Intercellular communication in pancreatic islet monolayer cultures: a microfluorometric study

Glucose-induced insulin release depends on functional cooperation between islet cells

Similar to other endocrine glands, the endocrine pancreas displays a characteristic topography of its constituent cells. The functional significance of this structural organization was examined by measuring the secretory activity of the B cell in rat islet cell preparations of different composition. Glucose released 30-fold more insulin from B cells lodged within intact islets as from purified single B cells; structurally coupled B cells and single B cells isolated with A cells or incubated with glucagon responded 4- and 2-fold, respectively, more effectively to glucose than single B cells alone. Glucose homeostasis is thus dependent not only on the number and integrity of the insulin-containing B cells but also on their interactions with neighboring B and non-B cells. This study provides direct support for the concept that the microanatomy of the islet creates the anatomical basis for functional cooperation between islet cells and hence for an appropriate glucose-induced insulin release.

Difference in calcium dependency of insulin, glucagon and somatostatin secretion in response to glibenclamide in perfused rat pancreas

The extracellular calcium requirements for insulin, glucagon and somatostatin release induced by 1 microgram/ml of glibenclamide have been compared in the perfused, isolated rat pancreas. In the absence of glucose, the drug evoked insulin release equally well at physiological (2.6 mmol/l) and low (0.25 mmol/l) levels of total calcium. In contrast, glibenclamide evoked somatostatin release at 2.6 but not at 0.25 mmol/l of calcium. At 2.6 mmol/l of calcium, glibenclamide evoked bimodal effects (stimulation followed by inhibition) on glucagon secretion. At 0.25 mmol/l of calcium, basal secretory rates of glucagon were elevated and a small stimulatory effect of glibenclamide was seen. Addition of 0.5 mmol/l of EGTA to media with low calcium concentrations uniformly abolished the A, B and D cell secretory responses to glibenclamide. The possible modulation of calcium dependency by a non-stimulatory concentration of glucose was tested by its addition at 3.3 mmol/l to the perfusion media. Glucose enhanced glibenclamide-induced insulin secretion, both at 0.25 and 2.6 mmol/l of calcium. However, at 0.25 mmol/l of calcium, the enhancing effect of glucose was more pronounced than at 2.6 mmol/l. At 2.6 mmol/l of calcium, glucose diminished the somatostatin and abolished the glucagon response to glibenclamide. At 0.25 mmol/l of calcium, glucose did not influence somatostatin release while the presence of the sugar diminished basal and glibenclamide-induced glucagon secretion. The present data confirm the requirement of extracellular calcium for A, B and D cell secretion, demonstrating different calcium dependencies for the cell types and indicate that this dependency can, in part, be modulated by glucose.

Functional differences between rat islets of ventral and dorsal pancreatic origin

Do functional linkages between islet endocrine cells exist? The effect of differences in frequency and distribution of islet endocrine cells on B cell function was examined in islets from the ventral (ventral islets) and dorsal (dorsal islets) areas of the rat pancreas. Dorsal islets contained 10 times as much glucagon as ventral islets, whereas insulin and total protein contents were similar. Basal rates of insulin secretion and proinsulin biosynthesis were similar in the two types of islet, but, under conditions of glucose stimulation, both insulin secretion and proinsulin biosynthesis were significantly greater in the glucagon-rich dorsal islets. Similarly, glucose utilization rates an ATP levels were greater in dorsal islets. In contrast, the rates of processing of newly synthesized proinsulin were similar in ventral and dorsal islets. That the islet glucagon content may have affected B cell function is inferred from two independent findings. Firstly, basal and glucose-stimulated cyclic AMP contents of glucagon-rich dorsal islets were greater than those of ventral islets. Secondly, in the presence of excess exogenous glucagon (1 microgram/ml), the differences in glucose-induced insulin secretion and proinsulin biosynthesis rates between the two types of islets were eliminated. These results strongly suggest that changes in the relative proportions of the different islet endocrine cells exert marked effects on islet function. In particular, a greater A cell and glucagon content is associated with higher rates of glucose-induced insulin secretion and biosynthesis.

Direct communication of homologous and heterologous endocrine islet cells in culture

The transfer of 6-carboxyfluorescein between islet cells in monolayer culture was observed by fluorescence microscopy, and the endocrine cells involved in this transfer were identified by immunohistochemistry and electron microscopy. The results show that carboxyfluorescein was directly exchanged between homologous B-cells and also between B- and A- or D-cells. Successive microinjections of the probe into different cells of the same cluster showed the existence of separate territories, each formed by 2-8 communicating cells. Intercellular communication was not observed after every dye microinjection, and communicating and noncommunicating islet cells were found to coexist within the same cluster. The data indicate that the exchange of exogenous cytoplasmic molecules occurs between different types of endocrine islet cells. However, within a single cluster, all islet cells are not metabolically coupled to one another, at a given time.

Islets of Langerhans: dye coupling among immunocytochemically distinct cell types

Cells in isolated rat islets of Langerhans were microinjected with Lucifer Yellow CH in a medium containing 16.7 millimolar glucose. Dye was rapidly transferred from the injected cell to neighboring islet cells without specificity with regard to the immunocytochemical identity of either the donor or the recipient cells. The transfer of dye between the islet cells (types A, B, and D) demonstrates homologous and heterologous cell coupling in a system where the normal proportions and relationships of the cell types are maintained.

A method for the purification of single A, B and D cells and for the isolation of coupled cells from isolated rat islets

A method has been developed for the purification of single A, B and D cells and for the isolation of coupled islet cells. Isolated rat islets were dissociated by repeated pipetting in the presence of trypsin and ethylene glycol bis (beta-aminoethyl ether) N,N' tetra-acetic acid (EGTA), and then filtered through nylon and Percoll; the cell preparation consisted of 70% single and 30% coupled cells. Sizing of the cells led to the recognition of a small-islet cell population (35%; cell volume 200-600 micrometer 3) composed of A and D cells, and a large-islet cell population (65%; cell volume 600-1500 micrometer 3) identified as B cells. Differences in sedimentation velocity formed the basis for the islet cell separation by counterflow elutriation. Single islet cells eluted prior to coupled cells and were distributed over A and D cell-enriched fractions I and II (65% A, 25% B, 10% D) and the B cell-enriched fraction III (93% B). The slightly different densities of A (d = 1.068), B (d = 1.065) and D (d = 1.070) cells allowed a subsequent purification by density gradient centrifugation resulting in a final 10- to 30-fold enrichment in either A, B or D cells. Most coupled islet cells were recovered in fraction IV, occurred mainly as doublets and were composed of 90% B cells and 7% D cells; the multiple pseudopods, which characterize isolated D cells, might contribute to the coupling tendency of the D cells. It is concluded that the purified A, B and D cell fractions and the coupled islet cell preparations offer a direct approach to the study of individual islet cell types and their intercellular communication.

Previous exposure to glucose enhances somatostatin secretion from the isolated perfused rat pancreas

Previous exposure to glucose enhances insulin and depresses glucagon secretion by the pancreas. We have investigated whether secretion of somatostatin is also influenced by a glucose priming effect. In perfused rat pancreas from 36 h fasted rats a 5 min pulse of arginine (8 mmol/l) rapidly elicited a peak of somatostatin release. A similar somatostatin response was evoked by a second, identical, pulse of arginine after perfusion with "basal" glucose (3.9 mmol/l) for 45 min. On the other hand when 27.7 mmol/l D-glucose, was administered for 20 min between arginine pulses, there was significant stimulation of somatostatin secretion. When arginine was re-introduced 15 min after the cessation of the pulse of elevated glucose the magnitude of the arginine-induced peak (min 0-2 of stimulation) was increased from 16.2 +/- 4.1 to 33.1 +/- 4.7 pg/2 min, p less than 0.01, relative to the first stimulation with arginine. None of these effects of glucose could be reproduced by D-galactose. The somatostatin response to arginine was higher in pancreata from fed than from 36 h fasted animals as was also basal release (22.8 +/- 5.0 vs 9.0 +/- 2.0 pg/min). In the fed state the response to the second pulse of arginine was however reduced by 50% after perfusion with "basal" glucose. This decrease in responsiveness was counteracted by perfusion with 27.7 mmol/l glucose for 20 min between the arginine pulses. It is concluded that previous exposure to an elevated concentration of glucose enhanced D-cell responsiveness to arginine in the fasted as well as the fed state.

Tetraethylammonium modifies gap junctions between pancreatic beta-cells

Gap junctions between pancreatic beta-cells were quantitatively assessed in freeze-fracture replicas of isolated rat islets of Langerhans incubated for 90 min with or without the potassium conductance blocker tetraethylammonium (TEA). The results show that TEA increases the median number of particles per beta-cell gap junction but not the frequency of gap junctions at both nonstimulating and threshold-stimulating concentrations of glucose. TEA increased the relative gap junctional area at both concentrations of glucose. TEA had no effect on insulin release at a basal concentration of glucose but potentiated that release at the threshold glucose level. Thus TEA modifies beta-cell gap junctions independently of its effect on insulin release. However, the junctional changes observed were greater when insulin release was also elevated.

The pancreatic islets in diabetes

Despite the fact that heterogeneity of diabetes in man has become more and more evident in recent years, its pancreatic pathology is still represented by two distinct entities, roughly corresponding to the classic juvenile-onset and maturity-onset types of the disease. In juvenile-onset, insulin-dependent diabetes, the pancreatic islets show severe and pathognomonic changes. B cells are greatly reduced in number already at clinical onset. Contrary to classic opinion they do not always disappear in the years to follow. Insulitis, a common finding in the pancreas of recent onset juvenile diabetic subjects, is compatible with a viral infection as well as with an autoimmune reaction as the cause of B cell destruction. In the pancreas of juvenile-onset diabetic subjects the islets, which in the past have been regarded as atrophic and inactive, are actually composed of cells containing glucagon and somatostatin. There is also a profound distortion of islet organization, and many endocrine cells are scattered as single cells in the exocrine tissue. These findings may well account for the abnormal secretory behavior of the glucagon-secreting A cells in insulin-dependent juvenile-onset diabetes. In maturity-onset, noninsulin-dependent diabetes, the pancreatic pathology is extremely variable and not pathognomonic. A numeric reduction of the B cells can be demonstrated in many maturity-onset diabetic subjects, but this reduction is much more moderate than in insulin-dependent juvenile-onset diabetic subjects and does not account for the disease. The same amount of B cell reduction can be found in many elderly subjects without clinical evidence of diabetes. In many maturity-onset diabetic subjects, the cytologic characteristics of the B cells suggest a decreased responsiveness to the stimulus of hyperglycemia. Islet fibrosis and hyalinosis (amyloidosis), although common, cannot explain this secretory dysfunction. The exact site of the defect in the B cells of maturity-onset diabetic subjects remains to be defined. Further investigations are necessary to assess the role of disturbed intraislet intercellular relationships in the pathogenesis of late-onset diabetes. The dual pattern of islet pathology in diabetes in man does not preclude a more profound heterogeneity in the etiology and pathogenesis of the disease.

Tissue culture in nephrology: potential and limits for the study of renal disease

Kidney cells, when isolated and cultivated in vitro, retain differentiated renal properties. Glomerular epithelial and mesangial cells from animal and human kidneys express their normal ultrastructure and the ability for basement membrane biosynthesis. Mesangial cells in culture have been utilized particularly for the study of hormonal tissue receptors, of prostaglandin production, and of their contractile response to various hormonal stimuli. Cells of tubule origin have been a valuable tool for the study of transport mechanism which, as a consequence of the heterogeneity of nephron functions, can not be assessed in vivo. Ion transport and its structural basis, as well as transport regulation by hormones has been studied in established epithelial cell lines. Induction of ion transport and enzyme activities, and the control of cell proliferation and differentiation has also been succesfully evaluated in cultured epithelia derived from the kidney. Future work will attempt to prepare cell lines from defined nephron segments to study chemical and physical phenomena of renal disease.

Gap junction development is correlated with insulin content in the pancreatic B cell

The development of gap junctions between insulin-containing B cells was quantitatively analyzed in islets of Langerhans isolated from rats treated with the sulfonylurea glibenclamid for 1, 2, or 7 days. Glibenclamid treatment was associated with a marked depletion of the insulin content of B cells and with an increase in the number and size of gap junctions between these cells. A significance correlation was found between these two events.

Multichannel analysis of intracellular control and intercellular transfer of molecules

The metabolic regulation and exchanges within intracellular organelles or a cell cluster are studied by multichannel microfluorometry and microinjection of metabolites or tracers. The determination of structure-function relationships relies on the retrieval of cells after microfluorometry, for subsequent morphological evaluation. Rate constants of coenzyme reduction-reoxidation were deduced from a mathematical model of NAD(P) in equilibrium with NAD(P)H transients due to microinjection of metabolites into cultured cells belonging to a variety of normal or malignant lines. Nuclear and cytoplasmic sites operate synchronously or not, depending upon metabolic demand or pathological alterations. Intercellular transit times are determined for tracers and metabolites. Within cell clusters 'communicating territories' are described, which can show metabolically a multicellular integrated state. Microfluorometry in conjunction with ultrastructural and other studies can be used to develop a cybernetic model of the living cell, also yielding dynamic models of cooperative and regulatory interactions between different kinds of specialised cells within a cell cluster.

Nonrandom distribution of gap junctions between pancreatic beta-cells

The numerical and spatial distribution of gap junctions between insulin-containing cells (beta-cells) under resting and stimulated conditions of insulin secretion were quantitatively analyzed in freeze-fracture replicas of isolated rat islets of Langerhans. The results show that the beta-cells located at the periphery of the islet have twice as many gap junctions per unit membrane area as the beta-cells situated in the islet center. In both locations, gap junctions assumed a nonrandom clustering on the beta-cell membranes. During stimulation of insulin secretion, the gap junctions were found increased between the central and between the peripheral beta-cells. The degree of their clustering was also modified. The latter change depended both on the location of the gap junctions in the islet and on the type of stimulation used (high glucose or glibenclamide).