GABA-mediated induction of early neuronal markers expression in postnatal rat progenitor cells in culture.

Retinogenesis is a developmental process that involves the sequential formation of neurons and glia from retinal progenitors. Once retinogenesis is completed, Müller glial cells can be stimulated to differentiate into neuronal lineages and constitute a retina-intrinsic source of neural progenitors. The identification of the intrinsic and extrinsic factors that control proliferation and differentiation of Müller cells or retinal progenitors is needed in order to fully define their potential therapeutic use in regenerative approaches. Here we determined the response of retinal progenitors derived from Müller glia primary cell cultures to GABA-activated signal transduction cascades. Using Western blot analysis, immunocytochemistry and calcium imaging we found that GABA induces an increase of the number of progenitor cells that present spontaneous intracellular calcium transients as well as their frequency, which involve the participation of L-type voltage-gated calcium channels (VGCCs). This process correlates with the activation of transcription factor CREB through Ser33 phosphorylation and the induction of expression of the early neuronal markers NeuroD1 and ßIII-tubulin. GABA-mediated CREB phosphorylation was rapid and sustained and the pharmacological blockade of CREB activity inhibited the effect of GABA on NeuroD1 expression. Furthermore, consistent with the role of CREB as a histone acetyltransferase recruiter, we demonstrate that GABA induces the modification of histone H4 acetylation pattern in these cells suggesting that epigenetic alterations participate in the differentiation process. Our results support the notion that postnatal retinal progenitors derived from Müller glia primary cell cultures respond to GABA through the same molecular pathway previously characterized in hippocampal progenitors and developing neurons. We speculate that the induction of GABA receptor signaling could represent a novel strategy to enhance neural versus glial specification from these cells through genetic and epigenetic mechanisms.

Analysis of the domain interactions between the protease and helicase of NS3 in dengue and hepatitis C virus.

Flaviviridae non-structural 3 protein (NS3) is a multifunctional enzyme, composed by a protease domain (NS3pro) and an RNA helicase domain (NS3hel). The activities present in NS3 have proved to be critical for viral replication. The replicative cycle of Flaviviridae requires coordinated regulation of all the activities present in the full-length NS3 protein, however, the exact nature of these interactions remains unclear. The present work aimed to determine common structural features between NS3 of dengue and hepatitis C viruses and to characterize residues involved in the regulation of the interdomain motions between NS3pro and NS3hel. Analysis of the root mean square (RMS) variation shows that NS3pro increases the stability of subdomain 1 of the RNA helicase. Moreover, the dynamic behaviour of the carboxy terminus of NS3hel, supports the hypothesis that, upon release of the carboxy-terminus from NS3pro, the residues involved in this interaction are folded back into the last alpha-helix. Using normal mode analysis, we characterized slow collective motions of NS3, and observed that the two lowest-frequency normal modes are enough to describe reorientations of NS3pro relative to NS3hel. These movements induced an increment in the exposure of the active site of NS3pro that can be important during the proteolytic processing of the viral polyprotein. The third low-frequency normal mode was correlated to subdomain reorientations of NS3hel, similar to those proposed during NTP hydrolysis and dsRNA unwinding. Based on these data, we support a dynamic model, in which the domain movements between NS3pro and NS3hel result in the regulation of its activities.

Development of a questionnaire for the assessment of sources of stress in Spanish soccer referees

El objetivo de este estudio consistió en la elaboración de un instrumento de evaluación que identificara las principales fuentes de estrés en los árbitros de fútbol españoles, y que posibilitara la identificación de individuos con niveles elevados de estrés en este tipo de población. El Cuestionario de Estrés de Árbitros de Fútbol (CEAF) se desarrolló a partir de una muestra de 138 árbitros, y el análisis de componentes principales con rotación varimax produjo una solución de 5 factores que explicaban el 65.7% de la varianza. La versión definitiva del cuestionario obtuvo un aIpha de Cronbach de 0.88. Los estresores más importantes se relacionaban con la competencia arbitral percibida y con la evaluación que el árbitro recibe del informador en los partidos

The aim of the present study was to elaborate a self-report questionnaire to identify Spanish soccer referees' sources of stress and to provide a tool for the detection of referees with high levels of stress. The Soccer Referee Stress Questionnaire was administered to a sample of 138 referees, and a principal component analysis with varimax rotation revealed a S-factor solution that accounted for 65.7% of the variance. The final version of the test had a Cronbach's alpha of 0.88. The most important sources of stress were related to the referee's perceived competence and, to the referee-supervisor's rating ofmatches

Volume changes and whole cell membrane currents activated during gradual osmolarity decrease in C6 glioma cells: contribution of two types of K+ channels.

Volume changes and whole cell ionic currents activated by gradual osmolarity reductions (GOR) of 1.8 mosM/min were characterized in C6 glioma cells. Cells swell less in GOR than after sudden osmolarity reductions (SOR), the extent of swelling being partly Ca(2+) dependent. In nominally Ca(2+)-free conditions, GOR activated predominantly whole cell outward currents. Cells depolarized from the initial -79 mV to a steady state of -54 mV reached at 18% osmolarity reduction [hyposmolarity of -18% (H-18%)]. Recordings of Cl(-) and K(+) currents showed activation at H-3% of an outwardly rectifying Cl(-) current, with conductance of 1.6 nS, sensitive to niflumic acid and 5-nitro-2-(3-phenylpropylamino)benzoic acid, followed at H-18% by an outwardly rectifying K(+) current with conductance of 4.1 nS, inhibited by clofilium but insensitive to the typical K(+) channel blockers. With 200 nM Ca(2+) in the patch pipette, whole cell currents activated at H-3% and at H-13% cells depolarized from -77 to -63 mV. A K(+) current activated at H-1%, showing a rapid increase in conductance, suppressed by charybdotoxin and insensitive to clofilium. These results show the operation of two different K(+) channels in response to GOR in the same cell type, activated by Ca(2+) and osmolarity and with different osmolarity activation thresholds. Taurine and glutamate efflux, monitored by labeled tracers, showed delayed osmolarity thresholds of H-39 and H-33%, respectively. This observation clearly separates the Cl(-) and amino acid osmosensitive pathways. The delayed amino acid efflux may contribute to counteract swelling at more stringent osmolarity reductions.

Isovolumetric regulation mechanisms in cultured cerebellar granule neurons.

Cultured cerebellar granule neurons exposed to gradual reductions in osmolarity (-1.8 mOsm/min) maintained constant volume up to -50% external osmolarity (pi(o)), showing the occurrence of isovolumetric regulation (IVR). Amino acids, Cl-, and K+ contributed at different phases of IVR, with early efflux threshold for [3H]taurine, D-[3H]aspartate (as marker for glutamate) of pi(o) -2% and -19%, respectively, and more delayed thresholds of -30% for [3H]glycine and -25% and -29%, respectively, for Cl- (125I) and K+ (86Rb). Taurine seems preferentially involved in IVR, showing the lowest threshold, the highest efflux rate (five-fold over other amino acids) and the largest cell content decrease. Taurine and Cl- efflux were abolished by niflumic acid and 86Rb by 15 mM Ba2+. Niflumic acid essentially prevented IVR in all ranges of pi(o). Cl--free medium impaired IVR when pi(o) decreased to -24% and Ba2+ blocked it only at a late phase of -30% pi(o). These results indicate that in cerebellar granule neurons: (i) IVR is an active process of volume regulation accomplished by efflux of intracellular osmolytes; (ii) the volume regulation operating at small changes of pi(o) is fully accounted for by mechanisms sensitive to niflumic acid, with contributions of both Cl- and amino acids, particularly taurine; (iii) Cl- contribution to IVR is delayed with respect to other niflumic acid-sensitive osmolyte fluxes (osmolarity threshold of -25% pi(o)); and (iv), K+ fluxes do not contribute to IVR until a late phase (< -30% pi(o)).

Influence of CA2+ on K+ efflux during regulatory volume decrease in cultured astrocytes.

The calcium (Ca2+) dependence of potassium (K+) efflux activated by hyposmolarity in cultured cerebellar astrocytes was investigated, measuring in parallel experiments (86)Rb release and changes in cytosolic Ca2+ ([Ca2+]i). Hyposmotic (50%) medium increased [Ca2+]i from 117 to 386 nM, with contributions of extracellular Ca2+ and Ca2+ from the endoplasmic reticulum. Hyposmotic medium increased (86)Rb efflux rate from 0.015 min(-1) to a maximal of 0. 049 min(-1) and a net release of 30%. This osmosensitive efflux was inhibited by Ba(2+) (0.028 min(-1)), quinidine (0.024 min(-1)), and charybdotoxin (0.040 min(-1)), but was unaffected by TEA, 4-AP, or apamin. Removal of external Ca2+ from the hyposmotic medium increased (86)Rb efflux to a maximal rate constant of 0.056 min(-1) and a net release of 38% and caused a delay of inactivation. These changes were due to the overlaping of an efflux activated by Ca2+ removal in isosmotic medium. This isosmotic 86Rb efflux was unaffected by TEA or 4-AP, reduced by verapamil, and abolished by Ba2+, nitrendipine, and Mg2+. With the swelling-induced [Ca2+]i rise suppressed by ethyleneglycoltetraacetic acid-acetoxy-methyl ester (EGTA-AM), hyposmotic (86)Rb was 30% reduced. The Ca2+ entry blockers Cd2+, Ni2+, La3+, and Gd3+ did not affect (86)Rb efflux. A 40% decrease observed with verapamil and nitrendipine was found unrelated to Ca2+, because these agents did not affect the [Ca2+]i rise and the inhibition persisted in the absence of external Ca2+. The phospholipase C blocker U-73122 did not affect [Ca2+]i nor (86)Rb efflux. Blockers of Ca2+/calmodulin W7 and KN-93 decreased (86)Rb efflux to the same extent as EGTA-AM. Ionomycin markedly potentiated (86)Rb release in hyposmotic conditions only when [Ca2+]i was raised to about 1 microM, suggesting the implication of maxi-K+ channels at this [Ca2+]i threshold, which nonetheless, was not attained during hyposmotic swelling. It is concluded that (86)Rb efflux in cerebellar astrocytes is largely (70%) Ca2+-independent and the Ca2+-dependent fraction is sustained essentially by Ca2+ released from the endoplasmic reticulum and mediated by a mechanism involving Ca2+/calmodulin.

Intestinal amoebiasis: antibody-secreting cells and humoral antibodies.

Splenic plasma cell response and systemic antibody response to intestinal amoebiasis were studied in C3H/HeJ mice from 5 to 60 days post-inoculation with Entamoeba histolytica. At various time intervals specific antibody-secreting cells (ASC) in the spleen were measured in infected mice and non-infected control mice by enzyme-linked immunospot (ELISPOT) assay. Serum antibodies were measured by enzyme-linked immunosorbent assay (ELISA). The infected animals showed high IgA ASC from 30 to 50 days post-inoculation as compared to IgM and IgG ASC. However, class-specific serum antibody showed high IgG titre from 30 to 60 days post-inoculation as compared to IgM and IgA serum titres. Our results suggest that E. histolytica trophozoites can induce a plasma cell response in the spleen that is different from anti-amoebic antibody response in serum.

Ca2+ changes and 86Rb efflux activated by hyposmolarity in cerebellar granule neurons.

Hyposmotic swelling increased 86Rb release in cultured cerebellar granule neurons (1 day in vitro [DIV]) with a magnitude related to the change in osmolarity. 86Rb release was partially blocked by quinidine, Ba2+, and Cs+ but not by TEA, 4-AP, or Gd3+. 86Rb efflux decreased in Cl(-)-depleted cells or cells treated with DDF or DIDS, suggesting an interconnection between Cl- and K+ fluxes. Swelling induced a substantial increase in [Ca2+]i to which both external and internal sources contribute. However, 86Rb efflux was independent of [Ca2+]0, unaffected by depleting the endoplasmic reticulum (ER) by ionomycin or thapsigargin and insensitive to charybdotoxin, iberiotoxin, and apamin. Swelling-activated 86Rb efflux in differentiated granule neurons after 8 DIV, which express Ca2+-sensitive K+ channels, was not different from that in 1 DIV neurons, nor in time course, net release, Ca2+-dependence, or pharmacological sensitivity. We conclude that the swelling-activated K+ efflux in cerebellar granule neurons is not mediated by Ca2+-sensitive large conductance K+ channels (BK) as in many cell types but resembles that in lymphocytes where it is possibly carried by voltage-gated K+ channels.