Mae Jean Miller

Expression of adrenomedullin and its receptor during embryogenesis suggests autocrine or paracrine modes of action.

The present study reports the developmental patterns of expression of adrenomedullin (AM) in rat and mouse embryos. AM is a novel multifunctional peptide recently isolated from a human pheochromocytoma, which has been shown to promote growth in a variety of mammalian cell lines. We have applied several techniques to investigate the localization of both the AM peptide and its receptor throughout development. Immunocytochemical detection has been performed using different specific antibodies against AM and its gene-related peptide pro-AM N-terminal 20 peptide. In situ hybridization showed the localization of the messenger RNAs for AM and its receptor. Western blot analysis together with reverse transcription-PCR gave further support to the localization of AM and its receptor in a variety of embryonic tissues. The localization of the receptor paralleled that of AM itself, suggesting an autocrine or paracrine mode of action. The spatio-temporal pattern of expression of AM in cardiovascular, neural, and skelet...

Expression of Adrenomedullin and Its Receptor in Normal and Malignant Human Skin: A Potential Pluripotent Role in the Integument

Adrenomedullin (AM) is a multifunctional peptide involved in a variety of physiological functions, including growth regulation and antimicrobial activity. We have determined by immunohistochemistry and in situ hybridization that AM and its receptor are present in all the epithelial cells of the normal skin, including keratinocytes of the epidermis and hair follicles, as well as cells of the glands and secretory ducts. We also have detected AM in the sweat, by RIA. In addition, AM and its receptor were found in skin tumors of different histologies. The presence of AM and its receptor in normal and neoplastic skin was confirmed by RT-PCR and Western blot analysis performed on cell extracts from human skin cell lines. Radiolabeled AM bound to specific sites in cultured cells with a Kd of 9 nM. This binding was blocked by the addition of cold AM but not by related peptides such as AM 22-52, pro-AM 20 N-terminal peptide, calcitonin gene-related peptide, calcitonin gene-related peptide 8-37, or amylin. Finally, exposure to synthetic AM resulted in an increase of thymidine intake by skin cells. These results implicate AM as a potential player in skin defense against infectious microorganisms and as a possible autocrine growth factor in normal skin physiology and tumor development.

Adrenomedullin Receptor Expression in Human Lung and in Pulmonary Tumors

Adrenomedullin (AM) is a multifunctional regulatory peptide that stimulates cyclic AMP production in many target tissues and is highly expressed in the lung. Analysis of the distribution of the recently cloned AM receptor (AM-R) by non-radioactive in situ hybridization revealed abundant expression in the basal cells of the airway epithelium and Type II pneumocytes. The expression of AM-R in the two cell types involved in epithelial regeneration of the lung suggests that AM may be relevant in such functions as organ development, wound repair, and epithelial turnover. AM-Rs are also synthesized in vivo and in vitro by a variety of tumor cells that also express the ligand, suggesting the existence of an autocrine loop that may be involved in tumor growth stimulation. The present findings suggest that the AM/AM-R regulatory system plays a major role in respiratory physiology and lung carcinogenesis and that new functions for AM remain to be identified.

Underlying Disease Stress Augments Plasma and Tissue Adrenomedullin (AM) Responses to Endotoxin: Colocalized Increases in AM and Inducible Nitric Oxide Synthase within Pancreatic Islets*

Rapid onset metabolic impairments accompany the initiation of the acute phase response to many disease stresses, whereas more chronic metabolic perturbations may prolong the recovery period. In the present experiment the application of a mild endotoxin challenge [lipopolysaccharide (LPS)] alone or additive to a chronic subclinical parasitic infection (Sarcocystis cruzi; LPS 1 PI) in calves was used as a model to investigate and define a dynamic axis coordinated between adrenomedullin (AM) and nitric oxide in response to immune challenge. Plasma AM and NO2/NO3 concentration responses after LPS (0.45 mg/kg, iv) were rapid in onset and of higher magnitude and longer duration in PI 1 LPS calves than in those challenged with LPS alone. The post-LPS increase in plasma insulin was significantly greater in PI 1 LPS than in LPS; following refeeding of calves, insulin secretion was most blunted in PI 1 LPS calves, consistent with the inhibitory effects of NO and AM on insulin secretion. A more chronic response to the immune challenge (organ specific) was in evidence in tissues harvested 24 h after LPS challenge. Where lung and liver showed no immunostaining for inducible nitric oxide (iNOS), iNOS immunostaining was present in the pancreas, localized to islets only. The percentages of iNOS-immunopositive cells in islets were 1.7%, 21%, 6.7%, and 24% for control (C; saline infused), PI, LPS, and PI 1 LPS calves, respectively. AM immunostaining was not evident in the liver and was present, but not differentially affected by treatment, in airway epithelium in the lung. The number of islet cells with positive immunostaining for AM was increased in LPS, PI, and PI 1 LPS calves. The percentages of AM-immunopositive cells in islets were 8%, 27%, 20%, and 33% for C, PI, LPS, and PI 1 LPS, respectively. Immunostaining for AM and iNOS was colocalized with cells positive for pancreatic polypeptide. By triple label confocal fluorescence immunocytochemistry, colocalization of intense AM and iNOS immunostaining was confirmed in peripheral islet cells. A weaker, more diffuse iNOS signal was also apparent in insulin-containing cells in PI 1 LPS. We conclude that chronic low level infection potentiates the severity of metabolic perturbations that arise with additive sudden onset immune challenge, as can occur with bacterial toxins. These metabolic disturbances are reflected in and possibly mediated by early onset increases in plasma tumor necrosis factor-a, insulin, and AM and up-regulated iNOS activity. These acute complications rapidly progress into a more chronic state characterized by diminished insulin response to feeding stimulus and colocalized increases in pancreatic islet AM and iNOS. The pancreatic responses in AM and iNOS may play a major role in mediating prolonged disturbances in nutrient use by tissues through their influences on temporal patterns of pancreatic hormone secretion during chronic illness. (Endocrinology 140: 5402‐5411, 1999)