Excitatory effects of bombesin receptors in urinary tract of normal and diabetic rats in vivo.

AIMS: Bombesin receptors (BB receptors) and bombesin related peptides are expressed in the lower urinary tract of rodents. Here we investigated whether in vivo activation of BB receptors can contract the urinary bladder and facilitate micturition in sham rats and in a diabetic rat model of voiding dysfunction. MATERIAL AND METHODS: In vivo cystometry experiments were performed in adult female Sprague-Dawley rats under urethane anesthesia. Diabetes was induced by streptozotocin (STZ; 65mg/kg, i.p.) injection. Experiments were performed 9 and 20weeks post STZ-treatment. Drugs included neuromedin B (NMB; BB1 receptor preferring agonist), and gastrin-releasing peptide (GRP; BB2 receptor preferring agonist). KEY FINDINGS: NMB and GRP (0.01-100µg/kg in sham rats; 0.1-300µg/kg in STZ-treated rats, i.v.) increased micturition frequency, bladder contraction amplitude and area under the curve dose dependently in both sham and STZ-treated rats. In addition, NMB (3, 10µg/kg i.v.) triggered voiding in >80% of STZ-treated rats when the bladder was filled to a sub-threshold voiding volume. NMB and GRP increased mean arterial pressure and heart rate at the highest doses, 100 and 300µg/kg. SIGNIFICANCE: Activation of bombesin receptors facilitated neurogenic bladder contractions in vivo. Single applications of agonists enhanced or triggered voiding in sham rats as well as in the STZ-treated rat model of diabetic voiding dysfunction. These results suggest that BB receptors may be targeted for drug development for conditions associated with poor detrusor contraction such as an underactive bladder condition.

Functional bombesin receptors in urinary tract of rats and human but not of pigs and mice, an in vitro study.

AIMS: Bombesin receptors (BB receptors) and/or bombesin related peptides are expressed in the lower urinary tract, though their function and distribution in different species is largely unknown. This study examines whether BB receptor agonists can contract bladder smooth muscle in rats, mice, pigs and humans. METHODS: Bladder strips were placed in tissue baths for in vitro contractility. Neuronally evoked contractions were elicited using electric field stimulation (EFS). Effects of the BB receptor agonists, neuromedin B (NMB; BB1 receptor agonist) and gastrin-releasing peptide (GRP; BB2 receptor agonist) on baseline tone and EFS-induced contractions were monitored. RESULTS: In rat and human bladder strips, NMB and GRP (10(-11)-10(-6)M) increased EFS-induced contractions in a concentration dependent manner. In these species, NMB and GRP also increased baseline tension. In mouse and pig bladder strips, NMB and GRP (10(-8)-3×10(-6)M) had no effects on either parameter. CONCLUSIONS: These data suggest that bombesin receptors BB receptor 1 and/or BB receptor 2 increase bladder contractions in rat and human. The site of action of these receptors may be pre- and/or post-synaptic, increasing release of transmitters or enhancing smooth muscle excitability, respectively. Thus, BB1 receptor and/or BB2 receptor may offer therapeutic targets for voiding dysfunction associated with impaired bladder contractility; however, species differences must be considered when studying these receptors. Part of this work was published in an abstract form at the SFN meeting New Orleans, 2012.

Stability of the acetic acid-induced bladder irritation model in alpha chloralose-anesthetized female cats.

Time- and vehicle-related variability of bladder and urethral rhabdosphincter (URS) activity as well as cardiorespiratory and blood chemistry values were examined in the acetic acid-induced bladder irritation model in α-chloralose-anesthetized female cats. Additionally, bladder and urethra were evaluated histologically using Mason trichrome and toluidine blue staining. Urodynamic, cardiovascular and respiratory parameters were collected during intravesical saline infusion followed by acetic acid (0.5%) to irritate the bladder. One hour after starting acetic acid infusion, a protocol consisting of a cystometrogram, continuous infusion-induced rhythmic voiding contractions, and a 5 min "quiet period" (bladder emptied without infusion) was precisely repeated every 30 minutes. Administration of vehicle (saline i.v.) occurred 15 minutes after starting each of the first 7 cystometrograms and duloxetine (1mg/kg i.v.) after the 8(th). Acetic acid infusion into the bladder increased URS-EMG activity, bladder contraction frequency, and decreased contraction amplitude and capacity, compared to saline. Bladder activity and URS activity stabilized within 1 and 2 hours, respectively. Duloxetine administration significantly decreased bladder contraction frequency and increased URS-EMG activity to levels similar to previous reports. Cardiorespiratory parameters and blood gas levels remained consistent throughout the experiment. The epithelium of the bladder and urethra were greatly damaged and edema and infiltration of neutrophils in the lamina propria of urethra were observed. These data provide an ample evaluation of the health of the animals, stability of voiding function and appropriateness of the model for testing drugs designed to evaluate lower urinary tract as well as cardiovascular and respiratory systems function.

Effects of the 5-HT4 receptor agonist, cisapride, on neuronally evoked responses in human bladder, urethra, and ileum.

This study evaluated the effects of a 5-HT4 agonist, cisapride, on neuronally evoked smooth muscle responses in bladder, urethra and ileum and compared these effects with those of an acetylcholinesterase inhibitor, distigmine. Electrical field stimulation (EFS) was applied to human bladder and ileum smooth muscle strips from human organ transplant donors and to urethral strips from prostatectomy patients, to evoke neuronally mediated smooth muscle responses. EFS induced contractions in bladder and mixed responses, consisting of contractions and relaxations, in urethra and ileum. Relaxations were mediated by nitric oxide while contractions were partially cholinergic (i.e. atropine sensitive). This atropine sensitive component amounted to~95% in bladder and ~75% in ileum, and it was enhanced by distigmine in a concentration dependent manner (0.1-3 µM; ~100-600% increase in bladder and ~50-250% increase in ileum). Cisapride (0.0003-1 µM) also enhanced bladder contractions (~75-100% increase) but had no effect on urethral contractions or relaxations, and modestly enhanced ileum contractions (~10-40% increase). Facilitatory effects of cisapride were reversed by the specific 5-HT4 receptor antagonist, SB-203186 (3 µM), but were resistant to repeated washing in the bladder. These data indicate that 5-HT4 receptor agonists enhanced EFS-induced contractions in bladder and ileum without an effect on urethra and suggest that it may be possible to enhance bladder activity with a dose of cisapride that is at, or below, those producing gastrointestinal (GI) effects. Although distigmine's maximal facilitation of bladder and GI tract function was greater than that of cisapride, at clinically relevant concentrations cisapride showed much greater efficacy.

Exogenous activation of muscarinic receptors decreases subsequent non-muscarinic bladder contractions in vivo in the female rat.

AIMS: To determine if the muscarinic agonist, bethanechol, inhibits the non-cholinergic, atropine-resistant (i.e. putatively purinergic) component of naturally occurring (i.e. reflexogenic) bladder contractions in vivo in the rat, as previously described in vitro. Our second aim was to determine if elevation of endogenous acetylcholine (ACh) with distigmine, an acetylcholine esterase (AChE) inhibitor, could also inhibit non-cholinergic component of reflexogenic bladder contractions. MAIN METHODS: Cystometry was performed in urethane anesthetized adult female Sprague Dawley rats. The nonselective muscarinic receptor (mAChR) antagonist, atropine, was administered intravenously (i.v.) before and after i.v. administration of the non-selective mAChR agonist, bethanechol, the AChE inhibitor, distigmine or the neurokinin receptor 2 agonist, [ßAla(8)]-Neurokinin A(4-10). Intermicturition interval (IMI), bladder contraction amplitude (BCA), postvoid bladder pressure (PVBP), and voiding efficiency (VE) were measured. KEY FINDINGS: Atropine (0.4 mg/kg; n=11 rats) delivered as the first drug, had insignificant effects on BCA (~15% reduction) or PVBP (~15% increase) and weakly reduced IMI and VE by ~40% (p<0.05) relative to vehicle. Bethanechol and distigmine on their own produced excitatory effects on bladder activity, consistent with mAChR activation. Unexpectedly atropine, administered after bethanechol or after distigmine but not after [ßAla(8)]-Neurokinin A(4-10), completely blocked bladder activity for 3-10 min. Partial recovery of bladder activity occurred after that time, but BCA, IMI, and VE remained significantly reduced and PVBP remained significantly increased. SIGNIFICANCE: Activation of mAChRs by an exogenous agonist or elevation of endogenous ACh levels by an AChE inhibitor inhibits the non-cholinergic, atropine-resistant, component of reflexogenic bladder contractions in vivo.

Dual inhibition of cathepsin G and chymase is effective in animal models of pulmonary inflammation.

RATIONALE: Mast cells and neutrophils are key contributors to the pathophysiological inflammatory processes that underpin asthma and chronic obstructive pulmonary disease, partly through the release of noxious serine proteases, including cathepsin G (Cat G) and chymase. From this standpoint, a dual inhibitor of neutrophil Cat G and mast cell chymase could protect against these disease-related inflammatory responses. OBJECTIVES: We examined the antiinflammatory pharmacology of RWJ-355871, a dual inhibitor of Cat G and chymase, in animal models of inflammation that evince pathophysiological pathways relevant to asthma and chronic obstructive pulmonary disease to determine the therapeutic potential of this compound. METHODS: In an ovalbumin (OVA)-sensitized rat model, RWJ-355871 was administered to block the mast-cell-mediated increase in paw volume caused by OVA injection. In a sheep asthma model, antigen-induced airway responses were assessed with and without aerosol treatment with RWJ-355871. In a murine tobacco-smoke model of airway inflammation, the effect of RWJ-355871 on smoke-induced neutrophilia was determined. MEASUREMENTS AND MAIN RESULTS: Intravenous treatment of OVA-sensitized rats with RWJ-355871 provided dose-dependent reduction in the increase in rat paw volume. In allergic sheep, aerosol pretreatment with RWJ-355871 showed dose-dependent inhibition of the antigen-induced early response, late response, and post-antigen-induced airway hyperreponsiveness. In tobacco-smoke-exposed mice, nebulized RWJ-355871 significantly reduced the smoke-induced neutrophilia from the levels observed in untreated mice. CONCLUSIONS: The preclinical antiinflammatory effects of RWJ-355871 in these animal models of inflammation indicate that this dual inhibitor may have therapeutic utility for treating airway inflammatory diseases involving mechanisms that depend on Cat G and/or chymase.

A novel, potent dual inhibitor of the leukocyte proteases cathepsin G and chymase: molecular mechanisms and anti-inflammatory activity in vivo.

Certain leukocytes release serine proteases that sustain inflammatory processes and cause disease conditions, such as asthma and chronic obstructive pulmonary disease. We identified beta-ketophosphonate 1 (JNJ-10311795; RWJ-355871) as a novel, potent dual inhibitor of neutrophil cathepsin G (K(i) = 38 nm) and mast cell chymase (K(i) = 2.3 nm). The x-ray crystal structures of 1 complexed with human cathepsin G (1.85 A) and human chymase (1.90 A) reveal the molecular basis of the dual inhibition. Ligand 1 occupies the S(1) and S(2) subsites of cathepsin G and chymase similarly, with the 2-naphthyl in S(1), the 1-naphthyl in S(2), and the phosphonate group in a complex network of hydrogen bonds. Surprisingly, however, the carboxamido-N-(naphthalene-2-carboxyl)piperidine group is found to bind in two distinct conformations. In cathepsin G, this group occupies the hydrophobic S(3)/S(4) subsites, whereas in chymase, it does not; rather, it folds onto the 1-naphthyl group of the inhibitor itself. Compound 1 exhibited noteworthy anti-inflammatory activity in rats for glycogen-induced peritonitis and lipopolysaccharide-induced airway inflammation. In addition to a marked reduction in neutrophil influx, 1 reversed increases in inflammatory mediators interleukin-1alpha, interleukin-1beta, tissue necrosis factor-alpha, and monocyte chemotactic protein-1 in the glycogen model and reversed increases in airway nitric oxide levels in the lipopolysaccharide model. These findings demonstrate that it is possible to inhibit both cathepsin G and chymase with a single molecule and suggest an exciting opportunity in the treatment of asthma and chronic obstructive pulmonary disease.