Lysosomes and pancreatic islet function

Summary The relation between qualitative and quantitative glucose-dependent alterations of lysosomes in pancreatic islets and the function of the islets was studied. Isolated islets of the mouse were maintained in tissue culture for one week in either 28, 5.5 or 3.3 mmol/l glucose. Insulin biosynthesis, insulin secretion and insulin content of the cultured islets were determined. After culture, the islets were subjected to acid phosphatase cytochemistry and examined by electron microscopy and ultrastructural morphometry. Islets cultured in 28 mmol/l glucose both produced and secreted insulin rapidly. Such islets seemed, however, unable to maintain more than small amounts of granule-stored insulin. Islets cultured at the lower concentrations of glucose displayed a reduced insulin secretion, which apparently resulted in considerable amounts of intracellularly stored insulin. In all cultured islets different types of lysosomes, identified by their acid phosphatase reactivity, could be seen. Dense bodies, i.e., lysosomes characterized by a homogeneous, very fine, particulate content of high density, seemed to predominate at all concentrations of glucose. It is suggested that, in the islets, the dense bodies correspond morphologically to primary lysosomes. Other types of lysosomes with inclusions of various kinds, which were frequent at the two lower concentrations of glucose, may correspond to secondary lysosomes. Morphometry revealed differences between the size distributions of lysosomes in the three experimental groups. Thus, the average lysosomal size was inversely proportional to the concentration of glucose in the culture medium. However, the numerical density of lysosomes was greatest at the highest glucose concentration. The observation of secondary lysosomes, containing material resembling secretory granules, suggests that the increased size and lowered number of lysosomes in islets cultured at low glucose concentrations may depend on a crinophagic process. Such a process, together with insulin biosynthesis and insulin secretion, may be of physiological importance for control of the secretory granule content within the pancreatic B-cell.     

Sequential reactors for the removal of endocrine disrupting chemicals by laccase immobilized onto fumed silica microparticles

Abstract

The main objective of this study is the evaluation of the capability of laccase from Myceliophthora thermophila immobilized on fumed silica microparticles (fsMP) for the removal of endocrine disrupting chemicals (EDCs) in two enzymatic reactor configurations. This type of support can also be magnetized to allow the straightforward separation of the biocatalyst under a magnetic field. The support exhibited excellent biocompatibility with the enzyme, superior tolerance to pH and temperature as well as improved stability in comparison with the free enzyme, even in the presence of organic solvents and enzyme inhibitors. The technical feasibility of the removal of EDCs by immobilized laccase was assessed in two types of enzymatic reactors operated in sequential mode: a membrane reactor using fsMP-laccase and a reactor with magnetic separation using magnetized fsMP-laccase. The extent of transformation for the target compounds: bisphenol A (BPA) and 17β-estradiol (E2) was high and comparable to free laccase in both systems (up to 80%). The possibility of reusing the immobilized enzyme, especially for magnetized supports, offers an interesting approach in the development of enzyme based processes for the biotransformation of emerging pollutants.     

Ontogenetic development of neuropeptide Y-like-immunoreactive cells in the gastroenteropancreatic endocrine system of the dogfish

This immunocytochemical study was carried out to elucidate the ontogenetic development of neuropeptide Y-like-immunoreactive cells in the gastroenteropancreatic endocrine system of the cloudy dogfish, Scyliorhinus torazame. Immunostained cells first appeared in the pancreas of the embryo at the 15-mm stage, and were also detected in the vitellointestinal duct of the yolk stalk at the 20-mm stage. These cells were polymorphic, with occasional processes that were sometimes directed toward the vascular wall or into the cavity of the vitellointestinal duct. At the 34-mm stage, immunostained cells could also be found in the proximal part of the spiral intestine and, by the 74-mm stage, immunopositive cells were present in the gastric mucosa. In the gut and pancreas, the cells gradually increased in number with development, whereas in the vitellointestinal duct and internal yolk sac, they decreased and seemed to disappear following hatching. Thus, in juveniles, the distribution of the neuropeptide Y-like-immunoreactive cells in the gastroenteropancreatic endocrine system had attained that of adults. Electron-microscopic immunocytochemistry demonstrated that, in the labeled cells of the vitellointestinal duct, the neuropeptide Y-like antigen was located in cytoplasmic granules, as in the cells of the gut and pancreas.This paper is dedicated to Professor Yoshiharu Honma, on the occasion of his retirement and inauguration as Emeritus Professor     

The effect of maternal exposure to endocrine disrupting chemicals on fetal and neonatal development: A review on the major concerns

There is a widespread exposure of general population, including pregnant women and developing fetuses, to the endocrine disrupting chemicals (EDCs). These chemicals have been reported to be present in urine, blood serum, breast milk, and amniotic fluid. Endocrine disruptions induced by environmental toxicants have placed a heavy burden on society, since environmental exposures during critical periods of development can permanently reprogram normal physiological responses, thereby increasing susceptibility to disease later in life—a process known as developmental reprogramming. During development, organogenesis and tissue differentiation occur through a continuous series of tightly‐regulated and precisely‐timed molecular, biochemical, and cellular events. Humans may encounter EDCs daily and during all stages of life, from conception and fetal development through adulthood and senescence. Nevertheless, prenatal and early postnatal windows are the most critical for proper development, due to rapid changes in system growth. Although there are still gaps in our knowledge, currently available data support the urgent need for health and environmental policies aimed at protecting the public and, in particular, the developing fetus and women of reproductive age. Birth Defects Research (Part C) 108:224–242, 2016. © 2016 Wiley Periodicals, Inc.     

Monoclonal antibodies obtained through insect brain homogenates: Tools for cell-specific neuroanatomical studies in the Colorado potato beetle

Immunization of mice with crude or purified homogenates of brain and endocrine organs of the Colorado potato beetle, Leptinotarsa decemlineata (Say), generated antibodies against specific antigens in the insect tissue. Hybridomas were prepared and screened immunocytochemically for the production of monoclonal antibodies (MAB) that recognized specific cells and that were useful for neuroanatomical studies. A relatively high proportion of MABs recognized one or more cells or tissues in neuronal, neuroendocrine or nonneural compartments of the brain or in fatbody or haemocytes, using standard immunocytochemical procedures. We could make a clear differentiation in subsets of neurons (both normal and peptidergic) and neuron-specific neuroglial cells. A full account of the obtained responses is given. The preparation of the immunogen and the immunization protocol affects the selection of MABs produced. It is argued that not all possibilities have been exploited and that continued experiments would probably increase the number of selective MABs.

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Résumé L'utilisation de techniques immunocytochimiques lors d'études neuro-anatomiques est encore dans l'enfance par suite de l'absence de données sur la chimie de structures spécifiques et, par conséquent, de l'absence d'anticorps spécifiques d'antigènes et de tissus. Nous apportons la preuve que de nombreuses substances réelles d'homogénats bruts de cerveaux sont de bons antigènes et que les souris peuvent être induites à produire des anticorps contre ceux-ci. Nous avons produit et testé de nombreux anticorps monoclonaux qui reconnaissent ces antigènes sur des lames de microscope, en utilisant des techniques immunocytochimiques courantes ou plus élaborées.Les immunogènes ont été préparés de différentes façons pour examiner si le taux de mélange de tissus du cerveau et/ou des ganglions associés et de glandes endocrines, et si les procédés ultérieurs de purification et d'immunisation, influeraient sur la spécificité des anticorps. L'intégralité de l'ensemble cerveau-glandes endocrines a été le plus immunogénique quand l'homogénat a subi le minimum de manipulations. Une grande diversité d'anticorps a été obtenue après des injections répétées chez la souris. Ces anticorps reconnaissent les épitopes dans toutes les catégories de tissus considérés, c'est-à-dire, les tissus spécifiquement nerveux, neuro-endocrines, et non nerveux. La purification progressive et le cross-linking des constituants de l'homogénat réduisent la variabilité des anticorps. Tout en l'espérant, on ne s'attendait pas à ce que les substances jusqu'alors dans des centres peptidergiques indéfinis fussent parmi les structures les plus souvent identifiées. Les chances de produire de tels anticorps spécifiques de peptides ont augmenté quand les tissus endocrines ont servi d'immunogènes.Nous avons résumé les types de tissus et de cellules mis en évidence par cette sélection d'anticorps monoclonaux. Nous soulignons que l'expérimentateur peut difficilement influencer les préférences du système immunologique de la souris, mais les anticorps produits jusqu'ici sont valables pour les études neuroanatomiques et pour la récolte d'antigènes intéressants à partir de procédés biochimiques de séparation. Il reste à explorer la spécificité sensu stricto des anticorps.

     

Galanin is co-localized with noradrenaline and neuropeptide Y in dog pancreas and celiac ganglion

Summary To visualize the localization and potential colocalization of noradrenaline and the putative pancreatic sympathetic neurotransmitters, galanin and neuropeptide Y (NPY), immunofluorescent staining for galanin, NPY and tyrosine hydroxylase (TH) was performed on sections of canine pancreas and celiac ganglion. In the pancreas, galanin-immuno-fluorescent nerve fibers were confirmed as densely and preferentially innervating the islets, whereas numerous NPY-positive nerve fibers were found in the exocrine parenchyma, the surrounding of the blood vessels and within the islets. Double-staining for the peptides and TH indicated that most galaninpositive nerve fibers were adrenergic, most NPY-positive nerve fibers were adrenergic, and many islet nerves contained both galanin and NPY, although some galaninpositive nerve fibers appeared to lack NPY. In the celiac ganglion, virtually all cell bodies were positive for both galanin and TH; a large subpopulation of these cells were also positive for NPY. Radioimmunoassay (RIA) of galanin in extracts of dog celiac ganglion revealed a very high content (256±33 pmol/g wet weight) of galanin-like immunoreactivity (GLIR), consistent with the dense staining observed. This GLIR behaved in a similar manner to synthetic porcine galanin in the RIA. In addition, the majority of the GLIR in ganglion extracts coeluted with the synthetic peptide upon gel filtration, although a minor peak of a larger apparent molecular weight was also observed, observations consistent with the presence of a precursor peptide. These findings suggest that galanin is a sympathetic post-ganglionic neurotransmitter in the canine endocrine pancreas and that NPY might serve a similar function.     

Regulatory peptides in the pancreas of two species of elasmobranchs and in the Brockmann bodies of four teleost species

Summary Immunohistochemistry was used to localize regulatory peptides in endocrine cells and nerve fibres in the pancreas of two species of elasmobranchs (starry ray,Raja radiata and spiny dogfish,Squalus acanthias), and in the Brockmann bodies of four teleost species (goldfish,Carassius auratus, brown troutSalmo trutta, rainbow trout,Oncorhynchus mykiss and cod,Gadus morhua). In the elasmobranchs, the classical pancreatic hormones somatostatin, glucagon and insulin were present in endocrine cells of the islets. In addition, endocrine cells were labelled with antisera to enkephalins, FMRF-amide, gastrin/cholecystokinin-(CCK)/caerulein, neurotensin, neuropeptide Y (NPY), and peptide YY (PYY). Nerve fibres were demonstrated with antisera against bombesin, galanin and vasoactive intestinal polypeptide (VIP). These nerve fibres innervated the walls of blood vessels, in the exocrine as well as the endocrine tissue. In the four teleost species immunoreactivity to somatostatin, insulin and glucagon was intense in the Brockmann bodies. Cells were labelled with antisera to enkephalin, neurotensin, FMRFamide, gastrin/CCK/ caerulein, NPY, PYY and VIP. Only a few nerve fibres were found with antisera against dopamine--hydroxylase (DBH, cod), enkephalin (met-enkephalin-Arg-Phe, cod), bombesin (cod), gastrin/CCK/caerulein (cod) and VIP. Galanin-like-immunoreactive fibres were numerous in the Brockmann bodies of all teleosts examined. Immunoreactivity to calcitonin gene-related peptide (CGRP), substance P, tyrosine hydroxylase (TH), and phenyl-N-methyl transferase (PNMT) could not be found in any of the species studied.     

Coexistence of peptide YY and glicentin immunoreactivity in endocrine cells of the gut

Endocrine cells containing peptide YY (PYY) were numerous in the rectum, colon and ileum and few in the duodenum and jejunum of rat, pig and man. No immunoreactive cells could be detected in the pancreas and stomach. Coexistence of PYY and glicentin was revealed by sequential staining of the same section and by staining consecutive semi-thin sections. Since the PYY sequence is not contained in the glucagon/glicentin precursor molecule the results suggest that the PYY cell in the gut expresses two different genes coding for regulatory peptides of two different families.