Rachele Garella

Muscular effects of orexin A on the mouse duodenum: mechanical and electrophysiological studies

Non‐Technical Summary  Nerve‐mediated influences on gastrointestinal motility in response to orexin A, either centrally injected or applied to isolated gut preparations, have been reported. However, the presence of orexin receptors at the gastrointestinal smooth muscle level has been found. On these grounds, in the present study we evaluated whether orexin A also exerts direct muscular effects in the duodenal smooth muscle of the mouse in an attempt to explain the possible mechanism of action involved. The experimental results from mechanical and electrophysiological studies indicate that orexin A causes direct contractile responses in the isolated preparations and evokes changes in the ionic currents of the smooth muscle cells. Thus, orexin A, in addition to its neutrally mediated influences on gastrointestinal motility, exerts direct muscular effects on the mouse duodenum. This latter mechanism, from a physiological point of view, may act in a synergic manner to reinforce the neuronal signals.

Glucagon-like peptide 2 counteracts the mucosal damage and the neuropathy induced by chronic treatment with cisplatin in the mouse gastric fundus

Glucagon‐like peptide‐2 (GLP‐2) is a pleiotropic hormone synthesized and secreted by the enteroendocrine ‘L’ cells able to exert intestine‐trophic and anti‐inflammatory effects. The antineoplastic drug cisplatin causes gastrointestinal alterations with clinical symptoms (nausea and vomiting) that greatly affect the therapy compliance. Experimentally, it has been reported that chronic cisplatin treatment caused mucosal damage and enteric neuropathy in the rat colon.

Protection from cigarette smoke-induced vascular injury by recombinant human relaxin-2 (serelaxin)

Smoking is regarded as a major risk factor for the development of cardiovascular diseases (CVD). This study investigates whether serelaxin (RLX, recombinant human relaxin‐2) endowed with promising therapeutic properties in CVD, can be credited of a protective effect against cigarette smoke (CS)‐induced vascular damage and dysfunction. Guinea pigs exposed daily to CS for 8 weeks were treated with vehicle or RLX, delivered by osmotic pumps at daily doses of 1 or 10 μg. Controls were non‐smoking animals. Other studies were performed on primary guinea pig aortic endothelial (GPAE) cells, challenged with CS extracts (CSE) in the absence and presence of 100 ng/ml (17 nmol/l) RLX. In aortic specimens from CS‐exposed guinea pigs, both the contractile and the relaxant responses to phenylephrine and acetylcholine, respectively, were significantly reduced in amplitude and delayed, in keeping with the observed adverse remodelling of the aortic wall, endothelial injury and endothelial nitric oxide synthase (eNOS) down‐regulation. RLX at both doses maintained the aortic contractile and relaxant responses to a control‐like pattern and counteracted aortic wall remodelling and endothelial derangement. The experiments with GPAE cells showed that CSE significantly decreased cell viability and eNOS expression and promoted apoptosis by sparkling oxygen free radical‐related cytotoxicity, while RLX counterbalanced the adverse effects of CSE. These findings demonstrate that RLX is capable of counteracting CS‐mediated vascular damage and dysfunction by reducing oxidative stress, thus adding a tile to the growing mosaic of the beneficial effects of RLX in CVD.

Relaxin counteracts the altered gastric motility of dystrophic (mdx) mice: functional and immunohistochemical evidence for the involvement of nitric oxide

Impaired gastric motility ascribable to a defective nitric oxide (NO) production has been reported in dystrophic (mdx) mice. Since relaxin upregulates NO biosynthesis, its effects on the motor responses and NO synthase (NOS) expression in the gastric fundus of mdx mice were investigated. Mechanical responses of gastric strips were recorded via force displacement transducers. Evaluation of the three NOS isoforms was performed by immunohistochemistry and Western blot. Wild-type (WT) and mdx mice were distributed into three groups: untreated, relaxin pretreated, and vehicle pretreated. In strips from both untreated and vehicle-pretreated animals, electrical field stimulation (EFS) elicited contractile responses that were greater in mdx than in WT mice. In carbachol-precontracted strips, EFS induced fast relaxant responses that had a lower amplitude in mdx than in WT mice. Only in the mdx mice did relaxin depress the amplitude of the neurally induced excitatory responses and increase that of the inhibitory ones. In the presence of L-NNA, relaxin was ineffective. In relaxin-pretreated mdx mice, the amplitude of the EFS-induced contractile responses was decreased and that of the fast relaxant ones was increased compared with untreated mdx animals. Responses to methacholine or papaverine did not differ among preparations and were not influenced by relaxin. Immunohistochemistry and Western blotting showed a significant decrease in neuronal NOS expression and content in mdx compared with WT mice, which was recovered in the relaxin-pretreated mdx mice. The results suggest that relaxin is able to counteract the altered contractile and relaxant responses in the gastric fundus of mdx mice by upregulating nNOS expression.

Influence of obestatin on the gastric longitudinal smooth muscle from mice: mechanical and electrophysiological studies

Obestatin is a hormone released from the stomach deriving from the same peptide precursor as ghrelin. It is known to act as an anorectic hormone decreasing food intake, but contrasting results have been reported about the effects of obestatin on gastrointestinal motility. The aim of the present study was to investigate whether this peptide may act on the gastric longitudinal smooth muscle by using a combined mechanical and electrophysiological approach. When fundal strips from mice were mounted in organ baths for isometric recording of the mechanical activity, obestatin caused a tetrodotoxin-insensitive decrease of the basal tension and a reduction in amplitude of the neurally induced cholinergic contractile responses, even in the presence of the nitric oxide synthesis inhibitor N(G)-nitro-l-arginine. Obestatin reduced the amplitude of the response to the ganglionic stimulating agent dimethylphenyl piperazinium iodide but did not influence that to methacholine. In nonadrenergic, noncholinergic conditions, obestatin still decreased the basal tension of the preparations without influencing the neurally induced relaxant responses. For comparison, in circular fundal strips, obestatin had no effects. Notably, in the longitudinal antral ones, obestatin only caused a decrease of the basal tension. Electrophysiological experiments, performed by a single microelectrode inserted in a gastric longitudinal smooth muscle cell, showed that obestatin had similar effects in fundal and antral preparations: it decreased the resting specific membrane conductance, inhibited Ca(2+) currents, and positively shifted their voltage threshold of activation. In conclusion, the present results indicate that obestatin influences gastric smooth muscle exerting site-specific effects.

Contribution of endogenous nitrergic and peptidergic influences to the altered neurally-induced gastric contractile responses in strips from dystrophic (mdx) mice.

Gastrointestinal motor disorders have been reported to occur in dystrophic (mdx) mice. The aim of the present study was to investigate the contribution of endogenous nitrergic and peptidergic components to the gastric contractile responses in strips from wild type (WT) and mdx mice. In both preparations, electrical field stimulation (EFS) induced frequency-dependent excitatory responses that were abolished by atropine or tetrodotoxin. The amplitude of the neurally-induced contractile responses was greater in strips from mdx mice in respect to the WT ones. In both preparations, at the end of the stimulation period strip tension decayed below the pre-stimulus level (off-relaxations). The nitric oxide (NO) synthesis inhibitor L-NNA increased the amplitude of the EFS-induced contractile responses without influencing off-relaxations. alpha-chymotrypsin and PACAP 6-38 abolished off-relaxations and also caused a reduction in amplitude of the contractile responses, whereas VIP receptor antagonists were ineffective. The efficacy of L-NNA, alpha-chymotrypsin or PACAP 6-38 on the excitatory responses was lower in strips from mdx mice in respect to the WT ones. alpha-chymotrypsin, in the presence of L-NNA, was no longer able to decrease the amplitude of the neurally-induced contractile responses but still abolished off-relaxations in both preparations. Direct muscular responses to methacholine were similar in amplitude in the two preparations and were not influenced by L-NNA or alpha-chymotrypsin. The results indicate that both endogenous NO and peptides influence the EFS-induced cholinergic responses: a stronger peptidergic modulatory action on a weaker nitrergic neurotransmission is suggested to occur in strips from mdx mice in respect to the WT ones and to contribute to the altered gastric contractile responses.

Inhibitory effects of relaxin on cardiac fibroblast‐to‐myofibroblast transition: an electrophysiological study

What is the central question of this study? Fibroblast‐to‐myofibroblast transition is a key mechanism in the reparative response to tissue damage, but myofibroblast persistence in the wound leads to fibrosis and organ failure. The role of relaxin as an antifibrotic agent capable of counteracting the acquisition of biophysical features of differentiated myofibroblasts deserves further investigation. What is the main finding and its importance? Electrophysiological analysis showed that relaxin, administered during profibrotic treatment, hyperpolarizes the membrane potential and attenuates delayed rectifier and inwardly rectifying K+ currents, which usually increase in the transition to myofibroblasts. These findings provide further clues to the therapeutic potential of relaxin in fibrosis.

Endocannabinoids modulate non-adrenergic, non-cholinergic inhibitory neurotransmission in strips from the mouse gastric fundus

To investigate the effects of endocannabinoids on non‐adrenergic, non‐cholinergic (NANC) relaxant responses in gastric strips from mice.

Relaxin affects smooth muscle biophysical properties and mechanical activity of the female mouse colon.

The hormone relaxin (RLX) has been reported to influence gastrointestinal motility in mice. However, at present, nothing is known about the effects of RLX on the biophysical properties of the gastrointestinal smooth muscle cells (SMCs). Other than extending previous knowledge of RLX on colonic motility, the purpose of this study was to investigate the ability of the hormone to induce changes in resting membrane potential (RMP) and on sarcolemmal ion channels of colonic SMCs of mice that are related to its mechanical activity. To this aim, we used a combined mechanical and electrophysiological approach. In the mechanical experiments, we observed that RLX caused a decay of the basal tone coupled to an increase of the spontaneous contractions, completely abolished by the guanylate cyclase inhibitor 1H-[1,2,4]oxadiazolo[4,3-a]-quinoxalin-1-one (ODQ). The electrophysiological results indicate for the first time that RLX directly affects the SMC biophysical properties inducing hyperpolarization of RMP and cycles of slow hyperpolarization/depolarization oscillations. The effects of RLX on RMP were abolished by ODQ as well as by a specific inhibitor of the cGMP-dependent protein kinase, KT5823. RLX reduced Ca(2+) entry through the voltage-dependent L-type channels and modulated either voltage- or ATP-dependent K(+) channels. These effects were abolished by ODQ, suggesting the involvement of the nitric oxide/guanylate cyclase pathway in the effects of RLX on RMP and ion channel modulation. These actions of RLX on membrane properties may contribute to the regulation of the proximal colon motility by the nitric oxide/cGMP/cGMP-dependent protein kinase pathway.

Relaxin and gastrointestinal motility

Relaxin is involved in a variety of functions. Among them, relaxin influences gastrointestinal motility in mice mainly regulating the biosynthesis of nitric oxide, considered as the main substance causing smooth muscle relaxations. Relaxin is able to regulate the different nitric oxide synthase expression depending on the gut region considered. Relaxin also counteracts the hypermotility state, related to a defective nitric oxide production, observed in the gut of dystrophic (mdx) mice. From the above considerations, it appears that relaxin, in addition to its physiological roles, may be regarded as a therapeutic tool in gastrointestinal diseases characterized pathogenically by an altered nitric oxide production.