Functional glycine receptor maturation in the absence of glycinergic input in dopaminergic neurones of the rat substantia nigra

The postnatal maturation pattern of glycine receptor channels (GlyRs) expressed by dopaminergic (DA) neurones of the rat substantia nigra pars compacta (SNc) was investigated using single-channel and whole-cell patch-clamp recordings in brain slices from rats aged 7-21 postnatal days (P). In neonatal rats (P7-P10), GlyRs exhibited a main conductance state of 100-110 pS with a mean open time of 16 ms. In juvenile rats (P19-P22), both the GlyR main conductance state (46-55 pS) and the mean open time (6.8 ms) were decreased. In neonatal rats, application of 30 microM picrotoxin, which is known to block homomeric GlyRs, strongly reduced glycine-evoked responses, while it was much less effective in juvenile rats. These results suggest that these GlyRs correspond functionally to alpha(2) homomeric GlyRs in neonatal rats and alpha(1)/beta heteromeric GlyRs in juvenile rats. A drastic but transient decrease in the glycine responsiveness of DA neurones occurred around P17 concomitant to the functional switch from the homomeric state to the heteromeric state. This age corresponds to a maturation phase for DA neurones. The application of 1 microM gabazine blocked spontaneous or evoked inhibitory synaptic current, while the addition of 1 microM strychnine had no effect, suggesting a lack of functional glycinergic synapses on DA neurones. Although it has been proposed that taurine is co-released with GABA at GABAergic synapses on DA neurones, in the present study the stimulation of GABAergic fibres failed to activate GlyRs. Blockade of taurine transporters and applications of high K(+) and hyposmotic solutions were also unable to induce any strychnine-sensitive current. We conclude that functional maturation of GlyRs can occur in the absence of any detectable GlyR activation in DA neurones of the SNc.

Neuromuscular transmission on the rebound

Recent work at the zebrafish neuromuscular junction (NMJ) has shown that positively charged acetylcholine (ACh), at the high concentrations reached in the cleft during neuromuscular transmission, blocks acetylcholine receptors (AChRs) as soon as they open. Thus after two ACh molecules bind and open the channel, a third molecule enters and blocks the pore at a site resembling that for block by local anesthetics, suggesting that ACh is the endogenous anesthetic of the NMJ. Recovery from open channel block results in a rebound synaptic current only after ACh is cleared from the cleft. Kinetic modeling of other AChRs suggests that a rebound current is generated at all vertebrate NMJs, from fish to frogs to mammals. Open channel block prolongs the current at fast zebrafish NMJs in order to more effectively spread charge along the fibers, akin to multiple central synapses spread over dendrites. Together these findings indicate the need for a fundamental revision of current thinking about neuromuscular transmission at many levels, including channel structure, function and pharmacology.

von Willebrand factor binding to heparin in various types of von Willebrand disease

INTRODUCTION

The purpose was to study von Willebrand factor (vWF) binding to heparin in different types of von Willebrand disease (vWD).

MATERIALS AND METHODS

Plasma samples from 92 patients were representative of most vWD subtypes as they included 13 type 1, ten type 2N, 27 type 2A, 23 type 2B, and 19 type 2M patients. We selected assay conditions suitable for the screening of plasma vWF concentrations as low as 15 U/dl vWF:Ag. We determined the range of vWF concentrations in plasma where the percentage of (125)I-MAb/vWF complexes bound to heparin-agarose beads was constant. This range of dilution allowed circumvention of potential competition by other plasma heparin-binding proteins.

RESULTS

The multimeric composition of vWF had hardly any influence on the ability of vWF to bind to heparin. Results were expressed as the ratio of heparin-binding capacity of patients' plasma to that of normal pool plasma. We found a ratio of 0.99+/-0.004 (mean+/-s.e.m.) for 23 normal individual donors. Furthermore, when comparing the mean values of plasma vWF-heparin binding ratios by ANOVA F-test in the six groups (one normal and five vWD), we found significant differences between them (P<0.0001). Pairwise comparison of multiples by the Scheffe's test indicated that the mean values of ratios in type 2A on the one hand and type 2M on the other, were significantly lower than in normal plasma, type 2N, type 2B and type 1.

CONCLUSION

Our data suggest a relationship between the ability of vWF to bind to heparin and to the platelet GPIb receptor, since type 2B and 2N patients have an increased or normal ability to bind to GPIb whereas type 2A and 2M patients have an impaired interaction with that receptor.

Defect of heparin binding in plasma and recombinant von Willebrand factor with type 2 von Willebrand disease mutations

The aim of our study was to characterise heparin-binding properties of mutated von Willebrand factor (VWF) in 24 patients plasmas with type 2 von Willebrand disease (VWD). and in 15 recombinant VWF (rVWF) with the corresponding mutations. Binding of mutated rVWF or plasma VWF was compared to that of WT-rVWF or normal pool plasma VWF. Four mutations, at positions C509, V551, R552 and R611 lead to significantly decreased binding to heparin in both plasma and rVWF. Interestingly, whereas these four residues are distant in the primary structure of VWF-A1domain, they are close to each other in its three-dimensional structure. Structural analysis suggested how folding problems and destabilisation due to these mutations could induce reorganisation of surface regions involved in heparin binding. In contrast, no heparin-binding defect was found associated with different type 2 VWF mutants, at positions G561, E596, I662, R543, R545, V553, R578 or L697.

Limits to the development of fast neuromuscular transmission in zebrafish

Zebrafish embryos have small and slow miniature end-plate currents (mEPCs), whereas only a few days later larval mEPCs are an order of magnitude larger and faster, being among the fastest of all neuromuscular synapses. To identify the bases for these changes we compared, in embryos and larvae, the properties and distributions of acetylcholine (ACh) receptors (AChRs) and acetylcholinesterase (AChE) as well as the ultrastructure of the developing neuromuscular junctions (NMJs). To mimic synaptic release, patches of muscle membrane were exposed briefly (for 1 ms) to a saturating concentration (10 mM) of ACh. The AChR deactivation kinetics were twice as slow in embryos compared with larvae. In both embryos and larvae, AChRs demonstrated open channel block by millimolar ACh, and this was detected during mEPCs, indicating that a high concentration of ACh is released at immature and mature NMJs. AChR and AChE distributions were compared using the selective fluorescently conjugated labels alpha-bungarotoxin and fasciculin 2, respectively. In larvae, punctate AChR clusters were detected whereas junctional AChE staining was less intense than that found at adult NMJs. Transmission electron microscopy revealed immature nerve endings in embryos that were closely juxtaposed to the surrounding muscle cells, whereas mature larval NMJs had a wider synaptic cleft with a conspicuous basal lamina over a limited region of synaptic contact. Our results indicate that ACh is released at high concentrations at immature NMJs, but its clearance is prolonged and the AChRs are dispersed, resulting in a slow mEPC time course until a mature cleft appears with densely packed faster AChRs and abundant AChE.

Clinical and laboratory findings of cytomegalovirus infection in 115 hospitalized non-immunocompromised adults

We report a retrospective study of 115 hospitalized non-immunocompromised adults with proved or presumed diagnosis of cytomegalovirus infection. Clinical symptoms were fever (95%), constitutive symptoms (80%), joint and muscle pain (41%), shivering (32%), abdominal pain (26%), non-productive cough (20%), cutaneous eruption (20%), and diarrhea (10%). Examination found hepatomegaly (25%), splenomegaly (23%), cutaneous rash (20%), adenopathy (19%), pharyngitis (9%), jaundice (3%) or signs of meningeal irritation (1%). Seventeen patients had a gastrointestinal form (hepatitis, jaundice, colitis, antral gastritis or cholecystitis), eight had a pattern of hemopathy, two interstitial pneumonitis, two pericarditis, two immune thrombocytopenic purpura, two a polymyalgia rheumatica-like pattern, one thrombotic thrombocytopenic purpura, one cutaneous vasculitis and one meningoencephalitis. Sixty-four percent of the patients had atypical lymphocytosis. Hepatocellular injury occurred in 90% of the patients. Nineteen of the patients had biological immune abnormalities. Cytomegalovirus infection should be mainly suspected in any patient with persistent fever, isolated or associated with signs of poor specificity, or in some patients with visceral manifestations of initially unknown origin.

The glycinergic inhibitory synapse

Glycine is one of the most important inhibitory neurotransmitters in the spinal cord and the brainstem, and glycinergic synapses have a well-established role in the regulation of locomotor behavior. Research over the last 15 years has yielded new insights on glycine neurotransmission. Glycinergic synapses are now known not to be restricted to the spinal cord and the brainstem. Presynaptic machinery for glycine release and uptake, the structure and function of postsynaptic receptors and the factors (both pre- and postsynaptic) which control the strength of glycinergic inhibition have been extensively studied. It is now established that glycinergic synapses can be excitatory in the immature brain and that some inhibitory synapses can corelease gamma-aminobutyric acid (GABA) and glycine. Moreover, the presence of glycine transporters on glial cells and the capacity of these cells to release glycine suggest that glycine may also act as a neuromodulator. Extensive molecular studies have revealed the presence of distinct subtypes of postsynaptic glycine receptors with different functional properties. Mechanisms of glycine receptors aggregation at postsynaptic sites during development are better understood and functional implications of variation in receptor number between postsynaptic sites are partly elucidated. Mutations of glycine receptor subunits have been shown to underly some human locomotor disorders, including the startle disease. Clearly, recent work on glycine receptor channels and the synapses at which they mediate inhibitory signalling in both young and adult animals necessitates an update of our vision of glycinergic inhibitory transmission.

High-affinity zinc potentiation of inhibitory postsynaptic glycinergic currents in the zebrafish hindbrain

Zinc has been reported to potentiate glycine receptors (GlyR), but the physiological significance of this observation has been put in doubt by the relatively high values of the EC(50), 0.5-1 microM, since such concentrations may not be attained in the synaptic cleft of glycinergic synapses. We have re-evaluated this observation in the frame of the hypothesis that contaminant heavy metals present in usual solutions may have lead to underestimate the affinity of the zinc binding site, and therefore to underestimate the potential physiological role of zinc. Using chelators either to complex heavy metals or to apply zinc at controlled concentrations, we have examined the action of zinc on GlyR kinetics in outside-out patches from 50-h-old zebrafish Mauthner cells. Chelating contaminating heavy metals with tricine or N,N,N',N'-tetrakis-(2-pyridylmethyl)-ethylenediamine (TPEN) decreased the duration of the currents evoked by glycine, confirming that traces of heavy metals alter the GlyR response in control conditions. Using tricine- (10 mM) buffered zinc solution, we then showed that zinc increases the amplitude of outside-out responses evoked by 0.1-0.5 mM glycine with an EC(50) of 15 nM. In contrast zinc had no effect on the amplitude of currents evoked by a saturating concentration (3-10 mM) of glycine. This suggests that zinc enhances GlyR apparent affinity for glycine. The study of the effects of zinc on the kinetics of the response indicates that this increase of apparent affinity is due to a decrease of the glycine dissociation rate constant. We then analyzed the effects of zinc on postsynaptic GlyRs in whole cell recordings of glycinergic miniature inhibitory postsynaptic currents (mIPSCs). Chelation of contaminant heavy metals decreased the amplitude and the duration of the mIPSCs; inverse effects were observed by adding zinc in buffered solutions containing nanomolar free zinc concentrations. Zinc plus tricine or tricine alone did not change the coefficient of variation ( approximately 0.85) of the mIPSC amplitude distributions. These results suggest that postsynaptic GlyRs are not saturated after the release of one vesicle.

Development of spontaneous glycinergic currents in the Mauthner neuron of the zebrafish embryo

We used whole cell and outside-out patch-clamp techniques with reticulospinal Mauthner neurons of zebrafish embryos to investigate the developmental changes in the properties of glycinergic synaptic currents in vivo from the onset of synaptogenesis. Miniature inhibitory postsynaptic currents (mIPSCs) were isolated and recorded in the presence of TTX (1 microM), kynurenic acid (1 mM), and bicuculline (10 microM) and were found to be sensitive to strychnine (1 microM). The mIPSCs were first observed in 26-29 h postfertilization (hpf) embryos at a very low frequency of approximately 0.04 Hz, which increased to approximately 0.5 Hz by 30-40 hpf, and was approximately 10 Hz in newly hatched (>50 hpf) larvae, indicating an accelerated increase in synaptic activity. At all embryonic stages, the amplitudes of the mIPSCs were variable but their means were similar ( approximately 100 pA), suggesting rapid formation of the postsynaptic matrix. The 20-80% rise times of mIPSCs in embryos were longer (0.6-1.2 ms) than in larvae (approximately 0.3 ms), likely due to slower diffusion of glycine at the younger, immature synapses. The mIPSCs decayed with biexponential (tau(off1) and tau(off2)) time courses with a half-width in 26-29 hpf embryos that was longer and more variable than in older embryos and larvae. In 26- to 29-hpf embryos, tau(off1) was approximately 15 ms and tau(off2) was approximately 60 ms, representing events of intermediate duration; but occasionally long mIPSCs were observed in some cells where tau(off1) was approximately 40 ms and tau(off2) was approximately 160 ms. In 30-40 hpf embryos, the events were faster, with tau(off1) approximately 9 ms and tau(off2) approximately 40 ms, and in larvae, events declined somewhat further to tau(off1) approximately 4 ms and tau(off2) approximately 30 ms. Point-per-point amplitude histograms of the decay of synaptic events at all stages resulted in the detection of similar single channel conductances estimated as approximately 45 pS, indicating the presence of heteromeric glycine receptors (GlyRs) from the onset of synaptogenesis. Fast-flow (1 ms) application of a saturating concentration of glycine (3-10 mM) to outside-out patches obtained at 26-29 hpf revealed GlyR currents that decayed biexponentially with time constants resembling the values found for intermediate and long mIPSCs; by 30-40 hpf, the GlyR currents resembled fast mIPSCs. These observations indicate that channel kinetics limited the mIPSC duration. Our data suggest that glycinergic mIPSCs result from the activation of a mixture of fast and slow GlyR subtypes, the properties and proportion of which determine the decay of the synaptic events in the embryos.

[Hematologic and immunologic manifestations of primary cytomegalovirus infections in non-immunocompromised hospitalized adults]

PURPOSE

Cytomegalovirus (CMV) infection in non-immunocompromised adults can sometimes induce hematological and immunological disorders that may mislead diagnosis.

METHODS

Case reports of hospitalized non-immunocompromised adults with positive serology for CMV including the presence of immunoglobulin M or seroconversion were assessed in a retrospective study (1981-1998). We focused on clinical and biological abnormalities showing the role of CMV in disruption of functioning of hematological and immunological systems.

RESULTS

Among 115 patients, lymphoma-like syndrome with large adenopathies and/or splenomegaly was diagnosed in eight patients, uncovering underlying CMV infection. Lymphoma was accompanied by hematoma in two patients. Three patients presented leg purpura (with thrombotic thrombocytopenic purpura in one case), one patient had cutaneous vasculitis and on other a Still's disease. Blood abnormalities were mononucleosis (64%), anemia (20%), and thrombopenia (25%) often of peripheral or hemolytic origin or due to hypersplenia. Electrophoresis of serum proteins showed an increase in immune globulins in 56% of the cases and monoclonal abnormality in nine cases. Immunological assessment was conducted in 18 patients. At least one abnormality was depicted in ten patients, consisting of either antinuclear, anti-platelet or anti smooth muscle antibodies, cryoglobulinemia, rheumatoid factor, or reduced complement fixation.

CONCLUSION

Testing for CMV infection can be of value in case of blood or immunological disorders associated with clinical or biological signs. Although hematological disorders occur early, they are rarely severe. Immunological disorders are rarely symptomatic, but often raise issues regarding the potential genesis of immune diseases in at-risk patients.

Recovery from open channel block by acetylcholine during neuromuscular transmission in zebrafish

At larval zebrafish neuromuscular junctions (NMJs), miniature end plate currents (mEPCs) recorded in vivo have an unusually fast time course. We used fast-flow application of acetylcholine (ACh) onto outside-out patches to mimic the effect of synaptic release onto small numbers of ACh receptor channels (AChRs). Positively charged ACh acted at hyperpolarized potentials and at millimolar concentrations as a fast ("flickering") open channel blocker of AChRs. Because of filtering, the open channel block resulted in reduced amplitude of single channel currents. Immediately after brief (1 msec) application (without significant desensitization) of millimolar ACh at hyperpolarized potentials, a slower, transient current appeared because of delayed reversal of the block. This rebound current depended on the ACh concentration and resembled in time course the mEPC. A simple kinetic model of the AChR that includes an open channel-blocking step accounted for our single channel results, as well as the experimentally observed slowing of the time course of mEPCs recorded at a hyperpolarized compared with a depolarized potential. Recovery from AChR block is a novel mechanism of synaptic transmission that may contribute in part at all NMJs.

Modulation by heparin of the interaction of the A1 domain of Von Willebrand factor with glycoprotein Ib

The conformation of the A1 domain of von Willebrand factor (vWF) is a critical determinant of its interaction with the glycoprotein (GP) Ib/V/IX complex. To better define the regulatory mechanisms of vWF A1 domain binding to the GPIb/V/IX complex, we studied vWF-dependent aggregation properties of a cell line overexpressing the GPIbalpha, GPIbbeta, and GPIX subunits (CHO-GPIbalphabeta/IX cells). We found that CHO-GPIbalphabeta/IX cell aggregation required the presence of both soluble vWF and ristocetin. Ristocetin-induced CHO-GPIbalphabeta/IX cell aggregation was completely inhibited by the recombinant VCL fragment of vWF that contains the A1 domain. Surprisingly, the substitution of heparin for ristocetin resulted in the formation of CHO-GPIbalphabeta/IX cell aggregates. Using monoclonal antibodies blocking vWF interaction with GPIb/V/IX or mocarhagin, a venom metalloproteinase that removes the amino-terminal fragment of GPIbalpha extending from aa 1 to 282, we demonstrated that both ristocetin- and heparin-induced aggregations involved an interaction between the A1 domain of vWF and the GPIbalpha subunit of the GPIb/V/IX complex. The involvement of heparin in cell aggregation was also demonstrated after treatment of heparin with heparinase that abolished CHO-GPIbalphabeta/IX cell aggregation. These results indicated that heparin was able to induce vWF-dependent CHO-GPIbalphabeta/IX cell aggregation. In conclusion, we demonstrated that heparin is capable of positively modulating the vWF interaction with the GPIb/V/IX complex.

Voltage dependence of the glycine receptor-channel kinetics in the zebrafish hindbrain

Electrophysiological recordings of outside-out patches to fast-flow applications of glycine were made on patches derived from the Mauthner cells of the 50-h-old zebrafish larva. As for glycinergic miniature inhibitory postsynaptic currents (mIPSCs), depolarizing the patch produced a broadening of the transient outside-out current evoked by short applications (1 ms) of a saturating concentration of glycine (3 mM). When the outside-out patch was depolarized from -50 to +20 mV, the peak current varied linearly with voltage. A 1-ms application of 3 mM glycine evoked currents that activated rapidly and deactivated biexponentially with time constants of approximately 5 and approximately 30 ms (holding potential of -50 mV). These two decay time constants were increased by depolarization. The fast deactivation time constant increased e-fold per 95 mV. The relative amplitude of the two decay components did not significantly vary with voltage. The fast component represented 64.2 +/- 2.8% of the total current at -50 mV and 54.1 +/- 10% at +20 mV. The 20-80% rise time of these responses did not show any voltage dependence, suggesting that the opening rate constant is insensitive to voltage. The 20-80% rise time was 0.2 ms at -70 mV and 0.22 ms at +20 mV. Responses evoked by 100-200 ms application of a low concentration of glycine (0.1 mM) had a biphasic rising phase reflecting the complex gating behavior of the glycine receptor. The time constant of these two components and their relative amplitude did not change with voltage, suggesting that modal shifts in the glycine-activated channel gating mode are not sensitive to the membrane potential. Using a Markov model to simulate glycine receptor gating behavior, we were able to mimic the voltage-dependent change in the deactivation time course of the responses evoked by 1-ms application of 3 mM glycine. This kinetics model incorporates voltage-dependent closing rate constants. It provides a good description of the time course of the onset of responses evoked by the application of a low concentration of glycine at all membrane potentials tested.

Encephalization, adaptation and evolution of chiroptera: A statistical analysis with further evidence for bat monophyly

As part of a large-scale study on brain morphometrics and adaptations in mammals, we addressed the problem of chiropteran evolution. A specific statistical framework was designed to test which of two competing hypotheses (bat monophyly vs. diphyly) is more strongly supported by quantitative brain data. Our analyses, based on 120 species, revealed that megabats and microbats were more closely related to each other than to primates, and illustrated the convergent adaptations of the brain of bats to similar trophic (i.e. feeding related) niches. Ecologically-corrected characters were then used to derive a new phylogeny which also supports the chiropteran clade. The monophyletic origin of bats is the preferred hypothesis to explain brain quantitative evolution in chiropterans and primates.

Regulation of growth factor gene expression in degenerating motoneurons of the murine mutant wobbler: a cellular patch-sampling/RT-PCR study

Motoneuronal degenerative diseases are characterized by their progressivity; once affected, the motoneurons remain in altered states during an intermediate phase of degeneration prior to their final disappearance. Whether this survival period coincides with active metabolic rearrangements in the affected neuron remains unknown. As a first step toward the elucidation of this question, we developed cDNA pooled samples obtained from degenerating and control motoneuron mRNA populations through cellular patch sampling and RT-PCR, using the murine wobbler mutant as a model of spinal atrophy. Hybridization of the cDNA pools to various markers of intact or degenerating motoneurons allowed us to verify the cellular specificity of the patch sampling and indicated conservation of the original mRNA population complexity. Exploration of transcriptional alterations of genes encoding growth factors thought to be involved in motoneuronal development revealed that gene expression of the neurotrophin BDNF was induced in affected motoneurons, while expression of neurotrophin-3 was present in both neuronal types. Likewise, expression of a member of the epidermal growth factor (EGF) family, the neuregulin transcript sensory motor neuron-derived factor, was detected in both control and degenerating motoneurons, while transforming growth factor alpha, the functional homolog of EGF, was present only in the affected motoneurons. Immunohistochemical detection of corresponding proteins corroborated these observations. These results demonstrate that, during the course of their degeneration, motoneurons can initiate expression of novel genes which lead to the production of molecules endowed with trophic and/or differentiative properties for the neurons themselves and their glial environment. They also validate the use of the developed cDNA pooled samples for further exploration of transcriptional alterations taking place in degenerating motoneurons.

A reluctant gating mode of glycine receptor channels determines the time course of inhibitory miniature synaptic events in zebrafish hindbrain neurons

Miniature IPSCs (mIPSCs) recorded in the Mauthner (M)-cell of zebrafish larvae have a broad amplitude distribution that is attributable only partly to the functional heterogeneity of postsynaptic glycine receptors (GlyRs). The role of the kinetic properties of GlyRs in amplitude fluctuation was investigated using fast-flow application techniques on outside-out patches. Short applications of a saturating glycine concentration evoked outside-out currents with a biphasic deactivation phase as observed for mIPSCs, and they were consistent with a rapid clearance of glycine from the synaptic cleft. Patch currents declined slowly during continuous applications of 3 mM glycine, but the biphasic deactivation phase of mIPSCs cannot reflect a desensitization process because paired-pulse desensitization was not observed. The maximum open probability (Po) of GlyRs was close to 0.9 with 3 mM glycine. Analyses of the onset of outside-out currents evoked by 0.1 mM glycine are consistent with the presence of two equivalent binding sites with a Kd of O.3-O.4 mM. Activation and deactivation properties of GlyRs were better described with a kinetic model, including two binding states, a doubly liganded open state, and a reluctant gating mode leading to another open state. The 20-80% rise time of mIPSCs was independent of their amplitude and is identical to that of outside-out currents evoked by the applications of a saturating concentration of glycine (>1 mM). These results support the hypothesis that GlyR kinetics determines the time course of synaptic events at M-cell inhibitory synapses and that large mIPSC amplitude fluctuations are mainly of postsynaptic origin.

Morphofunctional evidence for mature synaptic contacts on the Mauthner cell of 52-hour-old zebrafish larvae

In a previous study, miniature inhibitory synaptic events recorded in the Mauthner cell of the 52-hour-old zebrafish larvae (Brachydanio rerio) were found to be mainly glycinergic. Their amplitude distribution was not Gaussian and it was proposed that their large amplitude variation might reflect the activation of immature synapses. However, ultrastructural studies of the synaptic contacts over the M-cell soma of 52 h larvae described here, revealed that numerous synaptic contacts on this neuron are already mature at this developmental stage and that most of them already contain a single active zone. As in the adult goldfish, immunohistochemistry indicates the presence of both glycine- and GABA-immunoreactive boutons which establish synaptic contacts. We also found that, in addition to the predominant glycinergic postsynaptic inhibitory currents, some postsynaptic currents are also GABAergic since they are specifically inhibited by bicuculline (20 microM). GABAergic miniature events (time to peak close to 0.8 ms and decay time-constant close to 45 ms) were only detected in the presence of 11.5 mM [KCl]o. Their amplitude distributions were well fitted by one, or at most two, Gaussian curves. Outside-out recordings showed one class of GABA receptors with a main conductance state of 23 pS. This indicates that the smallest GABAergic miniature inhibitory synaptic events correspond to the opening of 14-20 chloride channels Pre- and postsynaptic factors which contribute to the predominance of glycinergic synaptic currents over GABAergic ones in untreated preparations and to the striking differences between their frequencies and their respective amplitude distribution histograms are discussed with reference to the morphological characteristics of the mature synaptic endings impinging on this still developing neuron.

Pharmacological evidence for two types of postsynaptic glycinergic receptors on the Mauthner cell of 52-h-old zebrafish larvae

The presence of homooligomeric and heterooligomeric glycine receptors (GlyRs) on the Mauthner (M) cell in the isolated medulla of 52-h-old zebrafish larvae was investigated by analysis of the effects of picrotoxin on glycine-gated channels and on glycinergic miniature inhibitory postsynaptic currents (mIPSCs). Two functionally different GlyRs have been previously described on the M cell. The effects of picrotoxin on these two GlyRs were first analyzed by measuring the relative change in their total open probability (NP(o)) with picrotoxin concentration. Picrotoxin had no significant effect on the glycine channel with a single conductance level of 40-46 pS. In contrast, picrotoxin application decreased the NP(o) of the GlyR with multiple subconductance levels. On this GlyR, picrotoxin decreased in a concentration-dependent manner the occurrence of the 80- to 86-pS substate (median inhibiting concentration = 0.89 microM) and had no apparent effect on the 40- to 46-pS opening probability. Opening frequency and the mean open times of the 80- to 88-pS main conductance state were reduced in the presence of 10 microM picrotoxin, but their relative weight remained unchanged. These effects of picrotoxin were not voltage dependent. Picrotoxin also modified 40- to 46-pS kinetics. At 100 microM, picrotoxin evoked voltage-independent flickering during channel openings. Short and long mean open times were significantly decreased, whereas the relative proportion of long mean open times was increased. The medium closed time was decreased, whereas medium burst duration was increased. The burst frequency remained unchanged. Spontaneous glycinergic mIPSCs were recorded in the presence of 1 microM tetrodotoxin + 25 microM bicuculline (holding potential = -50 mV). Application of 10 microM picrotoxin did not change the frequency of the synaptic activity, whereas it decreased the amplitude of large mIPSCs. No effect was observed on the time to peak (0.8 ms) or the mean decay time constant (tau(d) = 7.7 ms). Increasing picrotoxin concentration to 100 microM resulted in a decrease of mIPSC frequency (35.6%), amplitude (39.8%), and tau(d) (from 7.7 to 5 ms). These results suggest that these two functionally different GlyRs correspond to alpha1 homooligomeric-like and alpha1/beta-heterooligomeric-like GlyRs, and that both are synaptically activated. Variation in the proportions of GlyR subtypes from one synapse to another could partly account for the broad amplitude distribution of mIPSCs recorded from the zebrafish M cell.

Effects of nocodazole and taxol on glycine evoked currents on rat spinal cord neurones in culture

We examined the effect of altering the cytoskeleton polymerization state by treatment with nocodazole and taxol on glycine-evoked currents in patch-clamp recordings from cultured spinal cord neurones. Adding ATP and GTP to the pipette solution did not prevent the rundown of the peak current. In the absence or in the presence of ATP, the proportion of the non-desensitizing part of the glycine evoked-current declined with time. Adding intracellular GTP and ATP stabilized glycine-evoked responses although the proportion of non-inactivating current was reduced. Nocodazole reduced by itself the proportion of the non-inactivating current whereas taxol (with ATP and GTP) had an opposite effect. These results suggest that the polymerization state of microtubules has functional consequences on glycine receptors.

Voltage dependence of conductance changes evoked by glycine release in the zebrafish brain

1. The kinetics and mechanisms underlying the voltage dependence of inhibitory postsynaptic currents (IPSCs) recorded in the Mauthner cell (M cell) were investigated in the isolated medulla of 52-h-old zebrafish larvae, with the use of whole cell and outside-out patch-clamp recordings. 2. Spontaneous miniature IPSCs (mIPSCs) were recorded in the presence of 10(-6) M tetrodotoxin (TTX), 10 mM MgCl2, and 0.1 mM [CaCl2]o. Depolarizing the cell from -50 to +50 mV did not evoke any significant change in the distribution of mIPSC amplitudes, whereas synaptic currents were prolonged at positive voltages. The average decay time constant was increased twofold at +50 mV. 3. The voltage dependence of the kinetics of glycine-activated channels was first investigated during whole cell recording experiments. Currents evoked by voltage steps in the presence of glycine (50 microM) were compared with those obtained without glycine. The increase in chloride conductance (gCl-) evoked by glycine was time and voltage dependent. Inactivation and reactivation of the chloride current were observed during voltage pulses from 0 to -50 mV and from -50 to 0 mV, respectively, and they occurred with similar time constants (2-3 s). During glycine application, voltage-ramp analysis revealed a shift in the reversal potential (ECl-) occurring at all [Cl-]i tested. 4. The basis of the voltage sensitivity of glycine-evoked gCl- was first analyzed by measuring the relative changes in the total open probability (NPo) of glycine-activated channels with voltage.(ABSTRACT TRUNCATED AT 250 WORDS)

Matching behavioral evolution to brain morphology

A method is presented to test the relationship between a phylogenetic tree derived from brain morphology, and different hypotheses describing the evolution of a behavioral trait. This is a question of interest for evolutionary psychologists and behavioral biologists. The paper first discusses how hypotheses for behavioral evolution should be coded for such a comparison, then a triple-per-mutation test, originally proposed to compare independently obtained evolutionary trees, is used for the statistical assessment of each hypothesis. Non-parametric correlation coefficients computed between brain components and appropriately coded behavioral states can then be used to suggest what brain components are responsible for the development of the various states of the behavioral trait of interest. The procedure is illustrated with three different applications relating brain evolution to habitat selection in marsupials, locomotory specialization in primates, and trophic adaptation in bats.

Glycinergic inhibitory synaptic currents and related receptor channels in the zebrafish brain

To extend our study of the inhibitory synaptic network we have developed an isolated whole-brain preparation of the 52-h-old zebrafish (Brachydanio rerio) in which the structural and functional integrity of the brain is preserved. We report the characterization of quantal inhibitory events and the correlation of their properties with those of the underlying activated channels. During whole-cell recordings of the Mauthner cells, applications of 10(-6) M tetrodotoxin greatly reduced the frequency and amplitude of the spontaneously occurring synaptic events, which were dominated by Cl--dependent inhibitory postsynaptic currents (IPSCs). Lowering Ca2+ and adding Mg2+ to tetrodotoxin-containing solutions resulted in a further decrease in amplitude of the recorded synaptic currents, the remaining ones being considered as miniature IPSCs (mIPSCs). Applications of 0.5-1 microM strychnine in the presence of tetrodotoxin eliminated > 90% of the inhibitory currents in the preparation. The amplitude histograms of these mIPSCs exhibited two initial equally spaced peaks, followed by a skewed distribution for higher values. The first two components were well fitted by the sum of two Gaussian curves, giving a mean quantal amplitude of 35.7 pA (at a holding potential of -50 mV) and a coefficient of variation of 0.25 for the first peak. Outside-out recordings showed at least two classes of glycine receptor channels, one having multiple conductance levels with a main state of 81-86 pS and another displaying only one opening level of 41-43 pS. These two mean conductance states had similar mean open times, of 0.6-1 and 4.5-6 ms respectively. In addition, three mean closed times were observed for the 41-43 pS level. The shortest group (0.6-1 ms) was considered as representing gaps within bursts. Burst analysis revealed three mean burst durations, of 0.6, 4 and 35 ms. Comparisons of the amplitude of the first class of mIPSCs and of the open channel conductances indicated that one quantum opens 14-22 channels. Moreover, the correspondence between the mean decay time of mIPSCs and the mean open time or medium burst duration (4-5 ms) suggests that glycine-activated channels open only once in response to a single exocytosis. The pre- and postsynaptic origins of mIPSCs amplitude fluctuations are discussed in the context of multivesicular release versus the hypothesis of postsynaptic receptor saturation.

Automatic detection of spontaneous synaptic responses in central neurons

A fully automatized software package for detection and measurements of randomly occurring synaptic transients embedded in background noise is described. It is based on waveform recognition protocols, allows analysis of long data segments, and provides quantitative information about event amplitudes and kinetics. Simulated postsynaptic recordings have been used to assess its performance over a wide range of conditions mimicking those seen in physiological experiments.

Denitrification and methane production in sediment of Hamilton Harbour (Canada)

Systematic sampling of 21 sites covering Hamilton Harbour (Lake Ontario, Canada) was carried out during the summer in 1990 and 1991 in order to study how well environmental factors, such as O2, NO 3 (-) , and organic carbon, and the spatial structure can explain observed variation of potential denitrification, CH4 and CO2 production, as well as N2 fixation in sediment slurries. Using canonical redundancy analysis and an extension of this method to partial out the variance into spatial and environmental components, we found that most of the explained fraction of potential microbial activities (70-90%) was accounted for by the significant environmental variables (NH 4 (+) , particulate carbon, dissolved organic carbon, dissolved O2, depth, and temperature) and not much by the spatial polynomial trend surface. We found significant path coefficients (0.53 and 0.57 in 1990 and 1991) between CO2 production and potential denitrification, which suggests that denitrifiers are dependent upon a heterotrophic bacterial population for directly assimilable carbon sources. We also found significant path coefficients between particulate carbon and both CH4 production (0.67 and 0.33) and CO2 production (0.50 and 0.38), while significant path coefficients were also found between dissolved organic carbon and CO2 production (0.34 and 0.47). We conclude that beside well-known abiotic factors such as O2, NO 3 (-) , and organic carbon, a biotic factor involved in carbon metabolism may be important in explaining the spatial variation of denitrification capacity in the sediment of Hamilton Harbour.

Binding of heparin fractions to von Willebrand factor: effect of molecular weight and affinity for antithrombin III

To investigate the influence of the structure of heparin on its binding to vWF, we compared heparin fractions of different molecular weight (MW) or affinity for antithrombin III (ATIII). We studied the interaction of purified 125I-vWF or plasma vWF, labeled with a pool of 125I-monoclonal antibodies to vWF, with unfractionated heparin immobilized on agarose beads. Fractions were compared as competitors of these interactions and their effect was quantitated by their half-maximal inhibition (IC50). When the MW of the fractions decreased, especially below 7500, their IC50 increased, indicating that the affinity of the fractions for vWF decreased with their MW. Using heparin-derived oligosaccharides, we also demonstrated that a minimal chain length of 18 monosaccharides was required for heparin binding to vWF. In addition, different fractions with low affinity for ATIII were compared as competitors of 125I-vWF binding to heparin-agarose. Despite a very low content of ATIII binding sites, some fractions retained a low IC50. Thus, heparin interaction with vWF is independent of the presence of the ATIII binding site and is mostly dependent on the length of the heparin chain. These data suggest that unfractionated heparin is a more potent inhibitor of vWF-dependent functions than low MW heparin fractions.

The expression of matrix metalloproteinases and their inhibitors by pig synovial cells and their regulation by combinations of cytokines and growth factors

1. Pig synovial fibroblasts in culture were studied to determine if they were an easily reproducible model system for studying the actions of cytokines and growth factors on human synovial cells. The biochemical analyses were conducted by activity assays, enzymography and Northern blot. 2. Human recombinant interleukin-1 alpha, basic fibroblast growth factor and transforming growth factor-beta 1 were studied in combinations because of their known involvement in controlling tissue remodelling. 3. The response of pig fibroblasts to these agents, in terms of the expression of matrix metalloproteinases (collagenase, gelatinase and stromelysin) and their inhibitors (TIMPs), show that they behave similarly enough to human cells for use when supplies of human primary cells are unavailable.

Inactivation of NMDA channels in cultured hippocampal neurons by intracellular calcium

Calcium-dependent inactivation of NMDA channels was examined on cultured rat hippocampal neurons using whole-cell voltage-clamp and cell-attached single-channel recording. An ATP regeneration solution was included in the patch pipette to retard current "rundown." In normal [Ca2+]o (1-2 mM) and 10 microM glycine, macroscopic currents evoked by 15 sec applications of NMDA (10 microM) inactivated slowly following an initial peak. At -50 mV in cells buffered to [Ca2+]i < 10(-8) M with 10 mM EGTA, the inactivation time constant (tau inact) was approximately 5 sec. Inactivation did not occur at membrane potentials of +40 mV and was absent at [Ca2+]o < or = 0.2 mM, suggesting that inactivation resulted from transmembrane calcium influx. The percentage inactivation and tau inact were dependent on [Ca2+]o. The tau inact was also longer with BAPTA in the whole-cell pipette compared to EGTA, suggesting that tau inact reflects primarily the rate of accumulation of intracellular calcium. Inactivation was incomplete, reaching a steady state level of 40-50% of the peak current. At steady state, block of open NMDA channels with MK-801 ((+)-5-methyl-10,11-dihydro-5H- dibenzo[a,d]cyclohepten-5,10-imine) completely blocked subsequent responses to NMDA, suggesting that "inactivated" channels can reopen at steady state. Inactivation was fully reversible in the presence of ATP but was not blocked by inhibiting phosphatases or proteases. In cell-attached patches, transient increases in [Ca2+]i following cell depolarization also resulted in inactivation of NMDA channels without altering the single-channel conductance. This suggests that Ca(2+)-dependent inactivation occurs in intact cells and can be triggered by calcium entry through nearby voltage-gated calcium channels, although calcium entry through NMDA channels was more effective. We suggest that [Ca2+]i transients induce NMDA channel inactivation by binding to either the channel or a nearby regulatory protein to alter channel gating. This mechanism may play a role in downregulation of postsynaptic calcium entry during sustained synaptic activity.

Intrinsic quantal variability due to stochastic properties of receptor-transmitter interactions

Synaptic events at the neuromuscular junction are integer multiples of a quantum, the postsynaptic response to transmitter released from one presynaptic vesicle. At central synapses where quanta are small, it has been suggested they are invariant due to occupation of all postsynaptic receptors, a concept neglecting inherent fluctuations in channel behavior. If this did occur, the quantal release model would not apply there and could not be used to localize sites of synaptic modification. Monte Carlo simulations of quanta include transmitter diffusion and interactions with postsynaptic receptors that are treated probabilistically. These models suggest that when there are few postsynaptic channels available at a synapse, their stochastic behavior produces significant intrinsic variance in response amplitude and kinetics, and saturation does not occur. These results were confirmed by analysis of inhibitory quanta in embryonic and adult Mauthner cells involving a small and large number of channels, respectively. The findings apply to excitatory synapses as well.

Expression of NMDA channels on cerebellar Purkinje cells acutely dissociated from newborn rats

1. Conflicting evidence exists concerning the expression and properties of N-methyl-D-aspartate (NMDA) receptors on cerebellar Purkinje cells during development. We used whole-cell and single-channel recording to examine NMDA receptors on acutely dissociated Purkinje cells from newborn rats (postnatal day 0-4). 2. NMDA channels were present on > 80% of identified Purkinje cells and had pharmacological and single-channel properties that were indistinguishable from NMDA receptors on other neurons. In particular, responses were glycine-dependent and Mg2+ produced flickery open-channel block. 3. Our results demonstrate the transient expression of NMDA receptor/channels on Purkinje cells early in development. As NMDA receptors have been implicated in developmental plasticity in other regions of the CNS, a similar role is feasible during climbing fiber innervation of Purkinje cells.

Analyzing multivariate flow cytometric data in aquatic sciences

Flow cytometry has recently been introduced in aquatic ecology. Its unique feature is to measure several optical characteristics simultaneously on a large number of cells. Until now, these data have generally been analyzed in simple ways, e.g., frequency histograms and bivariate scatter diagrams, so that the multivariate potential of the data has not been fully exploited. This paper presents a way of answering ecologically meaningful questions, using the multivariate characteristics of the data. In order to do so, the multivariate data are reduced to a small number of classes by clustering, which reduces the data to a categorical variable. Multivariate pairwise comparisons can then be performed among samples using these new data vectors. The test case presented in the paper forms a time series of observations from which the new method enables us to study on the temporal evolution of cell types.

Ifenprodil blocks N-methyl-D-aspartate receptors by a two-component mechanism

The inhibition of N-methyl-D-aspartate (NMDA) receptor channels by the vasodilatory and anti-ischemic agent ifenprodil was examined on cultured rat hippocampal neurons. Whole-cell and single-channel patch recordings were used. Ifenprodil inhibition of NMDA currents could be separated into two components, with IC50 values of 0.75 and 161 microM. The high and low affinity components were both voltage independent but could be separated by their kinetics and dependence on extracellular calcium and glycine. The maximal inhibition of inward current by ifenprodil (approximately 90%) was equally divided between the two components in 0.3 mM extracellular calcium and 500 nM glycine. The low affinity action of ifenprodil had rapid kinetics and appeared to result from allosteric inhibition of the glycine modulatory site on the NMDA receptor. The macroscopic kinetics of the high affinity component were slow. The rate of onset was concentration dependent, and complete recovery required 1-2 min. Unlike open-channel blockers, ifenprodil block was not use dependent, and pre-exposure to ifenprodil also reduced subsequent NMDA responses. Low concentrations of ifenprodil were less effective after calcium-dependent inactivation of whole-cell currents, but the IC50 was unaffected, suggesting that calcium and ifenprodil act on a common set of channels. On outside-out membrane patches, ifenprodil reduced the frequency of channel opening without altering the single-channel conductance. Open time histograms of the large conductance events revealed two mean open times of approximately 2 and 8 msec, but only the duration of the long openings was decreased by ifenprodil. This effect was concentration dependent and revealed a blocking rate constant of 6 x 10(7) M-1sec-1. However, the proportion of current blocked by low concentrations of ifenprodil was larger in outside-out patches than in whole-cell recordings, suggesting that intracellular factors may influence ifenprodil efficacy. These results indicate that high affinity ifenprodil binding is extracellular and does not require agonist binding or channel opening. Because low concentrations of ifenprodil only partially inhibited the current and affected only the long openings, ifenprodil may promote a modal shift in channel gating.

Noncompetitive inhibition of gamma-aminobutyric acidA channels by Zn

The action of zinc on chloride currents evoked by gamma-aminobutyric acid (GABA) was examined on cultured hippocampal neurons using whole cell voltage clamp and outside-out patch recording. Zn (5-30 microM) noncompetitively blocked responses evoked by GABA (0.5-100 microM), but did not affect either the time-to-peak or desensitization of the macroscopic current. In outside-out patches, Zn had no effect on the mean conductance or lifetime of the 19 or 30 pS openings of the GABA channel; however, the frequency of channel opening was markedly decreased in a voltage-independent manner. Zn inhibition of GABA responses appeared to be independent of the benzodiazepine binding site as Zn was effective in the presence of either diazepam or Ro15-1788, a competitive antagonist of benzodiazepine agonists and inverse agonists. In contrast to prior reports, Zn also inhibited GABA currents in a similar manner on cultured superior cervical ganglion neurons. These results suggest that Zn acts at an extracellular site on the GABAA receptor complex, which is distinct from either the GABA or benzodiazepine binding sites. The structural similarity of the Cys-Cys loop of the alpha and gamma GABAA receptor subunits to some Zn-binding proteins suggests one possible region for a Zn binding site.

Maturation of a transient outward potassium current in mouse fetal hypothalamic neurons in culture

The whole-cell voltage clamp technique was used to record potassium currents in mouse fetal hypothalamic neurons developing in culture medium from days 1 to 17. The neurons were derived from fetuses of IOPS/OF1 mice on the 14th day of gestation. The mature neurons (greater than six days in culture) showed both a transient potassium current and a non-inactivating delayed rectifier potassium current. These were identified pharmacologically by using the potassium channel blockers tetraethyl ammonium chloride and 4-aminopyridine, and on the basis of their kinetics and voltage sensitivities. The delayed rectifier potassium current had a threshold of-20 mV, a slow time-course of activation, and was sustained during the voltage pulse. The 4-aminopyridine-sensitive current was transient, and was activated from a holding potential more negative (-80 mV) than that required for evoking the delayed rectifier potassium current (-40 mV). The delayed rectifier potassium current was detectable from day 1 onwards, while the transient potassium current showed a distinct developmental trend. The time-constant of inactivation became faster with age in culture. The half steady-state inactivation potential showed a shift towards less negative membrane potentials with age, and the relationship was best described by a logarithmic regression equation. The developmental trend of the transient potassium current may relate functionally to the progressive morphological changes, and the appearance of synaptic connections during ontogenesis.

Effects of dopamine on voltage-dependent potassium currents in identified rat lactotroph cells

The effects of dopamine (DA) on voltage-dependent potassium currents were investigated in rat lactotrophs maintained in primary culture. Lactotroph cells were identified using the reverse hemolytic plaque assay. Membrane currents and potentials of lactotroph cells were recorded using the patch-clamp recording technique in the 'whole-cell' configuration. In the presence of cobalt (2 mM), two types of voltage-dependent K+ currents were recorded, a voltage-activated delayed K+ current (IK) and a voltage-activated transient K+ current (IA). The current IK was activated at membrane potentials varying from -20 to +40 mV and did not inactivate during prolonged voltage steps (up to 25 s); it was blocked by tetraethylammonium (10 mM). The current IA was activated at membrane potentials higher than -45 mV and showed a voltage-dependent inactivation between -110 and -40 mV; it was slightly inhibited by 4-aminopyridine (5 mM). Under current-clamp conditions, the majority of the cells (60%) showed spontaneous Ca2(+)-dependent action potentials (APs) while silent cells (40%) were excitable by depolarizing current pulses. Bath application of 10 nM DA evoked a hyperpolarizing response, blocked spontaneous APs and decrease the amplitude of evoked APs. Only the hyperpolarizing response faded during the course of the whole cell recording experiments. Under voltage-clamp conditions, DA induced a reversible increase in both voltage-dependent outward K+ currents, without modifying their thresholds. Steady-state inactivation of IA was not affected by DA. These DA-induced responses were dose-dependent and they involved D2 receptor activation. They were mimicked by the specific D2 receptor agonist bromocriptine (10 nM) and blocked by the specific D2 receptor antagonist sulpiride (100 nM), the D1 antagonist SCH 23390 being ineffective. The ability of DA to increase voltage-dependent K+ currents cannot be observed without GTP in the recording pipette. It was pertussis-toxin-sensitive but was affected neither by bath application of 1 mM forskolin nor by the presence of 500 microM cyclic AMP with 500 microM 3-isobutyl-1-methylxanthine in the pipette solutions. We conclude that in lactotroph cells DA specifically increases two voltage-dependent K+ currents via a pertussis-toxin-sensitive guanine nucleotide regulatory protein and appears to be independent of intracellular cyclic AMP. This effect leads to a decrease in the excitability of the cell, explaining in part the inhibitory effect of DA on prolactin release.

The inhibition of single N-methyl-D-aspartate-activated channels by zinc ions on cultured rat neurones

1. Single channels activated by N-methyl-D-aspartate (NMDA) were studied in outside-out patches of cultured hippocampal neurones in the presence of glycine and absence of magnesium. The effects of the transition metal ions zinc and cadmium on NMDA channels were tested by placing the membrane patch at the mouth of one of an array of large barrelled flow pipes. 2. Amplitude histograms revealed several conductance levels between 5 and 45 pS with the majority of NMDA-activated openings greater than 25 pS. Zinc (5-100 microM) and cadmium (30-100 microM) reduced the number of large conductance events in a voltage-independent manner. Zinc (30 microM) reduced the large conductance openings by approximately 70-80%. The small number of events under 20 pS precluded quantitative assessment of the effects of zinc and cadmium on these conductance levels. Zinc inhibition of the calculated macroscopic current due to NMDA-activated channels could be fitted with a single binding site isotherm with an IC50 of 12 microM. 3. Zinc and cadmium also reduced the mean open time of the two largest conductance events of 38 and 43 pS; this reduction was voltage independent. Open-time histograms were fitted with the sum of two exponentials. In the presence of 5 microM-NMDA at -60 mV, tau o2 = 10.49 ms and tau o1 = 1.47 ms; in 30 microM-zinc, tau o2 = 3.49 and tau o1 = 0.8 ms. The 'blocking' rate constant calculated at a membrane potential of +40 mV from the slope of 1/tau o2 vs. [zinc]o was 4 x 10(6) M-1 S-1. 4. Closed-time analysis revealed brief (tau c = 0.4-1.0 ms) zinc-insensitive gaps; longer closed-time intervals were not analysed since all patches contained more than one channel. Both burst duration and the number of bursts were reduced in the presence of zinc. 5. At holding potentials negative to -40 mV in magnesium-free solutions, zinc also induced high-frequency flickering of the open channel which included complete channel closures at 4 kHz filtering. No zinc-induced flickering was seen at positive membrane potentials. The flickering was dose dependent, becoming prominent at zinc concentrations above 30 microM. Cadmium did not induce flickering at concentrations up to 100 microM.(ABSTRACT TRUNCATED AT 400 WORDS)

Dopamine inhibits two characterized voltage-dependent calcium currents in identified rat lactotroph cells

The effects of dopamine (DA) on voltage-dependent Ca2+ currents were investigated in cultured rat lactotroph cells using the patch clamp recording technique. Each recorded cell was identified by the reverse hemolytic plaque assay. In the whole-cell configuration, two types of Ca2+ currents, L and T, were characterized on the basis of their kinetics, voltage sensitivity, and pharmacology. The L component had a threshold of -25 mV, showed little inactivation during a 150-msec voltage step, and was maximal at +10 mV. Cadmium ions (100 microM) significantly reduced its amplitude (75%). The T component was activated at a membrane potential close to -50 mV, was maximal at -10 mV, and showed a voltage-dependent inactivation between -90 and -30 mV. It was quickly inactivated during a maintained depolarization (time constant, 27 ms at -30 mV) and was strongly reduced (80%) by nickel ions (100 microM). Bath application of DA (10 nM) caused a markedly general depression of inward Ca2+ currents, acting differently on the T- and L-type currents. DA application shifted the voltage-dependence of the L-type current activation toward depolarization values (8 mV) without modifying its time- and voltage-dependent inactivation. In contrast, DA enhanced the inactivation of the T-type current by accelerating its time-dependent inactivation (25% decrease in the time constant of inactivation) and by shifting the voltage-dependence of the T-type current inactivation toward hyperpolarizing values (-63 mV in control vs. -77 mV in the presence of DA). These effects of DA were dose-dependent and involved the activation of a D2 receptor type. They were mimicked by bromocriptine application (10 nM), whereas sulpiride (100 nM) blocked the DA-evoked response. The D1 antagonist SCH 23390 was ineffective up to 100 microM. All of these DA-induced modifications in Ca2+ currents were abolished using a GTP-free pipette solution or after pretreatment of cells with pertussis toxin, suggesting that DA can regulate the function of Ca2+ channels through GTP-binding proteins (G-proteins). Our results show that DA acts simultaneously by reducing both voltage-dependent Ca2+ currents on lactotroph cells. Thus, DA reduces the entry of Ca2+ ions across the surface membrane and thereby influences electrical activity and the cytosolic free Ca2+ concentration involved in both basal and evoked PRL release.

Electrophysiological effects of FLFQPQRF amide, an endogenous brain morphine modulating peptide, on cultured mouse spinal-cord neurons

Intracellular recordings were made from dissociated fetal mouse spinal cord neurones in primary culture. Micropressure application of FLFQPQRFamide (10(-5) M in the delivery pipette), an endogenous mammalian brain morphine modulating peptide, onto the surface of spinal cord neurones induced, in a dose dependent manner, a transitory hyperpolarization followed by a long lasting depolarization of the membrane potential (n = 37). In contrast, no response was observed when the peptide was applied on dorsal root ganglia neurones (n = 30). The depolarizing phase of this response was underlied by an increase of the input resistance. Extrapolated reversal potential for the depolarizing phase was close to -80 mV while it was close to -40 mV for the hyperpolarizing phase. Increasing extracellular K+ concentration raised the reversal potential value of depolarizing phases to more positive values. The amplitude of the depolarizing phase was reduced by application of tetraethylammonium (50 mM) while it was enhanced by application of 4-aminopyridine (3 mM). CaCl2 application (3 mM) reversibly blocked the hyperpolarization and decreased the subsequent depolarization. In presence of Ba2+ the extrapollated reversal potential of the hyperpolarizing phase was dramatically shifted to a more positive value. Finally FLFQPQRFamide induced response can be partially mimicked by FMRFamide application. Our observations indicate that FLFQPQRFamide can have multiple effects on membrane conductance of mammalian spinal cord neurones by acting on a single class of receptor. These effects of FLFQPQRFamide were found to be mainly excitatory.

Characterization of rat spinal cord receptors to FLFQPQRFamide, a mammalian morphine modulating peptide: a binding study

An in vitro binding assay, using 125I-YLFQPQRFamide, a newly synthetized iodinated analog of FLFQPQRFamide, in which Phe1 (F) has been substituted by a Tyr (Y), was developed to demonstrate and characterize putative binding sites of this brain morphine modulating peptide. This radioligand bound in a time-dependent manner to rat spinal cord membrane preparation. This binding was dose-dependent, saturable and reversible. Both kinetic data and saturation measured at equilibrium lead to the existence of a homogenous population of high affinity binding sites with a Kd value of 0.09-0.1 nM and a maximal capacity Bmax of 14.5 +/- 2 fmol/mg protein. Results of competition experiments show that both FLFQPQRFamide and its analog YLFQPQRFamide had a similar capacity to inhibit the 125I-YLFQPQRFamide binding, suggesting that this radioiodinated analog is a good tool to study binding characteristics of FLFQPQRFamide receptors. The related octadecapeptide AGEGLSSPFWSLAAPQRFamide, another mammalian morphine modulating peptide competes for radioligand binding with similar potency. Our results also show that mu, delta and kappa opiate receptor agonists as well as the antagonist naloxone were not able to affect binding either in presence or in absence of 120 mM NaCl. Together, these data demonstrate that FLFQPQRFamide does not function as an endogenous opiate receptor antagonist and that is capacity to reduce opiate-induced analgesia is supported by specific binding sites.

Genetic differences among language families in Europe

We investigated whether 59 allele frequencies and 10 cranial variables differed among speakers of the 12 modern language families in Europe. Although this is a classical analysis of variance design, special techniques had to be developed for the analysis because of spatial autocorrelation of both biological and language data. The method examines pooled sums of squares within language families. These are compared with the same quantities obtained by randomly partitioning the available data points in Europe into internally cohesive subsets representing the same sample sizes for each language family as in the originally observed data. Our results suggest that for numerous genetic systems, population samples differ more among language families than they do within families. These findings are considered in relation to two contrasting models: a model of random spatial differentiation of gene frequencies unrelated to language and a model of aboriginal genetic differences among speakers of different language groups. Our observed findings suggest partial validity of both models.

Dynamics of fecal coliform and culturable heterotroph densities in an eutrophic ecosystem: Stability of models and evolution of these bacterial groups

Time series of a population of fecal coliforms and a community of total viable counts were recorded during years 5 and 6 after the "birth" of an eutrophic aquatic ecosystem (sewage treatment lagoons). These time series were used to re-examine models, previously published, describing their temporal dynamics as well as the relationships between bacterial and environmental variables. The dynamics of the fecal coliforms and their relationships to the environment were unchanged; the fecal coliform abundances displayed an annual cycle with maximum reduction in numbers during the summer, which would be due at least partly to environmental variables (hypotheses of control by irradiance and pH, which have a seasonal behavior, are supported by the data). On the contrary, the total viable count dynamics moved towards a closer dependence on phytoplankton, from a situation of relative independence with respect to other biotic components of the ecosystem. Indeed during the first two years, only one of the abiotic variables in the model (the biological oxygen demand, which is an indicator of available organic matter) seemed to have an effect on the total viable counts. The behavior of these bacterial groups, measured during 1980-1982 and 1984-1986, shows that demographic and ecological laws founded on the observation of other organisms also apply to heterotrophic bacteria. A population, such as the fecal coliforms in the present study, has a limited ecological amplitude and is then more likely to react to environmental variables such as irradiance, pH, and phytoplanktonic metabolic products, whose bactericidal action is highest during the summer months and lowest during winter. On the other hand, a community such as that detected by the total viable counts of the present study is composed of many species and thus has a larger ecological amplitude. This makes it easier for the species to occupy the various available habitats and to maintain themselves through ecological succession and endogenous rhythms.

Characterization of three types of potassium current in cultured neurones of rat supraoptic nucleus area

1. Whole-cell, voltage-clamp recordings were obtained from neurones of the supraoptic area of neonatal rats in dissociated cell culture. Recordings were made from neurones having the same morphology as those which were vasopressin or oxytocin immunoreactive. 2. Three types of voltage-activated K+ current were identified on the basis of their kinetics, voltage sensitivities, Ca2+ dependence and pharmacology. The currents corresponded to the delayed rectifier current (IK), the A-current (IA), and the Ca2+-dependent current (IK(Ca] described in other neurones. 3. IK had a threshold of -40 mV, a sigmoidal time course of activation, and was sustained during voltage steps lasting less than 300 ms. The underlying conductance was voltage dependent reaching a maximum at +30 mV (mean maximum conductance 4.09 nS). The activation time constant was also voltage dependent declining exponentially from 4.5 ms at -30 mV to 1.8 ms at +50 mV. 4. IA was transient, and was activated from holding potentials negative to -70 mV; the maximum conductance (mean 5.9 nS) underlying the current was obtained at +10 mV. The activation and inactivation time constants were voltage dependent: the activation time constant declined exponentially between -40 mV (2.2 ms) and +40 mV (0.65 ms). 5. IK and IA were attenuated by the K+ channel blockers tetraethylammonium (TEA) and 4-aminopyridine (4-AP). TEA blocked the conductance underlying IK but appeared to alter the kinetics of IA. In contrast, 4-AP blocked the conductance underlying IA and, to a lesser extent, IK. 6. IK and IA were activated independently of external Ca2+ and the voltage activation of Ca2+ channels since these currents were recorded in the presence of Co2+, a Ca2+ channel blocker. 7. IK(Ca) was recorded only when Ca2+ (2 mM) was present in the external medium. From a holding potential of -30 mV, IK(Ca) had a threshold of -20 mV, was maximal at about +20 mV and declined at more positive potentials. This current was sustained during voltage steps lasting 100 ms and was abolished by addition of Co2+ (2 mM) to the medium. 8. The possible roles of the three K+ currents in regulating the characteristic firing behaviour of supraoptic neurones previously recorded in vivo and in vitro are discussed.

Characteristics and specific localization of receptors for atrial natriuretic peptides at non-neuronal cells in cultured mouse spinal cord cells

Characteristics of atrial natriuretic peptide receptors were determined in cultured mouse spinal cord cells. Saturation and competition experiments demonstrated the presence of a single class of atrial natriuretic peptide binding sites with high affinity (KD = 0.054 nM) and a density of 1.92 fmoles/10(6) cells. A similar affinity (KD = 0.070 nM) was observed in rat spinal cord membrane preparations. These atrial natriuretic peptide binding sites were functional receptors since the treatment of cells with atrial natriuretic peptide increased cyclic guanosine monophosphate levels within these cells in a classical time-dependent manner. When atrial natriuretic peptide was applied onto the cell body of intracellularly recorded spinal cord neurons, this peptide did not evoke a change of the input resistance or of the resting membrane potential value. Light-microscopic autoradiography studies showed that no atrial natriuretic peptide binding could be detected on typical birefringent neurons but it could be located on astroglial and epithelial cells as identified by immunocytochemical markers. These results show that functional atrial natriuretic peptide receptors with high affinity exist in cultured mouse spinal cord cells and are not located on neurons. The presence of atrial natriuretic peptide receptors on astrocytes suggests that this neuropeptide might be a good candidate for neuron-glial communication. As the atrial natriuretic peptide binding sites previously shown in epithelia responsible for maintaining fluid and electrolyte gradients, the atrial natriuretic peptide receptors on epithelial cells in these spinal cord cultures may be involved in vivo in the control of water balance in the central nervous system.

["The Jews interpret in a crazy manner." Evaluation of a classical text]

The author scrutinizes a text taken from the law of Justinian, 553 A. D., which assigns the Jews a place in the occidental-Christian system of thought. The identity of personal power, whether imperial or papal, and legal text merges the real and the symbolic. That is, authority determines the interpretation of the text. The author designates this the Christian-industrial religion and the Christian-industrial psychology and thereby draws connections with the present. Jewish textual interpretation, in which the text alone yields authority, is nourished--like psychoanalysis--by the tension between reality and fantasy, by the contradiction between power and desire.

Excitatory effect of serotonin on pacemaker neurons in spinal cord cell culture

Intracellular recordings were made from fetal mouse spinal cord neurons in primary culture. One type of neuron, with large somata (40-50 microns diameter) and thick neurites exhibited endogenous bursting or beating pacemaker electrical activity. Noradrenaline depolarized this type of neuron by decreasing an M-like conductance. Micropressure application of serotonin (10(-5) M in the delivery pipette) onto the surface of pacemaker neurons evoked a depolarization of the membrane potential in a dose-dependent manner with an increased input resistance. No such response was observed with other types of spinal cord neurons in culture. The response to serotonin was partially voltage-dependent. The serotonin-induced depolarization reversed at holding potential close to -100 mV. However, the input resistance variation evoked by serotonin increased exponentially when membrane potential was depolarized. The reversal potential was modified by increasing extracellular K+ concentration and it was unaltered by increasing the intracellular Cl- concentration. The decrease in K+ conductance induced by serotonin was not suppressed by the application of tetraethylammonium (50 mM) or 4-aminopyridine (10 mM). Furthermore, application of Ba2+ (6 mM) or Cd2+ (0.1 mM) had no effect on this response, suggesting that the depolarization evoked by serotonin application was not calcium-dependent. The serotonin evoked increase in input resistance was mediated by activation of a 5-HT1A-like receptor site. Spiperone, a 5-HT1A antagonist reversibly blocked the response. Methiothepin, a 5-HT1-5-HT2 antagonist (10(-3) M); cocaine, a 5-HT3 antagonist (10(-3) M); ketanserin, a 5-HT2 antagonist (10(-3) M); and prazosin, an alpha 1 antagonist (10(-3) M) had no effect.(ABSTRACT TRUNCATED AT 250 WORDS)