Immunoreactivities of gastrin (G-) cells

Summary Results of immunocytochemical studies reported by several laboratories suggest that gastrin (G-) cells of the stomach show immunoreactivities for various pituitary hormones (ACTH, met-enkephalin, -endorphin and growth hormone) in addition to gastrin. By reinvestigating the immunocytochemistry of G-cells we found that these cells exhibited reactivities towards a variety of antisera against enteric, pancreatic and hypophyseal hormones. Gastrin cells can also be immunostained by antisera towards proteins unrelated to any peptide hormones (e.g. -fetoprotein antiserum) and by nonimmune sera. Thus the specificity of immunocytochemical findings in G-cells seems to be uncertain. According to our findings the polyvalent immunoreactivities of G-cells may be caused by a distinct binding capacity for IgG molecules. This binding of IgG to G-cells seems to be mediated by the Fab fragments of the IgG molecules which may behave like a basic dye and therefore immunostain anionic components within G-cells. Thus the significance of the immunocytochemical proof of peptide hormones within G-cells is limited unless extended specificity controls have been performed. The results of specificity controls performed in this study (adsorption controls, use of ascending dilutions of the primary and secondary antisera, comparison of crude antisera and affinity chromatographically purified antibodies) suggest that corticotropin-lipotropin related peptides are not contained in G-cells.Supported by a grant of the Deutsche Forschungsgemeinschaft, SFB 87-G2     

Immunoreactivities of gastrin (G-) cells

Summary Various gastro-entero-pancreatic (GEP) endocrine cells have been shown to contain concomitantly immunoreactivities against several peptide hormones. In the present study the immunoreactivities of gastrin (G-) cells of the rat stomach against 21 specific antisera and 10 control sera were investigated by means of the unlabelled antibody enzyme (PAP) technique using modifications of single steps in the immunocytochemical staining sequence. The results indicate that immunoglobulins can bind to gastrin cell granules obviously by non-specific ionic interactions. This non-specific binding of immunoglobulins occurs even in dilution ranges of the sera commonly used in immunohistochemical investigations of the GEP endocrine system. Since adsorption controls (preadsorption of the antisera with their respective antigens) will not discriminate between specific and nonspecific binding of immunoglobulins to GEP endocrine cells additional specificity controls are necessary. In contrast to the immunostaining of various GEP endocrine cells by established antisera and of G-cells by gastrin antiserum immunoglobulins of sera from non-immunized animals as well as antibodies against corticotropin-lipotropin related peptides could be displaced from their binding sites in G-cells by alterations of the NaCl content of the buffers used as diluents or as rinsing solutions. To exclude immunostaining of GEP endocrine cells by nonspecific binding of immunoglobulins the following working procedures are recommended for immunocytochemical investigations of these cells: 1. Use of high titer antisera at low concentrations (diluted 1:1,500 or more). 2. Elevation of the salt (NaCl) content up to 0.5 M of the buffer used as diluent or as rinsing solution. 3. Adsorption controls will show reliable results only if point 1. and 2. have been taken into account.Supported by the Deutsche Forschungsgemeinschaft (SFB 87-G2)     

Characterisation of multiple immunoreactive neurons in the central nervous system of the pond snail Lymnaea stagnalis with different fixatives and antisera adsorbed with the homologous and the heterologous antigens

Summary In the central nervous system of the pond snail Lymnaea stagnalis a large number of elements (cells and fibers) can be identified with antisera (a-FM) to the molluscan cardioactive tetrapeptide FMRFamide (Phe-Met-Arg-Phe-NH₂). Of these elements some are also reactive to antivasotocin (a-VT) and/or anti-gastrin (a-Gas). These observations suggest that the a-FM positive elements belong to more than one type. Previous results had already indicated that the immunoreactivity of many a-FM positive cells is influenced by the type of fixation. Taking into account the effects of three fixatives on the reactivity of the cells, and their staining characteristics with the two other antisera used, 8 a-FM positive types could be distinguished.Homologous and heterologous adsorptions were carried out to test the specificity of a-FM, a-VT and a-Gas. After homologous adsorptions no staining was obtained. After heterologous adsorptions only part of the multiple staining cells were identified. This indicates that in a-FM, a-VT and a-Gas in addition to (more) selective IgG molecules, less specific IgG molecules occur that can bind to other peptides than those used to raise the antisera (cross-reaction). The (more) selective IgG molecules in a-FM bind to 6 of the a-FM positive types, suggesting that in L. stagnalis a family of FMRFamide-like substances occurs. This conclusion is sustained by results obtained with a-FM adsorbed with fragments of FMRFamide. It appeared that the less selective IgG molecules in a-FM, a-VT and a-Gas cause the multiple stainings of those cells that remain unstained with an antiserum adsorbed with a heterologous antigen. Multiple staining, which can not be abolished by heterologous adsorption, probably is due to the binding of (more) selective IgG molecules to different antigenic determinants present in the cells.The results show that unexpected cross-reactions may occur in immunocytochemical staining procedures. It thus seems precarious to draw conclusions about the chemical structure of a peptide solely on the basis of immunocytochemical studies.     

Intracellular topography of glycine-extended pro-gastrin-processing intermediates in human antral mucosa: an electron-microscopic immunocytochemical study

To identify and characterize the subcellular topography of glycine-extended pro-gastrin-processing intermediates (G-Gly) in human antral mucosa, we performed an electron microscopic immunocytochemical study using region-specific antisera generated against the synthetic peptide, Tyr-Gly-Trp-Met-Asp-Phe-Gly (GL7), and C-terminal-specific anti-gastrin antisera. As has been previously reported, G-cells contained both electron-dense and electron-lucent granules, with a range of intermediate forms. Gastrin immunoreactivity was demonstrated in almost all granules of each type, whereas anti-GL7 antisera immunostained chiefly electron-dense granules. The relative ratio of GL7/gastrin granules varied among different cells but was approximately 1:10 on average. Other cytoplasmic organelles were devoid of specific labeling for GL7 or gastrin. As we have assumed that G-Gly serves as the immediate precursor for each molecular form of gastrin, electron-dense granules with high labeling for GL7 are regarded as the principal site for conversion of G-Gly to gastrin. This speculation supports many previous reports that electron-dense granules are immature and that the granules become less electron-dense with maturation.     

Endocrine cells and nerves in the stomach of the lizard Podarcis hispanica detected by immunocytochemistry

The general identification of endocrine cells in the stomach of the lizard Podarcis hispanica was carried out by their response to the Grimelius and Masson-Fontana techniques. 11 immunoreactive cell-types, positive for chromogranin-, serotonin-, caerulein/gastrin/ cholecystokinin (CAER/G/CCK)-, glucagon-like-peptide-1 (GLP-1)-. glucagon-, bombesin-,somatostatin-, pancreatic polypeptide (PP)-, peptide tyrosine tyrosine (PYY)-, neurotensin-and calcitonin gene related peptide (CGRP)- antisera were detected by immunocytochemical methods. Co-existence of glucagon with GLP-1, and PP with PYY were observed in some cells. Furthermore, immunoreactivities for members of gastrin and PP families were also found to co-exist in a few cells. In the muscular layer, vasoactive intestinal peptide (VIP)- and substance P-immunoreactive nerve fibers were also found.     

Residue-specific radioimmunoanalysis: a novel analytical tool. Application to the C-terminus of CCK/gastrin peptides

Five antisera directed against the common bioactive C-terminal tetrapeptide sequence of cholecystokinin (CCK) and gastrin were examined with respect to the significance of each residue for the antibody binding. Systematic substitutions and/or derivatizations of each of the four residues showed a unique pattern for each antiserum although they were raised against the same antigen and have the same sequence-specificity. The pattern of reactivity towards the related cardioexcitatory FMRF amide peptide, and analogues hereof confirmed the residue specificity of the antisera. While it is well known that even small covalent modifications of the antigen can influence the antibody binding profoundly, the great variations in significance of each residue among randomly selected antisera raised against the same antigen and specific for the same sequence has not been known so far. Hence, by appropriate combination of antisera their different residue specificity can be used for detection of amino acid substitutions or modifications. Such immunochemical sequence analysis requires only femto- or picomolar amounts of peptides, which need not necessarily be purified. Thus, residue-specific immunoanalysis may be a versatile tool in studies of species differences, phylogenesis and synthesis of peptides.     

Xenopsin immunoreactivity in antral G-cells may reside in the N-terminus of gastrin 17

The nature of xenopsin immunoreactivity in mammalian antral G-cells has been reassessed. Xenopsin immunostaining was most intense in human antral G-cells, present in those of the dog and pig and not detected in guinea pig or rat tissues. Rigorous specificity controls for ionic binding of immunoglobulins to antral G-cell granules indicated that this mechanism was not responsible for xenopsin immunostaining. Preincubation of the xenopsin antiserum with xenopsin, human gastrin 1-13 and gastrin 2-17 completely abolished immunostaining at similar molar concentrations. Gastrin 34 was ineffective at much higher concentrations. These results infer that xenopsin-immunoreactivity in antral G-cells resides in the N-terminal region of gastrin 17. Examination of the primary structures of xenopsin and the N-terminal regions of some mammalian gastrins reveals a hitherto unrecognized homology.     

Xenopsin immunoreactivity in antral G-cells may reside in the N-terminus of gastrin 17

Summary The nature of xenopsin immunoreactivity in mammalian antral G-cells has been reassessed. Xenopsin immunostaining was most intense in human antral G-cells, present in those of the dog and pig and not detected in guinea pig or rat tissues. Rigorous specificity controls for ionic binding of immunoglobulins to antral G-cell granules indicated that this mechanism was not responsible for xenopsin immunostaining. Preincubation of the xenopsin antiserum with xenopsin, human gastrin 1–13 and gastrin 2–17 completely abolished immunostaining at similar molar concentrations. Gastrin 34 was ineffective at much higher concentrations. These results infer that xenopsin-immunoreactivity in antral G-cells resides in the N-terminal region of gastrin 17. Examination of the primary structures of xenopsin and the N-terminal regions of some mammalian gastrins reveals a hitherto unrecognized homology.     

Immunoreactivity of the endocrine pancreas. Evidence for the presence of cholecystokinin-pancreozymin within the A-cell

Summary The pancreas of man and rat were investigated immunohistochemically on occurrence and distribution of the classical enterohormones gastrin, secretin and cholecystokinin-pancreozymin (CCK-PZ). Concomitantly insulin-, glucagon- and somatostatin-immunoreactive cells have been demon-strated. The unlabelled antibody-enzyme (PAP) method was the most specific and sensitive one when compared with the other immunohistochemical methods performed in this investigation (immunofluorescence, immunoperoxidase). The PAP method reveals reliable and reproducible results, running with high dilutions of antisera and showing a minimum of nonspecific background staining. Extended specificity controls are necessary in immunohistochemistry, however, to exclude nonspecific or crossreactive staining results. From the numerous specificity methods tested, we propose the use of sequential immunohistochemical staining with increasing dilutions of the antisera as an essential control. The use of specific antisera, previously adsorbed with related or corresponding antigens (hormones) as specificity tests should be regarded with some restrictions, at least in the PAP method. When possible a radioimmunological assay should be performed as a final proof of immunohistochemical findings. — The immunohistochemical findings of the present investigations have confirmed previous results of other authors concerning occurrence and distribution of insulin-, glucagon- and somatostatin-immunoreactive cells in the pancreas of rat and man. From the enterohormones gastrin, secretin and CCK-PZ only CCK-PZ (or a CCK-PZ-like peptide) was found to occur in the human and rat pancreas. The presence of CCK-PZ in the pancreas was also confirmed by radioimmunological estimations of CCK-PZ in the rat pancreas. The concentration of CCK-PZ-immunoreactive substance was about 1400 pg/g pancreatic tissue (wet weight) and about 1200 pg/g tissue in the small intestine of rats. Concerning the type of endocrine cells in the endocrine pancreas which contain CCK-PZ, it could be demonstrated that obviously the A-(glucagon) cells are immunoreactive to CCK-PZ. Thus A-cells may contain two polypeptide hormones of different molecular structure. These findings, in addition to other consequences of our results put the one cell — one hormone theory in question. — Gastrin- and secretin-immunoreactivity was also present in the A-cells. The immunohistochemical staining was only possible with the PAP method, however. These immunoreactivities in the endocrine pancreas have to be regarded as nonspecific ones, as proved by specificity controls. The secretin-immunoreactivity may be interpreted as a cross-reaction to the structurally similar glucagon. The gastrin-immunoreactivity might be a cross-reaction to the structurally similar CCK-PZ. In fact these cross-reactivities could only be observed in immunohistochemistry but not in the radioimmunoassay. — The occurrence of CCK-PZ, a classical enterohormone, in its target organ itself forces to reflections on the concept of endocrine and paracrine functions of entero-endocrine cells. Moreover, the functional unity of the endocrine pancreas and the gastrointestinal endocrine system on the one hand as well as the close interrelationships between the endocrine and the exocrine part of the pancreas on the other is emphasized by these findings.Supported by a grant of the German Research Foundation, SFB 87, Ulm, FRG     

Immunocytochemical technique for detection of prolactin (PRL) and growth hormone (GH) in hyperplastic and neoplastic lesions of dog prostate and mammary gland.

An immunocytochemical technique was described to test for immunoreactive prolactin (PRL) and growth hormone (GH) in spontaneous and experimentally induced hyperplastic and neoplastic lesions of the prostate and mammary gland. The dog was used as an animal model. The specificity and validity of the immunocytochemical staining procedure and of the antisera to canine PRL and canine GH can be regarded as established for the demonstration of PRL- and GH-dependent staining respectively. In mammary and prostatic tissues, both endogenous PRL and GH as well as intracellular free binding sites (for exogenous PRL and GH) were detected immunocytochemically. The technique presented seems to be an important tool to localize putative target sites for pituitary hormones in hormone-dependent hyperplasia and neoplasia.     

Relationship of glucagon-somatostatin and gastrin-somatostatin cells in the stomach of the monkey

The stomach of the monkey Tupaia belangeri was investigated by serial sections utilizing the indirect immunoperoxidase reaction to demonstrate the distribution of glucagon, gastrin and somatostatin immunoreactive cells. A striking topographical distribution was found. Glucagon and somatostatin immunoreactive cells were located in the upper parts, whereas gastrin and somatostatin immunoreactive cells were situated in the lower parts of the stomach. The remaining regions of the stomach did not contain cells immunoreactive to the antisera applied. Similarly, the ultrastructural study revealed the same distribution of endocrine cell types identified as A-cells, D-cells, and G-cells. Thus, there may be a glucagon-somatostatin area in the upper part and a gastrin-somatostatin endocrine surface in the lower part of the stomach. This spatial relationship of the endocrine cells suggests a functional cell interaction between glucagon and somatostatin cells in the cranial stomach and between gastrin and somatostatin in the caudal parts of the stomach.     

Gastrin/CCK-like immunoreactivity in the nervous system of coelenterates

Using immunocytochemistry, gastrin/CCK-like immunoreactivity is found in sensory nerve cells in the ectoderm of the mouth region of hydra and in nerve cells in the endoderm of all body regions of the sea anemone tealia. These results are corroborated by radioimmunoassay: One hydra contains at least 5 fmole and one tealia at least 2 nmole gastrin/CCK-like immunoreactivity. Reactivities towards gastrin and CCK antisera with different specificities suggest that the coelenterate gastrin/CCK-like peptide contains the C-terminal amino-acid sequence common to mammalian gastrin and CCK. In addition the radioimmunochemical data indicate that the coelenterate peptide also contains an amino-acid sequence that resembles the sequence 20-30 of porcine CCK-33, but that no other sequences of gastrin are present. Thus, it is probably more CCK-like than gastrin-like.     

Immunocytochemical localization of peptidergic neurons and neurosecretory cells in the neuro-endocrine system of the Colorado potato beetle with antisera to vertebrate regulatory peptides

A large number of antisera to regulatory vertebrate peptides was tested immunocytochemically on the nervous system of the Colorado potato beetle to further characterize the peptidergic cells of the neuro-endocrine system and to reveal cells participating in endocrine control mechanisms. Neurons, neurosecretory cells, axons and axon terminals were revealed by antisera to ACTH, gastrin, CCK, alpha-endorphin, beta-endorphin, gamma 1-MSH, insulin, motilin, human calcitonin, growth hormone, somatostatin, CRF, ovine prolactin and rat prolactin. Together with previously described results these findings demonstrate that at least 19 different peptidergic cell types are present in the Colorado potato beetle. Several of these cell types are identical with the known neurosecretory cells, while others have not been identified before. The functions of the immunoreactive neurons are as yet unclear, although in two cases the localization of these cells gives some clues. Thus the lateral neurosecretory cells, which are immunoreactive with antisera to beta-endorphin and ovine prolactin, may regulate corpus allatum activity, whereas a CRF immunoreactive substance seems to be used as neurotransmitter by antennal receptors. These immunocytochemical findings do not imply that the immunoreactive substances are evolutionarily related to the vertebrate peptides to which the antisera were raised. It is postulated that if the part of the substance recognized by a certain antiserum is functionally important for the insect, which should be so if the insect peptide is evolutionarily related to its vertebrate homologue, the antiserum should reveal homologous cells in different insect species. The consequence of this hypothesis is, that if an antiserum does not reveal homologous neurons in different insect species, the immunologically demonstrated substance is probably of little physiological importance, and will not be related evolutionarily to the vertebrate analogue. The positive immunocytochemical results in the Colorado potato beetle are discussed in relation to these considerations.     

Cellular origins of different forms of gastrin. The specific immunocytochemical localization of related peptides.

We have localized the antigenic determinants for the main forms of gastrin (big gastrin, G34, and little gastrin, G17) in hog antral mucosa using sequence specific antibodies and an indirect immunofluorescence technique. Populations of monospecific antibodies were obtained after affinity immunoadsorption to remove populations of unwanted specificity. The specificity of the purified antisera was established by direct binding of 125I labeled peptides to antisera at the same dilutions as those used in immunocytochemistry. The results indicate that in hog antral mucosa there is a single population of cells with the antigenic determinants of the C-terminal region of G17 and G34, the N-terminal region of G17, the N-terminal region of G34, and the intact G17 molecule. In duodenum there are cells with only C-terminal reactivity; since gastrin and CCK share a common C-terminal sequence it is concluded that this cell type contains CCK-like peptides rather than gastrin.     

Co-localization of xenopsin and gastrin immunoreactivity in gastric antral G-cells

Studies indicating evidence for the presence of the amphibian octapeptide xenopsin in gastric mucosa of mammals prompted us to investigate the cellular localization of this peptide. Using the peroxidase-antiperoxidase method and a specific antiserum to xenopsin (Xen-7) on paraffin and adjacent semithin sections of gastric antral mucosa from man, dog, and Tupaia belangeri, we found numerous epithelial cells showing a specific positive immunoreaction. These cells were of typical pyramidal shape and could be classified as of the "open" type. Cell quantification in serial sections processed for xenopsin and gastrin immunoreactivity, respectively, revealed an identical number of cells per section and an identical distribution of these cells in the middle zone of the antral mucosa. Furthermore, adjacent semithin sections demonstrated the colocalization of xenopsin and gastrin immunoreactivity within the same G-cell. The xenopsin antiserum could be completely absorbed with synthetic xenopsin but not with gastrin. Preabsorption tests with neurotensin, a xenopsin related peptide, or with somatostatin, glucagon, and enkephalins gave no evidence for crossreactivity of the xenopsin antiserum with these peptides. It is concluded that gastric antral G-cells in addition to gastrin also contain the amphibian peptide xenopsin.     

Chromogranin A, B and C immunoreactivities of mammalian endocrine cells. Distribution, distinction from costored hormones/prohormones and relationship with the argyrophil component of secretory granules

Antibodies specific for chromogranin A, B or C have been used to detect immunohistochemically these three anionic proteins. Pancreatic A, B and PP cells, gut argentaffin EC, argyrophil ECL and gastrin G cells, thyroid C cells, parathyroid cells, adrenal medullary cells, pituitary TSH, FSH and LH cells as well as some axons of visceral nerves have been found to react with chromogranin A antibodies. Pancreatic A, gut EC and G, adrenal medullary and pituitary cells as well as some gut nerve fibers showed chromogranin B immunoreactivity. Chromogranin C immunoreactivity has been detected in pancreatic A, pyloric D1, intestinal L, thyroid C, adrenal medullary and pituitary cells, as well as in some gut neurons and nerve fibers. No crossreactivity has been found in immunohistochemical tests between chromogranins A, B or C and costored monoamines or peptide hormones/prohormones, from which chromogranins can be separated by selective extraction during fixation. On both morphological and chemical grounds a relationship seems to exist between chromogranin A and Grimelius' argyrophilia. Sialooligosaccharide chains of chromogranin A and, possibly, chromogranins' phosphoserine/phosphothreonine groups, seem to interact with guanidyl, amino, and/or imidazole groups of non-chromogranin components to form silver complexing sites accounting for granules' argyrophilia, which can be removed or blocked without affecting chromogranin immunoreactivities. The abundant anionic groups of the three proteins should contribute substantially to granules' basophilia, the partly "masked" pattern of which supports the existence of a close interaction of such groups with other components of secretory granules, including monoamines and peptide hormones or prohormones. Chromogranins could play a r?le in hormone postranslational biosynthesis and intragranular packaging.     

Immunocytochemical localization of peptidergic neurons and neurosecretory cells in the neuro-endocrine system of the Colorado potato beetle with antisera to vertebrate regulatory peptides

Summary A large number of antisera to regulatory vertebrate peptides was tested immunocytochemically on the nervous system of the Colorado potato beetle to further characterize the peptidergic cells of the neuro-endocrine system and to reveal cells participating in endocrine control mechanisms. Neurons, neurosecretory cells, axons and axon terminals were revealed by antisera to ACTH, gastrin, CCK, -endorphin, -endorphin, 1-MSH, insulin, motilin, human calcitonin, growth hormone, somatostatin, CRF, ovine prolactin and rat prolactin. Together with previously described results these findings demonstrate that at least 19 different peptidergic cell types are present in the Colorado potato beetle. Several of these cell types are identical with the known neurosecretory cells, while others have not been identified before.The functions of the immunoreactive neurons are as yet unclear, although in two cases the localization of these cells gives some clues. Thus the lateral neurosecretory cells, which are immunoreactive with antisera to -endorphin and ovine prolactin, may regulate corpus allatum activity, whereas a CRF immunoreactive substance seems to be used as neurotransmitter by antennal receptors. These immunocytochemical findings do not imply that the immunoreactive substances are evolutionarily related to the vertebrate peptides to which the antisera were raised. It is postulated that if the part of the substance recognized by a certain antiserum is functionally important for the insect, which should be so if the insect peptide is evolutionarily related to its vertebrate homologue, the antiserum should reveal homologous cells in different insect species. The consequence of this hypothesis is, that if an antiserum does not reveal homologous neurons in different insect species, the immunologically demonstrated substance is probably of little physiological importance, and will not be related evolutionarily to the vertebrate analogue. The positive immunocytochemical results in the Colorado potato beetle are discussed in relation to these considerations.     

Occurrence of met-enkephalin,met-enkephalin-Arg6-Phe7 and met-enkephalin-Arg6-Gly7-Leu8 in gastrin cells of hog antral mucosa

Summary Region-specific antisera to three enkephalins: met-enkephalin, met-enkephalin-Arg⁶-Phe⁷ and met-enkephalin-Arg⁶-Gly⁷-Leu⁸, together with four region specific antisera to progastrin: C-terminal G17 specific, N-terminal G34 specific, cryptic peptides A- and B-specific, were used in immunohistochemical studies of hog antral mucosa. A sub-population (6–10%) of the gastrin-containing endocrine cells (G-cells) was found to react with antisera to met-enkephalin, met-enkephalin-Arg⁶-Phe⁷ and met-enkephalin-Arg⁶-Gly⁷-Leu⁸. About 30% of all the enkephalin-containing cells were identified as G-cells. The results indicate that a fraction of G-cells produces both enkephalin-like peptides and gastrin.     

Gastrin/CCK-like immunoreactivity in the nervous system of coelenterates

Summary Using immunocytochemistry, gastrin/CCK-like immunoreactivity is found in sensory nerve cells in the ectoderm of the mouth region of hydra and in nerve cells in the endoderm of all body regions of the sea anemone tealia. These results are corroborated by radioimmunoassay: One hydra contains at least 5 fmole and one tealia at least 2 nmole gastrin/CCK-like immunoreactivity. Reactivities towards gastrin and CCK antisera with different specificities suggest that the coelenterate gastrin/CCK-like peptide contains the C-terminal amino-acid sequence common to mammalian gastrin and CCK. In addition the radioimmunochemical data indicate that the coelenterate peptide also contains an amino-acid sequence that resembles the sequence 20–30 of porcine CCK-33, but that no other sequences of gastrin are present. Thus, it is probably more CCK-like than gastrin-like.     

Multiple peptide immunoreactivities in the nervous system of Aeschna cyanea (Insecta, Odonata). An immunohistochemical study using antisera to cholecystokinin octapeptide, somatoliberin, vasoactive intestinal peptide, motilin and proctolin

By use of the indirect immunoperoxidase method, the brain, the suboesophageal ganglion and the corpora cardiaca of the dragonfly Aeschna cyanea have been shown to be immunoreactive to proctolin antiserum and to several mammalian peptide antisera including unsulfated cholecystokinin octapeptide (CCK-8 NS) (Andriès et al. 1989), vasoactive intestinal peptide (VIP), human somatoliberin (hGRF) (Andriès et al. 1984) and motilin antisera. Immunohistochemical studies have been performed on material fixed in a solution of picricacid paraformaldehyde or in Bouin Hollande's sublimate solution. Antisera were applied on alternate sections or, according to the elution-restaining method of Tramu et al. (1978), one after another on the same section. Multiple peptide immunoreactivities appear expressed in the brain and the suboesophageal ganglion. Cells reactive to both hGRF and VIP antisera show also gastrin/CCK-like immunoreactivity and some of them are also detected by motilin antiserum. Besides, some cells immunopositive to CCK-8 NS and motilin antisera do not show hGRF or VIP immunoreactivity. At least, two pairs of protocerebral cells appear immunoreactive to both CCK-8 NS and proctolin antisera. Therefore, the present observations support our previously developed idea (Andriès et al. 1989) that the population of CCK-like cells is heterogenous.