ABSTRACT
Tadeusz Reichstein was born in Wloclawek (Poland) into a Polish-Jewish family. His family emigrated to Switzerland, and he was educated in the Technical University of Zurich, becoming an engineer of chemistry. Thus he started his scientific career, firstly in Zurich and later in Basel. In his very busy life, he developed a method of vitamin C synthesis enabling industrial production of this important compound. Later, Reichstein isolated and synthesized such important adrenocortical hormones as cortisone, desoxycorticosterone and aldosterone. He received several awards but the most important was a Nobel Prize in Physiology or Medicine (1950). Reichstein spent the last years of his life in his own botanical garden and laboratory working on fern cytogenetics and the relations between different species of this archaic plant. Despite extraordinary and still valuable scientific achievements, he was always a very modest man with a humanistic attitude.
Subject(s)
Physiology/history , Aldosterone/history , Chemistry, Clinical/history , Cortisone/history , History, 19th Century , Humans , Nobel Prize , SwitzerlandABSTRACT
Classroom discussion of scientific articles can be an effective means of teaching scientific principles and methodology to both undergraduate and graduate science students. The availability of classic papers from the American Physiological Society Legacy Project has made it possible to access articles dating back to the early portions of the 20th century. In this article, we discuss a classic paper from the laboratory of Dr. James O. Davis on the regulation of aldosterone synthesis from the adrenal zona glomerulosa cell. Dr. Davis has conducted much of the seminal research investigating the renin-angiotensin system and the regulation of aldosterone release by angiotensin II. In addition to a characterization of the effects of ACTH on aldosterone regulation, this study is useful for discussing the basic principles of negative feedback pathways of the hypothalamic-pituitary axis. This study also provides examples of early bioassay techniques for the detection of angiotensin II and of the importance of quantitative measurements when investigating physiological responses. Three figures and one table are reproduced from the original article along with a series of discussion questions designed to facilitate discovery learning.
Subject(s)
Aldosterone/metabolism , Biological Science Disciplines/education , Physiology/education , Teaching Materials , Teaching , Adrenocorticotropic Hormone/physiology , Aldosterone/history , Angiotensin II/analysis , Biological Assay/methods , Biological Science Disciplines/history , Education, Medical, Undergraduate , Feedback, Physiological , History, 20th Century , Humans , Hypothalamo-Hypophyseal System/physiology , Physiology/history , Problem-Based LearningABSTRACT
The paper describes the impact of mineralocorticoid substances on water regulation from Theophrastus (IV century B.C.) to Thomas Addison (1849). It also opens to the missed discovery of aldosterone of I.A. Macchi.
Subject(s)
Aldosterone/history , Aldosterone/chemistry , Aldosterone/isolation & purification , Aldosterone/physiology , Body Water/metabolism , History, 19th Century , History, 20th Century , Potassium/metabolism , Sodium/metabolismSubject(s)
Cardiology/history , Aldosterone/history , History, 20th Century , Humans , Hypertension/history , United StatesABSTRACT
This paper has a focus on the early history of aldosterone. The Taits take us on a chronological trawl through the history in which they had a first hand role and made a major contribution-their bioassay was in many ways the key. The gifted Swiss chemists made a critical contribution to the scale and isolation of larger amounts. This was international collaboration at its best. Developing technologies were utilised as crucial cutting edge applications in the advancing front, technology transfer before the word was invented. Measurement of aldosterone and angiotensin were crucial advances to the understanding of the regulation of the hormone. In the period 1960-2003, some 30,000 papers mentioned aldosterone as a keyword, even so advances on a larger scale were slow. I have indicated some of my own work with the Howard Florey team using the adrenal autotransplant in the conscious sheep. Recently, the understanding of the role of induced proteins, the flow on from the RALES trial and the development of eplerenone has revitalised the aldosterone field.
Subject(s)
Aldosterone/metabolism , Spironolactone/analogs & derivatives , Spironolactone/metabolism , Aldosterone/analysis , Aldosterone/history , Aldosterone/isolation & purification , Angiotensins/analysis , Angiotensins/history , Angiotensins/metabolism , Biological Assay/history , Biological Assay/methods , Clinical Trials as Topic/history , Eplerenone , History, 20th Century , Humans , Proteins/metabolism , Spironolactone/chemistry , Spironolactone/history , Spironolactone/isolation & purification , Technology, Pharmaceutical/historyABSTRACT
Since the isolation and purification of aldosterone from adrenal extracts 50 years ago (Experientia 9 (1953) 33), scientists have learned a great deal about how and where aldosterone acts, the factors that control its release, what is its role in the pathophysiology of cardiovascular disease, how to make and study aldosterone antagonists, and for what medical purposes these agents are useful. In this paper, we will discuss the evolution of aldosterone antagonists from the relatively nonselective spironolactone (Aldactone), to the highly selective eplerenone (Inspra). Eplerenone represents a molecule with improved steroid receptor selectivity and pharmacokinetic properties in man compared to spironolactone. Recent clinical results have demonstrated that these improvements translate into tolerability and efficacy in patients with cardiovascular disease.
Subject(s)
Mineralocorticoid Receptor Antagonists , Spironolactone/analogs & derivatives , Aldosterone/history , Aldosterone/metabolism , Animals , Cardiovascular Diseases/drug therapy , Cardiovascular Diseases/metabolism , Clinical Trials as Topic , Eplerenone , Gynecomastia/drug therapy , Gynecomastia/metabolism , History, 20th Century , Humans , Mineralocorticoid Receptor Antagonists/chemical synthesis , Mineralocorticoid Receptor Antagonists/history , Mineralocorticoid Receptor Antagonists/pharmacokinetics , Mineralocorticoid Receptor Antagonists/therapeutic use , Spironolactone/chemical synthesis , Spironolactone/history , Spironolactone/pharmacokinetics , Spironolactone/therapeutic useABSTRACT
The circulating renin-angiotensin system is a major regulator of the secretion of the adrenocortical hormone, aldosterone. This renin-angiotensin aldosterone system is important in the control of salt and water balance and blood pressure. This review describes the historical background leading to the discovery of aldosterone in the 1950s and the recognition in the 1960s that angiotensin II was involved in its control. Although angiotensin II is important in the regulation of aldosterone secretion, its action is influenced by multiple other factors, especially potassium and atrial natriuretic peptide. In addition to the circulating renin-angiotensin system, a local renin-angiotensin system is present in the zona glomerulosa cell. This local system also appears to be involved in the regulation of aldosterone production. The mechanism by which angiotensin II stimulates the adrenal zona glomerulosa cell is described in some detail. Angiotensin II interacts with the angiotensin receptor (AT1) membrane receptor that is coupled to cellular second messengers. Specific AT1 receptor antagonists are now clinically used to block angiotensin II's action on various target organs, including the adrenal gland.
