[Biogenic amines in endocrine cells producing polypeptide hormones. The APUD-cells (Pearse) (author's transl)]

The endocrine cells of the digestive system: amines, peptides, and modes of action

The endocrine cells of the digestive system (entero-endocrine cells of gastro-intestinal epithelia and Langerhans' islets of the pancreas) and the chemical messengers produced by them constitute a complicated and complex system. The physiological function of this system is the regulation of all processes related to digestion and resorption, and to homeostasis of carbohydrate metabolism. Using morphological and histochemical features of this cellular community, the present review deals with amines and amine metabolism, polypeptides and their immunohistochemical identification, and with the modes of action of enteric and pancreatic hormones. Special attention is paid to the significance of amine precursor uptake and decarboxylation (APUD), to immunohistochemical methodology and the interpretation of immunohistochemical findings, and to local regulatory mechanisms, especially paracrinia. Finally, unifying concepts for the integration of these cells and similar endocrine cells of other organs into a common system are considered.

[The endocrine cells of the digestive system (author's transl)]

Endocrine cells occur in the digestive system as micro-organs (islets of Langerhans) or scattered throughout the epithelium of the gastrointestinal tract ("diffuse endocrine epithelial organ" of Feyrter). These gastro-entero-pancreatic (GEP) endocrine cells synthesize--in addition to serotonin--a great variety of polypeptide hormones, which regulate both carbohydrate metabolism and digestive processes. The present review deals mainly with cytology and cytochemistry of GEP endocrine cells. A synopsis is presented of the 19 endocrine cell types identified to date, which includes their update nomenclature and their anatomical distribution pattern. Morphological-functional aspects of cell biology, pathology, and cytogenesis of theses cells and their position within superimposed systems (APUD cells, paraneurons) are discussed.

The distribution and endocrine nature of the abdominal paraganglia of adult man

The paraganglia of adult man were studied using the formaldehyde-induced fluorescence (FIF) method for histochemical characterization of biogenic monoamines. Microspectrofluorimetry was used to record the emission spectra and fluorescence intensities of the paraganglionic cells. The study of samples from six patients showed that well vascularized paraganglia were widely distributed throughout the retroperitoneal spaces. The paraganglia exhibited strong FIF with the spectral characteristics of monamines. Treatment with HC1 caused an increase in the fluorescence intensity of the paraganglia and a simultaneous shift of the emission maximum from 480--495 nm. This change suggests the presence of high concentrations of tryptophyl-containing peptides and is not due to monoamines. The possibility of a dual endocrine function for the paraganglia is discussed.

Differentiation of two types of endocrine cells which take up amine precursors using their capacity to take up the fluorescent dihydroisoquinoline derivative of dopamine

A study was made of the accumulation of the strongly fluorescent 2-carboxymethyl-6,7-dihydroxy-3,4-dihydroisoquinolinium compound (2-Carb. Me-DIQ) derived from the condensation reaction of dopamine with glyoxylic acid in endocrine cells possessing the capacity to take up and store biogenic monoamine precursors. Thin-layer chromatographic studies of urine showed that 2-Carb. Me-DIQ was metabolized into two strongly fluorescent metabolites, possessing at least one hydroxyl group in the phenol moiety of the molecule, which were excreted in urine together with the parent compound. Histochemical observations, however, indicated that the tissue fluorescence showing maximal emission at 480 nm was due to 2-Carb. Me-DIQ. Generally, the injection of 2-Carb. Me-DIQ induced a strong fluorescence in those tissue components possessing the extraneuronal uptake mechanism of catecholamines. In the endocrine cells strong fluorescence was seen in the pineal glandular cells and in some cells of the pars distalis of the hypophysis, of which some cells also took up DL-5-HTP, as was seen following formaldehyde vapour treatment. No accumulation of 2-Carb. Me-DIQ was observed in the pancreatic islet cells, the C cells of the thyroid gland or the tracheal enterochromaffin-like cells. These findings lead to the conclusion that biogenic monoamines in the cells of the pars distalis of the hypophysis might use the phenolic moiety of the molecule to bind to some intracellular receptor. Thus, the pars distalis cells may have an intracellular binding mechanism for biogenic monoamines that is different from other endocrine cells showing the uptake and storage of biogenic monoamines. On the other hand, the findings gave further support to the suggestion that in the pancreatic islet cells, the thyroidal C cells and the tracheal enterochromaffin-like cells biogenic monoamines are stored by a mechanism in which the basic, positively charged amino group of biogenic monoamines is bound electrostatically to the anionic, negatively charged carboxyl group of a hormone storage granule. The pars distalis cells and the pineal glandular cells seemed to take up amines and amine derivatives in a similar manner. This suggests that in the pars distalis cells, too, biogenic monoamines have an active metabolism and possibly some regulative role in hormone synthesis and/or secretion.