Ross S. Feldberg

Expression of proinflammatory genes during estrogen-induced inflammation of the rat prostate.

Exposure of male Wistar rats to estradiol‐17β (E2) in the presence or absence of dihydrotestosterone propionate (DHT) was previously shown to result in prostate inflammation. The present study examines, for the first time, changes in the expression level of several proinflammatory genes during the course of this experimentally induced prostatitis.

Blockade of mast cell histamine secretion in response to neurotensin by SR 48692, a nonpeptide antagonist of the neurotensin brain receptor

1 Pretreatment of rat isolated mast cells with SR 48692, a nonpeptide antagonist of the neurotensin (NT) receptor, prevented histamine secretion in response to NT.

Neurotensin stimulation of mast cell secretion is receptor-mediated, pertussis-toxin sensitive and requires activation of phospholipase C

Pretreatment of isolated rat serosal mast cells with U-73122, an aminosteroid inhibitor of phospholipase C, inhibited histamine secretion in response to neurotensin (NT). This inhibition reached a maximum after 1 h of pretreatment at 37 degrees C and was dependent upon the concentration of U-73122 (IC50 approximately 0.2 microM). The inactive analog, U-73343, had no effect on the secretory response to NT. Pretreatment of mast cells with U-73122 also blocked histamine secretion in response to substance P (SP), mastoparan (MP), compound 48/80, or amidated NT (NT-NH2). Stimulation of mast cells by NT was accompanied by a rise in the level of intracellular free calcium and a rapid (within seconds) increase in the level of inositol trisphosphate (IP3) which was inhibited by pretreatment of the cells with U-73122. Pretreatment of isolated mast cells with pertussis toxin (PTx) blocked histamine release in response to NT as well as to all peptides tested. PTx had no effect on histamine secretion elicited by anti-IgE stimulation of sensitized mast cells. Pretreatment of mast cells with SR 48692, a NT-receptor antagonist, had no effect on histamine release induced by MP. At a high concentration (100 nM) SR 48692 partially inhibited the response to NT-NH2. These results, together with our earlier findings with SR 48692, indicate that the signal transduction pathway in mast cells activated by NT requires a specific NT-receptor, the activation of phospholipase C, and the involvement of a PTx sensitive G protein. The peptides SP and MP, and compound 48/80, while also requiring the activation of PLC and a PTx sensitive G protein, are not inhibited by the NT-R antagonist, SR 48692, suggesting that they exert their actions either via a different mast cell receptor or via a receptor-independent mechanism.

Rapid degradation of neurotensin by stimulated rat mast cells

A RIA towards neurotensin (NT) using C-terminal- and N-terminal-specific antisera was used to study degradation of this tridecapeptide by isolated rat mast cells. Incubation of NT (10 microM) with peritoneal or pleural mast cells resulted in a rapid loss of NT immunoreactivity (iNT), as measured by C-terminal-directed antiserum, with little effect on N-terminal iNT. The rate of the reaction was faster with pleural cells (T1/2, 30 s) than with peritoneal cells (T1/2, 180 s) and was greater than 10-fold slower in the presence of metabolic poisons. The enzyme(s) involved is most likely released from the cells during secretion, as NT was degraded by media conditioned by compound 48/80-stimulated mast cells 40-60 times faster than by media from unstimulated cells. This degradation by conditioned media was concentration dependent, pH dependent, and temperature sensitive. HPLC analyses indicated a near stoichiometric conversion of NT to NT(1-12) (66%) and NT(1-11) (34%) after incubation for 10-30 s with conditioned media. By 30 min only NT(1-11) and NT(1-10) were present. Phenanthroline (1 mM), an inhibitor of carboxypeptidase, prevented the loss of C-terminal iNT and the generation of NT(1-12) and NT(1-11). While NT(1-12) was effective in releasing histamine from mast cells in vitro and increasing vascular permeability in vivo, NT(1-11) was not. These results suggest that carboxypeptidase-like enzyme(s) could modulate the level and form of NT-related peptides in various states involving activation of mast cells.

Evidence for a neurotensin receptor in rat serosal mast cells

Abstract.Objective and Design: The ability of neurotensin (NT) at nmolar levels to stimulate exocytosis of the mast cell suggested that it could play a role in neuro-immune-endocrine interactions. The inhibition by a specific receptor antagonist of NT’s mast cell stimulation suggested the presence of a specific mast cell NT receptor. We have here employed several probes to determine if a specific neurotensin receptor was present on rat serosal mast cells.¶Material: Serosal mast cells were isolated from the peritoneal and pleural cavities of male Sprague-Dawley rats.¶Methods: Immunocytochemistry with an antibody raised against the C-terminal peptide of the neurotensin receptor was utilized. The same antibody was employed in immunoblotting following SDS gel electrophoresis of mast cell extracts. An RNA probe for ribonuclease protection assays (RPA) was prepared using the rat brain neurotensin receptor cDNA and polymerase chain reaction was carried out using primers based on the rat brain neurotensin receptor sequence.¶Results: Mast cells showed specific staining with the anti-neurotensin receptor antibody and this same antibody revealed a protein on SDS gels migrating as a 70 kDa species. Ribonuclease protection assays revealed the predicted protected fragment at approximately 450 bp while PCR amplification gave a major product at 843 bp.¶Conclusions: These results indicate that a specific neurotensin receptor is present on the rat mast cell.

Stimulated rat mast cells generate histamine-releasing peptide from albumin

Media conditioned by compound 48/80-stimulated rat mast cells generated immunoreactive histamine-releasing peptide (HRP) when incubated at physiological pH with bovine serum albumin and the carboxypeptidase inhibitor, O-phenanthroline. The generation of immunoreactive HRP (IR-HRP) was time (after 3 h the concentration of IR-HRP was 20 nM), temperature, and pH dependent and was prevented by omitting albumin, by using media conditioned by nonstimulated mast cells, or by pretreatment of mast cells with disodium cromoglycate, an inhibitor of mast cell secretion. The amount of IR-HRP generated increased linearly with the number of mast cells stimulated and varied directly with the concentration of conditioned media. After removal of the media from stimulated mast cells, the remaining cell pellet retained its ability to generate IR-HRP for up to 8 h. Stimulation of mast cells by either neurotensin or substance P, or of sensitized cells by anti-IgE serum, also produced conditioned media that generated IR-HRP. The amount of IR-HRP formed by various conditioned media or by stimulated cell pellets was dependent upon the concentration of O-phenanthroline used. Including the chymase inhibitor, chymostatin, prevented the formation of IR-HRP in a dose-dependent manner. HPLC analysis showed four peaks of IR-HRP. The major one coeluted with synthetic HRP. These results indicate that the peptide, HRP, can be generated by stimulated mast cells incubated in the presence of albumin. They suggest that a chymase-like enzyme secreted by the mast cell is able to cleave albumin to yield HRP.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibitory effects of the neurotensin8–13 analogs Asp13-NT8–13 and Asp12-NT8–13 on mast cell secretion

Pretreatment of isolated mast cells with analogs of neurotensin 8–13 (NT8–13), in which the amino acids Leu13 or Ile12 are replaced with an aspartic acid (Asp13-NT8–13 or Asp12-NT8–13), inhibits the secretion of histamine in response to NT. A 10 min pretreatment with either analog (10 μM) inhibited NT-induced histamine release by 90% (Asp13-NT8–13) or by 98% (Asp12-NT8–13). At concentrations that are inhibitory, Asp13-NT8–13 and Asp12-NT8–13 alone elicit very little release (<5% at 10 μM). In the continued presence of the analogs, the inhibitory effect lasts for more than 45 min; removal of the analogs resulted in restoration of sensitivity to NT within 10 min. Pretreatment with analog Asp13-NT8–13 resulted in a 39% inhibition of stimulation by substance P and a 52% inhibition of stimulation by histaminereleasing peptide (HRP). In contrast, pretreatment with analog Asp12-NT8–13 gave no inhibition of release by SP or HRP. Neither analog inhibited histamine release in response to bradykinin (BK), NT1–12, compound 48/80 (48/80), the calcium ionophore A23187, or anti-IgE stimulation of passively sensitized mast cells. Although Asp12-NT8–13 and Asp13-NT8–13 differ slightly in regard to the peptides they inhibit, both probably act at a step early in the stimulus-secretion coupling sequence; most likely before the rise in the level of free intracellular calcium that has been shown to accompany secretion in mast cells. It is suggested that these analogs exert their inhibitory effect on NT by competing with NT for a binding site on the mast cell membrane. The limited number of peptides inhibited by these analogs suggest that not all basic peptides act at the same site to stimulate secretion.

Viability and recovery from degranulation of isolated rat peritoneal mast cells

Using a culture system that allows prolonged maintenance of purified populations of peritoneal mast cells, we have examined them following stimulation by non-immunologic or immunologic agents. Employing phase-contrast microscopy of living cells and various pharmacological manipulations, we have noted that the recovery process includes a reduction in cell size, the probable sealing of exocytotic cavities, a pronounced displacement of the cell nucleus and a resynthesis of histamine. During recovery, mast cells can entrap molecules from the extracellular fluid and later release these substances by a Ca-dependent mechanism. Our results suggest that microfilaments, calmodulin, Ca, and metabolic energy are necessary for recovery.

Formation and cell-medium partitioning of autoinhibitory free fatty acids and cyclodextrin's effect in the cultivation of Bordetella pertussis

Palmitic, palmitoleic and stearic acids were found in the extracted cellular lipids of virulent Bordetella pertussis as unesterified acids in confirmation of earlier taxonomic analyses. The same free fatty acids (FFAs) were found in the spent culture supernatant in concentrations higher than in the uninoculated medium, indicating that they are released into the extracellular medium. These long-chain fatty acids are known to inhibit the growth of B. pertussis at concentrations as low as 1 ppm. Measurement of palmitate cell-medium partitioning demonstrated a strong tendency of FFAs for cellular adsorption. Inhibition kinetics indicated that the cell-bound FFA was responsible for inhibition and that the specific cellular FFA concentrations actually found during growth were similar to those determined to be inhibitory. Autoinhibition by these endogenous FFAs provides an explanation of the low maximum cell concentrations currently attainable in liquid media. Addition of soluble dimethyl-beta-cyclodextrin (MebetaCD) to FFA-inhibited cultures resulted in a rapid reversal of the inhibition. A corresponding shift in the distribution of FFAs from the cells to the extracellular medium demonstrated that MebetaCD sequesters FFAs. Although MebetaCD did not increase final cell concentrations and even had an adverse effect on growth at concentrations above 1 g l-1, it did (at 1 g l-1 extend the initial period of high growth rate leading to shorter cultivation times.

Recognition of a cytosine base lesion by a human damage-specific DNA binding protein.

Sodium bisulfite reacts with cytosine and 5-methylcytosine, forming the 5,6-dihydrosulfonate adducts which deaminate to the uracil and thymine adducts, respectively. At alkaline pH, the sulfonate groups are then released, generating uracil and thymine. In DNA, the resulting G:U and G:T base mismatches generated are potential sites of mutagenesis. Using a human damage-specific DNA binding protein as a probe, we have found protein-recognizable lesions in bisulfite-treated DNA and poly d(I-C), but not in treated poly d(A-T) or poly d(A-U). Although this suggests that the lesion recognized is cytosine-derived, there was no correlation between the number of uracils induced and the number of binding sites, suggesting that the protein-bound damage is not a uracil-containing mismatch. Modification of the treatment protocol to reduce elimination of the bisulfite from the base adducts increased the level of binding, suggesting that the protein recognizes a base-sulfonate adduct.