In view of the recent findings of stimulatory effects of GHRH analogs, JI-34, JI-36 and JI-38, on cardiomyocytes, pancreatic islets and wound healing, three series of new analogs of GHRH(1–29) have been synthesized and evaluated biologically in an endeavor to produce more potent compounds. “Agmatine analogs”, MR-356 (N-Me-Tyr1-JI-38), MR-361(N-Me-Tyr1, D-Ala2-JI-38) and MR-367(N-Me-Tyr1, D-Ala2, Asn8-JI-38), in which Dat in JI-38 is replaced by N-Me-Tyr1, showed improved relative potencies on GH release upon subcutaneous administration in vivo and binding in vitro. Modification with N-Me-Tyr1 and Arg29-NHCH3 as in MR-403 (N-Me-Tyr1, D-Ala2, Arg29 -NHCH3 -JI-38), MR-406 (N-Me-Tyr1, Arg29 -NHCH3 -JI-38) and MR-409 (N-Me-Tyr1, D-Ala2, Asn8, Arg29-NHCH3 -JI-38), and MR-410 (N-Me-Tyr1, D-Ala2, Thr8, Arg29-NHCH3 -JI-38) resulted in dramatically increased endocrine activities. These appear to be the most potent GHRH agonistic analogs so far developed. Analogs with Apa30-NH2 such as MR-326 (N-Me-Tyr1, D-Ala2, Arg29, Apa30-NH2 -JI-38), and with Gab30 -NH2, as MR-502 (D-Ala2, 5F-Phe6, Ser28, Arg29, Gab30 -NH2 -JI-38) also exhibited much higher potency than JI-38 upon i.v. administration. The relationship between the GH-releasing potency and the analog structure is discussed. Fourteen GHRH agonists with the highest endocrine potencies were subjected to cardiologic tests. MR-409 and MR-356 exhibited higher potency than JI-38 in activating myocardial repair in rats with induced myocardial infarction. As the previous class of analogs, exemplified by JI-38, had shown promising results in multiple fields including cardiology, diabetes and wound healing, our new, more potent, GHRH agonists should manifest additional efficacy for possible medical applications.
GPR39 is a vertebrate G protein-coupled receptor related to the ghrelin/neurotensin receptor subfamily. The receptor is expressed in a range of tissues including the pancreas, gut/gastrointestinal tract, liver, kidney and in some regions of the brain. GPR39 was initially thought to be the cognitive receptor for the peptide hormone, obestatin. However, subsequent in vitro studies have failed to demonstrate binding of this peptide to the receptor. Zn(2+) has been shown to be a potent stimulator of GPR39 activity via the Gα(q), Gα(12/13) and Gα(s) pathways. The potency and specificity of Zn(2+) in activating GPR39 suggest it to be a physiologically important agonist. GPR39 is now emerging as an important transducer of autocrine and paracrine Zn(2+) signals, impacting upon cellular processes such as insulin secretion, gastric emptying, neurotransmission and epithelial repair. This review focuses on the molecular, structural and biological properties of GPR39 and its various physiological functions.
Inflammation-related dysregulation of the hypothalamic-pituitary-adrenal (HPA) axis is central to the course of systemic inflammatory response syndrome or sepsis. The underlying mechanisms, however, are not well understood. Initial activation of adrenocortical hormone production during early sepsis depends on the stimulation of hypothalamus and pituitary mediated by cytokines; in late sepsis, there is a shift from neuroendocrine to local immuneadrenal regulation of glucocorticoid production. Therefore, the modulation of the local immune-adrenal cross talk, and not of the neuroendocrine circuits involved in adrenocorticotropic hormone production, may be more promising in the prevention of the adrenal insufficiency associated with prolonged sepsis. In the present work, we investigated the function of the crucial Toll-like receptor (TLR) adaptor protein myeloid differentiation factor 88 (MyD88) in systemic and local activation of adrenal gland inflammation and glucocorticoid production mediated by lipopolysachharides (LPSs). To this end, we used mice with a conditional MyD88 allele. These mice either were interbred with Mx1 Cre mice, resulting in systemic MyD88 deletion, predominantly in the liver and hematopoietic system, or were crossed with Akr1b7 Cre transgenic mice, resulting thereby in deletion of MyD88, which was adrenocortical-specific. Although reduced adrenal inflammation and HPAaxis activation mediated by LPS were found in Mx1Cre+ -MyD88 fl/fl mice, adrenocortical-specific MyD88 deletion did not alter the adrenal inflammation or HPA-axis activity under systemic inflammatory response syndrome conditions. Thus, our data suggest an important role of immune cell rather than adrenocortical MyD88 for adrenal inflammation and HPA-axis activation mediated by LPS.adrenal gland insufficiency | Toll-like receptors | the HPA axis S epsis and septic shock are major causes of death in intensivecare units worldwide and show an increasing incidence (1). In sepsis, excessive, uncontrolled activation of the immune system is harmful to the host and leads to multiorgan failure and death. Adrenal glucocorticoid production plays a beneficial role in response to systemic inflammation by counteracting hyperactivation of the immune system. However, in many critically ill patients, this homeostatic activation of adrenocortical hormone secretion is impaired (2). It has been estimated that 60% of critically ill patients show an abnormal adrenal glucocorticoid response to administration of exogenous adrenocorticotropic hormone (ACTH) (3).Adrenal hormone production in sepsis is thought to be regulated by cytokines that elevate hypothalamic corticotropin releasing hormone (CRH) levels. CRH, in turn, produces the release of pituitary ACTH-the main regulator of synthesis of adrenal glucocorticoid hormones (4). It is generally accepted that patternrecognition receptors such as Toll-like receptors (TLRs) play a substantial role in hypothalamic-pituitary-adrenal (HPA) axis activation induced by pathogens. This activation, in turn, may be a...
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