Andrew F. Stewart

Structural and Physiologic Characterization of the Mid-region Secretory Species of Parathyroid Hormone-related Protein

Parathyroid hormone-related protein (PTHrP) is initially translated as a preprohormone which is posttranslationally processed to yield a family of mature secretory forms. Most attention has focused on the amino-terminal portion of the molecule which is homologous to parathyroid hormone. It is clear, however, that a mid-region species of PTHrP is posttranslationally cleaved from the highly conserved mid-region of PTHrP, and that the amino terminus of this peptide is Ala38. The purposes of the current study were three: 1) to confirm that Arg37 immediately preceding Ala38 serves as a posttranslational processing site in the PTHrP precursor, 2) to determine the carboxyl terminus of the mid-region secretory species of PTHrP, and 3) to synthesize this authentic mid-region secretory form of PTHrP and determine whether it is biologically active. The results indicate that: 1) Arg37 is indeed a processing site in the PTHrP precursor; 2) three distinct mid-region PTHrP species are generated by posttranslational processing, PTHrP(38-94)amide, PTHrP(38-95), and most likely, PTHrP(38-101); and 3) synthetic mid-region PTHrP(38-94)amide is active in four different biological systems. These studies confirm the finding that PTHrP is a prohormone. More importantly, they define a novel, biologically active highly conserved mid-region secretory form of PTHrP.

Expression of parathyroid hormone-related protein in the rat glomerulus and tubule during recovery from renal ischemia.

Parathyroid hormone-related protein (PTHrP) is widely expressed in normal adult and fetal tissues, where it acts in an autocrine/paracrine fashion, stimulates growth and differentiation, and shares early response gene characteristics. Since recovery from renal injury is associated with release of local growth factors, we examined the expression and localization of PTHrP in normal and ischemic adult rat kidney. Male Sprague-Dawley rats underwent complete bilateral renal artery occlusion for 45 min, followed by reperfusion for 15 min, and 2, 6, 24, 48, and 72 h. Renal PTHrP mRNA levels, when compared with sham-operated animals, increased twofold after ischemia, and peaked within 6 h after reperfusion. PTH receptor, beta-actin, and cyclophilin mRNA levels all decreased after ischemia. PTHrP immunohistochemical staining intensity increased in proximal tubular cells after ischemia, changing its location from diffusely cytoplasmic to subapical by 24 h after reperfusion. In addition, PTHrP localized to glomerular epithelial cells (visceral and parietal), but not to mesangial cells. PTHrP and PTH stimulated proliferation two- to threefold in cultured mesangial cells. We conclude that PTHrP mRNA and protein production are upregulated after acute renal ischemic injury, that PTHrP is present in glomerulus and in both proximal and distal tubular cells, and that PTHrP stimulates DNA synthesis in mesangial cells. The precise functions of PTHrP in normal and injured kidney remain to be defined.

Hypercalcemia in breast cancer: Reassessment of the mechanism

Hypercalcemia in patients with breast cancer is usually attributed to osteolytic bone metastases. Seventeen patients with biopsy-proved breast cancer and hypercalcemia were identified in a prospective, unselected manner. Biochemical and clinical evaluation included measurements of parathyroid hormone, nephrogenous cAMP, vitamin D metabolites, fasting calcium excretion, and maximal tubular phosphate reabsorption, and bone radionuclide scanning. Tumor histologic findings were also reviewed. Four of the 17 patients (23.5 percent) had no evidence of bone involvement by bone scanning or radiography. Two additional patients (a total of 35 percent) appeared to have a humoral component to their hypercalcemia as determined by the presence of elevated nephrogenous cAMP excretion. These observations suggest that humoral, tumor-derived products may play a more important role in the hypercalcemia of breast cancer than has been previously recognized.

Parathyroid hormone-related protein a peptide of diverse physiologic functions

Parathyroid hormone-related protein (PTHrP) is the factor responsible for the syndrome of humoral hypercalcemia of malignancy. PTHrP is produced by a multitude o f normal as well as malignant cells, and exerts both classic parathyroid hormone (PTH)-like and PTH-unlike effects. The molecular cloning of the PTHrP gene, and the subsequent recognition of its widespread expression in normal tissues under normal physiologic conditions, has prompted intense inquiry into its biologic function. PTHrP appears to act in an autocrine or paracrine fashion in (a) normal embryogenesis and neonatal development, (b) cellular growth and differentiation, (c) reproduction and lactation, (d) epithelial calcium transport, and (e) smooth muscle relaxation. These five key emerging physiologic roles of PTHrP are the focus of this review.

Nephrogenous Cyclic AMP, Adenylate Cyclase-Stimulating Activity, and the Humoral Hypercalcemia of Malignancy

Publisher Summary This chapter discusses nephrogenous cyclic AMP (NcAMP), adenylate cyclase-stimulating activity (ACSA), and the humoral hypercalcemia of malignancy (HHM). Clinical HHM is a pathophysiologic syndrome which can be readily distinguished from 1°HPT group and local osteolytic hypercalcemia. Human HHM and animal models of HHM are associated with increases in NcAMP or UcAMP excretion. In contrast, NcAMP or UcAMP excretion is normal in humans and animals with HHM. These observations, and the findings that humans with MAHC can be divided into clinically and pathophysiologically distinct groups based upon NcAMP excretion, lead inescapably to the conclusion that the observed elevations in NcAMP are related mechanistically to hypercalcemia in patients with HHM. The ACSA that is present in human and animal HHM-associated tumors is not typically present in tumors derived from normocalcemic patients or animals. This ACSA can be prepared in highly purified form from human and animal tumors and can be shown to result from a basic protein with a molecular weight of approximately 30,000. This highly purified material contains potent in vitro bone-resorbing activity. These observations provide strong evidence that this PTH-like ACSA is related mechanistically to HHM. Human and animal HHM-associated tumors contain mRNA which encodes for a secretary protein which is closely related or identical to the ACSA found in tumor extracts.

Corticotroph Cell Pituitary Adenoma Within an Ovarian Teratoma: A New Cause of Cushing's Syndrome

A 24-year-old woman with severe Cushings syndrome was found to have corticotroph cell pituitary adenoma arising within a benign cystic ovarian teratoma. The patient manifested sustained hypercortisolemia and lack of suppression of either adrenocorticotropin (ACTH) or cortisol production. There was no evidence of a pituitary mass or secretion of other hormones. After careful clinical evaluation, no other tumor masses were found. Resection of the ovarian tumor led to normalization of ACTH and cortisol levels. Densely granulated corticotroph tumor cells with prominent Type I microfilaments and intracytoplasmic ACTH immunoreactivity characterized the neoplasm as a pituitary corticotroph cell adenoma. This is, to our knowledge, the first case reported of a functioning pituitary adenoma arising within a benign cystic teratoma.

Therapy of malignancy-associated hypercalcemia: 1983

Hypercalcemia is common among patients with cancer and may be due to secretion by tumors of a humoral, calcemic, bone-resorbing factor or, alternatively, to skeletal metastases. In each case, hypercalcemia ultimately results from osteoclastic bone resorption. Therapy should be aimed at (1) reducing or eliminating tumor burden, (2) increasing renal calcium clearance, and (3) inhibiting osteoclastic bone resorption. Hydration with saline infusion and augmentation of calciuresis with furosemide should be the initial modes of therapy in most patients. Oral phosphorus should be used in hypophosphatemic patients. Glucocorticoids, calcitonin, and prostaglandin synthetase inhibitors may be effective in reducing bone resorption in selected patients. Mithramycin reliably induces a fall in serum calcium but long-term use is usually complicated by toxicity. A new class of drugs that inhibit osteoclastic bone resorption, the diphosphonates, is being employed in clinical trials in patients with malignancy-associated hypercalcemia. Results have been particularly promising with dichloromethylene diphosphonate.

Hypercalcemia in small cell carcinoma of the pancreas

Although small cell carcinoma of the lung has a high incidence of skeletal metastasis and is frequently associated with paraneoplastic syndromes, it is only rarely associated with hypercalcemia. Similarly, the more unusual small cell carcinoma of the pancreas has not been associated with hypercalcemia. The authors describe the first such patient with small cell carcinoma of the pancreas and hypercalcemia. Comprehensive metabolic measurements (fasting calcium excretion, renal phosphorus threshold, 1,25 dihydroxyvitamin D, 25 hydroxyvitamin D levels, nephrogenous cyclic AMP and immunoreactive PTH levels) suggest that although bone metastases were present, the hypercalcemia may have been caused in part by humoral mechanisms.

Hypercalcemia associated with gynecologic malignancies: Biochemical characterization

Fasting calcium excretion, renal phosphorus threshold, plasma 1,25 dihydroxyvitamin D, immunoreactive PTH, nephrogenous cyclic AMP excretion, and tumor burden were assessed in nine patients with gynecologic neoplasms and hypercalcemia. Gynecologic neoplasms were responsible for hypercalcemia in seven of 34 (20.5%) consecutive patients with malignancy‐associated hypercalcemia. The tumor burden in each patient was large. Three of four endometrial carcinomas contained squamous elements. All patients displayed biochemical evidence of nonparathyroid humorally mediated hypercalcemia (bone resorption). Treatment of hypercalcemia did not appear to diminish production of the humoral calcemic factor but eradication of tumor eliminated biochemical evidence of the humoral syndrome. It can be concluded that (1) gynecologic neoplasms are a frequent cause of malignancy‐associated hypercalcemia, (2) humoral mechanisms appeared to be responsible for the hypercalcemia in 100% of the patients in this series, (3) squamous features occur with unexpected frequency in hypercalcemic endometrial carcinoma, (4) the presence of hypercalcemia connotes a large tumor burden, and (5) treatment directed at the neoplasm (but not treatment directed at hypercalcemia) may eliminate evidence of ectopic calcemic hormone production.

Hypercalcaemia complicating acute myelogenous leukaemia: a syndrome of multiple aetiologies

Summary. Hypercalcaemia complicating acute myelogenous leukaemia is a rare but well‐recognized phenomenon. In most cases the pathogenetic mechanism causing the hypercalcaemia remains poorly understood. We recently studied in detail two patients with acute myelogenous leukaemia who developed hypercalcaemia during the course of their illness. The results of these studies conclusively excluded primary hyperparathyroidism or ectopic parathyroid hormone production as causes of the patients’ hypercalcaemia. In vitro studies carried out on short‐term suspension cultures of one patients peripheral blood blast cells demonstrated production of a factor with potent bone resorbing activity, distinct from parathyroid hormone (iPTH) and prostaglandin E2 (PGE2). Further characterization of the bone resorbing factor suggested that it bore some similarity to osteoclast activating factor (OAF). Hypercalcaemia in the other case appeared to be due to a combination of skeletal invasion by malignant cells, and to ectopic secretion of an unidentified humoral factor with bone resorbing activity. These two cases demonstrate that the hypercalcaemia complicating acute myelogenous leukaemia may be due to a variety of mechanisms distinct from parathyroid hormone production.