Connexins and secretion

Connexin channels clustered at gap junctions are obligatory attributes of all macroscopic endocrine and exocrine glands investigated so far and also connect most types of cells which produce secretory products in other tissues. Increasing evidence indicates that connexins, and the cell-to-cell communications that these proteins permit, contribute to control the growth of secretory cells, their expression of specific genes and their differentiated function, including their characteristic ability to biosynthetize and release secretory products in a regulated manner. Since the previous reviews which have been published on this topic, several lines of evidence have been added in support of multiple regulatory roles of gland connexins. Here, we review this novel evidence, point to the many questions which are still open and discuss some interesting perspectives of the field.     

Involvement of gap junctional communication in secretion

Glands were the first type of tissues in which the permissive role of gap junctions in the cell-to-cell transfer of membrane-impermeant molecules was shown. During the 40 years that have followed this seminal finding, gap junctions have been documented in all types of multicellular secretory systems, whether of the exocrine, endocrine or pheromonal nature. Also, compelling evidence now indicates that gap junction-mediated coupling, and/or the connexin proteins per se, play significant regulatory roles in various aspects of gland functions, ranging from the biosynthesis, storage and release of a variety of secretory products, to the control of the growth and differentiation of secretory cells, and to the regulation of gland morphogenesis. This review summarizes this evidence in the light of recent reports.     

The role of gap junction membrane channels in secretion and hormonal action

Connexins, gap junctions, and coupling are obligatory features of both endocrine and exocrine glandular epithelia. Evidence from these two types of tissues, and particularly from pancreatic islets and acini, indicates that cell-to-cell communication via gap junction channels is required for proper biosynthesis, storage, and release of specific secretory products. However, endocrine and exocrine glands express a different set of connexins and show opposite connexin and coupling changes in relation with the activation and inhibition of their secretory function. Also, several hormones modulate connexin and coupling expression, and junctional coupling affects hormonal stimulation. These observations indicate that gap junction channels play an important role in the control of secretion and hormonal action.     

Cx36 and the function of endocrine pancreas

The secretory, duct, connective and vascular cells of pancreas are connected by gap junctions, made of different connexins. The insulin-producing beta-cells, which form the bulk of endocrine pancreatic islets, express predominantly Cx36. To assess the function of this connexin, we have first studied its expression in rats, during sequential changes of pancreatic function which were induced by the implantation of a secreting insulinoma. We observed that changes in beta-cell function were paralleled by changes in Cx36 expression. We have also begun to investigate mutant mice lacking Cx36. The absence of this protein did not affect the development and differentiation of beta-cells but appeared to alter their secretion. We have studied this effect in MIN6 cells which spontaneously express Cx36. After stable transfection of a construct that markedly reduced the expression of this connexin, we observed that MIN6 cells were no more able to secrete insulin, in contrast to wild type controls, and differentially displayed a series of still unknown genes. The data provide evidence that Cx36-dependent signaling contributes to regulate the function of native and tumoral insulin-producing cells.     

Electron microscopic identification of the histamine-storing argyrophil (enterochromaffin-like) cells in the rat stomach

Summary In the oxyntic gland area of the rat stomach the histamine-containing epithelial cells (also referred to as enterochromaffin-like cells because of their morphologic similarity with the 5-hydroxytryptamine-storing enterochromaffin cells) constitute the system of argyrophil cells in this area as previously shown by the combined use of fluorescence and light microscopic techniques. By performing the argyrophil staining reaction directly on ultra-thin sections it could be demonstrated in the electron microscope that the argyrophil cells have features suggesting that they are endocrine. Based on the ultrastructure of their secretory granules at least two such endocrine cell systems—both argyrophil—could be recognized in the oxyntic glands. The silver deposits were accumulated over the secretory granules of both these cell systems.It is well known that after injection of 1-3,4-dihydroxyphenylalanine, the histamine-storing (enterochromaffin-like) cells of the oxyntic glands store also dopamine. Under these conditions the enterochromaffin-like cells stain argentaffin, which has been shown at the light microscopic level. Also this reaction could be performed directly on ultra-thin sections. By electron microscopy it was then established that the two endocrine cell systems of the oxyntic gland area stained argentaffin upon treatment with 1-3,4-dihydroxyphenylalanine, and that the staining was confined to the secretory granules.The results clearly show that the enterochromaffin-like cells of the rat oxyntic gland area (which is devoid of 5-hydroxytryptamine-containing enterochromaffin cells) are identical with cells characterized as endocrine by ultrastructural criteria, and that gastric non-mast-cell histamine occurs in at least two separate systems of enterochromaffin-like cells.     

Connexin-dependent signaling in neuro-hormonal systems

The advent of multicellular organisms was accompanied by the development of short- and long-range chemical signalling systems, including those provided by the nervous and endocrine systems. In turn, the cells of these two systems have developed mechanisms for interacting with both adjacent and distant cells. With evolution, such mechanisms have diversified to become integrated in a complex regulatory network, whereby individual endocrine and neuro-endocrine cells sense the state of activity of their neighbors and, accordingly, regulate their own level of functioning. A consistent feature of this network is the expression of connexin-made channels between the (neuro)hormone-producing cells of all endocrine glands and secretory regions of the central nervous system so far investigated in vertebrates. This review summarizes the distribution of connexins in the mammalian (neuro)endocrine systems, and what we know about the participation of these proteins on hormone secretion, the life of the producing cells, and the action of (neuro)hormones on specific targets. The data gathered since the last reviews on the topic are summarized, with particular emphasis on the roles of Cx36 in the function of the insulin-producing beta cells of the endocrine pancreas, and of Cx40 in that of the renin-producing juxta-glomerular epithelioid cells of the kidney cortex. This article is part of a Special Issue entitled: The Communicating junctions, composition, structure and characteristics.     

Quantitative characteristics of the endocrine cells of the duodenal glands of Carnivora

In the duodenal glands of the Carnivora investigated endocrine elements have been revealed, a part of them is presented as serotonin-producing EC-cells. Endocrine cells are situated in terminal parts and in glandular ducts, among them elements of open and close types are distinguished. Distribution of these cells in the glandular lobules is subjected to the distal gradient regularity, specific for the gastrointestinal tract mucosal membrane. Amount of endocrinocytes in the glands is much less than in the gut crypts. There is no correlation between distribution of the endocrine cells in the glands and in the crypts. The results of unifactor analysis of variance demonstrate a slight effect of the taxonomic position of the species on the number of endocrine cells in the duodenal glands. The proper endocrine apparatus of the duodenal glands is supposed to produce a local regulatory influence on the secretory activity of exogenic glandulocytes, as well as ensure humoral connections of the duodenal glands with other parts of the gastrointestinal tract.     

Regulatory peptide involvement in the reproductive biology of flatworm parasites

Summary

Parasites are invariably characterized by a prodigious egg output and channel much of their metabolic activity towards reproduction. While certain aspects of reproduction, such as gametogenesis and egg formation, have received attention, surprisingly little is known about the mechanisms regulating reproductive physiology and behaviour. It is likely that these mechanisms will involve neuropeptides because, in the absence of endocrine glands and a circulatory system, it is the secretory (peptidergic) component of the nervous system that will serve as an endocrine system. The last few years have witnessed a growing awareness of the range of peptidergic molecules produced by parasites, a diversity that overshadows the number of transmitters produced by the conventional nervous system. Neuropeptides are distributed throughout the CNS; in addition, peptidergic elements occur in those components of the PNS that innervate the gonads and muscularised ducts of the male and female reproductive systems. Peptidergic cells are also associated with the eggforming chamber, or ootype, and the implications of this for the control of egg formation and as a possible target for chemotherapy are discussed.     

Utilizing endocrine secretory pathways in salivary glands for systemic gene therapeutics

Mammalian salivary glands are commonly used models of exocrine secretion. However, there is substantial experimental evidence showing the physiological existence of endocrine secretory pathways in these tissues. The use of gene transfer technology in vivo has allowed the unambiguous demonstration of these endocrine pathways. We and others have exploited such findings and evaluated salivary glands as possible target tissues for systemic applications of gene therapeutics. Salivary glands present numerous advantages for this purpose, including being well encapsulated, which limits extra-glandular vector dissemination, and having the luminal membranes of almost all parenchymal cells accessible via intraoral delivery of vectors through the main excretory ducts. Existing studies suggest that clinical benefits will result from salivary gland targeted systemic gene therapeutics.     

The 1989 Upjohn Award lecture. Cellular and molecular mechanisms in hormone and neurotransmitter secretion

Studies on adrenal medulla have had an important influence on the development of a variety of biological concepts, not only within the area of endocrinology, but also in the areas of chemical neurotransmission and secretion in general. The adrenal medulla chromaffin cells are derived embryologically from the neural crest, sharing a common origin with sympathetic neurons and common subcellular features with many endocrine cells. One such feature is the storage of secretory products in membrane-bound organelles, the secretory granules. Secretory cells with these characteristics have been named paraneurons, a term that embraces cells generally and traditionally not considered as neurons, and yet should be regarded as relatives of neurons on the basis of their structure, function, and metabolism. Many of the studies carried out in the past to understand the secretory process have employed perfused adrenal glands. Although this technique has provided very useful information regarding secretion, it did not allow the study of the cellular events involved in the secretory process. To obtain further information on cell secretion, several laboratories including our own have published methods for the isolation and culture of chromaffin cells. The cultured chromaffin cells have shown themselves to be one of the most useful systems developed for the study of the neuroendocrine functions of paraneurons. Studies on cultured chromaffin cells have provided important information on secretory cell cytoskeleton: a group of proteins, some of them previously known from studies on muscle, which form a cytoplasmic network in all non-muscle cells including secretory cells. Immunohistochemical studies have shown at least three types of filament systems: microfilaments, microtubules, and intermediate filaments. In addition, a large variety of cytoskeleton-associated proteins have been characterized. Chromaffin cells are among those non-muscle cells from which cytoskeleton proteins have been isolated and characterized. Owing to similarities between "stimulus-secretion coupling" and "excitation-contraction coupling" in muscle, it has been proposed that the secretory process might be mediated by contractile elements either associated with secretory vesicles or present elsewhere in the secretory cell. Cytoskeletal proteins (actin, myosin, alpha-actinin, fodrin, tubulin, and neurofilament subunits) and their regulatory proteins (calmodulin, gelsolin) have been isolated from chromaffin cells and characterized. Their physiochemical proteins have been studied and their cellular localizations have been revealed by biochemical, immunocytochemical, and ultrastructural techniques. alpha-Actinin and fodrin are components of chromaffin granule membranes and some of the cell actin co-purified with secretory granules. Actin forms a network of microfilaments in the subplasmalemma region.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pathways and control of connexin oligomerization

Connexins form gap junction channels that link neighboring cells into an intercellular communication network. Many cells that express multiple connexins produce heteromeric channels containing at least two connexins, which provides a means to fine tune gap junctional communication. Formation of channels by multiple connexins is controlled at two levels: by inherent structural compatibilities that enable connexins to hetero-oligomerize and by cellular mechanisms that restrict the formation of heteromers by otherwise compatible connexins. Here, I discuss roles for secretory compartments beyond the endoplasmic reticulum in connexin oligomerization and evidence that suggests that membrane microdomains help regulate connexin trafficking and assembly.     

Endocrine cells in the cardial glands of the esophagus in man

Distribution of endocrine cells in composition of the secretory epithelium of the cardial glands of the human esophagus in both sex and at various age has been investigated. In spiral paraffin slices the endocrine cells have been revealed by means of different silver impregnation methods (after Grimelius, Masson--Hamperl, Sevier--Munger), Sevke technique, ferry-ferrocyanide method. Some cells have been revealed, which according to the specific signs of their granule staining resemble very much G-, EC-, ECL-cells of the stomach. They can be triangular, flatten or polygonal and are stained in the cardial gland epithelium as single diffuse cells, or as groups of cells. Staining of the slices with aldehyde-fuchsin in various modifications reveals dark cells with dark-violet granules and lighter cells with acidophilic granules. Sometimes among these cells certain cells with light-violet cytoplasm are revealed. All these cells can be arranged both in composition of the secretory epithelium of the glands and in conglomerates of cells, resembling pancreatic islands. According to their tinctorial properties they resemble A-, B-, D-cells of these islands.     

Occurrence and morphometry of the hypopharyngeal glands inScaptotrigona postica Lat. (Hymenoptera, Apidae, Meliponinae)

As compared toApis mellifera where only workers have hypopharyngeal glands, inScaptotrigona postica, these glands occur in workers, queens and males. They are composed of two long axial ducts with many unicellular secretory alveoli interconnected by secretory canaliculi. The axial ducts are longer in males than in workers, but the alveolar areas of queens and males are generally smaller. In workers the alveoli have their greatest size in the nurses or middle-aged individuals while in queens and males they are larger in newly emerged individuals. The results indicate that the glands in workers may produce food for the brood as inA. mellifera, since they are well developed in the nurse workers. However, the function of the glands in queens and males remains to be clarified since these individuals have no part in brood care.     

Ultrastructure, histological distribution, and freeze-fracture immunocytochemistry of gap junctions in rat brain and spinal cord

The historical development of concepts of gap junctions as sites for electrical, ionic, and metabolic coupling is reviewed, from the initial discovery of gap junctions linking heart cells, to the current concepts that gap junctions represent 'electrotonic synapses' between neurons. The ultrastructure and immunocytochemistry of gap junctions in heart, brain, and spinal cord of adult rats is examined using conventional thin sections, negative staining, grid-mapped freeze-fracture replicas, and immunogold-labeled freeze-fracture replicas. We review evidence for neuronal gap junctions at 'mixed' (combined electrical and chemical) synapses throughout adult rat spinal cord. We also show immunogold labeling of connexin43 in astrocyte and ependymocyte gap junctions and of connexin32 in oligodendrocyte gap junctions. Ultrastructural and freeze-fracture immunocytochemical methods have provided for definitive determination of the number, size, histological distribution, and connexin composition of gap junctions between neurons in all regions of the central nervous systems of vertebrate species.     

Chromogranin A is present in and released by fish endocrine tissue

Chromogranin A (CgA) is a protein that is present in many mammalian endocrine cells and co-secreted with their resident hormones. We have demonstrated the presence of CgA by immunohistology in the ultimobranchial glands and corpuscles of Stannius of rainbow trout. CgA was also detected by radioimmunoassay in the medium of incubated coho salmon ultimobranchial glands. Our observations demonstrate the presence of CgA in endocrine glands of evolutionarily divergent species. These observations are consistent with the hypothesis that CgA participates in the secretory process of a wide variety of hormones.     

Coping with excess salt: adaptive functions of extrarenal osmoregulatory organs in vertebrates

In all organisms, changing environmental conditions require appropriate regulatory measures to physiologically adjust to the altered situation. Uptake of excess salt in non-mammalian vertebrates having limited or no access to freshwater is balanced by extrarenal salt excretion through specialized structures called ‘salt glands’. Nasal salt glands of marine birds are usually fully developed in very early stages of their lives since individuals of these species are exposed to salt soon after hatching. In individuals of other bird species, salt uptake may occur infrequently. In these animals, glands are usually quiescent and glandular cells are kept in a fairly undifferentiated state. This is the situation in ‘naive’ ducklings, Anas platyrhynchos, which have never been exposed to excess salt. When these animals become initially osmotically stressed, the nasal glands start to secrete a moderately hypertonic sodium chloride solution but secretory performance is meager. Within 48 h after the initial stimulus, however, the number of cells per gland is elevated by a factor of 2–3, the secretory cells differentiate and acquire full secretory capacity. During this differentiation process, extensive surface specializations are formed. The number of mitochondria is increased and metabolic enzymes and transporters are upregulated. These adaptive growth and differentiation processes result in a much higher efficiency of salt excretion in acclimated ducklings compared with naive animals. Receptors and signal transduction pathways in salt gland cells controling the adaptive processes seem to be the same as those controling salt secretion, namely muscarinic acetylcholine receptors and receptors for vasoactive intestinal peptide. This review focusses on signal transduction pathways activated by muscarinic receptors which seem to fine-tune salt secretion in salt-adapted ducklings and may control adaptive growth and differentiation processes in the nasal gland of naive animals.     

Role of gap junctions in fluid secretion of lacrimal glands

In glands such as the liver and pancreas, gap junctions containing connexin 26 and 32 (Cx26 and Cx32, respectively) couple the secretory cells. Uncoupling these junctions compromises the secretory function of these glands. Lacrimal glands also contain extensive arrays of gap junctions consisting of Cx26 and Cx32. We wanted to determine the role of these junctions in fluid secretion. In Cx32-deficient mice, immunocytochemistry showed that, in the male lacrimal gland, the remaining Cx26 was found evenly distributed in the membrane whereas there was little in the membranes of female glands. Western blot analysis of Cx26 showed that female Cx32-deficient mice expressed Cx26. Patch-clamp analyses of acinar cell coupling showed that the cell pairs from male glands were coupled whereas those from female glands were not. Stimulated fluid production by the glands from Cx32-deficient mice was abnormally low in female glands compared with controls at low topical doses of carbachol. The protein secretory response to different doses of carbachol was the same in all animals. These data suggest that gap junctions are essential for optimal fluid secretion in lacrimal glands.     

Ultrastructural evidence for the endocrine nature of the lateral organs of the cattle tick Boophilus microplus

The lateral organs of the tick Boophilus microplus were previously thought to have a neurohaemal function, but the present study shows that they consist of glandular cells which contain a rich system of smooth endoplasmic reticulum (SER) and Golgi but no indication of neurosecretory production or release. There is acid phosphatase activity throughout the SER as well as in Golgi and a major function of the latter may be the production of lysosomal enzymes. It is suggested that the organs are endocrine glands and that, in engorged females, may secrete a hormone involved in the control of vitellogenesis. The organs are more active in feeding than in unfed males and a related function could be in control of the development of genital organs or spermatogenesis. Also present in the cells are coated vesicles, lipid droplets and microtubules. Coated vesicles close to Golgi are probably primary lysosomes whereas those near the periphery are shown by ferritin tracer to arise from coated pits. Pinocytosis could be involved in membrane retrieval but, in the absence of evidence for exocytosis, this seems unlikely. It is tentatively proposed that, by analogy with vertebrate and insect endocrine glands, the lateral organs may take up hormone precursor via coated vesicles for storage in lipid droplets and conversion to hormone in the SER. As in other SER-rich endocrine glands, the release mechanism for the hormone or other secretory product of the lateral organs is uncertain. Both the steroid, ecdysone and the terpenoid, juvenile hormone, are discussed as possible candidates for the lateral organ hormones.     

Morphological and functional changes in several endocrine glands induced by hypothyroidism in the rat

The effect of hypothyroidism upon the morphology and the function of several endocrine glands was studied in radiothyroidectomized male rats. It was found that T3, T4, insulin, prolactin and corticosterone levels were significantly lower in hypothyroid rats. TSH levels were significantly higher in these animals while no changes were depicted in testosterone levels. The administration of T4 drew back to normal range the above-mentioned altered serum hormone levels. The studies performed with light microscopy revealed alterations only in the TSH secretory cells of the adenohypophysis. Conversely, when using the electron microscope to study the different endocrine glands, clear alterations were depicted in the TSH and prolactin secretory cells of the adenohypophysis, as well as in the pancreatic B cells and the cells of the zona fasciculata of the adrenal cortex. No abnormal changes were demonstrable at the level of the seminiferous tubules of the testis. All the above morphological changes were corrected by the administration of T4 to hypothyroid rats. These results suggest that the hypothyroid state is a complex hormonal dysfunction rather than a single hormonal defect. The secretory alterations are accompanied by fine cellular alterations in the corresponding glands.