Endocrine markers of cellular immunity: defining the endocrine phenotype

The term neuroendocrine has been used to define cells that secrete their products in a regulated manner, in response to a specific stimulus. The neuroendocrine system includes neurons and endocrine cells sharing a common phenotypic program characterized by the expression of markers such as neuropeptides, chromogranins, neuropeptide processing enzymes SPC2 and SPC3 (subtilase-like pro-protein convertases) or dense core secretory granules. Various theories such as the APUD (amine precursor uptake decarboxylation) concept, the diffuse neuroendocrine system (DNES) or the paraneuron concept have been put forth to classify neuroendocrine cells as a cohesive group. Neuroendocrine characteristics have been used as evidence of a common embryological origin for normal and neoplastic cells. However, it is now recognized that neuroendocrine characteristics can be observed in various cell types, such as immunocytes, that do not share a common embryological origin with either neurons or endocrine cells. We propose to redefine previous "neuroendocrine" concepts to include the notion that activation of specific genetic switches can lead to the expression of a partial or full neuroendocrine phenotype in a variety of cell types, including immune cells.     

Immunohistochemical detection of alpha1E voltage-gated Ca(2+) channel isoforms in cerebellum, INS-1 cells, and neuroendocrine cells of the digestive system.

Polyclonal antibodies were raised against a common and a specific epitope present only in longer alpha1E isoforms of voltage-gated Ca(2+) channels, yielding an "anti-E-com" and an "anti-E-spec" serum, respectively. The specificity of both sera was established by immunocytochemistry and immunoblotting using stably transfected HEK-293 cells or membrane proteins derived from them. Cells from the insulinoma cell line INS-1, tissue sections from cerebellum, and representative regions of gastrointestinal tract were stained immunocytochemically. INS-1 cells expressed an alpha1E splice variant with a longer carboxy terminus, the so-called alpha1Ee isoform. Similarily, in rat cerebellum, which was used as a reference system, the anti-E-spec serum stained somata and dendrites of Purkinje cells. Only faint staining was seen throughout the cerebellar granule cell layer. After prolonged incubation times, neurons of the molecular layer were stained by anti-E-com, suggesting that a shorter alpha1E isoform is expressed at a lower protein density. In human gastrointestinal tract, endocrine cells of the antral mucosa (stomach), small and large intestine, and islets of Langerhans were stained by the anti-E-spec serum. In addition, staining by the anti-E-spec serum was observed in Paneth cells and in the smooth muscle cell layer of the lamina muscularis mucosae. We conclude that the longer alpha1Ee isoform is expressed in neuroendocrine cells of the digestive system and that, in pancreas, alpha1Ee expression is restricted to the neuroendocrine part, the islets of Langerhans. alpha1E therefore appears to be a common voltage-gated Ca(2+) channel linked to neuroendocrine and related systems of the body.     

Embryology of the diffuse neuroendocrine system and its relationship to the common peptides.

The diffuse neuroendocrine system is constituted by the cells, now more than 40 in number, of the central and peripheral divisions of the amine precursor uptake and decarboxylation (APUD) series. At one time presumed to be derived from a common "neural" ancestor, all are now deemed to be "neuroendocrine-programmed," arising either in the embryonic epiblast itself or in one of its principal descendants. The APUD cells produce more than 35 physiologically active peptides and a small number of equally active amines. Within the last 3 years, 17 of these peptides have been identified jointly in endocrine cells and in neuronal cell bodies or processes. Sharing in this way a neural and an endocrine location and site of production, they are called the "common peptides." The diffuse neuroendocrine system is to be regarded as a third division of the nervous system, whose products suppress, amplify, or modulate the activities of the other two divisions. The relationship of its products to the cells and processes of these two divisions is currently the object of intensive inquiry.     

Identification of a complex peptidergic neuroendocrine network in the hard tick, <Emphasis Type="Italic">Rhipicephalus appendiculatus</Emphasis>

Neuropeptides are crucial regulators of development and various physiological functions but little is known about their identity, expression and function in vectors of pathogens causing serious diseases, such as ticks. Therefore, we have used antibodies against multiple insect and crustacean neuropeptides to reveal the presence of these bioactive molecules in peptidergic neurons and cells of the ixodid tick Rhipicephalus appendiculatus. These antibodies have detected 15 different immunoreactive compounds expressed in specific central and peripheral neurons associated with the synganglion. Most central neurons arborize in distinct areas of the neuropile or the putative neurohaemal periganglionic sheath of the synganglion. Several large identified neurons in the synganglion project multiple processes through peripheral nerves to form elaborate axonal arborizations on the surface of salivary glands or to terminate in the lateral segmental organs (LSO). Additional neuropeptide immunoreactivity has been observed in intrinsic secretory cells of the LSO. We have also identified two novel clusters of peripheral neurons embedded in the cheliceral and paraspiracular nerves. These neurons project branching axons into the synganglion and into the periphery. Our study has thus revealed a complex network of central and peripheral peptidergic neurons, putative neurohaemal and neuromodulatory structures and endocrine cells in the tick comparable with those found in insect and crustacean neuroendocrine systems. Strong specific staining with a large variety of antibodies also indicates that the tick nervous system and adjacent secretory organs are rich sources of diverse neuropeptides related to those identified in insects, crustaceans or even vertebrates. This work was supported by Slovak grant agencies: Agentúra na podporu vyskumu a vyvoja (APVV-51-039105) and Vedecká grantová agentúra (VEGA 2-6090-26 and 2/6155/26).     

Histochemical differentiation of endocrine gastrointestinal cells in test animals, with special reference to chicken embryos.

Based upon the characteristics of argent-affinity and argyrophilia and the application of specific immune histochemical methods, endocrine cells can be differentiated in the most prominent species of test animals. These methods are demonstrated in chicken embryos, because embryological studies made in order to reveal the still unknown endodermal or neuroectodermal origin of these cells are highly important.     

Multidirectional differentiation in neuroendocrine neoplasms

Histopathological and experimental observations indicate that tumors composed wholly or in part of neuroendocrine elements may arise in tissues derived from ectoderm (including neuroectoderm), mesoderm, and endoderm. These tumors frequently exhibit multidirectional differentiation as manifested by multihormonality and by the presence of morphological features indicative of divergent differentiation both in vivo and in vitro. The existence of stem cells, plasticity of differentiated cells, microenvironmental influences, and random events are factors which might all interact to determine the characteristics of any particular tumor. The production of characteristic regulatory peptide products in association with tumors of specific histological subtypes and with other neuroendocrine markers suggests mechanisms for nonrandom activation of multiple genes common to neuroendocrine-programmed cells. Future studies applying new molecular biological techniques to intact tissues and to in vitro models may help to clarify the mechanisms that regulate the expression of the neuroendocrine phenotype in normal and neoplastic states.     

Formation of the transverse nerve in moth embryos. II. Stereotyped growth by the axons of identified neuroendocrine neurons

We are interested in the cellular mechanisms that guide neuroendocrine axons to their neurohaemal target regions and that regulate the extent and positioning of their terminal arbor. The neurohaemal organ we have studied is the segmentally repeated transverse nerve of the moth Manduca. In the mature animal, two motor neurons and a heterogeneous set of identified neuroendocrine neurons project to this nerve; the latter release hormonal peptides from along its length. In the preceding report, we demonstrated that during embryogenesis, the position, trajectory and extent of the transverse nerve are anticipated by two sets of nonneuronal cells, the strap and the bridge. In this paper we show that four identified neuroendocrine neurons (L1 and B1-3), like the identified motor neurons before them, elaborate growth cones that use this preexisting scaffolding as a substrate for axonal elongation. Moreover, growth cone navigation by these neuroendocrine neurons is as precise and invariant as that displayed by the motor neurons. One feature that differentiates the behavior of the developing neuroendocrine cells from that of the motor neurons is a stereotyped interaction that the L1 and B1-3 axons undergo with an identified syncytial cell that lies in close proximity to the strap. Each neuroendocrine neuron specifically adheres to the syncytium by extending numerous filopodia, and an occasional large lamellopodium, over its surface. These contacts are maintained by the neuroendocrine axons after their growth cones have left the vicinity of the syncytium and proceeded into the strap/bridge complex. Adhesion to the syncytium is transient and specific to the neuroendocrine neurons: although motor neuron axons are present at this same time and place, they display no affinity for the syncytium. This distinction correlates with the fact that the neuroendocrine neurons go on to elaborate arbor within the confines of the transverse nerve, while the motor neurons do not. We suggest that the syncytium may act as a "fictive target" for these neurons to aid in the differentiation of features that are specific to their cellular phenotype.     

Interactions between the immune and neuroendocrine systems: clinical implications

The endocrine and immune systems are interrelated via a bidirectional network in which hormones affect immune function and, in turn, immune responses are reflected in neuroendocrine changes. This bidirectional communication is possible because both systems share a common "chemical language" that results from a sharing of common ligands (hormones and cytokines) and their specific receptors. Cytokines are important partners in this crosstalk. They play a role in modulating the hypothalamo-pituitary-adrenal (HPA) axis responses at all three levels: the hypothalamus, the pituitary gland and the adrenals. Acute effects of cytokines are produced at the central nervous system level, particularly the hypothalamus, whereas pituitary and adrenal actions are slower and are probably involved during prolonged exposure to cytokines such as during chronic inflammation or infection. Several mechanisms have been proposed by which peripheral cytokines may gain access to the brain. They include an active transport through the blood-brain barrier, a passage at the circumventricular organ level, as well as a neuronal pathway through the vagal nerve. The immune-neuroendocrine interactions are involved in numerous physiological and pathophysiological conditions and the interactions with the HPA axis may represent a mechanism through which the immune system, by stimulating the production of glucocorticoids, avoids an overshoot of inflammatory response. They may also be involved in the state of hypogonadism, of hypothyroidism and growth inhibition which can occur during inflammatory and infectious diseases. The crosstalk between the immune and endocrine systems is important to homeostasis, since the interactions can produce various appropriate adaptative responses when homeostasis is threatened.     

Sites of origin and patterns of migration of vasotocin/mesotocin neurons in developing brain of the chick

Vasotocin/mesotocin (VT/MT) producing neurons are known to migrate extensively during development of the hypothalamus. Birthdating studies as well as immunohistochemical studies suggested the possibility that VT/MT producing neurons originate from specific sites of the neural tube. Furthermore, a relationship between the site of origin and the eventual fate of VT/MT cells has been suggested. This study proposes to identify the sites of origin of VT/MT cells and to establish whether magnocellular and parvocellular VT/MT, and neuromodulatory and neurosecretory VT/MT arise from common or different areas of the developing neural tube. To do so, the embryological distribution of VT/MT producing neurons of the chick was studied with immunohistochemistry. Analysis of the youngest brains in which VT/MT cells could be detected (embryonic day 7.25, E7.25) suggested the presence of two separate sites of origin. The first site was located in the hypothalamic anlage, next to the third ventricle, and the second in the mesencephalon, next to the fourth ventricle. Three-dimensional reconstructions of the location of VT/MT cells throughout development substantiated the hypothesis that diencephalic VT/MT cells originate from the first site while mesencephalic ones originate from the second site. Mesencephalic VT/MT producing cells were confined to the nucleus of Edinger-Westphal and were only detectable during a brief period in development (E7.25–E10). Diencephalic VT/MT producing neurons were noted to form two main paths from their site of origin to the rostral diencephalon. Quantitative analysis confirmed this caudal to rostral displacement. Magnocellular and parvocellular VT/MT+ cells were intermingled at the diencephalic site of origin as well as in the migratory paths. Neuromodulatory and neurosecretory VT/MT cells of the diencephalon appeared to be derived from a common diencephalic site of origin. These studies support the hypothesis that while specific groups of progenitors may be important in allowing their offspring to produce VT/MT, they do not appear to influence the morphological attributes (magnocellular vs. parvocellular), nuclear locations, or functional characteristics of these cells. © 1996 John Wiley & Sons, Inc.     

Interdependence between neuroendocrine programming and the generation of immune recognition in ontogeny

Sequential, chronologically, and quantitatively critical inoculation of different allogeneic hybrid cells into mice during the neonatal and perinatal period results in an indefinite prolongation of the perinatal stage during which tolerance can be readily induced. Consequently, a permanent specific tolerance to the sequentially inoculated alloantigens and a parallel alteration and retardation in the maturation of the developing endocrine system which normally controls immune differentiation are observed. The endocrine and immune parameters are altered only when the successive presentation of alloantigens is begun at birth, as this is a critical stage of development at which both the neuroendocrine (hypothalamic-pituitary) and the thymo-lymphatic systems are still highly undifferentiated. The phylogenetically and ontogenetically interlocked and interdependent thymo-lymphatic and neuroendocrine networks thus constitute a basic homoeostatic regulatory system in which signals of both endocrine and antigenic nature are detected and elaborated with consequent proper response in a homeostatic fashion. On the basis of these considerations and the experimental findings that support them, the generation of tolerance and immunity (recognition of self and nonself components of the body) appears to be a part of the definitive brain programming for neuroendocrine and immune functions in early ontogey. This would constitute an augmented interpretation of the concept of immune tolerance as “specific central failure of the mechanisms of response” originally put forth by Medawar (1956, Proc. Roy. Soc.146B, 1).     

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)     

Sim2 contributes to neuroendocrine hormone gene expression in the anterior hypothalamus

Paraventricular (PVN) and supraoptic nuclei of the hypothalamus maintain homeostasis by modulating pituitary hormonal output. PVN and supraoptic nuclei contain five major cell types: oxytocin-, vasopressin-, CRH-, somatostatin-, and TRH-secreting neurons. Sim1, Arnt2, and Otp genes are essential for terminal differentiation of these neurons. One of their common downstream genes, Brn2, is necessary for oxytocin, vasopressin, and CRH cell differentiation. Here we show that Sim2, a paralog of Sim1, contributes to the expression of Trh and Ss genes in the dorsal preoptic area, anterior-periventricular nucleus, and PVN. Sim2 expression overlaps with Trh- and Ss-expressing cells, and Sim2 mutants contain reduced numbers of Trh and Ss cells. Genetically, Sim1 acts upstream of Sim2 and partially compensates for the loss of Sim2. Comparative expression studies at the anterior hypothalamus at early stages reveal that there are separate pools of Trh cells with distinctive molecular codes defined by Sim1 and Sim2 expression. Together with previous reports, our results demonstrate that Sim1 and Otp utilize two common downstream genes, Brn2 and Sim2, to mediate distinctive sets of neuroendocrine hormone gene expression.     

Microevolution of neuroendocrine mechanisms regulating reproductive timing in Peromyscus leucopus

A key question in the evolution of life history and in evolutionary physiology asks how reproductive and other life-history traits evolve. Genetic variation in reproductive control systems may exist in many elements of the complex inputs that can affect the hypothalamic-pituitary-gonadal (HPG) or reproductive axis. Such variation could include numbers and other traits of secretory cells, the amount and pattern of chemical message released, transport and clearance mechanisms, and the number and other traits of receptor cells. Selection lines created from a natural population of white-footed mice (Peromyscus leucopus) that contains substantial genetic variation in reproductive inhibition in response to short winter daylength (SD) have been used to examine neuroendocrine variation in reproductive timing. We hypothesized that natural genetic variation would be most likely to occur in the inputs to GnRH neurons and/or in GnRH neurons themselves, but not in elements of the photoperiodic pathway that would have pleiotropic effects on nonreproductive functions as well as on reproductive functions. Significant genetic variation has been found in the GnRH neuronal system. The number of GnRH neurons immunoreactive to an antibody to mature GnRH peptide under conditions maximizing detection of stained neurons was significantly heritable in an unselected control (C) line. Furthermore, a selection line that suppresses reproduction in SD (photoperiod responsive, R) had fewer IR-GnRH neurons than a selection line that maintains reproduction in SD (photoperiod nonresponsive, NR). This supports the hypothesis that genetic variation in characteristics of GnRH neurons themselves may be responsible for the observed phenotypic variation in reproduction in SD. The R and NR lines differ genetically in food intake and iodo-melatonin receptor binding, as well as in other characteristics. The latter findings are consistent with the hypothesis that genetic variation occurs in the nutritional and hormonal inputs to GnRH neurons. Genetic variation also exists in the phenotypic plasticity of responses to two combinations of treatments, (1) food and photoperiod, and (2) photoperiod and age, indicating genetic variation in individual norms of reaction within this population. Overall, the apparent multiple sources of genetic variation within this population suggest that there may be multiple alternative combinations of alleles for both the R and NR phenotypes. If that interpretation is correct, we suggest that this offers some support for the evolutionary "potential" hypothesis and is inconsistent with the evolutionary "constraint" and "symmorphosis" hypotheses for the evolution of complex neuroendocrine pathways.     

Ultrastructure of a neuroendocrine complex in oxyntic mucosa of normal human stomach

Summary The occurrence and ultrastructural characteristics of an extraepithelial neuroendocrine complex found in the oxyntic mucosa of a healthy young adult subject are described. The complex is composed of endocrine cells (P and ECL types) identical to those located intraepithelially and peripherally located axons embraced by cytoplasmic extension of scattered Schwann cells.     

Detection of functional interferon alpha receptors in human neuroendocrine tumor cell lines using a new monoclonal antibody.

While first described as antiviral agents, interferons (IFNs) exhibit significant antiproliferative and antitumor effects as well. IFN alpha has been successfully used in clinical trials to treat several malignancies, including leukemias and certain solid tumors. While many cell types have been studied for IFN alpha receptor expression, very little is known about receptor expression on human neuroendocrine cells. Using a novel anti-IFN alpha receptor monoclonal antibody, we examined IFN alpha receptor expression in 10 human cell lines derived from tumors of neuroendocrine origin, including neuroblastoma, neuroepithelioma and small cell lung carcinoma. All cell lines studied displayed a similar pattern of IFN alpha receptor expression and 5 of 8 cell lines demonstrated reduced thymidine incorporation following IFN alpha treatment. Addition of exogenous IFN alpha caused a decrease in IFN alpha receptor expression, while differentiating agents, such as phorbol esters and retinoic acid, induced an increase in receptor number without altering receptor affinity.     

Comparative Histophysiology of the Pancreatic Islets

The embryological origin of the islet tissue from a common entodermalanlage with the exocrine pancreas has been questioned recently.The islet tissue may be of. neural crest origin, and the ancestralislet cells may have been "taste cells in the gut." Whether the separation of exocrine and endocrine tissue in thecyclostomes is an original one or not remains an open phylogenetickey question. One or more islet hormones affect the exocrine pancreas tissue.However, the islet topography in various groups shows that intrapancreaticislet dissemination is not a general prerequisite for the normalfunction of the exocrine tissue. The D-cell is now generally recognized as the source of a thirdislet hormone. A fourth granular cell type (X-cell) may wellsecrete a fourth islet hormone. The significance of the amphiphilislet cells, found in various species, and of the "light" cellsof the cyclostomes requires further studies. The islet function in lower vertebrates is largely unknown.So far, neither the islet cytology nor the known effects ofpancreatectomy allow far-reaching conclusions. The evolutionof the islet functions may be only understood when their interactionswith the pituitary functions become clear.