The neuropeptide neuromedin U activates eosinophils and is involved in allergen-induced eosinophilia

Neuromedin U (NMU) is a neuropeptide expressed not only in the central nervous system but also in various organs, including the gastrointestinal tract and lungs. NMU interacts with two G protein-coupled receptors, NMU-R1 and NMU-R2. Although NMU-R2 is expressed in a specific region of the brain, NMU-R1 is expressed in various peripheral tissues, including immune and hematopoietic cells. Our recent study demonstrated an important role of NMU in mast cell-mediated inflammation. In this study, we showed that airway eosinophilia was reduced in NMU-deficient mice in an allergen-induced asthma model. There were no differences in the antigen-induced Th2 responses between wild-type and NMU knockout mice. NMU-R1 was highly expressed in the eosinophil cell line, and NMU directly induced Ca(2+) mobilization and extracellular/signal-regulated kinase phosphorylation. NMU also induced cell adhesion to components of the extracellular matrix (fibronectin and collagen type I), and chemotaxis in vitro. Furthermore, NMU-R1 was also expressed in human peripheral blood eosinophils, and NMU induced cell adhesion in a dose-dependent manner. These data indicate that NMU promotes eosinophil infiltration into inflammatory sites by directly activating eosinophils. Our study suggests that NMU receptor antagonists could be novel targets for pharmacological inhibition of allergic inflammatory diseases, including asthma.     

The neuropeptide neuromedin U promotes IL-6 production from macrophages and endotoxin shock

Neuromedin U (NMU) is a neuropeptide involved in appetite, circadian rhythm, and pronociception. However, the NMU receptor NMU-R1 has been shown to be expressed in immune cells and NMU promotes mast cell-dependent inflammation. In this study, we demonstrated that NMU plays an important role in IL-6 production in macrophages. NMU-deficient mice were resistant against cecal ligation puncture- as well as LPS-induced septic shock. IL-6 but not TNF-alpha levels were markedly reduced in LPS-treated NMU-deficient mice compared with wild type mice. Both NMU and NMU-R1 were expressed in wild type peritoneal macrophages, and treatment with LPS resulted in up-regulation of NMU but down-regulation of NMU-R1 expression, however, no down-regulation of NMU-R1 was observed in NMU-deficient macrophages where LPS-induced IL-6 production was severely reduced. These data suggest that LPS-induced IL-6 expression is partly dependent on autocrine/paracrine activation of the NMU-NMU-R1 signals in macrophages.     

Calcium activates and inactivates a photoreceptor soma potassium current.

Light-induced currents were measured with a two-microelectrode voltage clamp of type B photoreceptor somata, which had been isolated by axotomy from all synaptic interactions as well as from all membranes capable of generating impulse activity. In artificial seawater (ASW), light elicited a transient early inward current, INa+, which depended on Na+o and had a linear current-voltage relation and an extrapolated reversal potential of 30-40 mV (absolute). In 0-Na+ ASW, light elicited a transient short-latency outward current that dependent on K+o, increased exponentially with more positive voltages (greater than or equal to -40 mV), and reversed at -70 to -75 mV. This outward current was not blocked by Ca++ channel blockers (e.g., Cd++, Co++) or substitution of Ba++o, for Ca++o, but was reduced by iontophoretic injection of EGTA. In both ASW and 0-Na+ ASW, light also elicited a delayed, apparently inward current, which was associated with a decreased conductance, depended on K+o, increased exponentially with more positive voltages (greater than or equal to -40 mV), reversed at the equilibrium potential for K+ flux in elevated K+o was eliminated by substitution of Ba++o for Ca++o, and was greatly reduced by Cd++o or Co++o. Thus, light elicited an early Ca++-dependent K+ current, IC, and a prolonged decrease of IC. Iontophoretic injection of Ca++ through a third microelectrode caused prolonged reduction of both IC and the light-induced decrease of IC, but did not alter ICa++ or the current-voltage relation of IC. Ruthenium red (1 microM) in the external medium caused a prolongation of the light-induced decrease of IC. Iontophoretic injection of EGTA often eliminated the light-induced IC decrease while decreasing peak IC (during depolarizing steps to -5 or 0 mV) by less than one-half. EGTA injection, on the average, did not affect steady state IC but reduced the light-induced decrease of steady state IC to approximately one-third of its original magnitude. The prolonged IC decrease, elicited by dim light in the absence of light-induced IC or INa+, was more completely eliminated by EGTA injection. It was concluded that light, in addition to inducing a transient inward Na+ current, causes both a transient increase and a prolonged decrease of IC via elevation of Ca++i.     

The neuropeptide neuromedin U promotes autoantibody-mediated arthritis

Introduction  

Neuromedin U (NMU) is a neuropeptide with pro-inflammatory activity. The primary goal of this study was to determine if NMU promotes autoantibody-induced arthritis. Additional studies addressed the cellular source of NMU and sought to define the NMU receptor responsible for its pro-inflammatory effects.     

Sodium-activated potassium current in mouse diaphragm

The mouse diaphragm muscle fiber was studied using the loose patch clamp technique. The voltage gated sodium currents were evoked by step pulses from a holding potential of about −70 mV. Following the activation of the sodium current, a very large and fast outward current was evoked. The sensitivity of this current to 4-aminopyridine and tetraethylammonium indicates the potassium ion as the possible carrier for the channel. Furthermore, the sensitivity to tetrodotoxin and extracellular sodium demonstrated the sodium dependence of this current.     

Delayed-rectifying potassium channels in mouse peritoneal macrophages: Pharmacological analysis

The effects of 4-aminopyridine, verapamil, and 4-bromophenacylbromide (4-BPB) on the kinetics of delayed outward-rectifying potassium currents (I _K) were investigated in cultured mouse peritoneal macrophages using a classical whole-cell patch-clamp technique. The outwardI _K was completely blocked by 4-aminopyridine at 1.0 mM concentration. Verapamil at the same concentration also blockedI _K completely. Lower concentration (50 µM) of verapamil demonstrated only partial blocking action, which was almost fully reversible, and markedly increased the rate ofI _K inactivation. The main effect of 4-BPB on the outwardI _K was a significant acceleration ofI _K activation and inactivation kinetics. It is suggested that this modulation results from a direct effect of 4-BPB on potassium channels or relates to the arachidonic acid cascade.Neirofiziologiya/Neurophysiology, Vol. 26, No. 1, pp. 49–53, January–February, 1994.     

SR47063, A potent channel opener,activates KATP and a time-dependent current likely due to potassium accumulation

(i) We studied the effects of a new cromakalim analogue, SR47063, in guinea-pig ventricular cells. The experiments were carried out in whole-cell patch clamp with internal and external solutions supposedly similar to the physiological ones. (ii) SR47063 reversibly activated a time-independent current reversing near the potassium equilibrium potential, and a time-dependent current reversing at a more positive potential. Both currents were blocked by application of glibenclamide. (iii)The time-independent and the time-dependent currents were activating for the same concentration of agonist in every cell, this concentration being very different from cell to cell. (iv) The amplitude of the time-dependent current was shown to depend directly neither on agonist concentration nor on potential, but rather on the amplitude of the current flowing during the prepulse before the test pulse. (v) We conclude that SR47063 is a potent K_ATP channel opener acting at concentrations lower than one micromolar, and that the time-dependent current is likely due to accumulation and depletion of potassium in restricted areas of the cells.The authors wish to thank C. Ojeda and O. Rougler for their helpful comments.     

Calcium-mediated decrease of a voltage-dependent potassium current.

Elevated intracellular Ca++ concentration reduces the amplitude of an early, voltage-dependent K+ current (IA) in the Type B photoreceptor of Hermissenda crassicornis. Internal Ca++ is increased by activating a voltage and light-dependent Ca++ current present in these cells or by direct iontophoresis of Ca++ ions. Substitution of Ba++ for Ca++ or elimination of Ca++ from the sea water bathing the cells abolishes the reduction in IA during paired light and depolarizing voltage steps. The delayed K+ current (IB) in these cells is also reduced during paired light and voltage steps, but this decrease of IB is not affected by removal of extracellular Ca++. IB (but not IA), apparently much less dependent on intracellular Ca++ levels, is reduced by light alone. Ca++ iontophoresis also abolishes the light-dependent Na+ current, which recovers with a time course of minutes.     

Membrane structure of bombesin studied by infrared spectroscopy. Prediction of membrane interactions of gastrin-releasing peptide, neuromedin B, and neuromedin C

Bombesin, in contact with flat phospholipid bilayer membranes, was shown to adopt a membrane structure similar to that of substance P, dynorphin-(1-13)-tridecapeptide, and adrenocorticotropin-(1-24)-tetracosapeptide. The C-terminal message segment, comprising 8-10 amino acid residues, is inserted into a relatively hydrophobic membrane compartment as an alpha-helical domain oriented perpendicularly on the membrane surface. The N-terminal, hydrophilic tetrapeptide segment remains in the aqueous compartment as a random coil. This was shown with IR and IR attenuated total reflection spectroscopy. Equilibrium thermodynamic estimations confirmed the observed membrane structure with respect to helix length, strength of hydrophobic membrane association, and orientation (caused by favorably oriented molecular amphiphilic and helix electric dipole moments). The membrane structure may explain why Trp-8 and His-12 are essential for biologic activity. Neuromedin B is predicted to be able to adopt a membrane structure similar to that of bombesin. However, gastrin-releasing peptide and neuromedin C are predicted not to behave in the same manner. The molecular mechanism of receptor subtype selection by bombesin-like peptides may prove to be similar to that observed earlier for opioid peptides and the neurokinins.     

Induction of two K+ currents by complement component C5a in mouse macrophages.

Puff application of complement component C5a (5 x 10(-8) M) onto peritoneal macrophages from thioglycollate-stimulated mice induced two kinds of outward current at a holding potential of -68 mV, a slowly-rising sustained outward current and a spike-like transient outward current. Quinidine (2 x 10(-4) M) and tetraethylammonium (10(-2) M) partially suppressed both types of outward current. Charybdotoxin (2 x 10(-6) M) markedly suppressed the spike-like outward current. Reversal potentials in bath solutions of different external K+ concentrations were dependent only on K+ concentrations. The transient current was not suppressed in Ca(2+)-free EGTA-containing solution, but was completely abolished in BAPTA-containing solution. One kind of single channel responding to C5a, which has a single-channel conductance of 29 pS, was recorded from cell-attached patches. These results suggest that C5a activates a Ca(2+)-dependent and another type of K+ current.     

Regulation of prostaglandin synthesis by protein kinase C in mouse peritoneal macrophages.

Resident mouse peritoneal macrophages synthesized and released prostaglandins (PGs) when challenged with 12-O-tetradecanoylphorbol 13-acetate (TPA) or 1,2-dioctanoyl-sn-glycerol (DiC8). Both stimuli were found to activate Ca2+/phospholipid-dependent protein kinase C (PKC). 1-(5-Isoquinolinesulphonyl)-2-methylpiperazine ('H-7') and D-sphingosine, known to inhibit PKC by different mechanisms, were able to decrease the PKC activity of macrophages in a dose-dependent manner. Addition of either PKC inhibitor decreased PG synthesis and also the release of arachidonic acid (AA) from phospholipids induced by TPA or DiC8. Simultaneously TPA or DiC8 also decreased incorporation of free AA into membrane phospholipids of macrophages. AA incorporation could be restored, however, by pretreatment with the PKC inhibitors. Our results demonstrate an involvement of PKC in the regulation of PG synthesis in mouse peritoneal macrophages and provide further evidence that reacylation of released fatty acids may be an important regulatory step.     

The synthetic peptide octarphin activates soluble guanylate cyclase in macrophages

The effect of the peptide octarphin (TPLVTLFK), a selective agonist of the nonopioid β-endorphin receptor, on the activity of soluble (sGC) and membrane-bound guanylate cyclase (mGC) of peritoneal macrophages from mouse, rat, and guinea pig has been studied. It has been found that, in the concentration range of 10–1000 nM, octarphin increases the activity of sGC and has no effect on the activity of mGC in macrophages of these species. The activating effect of the peptide toward sGC was dose-dependent and was maximal at a concentration of 100 nM. These results indicate that the increase in the concentration of guanosine 3',5'-cyclophosphate in macrophages in the presence of octarphin occurs through the activation of sGC. It can be stated that the activating effect of octarphin on peritoneal macrophages is accomplished in the following way: an increase in the activity of inducible NO synthase → an increase in NO production → activation of sGC → an increase in the intracellular cGMP level.     

Hypotonicity activates a native chloride current in Xenopus oocytes

Xenopus oocytes are frequently utilized for in vivo expression of cellular proteins, especially ion channel proteins. A thorough understanding of the endogenous conductances and their regulation is paramount for proper characterization of expressed channel proteins. Here we detail a novel chloride current (ICl.swell) responsive to hypotonicity in Xenopus oocytes using the two-electrode voltage clamp technique. Reducing the extracellular osmolarity by 50% elicited a calcium-independent chloride current having an anion conductivity sequence identical with swelling-induced chloride currents observed in epithelial cells. The hypotonicity-activated current was blocked by chloride channel blockers, trivalent lanthanides, and nucleotides. G- protein, cAMP-PKA, and arachidonic acid signaling cascades were not involved in ICl.swell activation. ICl.swell is distinct from both stretch-activated nonselective cation channels and the calcium- activated chloride current in oocytes and may play a critical role in volume regulation in Xenopus oocytes.     

The role of a transient potassium current in a bursting neuron model

Presented here is a biophysical cell model which can exhibit low-frequency repetitive activity and bursting behavior. The model is developed from previous models (Av-Ron et al. 1991, 1993) for excitability, oscillations and bursting. A stepwise development of the present model shows the contribution of a transient potassium current (I _A ) to the overall dynamics. By changing a limited set of model parameters one can describe different firing patterns; oscillations with frequencies ranging from 2–200 Hz and a wide range of bursting behaviors in terms of the durations of bursting and quiescence, peak firing frequency and rate of change of the firing frequency.     

Calcium- and voltage-activated potassium channels in human macrophages.

Single calcium-activated potassium channel currents were recorded in intact and excised membrane patches from cultured human macrophages. Channel conductance was 240 pS in symmetrical 145 mM K+ and 130 pS in 5 mM external K+. Lower conductance current fluctuations (40% of the larger channels) with the same reversal potential as the higher conductance channels were noted in some patches. Ion substitution experiments indicated that the channel is permeable to potassium and relatively impermeable to sodium. The frequency of channel opening increased with depolarization and intracellular calcium concentration. At 10(-7) M (Ca++)i, channel activity was evident only at potentials of +40 mV or more depolarized, while at 10(-5) M, channels were open at all voltages tested (-40 to +60 mV). In intact patches, channels were seen at depolarized patch potentials of +50 mV or greater, indicating that the ionized calcium concentration in the macrophage is probably less than 10(-7) M.