An amino-terminal fragment of hemokinin-1 has an inhibitory effect on pruritic processing in rats.

Hemokinin-1 (HK-1) is a peptide encoded by the preprotachykinin gene, TAC-4, and shares the hydrophobic carboxyl-terminal (C-terminal) region common to mammalian tachykinin peptides, such as substance P (SP). It is generally believed that C-terminal fragments of SP elicit an excitatory effect, while pretreatment with amino-terminal (N-terminal) fragments of SP inhibits the function of SP; however, there is no available information on HK-1. Therefore, to clarify the characteristics of C-terminal and N-terminal fragments of HK-1, HK-1 was divided into HK-1 (1-5) as the N-terminal fragment and HK-1 (6-11) as the C-terminal fragment based on the similarity of amino acids between HK-1 and SP. Intrathecal administration of HK-1 (6-11) induced scratching behavior similar to HK-1, while HK-1 (1-5) hardly induced scratching. Pretreatment with HK-1 (1-5), however, attenuated scratching induced by HK-1 and SP, whereas pretreatment with SP (1-5) attenuated SP-induced scratching, but not HK-1. Furthermore, intrathecal administration of HK-1 (1-5) and SP (1-5) markedly attenuated the induction of flinching and enhancement of c-Fos expression in the spinal cord following the intradermal administration of formalin, a noxious stimulant, while pretreatment with HK-1 (1-5), but not SP (1-5), markedly attenuated the induction of scratching behavior by subcutaneous administration of pruritic agents, such as serotonin or histamine. Taken together, these findings indicate that HK-1 (1-5) suppresses pruritic and nociceptive processing, while SP (1-5) suppresses nociceptive processing. Therefore, it is suggested that HK-1 (1-5) may be a useful tool for revealing pruritic processing and HK-1 may play a crucial role in pruritic processing.

Tachykinin-independent effects of capsaicin on smooth muscle in human isolated bronchi.

Contractile and relaxant responses to capsaicin and resiniferatoxin were examined in human isolated bronchus (5-12 mm o.d.). Bronchi isolated from 10 of 16 lungs contracted in response to capsaicin. The contractions averaged 20% of maximal contraction at 1 microM and averaged > 40% maximal contraction at 300 microM (the highest concentration studied). The capsaicin-induced contractions were mimicked by resiniferatoxin (0.1-10 microM) and inhibited by the putative capsaicin receptor antagonist, capsazepine (10 microM). The contractile response to capsaicin was not affected by the potent NK-2 selective antagonist SR 48968 (0.3 microM), whereas responses to concentrations of neurokinin A (10 nM), neurokinin B (0.1 microM), substance P (1 microM), neuropeptide gamma (10 nM), and neuropeptide K (10 nM) which produced similar-size contractions were almost abolished by 0.1 microM SR 48968. The bronchi isolated from 8 of 16 lungs also exhibited relaxations in response to capsaicin. Capsaicin-induced relaxations were not inhibited by the nitric oxide synthase inhibitor L-nitro-n-arginine (10 microM). In whole-cell patch-clamp experiments on human cultured airway smooth muscle cells, capsaicin was found to enhance outward currents due to the activation of charybdotoxin-sensitive large conductance Ca2+-activated K+ channels. Neither the capsaicin-induced contractions nor the relaxations were mimicked by angiotensin II, bombesin, or calcitonin gene-related peptide at concentrations up to 1 microM. These results suggest that capsaicin and resiniferatoxin can alter smooth muscle tone, but this response does not appear to involve substance P or related neurokinins. Relaxations to capsaicin may, however, involve the activation of large conductance Ca2+-activated K+ channels.

Tachykinins mediate the potentiation of antigen-induced bronchoconstriction by cold air in guinea pigs.

The role of tachykinins in the potentiation of antigen-evoked bronchoconstriction induced by inhalation of cold air was studied in guinea pigs. Cold air was delivered through a tracheal cannula to anesthetized, artificially ventilated guinea pigs sensitized with ovalbumin and pretreated with atropine (1.4 micromol/kg). Inhalation of cold air increased total pulmonary resistance (RL) in a time-dependent manner; inhalation of cold air for 10 or 15 minutes, but not for 5 minutes, produced a significant increase in RL. Aerosolized ovalbumin (5 breaths) increased RL in a dose-dependent manner (0.5% to 5%). Inhalation of cold air for 5 minutes significantly enhanced both the peak and the duration of the increase in RL induced by 0.5% ovalbumin. The tachykinin neurokinin 2-receptor antagonist, SR 48968 (0.3 micromol/kg intravenously) inhibited both the peak and the duration of the bronchoconstriction induced by 5-minute inhalation of cold air and ovalbumin (0.5%), whereas it did not affect the response to ovalbumin (0.5%) alone. These findings suggest that exposure to cold air potentiates the bronchoconstriction response to antigen and that this potentiation is mediated by tachykinin release from sensory nerves.