Regulation of pancreatic endocrine cell differentiation by sulphated proteoglycans.

AIMS/HYPOTHESIS: Epithelium-mesenchyme interactions play a major role in pancreas development. Recently, we demonstrated that embryonic pancreatic mesenchyme enhanced progenitor cell proliferation but inhibited endocrine cell differentiation. Here, we investigated the role played by sulphated proteoglycans, which are known to be essential to embryonic development, in this inhibitory effect. MATERIALS AND METHODS: We first determined the expression of the genes encoding glypicans, syndecans and the main glycosaminoglycan chain-modifying enzymes in immature embryonic day (E) 13.5 and more differentiated E17.5 rat pancreases. Next, using an in vitro model of pancreas development, we blocked the action of endogenous sulphated proteoglycans by treating embryonic pancreases in culture with chlorate, an inhibitor of proteoglycan sulphation, and examined the effects on pancreatic endocrine cell differentiation. RESULTS: We first showed that expression of the genes encoding glypicans 1, 2, 3 and 5 and heparan sulphate 2-sulfotransferase decreased between E13.5 and E17.5. We next found that alteration of proteoglycan action by chlorate blocked the inhibitory effect of the mesenchyme on endocrine differentiation. Chlorate-treated pancreases exhibited a dramatic increase in beta cell number in a dose-dependent manner (169-and 375-fold increase with 30 mmol/l and 40 mmol/l chlorate, respectively) and in alpha cell development. Insulin-positive cells that developed in the presence of chlorate exhibited a phenotype of mature cells with regard to the expression of the following genes: pancreatic and duodenal homeobox gene 1 (Pdx1), proprotein convertase subtilisin/kexin type 1 (Pcsk1; previously known as pro-hormone convertase 1/3), proprotein convertase subtilisin/kexin type 2 (Pcsk2; previously known as pro-hormone convertase 2) and solute carrier family 2 (facilitated glucose transporter), member 2 (Slc2a1; previously known as glucose transporter 2). Finally, we showed that chlorate activated endocrine cell development by inducing neurogenin 3 (Neurog3) expression in early endocrine progenitor cells. CONCLUSIONS/INTERPRETATION: We demonstrated that sulphated proteoglycans control pancreatic endocrine cell differentiation. Understanding the mechanism by which sulphated proteoglycans affect beta cell development could be useful in the generation of beta cells from embryonic stem cells.

Association of RET codon 691 polymorphism in radiation-induced human thyroid tumours with C-cell hyperplasia in peritumoural tissue.

The RET proto-oncogene encodes a protein structurally related to transmembrane receptors with an intracellular tyrosine kinase domain. In human thyroid gland, the RET proto-oncogene is normally expressed in parafollicular C-cells. Thyroid C-cell hyperplasia is associated with inherited medullary thyroid carcinomas and is considered as a pre-neoplastic stage of C-cells disease. It has also been observed in thyroid tissues adjacent to follicular and papillary carcinomas. In order to study the relationship between a misfunctioning of the RET proto-oncogene and the presence of C-cell hyperplasia, we compared a series of thyroid glands presenting sporadic or radiation-associated tumours, as well as samples of unrelated normal thyroid tissues, for alteration in exons 10 and 11 of the gene and for the presence or absence of C-cell hyperplasia. Here we report a significantly higher frequency of C-cell hyperplasia present in peritumoural thyroid tissues of radiation-induced epithelial thyroid tumours, than in peritumoural of sporadic thyroid tumours or in control normal thyroid tissues (P=0.001). A G691S RET polymorphism was present with a higher frequency in radiation-induced epithelial thyroid tumours (55%) than in sporadic tumours (20%) and in control normal thyroid tissues (15%). Interestingly, this polymorphism was associated in the majority (88%) of radiation-induced tumours with a C-cell hyperplasia in the peritumoural tissues. Several explanations for this association are discussed.

Papillary thyroid carcinoma: 6 cases from 2 families with associated lymphocytic thyroiditis harbouring RET/PTC rearrangements.

Familial papillary thyroid carcinoma (PTC) is a well recognized disease. However, genetic predisposition to familial PTC is rare and the molecular alterations at the origin of the pathology are unknown. The association between PTC and lymphocytic thyroiditis (LT) has been reported recently. We communicate here 6 cases of PTC associated with LT in 2 unrelated families. PTC was diagnosed on classical nuclear and architectural criteria. It was bilateral in 5 cases. Architecture was equally distributed between typical PTC and its follicular variant. LT was present in variable degrees, including in 4 cases, oncocytic metaplasia. Using the RT-PCR technique, we observed a RET/PTC rearrangement in the carcinomatous areas of patients of both families: PTC1 in family 1 and PTC3 in family 2 and a RET/PTC rearrangement in non-malignant thyroid tissue with LT in family 2. The RET/PTC band was weaker or absent in pure LT areas. Furthermore, using a polyclonal ret antibody, an apical or a diffuse cytoplasmic ret onc protein immunolabelling was observed in the three patients with RET/PTC1 rearrangement and in the three patients with RET/PTC3 rearrangement. In conclusion our data: (1) show the presence of a RET/PTC 1 or 3 rearrangement (depending on the family) together with a variable expression of ret protein in all the PTCs; (2) suggest that the molecular event at the origin of the PTCs seems to be particular to each one of the studied families; and (3) confirm that the ret proto-oncogene activating rearrangement(s) is an early event in the thyroid tumorigenic process and that it can be observed in association with LT.

Evidence for a telomere-independent "clock" limiting RAS oncogene-driven proliferation of human thyroid epithelial cells.

An initiating role for RAS oncogene mutation in several epithelial cancers is supported by its high incidence in early-stage tumors and its ability to induce proliferation in the corresponding normal cells in vitro. Using retroviral transduction of thyroid epithelial cells as a model we ask here: (i) how mutant RAS can induce long-term proliferation in an epithelial cell in contrast to the premature senescence observed in fibroblasts; and (ii) what is the "clock" which eventually triggers spontaneous growth arrest even in epithelial clones generated by mutant RAS. The early response to RAS activation in thyroid epithelial cells showed two features not seen in fibroblasts: (i) a marked decrease in expression of the cyclin-dependent kinase inhibitor (CDKI) p27(kip1) and (ii) the absence of any induction of p21(waf1). When proliferation eventually ceased (after up to 20 population doublings) this occurred despite undiminished expression of mutant RAS and was tightly correlated with a return to the initial high level of p27(kip1) expression, together with the de novo appearance of p16(ink4a). Importantly, neither the CDKI changes nor the proliferative life span of RAS-induced epithelial clones was altered by induction of telomerase activity through forced expression of the catalytic subunit, hTERT, at levels sufficient to immortalize human fibroblasts. These data provide a basis for cell-type differences in sensitivity to RAS-induced proliferation which may explain the corresponding tumor-type specificity of RAS mutation. They also show for the first time in a primary human cell model that a telomere-independent mechanism can limit not only physiological but also oncogene-driven proliferation, pointing therefore to a tumour suppressor mechanism additional, or alternative, to the telomere clock.

[Radiation-induced thyroid cancers]. / Cancers thyroïdiens radio-induits.

Human epithelial thyroid radiation-induced tumorigenesis is the most frequent radiation-induced tumorigenic process in man. Results of different studies, concerning the molecular mecanism(s) of epithelial thyroid radiation-associated tumorigenesis show : 1) that there is not a significant difference in the frequency of activation of ras, gsp and trk proto-oncogenes between radiation-associated and <> thyroid tumors; 2) the relevant role played by RET/PTC ret proto-oncogene activating rearrangements, in the development of radiation-associated thyroid tumors originated after therapeutic radiation (mainly PTC 1) or the atomic accident of Chernobyl (mainly PTC 3) and 3) suggest that the patients who develop thyroid tumors after a history of irradiation, show a genomic instability consisting in a DNA repair defect.

Search for NTRK1 proto-oncogene rearrangements in human thyroid tumours originated after therapeutic radiation.

Rearrangements of NTRK1 proto-oncogene were detected in 'spontaneous' papillary thyroid carcinomas with a frequency varying from 5 to 25% in different studies. These rearrangements result in the formation of chimaeric genes composed of the tyrosine kinase domain of NTRK1 fused to 5' sequences of different genes. To investigate if the NTRK1 gene plays a role in radiation-induced thyroid carcinogenesis, we looked for the presence of NTRK1-activating rearrangements in 32 human thyroid tumours (16 follicular adenomas, 14 papillary carcinomas and two lymph-node metastases of papillary thyroid carcinomas) from patients who had received external radiation, using the reverse transcription polymerase chain reaction, Southern blot and direct sequencing techniques. These data were compared with those obtained in a series of 28 'spontaneous' benign and malignant thyroid tumours, collected from patients without a history of radiation exposure and four in vitro culture cell lines derived from 'spontaneous' thyroid cancers. Our results concerning the radiation-associated tumours showed that only rearrangements between NTRK1 and TPM3 genes (TRK oncogene) were detected in 2/14 papillary carcinomas and in one lymph-node metastasis of one of these papillary thyroid carcinomas. All the radiation-associated adenomas were negative. In the 'spontaneous' tumours, only one of the 14 papillary carcinomas and one of the four in vitro culture cell lines, derived from a papillary carcinoma, presented a NTRK1 rearrangement also with the TPM3 gene. Twenty-five of this series of radiation-associated tumours were previously studied for the ras and RET/PTC oncogenes. In conclusion, our data: (a) show that the overall frequency of NTRK1 rearrangements is similar between radiation-associated (2/31: 6%) and 'spontaneous' epithelial thyroid tumours (2/32: 6%). The frequency, if we consider exclusively the papillary carcinomas, is in both cases 12%; (b) show that the TRK oncogene plays a role in the development of a minority of radiation-associated papillary thyroid carcinomas but not in adenomas; and (c) confirm that RET/PTC rearrangements are the major genetic alteration associated with ionizing radiation-induced thyroid tumorigenesis.

Mechanisms of mutagenesis in mammalian cells. Application to human thyroid tumours.

Mutations are defined as stable and irreversible modifications of the normal genetic message due to small changes in the number or type of bases, or to large modifications of the genome such as deletions, insertions or chromosome rearrangements. These lesions are due to either polymerase errors during normal DNA replication or unrepaired DNA lesions, which will give rise to mutations through a mutagenic pathway. The molecular process leading to mutagenesis depends largely on the type of DNA lesions. Base modifications, such as 8-oxo-guanine or thymine glycol, both induced by ionizing radiations (IR), are readily replicated leading to direct mutations, usually base-pair substitutions. The 8-oxo-G gives rise predominantly to G to T transversions, the type of mutations found in ras or p53 gene from IR-induced tumors. Bulky adducts produced by chemical carcinogens or UV-irradiation are usually repaired by the nucleotide excision repair (NER) pathway which is able to detect structural distortion in the normal double-strand DNA backbone. These lesions represent a blockage to DNA and RNA polymerases as well as some signal for p53 accumulation in the damaged cell. In the absence of repair, these lesions could be eventually replicated owing to the induction of specific proteins at least in bacteria during the SOS process. The precise nature of the error-prone replication across an unexcised DNA lesion in the template is not fully understood in detailed biochemical terms, in mammalian cells. IR basically produce a very large number of DNA lesions from unique base modifications to single- or double-strand breaks and even complex DNA lesions due to the passage of very high energy particles or to a local re-emission of numerous radicals. The breakage of the double-helix is a difficult lesion to repair. Either it will result in cell death or, after an incorrect recombinational pathway, it will induce frameshifts, large deletions or chromosomal rearrangements. Most of the IR-induced mutations are recessive ones, requiring therefore a second genetic event in order to exhibit any harmful effect and a long latency period before the development of a radiation-induced tumor. The fact that IR essentially induced deletions and chromosomal translocations renders very difficult the use of the p53 gene as a marker for mutation analysis. In agreement with the type of lesions induced by IR, it is interesting to point out that the presence has been observed, in a vast majority of radiation-induced papillary thyroid carcinomas (PTC), of an activated ret proto-oncogene originated by the fusion of the tyrosine kinase 3' domain of this gene with the 5' domain of four different genes. These ret chimeric genes which are due to intra- or inter-chromosomal translocations, were called RET/PTC1 to PTC5. The RET/PTC rearrangements were found in PTC from children contaminated by the Chernobyl fall-out as well as in tumours from patients with a history of therapeutic external radiation, with a frequency of 60-84%. This frequency was only 15% in 'spontaneous' PTC. The type of ret chimeric gene predominantly originated by the accidental or therapeutic IR was different. Indeed, PTC1 was present in 75% of the tumours linked to a therapeutic radiation and PTC3 in 75% of the Chernobyl ones. The other forms of RET/PTC were observed in only a minority of the post-Chernobyl PTC (< 20%). The difference in the frequency of PTC1 and PTC3 in both types of PTC, is statistically significant (P < 10(-5), Fischer's exact test). In two of the post-therapeutic radiation PTC, RET/PTC1 and PTC3 were simultaneously present. A PTC1 gene was also observed in 45% of the adenomas appearing after therapeutic radiation. The long-period of latency between exposure to IR and the appearance of thyroid tumours is probably due to the conversion of a heterozygote genotype of IR-induced mutations to a homozygote one. It will be interesting to use this time lag in accidental or therapeutic-irradiated p

High prevalence of activating ret proto-oncogene rearrangements, in thyroid tumors from patients who had received external radiation.

A high frequency (about 60%) of ret rearrangements in papillary thyroid carcinomas of children exposed to radioactive fallout in Belarus after the Chernobyl accident, has been reported by three recent studies (Fugazzola et al., 1995; Ito et al., 1994; Klugbauer et al., 1995). These studies suggested that the radiation exposure may be a direct inducer of activating rearrangements in the ret gene. In order to confirm the postulated link between irradiation and the role of the ret proto-oncogene in thyroid tumorigenesis, we analysed for the presence of ret activating rearrangements using RT-PCR, XL-PCR, Southern blot and direct sequencing techniques, 39 human thyroid tumors (19 papillary carcinomas and 20 follicular adenomas), from patients who had received external radiation for benign or malignant conditions. As controls, we studied 39 'spontaneous' tumors (20 papillary carcinomas and 19 follicular adenomas). Our data concerning the radiation-associated tumors, showed that: (1) the overall frequency of ret rearrangements was 84% in papillary carcinomas (16/19) and 45% (9/20) in follicular adenomas; (2) in contrast with the results obtained in the Chernobyl tumors, the most frequently observed chimeric gene was RET/PTC1 instead of the RET/PTC3 and (3) all the tumors were negative for RET/PTC2. In the 'spontaneous' tumors, only the papillary carcinomas presented a ret rearrangement (15%:3/20): 1 RET/PTC1, 1 RET/ PTC3 and 1 uncharacterized. In conclusion, our results confirm the crucial role played by the ret proto-oncogene activating rearrangements in the development of radiation-associated thyroid tumors appearing after therapeutic or accidental ionizing irradiation, and show, for the first time, the presence of RET/PTC genes in follicular adenomas appeared after external irradiation.

Oncogenic rearrangements of the ret proto-oncogene in thyroid tumors induced after exposure to ionizing radiation.

A high frequency (approximately 60%) of ret rearrangements in Chernobyl papillary thyroid carcinomas (PTC) has been reported recently. The data suggested that the radiation exposure may be a direct inducer of activating rearrangements in the ret gene. In our study, we have analyzed for the presence of RET/PTC oncogenes using the RT-PCR, XL-PCR, Southern blot and direct sequencing techniques, 39 human thyroid tumors from patients who had received external radiation for benign or malignant conditions. As controls, we studied 39 'spontaneous' tumors. Our results indicate that: 1) the overall frequency of ret rearrangements was 84% in papillary carcinomas (16/19) and 45% (9/20) in follicular adenomas; 2) in contrast with the results obtained in the Chernobyl tumors, the most frequently observed chimeric gene was RET/PTC1; and 3) all the tumors were negative for RET/PTC2. In the 'spontaneous' tumors, only the papillary carcinomas presented a ret rearrangement (15%: 3/20). Our data confirm the crucial role played by the ret proto-oncogene activating rearrangements in the development of radiation-associated thyroid tumors, and show, for the first time, the presence of RET/PTC genes in follicular adenomas appeared after external irradiation.

Cloning and sequencing of a tpr-met oncogene cDNA isolated from MNNG-transformed human XP fibroblasts.

A rearranged tpr-met oncogene was identified in a MNNG-transformed human Xeroderma pigmentosum (XP) cell line (ASKMN). A 2016 bp cDNA was cloned and sequenced, disclosing an ORF with a coding capacity for a 523 aa protein. The sequence of this tpr-met cDNA was very similar to that previously reported in another human MNNG-transformed cell line (MNNG-HOS).

Pattern of ras and gsp oncogene mutations in radiation-associated human thyroid tumors.

The preferential activation of the Ki-ras oncogene in follicular radiation-associated human thyroid carcinomas, has been suggested by Wright et al. (1991). However, only 12 thyroid tumors were analysed in this study. In order to confirm if radiation favours, in human thyroid tumorigenesis, the appearance of a particular molecular lesion, we studied 33 benign and malignant human radiation-associated thyroid tumors. We used polymerase chain reaction (PCR) amplification and allele-specific hybridization with mutant-specific probes for the three ras genes and the gsp oncogene. Compared to 85 'spontaneous' human thyroid tumors, the radiation-associated cases: (1) show a similar overall frequency of ras and gsp mutations (about 30% and 6% respectively); (2) present a similar frequency of mutation of the three ras genes without any predominance in adenomas and papillary carcinomas and (3) all Ki-ras mutations were found in papillary carcinomas (4/15). ras and gsp genes were never found mutated simultaneously, suggesting an alternative role for both oncogenes in the thyroid tumorigenic radiation-associated process.