Distribution and characterisation of somatostatin receptor mRNA and binding sites in the brain and periphery.

The distribution and nature of (somatostatin) SRIF receptors and receptor mRNAs was studied in the brain and periphery of various laboratory animals using in situ hybridisation, autoradiography and radioligand binding. The messenger RNA (mRNA) expression of SRIF receptors msst1, msst2, msst3, msst4 and msst5 was studied in the adult mouse brain by in situ hybridisation histochemistry using specific oligonucleotide probes and compared to that of adult rats. As observed in rat brain, sst3 receptor mRNA is prominently expressed across the mouse brain, although equivalent binding has not yet been identified in situ. Sst1 and sst2 receptor mRNA expression, was prominent and again comparable to that observed in rat brain, whereas sst4 and especially sst5 receptor mRNA show comparatively low levels, although the former appears to be widely distributed while the latter could only be identified in a few nuclei. Altogether, the data are compatible with current knowledge, i.e. sst1 and sst2 receptor mRNA is prominent (both receptors have been functionally identified in the brain and for sst2 in the periphery), sst3 mRNA is highly expressed but in the absence of any functional correlate remains elusive. The expression of sst4 mRNA is comparatively low (especially when compared to what is seen in the lung, where high densities of sst4 receptors are present) and it remains to be seen whether sst5 receptor mRNA, which is confined to a few nuclei, will play a role in the brain, keeping in mind that high levels are found in the pituitary. Radioligand binding studies were performed in CCL39 cells expressing the five human recombinant receptors and compared to binding in membranes of rat cerebral cortex with [125I]Tyr11-SRIF14 which in the presence of 120 mM labels primarily sst1 receptor as suggested by the better correlation hsst1 and similar rank order of potency. The profile of [125I]Tyr3-octreotide labelled sites in rat cortex correlates better with recombinant sst2 than sst3 or sst5 binding profiles. Finally, [125I]LTT-SRIF28-labelled sites in rat lung express a sst4 receptor profile in agreement with previous findings. SRIF receptor autoradiography was performed in the brain and peripheral tissue of rat and/or guinea-pig using a number of ligands known to label recombinant SRIF receptors: [125I]LTT-SRIF28, [125I]CGP 23996, [125I]Tyr10-CST, or [125I]Tyr3-octreotide. Although, [125I]Tyr10-CST has been shown to label all five recombinant SRIF receptors, it is apparent that this radioligand is not useful for autoradiographic studies. By contrast, the other three ligands show good signal to noise ratios in rat or guinea-pig brain, rat lung, rat pancreas, or guinea-pig ileum. In most tissues, [125I]Tyr3-octreotide represents a prominent part of the binding (when compared to [125I]LTT-SRIF28 and [125I]CGP 23996), suggesting that sst2 receptors are strongly expressed in most tissues; it is only in rat lung that [125I]LTT-SRIF28 and [125I]CGP 23996 show marked binding, whereas [125I]Tyr3-octreotide does apparently label no sites, in agreement with the sole presence of sst4 receptors in this tissue.     

High affinity binding sites for a somatostatin-28 analog in rat brain

Using an iodinated analog of a large (28 residues) and biologically active form of somatostatin, ¹²⁵I[Leu⁸,D-Trp²²,Tyr²⁵]SS-28, it was possible to demonstrate saturable and high affinity binding sites (dissociation constant = 0.46 ± 0.04 nM) in rat cortical membranes. Somatostatin, somatostatin-28, as well as two potent analogs, [D-Trp⁸] somatostatin and [D-Trp²²] somatostatin-28, could completely displace the radiogland in the nanomolar range whereas the inactive analog Des-Trp⁸-somatostatin and the unrelated peptide GnRH showed no affinity for these binding sites; octa- and nona-peptide analogs of somatostatin were inactive. High binding was found in hippocampus, amygdala, tuberculum olfactorium, caudate-putamen and cortex; moderate binding in midbrain and hypothalamus, and no binding in the cerebellum. These results suggest that specific somatostatin receptors can be measured within the brain with ¹²⁵I[Leu⁸,D-Trp²²,Tyr²⁵] SS-28 as radioligand.     

Characterization of somatostatin binding sites in isolated rat adipocytes

Somatostatin binding sites were characterized in isolated rat adipocytes. The binding was found to be saturable, reversible, and time- and temperature-dependent. The somatostatin binding sites are principally located on the cell surface. 125I-[Tyr11]somatostatin binding was not inhibited by glucagon and angiotensin II. By contrast, native somatostatin and somatostatin-28 displaced labeled peptide with a similar ED50: 50 nM. Scatchard analysis pointed to the existence of two classes of binding sites, with a Kd of 7.64 nM for the high-affinity sites and a Kd of 295 nM for the low-affinity ones. Comparison of somatostatin receptor binding and its lipolytic action in isolated rat adipocytes suggested that the spare receptor phenomenon cannot be applied to the lipolytic action of somatostatin in rat adipose tissue.     

Pituitary somatostatin receptors. Characterization by binding with a nondegradable peptide analogue

Somatostatin receptors in the rat pituitary gland were characterized by binding analysis with a radioiodinated high affinity somatostatin analogue, 125I-Tyr1[D-Trp8]somatostatin. Receptor binding of this derivative reached equilibrium at 30 min and was maintained at a plateau for at least 60 min. Two L-Trp8- labeled somatostatin analogues. 125I-Tyr1- and [125I-Tyr11]somatostatin, displayed less stable and lower specific uptake and higher nonspecific binding. In contrast to the rapid degradation of the L-Trp8 ligands during binding assay, 125I-Tyr1]D-Trp8]somatostatin retained more than 80% of its binding activity after 90 min of incubation with pituitary particles. Pituitary particles bound 125I-Tyr1]D-Tyr8]somatostatin with high affinity (Ka = 8.6 +/- 1.2 X 10(9) M-1) and capacity of 54.4 +/- 2.6 fmol/mg. These binding sites showed specificity for the native peptide and its active analogues, and other peptide hormones, including angiotensin II, thyrotropin-releasing hormone, vasopressin, oxytocin, substance P, and gonadotropin-releasing hormone, did not inhibit tracer binding. A good correlation was observed between the binding affinities of several somatostatin analogues and their potencies as inhibitors of growth hormone release in rat pituitary cells. These findings emphasize the physiological importance of the pituitary somatostatin receptor in mediating the inhibitory action of the peptide on growth hormone release. The use of Tyr1[d-Trp8]somatostatin as a labeled ligand permits accurate determinations of the binding affinity and concentration of receptors for somatostatin in the normal pituitary gland and provides a basis for further studies of somatostatin receptor regulation and receptor-mediated cellular effects of the tetradecapeptide.     

Atrial natriuretic factor (ANF) binding sites in brain and related structures

Visualization of [¹²⁵I]ANF binding sites in rat brain by an autoradiographic technique demonstrated that these sites are highly localized in areas such as the olfactory bulb, subfornical organ, area postrema and nucleus tractus solitarius. This distribution suggests that certain cardiovascular effects of ANF could be centrally mediated and that the existence of brain ANF-related peptides should be considered. Finally, moderate densities of [¹²⁵I]ANF binding sites are found in the rat and guinea pig eye while low densities are seen in pituitary and pineal gland.     

Atrial natriuretic peptide binding sites in the brain and pituitary gland of the toad, Bufo marinus: localisation and receptor characterisation

The distribution and nature of 125I-atrial natriuretic peptide binding sites have been examined in the brain and pituitary gland of the toad, Bufo marinus, using tissue section autoradiography, affinity cross-linking and electrophoresis, guanylyl cyclase assays and molecular analysis of natriuretic peptide receptor C (NPR-C) and NPR-GC mRNA expression. The highest density of 125I-atrial natriuretic peptide binding sites occurred in the dorsal pallium, the habenular region, the torus semicircularis, the choroid plexus, and the pituitary gland. Less dense binding was observed in the medial pallium, the thalamic region, the hypothalamus, the optic tectum, and the interpeduncular nucleus. The natriuretic peptide receptor-C specific ligand, C-ANF, displaced the binding in all brain regions; however, some residual binding was observed in the habenular region, the hypothalamus, the choroid plexus, and the pituitary gland. In isolated brain membranes, 1 microM rat atrial natriuretic peptide increased cyclic guanosine monophosphate levels to 90% above basal. Affinity cross-linking followed by reducing electrophoresis showed that 125I-atrial natriuretic peptide bound to proteins of 65 kDa and 135 kDa respectively. Furthermore, molecular analysis demonstrated that natriuretic peptide receptor-C and guanylyl cyclase messenger ribonucleic acid are expressed in the brain. In combination with the autoradiography, the data indicated that atrial natriuretic peptide acting via specific receptors could be important in natriuretic peptide regulation of the brain.     

Radioautographic localization of somatostatin-14 and somatostatin-28 binding sites in the rat brain

Somatostatin-14 (S14) and its precursor, somatostatin-28 (S28), are widely distributed throughout the rat brain, suggesting that they could act as neurotransmitter or neuromodulator in the central nervous system. The present study was undertaken to study the localization of S14 and S28 receptors in the rat brain determined by "in vitro" radioautography. The study performed on slide mounted frozen brain section with iodinated S14 and S28 analogs revealed an identical distribution of binding sites for the two forms of somatostatin. A good correlation could be observed between receptor distribution and immunohistologically localized neuropeptides except for striatum and hypothalamus. However, receptors were not detectable in the hypothalamus and were found in low concentration in the caudate-putamen nucleus, two regions containing high amounts of S28 and S14, suggesting a high occupancy of receptors in these areas by endogenous peptides or an inverse correlation between receptor and peptide concentrations.     

Autoradiographic localization of peptide YY and neuropeptide Y binding sites in the medulla oblongata

Peptide YY is a highly potent emetic when given intravenously in dogs. We hypothesized that the area postrema, a small brain stem nucleus that acts as a chemoreceptive trigger zone for vomiting and lies outside the blood-brain barrier, might have receptors that PYY would bind to, in order to mediate the emetic response. We prepared [125I]PYY and used autoradiography to show that high affinity binding sites for this ligand were highly localized in the area postrema and related nuclei of the dog medulla oblongata. Furthermore, the distribution of [125I]PYY binding sites in the rat medulla oblongata was very similar to that in the dog; the distribution of [125I]PYY binding sites throughout the rat brain was seen to be similar to the distribution of [125I]NPY binding sites.     

The Elusive Nature of Cerebellar Somatostatin Receptors: Studies in Rat,Monkey and Human Cerebellum

Abstract

The pharmacological profile and localization of somatostatin (SRIF) receptors were determined in rat, monkey and human cerebellum. In rat cerebellar cortex, low ss₁/sst₄, intermediate sst₂ and very high sst₃ receptor mRNA levels were found, sst₁ mRNA was also expressed in the deep cerebellar nuclei. [¹²⁵I]Tyr³-octreotide binding sites in cerebellar membranes correlated with recombinant sst₂, but not with sst₅ or sst₃ receptors and were found in the molecular layer of the cerebellum. [¹²⁵I]CGP 23996 (in Na⁺-buffer) binding in rat cerebellum correlated with sst₁ or sst₄, but not with sst₂, sst₃ or sst₅ receptor binding. Similar data were obtained in rhesus monkey cerebellum. mRNAs for all five receptors were found in the granule cell layer of the human cerebellum and/or in the dentate nucleus. [¹²⁵I]Tyr³-octreotide binding was strong in the molecular layer and correlated with that of recombinant sst₂ receptors, but not with sst₃ or sst₅ receptors. [¹²⁵I]CGP 23996 (in Mg⁺⁺-buffer) binding was heterogeneous (about 75%. to sst₂ and 25% to sst₁ and/or sst₄ receptors). The molecular and granular layers were equally and the dentate nucleus strongly labeled. Thus. SRIF receptors of the sst₂, sst₁ and/or sst₄ subtype are present in the rat, monkey and human cerebellum. In the latter two species, the sst₂ type appears to be predominant. Surprisingly, the high expression of sst₃ receptor mRNA is not supported by radioligand binding data in any of the species studied. The reason for this discrepancy remains to be elucidated.     

Characterization of somatostatin binding sites in cytosolic fraction of rat intestinal mucosa

Specific binding sites for somatostatin have been characterized in cytosolic fraction of rat intestinal mucosa by using 125I-labelled Tyr11-somatostatin and a variety of physicochemical conditions. The binding depended on time, temperature and pH, and was reversible, saturable and specific. At apparent equilibrium, the specific binding of 125I-Tyr11-somatostatin was competitively inhibited by native somatostatin in the 1 nM-4 microM concentration range. Binding studies suggested the presence of two classes of binding sites: a class with high affinity (Kd = 0.07 microM) and low capacity (4.6 pmol/mg protein) and a class with low affinity (Kd = 1.05 microM) and high capacity (277 pmol/mg protein) at 25 degrees C. Somatostatin exhibited competitive inhibition of tracer binding, while neuropeptides such as neurotensin, substance P, Leu-enkephalin, and vasoactive intestinal peptide were ineffective. The presence of somatostatin binding sites in cytosolic fraction of intestinal mucosa, together with the known occurrence of somatostatin in D-cells and nerve endings in the small intestine, strongly suggest that this peptide may be involved in the physiology and physiopathology of intestinal epithelium.     

Leu31-Pro34] neuropeptide Y identifies a subtype of 125I-labeled peptide YY binding sites in the rat brain.

Subtypes of the neuropeptide Y (NPY) receptor in the rat brain were identified by the use of the selective Y-1 analog, [Leu34-Pro34] NPY. In rat brain homogenate binding studies, [Leu31-Pro34] NPY was found to produce a partial inhibition of 100 pM 125I-labeled peptide YY (PYY) binding with a plateau at 50-1000 nM [Leu31-Pro34] NPY resulting in a 70% inhibition of binding. The C-terminal fragment NPY 13-36, a putative Y-2 agonist, exhibited very little selectivity in rat brain homogenates. Scatchard analysis of 125I-labeled PYY binding to rat brain homogenate yielded biphasic plots with Kd values of 40 and 610 pM. Inclusion of 100 nM [Leu31-Pro34] NPY was found to eliminate the low affinity component of 125I-labeled PYY binding leaving a single, high affinity binding site with a Kd of 68 pM. In autoradiographic studies, displacement curves indicated that [Leu31-Pro34] NPY completely inhibited binding in the cerebral cortex with little effect on the binding in the hypothalamus. On the other hand NPY 13-36 inhibited binding in the hypothalamus at low concentrations but required higher concentrations to inhibit binding in the cerebral cortex. Other brain regions such as the hippocampus, appeared to contain both subtypes. Subsequent to these studies, a quantitative autoradiographic map was conducted using 50-100 pM 125I-labeled PYY in the presence and absence of [Leu31-Pro34] NPY which produced a selective displacement of binding in certain distinct brain regions. These areas included the cerebral cortex, certain thalamic nuclei and brainstem while ligand binding was retained in other brain regions including the zona lateralis of the substantia nigra, lateral septum, nucleus of the solitary tract and the hippocampus. Numerous brain regions appeared to contain both receptor subtypes. Therefore, the Y-1 and Y-2 receptor subtypes exhibited a somewhat distinct distribution in the brain. In addition, 125I-labeled PYY appears to label the Y-2 receptor with relatively higher affinity when compared to the Y-1 receptor.     

Evidence for a new subclass of calcitonin/ calcitonin gene-related peptide binding site in rat brain

Binding sites for calcitonin and calcitonin gene-related peptide are widely distributed in the central nervous system. In this study, binding of [¹²⁵I]-alpha-rat calcitonin gene-related peptide and [¹²⁵I]-salmon calcitonin in adjacent sections of rat brain revealed clearly distinct patterns of binding in most regions although in some restricted areas such as parts of the ventral striatum, including the nucleus accumbens, there was some overlap in the patterns of binding. In the primary olfactory cortex, which bound only calcitonin gene-related peptide, salmon calcitonin was very weak in inhibiting the binding of calcitonin gene-related peptide. In the nucleus accumbens, high affinity binding of calcitonin and calcitonin gene-related peptide at their homologous receptors was observed, with affinity constants for calcitonin and calcitonin gene-related peptide of 1.4 × 10⁹ M⁻¹ and 1.2 × 10⁹ M⁻¹ respectively. Cross competition studies in this nucleus demonstrated that salmon calcitonin was able to compete for [¹²⁵I]-rat calcitonin gene-related peptide labelled sites with high affinity, with an affinity constant of 0.8 × 10⁹ M⁻¹. However, rat calcitonin gene-related peptide was less potent in inhibiting the binding of [¹²⁵I]-salmon calcitonin labelled sites with only 28% inhibition at 10⁻⁶M. Further characterization of the calcitonin sensitive calcitonin gene-related peptide labelled sites demonstrated that a range of calcitonin analogs inhibited the binding of [¹²⁵I]-rat calcitonin gene-related peptide with the same order of potency as the analogs competed for [¹²⁵I]-salmon calcitonin labelled sites. Digital substraction mapping revealed calcitonin-sensitive calcitonin gene-related peptide binding sites over parts of the ventral striatum, including mid-caudal nucleus accumbens and fundus striati; over the lateral border of the lateral bed nucleus of the stria terminalis; part of the central amygdaloid nucleus; the organum vasculosum of the lamina terminalis and area postrema and over the wings of the dorsal raphe.These results demonstrate the existence of a new subtype of calcitonin/calcitonin gene-related peptide binding site, which has high affinity for the two otherwise biochemically distinct peptides.     

The binding of bombesin and somatostatin and their analogs to human colon cancers.

Specific receptors for bombesin/gastrin-releasing peptide, somatostatin, and EGF were investigated in 15 human colon cancer specimens. Eight of 15 clinical specimens (15%) of colon cancer showed the presence of somatostatin receptors. Octapeptide somatostatin analogs, RC-160 and RC-121, showed 10 times higher binding affinity for somatostatin receptors on colon cancer membranes than somatostatin. Analysis of 125I-Tyr4-bombesin binding data revealed the presence of specific binding sites in six (40%) specimens of human colon cancer. Scatchard analysis of 125I-labeled bombesin indicated a single class of receptors in three specimens with an apparent Kd value of 2.5 nM and two classes of receptors with high (Kd = 0.4 +/- 0.2 nM) and low affinity (Kd = 1.6 +/- 0.4 microM) in three other specimens. The 125I-Tyr4-bombesin binding capacities in the colon cancers for high affinity binding sites were from 6 to 228 fmol/mg protein and for low affinity binding sites 76 +/- 15 pmol/mg protein. None of the membrane preparations made from normal colonic mucosa specimens showed specific binding for 125I-Tyr4-bombesin. Five pseudononapeptide (psi 13-14) bombesin (6-14) antagonists, with different modifications at Positions 6 and 14, synthesized in our laboratory, inhibited the binding of 125I-Tyr4-bombesin in nanomolar concentrations. No correlation was found between the degree of differentiation and the presence of binding sites for somatostatin or bombesin. Specific binding of EGF was detected in 80% of colon cancer specimens. EGF binding capacity in colon cancer membranes was on average twice as high as in normal colon mucosa (50 +/- 21 vs 28 +/- 14 fmol/mg protein, respectively). Specific binding sites for somatostatin and EGF, but not bombesin, were also demonstrated in human colon cancer cell line HT-29. In HCT-116 colon cancer line only EGF receptors were found. These receptor findings and our in vivo studies on inhibition of colon cancer growth support the merit of continued evaluation of somatostatin analogs and bombesin/gastrin-releasing peptide antagonists in the management of colonic carcinoma.     

Interactions between the antiopiate Tyr-MIF-1 and the mu opiate morphiceptin at their respective binding sites in brain

The interactions between Tyr-MIF-1, a brain peptide with antiopiate activity, and the beta-casomorphins, a family of peptides derived from milk protein with opiate activity, were investigated by in vitro binding assays. Specific binding of 125I-Tyr-MIF-1 to rat brain membranes was displaced with high potency by beta-casomorphin, morphiceptin, and the morphiceptin analog PL017 but not by the analgesically inactive analog D-Pro2-morphiceptin or by several other ligands for classical delta, kappa, or sigma opiate receptors. In addition, Tyr-MIF-1 displaced 125I-morphiceptin from its binding sites in brain with affinities similar to those of unlabeled morphiceptin and PL017. These results, which include the first demonstration of a binding site in brain for labeled morphiceptin, indicate that brain antiopiate Tyr-MIF-1 and the beta-casomorphin derived peptides with opiate activity may share a common binding site or cross-react at each other's site. This suggests a possible mechanism of action for endogenous antiopiate-opiate interactions.     

Angiotensin II binding to mammalian brain membranes.

High affinity binding sites for angiotensin II in bovine and rat brain membranes have been identified and characterized using monoiodinated Ile5-angiotensin II of high specific radioactivity. Degradation of labeled and unlabeled peptide by washed brain particulate fractions was prevented by adding glucagon to the final incubation medium and including a proteolytic enzyme inhibitor (phenylmethylsulfonyl fluoride) in preincubation and incubation procedures. 125I-Angiotensin II binding can be studied using either centrifugation or filtration techniques to separate tissue-bound radioactivity. 125I-Angiotensin II binding to calf brain membranes is saturable and reversible, with a dissociation binding constant of 0.2 nM at 37 degrees. A similar binding constant is found in rat brain membranes. Analogues and fragments of angiotensin II compete for these brain binding sites with potencies which correlate with both their in vivo potencies and their binding inhibition protencies at adrenal cortex angiotensin II receptors. Angiotensin I is 1 to 2 orders of magnitude weaker than angiotensin II; the 3-8 hexapeptide and 4-8 pentapeptide are much weaker still. (desAsp1) angiotensin II (angiotensin III) is slightly more potent than angiotensin II, as are several antagonists of angiotensin II with aliphatic amino acids substituted at position 8. In calf brain 125I-angiotensin II binding is restricted almost exclusively to the cerebellum (cortex and deep nuclei). In rat brain, angiotensin II binding is highest in the thalamus-hypothalamus, midbrain, and brainstem, areas which are believed to be involved in mediating angiotensin II-induced central effects. These findings illustrate the presence of high affinity specific binding sites for angiotensin II in rat and bovine brain and suggest a physiological role for angiotensin peptides in the central nervous system.     

Neuropeptide Y (NPY) and peptide YY (PYY) receptors in rat brain

1. Specific binding sites for neuropeptide Y (NPY) and peptide YY (PYY) were investigated in rat brain areas using quantitative receptor autoradiography with 125I-Bolton-Hunter NPY (125I-BH-NPY) and 125I-PYY, radioligands for PP-fold family peptides receptors. 2. There were no differences between localization of 125I-BH-NPY and 125I-PYY binding sites in the rat brain. High densities of the binding sites were present in the anterior olfactory nucleus, lateral septal nucleus, stratum radiatum of the hippocampus, posteromedial cortical amygdaloid nucleus, and area postrema. 3. In cold ligand-saturation experiments done in the presence of increasing concentrations of unlabeled NPY and PYY, 125I-BH-NPY and 125I-PYY binding to the stratum radiatum of the hippocampus, layer I of the somatosensory frontoparietal cortex, molecular layer of the cerebellum, and area postrema was single and of a high affinity. There was a significant difference between the affinities of 125I-BH-NPY (Kd = 0.96 nM) and 125I-PYY binding (Kd = 0.05 nM) to the molecular layer of the cerebellum. The binding of the two radioligands to the other areas examined had the same affinities. 4. When comparing the potency of unlabeled rat pancreatic polypeptide (rPP), a family peptide of NPY and PYY, to inhibit the binding to the areas examined, rPP displaced 125I-BH-NPY and 125I-PYY binding to the area postrema more potently than it did the binding to the stratum radiatum of the hippocampus, layer I of the somatosensory frontoparietal cortex, and molecular layer of the cerebellum. 5. Thus, the quantitative receptor autoradiographic method with 125I-BH-NPY and 125I-PYY revealed differences in binding characteristics of specific NPY and PYY binding sites in different areas of the rat brain. The results provide further evidence for the existence of multiple NPY-PYY receptors in the central nervous system.     

Regional distribution of somatostatin receptor affinity states in rat brain: effects of divalent cations and GTP

In the present work, we have characterized by film radioautography the effects of divalent cations and guanine nucleotide on specific receptor for somatostatin (SRIF) using 125I-TyrO-DTrp8-SRIF14 (125I-ToD8-SRIF) as a ligand. The experiments were performed on coronal 20-microM-thick sections cut at the level of the amygdala, thus allowing to study binding sites in several regions enriched in binding sites (frontal cortex, hippocampus CA1 and dentate gyrus, habenula, basolateral nucleus of the amygdala). In a preliminary set of experiments using brain cortical membranes it was found that 3 mM Mg2+ ions doubled the specific binding of 125I-ToD8-SRIF. However, Mg2+ enhanced equally by a factor of 3 affinities of high- and low-affinity binding sites as evidenced by SMS 201.995 displacement curves without modifying the ratio between high and low affinity sites. In radioautographic studies while SRIF14 and SRIF28 elicited monophasic displacement curves, SMS 201.995 displaced 125I-ToD8-SRIF binding in a biphasic manner in all regions tested but the baso-lateral nucleus of the amygdala. Radioautographic distribution of 125I-ToD8-SRIF binding sites was identical whether the sections were incubated with MgCl2 or with MnCl2 and almost undetectable in the absence of ions. In all structures investigated increasing concentrations of GTP totally inhibited 125I-ToD8-SRIF binding with an IC50 value of 3 microM. In conclusion, our results demonstrate that 125I-ToD8-SRIF-binding sites in brain occur on two different affinity states as assessed by a displacement curve using endogenous ligands and SMS 201.995. According to the comparable effects of divalent cations and GTP, the two subtypes of 125I-ToD8-SRIF-binding sites discriminated by SMS 201.995 are likely to correspond to interconvertible forms of the same receptor coupled to a G protein-transducing system.     

Evidence for somatostatin binding sites in rabbit kidney

Specific binding sites for somatostatin have been identified in cytosolic fraction of rabbit kidney (cortex and outer medulla) using 125I-Tyr11-somatostatin. The binding was saturable and reversible, as well as time and temperature dependent. Optimal pH for binding was observed at about 7.4. Scatchard plots were compatible with the existence of two classes of binding sites: a first class with a high affinity (Kd = 40 nM) and a low binding capacity (2.0 pmol somatostatin/mg protein) and a second class with a low affinity (Kd = 222 nM) and a high binding capacity (114.3 pmol somatostatin/mg protein). Vasoactive intestinal peptide, neurotensin, substance P, Leu-enkephalin and vasopressin had practically no effect on somatostatin binding. The properties of these binding sites strongly support the concept that somatostatin could behave as a regulatory peptide on the rabbit kidney.     

Analogues of Somatostatin Bind Selectively to Brain Somatostatin Receptor Subtypes

Somatostatin (SRIF) is a neurotransmitter that produces its multiple effects in the CNS through interactions with membrane-bound receptors. Subtypes of SRIF receptors are found in the CNS that are distinguished by their sensitivities to the cyclic hexapeptide MK-678, such that SRIF1 receptors are sensitive to MK-678 and SRIF2 receptors are insensitive to MK-678. In the present study, we further examined the selectivities of a series of structurally diverse SRIF analogues for SRIF receptor subtypes. SRIF receptors were labeled by 125I-Tyr11-SRIF, which has indistinguishable affinities for SRIF receptor subtypes. The inhibition by MK-678 was incomplete, indicating this peptide is highly selective for a subtype of SRIF receptor that we have termed the SRIF1 receptor. The binding of 125I-MK-678 to SRIF1 receptors was monophasically inhibited by SRIF, the octapeptides (such as SMS-201-995), and the hexapeptides (such as MK-678), consistent with the highly selective labeling of a subtype of SRIF receptor. In contrast, the smaller CGP-23996-like analogues did not inhibit 125I-MK-678 binding to SRIF1 receptors. The binding of 125I-CGP-23996 to SRIF receptors was inhibited by SRIF and the octapeptides with Hill coefficients of less than 1, indicating that 125I-CGP-23996 labels multiple SRIF receptor subtypes. The hexapeptides and CGP-23996-like compounds produced only partial inhibitions of 125I-CGP-23996 binding, which were additive, indicating selective interactions of these compounds with the different receptor subpopulations labeled by 125I-CGP-23996. 125I-Tyr11-SRIF binding and 125I-CGP-23996 binding to SRIF receptors were likewise only partially affected by 100 microM guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S), a concentration that completely abolishes specific 125I-MK-678 binding to SRIF1 receptors. The component of 125I-CGP-23996 labeling that was sensitive to GTP gamma S was also MK-678 sensitive. Thus, two subpopulations of SRIF receptors exist in the CNS. The SRIF1 receptor is sensitive to cyclic hexapeptides such as MK-678 and to GTP gamma S but insensitive to smaller CGP-23996-like compounds. The SRIF2 receptor is sensitive to the CGP-23996-like compounds and can be selectively labeled by 125I-CGP-23996 in the presence of high concentrations of the hexapeptides or GTP gamma S because, unlike the SRIF1 receptor, the SRIF2 receptor is insensitive to these agents. The SRIF receptor subtype-selective peptide analogues will be useful in the future characterization of the functions mediated by SRIF receptor subtypes in the CNS.     

Characterization, distribution and plasticity of atrial natriuretic factor binding sites in brain

The [125I]iodotyrosyl derivative of atrial natriuretic factor [( 125I])ANF) apparently binds to a single class of high affinity sites in guinea pig brain membrane preparations. Ligand selectivity pattern reveals that the structural requirements of brain [125I]ANF binding sites are similar to those reported in most peripheral tissues. In vitro receptor autoradiographic studies demonstrate that the brain distribution of [125I]ANF binding sites is species dependent. In rat, high levels of binding are found in olfactory bulb, subfornical organ, area postrema, choroid plexus, and ependyma. In guinea pig, these regions are also enriched with [125I]ANF binding in addition to various thalamic nucleic, amygdala, hippocampus, and cerebellum. In monkey, high densities of sites are seen in the cerebellar cortex. This suggests that brain ANF receptor sites could mediate ANF effects related to the central integration of cardiovascular parameters, as well as other actions not associated with these systems. As in the periphery, it appears that brain [125I]ANF binding sites are associated with guanylate cyclase. Moreover, the density of [125I]ANF receptor binding sites is altered in certain brain regions in spontaneously hypertensive rats and in cardiomyopathic hamsters, demonstrating the plasticity of brain ANF receptors. Thus, ANF and ANF receptors are complementary facets of a new neurotransmitter-neuromodulator system present in mammalian brain.