R. Lauro

NGF-withdrawal induces apoptosis in pancreatic beta cells in vitro

Abstract.Aims/hypothesis: Using primary cultures of human pancreatic islets, purified human pancreatic beta cells and the mouse βTC6-F7 cell line, we analysed the expression of nerve growth factor, (NGF/NGF) receptors in beta cells. To investigate whether NGF could sub-serve an autocrine antiapoptotic role in beta cells, we studied the effects of NGF withdrawal using a neutralizing monoclonal anti-NGF antibody. Methods: The expression of NGF and NGF receptors (gp140Trk-A and p75NTR) were analysed by RT-PCR and immunofluorescence. Pulse-chase experiments and beta cell/PC12 co-cultures were used to investigate NGF production and secretion from beta cells. Possible apoptosis induced by NGF withdrawal was monitored by phosphatidylserine translocation, nucleosomal formation, DNA laddering and FACS analysis. Involvement of transcription/translation mechanisms were investigated as well as the gp140Trk-A required. Finally, signal transduction pathways typically involved in apoptotic mechanisms were analysed by western blot analysis. Results: We show that NGF and both NGF receptors, gp140Trk-A and p75NTR are expressed in beta cells where NGF is produced and secreted in a biologically active form. NGF-withdrawal induces beta-cell transcription/translation independent apoptosis but mediated by gp140Trk-A. Analysis of signal transduction pathways revealed that NGF withdrawal inhibits the PI3-K, protein kinase B (AKT), Bad survival pathway and activates c-Jun kinase (JNK) whereas ERKs and p38 mitogen-activated protein kinase (MAPK) are not affected. Moreover, Bcl-XL, but not Bcl-2 protein expression are reduced. Conclusion/interpretaiton: We suggest that the integrity of the NGF/NGF receptor system and NGF bioavailability participate in controlling beta-cell survival in culture which represents a key issue for improving possibilities for transplantations in the treatment of diabetes. [Diabetologia (2001) 44: 1281–1295]

Effect of biotin on glucokinase activity, mRNA expression and insulin release in cultured beta-cells

Biotin is known to influence hepatic glucokinase (GK) expression both at a transcriptional and at a translational level. The aim of the present paper was to investigate the effect of biotin on pancreatic GK. For this purpose, RIN 1046-38 cells were cultured in the presence of different biotin concentrations for different times; there-after, GK mRNA expression, GK activity and insulin release were studied. Results demonstrated that biotin has a biphasic effect on GK mRNA expression, being stimulatory after short-term treatment and inhibitory after long-term treatment. GK activity was increased after long-term treatment. Insulin release was not affected by biotin treatment. These data suggest that biotin may influence glucose metabolism also by acting directly at the level of beta-cells.

Distribution of glucocorticoid receptor mRNA in the rat spinal cord

Using in situ hybridization (ISH), we studied the distribution of rat glucocorticoid receptors (GR) mRNA in rat spinal cord. mRNA encoding for GR was abundant throughout the white matter and a clear pattern of distribution was detected within the grey matter. In the grey matter mRNA was primarily localized in the ventral horn, where motoneurones were strongly labelled. In the dorsal horn, the distribution appears more diffuse but the superficial layers (I and II) clearly exhibited a shigher signal. We conclude that, in rat spinal cord, GR are present in both glial and neuronal cells. In particular, both somatosensory and motor pathways contain GR.

Peptide-based radioimmunoassay for the two isoforms of the human insulin receptor.

SummaryThe insulin receptor exists in two isoforms differing by the absence (HIR-A) or presence (HIR-B) of 12 amino acids in the COOH-terminus of the α-subunit as a consequence of alternative splicing of exon 11. In this study, we developed a radioimmunoassay for the two isoforms employing antibodies raised against two peptides, one (Pep-12) corresponding to residues encoded by exon 11, and the other (Pep-13) corresponding to a COOH-terminal domain of the α-subunit which is common to both HIR-A and HIR-B isoforms. These peptides were iodinated and used as both ligands and standards. The assay is specific, highly reproducible, and sensitive with a detection limit of 10 fmol of receptor. One mole of purified insulin receptor, measured by Scatchard analysis, is read as one mole of receptor in the radioimmunoassay with either Pep-12 or Pep-13 as standards. The radioimmunoassay is applicable to the measurement of total content and relative abundance of the two isoforms in extracts from various tissues. We applied the radioimmunoassay to measure the relative abundance of the two isoforms in fat and muscle from normal, obese non-diabetic and non-insulin-dependent diabetic (NIDDM) subjects. Results demonstrate that expression of the low-affinity HIR-B form is significantly increased in obese and NIDDM subjects compared with control subjects. In addition, the increased expression of the HIR-B isoform was significantly correlated with both body mass index (r=0.52; p=0.006) and fasting glucose levels (r=0.59; p=0.001).

Tissue-specific expression of two alternatively spliced isoforms of the human insulin receptor protein.

Two insulin receptor mRNA species are expressed in human tissues as a result of alternative splicing of exon 11. This event is regulated in a tissue-specific manner. To date, there is little information about the relative abundance of the two receptor protein isoforms on the cell surface. The aim of the present investigation was to assess whether the tissue-specific expression of the two insulin receptor mRNA species is paralleled by a similar pattern of expression of the two receptor protein isoforms. To this end, we assessed the relative distribution of the two receptor variants in various human tissues at the mRNA and protein levels. A PCR-based technique was used to measure the relative abundance of the two mRNA species, and two immunological assays were used to measure the relative steady-state expression of the two receptor protein isoforms. The expression of the two insulin receptor protein isoforms followed the tissue-specific pattern of expression of the two mRNA species.

Differential regulation of adrenocorticoid receptors in the hippocampus and spinal cord of adrenalectomized rats.

Using multiplex polymerase chain reaction assay and cytosolic receptor binding assay we studied type I, mineralocorticoid receptor (MR), and type II, glucocorticoid receptor (GR), adrenocorticoid receptors expression in rat hippocampus and spinal cord, at various times after adrenalectomy: 12 hr, 24 hr, 3 days, and 1 week. Analysis of the data demonstrates that in hippocampus the expression of MR and GR mRNA was not significantly affected by adrenalectomy. On the contrary, Bmax of MR was significantly increased at each time post‐surgery, with only slight modifications of Kd. Bmax and Kd for GR showed a significant increase after 3 days and 1 week. In the spinal cord, MR mRNA was increased 12 hr after adrenalectomy, reaching a maximum at 3 days. Bmax of MR was also significantly increased after 3 days, whereas its Kd remained unchanged for the entire duration of the study. Both GR mRNA and binding parameters were poorly affected by adrenalectomy. The results of the present experiments demonstrate that the absence of adrenocortical hormones influences differentially MR and GR expression in hippocampus and spinal cord, suggesting the existence of various and independent mechanisms of regulation of adrenocorticoid receptor.

Role of the exon 11 of the insulin receptor gene on insulin binding identified by anti-peptide antibodies.

The insulin receptor exists in two isoforms differing by the absence (HIR-A) or presence (HIR-B) of 12 amino acids in the C-terminus of the alpha-subunit as a consequence of alternative splicing of exon 11. It was shown that the two isoforms exhibit different binding affinities for insulin, thus suggesting that the sequence encoded by exon 11 may be important for insulin binding. To further investigate this issue, we generated polyclonal antibodies against C-terminal peptides of the two HIR alpha-subunit variants. Herein, we characterized two antibodies, PA-11 and PA-12, directed against the C-terminus or the N-terminus of the sequence encoded by exon 11, respectively, and one (PA-13) directed against a sequence in the carboxy-terminal region of the alpha-subunit which is common to HIR-A and HIR-B. Antibodies were characterized for their ability to immunoprecipitate the receptor and to inhibit [125I]insulin binding to both isoforms. We found that PA-13 immunoprecipitates both the HIR-A and the HIR-B, PA-12 immunoprecipitates exclusively the HIR-B, and PA-11 fails to precipitate both isoforms. Interestingly, PA-12 inhibits specifically insulin to the HIR-B, whereas other PAs fail to affect insulin binding to either isoforms. Furthermore, PA-12 linearises the Scatchard plot of binding data, and retards the dissociation rate of insulin, thus suggesting that antibody affects cooperative interactions among binding sites. We conclude that the sequence encoded by exon 11 may play a role in modulating the binding of insulin to the receptor and negative cooperativity.

DBI mRNA is expressed in endocrine pancreas and its post-translational product DBI(33-50) inhibits insulin release.

It has been previously demonstrated that DBI is present in endocrine pancreas and it is able to inhibit insulin release in isolated rat islets. Its mechanism of action has been investigated, demonstrating the possible involvement of cAMP and ATP-dependent K+ channels. DB133–50, a post-translational product of DBI, is also able to inhibit insulin release, but its action has not been characterized. In the present study, we have investigated the presence of DBI mRNA in pancreas, islets and cultured ß cells. The possible mechanism of action of DBI33–50 and the involvement of BZ/GABAA receptors has been studied.

Distribution of Adrenocorticoid Receptors in the Rat CNS Measured by Competitive PCR and Cytosolic Binding

Combined quantitative polymerase chain reaction (PCR) and cytosolic binding assay techniques are used to measure mineralocorticoid receptor (MR) and glucocorticoid receptor (GR) mRNA, Kd, and Bmax in various rat central nervous system (CNS) regions, namely amygdala, hypothalamus, hippocampus, cortex, pituitary, and cervical, thoracic, and lumbar spinal cord. Two internal standards (i.s.) cDNA were cloned for quantitative PCR purposes. The i.s. templates differed from the respective wild-type (wt) templates for a single base-pair mutation introduced by PCR that generated a unique restriction site, thus allowing amplification products arising from coamplification ofwt and i.s. to be distinguished. Results show that cerebellum, which displayed average Bmax values for both receptors, contained the highest level of MR and GR mRNA. Hippocampus also had a high level of MR mRNA. Low mRNA content was found in the hypothalamus for MR and GR as well as in the cortex for GR. High Bmax values for both MR and GR were found in the lumbar spinal cord, despite a modest mRNA content. The lowest Bmax values were found in the cortex for both receptors. It is, therefore, concluded that mRNA content and Bmax are not closely correlated in the rat CNS. These data suggest a differential regulation of various adrenocorticoid receptor isoforms. Moreover, this quantitative PCR method is very sensitive and can be used to assay small amounts of material in order to obtain absolute measurements of mRNA expression.