ATP-gated currents in rat primary auditory neurones in situ arise from a heteromultimetric P2X receptor subunit assembly.

Spiral ganglion neurones provide the primary afferent innervation to sensory hair cells within the mammalian cochlea. Recent evidence suggests that their function may be modulated by purinergic signalling mechanisms, associated with release of adenosine 5'-triphosphate (ATP). Utilising a newly developed slice preparation of the neonatal rat cochlea, we have investigated the response of neurones in situ, to purinergic agonists and antagonists using whole-cell voltage clamp recordings. In cells identified as type I spiral ganglion neurones on the basis of morphology and voltage-dependent conductances, pressure-applied ATP, alpha,beta-methyleneATP (alpha,beta-meATP), 2-methylthioATP (2-MeSATP) and adenosine 5'-diphosphate (ADP) elicited a consistent phenotype of desensitising, inwardly rectifying current. The ATP-activated currents were reversibly blocked by the P2X receptor antagonists pyridoxalphosphate-6-azophenyl-2',4'-disulphonic acid (PPADS, 10 microM), and 2',3'-O-(2,4,6-trinitrophenyl)-ATP (TNP-ATP; IC(50) 407 nM). Neurones were more sensitive to ATP at low pH. The EC(50) value for ATP shifted from 18 microM at pH 7.3, to 1 microM at pH 6.3, with Hill coefficients of approximately 1. The results indicate that ATP-gated ion channels in spiral ganglion neurones arise from a specific heteromultimeric assembly of P2X receptor subunits which has no correspondence with present recombinant P2X receptor models.

Purinergic regulation of sound transduction and auditory neurotransmission.

In the cochlea, extracellular ATP influences the endocochlear potential, micromechanics, and neurotransmission via P2 receptors. Evidence for this arises from studies demonstrating widespread expression of ATP-gated ion channels (assembled from P2X receptor subunits) and G protein-coupled receptors (P2Y receptors). P2X2 receptor subunits are localized to the luminal membranes of epithelial cells and hair cells lining scala media. These ion channels provide a shunt pathway for K+ ion egress. Thus, when noise exposure elevates ATP levels in this cochlear compartment, the K+ conductance through P2X receptors reduces the endocochlear potential. ATP-mediated K+ efflux from scala media is complemented by a P2Y receptor G protein-coupled pathway that provides coincident reduction of K+ transport into scala media from the stria vascularis when autocrine or paracrine ATP signalling is invoked. This purinergic signalling likely provides a basis for a reactive homoeostatic regulatory mechanism limiting cochlear sensitivity under stressor conditions. Elevation of ATP in the perilymphatic compartment under such conditions is also likely to invoke purinergic receptor-mediated changes in supporting cell micromechanics, mediated by Ca2+ influx and gating of Ca2+ stores. Independent of these humoral actions, ATP can be classified as a putative auditory neurotransmitter based on the localization of P2X receptors at the spiral ganglion neuron-hair cell synapse, and functional verification of ATP-gated currents in spiral ganglion neurons in situ. Expression of P2X receptors by type II spiral ganglion neurons supports a role for ATP as a transmitter encoding the dynamic state of the cochlear amplifier.

P2X2 receptor expression by interstitial cells of Cajal in vas deferens implicated in semen emission.

Male reproduction is dependent upon seminal emission mediated by vas deferens contraction. This drives spermatic fluid to the prostatic urethra during ejaculation. We localize interstitial cells of Cajal (ICC), which express P2X2 receptor, subunits of ATP-gated ion channels, to rat, mouse and guinea-pig vas deferens submucosa. Reverse transcription-polymerase chain reaction (RT-PCR) analysis of rat vas deferens resolved two functional splice variant transcripts of the P2X2 receptor subunit. The P2X2 receptor mRNA was localized principally within the lamina propria (submucosal) region of the rat vas deferens using in situ hybridization (ISH) and in situ RT-PCR-ISH. Immunohistochemistry using rat, mouse and guinea-pig vas deferens tissues confirmed expression of P2X2 receptor protein within the lamina propria, particularly within a dense column of small spindle-shaped cells adjacent to the columnar epithelial cells which line the lumen. This immunoreactivity was co-localized with neurone-specific enolase (NSE) and c-Kit protein expression, gene markers for ICC. Mucosal mast cells were distinguished from ICC by toluidine blue staining. Choline acetyltransferase immunoreactivity, a marker for post-ganglionic parasympathetic innervation, occurred on the lateral margin of the lamina propria and extended into the inner longitudinal muscle layer. P2X1 receptor immunolabelling was associated with sympathetic innervation of the smooth muscle in the outer longitudinal and circular muscle layers, but not the inner longitudinal layer. The physiological significance of the vas deferens ICC which express P2X2 receptors remains to be established. Possible roles include regulation of smooth muscle activity or mucosal secretion utilizing local ATP signaling, both of which would affect semen transport.

ATP-gated ion channel expression in primary auditory neurones.

Extracellular ATP acts via ionotropic P2X receptors to mediate fast neurotransmission in the central and autonomic nervous systems. Recent data, including identification of P2X2 receptor mRNA expression by spiral ganglion neurones, suggests that purinergic signalling may influence auditory neurotransmission via ATP-gated ion channels assembled from these subunits. Expression of the P2X2 receptor was localized to the region of the spiral ganglion neurone synapses with the inner hair cells using a P2X2 receptor specific antiserum. Whole-cell patch clamping of neurones cultured from post-natal day 3-5 spiral ganglia demonstrated a heterogeneity of ATP-activated conductances, consistent with the functional expression of P2X2 receptor subunit isoforms along with possible co-expression of additional P2X receptor subunits. These data provide substantive support for a purinergic transmission element at the peripheral auditory synapse.

Expression of the P2X(2) receptor subunit of the ATP-gated ion channel in the cochlea: implications for sound transduction and auditory neurotransmission.

Extracellular ATP has multimodal actions in the cochlea affecting hearing sensitivity. ATP-gated ion channels involved in this process were characterized in the guinea pig cochlea. Voltage-clamped hair cells exhibited a P2 receptor pharmacology compatible with the assembly of ATP-gated ion channels from P2X(2) receptor subunits. Reverse transcription-PCR experiments confirmed expression of the P2X(2-1) receptor subunit mRNA isoform in the sensory epithelium (organ of Corti); a splice variant that confers desensitization, P2X(2-2), was the predominant subunit isoform expressed by primary auditory neurons. Expression of the ATP-gated ion channel protein was localized using a P2X(2) receptor subunit-specific antiserum. The highest density of P2X(2) subunit-like immunoreactivity in the cochlea occurred on the hair cell stereocilia, which faces the endolymph. Tissues lining this compartment exhibited significant P2X(2) receptor subunit expression, with the exception of the stria vascularis. Expression of ATP-gated ion channels at these sites provides a pathway for the observed ATP-induced reduction in endocochlear potential and likely serves a protective role, decoupling the "cochlear amplifier" in response to stressors, such as noise and ischemia. Within the perilymphatic compartment, immunolabeling on Deiters' cells is compatible with purinergic modulation of cochlear micromechanics. P2X(2) receptor subunit expression was also detected in spiral ganglion primary afferent neurons, and immunoelectron microscopy localized these subunits to postsynaptic junctions at both inner and outer hair cells. The former supports a cotransmitter role for ATP in a subset of type I spiral ganglion neurons, and latter represents the first characterization of a receptor for a fast neurotransmitter associated with the type II spiral ganglion neurons.

Expression of ATP-gated ion channels by Reissner's membrane epithelial cells.

Reissner's membrane forms a partition between the endolymphatic and perilymphatic cochlear compartments. Expression of the P2X2 receptor subunit which assembles to form ATP-gated ion channels was detected in guinea-pig Reissner's membrane using the reverse transcription polymerase chain reaction (RT-PCR). The P2X2 receptor subunit protein was localized to the epithelial cells which line the endolymphatic surface of Reissner's membrane using confocal immunofluorescence. The P2X receptor expression in Reissner's membrane was functionally confirmed using whole-cell voltage-clamp. An inwardly rectifying conductance was activated in Reissner's membrane epithelial cells in the presence of extracellular ATP (100 microM). This conductance had a pharmacological profile compatible with the P2X2 receptor designation, but exhibited substantial desensitisation which may be attributable to additional P2X receptor subunits. This study indicates that extracellular ATP, a humoral factor within scala media, acts via ATP-gated ion channels expressed by Reissner's membrane epithelial cells to decrease the driving force for sound transduction.

P2X2 receptor subunit expression in a subpopulation of cochlear type I spiral ganglion neurones.

Spiral ganglion neurones in rat cochlea express three different isoforms of the P2X2 receptor subunit which assemble into ATP-gated ion channels. Two of these P2X2R subunit isoforms have previously been detected in other auditory tissues. The third isoform (designated P2X2-3R) has not been described. This isoform lacks 39 bp immediately prior to the stop codon, corresponding to a 13 amino acid deletion of the extreme C-terminus domain. Using direct in situ RT-PCR, expression of P2X2R mRNA was confined to a subpopulation of type I spiral ganglion neurones. This study supports a role for extracellular ATP as a neurotransmitter for a discrete population of auditory neurones where variation in P2X2R isoform assembly may confer functional heterogeneity, including enhanced desensitization.

Extraction, purification, identification and metabolism of 3',5'-cyclic UMP, 3',5'-cyclic IMP and 3',5'-cyclic dTMP from rat tissues.

The large-scale extraction and partial purification of endogenous 3',5'-cyclic UMP, 3',5'-cyclic IMP and 3',5'-cyclic dTMP are described. Rat liver, kidney, heart, spleen and lung tissues were subjected to a sequential purification procedure involving freeze-clamping, perchlorate extraction, alumina and Sephadex ion-exchange chromatography and preparative electrophoresis. The samples thus obtained co-chromatographed with authentic cyclic UMP, cyclic IMP and cyclic dTMP on t.l.c. and h.p.l.c. and the u.v. spectra of the extracted samples were identical with those of the standards. Fast atom bombardment of the three cyclic nucleotide standards yielded mass spectra containing a molecular protonated ion in each case; mass-analysed ion kinetic-energy spectrometry ('m.i.k.e.s') of these ions produced a spectrum unique to the parent cyclic nucleotide. The extracted putative cyclic UMP, cyclic IMP and cyclic dTMP each produced a m.i.k.e.s. identical with that obtained with the corresponding cyclic nucleotide standard. Rat liver, heart, kidney, brain, intestine, spleen, testis and lung protein preparations were each found capable of the synthesis of cyclic UMP, cyclic IMP and cyclic dTMP from the corresponding nucleoside triphosphate, of the hydrolysis of these cyclic nucleotides and of their binding, with the exception that cyclic dTMP was not synthesized by the kidney preparation.

Cyclic CMP phosphodiesterase: isolation, specificity and kinetic properties.

Cyclic CMP phosphodiesterase activity was demonstrated in rat liver, heart, brain, kidney, intestine, skeletal muscle, blood, testes, ovaries, spleen and lung; that present in the liver was purified to homogeneity by a sequential process of ammonium sulphate fractionation, gel filtration, two ion-exchange chromatographic steps, preparative electrophoresis and two affinity chromatographic stages with selection at each stage for maximum specificity. The final enzyme preparation was confirmed as a single protein by HPLC and isoelectric focussing; the total yield obtained was 1.5% and the final specific activity of 48.6 mumol cyclic CMP hydrolysed/min/mg reflected a 88,000 fold purification. The phosphodiesterase had a Mr of 2.8 X 10(4), pH optimum 7.2-7.4, isoelectric point between 4.2 and 4.4 and a Km of 9.0 mM cyclic CMP. This enzyme differs from a previously isolated cyclic CMP phosphodiesterase in its amino acid composition and specificity. The absolute specificity for 3',5'-cyclic CMP as substrate distinguishes this cyclic CMP phosphodiesterase from all other reported phosphodiesterases and shows it to be a novel enzyme. Its potential as a research tool and the significance of its occurrence are discussed.

Extraction, purification and identification of cytidine 3',5'-cyclic monophosphate from rat tissues.

The large-scale extraction and purification to homogeneity of cyclic CMP and its unequivocal identification are described. Rat liver, kidney, heart, spleen and lung tissues were subjected to a sequential purification procedure involving freeze-clamping, perchlorate extraction, alumina and boronate column chromatography, polyacrylamide-gel column electrophoresis and high-voltage paper electrophoresis. The purified sample co-chromatographed with authentic cyclic CMP on t.l.c. and high-pressure liquid chromatography and was positive in a cyclic CMP radio-immunoassay. The u.v., i.r. and p.m.r. spectra were each essentially identical with those of authentic cyclic CMP. Fast-atom bombardment of authentic cyclic CMP yielded a mass spectrum containing a molecular protonated ion: mass-ion-kinetic-energy scanning of this ion produced a spectrum unique to 3',5'-cyclic CMP. The extracted nucleotide produced an identical mass-ion-kinetic-energy spectrum.