GROWTH HORMONE RELEASING FACTOR-TEST IN ACROMEGALY: COMPARISON WITH OTHER DYNAMIC TESTS

Human pancreatic growth hormone releasing factor (hpGRF1-44) was given intravenously as a 100 micrograms bolus to 20 patients with active acromegaly. The GH-responses were variable, ranging from an increase of 8 to 2813% from the basal level (mean +/- SE, 428 +/- 136%). Sixteen GRF-responders (delta% greater than or equal to 100%) were arbitrarily distinguished from four GRF non-responders, whose GH-levels increased less than 100% from basal level after GRF-administration. The outcome of the GRF-test did not correlate with the results of other dynamic tests of GH-secretion in acromegaly (oral glucose tolerance test, insulin hypoglycaemia, TRH-, LHRH-, CRF-stimulation). In 10 patients who had not been treated before, the GH-increments after GRF were higher than those in seven patients who had previously been subjected to transsphenoidal surgery, though they still had clinically and biochemically active acromegaly. Ten acromegalics, who were tested with GRF, were later treated surgically by the transsphenoidal route and were reevaluated with GRF-stimulation 2 months after surgery. Eight patients appeared clinically cured of whom four had complete normalization and four had significantly lower basal and conventionally stimulated GH-levels postoperatively. These patients also had normal postoperative GH-responses to GRF, which had been significantly higher before surgery compared with normal controls. It is concluded that the GRF-test in acromegaly does not help in establishing the diagnosis. The normalization of the GH-response to GRF after transsphenoidal surgery seems to represent additional evidence for normalization of GH-secretion, though the latter is not proven by the normal outcome of this test.     

ACUTE DEXAMETHASONE SUPPRESSION OF ACTH SECRETION STIMULATED BY HUMAN CORTICOTROPHIN RELEASING HORMONE, AVP AND HYPOGLYCAEMIA

In order to obtain more insight into the mechanisms regulating endogenous ACTH secretion in humans we studied the inhibitory effect of acute i.v. dexamethasone administration on ACTH release under various conditions. Six male volunteers were subjected to six different protocols. After combined i.v. injection of 100 micrograms corticotrophin releasing hormone (CRH) and 100 micrograms growth hormone releasing hormone (GRH) there was the expected rise in ACTH (area under the curve, 1053 +/- 204 (SE) (pmol/l) min) and cortisol (59788 +/- 10098 (nmol/l) min) rise which was suppressed by prior i.v. injection of 2 mg dexamethasone (ACTH: 444 +/- 63 (pmol/l) min; cortisol: 28528 +/- 2152 (nmol/l) min). Insulin hypoglycaemia (IH) led to a more pronounced ACTH and cortisol rise compared with CRH (6307 +/- 817 (pmol/l) min and 82080 +/- 21934 (nmol/l) min, respectively) which was not completely suppressed by prior pretreatment with dexamethasone (ACTH, 580 +/- 103 (pmol/l) min; cortisol: 55649 +/- 5821 (nmol/l) min). Combined AVP/CRH injection (10 IU/100 micrograms) after pretreatment with dexamethasone (344 +/- 41 (pmol/l) min for ACTH; 32832 +/- 3173 (nmol/l) min for cortisol) could not reproduce the ACTH secretion following IH after pretreatment with dexamethasone (579 +/- 103 (pmol/l) min for ACTH and 55649 +/- 5821 (nmol/l) min for cortisol). In all subjects a saline control with 2 mg dexamethasone was performed. These findings confirm the acute inhibitory effect of glucocorticoids on CRH-stimulated ACTH secretion. Since CRH-induced ACTH secretion is almost completely abolished by administration of dexamethasone the ACTH rise following IH after dexamethasone can not be mediated by endogenous CRH alone. Moreover, since the addition of AVP to CRH (after dexamethasone suppression) could not reproduce the ACTH rise during IH after dexamethasone pretreatment, an additional, yet unknown factor stimulating ACTH secretion may be involved. In the same protocols, no significant difference could be observed comparing IH and GRH induced GH secretion (4948 +/- 1172 (mU/l) min vs 3596 +/- 820 (mU/l) min, NS); furthermore, in contrast to results obtained by chronic steroid administration, acute i.v. dexamethasone pretreatment did not affect IH or GRH-induced GH secretion (4110 +/- 666 (mU/l) min vs 2916 +/- 462 (mU/l) min, NS). The GRH-stimulated GH secretion (3596 +/- 820 (mU/l) min) was not suppressed by prior intravenous treatment with dexamethasone (2916 +/- 504 (mU/l) min, NS).     

PSEUDOHYPOPARATHYROIDISM: INHERITANCE AND EXPRESSION OF DEFICIENT RECEPTOR-CYCLASE COUPLING PROTEIN ACTIVITY

Pseudohypoparathyroidism, Type I (PSP-I) is a familial disorder characterized by secondary hyperparathyroidism, resistance of urinary cyclic adenosine-3', 5'-monophosphate (cAMP) excretion to exogenous parathyroid hormone (PTH), and by effects upon other hormones, including thyrotrophin (TSH) hyperresponsiveness to thyroliberin (TRH). In the present study, 12 PSP-I patients in five families exhibited partial deficiency of receptor-cyclase coupling protein (N protein) in blood cells, in association with the skeletal findings of Albright's hereditary osteodystrophy. In one father and six mothers of PSP-I patients, deficient N protein activity was associated with normal urinary cAMP responses to PTH. In this group of seven parents, five had Albright's osteodystrophy, two exhibited secondary hyperparathyroidism, and two had TSH hyperresponsiveness to TRH. In a sixth family with none of the features of Albright's osteodystrophy, N protein deficiency did not correlate with urinary cAMP responsiveness to PTH. In this kindred, one mother with N protein deficiency, but normal urinary cAMP responsiveness to PTH had raised serum levels of immunoreactive PTH. We conclude that in the majority of families with PSP-I the urinary cAMP response to PTH is an inadequate indicator of the genetic defect. In such families, deficiency of N activity more consistently points to metabolic defects, including secondary hyperparathyroidism and TSH hyperresponsiveness, even when urinary cAMP responses are normal.