Ghrelin and cortistatin in lung cancer: expression of peptides and related receptors in human primary tumors and in vitro effect on the H345 small cell carcinoma cell line.

Ghrelin, a natural GH secretagogue (GHS) acylated peptide, and cortistatin (CST), a natural SRIF-like peptide, interfere with neoplastic growth in different cancers. We tested forty-one lung carcinomas and the H345 small cell lung carcinoma (SCLC) cell line by RT-PCR to investigate the presence of ghrelin and CST and related receptors, including type 1a GHS receptor (GHS-R1a), all SRIF-receptor subtypes (sst 1-5) and MRGX2. Moreover, the presence of ghrelin and CST peptides was studied in both tumors and H345 cells. Ghrelin and CST mRNA were present in the majority of tested tumors, but ghrelin and CST proteins were revealed only in tumors with a neuroendocrine phenotype. All the receptors mRNA had a heterogeneous expression without correlation between ghrelin (or CST) and their receptor distribution. All the transcripts, but not GHS-R1a, were expressed in H345 cells. However, ghrelin and desacyl ghrelin induced in vitro a dose-dependent inhibition on the H345 cell proliferation and increased apoptosis. Conversely, neither CST nor SRIF affected H345 cell growth, despite the presence of their specific receptors. The anti-proliferative and the pro-apoptotic effects of ghrelin were consistent with binding experiments on H345 cell, where either acylated or des-acylated ghrelin recognized a common binding site. In conclusion, the present study indicates that: a) ghrelin and CST mRNAs are expressed in lung cancers, although some neuroendocrine tumors contain detectable amounts of the peptides; b) GHSR-1a mRNA is present exclusively in neuroendocrine tumors, whereas MRGX2 mRNA (but not peptide) is expressed in all histological types; c) both ghrelin forms inhibit H345 cell proliferation, both directly and enhancing apoptosis, despite the absence of GHS-R1a, whereas CST and its receptors do not interfere with cell growth.

Oxytocin and oxytocin receptors in cancer cells and proliferation.

The hypothalamic nonapeptide oxytocin plays a crucial role in many reproductive and behavioural functions. However, in recent years, an additional new role for oxytocin has been identified in neoplastic pathology. In tumours, oxytocin acts as a growth regulator, through the activation of a specific G-coupled transmembrane receptor, the oxytocin receptor. In vitro, oxytocin inhibits proliferation of neoplastic cells of either epithelial (mammary and endometrial), nervous or bone origin, all expressing oxytocin receptor. Furthermore, an oxytocin growth-inhibiting effect was also tested and confirmed in vivo in mouse and rat mammary carcinomas. In neoplastic cells derived from two additional oxytocin target tissues, trophoblast and endothelium, oxytocin was found to promote cell proliferation, an effect opposite to that previously described in all other neoplastic oxytocin-responsive cells. The signal transduction pathways coupled to the biological effects of oxytocin are different in oxytocin growth-inhibited or growth-stimulated cells, and may depend on the membrane localization of the oxytocin receptor itself. The inhibitory effect of oxytocin is apparently mediated by activation of the cAMP-protein kinase A pathway, a nonconventional oxytocin signalling pathway, whereas the mitogenic effect is coupled to the increase of intracellular [Ca(2+)] and tyrosine phosphorylation, 'classical' oxytocin transducers. Moreover, the oxytocin receptor localization in lipid rafts enriched in caveolin-1 turns the inhibition of cell growth into a proliferative response, eliciting different epidermal growth factor receptor/mitogen-activated protein kinase activation patterns. This unexpected role of oxytocin (and oxytocin analogues) in regulating cell proliferation, as well as the widespread expression of oxytocin receptors in neoplastic tissues of different origin, opens up new perspectives on the biological role of the oxytocin-oxytocin receptor system in cancer.

Biological relevance of oxytocin and oxytocin receptors in cancer cells and primary tumors.

For a long time, the hypothalamic nonapeptide oxytocin (OT) is known to play a crucial role in many reproductive and behavioral functions. In recent years, a new biological effect of OT has been identified in neoplastic pathology. In this context, OT acts as a growth regulator. through the activation of specific G-coupled transmembrane receptors (OTR). In vitro, an antiproliferative effect of OT was demonstrated in neoplastic cells of either epithelial (mammary and endometrial) or nervous or bone origin, all expressing OTR. Furthermore, the growth-inhibiting effect of OT was also tested and confirmed in mouse and rat mammary carcinomas in vivo. In neoplastic cells from another OT target tissue, trophoblast, the OT effect was to promote proliferation, the opposite of what previously observed in all the other neoplastic OT responsive cells. The signal transduction involved in the OT biological effect was different in OT growth-inhibited or growth-stimulated cells. In the former, the OT effect was mediated by the activation of the cAMP-PKA pathway, a non-conventional OT signaling, whereas in the latter by the increase of intracellular calcium and tyrosine phosphorylation, which are the 'classical' OT transducers. The unexpected role of OT (and OT analogues) in regulating cell proliferation, as well as the diffuse expression of OTR in neoplastic tissue of different origin, open new perspectives on the biological role of the OT-OTR system in cancer.

Oxyphilic and non-oxyphilic thyroid carcinoma cell lines differ in expressing apoptosis-related genes.

Oxyphilic tumors of the thyroid are characterized by mitochondrion-rich cells and extensive DNA fragmentation. In order to clarify if a different expression of apoptosis-related genes could be responsible for DNA fragmentation in oxyphilic cell tumors, two thyroid follicular carcinoma-derived cell lines, having oxyphilic (XTC.UC1) and non-oxyphilic (WRO) features, were compared applying a gene array technique. Under basal culture conditions, several pro-apoptotic genes [caspases 3 and 10, Fas and the tumor necrosis factor-related apoptosis-inducing ligand (trail) genes] were switched on in oxyphilic, but not in non-oxyphilic cells. No difference in the mitochondrial apoptosis-related genes (bax, bad, bcl family etc.) was observed. Using the ISEL technique, the extent of DNA fragmentation did not differ under basal conditions in the two cell lines. Conversely, following an oxidative pro-apoptotic stress (6-h methylene blue treatment and light exposure), XTC.UC1 cells showed an extensive DNA fragmentation (up to 70% of cells), dramatically exceeding that observed in WRO cells (up to 20% of cells). In contrast, the oxidative stimulus induced a remarkable apoptosis gene activation in non-oxyphilic WRO cells only. These results suggest that oxyphilic cells may have a unique silent activation of a pro-apoptotic phenotype, which could be responsible for DNA instability and lead to cell death as the consequence of an increased sensitivity to ischemic stresses, as frequently observed in vivo.

Cortistatin-14 inhibits cell proliferation of human thyroid carcinoma cell lines of both follicular and parafollicular origin.

Cortistatin (CST-14, Pro-c[Cys-Lys-Asn-Phe-Phe-Trp-Lys-Thr-Phe-Ser-Ser-Cys]-Lys-NH2), a neuropeptide member of the SRIH family, binds to all 5 SRIH receptor (sst) subtypes, but also possesses a significant binding affinity to GH secretagogue receptors (GHS-R), which have been reported to mediate the antiproliferative activity of GHS on thyroid cancer cells. The effect of CST-14 on cell proliferation was studied in 3 different human thyroid carcinoma cell lines of follicular origin (N-PAP, WRO, ARO) and in one thyroid medullary carcinoma cell line (TT). CST-14 1 pM determined a significant inhibition of cell proliferation in TT, N-PAP and WRO cells and this effect was dose-dependent and more pronounced than that displayed by SRIH-14 (Ala-Gly-c[Cys-Lys-Asn-Phe-Phe-Trp-Lys-Thr-Phe-Thr-Ser-Cys]-OH) treatment. To a minor extent, CST-14, but not SRIH-14, also temporary inhibited ARO cell proliferation. By immunofluorescence, sst2, sst3 and sst5 have been demonstrated in TT cells, whereas types 3 and 5 only were expressed in N-PAP and WRO cells, and no sst subtype was found in ARO cells. The presence of both GHS-Rla and lb mRNA has been studied and demonstrated in the TT medullary carcinoma cell line, whereas follicular derived cell lines were already known to express GHS binding sites. Addition of EP-80874 (D-Mrp-c[D-Cyspyridilalanyl3-D-Trp-Lys-Val-Cys]-Mrp-NH2), a synthetic peptide that binds to SRIH and GHS-R, completely abolished the antiproliferative effects of CST-14 or SRIH-14 on sst/GHS-R positive thyroid carcinoma cell lines (WRO, N-PAP and TT). EP-80874 was also able to antagonize the inhibitory activity of CST-14 on the growth of cells (ARO) expressing GHS-R but not sst. Taken together, these data firstly demonstrate that EP-80874 has a mixed SRIH/CST antagonist activity and suggest that the oncostatic effect of CST-14 on thyroid cancer cells could be mediated by both sst and/or GHS-R.

Improved radiotracing of oxytocin receptor-expressing tumours using the new [111In]-DOTA-Lys8-deamino-vasotocin analogue.

Oxytocin receptors (OTR) have been described in a number of tumours of different origin, and represent a new target for specific radiolabelled oxytocin (OT) analogues in cancer diagnosis and therapy. By linking the DOTA chelating agent to position 8 of the deamino derivative of Lys(8)-vasotocin (dLVT), we obtained a new compound (DOTA-dLVT) with the following characteristics: (1) it forms a monomeric and stable compound that binds to OTR with an affinity comparable to that of the endogenous OT ligand; (2) it is characterised by a very good selectivity profile for the human OTR, with a low affinity binding to the closely related V1a, V1b and V2 vasopressin receptor subtypes; (3) it induces rapid and persistent receptor internalisation and (4) when radiolabelled, [(111)In]-DOTA-dLVT is efficiently and selectively taken up by OTR-positive tumours grown in mice. These features makes radiolabelled DOTA-dLVT a very good candidate for the radiotargeting of OTR-expressing tumours.