Downregulation of hepatoma-derived growth factor contributes to retarded lung metastasis via inhibition of epithelial-mesenchymal transition by systemic POMC gene delivery in melanoma.

The prognosis of malignant melanoma is poor due to high incidence of metastasis, underscoring the demand for development of novel therapeutic strategies. Stress hormone pro-opiomelanocortin (POMC) is the precursor for several anti-inflammatory peptides that hold promise for management of cancer-related diseases. The present study evaluated the antimetastatic potential and mechanism of POMC therapy for metastatic melanoma. Adenovirus-mediated POMC gene delivery potently inhibited the invasiveness of human and mouse melanoma cells. Moreover, after induction of lung metastasis, systemic POMC expression significantly reduced the foci formation and neovascularization in lungs. Mechanistic studies revealed that POMC therapy inhibited the epithelial-mesenchymal transition (EMT) of melanoma cells by upregulation of E-cadherin and downregulation of vimentin and α-smooth muscle actin (α-SMA). In addition, microarray analysis unveiled POMC gene transfer reduced the mRNA level of multiple prometastatic factors, including hepatoma-derived growth factor (HDGF). Cell culture and immunohistochemical studies further confirmed that POMC gene delivery significantly decreased the expression of HDGF in melanoma cells and tissues. Despite stimulating the invasion and EMT, exogenous HDGF supply only partially attenuated the POMC-mediated invasion inhibition and EMT change in melanoma cells. Finally, we delineated the contribution of melanocortins to POMC-induced inhibition of invasion, HDGF downregulation, and E-cadherin upregulation. Together, these results indicate that HDGF downregulation participates in POMC-induced suppression of metastasis and EMT in melanoma.

Peripheral administration of the N-terminal pro-opiomelanocortin fragment 1-28 to Pomc-/- mice reduces food intake and weight but does not affect adrenal growth or corticosterone production.

Pro-opiomelanocortin (POMC) is a polypeptide precursor that undergoes extensive processing to yield a range of peptides with biologically diverse functions. POMC-derived ACTH is vital for normal adrenal function and the melanocortin alpha-MSH plays a key role in appetite control and energy homeostasis. However, the roles of peptide fragments derived from the highly conserved N-terminal region of POMC are less well characterized. We have used mice with a null mutation in the Pomc gene (Pomc(-/-)) to determine the in vivo effects of synthetic N-terminal 1-28 POMC, which has been shown previously to possess adrenal mitogenic activity. 1-28 POMC (20 mug) given s.c. for 10 days had no effect on the adrenal cortex of Pomc(-/-) mice, with resultant cortical morphology and plasma corticosterone levels being indistinguishable from sham treatment. Concurrent administration of 1-28 POMC and 1-24 ACTH (30 mug/day) resulted in changes identical to 1-24 ACTH treatment alone, which consisted of upregulation of steroidogenic enzymes, elevation of corticosterone levels, hypertrophy of the zona fasciculate, and regression of the X-zone. However, treatment of corticosterone-depleted Pomc(-/-) mice with 1-28 POMC reduced cumulative food intake and total body weight. These anorexigenic effects were ameliorated when the peptide was administered to Pomc(-/-) mice with circulating corticosterone restored either to a low physiological level by corticosterone-supplemented drinking water (CORT) or to a supraphysiological level by concurrent 1-24 ACTH administration. Further, i.c.v. administration of 1-28 POMC to CORT-treated Pomc(-/-) mice had no effect on food intake or body weight. In wild-type mice, the effects of 1-28 POMC upon food intake and body weight were identical to sham treatment, but 1-28 POMC was able to ameliorate the hyperphagia induced by concurrent 1-24 ACTH treatment. In a mouse model which lacks all endogenous POMC peptides, s.c. treatment with synthetic 1-28 POMC alone can reduce food intake and body weight, but has no impact upon adrenal growth or steroidogenesis.

Hypothalamic pro-opiomelanocortin gene delivery ameliorates obesity and glucose intolerance in aged rats.

AIMS/HYPOTHESIS: Age-related obesity is associated with impaired hypothalamic pro-opiomelanocortin (Pomc) gene expression. We assessed whether overproduction of POMC in the hypothalamus ameliorates age-related obesity in rats. METHODS: Recombinant adeno-associated virus (rAAV) encoding Pomc (rAAV-Pomc) or control vector was delivered bilaterally into the basomedial hypothalamus of aged obese rats with coordinates targeting the arcuate nucleus. Energy balance, glucose metabolism, brown adipose tissue thermogenesis and mRNA levels of hypothalamic neuropeptides and melanocortin receptors were assessed. RESULTS: Forty-two days after Pomc gene delivery, hypothalamic Pomc expression increased 12-fold while agouti-related protein and neuropeptide Y mRNA levels remained unchanged. Using a punch technique, we detected the highest Pomc RNA level in the arcuate nucleus. Pomc overexpression reduced food consumption from day 10 after vector injection, but this anorexic effect abated by day 30. In contrast, there was a steady decrease in body weight without apparent attenuation. Pomc gene delivery decreased visceral adiposity and induced uncoupling protein 1 in brown adipose tissue in aged rats. Serum NEFA and triglyceride levels were also diminished by rAAV-Pomc treatment. Improved glucose metabolism and insulin sensitivity were observed on day 36 but not day 20 after Pomc gene delivery. The expression of hypothalamic melanocortin 3 and 4 receptor decreased by 17% and 25%, respectively in rAAV-Pomc rats. CONCLUSIONS/INTERPRETATION: This study demonstrates that targeted Pomc gene therapy in the hypothalamus reduces body weight and visceral adiposity, and improves glucose and fat metabolism in aged obese rats. Thus long-term activation of the central melanocortin system may be a viable strategy to combat age-related obesity and diabetes.

Targeting melanocortin receptors as a novel strategy to control inflammation.

Adrenocorticotropic hormone and alpha-, beta-, and gamma-melanocyte-stimulating hormones, collectively called melanocortin peptides, exert multiple effects upon the host. These effects range from modulation of fever and inflammation to control of food intake, autonomic functions, and exocrine secretions. Recognition and cloning of five melanocortin receptors (MCRs) has greatly improved understanding of peptide-target cell interactions. Preclinical investigations indicate that activation of certain MCR subtypes, primarily MC1R and MC3R, could be a novel strategy to control inflammatory disorders. As a consequence of reduced translocation of the nuclear factor kappaB to the nucleus, MCR activation causes a collective reduction of the major molecules involved in the inflammatory process. Therefore, anti-inflammatory influences are broad and are not restricted to a specific mediator. Short half-life and lack of selectivity could be an obstacle to the use of the natural melanocortins. However, design and synthesis of new MCR ligands with selective chemical properties are already in progress. This review examines how marshaling MCR could control inflammation.

In vivo electroporation of proopiomelanocortin induces analgesia in a formalin-injection pain model in rats.

Opioids remain the most efficacious pharmacological agents for various clinical pain syndromes. Recently, various engineered cells capable of secreting opioidergic peptides have been applied to relieve pain in animal models. In vivo gene delivery by viruses encoding endogenous opioids has also been used with success. In this study, we attempted non-viral intrathecal in vivo gene delivery by electroporation to induce analgesia. Thirty Sprague-Dawley rats were used in this study, six in each of five groups. Rats were treated as follows: vehicle without electroporation (group A), vehicle with electroporation (group B), 100 microg of pCMV-hPOMC plasmid without electroporation (group C), or 100 microg of pCMV-hPOMC plasmid with electroporation (group D). Group E was treated with both pCMV-hPOMC plasmid and electroporation, and given naloxone (1mg/kg) 1h before the formalin test. The tail flick, paw withdrawal latency from radiant heat, and formalin test results for each groups were compared. Radioimmunoassay (RIA) and reverse transcription-polymerase chain reaction (RT-PCR) were used to determine the levels of expression of beta-endorphin in the spinal cord. beta-Endorphin expression was localized by immunohistochemistry. A significant decrease in the number of flinches in phase 2 of the formalin test was observed in the group treated with both plasmid and electroporation (group D), whereas the other measures of pain did not differ between groups. RIA and RT-PCR both showed increased expression of beta-endorphin in group D. The expression of beta-endorphin was highest in laminae I and II of the dorsal horn of the spinal cord. We conclude that electroporation successfully delivered intrathecally administered pCMV-hPOMC into the dorsal horn cells of the spinal cord, and induced analgesia in phase 2 of the formalin test in rats.

Leptin resistance in obesity is characterized by decreased sensitivity to proopiomelanocortin products.

Obesity in normal animals has been demonstrated to be associated with a decrease in sensitivity to leptin especially as it relates to leptin's capacity to increase sympathetic nerve activity and enhance cardiovascular dynamics. In normal animals leptin has been demonstrated to exert significant regulatory responses by its capacity to increase proopiomelanocortin (POMC) expression and especially the increase in alpha melanocyte stimulating hormone (alphaMSH). These responses to leptin are blocked by a melanocortin-4 (MC-4) receptor antagonist. In this study we investigated the responsiveness of the sympathetic nervous system and cardiovascular system of high fat fed obese animals to the intracerebroventricular (ICV) administration of the POMC products alphaMSH and beta-endorphin (beta-END). We further investigated these responses in obese animals following leptin administration in the presence of MC-4 receptor and opioid receptor blockade. The ICV administration of leptin resulted in an increase in lumbar sympathetic nerve activity (LSNA) and mean arterial pressure (MAP) in normals but decreased it in the obese. The ICV administration of alphaMSH increased the LSNA and MAP in normal animals but to a lesser degree in obese animals. On the other hand beta-endorphin decreased the LSNA and MAP in normal animals but increased it in obese animals. Additionally ICV leptin administration in obese animals in the presence of MC-4 or opioid receptor blockade resulted in an increase in sympathetic activity and a pressor response. From these studies we conclude that obesity in high fat fed animals is characterized by a decreased sensitivity to alphaMSH and a paradoxical response to beta-endorphin and this altered responsiveness may be a factor in the altered leptin resistance characteristic of obese animals.

Central cardiovascular effects of joining peptide in genetically hypertensive rats.

Joining peptide (JP) is one of the major products of proopiomelanocortin (POMC). The biological function of this peptide has not been clarified despite its relative abundance in the pituitary and the hypothalamus. Recently we demonstrated that JP, which was isolated from bovine posterior pituitary, possesses Na pump inhibitor activity. The purpose of this study is to explore the physiological relevance of JP in cardiovascular regulation. For these investigations, we used the synthetic peptides bovine JP (bJP) and COOH-terminally amidated rat JP (rJP), since JP is known to have sequence variability among species. Intracisternal administration of both bJP and rJP in urethan-anesthetized rats evoked similar hypertensive and tachycardia effects. The effects of both peptides were markedly greater in the spontaneously hypertensive rats (SHR) compared with the normotensive Wistar Kyoto rats (WKY). Intravenous bolus injections of rJP at the same doses were without effect. Autoradiography, using 125I-labeled [0Tyr]-rJP as a ligand, revealed specific binding sites for rJP in the dorsal medulla in areas corresponding to the nucleus tractus solitarii (NTS) (extending from approximately 0.4 mm caudal to 1.8 mm rostral to the obex). Microinjections of rJP into the caudal part of the NTS of anesthetized SHR produced dose-related pressor and tachycardic responses. The pressor and tachycardic responses were also observed at the rostral part of the NTS, whereas the injections into the intermediate part of the NTS evoked depressor and bradycardic responses in SHR. These results suggest that at doses tested, the site of JP action resides in the central nervous system, and that JP is a potent neuropeptide in medullary sites known to be pivotal in central cardiovascular regulation. The effect of JP is especially prominent in the genetically hypertensive rat.