From Escherichia coli heat-stable enterotoxin to mammalian endogenous guanylin hormones

The isolation of heat-stable enterotoxin (STa) from Escherichia coli and cholera toxin from Vibrio cholerae has increased our knowledge of specific mechanisms of action that could be used as pharmacological tools to understand the guanylyl cyclase-C and the adenylyl cyclase enzymatic systems. These discoveries have also been instrumental in increasing our understanding of the basic mechanisms that control the electrolyte and water balance in the gut, kidney, and urinary tracts under normal conditions and in disease. Herein, we review the evolution of genes of the guanylin family and STa genes from bacteria to fish and mammals. We also describe new developments and perspectives regarding these novel bacterial compounds and peptide hormones that act in electrolyte and water balance. The available data point toward new therapeutic perspectives for pathological features such as functional gastrointestinal disorders associated with constipation, colorectal cancer, cystic fibrosis, asthma, hypertension, gastrointestinal barrier function damage associated with enteropathy, enteric infection, malnutrition, satiety, food preferences, obesity, metabolic syndrome, and effects on behavior and brain disorders such as attention deficit, hyperactivity disorder, and schizophrenia.

Evidence that guanylate cyclase is involved in modulating the resting tension and neurally induced contraction of the guinea pig tracheal muscle

Electrical field stimulation of guinea-pig tracheal muscle strips produced a frequency-dependent biphasic response consisting of an initial cholinergic contraction followed by relaxation. Both phases of the response were of neural origin. In the presence of methylene blue, a guanylate cyclase inhibitor, the resting tension and the contraction were increased, but the accompanying relaxation was inhibited. However, in the presence of sodium nitroprusside, guanylate cyclase activator, the resting tension was reduced and the contraction was inhibited, but the relaxation was prolonged and increased. Similarly, in the presence of either 3-isobutyl-lmethylxanthine, which promotes cyclic guanosine monophospate (cGMP) accumulation, or 8-bromo-cGMP, an analogue of cGMP, the resting tension was reduced and the contraction was inhibited but the relaxation was prolonged and increased. From these results, it is concluded that guanylate cyclase is involved in modulating the resting tension and the neurally-induced contraction of guinea-pig tracheal muscle

Activation of guanylate cyclase in the guinea-pig trachea reduces contractile responses of the smooth muscle

Guinea-pig tracheal strips were used to investigate whether activation of guanylate cyclase in the trachea can reduce the contractile response of the smooth muscle. Guanylate cyclase was activated by glyceryl trinitrate and a combination of sodium nitrite and ascorbic acid. These activators inhibited tracheal smooth muscle contractions produced by acetylcholine histamine and electrical field stimulation. However, in the presence of methylene blue, a guanylate cyclase inhibitor, tracheal smooth muscle contractions were not inhibited by the activators. But, in the presence of propranolol, which blocked inhibition mediated by beta-adrenoceptor, both glyceryl trinitrate and the sodium nitrite/ascorbic acid combination were still capable of inhibiting tracheal smooth muscle contractions. Additionally, methylene blue inhibited tracheal smooth muscle relaxation that was electrically induced. These results suggest that the inhibitory action mediated by activated guanylate cyclase may be a mechanism for regulating tracheal smooth muscle contractile reponses