G. Teitelman

Hybrid insulin genes reveal a developmental lineage for pancreatic endocrine cells and imply a relationship with neurons

Insulin appears in the developing mouse pancreas at embryonic day 12 (e12). Transgenic mice harboring three distinct hybrid genes utilizing insulin gene regulatory information first express the transgene product two days earlier, at e10, in a few cells of the pancreatic bud. Throughout development and postnatal life, all of the insulin-producing (beta) cells coexpress the hybrid insulin gene. In addition, islet cells containing glucagon, somatostatin, pancreatic polypeptide, and the neuronal enzyme tyrosine hydroxylase coexpress the transgene when they first arise. Similarly, coexpression of these normally distinct islet cell markers occurs during differentiation of the four endocrine cell types. The transgene product also appears transiently during embryogenesis in cells of the neural tube and in neural crest. The results suggest a common precursor for the endocrine cells of the pancreas. Moreover, they imply a relationship between neural and pancreatic endocrine tissue.

Glucagon gene regulatory region directs oncoprotein expression to neurons and pancreatic a cells

The regulatory region of the rat preproglucagon gene targets expression of the SV40 large T oncoprotein to two cell types in transgenic mice, the pancreatic alpha cells and a set of neurons localized in the hindbrain, both of which normally produce preproglucagon. Additional neurons in the forebrain and midbrain stain for T antigen but do not express the endogenous glucagon gene. Synthesis of T antigen in endocrine alpha cells results in the heritable development of pancreatic glucagonomas. In brains of transgenic mice from three independent lineages, expression of the hybrid gene begins at embryonic day 12 in neuroblasts of the hindbrain, where it continues throughout adult life, most notably in the medulla. Remarkably, oncoprotein expression in both proliferating neuroblasts and mature neurons has no apparent consequences, either phenotypic or tumorigenic. Expression of the hybrid glucagon gene in both neurons and islet cells supports a possible interrelationship between these cell types.

Cell lineage analysis of pancreatic islet cell development: Glucagon and insulin cells arise from catecholaminergic precursors present in the pancreatic duct

We have previously reported that cells transiently expressing tyrosine hydroxylase (TH), the first enzyme of the catecholamine biosynthetic pathway, are present in the pancreas of mouse embryos from prenatal Day 11 (E11) and that, at E12, some TH cells contain glucagon. Cells containing TH were also found in adults which, unlike the TH cells of embryos, did not contain glucagon (G. Teitelman, T. H. Joh, and D. J. Reis (1981). Proc. Natl. Acad. Sci. 78, 5225). These findings suggested to us that the TH cells of embryonic pancreas were the precursors of glucagon cells of adults. In this study we used immunocytochemical and autoradiographic techniques to determine whether cells containing TH (a) were present in pancreas throughout pre- and postnatal development, (b) were localized to a specific region of the gland, (c) contained insulin at any time, and (d) proliferated. We found that TH cells were present in pancreas throughout life. In embryos, cells containing TH localized only along the pancreatic duct, also contained either glucagon or insulin, and were able to proliferate. In contrast, after birth, the pancreatic duct contained no TH cells. Cells containing TH in postnatal and adult mice also differed from embryonic TH cells in that they were found in all islets, contained insulin but not glucagon, and did not synthesize DNA, and hence did not proliferate. These findings suggest that progenitor cells that contain catecholamines and are present in the pancreatic duct give rise to glucagon and insulin cells of adult islets. They also indicate that the TH-insulin cells of postnatal and adult mice are not stem cells but are postmitotic cells that appear in the islets after birth.

Transient expression of a noradrenergic phenotype in cells of the rat embryonic gut

The neural crest is a transient embryonic structure that originates from the dorsal surface of the neural tube. Soon after their appearance, the crest cells migrate throughout the body and differentiate into a variety of cell types8, 25,26. We have recently discovered z4 that in rat embryo the enzymes tyrosine hydroxylase (TH) and dopamine-fl-hydroxylase (DBH), which specifically subserve the synthesis of norepinephrine, could be detected with immunohistochemical techniques when the crest cells reached the region of the future sympathetic chain. Some of these cells formed the sympathetic chain, while others, also containing TH and DBH, migrated alongside the aorta to form the paraganglia and adrenal medulla. In the course of this study we also detected the presence of cells containing TH in the embryonic gut wall. Since the gut of adult rats lacks intrinsic noradrenergic neurons 3, several questions were raised: first, whether the cells containing TH disappear prior to or after birth, and second, whether these cells contained not only TH but also DBH and phenylethanolamine-N-methyltransferase (PNMT) and hence, if they could be defined as dopaminergic, noradrenergic or adrenergic. Pregnant albino rats (Sprague-Dawley) were purchased from a commercial animal colony. The first day of pregnancy was defined as the day the vaginal plug was detected. At the appropriate day of development, pregnant rats were anesthetized with pentobarbitol (40 mg/kg, i.p.), embryos removed individually from the uterus, fixed by immersion in formalin (4 ~ paraformaldehyde in 0.1 M phosphate buffer, pH 7.4) for 2 h and embedded in 30 ~ sucrose at 5 °C overnight. The following day the embryos were mounted in 30 ~ sucrose, frozen with dry ice and 15 #m sections cut in a cryostat microtome at --20 ~ 5 °C. The sections were melted onto glass slides. The bound antibody was localized by the peroxidase-antiperoxidase unlabelled antibody enzyme method (PAP technique) of Sternberger z3, as described by Pickel et al. is. The procedure for preparation of the antibodies to TH, DBH and PNMT, as well as the criteria used to judge their specificity, have been previously described 9,1o,21.

Cholinergic neurons of the chick ciliary ganglia express adrenergic traits in vivo and in vitro

In this study, we sought to determine whether neurons of the chick embryo ciliary ganglia (CG), a parasympathetic cholinergic ganglia, can express catecholaminergic (CA) traits. To accomplish this, we used immunocytochemical techniques to examine the presence of the CA enzymes tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT) in CGs removed from chick embryo at day 8 of development (E8). Few neurons containing TH but not PNMT were found in the E8 CG. To examine whether CG neurons express CA enzymes in vitro, CGs removed from E8 chick embryo were dissociated and kept in culture for 3 to 12 days. In 50% of the culture dishes, some neurons contain TH or PNMT after 5 days in vitro. In an equal proportion of culture plates, CG neurons did not express the enzymes. To determine whether the proportion of CG neurons expressing TH or PNMT is increased by tissue influences, ganglion cells were co-cultured with notochord. In 90% of the co-culture experiments, most neurons present in the culture dishes stained with TH or PNMT after 5 days in vitro. To test for the presence of aromatic L-amino acid decarboxylase (AADC), another CA enzyme, cultures of CGs and CGs plus notochord were incubated with levodopa and processed for the detection of CA histofluorescence. Dopamine histofluorescence was present in all neurons after 3 days in vitro irrespective of the presence of notochord, suggesting that the expressions of TH and PNMT and that of AADC are differentially regulated. This study, therefore, demonstrates that cholinergic neurons of the CG contain CA enzymes in vivo and in vitro and that the proportion of neurons expressing CA traits during development in vitro can be increased by environmental cues such as those released by the notochord.

Expression of the adrenergic phenotype in cultured fetal adrenal medullary cells: Role of intrinsic and extrinsic factors

Abstract During embryogenesis of the rat the enzymes tryosine hydroxylase (TH) and dopamine-β-hydroxylase (DBH) are first detected by immunocytochemistry or biochemical assay on the 16th day of gestation (E 16). It is not until E 18 that the enzyme phenylethanolamine- N -methyltransferase (PNMT), which is required for biosynthesis of adrenaline, can be detected cytochemically or biochemically. In this study we sought to determine whether the delayed appearance of PNMT is consequent to invasion of the adrenal medulla by E 18 of cells destined to express PNMT, cues provided by the ingrowing splachnic nerves or the action of corticosterone (CS) secreted by the adrenal cortical anlage, a hormone which regulates PNMT in adult rats. When adrenal glands are removed on E 16 and placed in culture, PNMT cannot be detected cyto- or biochemically until 2 days later (E 16 + 2). While CS levels increase 100-fold in vivo between E 16 and E 18, the surge of CS is not necessary for expression of PNMT since (a) adrenals removed on E 16 and cultured in the absence of exogenous ACTH fail to increase CS yet still express PNMT and (b) addition of CS (10 −5 M ) to the cultures on E 16 does not alter the time of appearance of the enzyme. CS, on the other hand, increases the amount of PNMT protein and activity 3-fold with respect to control at all time points, without any effect on TH. We conclude that (a) it is the cells already present in the adrenal medulla at E 16 which differentiate to express PNMT; (b) the initial expression of PNMT is not controlled by nerves nor by corticosteroids; and (c) corticosteroids have a selective action on regulating the amount of PNMT, once it is expressed, but not TH enzyme protein. It remains to be determined whether the differentiation of PNMT is elicited by genetic or epigenetic signals.

Insulin cells of pancreas extend neurites but do not arise from the neuroectoderm

It is generally believed that during mammalian embryogenesis neurons arise only from the ectodermal germ layer, while the other two germ layers, mesoderm and endoderm, give rise to connective tissue and gut, respectively. Pancreatic islet cells, however, may be an exception to this classical cell lineage derivation. These cells, of endodermal origin, can express several neuronal antigens in addition to the peptide hormones which regulate carbohydrate metabolism. This study sought to determine whether islet cells of adult mice, in addition to displaying biochemical homology to neurons, are also capable of extending neurites, the cytoplasmic elongations that are recognized as a hallmark of the neuronal phenotype. It was found that dissociated pancreatic islet cells can extend neurite-like processes when maintained in vitro and that these processes contain neurofilament, the intermediate filament protein specific to neurons. Islet cells maintained in vitro as explants, however, did not form neurites thereby indicating that normal histotypical contacts inhibit process formation. This observation may account for the absence of process elaboration by intact islets in vivo. These results demonstrate that cells derived from the endoderm share the ability to display a characteristic neuronal phenotype with neuroectodermal cells and, furthermore, that the expression of these traits is regulated by epigenetic cues.

Partial expression of catecholaminergic traits in cholinergic chick ciliary ganglia: Studies in vivo and in vitro

We have previously demonstrated that at embryonic Day (E) 8, some cells of the chick ciliary ganglion (CG) contain the catecholaminergic (CA) enzyme tyrosine hydroxylase (TH), but not phenylethanolamine-N-methyltransferase (PNMT); and that in culture essentially all cells express both enzymes. In the present study, we sought to determine, first, whether the expression of adrenergic traits in the CG in vivo is transient or permanent in the CG. To do so, CGs were removed from E5 to postnatal Day 5, fixed, and processed for the immunocytochemical localization of the CA enzymes: TH, L-amino acid decarboxylase (AADC), and PNMT. At all stages examined, some CG neurons expressed TH immunoreactivity (TH-IR) and all contained AADC-IR. However, none stained with PNMT antibodies, indicating that these cells stably express some, but not all, of the CA enzymes. Second, we examined whether CG neurons in culture expressed other CA markers. CG neurons did not contain detectable levels of TH enzyme activity nor did they transport and store exogenously supplied monoamines. These results indicate that some but not all traits necessary for adrenergic function are present in CG neurons in vitro. Third, we sought to establish whether CA expression in CG neurons is affected by modification in culture conditions. Cultures of CG neurons continued to express TH-IR even when grown in the presence of either 50% HCM or 20 mM KCl for 5 days. Finally, the expression of the cholinergic enzyme, choline acetyltransferase (CAT) was assessed in CG cultures by biochemical assay. CAT activity increased five-fold between 5 and 17 days in vitro, irrespective of the presence of TH-IR in 100% of the CG neurons of sister cultures. These data suggest that at least a subpopulation of CG neurons express both TH and CAT in culture. We conclude that the postmitotic neurons of the CG are able to express some but not all of the traits characteristic of a CA phenotype while maintaining cholinergic expression. These findings suggest that (1) the appearance of the full complement of adrenergic properties is not coordinated and may be regulated by different environmental cues and (2) parasympathetic neurons can express both adrenergic and cholinergic traits simultaneously.

Expression of cell type-specific markers during pancreatic development in the mouse: implications for pancreatic cell lineages

SummaryThe islet cells of the mammalian pancreas are comprised of four different endocrine cell types, each containing a specific hormone. Islet cells also contain two enzymes of the catecholamine biosynthetic pathway: tyrosine hydroxylase (TH) and aromatic L-amino acid decarboxylase (AADC). The cell lineage relationships of these different cell types have not been examined and it is not known whether, during development, they originate from the same or from different precursor populations. In this study we used immunocytochemical procedures to determine whether developing pancreatic cells express markers common to endocrine and exocrine cell types. We found that acinar cell precursors express AADC prior to the appearance of an exocrine marker and that the expression of AADC in acinar cells persists throughout embryogenesis to the first month of postnatal life. At this time, acinar cells do not contain AADC. We also found that exocrine cells containing AADC never express other islet-cell markers. These findings suggest that while acinar and islet cells both arise from precursor cells containing AADC, these progenitor cells do not express a combined endocrine-exocrine phenotype.

Immunohistochemical localization of choline acetyltransferase using a monoclonal antibody: a radioautographic method.

Monoclonal antibodies to rat striatal choline acetyltransferase were produced by fusion of sensitized mouse lymphocytes with murine plasmacytoma (NS1) cells. Two stable anti-choline acetyltransferase lines were established by limiting dilution cloning. Specificity of antibody was established by the following criteria: (1) on an enzyme linked immunosorbant assay, antibodies reacted against choline acetyltransferase which was highly purified; (2) by immunoprecipitation, monoclonal antibody bound to its antigen and precipitated choline acetyltransferase activity from solution, when used in conjunction with rabbit antimouse IgG; and (3) monoclonal antibody was shown to specifically localize cholinergic neurons. The monoclonal antibody to choline acetyltransferase was radiolabeled in culture by incubating hybridomas in medium containing 3H-labeled amino acids. This 3H-labeled antibody was used for radioautography on cryostat sections of rat peripheral and central nervous systems. In a sampling of areas, highly specific labeling of cholinergic structures was afforded at both light and electron microscopic levels. Double labeling of tyrosine hydroxylase, a catecholaminergic marker, and choline acetyltransferase was carried out by reacting sections first with the 3H-labeled antibody to choline acetyltransferase and then with rabbit antibody to tyrosine hydroxylase. The choline acetyltransferase label was radioautographically processed and tyrosine hydroxylase was visualized by the peroxidase-antiperoxidase method. The combined techniques of peroxidase and radioautographic histochemistry provide permanent electron dense labels which can be examined simultaneously within a single histologic section.