Regulation of the stimulant actions of neurokinin a and human hemokinin-1 on the human uterus: a comparison with histamine

Regulation of the contractile effects of tachykinins and histamine on the human uterus was investigated with biopsy sections of the outer myometrial layer. The effects of neurokinin A (NKA) and human hemokinin-1 (hHK-1) in tissues from pregnant but not from nonpregnant women were enhanced by the inhibition of neprilysin. The effects of NKA and eledoisin were blocked by the NK2 receptor antagonist SR 48968 but not by the NK1 receptor antagonist SR 140333 in tissues from both groups of women. Human HK-1 acted as a partial agonist blocked by SR 48968 and, to a lesser extent, by SR 140333; endokinin D was inactive. In tissues from pregnant women, responses to high potassium-containing Krebs solution were 2-3-fold higher than those from nonpregnant women. Mepyramine-sensitive maximal responses to histamine were similarly enhanced. The absolute maximum responses to NKA and its stable NK2 receptor-selective analogue, [Lys5MeLeu9Nle10]NKA(4-10), were increased in pregnancy, but their efficacies relative to potassium responses were decreased. Tachykinin potencies were lower in tissues from pregnant women than in those from nonpregnant women. These data 1) show for the first time that hHK-1 is a uterine stimulant in the human, 2) confirm that the NK2 receptor is predominant in mediating tachykinin actions on the human myometrium, and 3) indicate that mammalian tachykinin effects are tightly regulated during pregnancy in a manner that would negate an inappropriate uterotonic effect. The potencies of these peptides in tissues from nonpregnant women undergoing hysterectomy are consistent with their possible role in menstrual and menopausal disorders.     

Pharmacological profile of hemokinin 1: a novel member of the tachykinin family

Recently, the cloning of a novel preprotachykinin gene (PPT-C) has been reported. This gene codes for a novel peptide named hemokinin 1 (HK-1). In contrast with the known tachykinins, which are exclusively expressed in neuronal tissues, PPT-C mRNA was detected primarily in hematopoietic cells. In this study, we pharmacologically characterised the effects of HK-1 using three tachykinin monoreceptor systems, namely the rabbit jugular vein (rbJV) for NK(1), the rabbit pulmonary artery (rbPA) for NK(2), and rat portal vein (rPV) for NK(3) receptors. In all these preparations substance P (SP), neurokinin A (NKA) and neurokinin B (NKB) elicited concentration dependent contractions showing similar maximal effects and the following rank order of potency: SP > NKA = NKB in the rbJV, NKA > NKB > SP in the rbPA, and NKB > NKA > SP in the rPV. In those vessels HK-1 behaved as a full agonist displaying potencies similar (rbPA and rPV) or slightly higher (rbJV) than those of SP. In the rbJV, SR 140333, a selective NK(1) receptor antagonist, antagonised the effects of HK-1 and SP with similar high potencies (pK(B) 9.3 and 9.5, respectively). Similar results were obtained with the pseudopeptide NK(1) antagonist, MEN 11467 (pK(B) 8.8 and 8.6, respectively). Taken together, these data indicate that HK-1 behaves as a NK(1) preferring receptor agonist.     

Tachykinin receptor subtype that mediates the increase in vascular permeability in guinea pig skin

To determine the tachykinin receptor subtype that mediates the increase in vascular permeability, we examined the rank order of potency of tachykinins for inducing plasma extravasation in guinea pig skin and the specificity of tachykinin-induced tachyphylaxis of the responses. Plasma extravasation of the skin induced by tachykinins was NK-1 (SP-P)-type response from the rank order of potency of mammalian and nonmammalian tachykinins. Tachyphylaxis of the vascular response was induced by intradermal preinjection of mammalian tachykinins and was tachykinin-specific. In substance P (SP) tachyphylaxis (where SP was preinjected), the response to SP, not to neurokinin A (NKA) or neurokinin B (NKB), was decreased. In NKA tachyphylaxis and NKB tachyphylaxis, the response to NKA, not to SP or NKB, and the response to NKB, not to SP or NKA, were decreased, respectively. Thus, we conclude that the apparent NK-1-type response is mediated through three mammalian tachykinin receptors, NK-1, NK-2, and NK-3, which are specifically stimulated by their preferred agonist, SP, NKA, and NKB, respectively.     

Tachykinin receptors mediating airway macromolecular secretion.

Three tachykinin receptor types, termed NK1, NK2, and NK3, can be distinguished by the relative potency of various peptides in eliciting tissue responses. Airway macromolecular secretion is stimulated by the tachykinin substance P (SP). The purposes of this study were to determine the tachykinin receptor subtype responsible for this stimulation, and to examine the possible involvement of other neurotransmitters in mediating this effect. Ferret tracheal explants maintained in organ culture were labeled with 3H-glucosamine, a precursor of high molecular weight glycoconjugates (HMWG) which are released by airway secretory cells. Secretion of labeled HMWG then was determined in the absence and presence of the tachykinins SP, neurokinin A (NKA), neurokinin B (NKB), physalaemin (PHY), and eledoisin (ELE). All the tachykinins tested stimulated HMWG release to an approximately equal degree. Stimulation was concentration-related, with log concentrations giving half-maximal effects (EC50) as follows: SP -9.47, NKA -7.37, NKB -5.98, PHY -8.08, and ELE -7.68. This rank order of potency (SP greater than PHY greater than or equal to ELE greater than or equal to NKA greater than NKB) is most consistent with NK1 receptors. To evaluate the possible contribution of other mediators, tachykinin stimulation was examined in the presence of several receptor blockers. The potency of SP was not diminished by pretreatment with atropine, propranolol, or chlorpheniramine, and atropine actually increased the magnitude of the secretory response. The SP receptor antagonist [D-Arg1,D-Phe5, D-Trp7,9, Leu11]-SP blocked SP-induced secretion. These findings indicate that SP is a potent stimulus of airway macromolecular secretion. This effect occurs through the action of NK1 receptors, and is not dependent upon cholinergic, beta-adrenergic, or H-1 histamine receptors. The facilitation by atropine of SP stimulation suggests the existence of a mechanism of cholinergic inhibition of SP-induced stimulation.     

Expression and proliferative effect of hemokinin-1 in human B-cells

Tachykinins are a family of structurally related peptides, including substance P (SP), hemokinin-1 (HK-1), neurokinin A (NKA), and neurokinin B. SP and NKA have been shown to modulate hematopoiesis and rat/mouse HK-1 has been found to be involved in the survival and differentiation of mouse B-cells. This study was designed to assess the expression of tachykinins with a focus on human HK-1 (hHK-1) in human B lymphocytes and the role of these peptides in cell differentiation, apoptosis and proliferation. Expression of tachykinin and tachykinin receptor mRNA was determined quantitatively in human B lymphoproliferative malignancies and compared to normal B-cells. Expression of hHK-1 and NK₁ receptor, but not SP, was detected in human B-lymphocytes, and was up-regulated in B-lymphocytes from chronic lymphocytic leukemia and non-Hodgkin's lymphoma, while it was down-regulated in acute lymphoblastic leukemia. Moreover, hHK-1, in contrast to SP, was able to induce proliferation of human pre-B lymphocytes through a NK₁ receptor-independent mechanism. These data suggest a role for hHK-1 in normal and pathological B lymphopoiesis, and open the door to a better understanding of the physiopathological mechanisms leading to lymphoproliferative malignancies.     

Role of Pituitary Adenylate-Cyclase Activating Polypeptide and Tac1 gene derived tachykinins in sensory,motor and vascular functions under normal and neuropathic conditions

Pituitary Adenylate-Cyclase Activating Polypeptide (PACAP) and Tac1 gene-encoded tachykinins (substance P: SP, neurokinin A: NKA) are expressed in capsaicin-sensitive nerves, but their role in nociception, inflammation and vasoregulation is unclear. Therefore, we investigated the function of these neuropeptides and the NK₁ tachykinin receptor (from Tacr1 gene) in the partial sciatic nerve ligation-induced traumatic mononeuropathy model using gene deficient (PACAP^−/−, Tac1^−/−, and Tacr1^−/−) mice. Mechanonociceptive threshold of the paw was measured with dynamic plantar aesthesiometry, motor coordination with Rota-Rod and cutaneous microcirculation with laser Doppler imaging. Neurogenic vasodilation was evoked by mustard oil stimulating sensory nerves. In wildtype mice 30–40% mechanical hyperalgesia developed one week after nerve ligation, which was not altered in Tac1^−/− and Tacr1^−/− mice, but was absent in PACAP^−/− animals. Motor coordination of the PACAP^−/− and Tac1^−/− groups was significantly worse both before and after nerve ligation compared to their wildtypes, but it did not change in Tacr1^−/− mice. Basal postoperative microcirculation on the plantar skin of PACAP^−/− mice did not differ from the wildtypes, but was significantly lower in Tac1^−/− and Tacr1^−/− ones. In contrast, mustard oil-induced neurogenic vasodilation was significantly smaller in PACAP^−/− mice, but not in Tacr1^−/− and Tac1^−/− animals. Both PACAP and SP/NKA, but not NK₁ receptors participate in normal motor coordination. Tachykinins maintain basal cutaneous microcirculation. PACAP is a crucial mediator of neuropathic mechanical hyperalgesia and neurogenic vasodilation. Therefore identifying its target and developing selective, potent antagonists, might open promising new perspectives for the treatment of neuropathic pain and vascular complications.     

Degradative enzymes modulate airway responses to intravenous neurokinins A and B

We studied the effects of the neutral endopeptidase (NEP) inhibitor thiorphan (1.7 mg/kg iv) and the angiotensin-converting enzyme (ACE) inhibitor captopril (5.7 mg/kg iv) on airway responses to rapid intravenous infusions of neurokinin A (NKA) and neurokinin B (NKB) in anesthetized, mechanically ventilated guinea pigs. The dose of NKA required to decrease pulmonary conductance to 50% of its base-line value (ED50GL) was fivefold less (P less than 0.0001) in animals treated with thiorphan compared with controls. NKA1-8, a product resulting from cleavage of NKA by NEP, had no bronchoconstrictor activity. Similar results were obtained by using NKB as the bronchoconstricting agent. Captopril had no significant effect on airway responses to NKA or NKB. In contrast, both thiorphan and captopril decrease the ED50GL for substance P (SP). We also compared the relative bronchoconstrictor potency of NKA, NKB, and SP. In control animals, the rank order of ED50GL values was NKA much less than NKB = SP. NKA also caused a more prolonged bronchoconstriction than SP or NKB. Thiorphan had no effect on the rank order of bronchoconstrictor potency, but in animals treated with captopril, the rank order of ED50GL values was altered to NKA less than SP less than NKB. These results suggest that degradation of NKA and NKB by NEP but not by ACE is an important determinant of the bronchoconstriction induced by these peptides. The degradation by ACE of SP but not NKA or NKB influences the observed relative potency of the three tachykinins as bronchoactive agents.     

Pharmacological characterization of tachykinin septide-sensitive binding sites in the rat submaxillary gland

Binding studies have shown that [125I]NKA is a selective ligand of tachykinin septide-sensitive binding sites from membranes of the rat submaxillary gland. Indeed, this ligand bound with high affinity to a single population of sites. In addition, competition studies indicated that natural tachykinins and tachykinin-related compounds had a similar affinity for these sites than for those labeled with [3H]ALIE-124, a selective ligand of septide-sensitive binding sites. Moreover, selective tachykinin NK2, or NK3 agonists or antagonists exhibited weak or no affinity for [125I]NKA binding sites. As indicated by Ki values of several compounds, the pharmacological characteristics of the septide-sensitive binding sites (labeled with [125I]NKA) largely differ from those of classic NK1 binding sites, as determined on crude synaptosomes from the rat brain using [125I]Bolton-Hunter substance P (SP) as ligand. Indeed, several tachykinins including neurokinin A (NKA), neuropeptide K (NPK), neuropeptide gamma (NKgamma), and neurokinin B, as well as some SP and NKA analogues or C-terminal fragments such as septide, ALIE-124, SP(6-11), NKA(4-10), which have a weak affinity for classic tachykinin NK1 binding sites exhibited a high affinity for the septide-sensitive binding sites. In contrast, SP, classic selective NK1 agonists, and antagonists had a high affinity for both types of binding sites. The presence of a large population of tachykinin septide-sensitive binding sites in the rat submaxillary gland may thus explain why NPK and NPgamma induce salivary secretion and may potentiate the SP-evoked response in spite of the absence of tachykinin NK2 receptors in this tissue.     

Tachykinins Induce Secretion of Prolactin from Perifused Rat Anterior Pituitary Cells by Interactions with Two Different Binding Sites

Abstract

Substance P and the two other mammalian tachykinins, neurokinin A and B, are accepted to have direct regulating effects at the anterior pituitary level. We have examined the effects of substance P (SP) and neurokinin B (NKB), alone and in combination, on prolactin release from cultured anterior pituitary cells grown on collagen-coated micro beads and placed in a perfusion system. Prolactin (Prl) secretion was observed within 25 s after exposure to either secretagogue and reached a maximum within 60-80 s. Furthermore, the prolactin response induced by SP and NKB was dose-dependent. Prl secretion remained constant for up to 4 h when SP or NKB were perifused and then fell gradually towards basal levels. Simultaneous addition of submaximal concentrations of SP and NKB resulted in an additive response compared with the responses of either secretagogue alone. Continuous (8 h) perifusion with SP did not prevent a normal prolactin response by NKB or TRH. These results indicate that the tachykinins, substance P and neurokinin B, release Prl from perifused female rat anterior pituitary cells by interaction with two different receptors, possibly the NK1 and NK3 tachykinin receptor subtypes.     

Receptor subtypes involved in tachykinin-mediated edema formation.

Intradermal (ID) injection of the natural tachykinins substance P (SP), neurokinin A (NKA), and neurokinin B (NKB) (0.3-30 nmol) resulted in a marked and dose-related rat paw edema, with mean ED50 values of 2.68 nmol, 1.17 nmol, and 0.80 nmol, respectively. The ID injection of the selective NK1, SP methyl-ester (1-30 nmol), NK2, [beta-Ala8]-neurokinin A4-10) (beta-Ala, 0.3-30 nmol), or NK3, senktide (1-10 nmol) agonists, caused extensive edema formation with mean ED50s of 0.48 nmol, 0.41 nmol, and 0.18 nmol, respectively. The ID injection of the selective NK1 antagonist FK888 (0.1-3 nmol) produced marked inhibition (94%, 52%, and 66%, respectively) of rat paw edema induced by SP, NKA, or SP methyl-ester. The ID co-injection of the NK2 receptor antagonist SR 48968 elicited a graded inhibition (52%, 67%, and 35%, respectively) of rat paw edema induced by NKA, beta-Ala and, to a lesser extent, the edema caused by SP. Finally, the ID co-injection of the NK, receptor antagonist SR 142801 significantly inhibited (53%, 76%, 53%, and 100%, respectively) the edema formation caused by NKB and NKA or by SP and senktide. Together, the data of the present study suggest that tachykinin-mediated rat paw edema depends on the activation of NK1, NK2 and NK3 receptor subtypes, with apparent major involvement of NK1 receptors subtypes.     

Role of Tachykinin 1 and 4 Gene-Derived Neuropeptides and the Neurokinin 1 Receptor in Adjuvant-Induced Chronic Arthritis of the Mouse

Objective

Substance P, encoded by the Tac1 gene, is involved in neurogenic inflammation and hyperalgesia via neurokinin 1 (NK1) receptor activation. Its non-neuronal counterpart, hemokinin-1, which is derived from the Tac4 gene, is also a potent NK1 agonist. Although hemokinin-1 has been described as a tachykinin of distinct origin and function compared to SP, its role in inflammatory and pain processes has not yet been elucidated in such detail. In this study, we analysed the involvement of tachykinins derived from the Tac1 and Tac4 genes, as well as the NK1 receptor in chronic arthritis of the mouse.

Methods

Complete Freund’s Adjuvant was injected intraplantarly and into the tail of Tac1^−/−, Tac4^−/−, Tacr1^−/− (NK1 receptor deficient) and Tac1^−/−/Tac4^−/− mice. Paw volume was measured by plethysmometry and mechanosensitivity using dynamic plantar aesthesiometry over a time period of 21 days. Semiquantitative histopathological scoring and ELISA measurement of IL-1β concentrations of the tibiotarsal joints were performed.

Results

Mechanical hyperalgesia was significantly reduced from day 11 in Tac4^−/− and Tacr1^−/− animals, while paw swelling was not altered in any strain. Inflammatory histopathological alterations (synovial swelling, leukocyte infiltration, cartilage destruction, bone damage) and IL-1β concentration in the joint homogenates were significantly smaller in Tac4^−/− and Tac1^−/−/Tac4^−/− mice.

Conclusions

Hemokinin-1, but not substance P increases inflammation and hyperalgesia in the late phase of adjuvant-induced arthritis. While NK1 receptors mediate its antihyperalgesic actions, the involvement of another receptor in histopathological changes and IL-1β production is suggested.     

Attenuation of reflex pressor and ventilatory responses to static contraction by an NK-1 receptor antagonist.

The chemical messengers released onto second-order dorsal horn neurons from the spinal terminals of contraction-activated group III and IV muscle afferents have not been identified. One candidate is the tachykinin substance P. Related to substance P are two other tachykinins, neurokinin A (NKA) and neurokinin B (NKB), which, like substance P, have been isolated in the dorsal horn of the spinal cord and have receptors there. Whether NKA or NKB plays a transmitter/modulator role in the spinal processing of the exercise pressor reflex is unknown. Therefore, we tested the following hypotheses. After the intrathecal injection of a highly selective NK-1 (substance P) receptor antagonist onto the lumbosacral spinal cord, the reflex pressor and ventilatory responses to static muscular contraction will be attenuated. Likewise, after the intrathecal injection either of an NK-2 (NKA) receptor antagonist or an NK-3 (NKB) receptor antagonist onto the lumbrosacral spinal cord, the reflex pressor and ventilatory responses to static contraction will be attenuated. We found that, 10 min after the intrathecal injection of 100 micrograms of the NK-1 receptor antagonist, the pressor and ventilatory responses to contraction were significantly (P < 0.05) attenuated. Mean arterial pressure was attenuated by 13 +/- 3 mmHg (48%) and minute volume of ventilation by 120 +/- 38 ml/min (34%). The cardiovascular and ventilatory responses to contraction before either 100 micrograms of the NK-2 receptor antagonist or 100 micrograms of the NK-3 receptor antagonist were not different (P > 0.05) from those after the NK-2 or the NK-3 receptor antagonists.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of tachykinins in non-adrenergic non-cholinergic excitation in smooth muscles of the gastrointestinal tract

Two peptides from the tachykinin family, substance P (SP) and neurokinin A (NKA), were identified as neurotransmitters (co-transmitters) of non-adrenergic non-cholinergic (NANCh) excitation in the gastrointestinal tract. The contraction of smooth muscles produced by tachykinins released from the excitatory enteric motoneurons is mediated by the NK1 and/or the NK2 tachykinin receptors. The differing contribution of these receptors in mediating the NANCh excitatory responses has been demonstrated in various regions of the intestine. The NK3 tachykinin receptors are confined only to the enteric neurons; they mediate release of different excitatory and inhibitory transmitters. The main secondary messenger pathway for all three tachykinin receptors is phosphoinositide breakdown that results in an increase of intracellular Ca²⁺ concentration. Signal transduction mechanisms are still not adequately known for tahykinin receptors. A multiple ionic mechanism has been proposed to mediate excitatory action of SP; it comprises activation of non-selective cationic channels, or activation of maxi Cl^– channels, and/or inhibition of K⁺ channels. Data about the ionic mechanism underlying the NK2 receptor activation are still missing. In conclusion, SP and NKA play a physiological role as NANCh neurotransmitters in smooth muscles of the gastrointestinal tract and, therefore, tachykinins may have a significant pathophysiological relevance in humans.Neirofiziologiya/Neurophysiology, Vol. 27, No. 5/6, pp. 425–432, September–December, 1995.     

Structure–activity relationship study of tachykinin peptides for the development of novel neurokinin-3 receptor selective agonists

Neurokinin B (NKB) is a potential regulator of pulsatile gonadotropin-releasing hormone (GnRH) secretion via activation of the neurokinin-3 receptor (NK3R). NKB with the consensus sequence of the tachykinin peptide family also binds to other tachykinin receptors [neurokinin-1 receptor (NK1R) and neurokinin-2 receptor (NK2R)] with low selectivity. In order to identify the structural requirements for the development of novel potent and selective NK3R agonists, a structure–activity relationship (SAR) study of [MePhe⁷]-NKB and other naturally occurring tachykinin peptides was performed. The substitutions to naturally occurring tachykinins with Asp and MePhe improved the receptor binding and agonistic activity for NK3R. The corresponding substitutions to NKB provided an NK3R selective analog.