated with T7 RNA polymerase to generate an anti-sense riboprobe that recognizes two fragments of 300 and 700 bases. Rat IGFBP-2 cDNA, ligated into a pGEM-4Z (Promega Biotech, Madison, WI) plasmid, was linearized with HindIII and incubated with SP6 RNA polymerase to generate a 550 base anti-sense riboprobe devoid of pGEM-4Z complementary sequences. pT7 RNA 18S was incubated with T7 RNA polymerase to produce a 109 nucleotide runoff transcript, 80 nucleotides of which are complementary to human 18S ribosomal RNA. (32P)UTP was purchased from ICN (Nuclear Iberica, Madrid). The Riboprobe Gemini II Core System (Promega) was used for the generation of RNA probes.
Solution hybridization/RNase protection assay.
Solution hybridization/RNase protection assays were performed as previously described (10,12). Autoradiography was performed at -70°C against a Hyperfilm MP film between intensifying screens. Bands representing protected probe fragments were quantified using a Molecular Dynamics scanning densitometer and accompanying software. RNase A and T1 were purchased from Boehringer Mannheim.
Fetal rat islet preparation and islet culture with IGFs.
Fetal islets from GK and Wistar rats were prepared according to Hellerström et al. (13) as previously described (8). At the end of the 6-day culture period, 40 fetal islets in each group were collected under a stereomicroscope and further cultured for 2 days in RPMI 1640 medium (Bio Whittaker, Verviers, Belgium) supplemented with 2 mmol/l glutamine (Bio Whittaker), 1% heat-inactivated fetal bovine serum (Bio Whittaker), and 100 ng/ml IGF-1 (R&D Systems, Abingdon, U.K.) or 100 ng/ml IGF-2 (R&D Systems). The culture dishes were kept at 37°C in a humidified atmosphere of 5% CO2 in air. The complete culture medium was changed the next day.
ß-Cell replication.
To measure ß-cell replication in isolated fetal islets, 5'-bromo-2'-deoxyuridine (BrdU) (Amersham, Amersham, U.K.) was incorporated in newly synthesized DNA and therefore labeled replicating cells. In each group of fetal islets, 1 h before the end of islet cultures, BrdU was added at 100 µmol/l final concentration. Thereafter, islets were collected under stereomicroscope, fixed, and then processed for serial sections as previously described (8). Islets sections were doubled-stained for BrdU, using a cell proliferation kit (Amersham International, Amersham, U.K.), and insulin. Sections were incubated with a mouse monoclonal antibody anti-BrdU diluted in a nuclease solution (according to the kit protocol) for 1 h at room temperature and washed with Tris 0.05 mol/l, pH 7.6. Thereafter, they were incubated with an affinity-purified peroxidase anti-mouse IgG and stained with DAB using a peroxidase substrate kit 3,3'-diaminobenzidine-tetra-hydrochloride (DAB). Sections were then incubated with guinea pig anti-insulin antibody for 1 h as described above and then with alkaline phosphatase-conjugated goat anti-guinea pig IgG for 45 min (Dako, Trappes France). The activity of the antibody-alkaline phosphatase complex was revealed with an alkaline phosphatase substrate kit (Valbiotech, Paris, France). Sections were mounted in Eukitt (Labonord, Templemars, France). On these sections, ß-cells showed red cytosol, and BrdU-positive ß-cell appeared with brown nuclei. A mean of 250 ß-cells were counted per islet at a final magnification of 1000x. The proportion of BrdU-positive ß-cell nuclei to total ß-cell nuclei was calculated. The result represents the percentage ß-cell replicative rate in a 1-h interval (BrdU labeling index of ß-cells).
Statistical analysis.
All data are presented as means ± SE. Comparison between groups were evaluated using Students unpaired t test. P < 0.05 was considered significant.
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RESULTS |
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Pancreas IGF and IGFBP mRNA expression in Wistar and GK fetuses.
Densitometric measurements of protected probe fragments are expressed as percent of the corresponding Wistar fetuses (Fig. 3). Whereas pancreas IGF-1 mRNA expression in GK fetuses was similar to that in Wistar fetuses, IGF-2 mRNA expression was decreased (P < 0.001) by 55% in GK pancreas. IGFBP-1 and -2 mRNA expression were similar in the two groups of fetuses.
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DISCUSSION |
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Although it confirms that GK fetuses are hypoinsulinemic despite enhanced plasma glucose level due to maternal hyperglycemia, the present study shows for the first time that IGF-2 expression in the liver and pancreas and IGF-2 serum levels are decreased in GK fetuses.
IGFs are locally produced by pancreas, where they act in an autocrine or paracrine manner and are involved in the regulation of islet growth and differentiation (5). We have previously shown that the reduced ß-cell mass in GK fetuses is due to an early impaired rate of ß-cell neogenesis, because poor proliferation and/or survival of endocrine precursor cells leads to early defective development of the ß-cell mass (3). Thus, the reduced IGF-2 serum level together with the reduced expression of IGF-2 in pancreas of GK fetuses could play a crucial role in the anomaly of ß-cell mass in the GK fetuses. This is substantiated by the recent demonstration that an increased expression of IGF-2 under the control of the rat insulin promoter in ß-cells of transgenic mice led to ß-cell hyperplasia (14). In a rat model of increased islet number induced by high- carbohydrate feeding in the neonate, IGF-2 expression was found increased within the pancreatic ductal epithelium, and it may contribute to the associated higher rate of neogenesis (15). There is also clear evidence that IGF-2 inhibits cell apoptosis in many cell types. Hill et al. (16) have demonstrated that increased and persistent circulating IGF-2 in neonatal transgenic mice suppresses developmental apoptosis in the pancreatic islets. Conversely, Petrik and al. (17) have suggested that a reduced pancreatic expression of IGF-2 may contribute to the increased apoptosis seen in the fetus after low-protein diet. However, it is unlikely that the reduced pancreatic expression of IGF-2 observed in GK fetuses may contribute to an increased ß-cell death because ß-cell apoptosis rate was not increased in GK fetuses at late fetal age (3). Due to our observation that the pancreatic expression of IGF-2 is decreased by 55% in GK fetuses, the anomaly of the IGF-2 expression in pancreas of GK fetuses could be the reflection of the reduced ß-cell mass (by 60%) observed at this stage. However, in the present study, we observed that the IGF-1 pancreatic expression is similar in GK and Wistar fetuses, and it is known that IGF-1 is produced by fetal and neonatal rat pancreatic islets (18,19). Therefore, the reduced pancreatic IGF-2 expression in GK fetuses cannot be solely attributed to the decreased ß-cell mass observed at this stage. Moreover, whereas pancreatic expression of IGF-2 in normal fetus, as shown by in situ hybridization technique, is largely associated with pancreatic endocrine cells (20), it has also been reported within the pancreatic ductal epithelium in neonatal rat pancreas (15).
Recent studies in our laboratory have suggested that the growth and endocrine differentiation of GK and Wistar pancreatic rudiments are identical when followed in vitro (3). Thus, as far as the in vivo fetal situation is recapitulated by the in vitro development of the GK rudiments, the anomaly of the GK rat leading to deficient pancreatic endocrine cell differentiation in vivo could mainly result from a deficiency of one (or several) extrapancreatic factor(s) (3). Because it is known that in the developing normal pancreas, IGF-2 is involved in the regulation of both islet growth and differentiation (5), the reduced circulating IGF-2 levels in GK fetuses could therefore play a crucial role in the anomaly of ß-cell mass in the GK fetuses. As circulating levels of IGF-2 in the rat fetus derive predominantly from the hepatic production site (5), the decreased serum IGF-2 levels are probably the result of the decreased IGF-2 mRNA hepatic expression. Involvement of circulating insulin and plasma glucose levels in the regulation of liver IGFs production at fetal stages has been repeatedly reported (21), whereas the role of plasma GH on fetal IGF regulation is considered as negligible (10,21). Therefore, it is important to take into account the IGF data available in a rat model of induced (streptozotocin) gestational diabetes with fetal hyperglycemia and hypoinsulinemia in the range of the values found in GK fetuses (10). In this study (10), the fetal serum IGF-2 (and IGF-1) level as well as the fetal liver IGF-2 (and IGF-1) mRNA expression were found to be clearly increased, which is in accordance with reports showing that high glucose in vivo (22) or in vitro (23) increases liver IGF-2 expression. The only in vivo situation with a reported decrease of the serum IGF-2 was found in fetuses from undernourished mothers (10). However, in this last situation, both fetal liver IGF-2 (and IGF-1) mRNA levels were still significantly increased as compared with normal fetuses. Taken together, these observations suggest that the situation in the GK fetuses is a very unique one because the decreased IGF-2 level in the serum and its decreased expression in the liver seems to be largely independent of the variations of fetal insulin and glucose levels. Thus, IGF-2 defective production in the GK fetuses may reflect a primary and generalized anomaly. Such a view is also consistent with the results of previous genetic studies reporting that a locus containing the gene encoding the IGF-2 is associated with diabetes phenotype in the GK rat (24). Whereas defective IGF-2 appears to be an early landmark in the pathological sequence leading to retardation of ß-cell growth in the fetal GK rat, the pancreatic IGF-2 status in the aging adult GK animal is quite different. Using the swedish GK colony, Höög et al. (25) have reported that an inappropriately processed IGF-2 of high molecular weight accumulates in pancreas from 6-month-old GK rats. More immunoreactive IGF-2 was localized together with insulin to secretory granules in a subset of large and irregular-shaped islets than in either GK rat islets with normal structure or islets from normal rats (26). Because this increase in the high molecular weight form of IGF-2 in the GK pancreas appears to be a late consequence of the early reduction of ß-cell number/function in the GK model, it might be triggered by long-term hyperglycemia and might represent an islet self-damaging process disrupting normal arrangement of islet architecture through fibroblast proliferation and collagen deposition.
In view of the reported ability of IGFBPs to modulate IGF bioactivity, we examined serum and tissular expression of IGFBP-1 and -2 in GK fetuses. In general, IGFBP-2 appears to inhibit IGF actions, particularly those of IGF-2 (4). We report here normal serum, liver, and pancreatic mRNA expression of IGFBP-2 in GK fetuses. This conclusion is not at odds with the general agreement that few changes in liver IGFBP-2 mRNA were found in fetuses from experimental diabetic (10) or undernourished mothers (6). By contrast, an increased serum and liver mRNA expression of IGFBP-1 was found in GK fetuses. Insulin appears to play a major role in regulating IGFBP-1 gene transcription in adult animals, i.e., IGFBP-1 transcription is high in diabetic animals and rapidly reduced to normal values after insulin treatment (27,28). The hypoinsulinemic status of GK fetuses could therefore contribute to the high levels of IGFBP-1.
Finally, we have tested the possibility that direct biological action of IGFs on fetal GK ß-cell is impaired. Our in vitro results showed that IGF-1 and -2 stimulate the ß-cell replication in fetal Wistar islets in accordance with a previous demonstration (29). Similarly, addition of IGF-1 or -2 to the GK isolated islets significantly increased the ß-cell replication. These effects were obtained with a submaximal IGF-2 concentration and a maximal IGF-1 concentration based in our circulating-levels evaluation and in vitro data, respectively (19,30). Therefore, we can conclude that IGF responsiveness by fetal GK islets is maintained but cannot eliminate the possibility that the sensitivity of the islet to these factors could be altered.
In conclusion, in GK fetuses at 21.5 dpc, the defective IGF-2 production appears to be an early landmark in the pathological sequence leading to retardation of ß-cell growth in the fetal GK rat.
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ACKNOWLEDGMENTS |
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The authors are grateful to Mylène Vincent for expert assistance with serial sections of isolated fetal islets. They also thank Susana Fajardo for her invaluable technical help.
Parts of this work were presented at the 36th Annual Meeting of the European Association for the Study of Diabetes, Jerusalem, Israel, 1721 September 2000, and has appeared as an abstract in Diabetologia 43 (Suppl. 1):A131, 2000.
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FOOTNOTES |
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Received for publication 19 April 2001 and accepted in revised form 8 November 2001.
BrdU, 5'-bromo-2'-deoxyuridine; dpc, days postcoitum; GH, growth hormone; IGFBP, IGF binding protein; PVDF, polyvinylidene fluoride; TBS, Tris-buffered saline.
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REFERENCES |
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