Signalling of multiple interleukin (IL)-17 family cytokines via IL-17 receptor A drives psoriasis-related inflammatory pathways.

BACKGROUND: The interleukin (IL)-23/IL-17 immune axis is of central importance in psoriasis. However, the impact of IL-17 family cytokines other than IL-17A in psoriasis has not been fully established. OBJECTIVES: To elucidate the contribution of IL-17 family cytokines in psoriasis. METHODS: To address the expression and localization of IL-17 family cytokines, lesional and nonlesional skin samples from patients with psoriasis were analysed by several complementary methods, including quantitative polymerase chain reaction, immunoassays, in situ hybridization and immunohistochemistry. Mechanistic studies assessing the functional activity of IL-17 family cytokines were performed using ex vivo cultured human skin biopsies and primary human keratinocytes. RESULTS: We demonstrated that IL-17A, IL-17F, IL-17A/F and IL-17C are expressed at increased levels in psoriasis lesional skin and induce overlapping gene expression responses in ex vivo cultured human skin that correlate with the transcriptomic signature of psoriasis skin. Furthermore, we showed that brodalumab, in contrast to ixekizumab, normalizes gene expression responses induced by the combination of IL-17A, IL-17F, IL-17A/F and IL-17C in human keratinocytes. CONCLUSIONS: Several IL-17 ligands signalling through IL-17RA are overexpressed in psoriasis skin and induce similar psoriasis-related inflammatory pathways demonstrating their relevance in relation to therapeutic intervention in psoriasis.

Bidirectional synaptic transmission in Necturus taste buds.

Pairs of taste cells were impaled with intracellular recording microelectrodes in intact taste buds in slices of Necturus lingual epithelium. Applying short pulses of 140 mM KCl or 200 mM CaCl2 solutions to the apical pore elicited receptor potentials in taste receptor cells. Chemostimulation of receptor cells elicited postsynaptic responses in basal cells in the taste bud. Postsynaptic responses in basal cells had a threshold for activation and did not saturate with increasing doses of chemical stimulus applied to the receptor cells. We directly depolarized individual receptor cells and tested whether this would evoke postsynaptic responses in basal cells. Depolarizing receptor cells to approximately 0 mV evoked small depolarizing responses in basal cells in 16% of the experiments. The properties of these responses were consistent with their being mediated by a chemical synapse. A comparison of the responses in basal cells evoked by depolarizing single receptor cells, with responses evoked by stimulating the entire receptor cell population with KCl suggests that there is extensive synaptic convergence from receptor cells onto each basal cell. We also tested whether electrical excitation of basal cells would elicit (retrograde) synaptic responses in receptor cells. Single depolarizing pulses (up to 1 sec duration) applied to basal cells through the intracellular recording microelectrode never evoked synaptic responses in receptor cells. However, when repetitive electrical stimuli were applied to basal cells (four to six 1 sec depolarizations to approximately 0 mV every 12 sec) we observed prolonged effects on receptor cells in 11 of 23 experiments. These effects included an increase in the amplitude of receptor potentials elicited by KCI (mean +/- SD = +19 +/- 5%), an increase in membrane input resistance of receptor cells (+27 +/- 11%), and a hyperpolarization of receptor cells (3-10 mV). In control experiments, repetitive stimulation of one receptor cell never elicited such effects in another receptor cell. We investigated the possibility that serotonin (5-HT), released from basal cells, mediated the above modulatory effects on receptor cells. Bath-applied 5-HT (100 microM) mimicked the effects produced by repetitive basal cell stimulation (KCI responses increased by 23 +/- 12%; input resistance increased by 24 +/- 11%; hyperpolarization of 5-15 mV; N = 14). We conclude that basal cells release 5-HT onto adjacent taste receptor cells and that this enhances the electrotonic propagation of receptor potentials from the apical (chemosensitive) tip to the basal (synaptic) processes of receptor cells. The net effect is that activation of basal cells effectively increases the chemosensitivity of taste receptor cells.

Intercellular signaling in Necturus taste buds: chemical excitation of receptor cells elicits responses in basal cells.

1. Taste cells in intact taste buds in slices of Necturus lingual epithelium were impaled with microelectrodes for intracellular recording. Two types of cells were investigated: taste receptor cells and basal cells. 2. Impaling cells in the apical end of taste buds resulted in intracellular records from taste receptor cells. Applying short pulses (100- to 200-ms duration) of 140 mM KCl solution to the apical pore elicited receptor potentials in the taste receptor cells. 3. Impaling cells in the base of the taste bud resulted in intracellular records from taste receptor cells and basal cells. KCl applied to the taste pore elicited responses in the basal region that varied greatly in both magnitude and time of onset. The latency of these responses (time of onset compared with the onset of the receptor potential) ranged from 0 to hundreds of milliseconds. 4. Impaled cells were identified by injecting Lucifer yellow after recording KCl responses for 21 cells. KCl responses recorded from identified basal cells all had latencies of greater than 75 ms. KCl responses from identified receptor cells all had latencies of less than 75 ms. 5. One explanation for the long latency of KCl responses recorded in basal cells is that the responses represent postsynaptic potentials. In agreement with this interpretation, long-latency responses, but not short-latency responses, were reversibly reduced by the Ca antagonist Cd (1 mM, 10- to 20-min bath exposure). 6. Long-latency responses also differed from short-latency responses in their voltage dependence. Short-latency responses had the same voltage dependence as apically recorded receptor potentials, increasing with hyperpolarization from resting potential with an extrapolated reversal potential near 0 mV. Long-latency responses were much less dependent on voltage in this range. 7. We measured the spread of exogenously applied KCl with potassium-sensitive electrodes. Long-latency responses were not generated by diffusion of applied KCl to the basal region of the taste bud. A small transient increase in extracellular potassium occurred at the base of the taste bud after chemostimulation at the apical pore. This increase was due to depolarization-evoked release of potassium from taste cells and did not cause the long-latency responses in basal cells. 8. We conclude that short-latency (less than 75 ms) responses recorded from cells situated in the bases of taste buds are electrotonically conducted receptor potentials generated at the apical region. Long-latency (greater than 75 ms) responses are consistent with recording postsynaptic responses in basal cells.

Purification and characterization of Go alpha and three types of Gi alpha after expression in Escherichia coli.

Complementary DNAs for the G protein alpha subunits Gi alpha 1, Gi alpha 2, Gi alpha 3, and Go alpha were expressed in Escherichia coli, and the four proteins were purified to homogeneity. The recombinant proteins exchange and hydrolyze guanine nucleotide, are ADP-ribosylated by pertussis toxin, and interact with beta gamma subunits. The rates of dissociation of GDP from Gi alpha 1 and Gi alpha 3 (0.03 min-1) are an order of magnitude slower than that from rGo alpha; release of GDP from Gi alpha 2 is also relatively slow (0.07 min-1). However, the values of kcat for the hydrolysis of GTP by rGo alpha and the three rGi alpha proteins are approximately the same, about 2 min-1 at 20 degrees C. The recombinant proteins restore inhibition of Ca2+ currents in pertussis toxin-treated dorsal root ganglion neurons in response to neuropeptide Y and bradykinin, indicating that the proteins can interact functionally with all necessary components of at least one signal transduction system. The two different receptors function with different arrays of G proteins to mediate their responses, since all four G proteins restored responses to bradykinin, while Gi alpha 2 was inactive with neuropeptide Y. Despite these results, high concentrations of activated Gi alpha proteins are without effect on adenylyl cyclase activity, either in the presence or absence of forskolin or Gs alpha, the G protein that activates adenylyl cyclase. These results are consistent with the hypothesis that G protein beta gamma subunits are primarily responsible for inhibition of adenylyl cyclase activity.

Differential G protein-mediated coupling of neurotransmitter receptors to Ca2+ channels in rat dorsal root ganglion neurons in vitro.

The peptides neuropeptide Y (NPY) and bradykinin (BK) both inhibited Ca2+ currents in rat dorsal root ganglion neurons (DRG) in vitro. The effects of both peptides were completely blocked by treatment of cells with pertussis toxin. Based on antigenic determinants, DRG cells contained at least two pertussis toxin substrates, alpha o (Mr, 39 kd) and alpha i2 (Mr, 40 kd). We examined the ability of three purified bovine alpha subunits (identified with antibodies as alpha o, alpha i1, and alpha i2) to reconstitute the inhibitory effects of NPY and BK. Reconstitution of NPY effects occurred according to the potency series alpha o greater than alpha i1 much greater than alpha i2. However, in the case of BK all three G proteins were approximately equally effective. Whereas complete reconstitution of NPY effects could be obtained with alpha o, no single alpha subunit produced complete reconstitution of BK. Combinations of alpha o and alpha i2, however, were able to completely reconstitute the effects of BK. Thus several G proteins can effect the regulation of Ca2+ channels in these cells. However, neurotransmitters may be selective in the G proteins or combinations of G proteins utilized to achieve this regulation.

The effect of down regulation of protein kinase C on the inhibitory modulation of dorsal root ganglion neuron Ca2+ currents by neuropeptide Y.

Dorsal root ganglion (DRG) neurons cultured from neonatal rats contained high concentrations of protein kinase C (PKC). Normally, the majority of the enzyme activity was found in the cytosol and considerably less was associated with the membrane fraction. Upon incubation with the phorbol ester phorbol dibutyrate (PDBu, 10(-6) M) for 20 min, PKC activity increased in the membrane-associated fraction and decreased in the cytoplasmic fraction. Longer incubations with phorbol ester also induced a decline in membrane-associated PKC activity. If incubations were continued for periods of over 10 hr, both membrane and cytosolic PKC activity declined essentially to zero. Down-regulation of PKC had no effect on the number or affinity of 125I-neuropeptide Y (NPY) binding sites on DRG cells or on the absolute magnitude of the DRG Ca2+ current. However, the ability of NPY to inhibit the DRG Ca2+ current was greatly reduced. When sustained Ca2+ currents were evoked from depolarized holding potentials (-40 mV), all concentrations of NPY (10(-10)-10(-7) M) were less effective. In contrast, higher concentrations of NPY still blocked the transient portion of the DRG Ca2+ current evoked from hyperpolarized holding potentials. These results support the suggestion that PKC is involved in the inhibitory modulation of DRG Ca2+ currents by neurotransmitters. The precise role of PKC may vary depending on the type of Ca2+ channel involved.

Neuropeptide Y modulates neurotransmitter release and Ca2+ currents in rat sensory neurons.

Using 125I-labeled neuropeptide Y (NPY) and peptide YY (PYY), we demonstrated the existence of specific receptors for these peptides on rat dorsal root ganglion (DRG) cells grown in primary culture. Scatchard analysis of membrane homogenates indicated that the peptides bound to 2 populations of sites, with approximate affinities of 0.08 and 6.5 nM. Only low levels of binding were detected on sympathetic neurons cultured from the same animals or on a variety of neuronal clonal cell lines. The binding of 125I-NPY and 125I-PYY to DRG cell membranes was considerably reduced by the nonhydrolyzable analog of GTP, Gpp(NH)p. The major effect of Gpp(NH)p was to reduce the number of lower-affinity NPY binding sites without altering the number of high-affinity binding sites. NPY potently inhibited Ca2+ currents recorded under voltage clamp in rat DRG cells. Both the transient and sustained portions of the Ca2+ current were inhibited. The inhibitory effects of NPY were completely blocked following treatment of the cells with pertussis toxin. Depolarization elicited a large influx of Ca2+ into DRG neurons as assessed using fura-2-based microspectrofluorimetry. This influx of Ca2+ could be partially inhibited by NPY. Furthermore, NPY effectively inhibited the depolarization-induced release of substance P from DRG cells in vitro. Thus, NPY may be an important regulator of sensory neuron function in vivo.

Guanine nucleotide-binding protein Go-induced coupling of neuropeptide Y receptors to Ca2+ channels in sensory neurons.

Neuropeptide Y (NPY) inhibited the Ca2+ current (ICa) in rat dorsal root ganglion neurons in vitro. NPY inhibited the sustained ICa evoked by steps to 0 mV from a holding potential of -40 mV and the inactivating ICa, which was additionally evoked from a more negative holding potential of -80 mV. The effects of NPY on both phases of the ICa were abolished if cells were first treated with pertussis toxin (PTX). When a combination of GTP and the purified alpha-subunit of the guanine nucleotide-binding protein Go was perfused into PTX-treated cells, the inhibitory effects of NPY on the ICa reappeared in a time-dependent fashion. GTP or alpha-subunit perfused separately was relatively ineffective. The effects of NPY reappeared more rapidly at higher concentrations of alpha o. Chronic treatment of these cells with phorbol ester "down-regulates" protein kinase C (PKC) and reduces inhibition of the sustained current by NPY. In PTX-treated cells in which PKC had been removed by down-regulation, inhibition of ICa was also reconstituted following the perfusion of GTP/alpha o. Under these circumstances, NPY inhibited the transient phase of the ICa more than the sustained phase. These results indicate that Go, the major PTX substrate in the central nervous system, may normally mediate the inhibitory effects of NPY receptors on dorsal root ganglion Ca2+ channels.

Modulation of single Ca2+-dependent K+-channel activity by protein phosphorylation.

There is considerable evidence that cyclic AMP can modulate the electrical activity of excitable cells and that protein phosphorylation by the catalytic subunit (CS) of cAMP-dependent protein kinase is a necessary step in these modulatory effects. In analogy to alterations in enzyme activities following phosphorylation, it seems possible that direct phosphorylation of ion-channel proteins may alter their gating properties, giving rise to the observe changes in electrical activity. However, the results obtained so far do not indicate whether it is ion channels themselves that are phosphorylated, or whether phosphorylation is simply an early step in some cascade of events which leads ultimately to modulation of channel activity. The development of single-channel recording techniques has provided a way to investigate this question. Here we describe effects of CS on the activity of individual CA2+-dependent K+ channels from the nervous system of the land snail Helix measured in isolated membrane patches and in artificial phospholipid bilayers. The results demonstrate that cAMP-dependent protein phosphorylation produces long-lasting changes in the activity of individual channels, and indicate that the relevant phosphorylation site is closely associated with the channel.

Potentiation of postjunctional cholinergic sensitivity of rat diaphragm muscle by high-energy-phosphate adenine nucleotides.

The cholinergic sensitivity of rat diaphragm muscle, me-sured as the magnitude of depolarization responses to repetitive, iontophoretic pulses of acetylcholine (ACh) onto neuromuscular endplates, is increased by addition of ATP to the perfusion medium. Depolarization responses begin to increase within the first min after addition of 10 mM ATP and plateau at 60% above control levels (mean value) after 4 to 6 min. Neither the magnitude nor the time course of the potentiations corresponds to changes in resting potential or membrane resistance. Other nucleotides are equally or less effective at the same concentration: ATP=ADP greater than UTP greater than AMP=GTP (=no added nucleotide control) The duration of the individual ACh responses does not increase during continuous exposure to the active nucleotides for up to 15 min except when the muscle is pretreated with eserine. Mild enzymatic predigestion of the muscle with collagenase and then protease, increasing the availability of the postjunctional membrane to bath-applied drugs, decreases the variability and increases the magnitude of the potentiation to a given dose of ATP. The dose-response curve for ATP is then more than half-maximal at 1 mM and the ranking of the other nucleotides relative to ATP is the same as without predigestion. There is an optimum Ca++ concentration for the potentiation between zero and 2 mM: potentiation is enhanced in Ca++ -free medium, partially blocked in twice-normal Ca++ medium, and totally blocked in Ca++ -free medium 10 min after a 5 min exposure to 2.5 mM EGTA. The similar Ca++ dependence of ACh receptor activation in the absence of added nucleotide suggests that ATP directly facilitates receptor activation by ACh. This facilitory action could be one of the physiological roles for the ATP released from stimulated phrenic nerve.

Modulation of postjunctional cholinergic sensitivity of rat diaphragm muscle by cyclic adenosine monophosphate.

Addition of 2.5 mM cyclic adenosine monophosphate (cAMP) to the solution bathing a rat diaphragm muscle alters the magnitude of depolarization responses to iontophoretic pulses of acetylcholine (ACh) at neuromuscular endplates. Alterations are repeatable with small variability on a given preparation for initial and repeat experiments on both hemidiaphragms, but are different on each preparation. Five min after addition of the nucleotide solution, increases (potentiations) of up to 30% above control levels and decreases (attenuations) to 50% below control levels are observed. The effects on sensitivity to ACh of dibutyryl cAMP (1.25 mM), monobutyryl cAMP (0.25 mM), and cAMP (2.5 mM) in Ca++ -free solution are a function of whether the experiment is an initial one on that preparation or a repeat experiment after 10 or more minutes of perfusion flow. In all three cases, initial exposure attenuates sensitivity (means at 5 min: --30, --10, and --20%, respectively) and repeat exposure potentiates sensitivity (mean: 20% at 5 min, 15% at 5 min, and 10% at 2 min respectively). A concentration of dibutyryl cAMP (0.25 mM) which is without effect on sensitivity alone, produces a large, transient potentiation (mean: 45% at 1 min) in conjunction with 0.5 mM theophylline. A decrease in the rate of desensitization is observed during exposure to 0.25 mM cAMP. The results are interpreted in terms of a physiological mechanism whereby receptor activity at the postjunctional membrane is modulated by cAMP formed from prejunctionally released ATP.