Pichia kudriavzevii as a representative yeast of North Patagonian winemaking terroir.

Terroir concept includes specific soil, topography, climate, landscape characteristics and biodiversity features. In reference to the last aspect, recent studies investigating the microbial biogeography (lately called 'microbial terroir') have revealed that different wine-growing regions maintain different microbial communities. The aim of the present work was to identify potential autochthonous fermentative yeasts isolated from native plants in North Patagonia, Schinus johnstonii, Ephedra ochreata and Lycium chilense, that could be associated to the specific vitivinicultural terroir of this region. Different Pichia kudriavzevii isolates were recovered from these plants and physiologically and genetically compared to regional wine isolates and foreign reference strains of the same species. All isolates were subjected to molecular characterization including mtDNA-RFLP, RAPD-PCR and sequence analysis. Both wine and native P. kudriavzevii isolates from Patagonia showed similar features, different from those showed by foreign strains, suggesting that this species could be part of a specific regional terroir from North Patagonia.

TdKT, a new killer toxin produced by Torulaspora delbrueckii effective against wine spoilage yeasts.

Microbiological spoilage is a major concern throughout the wine industry, and control tools are limited. This paper addresses the identification and partial characterization of a new killer toxin from Torulaspora delbrueckii with potential biocontrol activity of Brettanomyces bruxellensis, Pichia guilliermondii, Pichia manshurica and Pichia membranifaciens wine spoilage. A panel of 18 different wine strains of T. delbrueckii killer yeasts was analysed, and the strain T. delbrueckii NPCC 1033 (TdKT producer) showed a significant inhibitory effect on the growth of all different spoilage yeasts evaluated. The TdKT toxin was then subjected to a partial biochemical characterization. Its estimated molecular weight was N30 kDa and it showed glucanase and chitinase enzymatic activities. The killer activity was stable between pH 4.2 and 4.8 and inactivated at temperature above 40 °C. Pustulan and chitin ­ but not other cell wall polysaccharides ­ prevented sensitive yeast cells from being killed by TdKT, suggesting that those may be the first toxin targets in the cell wall. TdKT provoked an increase in necrosis cell death after 3 h treatment and apoptotic cell death after 24 h showing time dependence in its mechanisms of action. Killer toxin extracts were active at oenological conditions, confirming their potential use as a biocontrol tool in winemaking.

Cell migration in BeWo cells and the role of epithelial sodium channels.

Cell migration/proliferation processes associated with wound healing were measured in BeWo cells at 6 h, when mitosis is still scarce. Cells were cultured in medium with 1% fetal bovine serum to minimize proliferation. BeWo cell migration covered 20.6 +/- 7.0%, 38.0 +/- 5.4%, 16.6 +/- 4.8% and 13.7 +/- 3.6% of the wound when cultivated under control, aldosterone (100 nM, 12 h), aldosterone plus amiloride (10 muM) and amiloride treatments, respectively. When BeWo cells were treated with aldosterone, there was an increase in wound healing (P < 0.05), which was prevented by adding the ENaC blocker amiloride (P < 0.05, n = 16). Immunocytochemistry studies showed that the three ENaC subunits showed greater expression at the leading edge of the wound 3 h after injury, supporting the notion that these proteins participate in a postinjury signal. Antisense oligonucleotides directed against the alpha-ENaC subunit decreased the migratory response of the cells compared to the sense treated cells or the cells without oligonucleotides (P < 0.001, n = 16): 30.2 +/- 3.7%, 17.6 +/- 1.3%, 27.5 +/- 1.5% and 20.2 +/- 1.5% reinvasion of the wound with aldosterone, aldosterone plus antisense, aldosterone plus sense treatments and control conditions, respectively. Aldosterone and amiloride influence wound healing in BeWo cells, probably by their effects upon ENaCs, transmitting a signal to the cell cytoplasm for the release of several agents that promote cell migration.

Imatinib resistance in multidrug-resistant K562 human leukemic cells.

The multidrug resistance phenotype (MDR) is one of the major causes of failure in cancer chemotherapy and it is associated with the over-expression of P-glycoprotein (P-gp or MDR1) in tumor cell membranes. A constitutive NF-kappaB activity has been observed in several haematological malignancies and this is associated with its anti-apoptotic role. In the present work, the relationship between NF-kappaB and MDR phenotype was evaluated in wild type K562 human leukemic cells (K562-WT) and in its vincristine-resistant counterpart, K562-Vinc cells. These data showed that K562-Vinc cells, which express an active P-gp, exhibited MDR phenotype. The resistant indexes (IC(50)(K562-Vinc)/IC(50)(K562-WT)) for structurally unrelated drugs like imatinib, doxorubicin and colchicine were 8.0+/-0.3, 2.8+/-0.4 and 44.8+/-8.8, respectively. The imatinib resistance was reversed by P-gp blockade suggesting the involvement of P-gp in imatinib transport. We observed that NF-kappaB was constitutively activated in both cell lines but in a lesser extent in K562-Vinc. The inhibition of NF-kappaB with BAY 11-7082 increased the cytotoxicity of imatinib in K562-Vinc cells but not in K562-WT. Further, the co-administration of imatinib and BAY 11-7082 sensitized multidrug-resistant K562 cells to cell death as detected by increased percentage of annexin V positive cells. The induced cell death in K562-Vinc cells was associated with activation of caspases 9 and 3. Finally, we provide data showing that BAY 11-7082 down-regulates the expression of P-gp suggesting that the activity of NF-kappaB could be functionally associated to this protein in K562 cells. Our results indicate that the vincristine-resistant K562 cells which developed MDR phenotype, exhibited resistance to imatinib associated with a functional P-gp over-expression. This resistance could be partially overcome by the inhibition of NF-kappaB pathway.

[Preeclampsia, cellular migration and ion channels]. / Preeclampsia, migración celular y canales iónicos.

The syncytiotrophoblast acts in human placenta as a transporting barrier regulating the transference of nutrients, solutes and water between maternal and fetal blood. This transepithelial transport involves movement of Na+ and its contribution to the osmotic pressure is an important determinant of the extracellular fluid volume. ENaC is a channel that mediates entry of Na+ from the luminal fluid into the cells in many reabsorbing epithelia; it is aldosterone, vasopressin, insulin and catecholamine-inducible, modulated by estrogens and progesterone and blocked by amiloride and its analogs. Multiple proteases are involved in the proteolytic processing and activation of ENaC subunits and aldosterone alters the protease-protease inhibitors balance. ENaC is also expressed in human placenta; although its function is not well known, the Na+ conductive properties may participate in electrolyte and extracellular volume homeostasis. The activity of ENaC channels and other ion channels and transporters is regulated by the state of actin filaments; on the other hand, changes in volume influence the actin cytoskeleton. Thus, there is an interaction between ENaC and components of the apical membrane cytoskeleton. In addition to their role in cellular homeostasis and electrical properties, Na+ currents through ENaC and other sodium channels are involved in cell migration, well documented in normal and cancer cells. In this work we presented evidences supporting the hypothesis that ENaC channels are required for the migration of BeWo cells, a human hormone-synthesizing trophoblastic cell line that express the three subunits of the ENaC channels. BeWo cell line has also been used as a model to investigate the placental transport mechanisms.

Preeclampsia, migración celular y canales iónicos / Preeclampsia, cellular migration and ion channels

En la placenta humana, el sinciciotrofoblasto es la barrera que regula el transporte de nutrientes, solutos y agua entre la sangre materna y fetal. Dentro de este movimiento transepitelial se encuentra el del Na+, su contribución a la presión osmótica es fundamental en la regulación del volumen de líquido extracelular. El canal epitelial de sodio sensible al amiloride (ENaC) media el transporte de Na+ desde el lumen hacia el interior celular en numerosos epitelios absortivos. Está regulado por la aldosterona, vasopresina, catecolaminas, estrógenos y progesterona. Es bloqueado por el amiloride y sus análogos. Para su activación, diversas proteasas lo escinden en la membrana plasmática y esto a su vez es regulado por la aldosterona. El ENaC está expresado también en la placenta humana y aunque su función no es conocida, podría participar en la homeostasis de agua y electrolitos. El ENaC también es influenciado por el estado de las proteínas del citoesqueleto y los cambios en el volumen celular alteran a su vez a éste. De esta manera existe una relación entre el ENaC y el citoesqueleto. Además, las corrientes de Na+ por el ENaC y otros canales de sodio participan en la migración celular en células normales y cancerosas. Aquí presentamos evidencias que avalan la hipótesis que el ENaC es necesario para la migración celular en células BeWo, derivadas del trofoblasto humano, que sintetizan hormonas y expresan el ENaC. Las células BeWO han sido utilizadas como modelo experimental para estudiar el transporte en células de placenta.

The syncytiotrophoblast acts in human placenta as a transporting barrier regulating the transference of nutrients, solutes and water between maternal and fetal blood. This transepithelial transport involves movement of Na+ and its contribution to the osmotic pressure is an important determinant of the extracellular fluid volume. ENaC is a channel that mediates entry of Na+ from the luminal fluid into the cells in many reabsorbing epithelia; it is aldosterone, vasopressin, insulin and catecholamine-inducible, modulated by estrogens and progesterone and blocked by amiloride and its analogs. Multiple proteases are involved in the proteolytic processing and activation of ENaC subunits and aldosterone alters the protease-protease inhibitors balance. ENaC is also expressed in human placenta; although its function is not well known, the Na+ conductive properties may participate in electrolyte and extracellular volume homeostasis. The activity of ENaC channels and other ion channels and transporters is regulated by the state of actin filaments; on the other hand, changes in volume influence the actin cytoskeleton. Thus, there is an interaction between ENaC and components of the apical membrane cytoskeleton. In addition to their role in cellular homeostasis and electrical properties, Na+ currents through ENaC and other sodium channels are involved in cell migration, well documented in normal and cancer cells. In this work we presented evidences supporting the hypothesis that ENaC channels are required for the migration of BeWo cells, a human hormone-synthesizing trophoblastic cell line that express the three subunits of the ENaC channels. BeWo cell line has also been used as a model to investigate the placental transport mechanisms.

Epithelial sodium channel in a human trophoblast cell line (BeWo).

The present study was performed to assay sodium currents in BeWo cells. These cells comprise a human trophoblast cell line which displays many of the biochemical and morphological properties similar to those reported for the in uterus proliferative cytotrophoblast. For whole-cell patch-clamp experiments, BeWo cells treated for 12 h with 100 nM aldosterone were exposed to 8Br-cAMP, a membrane-permeable cAMP analogue, to induce channel activity. Cells showed an amiloride-sensitive ion current (IC50 of 5.77 microM). Ion substitution experiments showed that the amiloride-sensitive current carried cations with a permeability rank order of Li+ > Na+ > K+ > NMDG (PLi/PNa = 1.3, PK/PNa = 0.6, PNMDG/PNa = 0.2). In cells pretreated with aldosterone, we observed that nearly half of successful patches had sodium channels with a linear conductance of 6.4 +/- 1.8 pS, a low voltage-independent Po and a PK/PNa of 0.19. Using RT-PCR, we determined that control cells express the alpha-, but not beta- and gamma-, epithelial sodium channel (ENaC) mRNA. When cells were treated with aldosterone (100 nM, 12 h), all alpha-, beta- and gamma-ENaC mRNAs were detected. The presence of ENaC subunit proteins in these cells was confirmed by Western blot analysis and immunolocalization with specific ENaC primary antibodies. In summary, our results suggest that BeWo cells express ENaC subunits and that aldosterone was able to modulate a selective response by generating amiloride-sensitive sodium currents similar to those observed in other human tissues.

HERG1 currents in native K562 leukemic cells.

The human ether-a-go-go related gene (HERG1) K+ channel is expressed in neoplastic cells, in which it was proposed to play a role in proliferation, differentiation and/or apoptosis. K562 cells (a chronic myeloid leukemic human cell line) express both the full-length (herg1a) and the N-terminally truncated (herg1b) isoforms of the gene, and this was confirmed with Western blots and coimmunoprecipitation experiments. Whole-cell currents were studied with a tail protocol. Seventy-eight percent of cells showed a HERG1-like current: repolarization to voltages negative to -40 mV produced a transient peak inward tail current, characteristic of HERG1 channels. Cells were exposed to a HERG-specific channel blocker, E4031. Half-maximal inhibitory concentration (IC50) of the blocker was 4.69 nM: The kinetics of the HERG1 current in K562 cells resembled the rapid component of the native cardiac delayed rectifier current, known to be conducted by heterotetrameric HERG1 channels. Fast and slow deactivation time constants at -120 mV were 27.5 and 239.5 ms, respectively. Our results in K562 cells suggest the assembling of heterotetrameric channels, with some parameters being dominated by one of the isoforms and other parameters being intermediate. Hydrogen peroxide was shown to increase HERG1a K+ current in heterologous expression systems, which constitutes an apoptotic signal. However, we found that K562 HERG1 whole-cell currents were not activated by H2O2.

[Characterization of the epithelial sodium channel in human pre-eclampsia syncytiotrophoblast]. / Caracterizacion del canal epitelial de sodio en sinciciotrofoblasto de placenta humana preeclamptica.

The syncytiotrophoblast (SCT), a multinucleated epithelium forming the outer layer of chorionic villi, acts in human placenta as a transporting barrier regulating the transference of nutrients, solutes and water between maternal and fetal blood. Electrolyte homeostasis and extracellular fluid volume are maintained primarily by regulated Na+ transport. The present study was conducted to analyze the presence of the epithelial Na channel (ENaC) in placental tissue from normal and pre-eclamptic women and in BeWo cell, a model of a human SCT. Changes in the expression of these proteins during sodium transport across the placenta may be related to the pathogeny of pre-eclampsia. The role that ENaC and Na+ transport deregulation play on human placental tissues still remains unknown although in aldosterone-responsive epithelial cells (kidney, colon), abnormalities upregulating its activity lead to increased Na+ uptake and hypertension (i.e. Liddle's syndrome) whereas a diminished channel activity can result in the pseudohypoaldosteronisn syndrome with salt loss and hypotension. Our results show that ENaC is expressed in the apical membrane of normal syncytiotrophoblast. The amplified fragment of alpha-ENaC was cloned and sequenced having a 100% identity with the sequence of (alpha-ENaC obtained from GenBank (SCNN1A, accession number Z92981). We found that the transcription of the alpha-ENaC mRNA was not detectable in preeclamptic placentas and the protein was not observed with immunohistochemistry staining, probably indicating a low protein expression level. In BeWo cells ENac was found and its expression is regulated by aldosterone, vasopressin, progesterone and estradiol. With patch clamp techniques we studied the currents trough ENaO channels in Bewo cells. We observed currents that were blocked by 10 microM amiloride in cells incubated in 100 nM aldosterone for 12 hs. The amplitude of this current was 20-fold the basal current, a reversal potential of 3 mV and a conductance of 127 +/- 26 pS/pF with pulses between -60 and -140 mV. These characteristics are similar to those reported in ENaC channels in several tissues. Although their roles in placenta are still poorly understood, the differences in the expression of ENaC in pre-eclamptic placentas may have consequences for ion transport and these data could lead to future studies concerning the mechanism involved in the pathophysiology of pre-eclampsia.

Caracterizacion del canal epitelial de sodio en sinciciotrofoblasto de placenta humana preeclamptica / Characterization of the epithelial sodium channel in human pre-eclampsia syncytiotrophoblast

El sinciciotrofoblasto (SCT) de placenta humana regula la transferencia de solutos y agua entre la sangre fetal y materna. En el presente trabajo observamos que el canal de sodio ENaC (asociado a cuadros como el síndrome de Liddle y pseudohipoaldosteronismo) está presente en la membrana apical del SCT y que la subunidad del canal tiene una expresión reducida en placentas con hipertensión gestacional (preeclampsia). Realizamos estudios a nivel de expresión de ARN (RT-PCR) y a nivel proteico (western blot e inmunohistoquímica). En la línea celular BeWo (modelo de SCT humano) el canal se encuentra presente y la expresión del mismo es regulada por las hormonas aldosterona, vasopresina, estradiol y progesterona. Analizamos la actividad del ENaC por electrofisiología y observamos corrientes sensibles a amiloride (10 μM) cuando las células BeWo se cultivaron 12 horas con aldosterona (100 nM). Esta corriente presentó una magnitud 20 veces mayor que las corrientes basales, un potencial de reversión cercano a 3 mV y una conductancia de 127 ± 26 pS/ pF entre los pulsos de ¹60 y ¹140 mV aplicados. Las características de esta corriente son similares a las producidas por ENaC en otros tejidos y evidencian la presencia de un canal funcional. El papel del ENaC en el SCT es poco comprendido, aunque la diferencia de expresión en la preeclampsia podría tener consecuencias para el transporteplacentario de agua y iones. Nuestros datos son un aporte para futuros estudios de los mecanismos involucrados en la patofisiología de la preeclampsia. (AU)

Caracterizacion del canal epitelial de sodio en sinciciotrofoblasto de placenta humana preeclamptica / Characterization of the epithelial sodium channel in human pre-eclampsia syncytiotrophoblast

El sinciciotrofoblasto (SCT) de placenta humana regula la transferencia de solutos y agua entre la sangre fetal y materna. En el presente trabajo observamos que el canal de sodio ENaC (asociado a cuadros como el síndrome de Liddle y pseudohipoaldosteronismo) está presente en la membrana apical del SCT y que la subunidad del canal tiene una expresión reducida en placentas con hipertensión gestacional (preeclampsia). Realizamos estudios a nivel de expresión de ARN (RT-PCR) y a nivel proteico (western blot e inmunohistoquímica). En la línea celular BeWo (modelo de SCT humano) el canal se encuentra presente y la expresión del mismo es regulada por las hormonas aldosterona, vasopresina, estradiol y progesterona. Analizamos la actividad del ENaC por electrofisiología y observamos corrientes sensibles a amiloride (10 μM) cuando las células BeWo se cultivaron 12 horas con aldosterona (100 nM). Esta corriente presentó una magnitud 20 veces mayor que las corrientes basales, un potencial de reversión cercano a 3 mV y una conductancia de 127 ± 26 pS/ pF entre los pulsos de ¹60 y ¹140 mV aplicados. Las características de esta corriente son similares a las producidas por ENaC en otros tejidos y evidencian la presencia de un canal funcional. El papel del ENaC en el SCT es poco comprendido, aunque la diferencia de expresión en la preeclampsia podría tener consecuencias para el transporteplacentario de agua y iones. Nuestros datos son un aporte para futuros estudios de los mecanismos involucrados en la patofisiología de la preeclampsia. (AU)

Caracterizacion del canal epitelial de sodio en sinciciotrofoblasto de placenta humana preeclamptica / Characterization of the epithelial sodium channel in human pre-eclampsia syncytiotrophoblast

El sinciciotrofoblasto (SCT) de placenta humana regula la transferencia de solutos y agua entre la sangre fetal y materna. En el presente trabajo observamos que el canal de sodio ENaC (asociado a cuadros como el síndrome de Liddle y pseudohipoaldosteronismo) está presente en la membrana apical del SCT y que la subunidad del canal tiene una expresión reducida en placentas con hipertensión gestacional (preeclampsia). Realizamos estudios a nivel de expresión de ARN (RT-PCR) y a nivel proteico (western blot e inmunohistoquímica). En la línea celular BeWo (modelo de SCT humano) el canal se encuentra presente y la expresión del mismo es regulada por las hormonas aldosterona, vasopresina, estradiol y progesterona. Analizamos la actividad del ENaC por electrofisiología y observamos corrientes sensibles a amiloride (10 μM) cuando las células BeWo se cultivaron 12 horas con aldosterona (100 nM). Esta corriente presentó una magnitud 20 veces mayor que las corrientes basales, un potencial de reversión cercano a 3 mV y una conductancia de 127 ± 26 pS/ pF entre los pulsos de –60 y –140 mV aplicados. Las características de esta corriente son similares a las producidas por ENaC en otros tejidos y evidencian la presencia de un canal funcional. El papel del ENaC en el SCT es poco comprendido, aunque la diferencia de expresión en la preeclampsia podría tener consecuencias para el transporteplacentario de agua y iones. Nuestros datos son un aporte para futuros estudios de los mecanismos involucrados en la patofisiología de la preeclampsia.

Selective antimicrobial activity of chitosan on beer spoilage bacteria and brewing yeasts.

Chitosan (0.1 g l(-1)), assayed in a simple medium, reduced the viability of four lactic acid bacteria isolated during the beer production process by 5 logarithmic cycles, whereas activity against seven commercial brewing yeasts required up to 1 g chitosan l(-1). Antimicrobial activity was inversely affected by the pH of the assay medium. In brewery wort, chitosan (0.1 g l(-1)) selectively inhibited bacterial growth without altering yeast viability or fermenting performance.