Serological survey for antibodies against bovine viral diarrhoea virus and Neospora caninum in a population of South Australian alpacas (Vicugna pacos).

OBJECTIVE: Bovine viral diarrhoea virus (BVDV) and Neospora caninum may cause clinical disease in alpacas. Both diseases are present in the Australian cattle population. The objective of this study was to perform a serological prevalence survey for BVDV and N. caninum exposure in a regional alpaca population of South Australia. METHODS: Serum samples were taken from 182 alpacas on 10 farms, which had a combined population of 1308 alpacas. Serological analysis for BVD antibodies was performed using a competitive BVDV antibody ELISA kit. Serological analysis for N. caninum was performed using an anti-Neospora ELISA with a protein G conjugate. RESULTS: Of the 182 alpacas sampled, 5 animals located on three properties were positive for BVDV antibodies, constituting a prevalence of 2.7% (95% confidence interval 1-6%). All samples tested negative for N. caninum antibodies. CONCLUSION: There is a low BVDV seroprevalence and N. caninum is currently either absent or present at a very low prevalence in this population of alpacas in South Australia. There is serological evidence for the presence of both organisms in South Australian beef and dairy cattle herds. Appropriate biosecurity protocols to minimise the risk of introduction and exposure should be a high priority to maintain this favourable status.

Minimal alterations in T-type calcium channel gating markedly modify physiological firing dynamics.

T-type calcium channel isoforms expressed in heterologous systems demonstrate marked differences in the biophysical properties of the resulting calcium currents. Such heterogeneity in gating behaviour not only reflects structural differences but is also observed following the regulation of channel activity by a number of ligands. However, the physiological impact of these differences in gating parameters of the T channels has never been evaluated in situ where the unique interplay between T-type calcium and other intrinsic currents is conserved, and T channel activation can be triggered by synaptic stimulation. Here, using the dynamic clamp technique, artificial T conductances were re-incorporated in thalamic neurons devoid of endogenous T currents to dissect the physiological role of the T current gating diversity on neuronal excitability. We demonstrate that the specific kinetics of the T currents in thalamocortical and nucleus reticularis thalami neurons determine the characteristic firing patterns of these neurons. We show that subtle modifications in T channel gating that are at the limit of the resolution achieved in classical biophysical studies in heterologous expression systems have profound consequences for synaptically evoked firing dynamics in native neurons. Moreover, we demonstrate that the biophysical properties of the T current in the voltage region corresponding to the foot of the activation and inactivation curves drastically condition physiologically evoked burst firing with a high degree of synaptic input specificity.

Modulation of neuronal T-type calcium channels.

As T-type calcium channels open near resting membrane potential and markedly influence neuronal excitability their activity needs to be tightly regulated. Few neuronal T-current regulations have been described so far, but interestingly some of them involve unusual mechanisms like G protein-independent but receptor-coupled modulation, while the use of recombinant channels has established both a direct action of Gbetagamma subunits, anandamide, arachidonic acid and a phosphorylation process by CaMKII. Nearly all reported types of modulation involve Cav3.2 channels while no regulation of Cav3.1 has been reported, a difference that may originate from diversities in the intracellular loop connecting the II and III domains of the two isotypes. The search for T-current regulators requires taking into account their peculiar activation properties, since a close link may exist between the channel conformation and its modulation. Indeed, in thalamocortical neurons a phosphorylation-mediated regulation of the amplitude of the T-current has been shown to be highly dependent upon the state of the channel and only to become apparent when the channels are in the voltage range close to neuronal resting membrane potential.

Distinct kinetics of cloned T-type Ca2 + channels lead to differential Ca2 + entry and frequency-dependence during mock action potentials.

Voltage-dependent activity around the resting potential is determinant in neuronal physiology and participates in the definition of the firing pattern. Low-voltage-activated T-type Ca2 + channels directly affect the membrane potential and control a number of secondary Ca2 + -dependent permeabilities. We have studied the ability of the cloned T-type channels (alpha1G,H,I) to carry Ca2 + currents in response to mock action potentials. The relationship between the spike duration and the current amplitude is specific for each of the T-type channels, reflecting their individual kinetic properties. Typically the charge transfer increases with spike broadening, but the total Ca2 + entry saturates at different spike durations according to the channel type: 4 ms for alpha1G; 7 ms for alpha1H; and > 10 ms for alpha1I channels. During bursts, currents are inhibited and/or transiently potentiated according to the alpha1 channel type, with larger effects at higher frequency. The inhibition may be induced by voltage-independent transitions toward inactivated states and/or channel inactivation through intermediate closed states. The potentiation is explained by an acceleration in the channel activation kinetics. Relatively fast inactivation and slow recovery limit the ability of alpha1G and alpha1H channels to respond to high frequency stimulation ( > 20 Hz). In contrast, the slow inactivation of alpha1I subunits allows these channels to continue participating in high frequency bursts (100 Hz). The biophysical properties of alpha1G, H and I channels will therefore dramatically modulate the effect of neuronal activities on Ca2 + signalling.

Expression and targeting to the plasma membrane of xClC-K, a chloride channel specifically expressed in distinct tubule segments of Xenopus laevis kidney.

ClC-K channels are Cl- channels specifically expressed in vertebrate kidneys. Although their heterologous functional expression is still controversial, indirect evidence points to them as major factors involved in Cl- reabsorption in the nephron. We cloned xClC-K, an amphibian (Xenopus) homologue of mammalian ClC-K. The cDNA encodes a 77 kDa protein presenting 62% similarity with human ClC-Kb. The protein is monoglycosylated and is expressed primarily in the Xenopus kidney. It is localized in the basolateral membranes of proximal convoluted tubules of the nephron and in the apical region of the diluting segments. Heterologous expression of xClC-K in HEK-293 cells showed that the full-length protein is glycosylated and targeted to the cell membrane, but no associated Cl- current could be observed with the patch-clamp recording technique. N-glycosylation of both the native kidney channel and the recombinant protein expressed in HEK-293 conferred on them anomalous behaviour in denaturing PAGE, which is indicative of strong interactions at the extracellular side of the plasma membrane. The expression of ClC-K channels in both mesonephric and metanephric kidneys will permit further comparative physiological studies of Cl- permeabilities at the molecular level.

Low-voltage-activated Ca2+ currents are generated by members of the CavT subunit family (alpha1G/H) in rat primary sensory neurons.

Recently, two members of a new family of Ca2+ channel alpha1 subunits, alpha1G (or CavT.1) and alpha1H (or CavT.2), have been cloned and expressed. These alpha1 subunits generate Ba2+ currents similar to the T-type Ca2+ currents present in sensory neurons. Here, we use three methods to investigate whether the T currents of nodosus ganglion neurons are encoded by members of the CavT family. PCR detected the presence of mRNA encoding both alpha1G and alpha1H, as well as a third highly related sequence, alpha1I. In situ hybridizations performed on nodosus ganglia demonstrate a high expression of alpha1H subunit RNAs. Transfection of nodosus ganglion neurons with a generic antisense oligonucleotide against this new alpha1 subunit family selectively suppresses the low-voltage-activated Ca2+ current. The antisense oligonucleotide effect increased with time after transfection and reached a maximum 3 d after treatment, indicating a 2-3 d turnover for the alpha1 proteins. Taken together, these results suggest that the T-type current present in the sensory neurons is mainly attributable to alpha1H channels. In addition, taking advantage of the high specificity of the antisense ON to the cloned channels, we showed that T-type currents greatly slowed the repolarization occurring during an action potential and were responsible for up to 51% of the Ca2+ entry during spikes. Therefore, the antisense strategy clearly demonstrates the role of low-voltage-activated Ca2+ current in affecting the afterpotential properties and influencing the cell excitability. Such tools should be beneficial to further studies investigating physiological roles of T-type Ca2+ currents.

Identifying neuronal non-L Ca2+ channels--more than stamp collecting?

The pharmacology of the majority of Ca2+ channels in the nervous system is very limited. Although attempts have been made to constrain native Ca2+ channels into the framework provided by the six pore-forming molecules cloned to date, refined biophysical analysis of Ca2+ currents, expression techniques and the use of selective toxins have helped to identify unambiguously only a limited number of Ca2+ channels. In fact, many native Ca2+ channel activities remain as 'orphans', waiting for their molecular counterparts to be defined. In this article, Janet Nooney, Régis Lambert and Anne Feltz systematically delineate the well characterized non-L Ca2+ channel activities and the missing elements in our knowledge of the Ca2+ channel family.

T-type Ca2+ current properties are not modified by Ca2+ channel beta subunit depletion in nodosus ganglion neurons.

At the molecular level, our knowledge of the low voltage-activated Ca2+ channel (T-type) has made little progress. Using an antisense strategy, we investigated the possibility that the T-type channels have a structure similar to high voltage-activated Ca2+ channels. It is assumed that high voltage-activated channels are made of at least three components: a pore forming alpha1 subunit combined with a cytoplasmic modulatory beta subunit and a primarily extracellular alpha2delta subunit. We have examined the effect of transfecting cranial primary sensory neurons with generic anti-beta antisense oligonucleotides. We show that in this cell type, blocking expression of all known beta gene products does not affect T-type current, although it greatly decreases the current amplitude of high voltage-activated channels and modifies their voltage dependence. This suggests that beta subunits are likely not constitutive of T-type Ca2+ channels in this cell type.

Voltage-dependent Na(+)-HCO3- cotransporter and Na+/H+ exchanger are involved in intracellular pH regulation of cultured mature rat cerebellar oligodendrocytes.

Intracellular pH (pHi) was measured at 37 degrees C in mature rat cerebellar oligodendrocytes dissociated in culture by using the pH-sensitive probe BCECF. Cells were identified by anti-galactocerebroside antibody. The mean steady-state pHi was 7.02 in the absence of CO2/bicarbonate (Hepes-buffered solution) at an external pH of 7.40 and 7.04 in 5% CO2/25 mM bicarbonate-buffered solution at the same external pH; this value was modified neither by the removal of external chloride nor by the addition of the chloride-coupled transport blocker DIDS. In both external solutions steady-state pHi values were strongly dependent on external pH. In Hepes-buffered solution pHi recovery following an acid load required external Na+ and was completely inhibited by amiloride, indicating the presence of a Na+/H+ exchanger. In CO2/bicarbonate-buffered solution amiloride partially reduced the pHi recovery rate, indicating the presence of a bicarbonate-dependent pHi regulating mechanism. Membrane depolarization induced by increasing external K+ concentration elicited an alkalinization only in the presence of external Na+ and bicarbonate. Analysis of the calculated HCO3- fluxes with respect to membrane potential indicated that these fluxes were mediated by a Na(+)-HCO3- cotransport with a stoichiometry of 1:3. These results demonstrate that a Na+/H+ exchanger and a Na(+)-HCO3- cotransporter are involved in pHi regulation of mature oligodendrocytes.

Polyethylenimine-mediated DNA transfection of peripheral and central neurons in primary culture: probing Ca2+ channel structure and function with antisense oligonucleotides.

To study neuronal ion channel function with antisense oligonucleotides, a reliable method is needed which allows different neuronal cell types to be transfected without artifactual disruptive effects on their electrical properties. Here we report that use of the recently introduced transfecting agent, polyethylenimine, fulfills this requirement. Four days after transfection, in both central and peripheral neurons, an antisense designed to block the synthesis of the Ca2+ channel beta subunits induced a maximal decrease of the Ca2- current amplitude and modification of their kinetics and voltage-dependence. Controls with scrambled oligonucleotides, as well as Na+ current recordings of antisense transfected neurons, confirm both that the transfecting agent does not modify the electrophysiological properties of the neurons and that the effect of the antisense is sequence specific.

Maintained L-type Ca2+ channel activity in excised patches of PTX-treated granule cells of the cerebellum.

Activity of high-threshold voltage activated neuronal Ca2+ channels, including dihydropyridine-sensitive (L-type) channels, rapidly disappears during cell dialysis in whole-cell recording conditions or after excision of a patch. To date, this phenomenom has been mainly related to phosphatase or protease activity. On the other hand, it has been suggested that Ca2+ channels may be regulated by G-proteins. Therefore, disruption of this regulatory pathway may also be involved directly or indirectly in the rundown process. Here, we show that treatment of cultured cerebellar granule cells with pertussis toxin (PTX) increases to 70% the probability for excising patches that display L-type Ca2+ channels activity in the inside-out recording configuration. Quantitative study indicates that, except a half decrease in the open probability, most features of the channel activity are retained after patch excision with minor modifications. The characteristics of the channel activity did not change with time during at least the first 9 min of the inside-out configuration. In addition, comparison of unitary currents recorded in the cell-attached, configuration on treated and nontreated cells demonstrates that the PTX treatment slows the activation kinetics of the current and increases the duration of channel openings evoked at -20 mV but not at 0 mV depolarizing potential. These data suggest that L-type Ca2+ channel activity are under a tonic regulation of a PTX-sensitive mechanism, which is implied in the run-down process.

Mortyn Jones Memorial Lecture. Limbic regions mediating central actions of oxytocin on the milk-ejection reflex in the rat.

Central oxytocin administration has a profound facilitatory effect on the patterning of the milk-ejection reflex in the lactating rat. Lesion and microinjection studies indicate that this action is, in part, mediated via a population of limbic neurones in the bed nuclei of the stria terminalis and ventrolateral septum, which have been shown to possess oxytocin receptors and to be activated by selective oxytocin-receptor agonists in vitro. In vivo electrophysiological recordings reveal that some of these neurones display cyclical activity which is highly correlated to each milk ejection, and are rapidly activated following i.c.v. administration of oxytocin, coincident with the facilitation of milk ejection activity. A hypothetical model is proposed in which this population of limbic neurones serves to gate the activity of a pacemaker which, in turn, coordinates the bursting of hypothalamic magnocellular neurones. The oxytocin innervation of these neurones and their expression of oxytocin receptors increases in the postpartum period, and the resultant enhanced sensitivity leads to a greater facilitatory response during lactation. Inhibitory opioid and noradrenergic inputs which converge on these oxytocin-sensitive neurones may function to switch off the facilitatory circuit during periods of stress. Thus, this population of limbic neurones participates in the regulation of neuroendocrine activity during lactation by providing an appropriate degree of feedback to alter the patterning of the milk-ejection reflex.

A rise in the intracellular Ca2+ concentration of isolated rat supraoptic cells in response to oxytocin.

1. Intracellular Ca2+ concentration ([Ca2+]i) was monitored in single cells isolated from adult rat supraoptic (SO) nuclei. The great majority of cells (85%) were neurones and most were immunoreactive to oxytocin or to vasopressin (AVP). 2. The resting [Ca2+]i of the majority (80%) of the neurones remained stable while 20% of the neurones displayed spontaneous [Ca2+]i oscillations which disappeared in low-Ca2+ (100 nM) EGTA buffer. 3. Addition of 100 nM oxytocin increased the [Ca2+]i in both stable and oscillating cells. Two types of responses were observed: (i) a sustained response with [Ca2+]i being maintained at an elevated level and (ii) a brief response with [Ca2+]i quickly returning to a near-resting level. Responses were reproducible, dose dependent and blocked with a specific oxytocin antagonist. 4. Removal of extracellular Ca2+ did not block the oxytocin response. In EGTA buffer, application of thapsigargin (200 nM) onto oxytocin-sensitive cells induced an increase in [Ca2+]i and inhibited the oxytocin response. These effects were not induced by other intracellular Ca2+ mobilizers such as tBuBHQ (see Methods) or caffeine. 5. In conclusion, half of the SO cells respond to oxytocin with a rise in [Ca2+]i. The effect is mediated by oxytocin receptors and results from release of Ca2+ from thapsigargin-sensitive stores.

Action of endogenous oxytocin within the paraventricular or supraoptic nuclei: a powerful link in the regulation of the bursting pattern of oxytocin neurons during the milk-ejection reflex in rats.

During suckling, the periodic and synchronous bursting activity of oxytocin neurons has been shown to be facilitated by oxytocin itself, acting via several target sites, including the magnocellular nuclei. To investigate the role of the endogenous oxytocin released within the magnocellular nuclei during the milk-ejection reflex in the rat, an oxytocin antagonist (50 microM solution of [d(CH2)5, Tyr(Me)2,Orn8]-vasotocin was pressure-injected into either one paraventricular or one supraoptic nucleus while recording the bursting pattern of oxytocin neurons within the injected nucleus and within a contralateral nucleus. The oxytocin antagonist was injected either during an ongoing milk-ejection reflex or during its facilitation induced by oxytocin (1 microliter of 1 microM solution injected into the third ventricle, i.e. 1 ng). During an ongoing milk-ejection reflex, injections of the oxytocin antagonist (10 nl of 50 microM solution, i.e. 50 ng) into the paraventricular or supraoptic nucleus decreased (more than 20% change) the burst amplitude (total number of spikes/burst) of neurons within the injected nucleus in 100% of tests, and simultaneously of contralateral neurons in 68% of tests. Burst periodicity of the entire population was also decreased in 50% of tests whatever the nucleus injected, but burst desynchronization was never observed. Successive injections of minute volumes of oxytocin (10 nl of 10 microM solution, i.e. 0.1 ng) into the paraventricular or supraoptic nucleus (which will progressively affect a greater number of neurons) first increased burst amplitude of oxytocin neurons within the injected nucleus and then increased simultaneously burst amplitude of contralateral neurons and burst frequency of the whole oxytocin neuron population. All these results suggest that the recruitment of a critical number of oxytocin neurons within one nucleus induces changes in the bursting activity of the oxytocin neurons in the four magnocellular nuclei. Within the minute following an intracerebroventricular oxytocin injection, the oxytocin antagonist injected into the supraoptic nucleus not only prevented the oxytocin-induced facilitation but also completely interrupted the milk-ejection reflex. When injected into the paraventricular nucleus, the oxytocin antagonist was less efficient: it decreased the oxytocin-induced facilitation but the reflex was not blocked. Similar partial inhibitory effect (decrease in burst amplitude and burst frequency) was also observed when the oxytocin antagonist was injected into the supraoptic nucleus after facilitation of the milk-ejection reflex by intracerebroventricular oxytocin injection. In conclusion, endogenous oxytocin released within the magnocellular nuclei during suckling represents a necessary link of the neuronal network regulating the bursting activity of oxytocin neurons.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrical activity of neurons in the ventrolateral septum and bed nuclei of the stria terminalis in suckled rats: statistical analysis gives evidence for sensitivity to oxytocin and for relation to the milk-ejection reflex.

Our previous results obtained by lesioning or stimulating the ventrolateral part of the lateral septum and the bed nuclei of the stria terminalis suggested that this area is involved in the control of milk ejection pattern in rats. The present study was undertaken with the aim of testing ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons as a putative link of the neuronal network controlling the bursting activity of oxytocin neurons in suckled lactating rats (anaesthetized with urethane). Ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons were recorded simultaneously with hypothalamic oxytocin neurons in either the paraventricular or supraoptic nucleus in rats with (n = 26) or without (n = 29) periodic milk ejections. Analysis of their firing pattern enabled differentiation of two subgroups: type I, characterized by numerous high frequency spikes, often grouped in clusters; and type II with very few or no high frequency clusters of spikes. The probability density function of the interspike intervals of both patterns could be modelled using a mixture of two log-normal distributions, the parameters of which differed significantly. The presence of absence of milk ejections did not influence the overall mean level of activity (2.0 +/- 0.5 and 1.9 +/- 0.4 spikes/s, respectively). However, the characteristics of the type I firing pattern were affected by the presence of the milk-ejection reflex. The average level of activity was not always constant and 16/55 ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons displayed cyclical activity (from 0.6 +/- 0.2 to 4.0 +/- 0.5 spikes/s) both in the presence (n = 8) and absence (n = 8) of the milk-ejection reflex. In five of eight neurons recorded during milk-ejection reflex, the cycles in firing were clearly correlated with the bursting of oxytocin neurons. These five neurons exhibited the type I firing pattern. The three remaining neurons and the eight neurons recorded in the absence of milk-ejection reflex displayed the type II firing pattern. Oxytocin (1-2 ng = 0.45-0.9 mU) was injected into the third ventricle (i.c.v.) in order to examine the possible involvement of ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons in the facilitatory effect of oxytocin on the reflex.(ABSTRACT TRUNCATED AT 400 WORDS)