Minimal ligand analysis of gastrin releasing peptide. Receptor binding and mitogenesis

Gastrin releasing peptide (GRP) is a peptide hormone containing 27 amino acids which is structurally analogous to the amphibian peptide bombesin. GRP serves a variety of physiological functions and has been implicated in the pathophysiology of small cell lung cancer. Previous work has demonstrated that the modified C terminus of GRP, N-acetyl-GRP-20-27, exerts full agonist activity in a variety of assay systems. However, no systematic comparison of binding of GRP fragments to its receptor and mitogenic potency has been reported. To investigate whether smaller GRP fragments could bind to the GRP receptor without stimulating mitogenesis, we performed binding inhibition and thymidine uptake assays with Swiss 3T3 fibroblasts. These studies were facilitated by the development of a novel tritiated GRP-based radioligand, [3H-Phe15] GRP-15-27, which exhibits enhanced chemical stability compared to iodinated GRP derivatives. We examined a series of C-terminal GRP fragments, from the pentapeptide to the octapeptide, with both N-acetyl and free amine moieties at the N terminus. N-Acetylated derivatives were more potent than their primary amine counterparts in both assays. Deletion of N-terminal residues from GRP-20-27 resulted in significant loss of potency in both assays: the EC50 values of N-acetyl-GRP-21-27 were 10(2)-fold higher than N-acetyl-GRP-20-27, those of N-acetyl-GRP-22-27 were 10(4)-fold higher, and N-acetyl-GRP-23-27 showed minimal activity at concentrations below 100 microM. These results suggest that 1) both His20 and Trp21 play an important role in binding of GRP to the receptor, and 2) for this series of N-terminal deletions, binding to the receptor and mitogenic activity are tightly coupled.     

Biological effects and receptor binding affinities of new pseudononapeptide bombesin/GRP receptor antagonists with N-terminal D-Trp or D-Tpi.

In an attempt to produce more powerful (effective) bombesin/GRP receptor antagonists, the D forms of Trp or Trp analog (Tpi) were introduced at position 6 in two pseudononapeptides, Leu13 psi (CH2NH)Leu14-bombesin(6-14) and Leu13 psi(CH2NH)Phe14-bombesin (6-14). These antagonists were tested for their ability to inhibit basal and gastrin releasing peptide (GRP) (14-27)-induced amylase release from rat pancreatic acini in a superfusion assay. They were also assessed for the inhibition of 125I-Tyr4-bombesin binding to Swiss 3T3 and small cell lung carcinoma cell line H-345 and the mitogenic response of Swiss 3T3 cells induced by GRP(14-27). The peptides, when given alone, did not stimulate amylase secretion, but were able to inhibit gastrin releasing peptide (14-27)-induced amylase release. All of the antagonists showed strong binding affinities for Swiss 3T3 and H-345 cells and suppressed the GRP(14-27)-induced increase of [3H]thymidine incorporation into DNA of Swiss 3T3 cells at nanomolar concentrations. Antagonist D-Tpi6,Leu13 psi (CH2NH)Leu14-bombesin (6-14)(RC-3095) was slightly more potent in these assays than D-Trp6,Leu13 psi (CH2NH)Leu14-bombesin (6-14)(RC-3125). Nevertheless, D-Trp6,Leu13 psi (CH2NH)Phe14-bombesin (6-14) showed the highest binding affinity for Swiss 3T3 and H345 cells and it was the most potent inhibitor of GRP(14-27)-induced amylase secretion. This antagonist RC-3420 was particularly effective in inhibiting the growth of Swiss 3T3 cells, exhibiting an IC50 value less than 1 nM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Gastrin-releasing peptide and cancer

Over the past 20 years, abundant evidence has been collected to suggest that gastrin-releasing peptide (GRP) and its receptors play an important role in the development of a variety of cancers. In fact, the detection of GRP and the GRP receptor in small cell lung carcinoma (SCLC), and the demonstration that anti-GRP antibodies inhibited proliferation in SCLC cell lines, established GRP as the prototypical autocrine growth factor. All forms of GRP are generated by processing of a 125-amino acid prohormone; recent studies indicate that C-terminal amidation of GRP18-27 is not essential for bioactivity, and that peptides derived from residues 31 to 125 of the prohormone are present in normal tissue and in tumors. GRP receptors can be divided into four classes, all of which belong to the 7 transmembrane domain family and bind GRP and/or GRP analogues with affinities in the nM range. Over-expression of GRP and its receptors has been demonstrated at both the mRNA and protein level in many types of tumors including lung, prostate, breast, stomach, pancreas and colon. GRP has also been shown to act as a potent mitogen for cancer cells of diverse origin both in vitro and in animal models of carcinogenesis. Other actions of GRP relevant to carcinogenesis include effects on morphogenesis, angiogenesis, cell migration and cell adhesion. Future prospects for the use of radiolabelled and cytotoxic GRP analogues and antagonists for cancer diagnosis and therapy appear promising.     

Bombesin-like peptides elevate cytosolic calcium in small cell lung cancer cells

The ability of bombesin-like peptides to elevate intracellular Ca2+ levels in small cell lung cancer cells was investigated using the fluorescent Ca2+ indicator Fura 2. Nanomolar concentrations of bombesin elevated cytosolic Ca2+ levels in the absence or presence of extracellular Ca2+. Potent bombesin receptor agonists, such as gastrin releasing peptide (GRP) or (GRP)14-27 elevated cytosolic Ca2+ levels whereas inactive compounds such as (D-Trp8)bombesin or (GRP)1-16 did not. Furthermore, the bombesin receptor antagonist (D-Arg1, D-Pro2, D-Trp7,9, Leu11) substance P (30 microM) had no effect on the Ca2+ levels by itself but antagonized the increase in Ca2+ caused by 10 nM or 100 nM bombesin. These data suggest that bombesin receptors may regulate the release of Ca2+ from intracellular organelles in small cell lung cancer cells.     

Posttranslational processing of endogenous and of baculovirus-expressed human gastrin-releasing peptide precursor.

The 27-amino-acid gastrin-releasing peptide (GRP1-27) is a neuropeptide and growth factor that is synthesized by various neural and neuroendocrine cells. The major pro-GRP hormone (isoform I) contains both GRP1-27 and a novel C-terminal extension peptide termed pro-GRP31-125. In order to define potentially active neuropeptides that could be generated from this novel protein domain, we analyzed the posttranslational processing of endogenous human pro-GRP1-125 in a small-cell lung cancer cell line. Because such studies are much easier in an overexpression system, we investigated at the same time the posttranslational processing of baculovirus-expressed human pro-GRP1-125 in an insect ovary cell line. In the small-cell lung cancer cell line, GRP1-27 was cleaved as expected from the endogenous prohormone at a pair of basic amino acids (29 and 30) and alpha-amidated at its C-terminal methionine; however, a number of novel peptides were generated by additional cleavages in the pro-GRP31-125 domain. In the insect ovary cell line, GRP1-27 was cleaved from the expressed prohormone by a different mechanism, as were a number of other peptides that appeared to be similar in size to those produced by the human neuroendocrine tumor cell line. These data show for the first time that an insect ovary cell line that is widely used to overexpress proteins can process a human neuropeptide precursor. They also reveal the existence of novel pro-GRP-derived peptides that are candidates for biologically active ligands.     

High affinity binding of cholecystokinin to small cell lung cancer cells

The binding of 125I-Bolton Hunter-cholecystokinin octapeptide (125I-BH-CCK-8) to small cell lung cancer cell lines was investigated. 125I-BH-CCK-8 bound with high affinity (Kd = 2.4 nM) to an apparent single class of sites (1700/cell) using cell line NCI-H209. Binding was time dependent and the ratio of specific/nonspecific binding was 8/1. Pharmacology studies indicated that gastrin, caerulein, CCK-33 and nonsulfated CCK-8 were potent inhibitors of specific 125I-BH-CCK-8 binding whereas CCK-26-32-NH2 was not. Because CCK receptors are present on small cell lung cancer cells, CCK may function as a regulatory peptide in this disease.     

Conveyance of partial agonism/antagonism to bombesin/gastrin-releasing peptide analogues on Swiss 3T3 cells by a carboxyl-terminal leucine insertion.

Gastrin-releasing peptide (GRP) is a neuroendocrine hormone that may be involved in the pathophysiology of small cell lung carcinoma. We describe carboxylterminal peptide analogues of GRP and bombesin, a 14-residue amphibian homologue, that were modeled after the antagonist [Leu13-psi(CH2NH)-Leu14]bombesin and retained the psi bond. Three novel peptides contained a Leu insertion amino to the psi bond, i.e. ... Leu13Leu14 psi X (residues numbered after bombesin) where X = LeuNH2 or norleucine-NH2). The Leu-insertion analogues behaved as pure partial agonists/antagonists when examined for the ability to stimulate [3H]thymidine incorporation into quiescent Swiss 3T3 cells (agonist activity) and to diminish the agonist response of GRP (antagonist activity). A time course of [3H]thymidine incorporation into quiescent cells indicated maximal incorporation at 20-h post-peptide addition for bombesin and GRP and a Leu-insertion peptide, but the extent of the incorporation for the Leu-insertion peptide was half that of GRP and bombesin. The agonist dose responses of the Leu-insertion peptides (EC50 values of 1-10 nM) paralleled GRP and bombesin, but the maximal response of the Leu-insertion peptides, even at concentrations as high as 10(-4) M, was half the maximal value of GRP or bombesin. High concentrations of the Leu-insertion peptides antagonized 10 nM GRP (a concentration that produced a near-maximal GRP response) yielding a response that was half the maximal value of GRP and equivalent to the maximal response of the Leu-insertion peptides alone. Analogues of the form ... Leu13 psi X behaved as complete antagonists. The KD values of the Leu-insertion peptides for competitive binding versus 125I-GRP (2-50 nM) were as potent as parent ... Leu14 agonists. Stability studies indicated that peptide potencies for both agonist and antagonist activities diminished upon peptide incubation in medium or on cells. The results suggested that, for the Leu-insertion peptides, degradation into distinct products with different activities was not responsible for their partial agonist/antagonist behavior. Computer-generated molecular modeling studies indicated that the novel structures could adopt energy minimized conformations for either an agonist or an antagonist as proposed earlier (Coy, D.H., Heinz-Erian, P., Jiang, N.-Y., Sasaki, Y., Taylor, J., Moreau, J.-P., Wolfrey, W.T., Gardner, J.D., and Jensen, R. T. (1988) J. Biol. Chem. 263, 5056-5060).     

Purification and characterization of the bombesin/gastrin-releasing peptide receptor from Swiss 3T3 cells

The bombesin/gastrin-releasing peptide (GRP) receptor was solubilized from Swiss mouse 3T3 cell membranes in an active form and was purified about 90,000-fold to near homogeneity by a combination of wheat germ agglutinin-agarose and ligand affinity chromatography. The purified receptor displayed a single diffuse band with a Mr of 75,000-100,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After treatment of the receptor with N-glycanase, removing N-linked oligosaccharide moieties, the protein yielded a Mr = 38,000 band. These results agree with the Mr value estimated for the GRP receptor that was labeled on Swiss 3T3 cells by cross-linking to 125I-GRP1-27. GRP1-27 bound to the purified receptor with a Kd of 0.038 +/- 0.019 nM. By comparison, the soluble receptor in unfractionated extracts and intact membranes displayed a Kd for GRP1-27 of 0.036 +/- 0.003 nM and 0.13 +/- 0.04 nM, respectively. The relative potencies of a series of GRP analogs for the soluble receptor and intact membranes indicated that the extraction procedure did not significantly alter the receptor's ligand binding specificity. However coupling of the receptor to its guanyl nucleotide regulatory protein was not maintained in the soluble extract, and a G-protein did not co-purify with the receptor. Physiological concentrations of NaCl greatly inhibited the binding of some GRP analogs to the receptor, while the binding of other analogs was not affected. A domain on the GRP molecule involving Lys-13 or Arg-17 was identified which promoted binding to the GRP receptor under conditions of low ionic strength. These findings aided the development of an effective ligand affinity resin for the purification of the GRP receptor.     

Isolation of the bombesin/gastrin-releasing peptide receptor from human small cell lung carcinoma NCI-H345 cells.

Purification of the gastrin-releasing peptide (GRP) or bombesin receptor has proved elusive in part due to technical difficulties. In the present studies, the problem of oxidized radioligand was avoided by the use of 125I-GRP, which was verified to be not oxidized by high performance liquid chromatography. Specific 125I-GRP binding (at 0 degrees C) to intact human small cell lung carcinoma NCI-H345 cells which had been subjected to a dilute acid wash was 6 fmol/10(6) cells. Inhibition of GRP degradation by human H345 cell membranes through the use of phenanthroline or phosphoramidon permitted the development of binding assays for the GRP receptor in detergent-solubilized crude membrane preparations. The solubilized GRP receptor exhibited saturable, high affinity (KD = 1.3 nM), temperature-dependent specific binding averaging 402 +/- 65 fmol/mg protein (mean +/- S.E. for eight separate membrane preparations with 125I-GRP concentration = 3 nM), with a Bmax = 434 fmol/mg protein using a gel filtration binding assay. That the GRP receptor had been solubilized was demonstrated by its failure to pellet when centrifuged at 100,000 x g for 60 min, its passage through a 0.22-micron filter without loss of binding activity, and its elution in the void volume of a Sephadex G-50 gel filtration column, but within the inclusion volume of a Sephacryl S-200 column (Ve/V0 = 1.1). Isolation of the GRP receptor from human H345 cell-solubilized membranes was achieved by ligand affinity chromatography. A unique 70-kDa band on silver-stained reduced sodium dodecyl sulfate-polyacrylamide gel electrophoresis was reproducibly eluted from GRP14-27 affinity columns by an acidic high salt buffer, but binding activity was denatured by these conditions. The protein nature of the GRP receptor was demonstrated by its sensitivity to proteases after isolation. In addition, two unique bands of 65 and 70 kDa were eluted from the GRP14-27 affinity column with GRP14-27 in neutral buffer, and this eluate possessed specific 125I-GRP binding with a stoichiometry of approximately 1:1. Thus, reported here is the isolation of a functional membrane-associated, saturable, high affinity GRP receptor with temperature-dependent binding from the solubilized membranes of human H345 cells.     

In vitro and in vivo evaluation of Alexa Fluor 680-bombesin[7-14]NH2 peptide conjugate, a high-affinity fluorescent probe with high selectivity for the gastrin-releasing peptide receptor

Gastrin-releasing peptide (GRP) receptors are overexpressed on several types of human cancer cells, including breast, prostate, small cell lung, and pancreatic cancers. Bombesin (BBN), a 14-amino acid peptide that is an analogue of human GRP, binds to GRP receptors with very high affinity and specificity. The aim of this study was to develop a new fluorescent probe based on BBN having high tumor uptake and optimal pharmacokinetics for specific targeting and optical imaging of human breast cancer tissue. In this study, solid-phase peptide synthesis was used to produce H(2)N-glycylglycylglycine-BBN[7-14]NH(2) peptide with the following general sequence: H(2)N-G-G-G-Q-W-A-V-G-H-L-M-(NH(2)). This conjugate was purified by reversed-phase high-performance liquid chromatography and characterized by electrospray-ionization mass spectra. The fluorescent probe Alexa Fluor 680-G-G-G-BBN[7-14]NH(2) conjugate was prepared by reaction of Alexa Fluor 680 succinimidyl ester to H(2)N-G-G-G-BBN[7-14]NH(2) in dimethylformamide (DMF). In vitro competitive binding assays, using (125)I-Tyr(4)-BBN as the radiolabeling gold standard, demonstrated an inhibitory concentration 50% value of 7.7 +/- 1.4 nM in human T-47D breast cancer cells. Confocal fluorescence microscopy images of Alexa Fluor 680-G-G-G-BBN[7-14]NH(2) in human T-47D breast cancer cells indicated specific uptake, internalization, and receptor blocking of the fluorescent bioprobe in vitro. In vivo investigations in SCID mice bearing xenografted T-47D breast cancer lesions demonstrated the ability of this new conjugate to specifically target tumor tissue with high selectivity and affinity.     

A gastrin-releasing peptide antagonist containing A psi (CH2O) amide bond surrogate

The [Leu26-psi(CH2O)Leu27] derivative of N-Ac-GRP20-27-peptide amide was prepared and evaluated as a gastrin-releasing peptide antagonist. This psi(CH2O) derivative was found to be a more potent inhibitor of [3H-Phe15]GRP15-24NH2 binding and N-Ac-GRP20-27NH2 induced mitogenesis in Swiss 3T3 fibroblasts than the related nitrogen analog [Leu13-psi(CH2NH)Leu14] bombesin. Possible reasons for the improved activity of the (CH2O) insert relative to the (CH2NH) group include increased hydrophobicity and a reduced tendency of the oxygen derivative to form hydrogen bonds.     

Bombesin-related peptides induce calcium mobilization in a subset of human small cell lung cancer cell lines

To examine the biochemical basis for growth factor-induced responses in human lung cancer cells, we used the quin2 technique to study the effect of the amphibian peptide bombesin and its congeners including mammalian gastrin-releasing peptide (GRP) on the intracellular free calcium level [Ca2+]i in small cell lung cancer cell lines. In five of eleven cell lines tested, Tyr4-bombesin or GRP elicited a rapid and transient increase in [Ca2+]i. The response was seen with as little as 1 nM ligand, was not affected by membrane depolarization, and derived in part from internal calcium stores. Desensitization to a second addition of active bombesin congeners occurs subsequent to initial addition of Tyr4-bombesin. Structure-activity analysis showed the carboxyl-terminal octapeptide was the active portion of the peptide. Analogs in which the carboxyl terminus was oxidized or deamidated were inactive. Ranatensin, litorin, alytesin, and GRP, but not physalaemin, were as active as Tyr4-bombesin. A monoclonal antibody to the carboxyl terminus of bombesin selectively blocked the increased [Ca2+]i elicited by Tyr4-bombesin. These studies suggest that bombesin congeners can act on some small cell lung cancer cell lines by a pathway utilizing increased [Ca2+]i.     

Gut hormones with activity to modulate cellular growth

Recent progress in cancer research revealed that gut hormones have the activity to regulate the cellular growth of cancer cells. Gastrin, cholecystokinin and vasoactive intestinal peptide were demonstrated to stimulate the growth of gastric cancer cells, pancreatic cancer cells and colon cancer cells, respectively. Accordingly, it is possible to assume that these gut hormones may play an important role in the progression of these cancers. Further studies will be required to clarify the role of gut hormones as physiological growth factors in gastrointestinal tissues. The other aspect of gut hormones related with cellular growth is their role as autocrine growth factors. Gastrin-releasing peptide (GRP) is classified as a gut hormone with the structural similarity with amphibian bombesin. Several reported findings indicate that GRP functions as an autocrine growth factor for human small cell lung carcinoma; a monoclonal antibody for GRP is now applied for the therapy of this cancer. It is important to find out other gut hormones functioning as autocrine growth factors.     

Effects of bombesin on human small cell lung cancer cells: evidence for a subset of bombesin non-responsive cell lines

The effects of bombesin on three human small cell lung carcinoma cell (SCLC) lines (NCI-H69, NCI-H128, and NCI-H345) have been examined and compared to the effects of the peptide on the mouse fibroblast cell line Swiss 3T3, and the rat pituitary tumor cell line GH3W5. While all three SCLC lines expressed messenger RNA encoding pro-gastrin releasing peptide (GRP), only the NCI-H345 cells expressed detectable membrane receptors for GRP and responded to nanomolar concentrations of bombesin as shown by 125I-GRP binding, total inositol phosphate accumulation, and increased clonal growth in soft agarose. These data show that some SCLC lines are insensitive to bombesin and do not express detectable membrane receptors for GRP.     

Gastrin-releasing peptide (GRP,mammalian bombesin) in the pathogenesis of lung cancer

Established human lung cancer exhibits a complex pattern of genetic changes as well as several distinct autocrine growth factor loops for regulatory peptides. The best studied example is that of gastrin-releasing peptide (GRP), the mammalian homolog of the amphibian bombesin. It is produced by up to 70% of small cell lung cancers and 10–20% of non-small cell lung cancers. GRP stimulates the growth of normal bronchial epithelium as well as that of small cell lung cancer, and its blockade with the use of antibodies or synthetic antagonists inhibits the growth of these tumors. Study of its molecular biology has revealed a complex pattern of mRNA processing which has lead to the recent isolation of a novel family of peptides termed gastrin-releasing peptide gene-associated peptides (GGAPs), present in normal and malignant human tissues. Additional efforts have been directed at characterizing the GRP receptor as well as its intracellular signaling pathways which have been reported both as G protein phospholipase C coupled events as well as activation of a membrane associated tyrosine kinase. In view of its expression in normal bronchial epithelium and its mitogenic effects on this tissue, GRP appears to play a central role in the early events of pulmonary carcinogenesis.     

Pseudononapeptide bombesin antagonists containing C-terminal Trp or Tpi.

Seven new antagonists of bombesin (Bn)/gastrin-releasing peptide (GRP) containing C-terminal Trp or Tpi (2,3,4,9-tetrahydro-1H-pyrido[3,4-b]indol-3-carboxylic acid) in a reduced peptide bond were synthesized by solid phase methods and evaluated biologically. The reduced bond in four [Leu13 psi(CH2NH)Trp14]Bn(6-14) analogs was formed by reductive alkylation at the dipeptide stage. In the case of three [Leu13 psi(CH2N)Tpi14]Bn(6-14) analogs, the Trp dipeptide with reduced bond was reacted with formaldehyde to form the corresponding Tpi derivative. These Tpi-containing analogs have a new reduced bond which is structurally more constrained. Leu13 psi(CH2N)Tpi14 analogs inhibit [125I][Tyr4]bombesin binding to Swiss 3T3 cells with IC50 values of 2-4 nM, compared to 5-10 nM for Leu13 psi(CH2NH)Trp14 analogs. Leu13 psi(CH2N)Tpi14 analogs are also more potent than Leu13 psi(CH2NH)Trp14 analogs in growth inhibition studies using Swiss 3T3 cells. The two best bombesin antagonists of this series, [D-Trp6,Leu13 psi(CH2N)Tpi14]Bn(6-14) (RC-3415) and [Tpi6,Leu13 psi(CH2N)Tpi14]Bn(6-14) (RC-3440), inhibited GRP-stimulated growth of Swiss 3T3 cells with IC50 values less than 1 nM. RC-3440 was also active in vivo, suppressing GRP(14-27)-stimulated serum gastrin secretion in rats. Bombesin/GRP antagonists, such as RC-3440, containing the new reduced bond (CH2N) reported herein are very potent.     

Comparative proteomic analysis of cancerous and adjacent normal lung tissues

Lung cancer is the leading cause of cancer-related mortality in industrialized countries. Unfortunately, most lung cancers are found too late for a cure, therefore early detection and treatment is very important. We have applied proteomic analysis by using two-dimensional gel electrophoresis and peptide mass fingerprinting techniques for examination of cancerous and adjacent non-cancerous lung tissues from the same patient. The aim of the study was to find proteins, which could be used as biomarkers for diagnosis and monitoring of this disease. Indeed, we found differences in expression of several proteins, related to various cellular activities, such as, chaperoning (e,g. GRP96, GRP78, HSP27), metabolism and oxidation stress (e.g. L-fucose, GST), cytoskeleton (e.g., tubulin beta 2/3, beta actin), cell adhesion (e.g. annexin A5/3), binding proteins (e.g. 14-3-3 theta) and signal transduction. These changes may be important for progression of carcinogenesis; they may be used as the molecular-support for future diagnostic markers.     

Bombesin activates MAP kinase in non-small cell lung cancer cells

The effects of bombesin (BB) on mitogen activated protein (MAP) kinase were investigated using non-small cell lung cancer (NSCLC) cells. By Western blot, both 42 and 44 kDalton forms of MAP kinase were present in NCI-H1299 and NCI-H838 cells. Addition of BB to NCI-H1299 cells resulted in phosphorylation of the MAP kinase substrate myelin basic protein (MBP). Phosphorylation of MBP was maximal 6 min after the addition of 10 nM BB to NCI-H1299 cells. Addition of gastrin releasing peptide (GRP) or GRP14-27 but not GRP1-16 to NCI-H 1299 cells caused MBP phosphorylation. The effects of BB were inhibited by BW2258U89, a BB receptor antagonist, and PD98059, a MAP kinase kinase inhibitor. Also, PD98059 inhibited the clonal growth of NCI-H1299 cells. These data suggest that MAP kinase may be an important regulatory enzyme in NSCLC.     

Binding of GRP(14-27) but not bombesin or GRP(1-27) to hypothalamic magnocellular elements: an immunohistochemical study

Bombesin, gastrin-releasing peptide (1-27), and gastrin-releasing peptide (14-27) abolished the specific immunocytochemical staining revealed by antiserum directed to the C-terminus of gastrin releasing peptide (GRP) and bombesin (BN) in rat hypothalamus. When the antiserum was preabsorbed with GRP(14-27), a strong reaction appeared in hypothalamic magnocellular neurons. This staining of magnocellular elements was produced by lower concentrations of GRP(14-27) than were needed to block immunocytochemical staining revealed by the antiserum in other hypothalamic locations. The distribution of GRP(14-27)-induced immunostaining was similar to that of neurophysin. Since only GRP(14-27) but not GRP(1-27) or bombesin was found to bind to magnocellular cells, it was concluded that binding was due to the N-terminus of GRP(14-27), which resembles the structure of oxytocin and vasopressin. In agreement with this, oxytocin and vasopressin were found to prevent the binding of GRP(14-27) to magnocellular cells. The similarity in localization and the effect of oxytocin and vasopressin suggest that GRP(14-27) may bind to neurophysin at low concentrations. The results suggest that enhancement of staining after preabsorption of antisera with antigens must be interpreted with care. Enhancement can occur at antigen concentrations lower than those required to block the immunostaining. These results fail to support the premise that antigen-induced enhancement of staining is due to antigen binding to specific receptors and subsequent detection of the receptor-bound antigen with the antiserum.