Esperanza Recio-Pinto, Ph.D.

The N-methyl-d-aspartate-evoked cytoplasmic calcium increase in adult rat dorsal root ganglion neuronal somata was potentiated by substance P pretreatment in a protein kinase C-dependent manner
Castillo C; Norcini M; Baquero-Buitrago J; Levacic D; Medina R; Montoya-Gacharna JV; Blanck TJ; Dubois M; Recio-Pinto E
2011 Mar 17;177:308-320, Neuroscience
The involvement of substance P (SP) in neuronal sensitization through the activation of the neurokinin-1-receptor (NK1r) in postsynaptic dorsal horn neurons has been well established. In contrast, the role of SP and NK1r in primary sensory dorsal root ganglion (DRG) neurons, in particular in the soma, is not well understood. In this study, we evaluated whether SP modulated the NMDA-evoked transient increase in cytoplasmic Ca(2+) ([Ca(2+)](cyt)) in the soma of dissociated adult DRG neurons. Cultures were treated with nerve growth factor (NGF), prostaglandin E(2) (PGE(2)) or both NGF+PGE(2). Treatment with NGF+PGE(2) increased the percentage of N-methyl-d-aspartate (NMDA) responsive neurons. There was no correlation between the percentage of NMDA responsive neurons and the level of expression of the NR1 and NR2B subunits of the NMDA receptor or of the NK1r. Pretreatment with SP did not alter the percentage of NMDA responsive neurons; while it potentiated the NMDA-evoked [Ca(2+)](cyt) transient by increasing its magnitude and by prolonging the period during which small- and some medium-sized neurons remained NMDA responsive. The SP-mediated potentiation was blocked by the SP-antagonist ([D-Pro(4), D-Trp(7,9)]-SP (4-11)) and by the protein kinase C (PKC) blocker bisindolylmaleimide I (BIM); and correlated with the phosphorylation of PKCepsilon. The Nk1r agonist [Sar(9), Met(O(2))(11)]-SP (SarMet-SP) also potentiated the NMDA-evoked [Ca(2+)](cyt) transient. Exposure to SP or SarMet-SP produced a rapid increase in the labeling of phosphorylated-PKCepsilon. In none of the conditions we detected phosphorylation of the NR2B subunit at Ser-1303. Phosphorylation of the NR2B subunit at Tyr1472 was enhanced to a similar extent in cells exposed to NMDA, SP or NMDA+SP, and that enhancement was blocked by BIM. Our findings suggest that NGF and PGE(2) may contribute to the injury-evoked sensitization of DRG neurons in part by enhancing their NMDA-evoked [Ca(2+)](cyt) transient in all sized DRG neurons; and that SP may further contribute to the DRG sensitization by enhancing and prolonging the NMDA-evoked increase in [Ca(2+)](cyt) in small- and medium-sized DRG neurons
— id: 121314, year: 2011, vol: 177, page: 308, stat: Journal Article,

DmSAS Is Required for Sialic Acid Biosynthesis in Cultured Drosophila Third Instar Larvae CNS neurons
Granell, Annelise E von Bergen; Palter, Karen B; Akan, Ihan; Aich, Udayanath; Yarema, Kevin J; Betenbaugh, Michael J; Thornhill, William B; Recio-Pinto, Esperanza
2011 Nov 18;6(11):1287-1295, ACS chemical biology
Sialylation is an important carbohydrate modification of glycoconjugates that has been shown to modulate many cellular/molecular interactions in vertebrates. In Drosophila melanogaster (Dm), using sequence homology, several enzymes of the sialylation pathway have been cloned and their function tested in expression systems. Here we investigated whether sialic acid incorporation in cultured Dm central nervous system (CNS) neurons required endogenously expressed Dm sialic acid synthase (DmSAS). We compared neurons derived from wild type Dm larvae with those containing a DmSAS mutation (148 bp deletion). The ability of these cells to produce Sia5NAz (sialic acid form) from Ac(4)ManNAz (azide-derivatized N-acetylmannosamine) and incorporate it into their glycoconjugates was measured by tagging the azide group of Sia5NAz with fluorescent agents via Click-iT chemistry. We found that most of the wild type Dm CNS neurons incorporated Sia5NAz into their glycoconjugates. Sialic acid incorporation was higher at the soma than at the neurite and could also be detected at perinuclear regions and the plasma membrane. In contrast, neurons from the DmSAS mutant did not incorporate Sia5NAz unless DmSAS was reintroduced (rescue mutant). Most of the neurons expressed alpha2,6-sialyltransferase. These results confirm that the mutation was a null mutation and that no redundant sialic acid biosynthetic activity exists in Dm cells, i.e., there is only one DmSAS. They also provide the strongest proof to date that DmSAS is a key enzyme in the biosynthesis of sialic acids in Dm CNS neurons, and the observed subcellular distribution of the newly synthesized sialic acids offers insights into their biological function
— id: 141694, year: 2011, vol: 6, page: 1287, stat: Journal Article,

Muscle-conditioned media and cAMP promote survival and neurite outgrowth of adult spinal cord motor neurons
Montoya G, Jose V; Sutachan, Jhon Jairo; Chan, Wai Si; Sideris, Alexandra; Blanck, Thomas J J; Recio-Pinto, Esperanza
2009 Dec;220(2):303-315, Experimental neurology
Embryonic spinal cord motor neurons (MNs) can be maintained in vitro for weeks with a cocktail of trophic factors and muscle-derived factors under serum-containing conditions. Here we investigated the beneficial effects of muscle-derived factors in the form of muscle-conditioned medium (MCM) on the survival and neurite outgrowth of adult rat spinal cord MNs under serum-free conditions. Ventral horn dissociated cell cultures from the cervical enlargement were maintained in the presence of one or more of the following factors: brain-derived neurotrophic factor (BDNF), glial cell-derived neurotrophic factor (GDNF), a cell permeant cyclic adenosine-3',5'-monophosphate (cAMP) analog and MCM. The cell cultures were immunostained with several antibodies recognizing a general neuronal marker the microtubule-associated protein 2 (MAP2) and either one or more motor neuronal markers: the non-phosphorylated neurofilament heavy isoform (SMI32), the transcription factors HB9 and Islet-1 and the choline acetyl transferase. We found that treatment with MCM together with the cAMP analog was sufficient to promote selective survival and neurite outgrowth of adult spinal cord MNs. These conditions can be used to maintain adult spinal cord MNs in dissociated cultures for several weeks and may have therapeutic potential following spinal cord injury or motor neuropathies. More studies are necessary to evaluate how MCM and the cAMP analog act in synergy to promote the survival and neurite outgrowth of adult MNs
— id: 102940, year: 2009, vol: 220, page: 303, stat: Journal Article,

Cytotoxicity of local anesthetics in human neuronal cells
Perez-Castro, Rosalia; Patel, Sohin; Garavito-Aguilar, Zayra V; Rosenberg, Andrew; Recio-Pinto, Esperanza; Zhang, Jin; Blanck, Thomas J J; Xu, Fang
2009 Mar;108(3):997-1007, Anesthesia & analgesia
BACKGROUND: In addition to inhibiting the excitation conduction process in peripheral nerves, local anesthetics (LAs) cause toxic effects on the central nervous system, cardiovascular system, neuromuscular junction, and cell metabolism. Different postoperative neurological complications are ascribed to the cytotoxicity of LAs, but the underlying mechanisms remain unclear. Because the clinical concentrations of LAs far exceed their EC(50) for inhibiting ion channel activity, ion channel block alone might not be sufficient to explain LA-induced cell death. However, it may contribute to cell death in combination with other actions. In this study, we compared the cytotoxicity of six frequently used LAs and will discuss the possible mechanism(s) underlying their toxicity. METHODS: In human SH-SY5Y neuroblastoma cells, viability upon exposure to six LAs (bupivacaine, ropivacaine, mepivacaine, lidocaine, procaine, and chloroprocaine) was quantitatively determined by the MTT-(3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetra-odium bromide) colorimetry assay and qualitatively confirmed by fluorescence imaging, using the LIVE/DEAD assay reagents (calcein/AM and ethidium homodimer-1). In addition, apoptotic activity was assessed by measuring the activation of caspase-3/-7 by imaging using a fluorescent caspase inhibitor (FLICA). Furthermore, LA effects on depolarization- and carbachol-stimulated intracellular Ca(2+)-responses were also evaluated. RESULTS: 1) After a 10-min treatment, all six LAs decreased cell viability in a concentration-dependent fashion. Their killing potency was procaine < or = mepivacaine < lidocaine < chloroprocaine < ropivacaine < bupivacaine (based on LD(50), the concentration at which 50% of cells were dead). Among these six LAs, only bupivacaine and lidocaine killed all cells with increasing concentration. 2) Both bupivacaine and lidocaine activated caspase-3/-7. Caspase activation required higher levels of lidocaine than bupivacaine. Moreover, the caspase activation by bupivacaine was slower than by lidocaine. Lidocaine at high concentrations caused an immediate caspase activation, but did not cause significant caspase activation at concentrations lower than 10 mM. 3) Procaine and chloroprocaine concentration-dependently inhibited the cytosolic Ca(2+)-response evoked by depolarization or receptor-activation in a similar manner as a previous observation made with bupivacaine, ropivacaine, mepivacaine, and lidocaine. None of the LAs caused a significant increase in the basal and Ca(2+)-evoked cytosolic Ca(2+)-level. CONCLUSION: LAs can cause rapid cell death, which is primarily due to necrosis. Lidocaine and bupivacaine can trigger apoptosis with either increased time of exposure or increased concentration. These effects might be related to postoperative neurologic injury. Lidocaine, linked to the highest incidence of transient neurological symptoms, was not the most toxic LA, whereas bupivacaine, a drug causing a very low incidence of transient neurological symptoms, was the most toxic LA in our cell model. This suggests that cytotoxicity-induced nerve injury might have different mechanisms for different LAs and different target(s) other than neurons
— id: 94380, year: 2009, vol: 108, page: 997, stat: Journal Article,

Isoflurane inhibits cyclic adenosine monophosphate response element-binding protein phosphorylation and calmodulin translocation to the nucleus of SH-SY5Y cells
Zhang, Jin; Sutachan, Jhon-Jairo; Montoya-Gacharna, Jose; Xu, Chong-Feng; Xu, Fang; Neubert, Thomas A; Recio-Pinto, Esperanza; Blanck, Thomas J J
2009 Oct;109(4):1127-1134, Anesthesia & analgesia
BACKGROUND: Calmodulin (CaM) activation by Ca(2+), its translocation to the nucleus, and stimulation of phosphorylation of cyclic adenosine monophosphate response element-binding protein (CREB) (P-CREB) are necessary for new gene expression and have been linked to long-term potentiation, a process important in memory formation. Because isoflurane affects memory, we tested whether isoflurane interfered with the translocation of CaM to the neuronal cell nucleus and attenuated the formation P-CREB. METHODS: SH-SY5Y cells, a human neuroblastoma cell line, were cultured. Cells were depolarized with KCl and the phosphorylation of CREB examined by Western blotting, enzyme-linked immunosorbant assay, and immunocytochemistry. The translocation of CaM from the cytosol to the nucleus was also examined after depolarization. Cells were depolarized and lysed and fractionated by centrifugation to determine the amount of CaM translocated to the nucleus. CaM was localized by immunocytochemistry and quantitated by Western blotting and imaging. Before and during KCl depolarization, cells were exposed to isoflurane, isoflurane plus Bay K 8644, nitrendipine, and omega-conotoxin GVIa, respectively. RESULTS: P-CREB increased after KCl depolarization. The increase of P-CREB peaked at depolarization duration of 30 s. The increase in P-CREB formation was inhibited by nitrendipine, but not omega-conotoxin, and by isoflurane in a concentration-dependent fashion. Pretreatment with the L-type Ca(2+) channel agonist, Bay K 8644, attenuated the inhibition of P-CREB formation by isoflurane. CaM presence in the nucleus occurred after KCl depolarization. CaM translocation was inhibited by nitrendipine and attenuated by isoflurane. Bay K 8644 pretreatment decreased the isoflurane inhibition of CaM translocation to the nucleus. CONCLUSIONS: Our data demonstrate that isoflurane inhibits CaM translocation and P-CREB formation. This most likely occurs through isoflurane inhibition of Ca(2+)entry through L-type Ca(2+) channels
— id: 102500, year: 2009, vol: 109, page: 1127, stat: Journal Article,

The Kv1.2 potassium channel: the position of an N-glycan on the extracellular linkers affects its protein expression and function
Zhu, Jing; Recio-Pinto, Esperanza; Hartwig, Torsten; Sellers, Will; Yan, Jingyi; Thornhill, William B
2009 Jan 28;1251:16-29, Brain research
Voltage-gated potassium Kv1 channels have three extracellular linkers, the S1-S2, the S3-S4, and the S5-P. The S1-S2 is the only linker that has an N-glycan and it is at a conserved position on this linker on Kv1.1-Kv1.5 and Kv1.7 channels. We hypothesize that an N-glycan is found at only this position due to its effect on folding, trafficking, and/or function of these channels. To investigate this hypothesis, N-glycosylation sites were engineered at different positions on the extracellular linkers of Kv1.2 to determine the effects of N-glycans on channel surface protein expression and function. Our data suggest that for Kv1 channels, (1) placing an N-glycan at non-native positions on the S1-S2 linker decreased cell surface protein expression but the N-glycan still affected function similarly as if it were at its native position, (2) placing a non-native N-glycan on the S3-S4 linker significantly altered function, and (3) placing a non-native N-glycan on the S5-P linker disrupted both trafficking and function. We suggest that Kv1 channels have an N-glycan at a conserved position on only the S1-S2 linker to overcome the constraints for proper folding, trafficking, and function that appear to occur if the N-glycan is moved from this position
— id: 94381, year: 2009, vol: 1251, page: 16, stat: Journal Article,

Pulses of extracellular K+ produce two cytosolic Ca2+ transients that display different temperature dependence and carbonyl cyanide m-chlorophenyl sensitivity in SH-SY5Y cells
Montoya G, Jose V; Sutachan, Jhon-Jairo; Corrales, Alexandra; Xu, Fang; Blanck, Thomas J J; Recio-Pinto, Esperanza
2008 Jun 5;1213:12-26, Brain research
In SH-SY5Y cells we have shown that stimulation with high extracellular K+ ([K+]e) evokes a transient increase in cytoplasmic Ca2+ ([Ca2+]cyt) (K+on) that is triggered by the opening of voltage-dependent Ca2+ channels and followed by Ca2+ -induced Ca2+ release from the endoplasmic reticulum (Xu, F., Zhang, J., Recio-Pinto, E. and Blanck, T.J., Halothane and isoflurane augment depolarization-induced cytosolic CA2+ transients and attenuate carbachol-stimulated CA2+ transients, Anesthesiology, 92 (2000) 1746-56). The removal of high-[K+]e results in a second transient increase in [Ca2+]cyt (K+off) that is independent of extracellular Ca2+ (Corrales, A., Montoya, G.J., Sutachan, J.J., Cornillez-Ty, G., Garavito-Aguilar, Z., Xu, F., Blanck, T.J. and Recio-Pinto, E., Transient increases in extracellular K+ produce two pharmacological distinct cytosolic Ca2+ transients, Brain Res., 1031 (2005) 174-184). In this study we further characterize the properties of K+off. We found that K+off was detectable at near physiological temperatures (34-36 degrees C) but, depending on the level of [K+]e, it was undetectable or highly diminished at room temperature. In contrast, K+on was increased by lowering the temperature. Extracellular Na+ -replacement with K+ did not affect K+off, indicating that K+off was not generated by osmolarity changes. Replacement of extracellular Na+ with choline+ did not affect K+off, indicating that K+off did not result from activity changes of the plasma membrane Na+/Ca2+ exchanger. Caffeine decreased K+on but not K+off. CCCP (carbonyl cyanide m-chlorophenyl), a protonophore uncoupler that decreases mitochondrial Ca2+ uptake, decreased K+on but not K+off. CGP37157, an inhibitor of the mitochondria Na+/Ca2+ exchanger, decreased K+off when added alone but not when added simultaneously with CCCP. Clonazepam had similar effects as CGP37157. These findings indicate that the generation of K+off is strongly temperature-dependent and its pharmacology is distinct from the [Ca2+]cyt changes observed previously at room temperature
— id: 86543, year: 2008, vol: 1213, page: 12, stat: Journal Article,

The glycosylation state of Kv1.2 potassium channels affects trafficking, gating, and simulated action potentials
Watanabe, Itaru; Zhu, Jing; Sutachan, Jhon J; Gottschalk, Allan; Recio-Pinto, Esperanza; Thornhill, William B
2007 May 4;1144:1-18, Brain research
We presented evidence previously that decreasing the glycosylation state of the Kv1.1 potassium channel modified its gating by a combined surface potential and a cooperative subunit interaction mechanism and these effects modified simulated action potentials. Here we continued to test the hypothesis that glycosylation affects channel function in a predictable fashion by increasing and decreasing the glycosylation state of Kv1.2 channels. Compared with Kv1.2, increasing the glycosylation state shifted the V(1/2) negatively with a steeper G-V slope, increased activation kinetics with little change in deactivation kinetics or in their voltage-dependence, and decreased the apparent level of C-type inactivation. Decreasing the glycosylation state had essentially the opposite effects and shifted the V(1/2) positively with a shallower G-V slope, decreased activation kinetics (and voltage-dependence), decreased deactivation kinetics, and increased the apparent level of C-type inactivation. Single channel conductance was not affected by the different glycosylation states of Kv1.2 tested here. Hyperpolarized or depolarized shifts in V(1/2) from wild type were apparently due to an increased or decreased level of channel sialylation, respectively. Data and modeling suggested that the changes in activation properties were mostly predictable within and between channels and were consistent with a surface potential mechanism, but those on deactivation properties were not predictable and were more consistent with a conformational mechanism. Moreover the effect on the deactivation process appeared to be channel-type dependent as well as glycosylation-site dependent. The glycosylation state of Kv1.2 also affected action potentials in simulations. In addition, preventing N-glycosylation decreased cell surface Kv1.2 expression levels by approximately 40% primarily by increasing partial endoplasmic reticulum retention and this effect was completely rescued by Kv1.4 subunits, which are glycosylated, but not by cytoplasmic Kvbeta2.1 subunits. The nonglycosylated Kv1.2 protein had a similar protein half-life as the glycosylated protein and appeared to be folded properly. Thus altering the native Kv1.2 glycosylation state affected its trafficking, gating, and simulated action potentials. Differential glycosylation of ion channels could be used by excitable cells to modify cell signaling
— id: 94382, year: 2007, vol: 1144, page: 1, stat: Journal Article,

Pluronic F-127 affects the regulation of cytoplasmic Ca2+ in neuronal cells
Sutachan, Jhon-Jairo; Montoya G, Jose V; Xu, Fang; Chen, Daniel; Blanck, Thomas J J; Recio-Pinto, Esperanza
2006 Jan 12;1068(1):131-137, Brain research
Fura-2 is one of the most widely used cytoplasmic Ca2+ ([Ca2+]cyt) sensors. In studies using isolated dorsal root ganglion (DRG) neurons, the loading of Fura-2 AM is often facilitated by the use of pluronic F-127. In preliminary studies, we detected that the use of pluronic F-127 appeared to be affecting the depolarization-evoked [Ca2+]cyt transient in DRG neurons. To determine whether this was the case, we conducted a systematic study. Adult rat DRG neurons were cultured, and their response to 50 mM KCl was measured in sister cultured cells (isolated on the same day) that were loaded with 5 microM Fura-2AM in the absence or in the presence of 0.02% pluronic F-127. In the absence of pluronic F-127, the KCl-evoked [Ca2+]cyt transient changed with time, being wider on day 1 than on day 2 after plating. On day 2, the KCl-evoked [Ca2+]cyt transient was wider in neurons Fura-2 loaded in the presence of pluronic F-127. These results indicate that pluronic F-127 significantly alters depolarization-evoked [Ca2+]cyt transients, which may reflect alteration in regulation of [Ca2+]cyt in neuronal cells
— id: 63600, year: 2006, vol: 1068, page: 131, stat: Journal Article,

Transient increases in extracellular K+ produce two pharmacological distinct cytosolic Ca2+ transients
Corrales, Alexandra; Montoya G, Jose V; Sutachan, Jhon-Jairo; Cornillez-Ty, Genoveve; Garavito-Aguilar, Zayra; Xu, Fang; Blanck, Thomas J J; Recio-Pinto, Esperanza
2005 Jan 21;1031(2):174-184, Brain research
Transient increases in extracellular K+ are observed under various conditions, including repetitive neuronal firing, anoxia, ischemia and hypoglycemic coma. We studied changes in cytoplasmic Ca2+ ([Ca2+]cyt) evoked by pulses of KCl in human neuroblastoma SH-SY5Y cells and rat dorsal root ganglia (DRG) neurons at 37 degrees C. A 'pulse' of KCl evoked two transient increases in [Ca2+]cyt, one upon addition of KCl (K+on) and the other upon removal of KCl (K+off). The K+on transient has been described in many cell types and is initiated by the activation of voltage-dependent Ca2+ channels followed by Ca2+-evoked Ca2+ release from intracellular Ca2+ stores. The level of KCl necessary to evoke the K+off transient depends on the type of neuron, in SH-SY5Y cells it required 100 mM KCl, in most (but not all) of dorsal root ganglia neurons it could be detected with 100-200 mM KCl and in a very few dorsal root ganglia neurons it was detectable at 20-50 mM KCl. In SH-SY5Y cells, reduction of extracellular Ca2+ inhibited the K+on more strongly than the K+off and slowed the decay of K+off. Isoflurane (1 mM) reduced the K+on)- but not the K+off-peak. However, isoflurane slowed the decay of K+off. The nonspecific cationic channel blocker La3+ (100 microM) had an effect similar to that of isoflurane. Treatment with thapsigargin (TG) at a concentration known to only deplete IP3-sensitive Ca2+ stores did not affect K+on or K+off, suggesting that Ca2+ release from the IP3-sensitive Ca2+ stores does not contribute to K+on and K+off transients and that the thapsigargin-sensitive Ca2+ ATPases do not contribute significantly to the rise or decay rates of these transients. These findings indicate that a pulse of extracellular K+ produces two distinct transient increases in [Ca2+]cyt
— id: 56139, year: 2005, vol: 1031, page: 174, stat: Journal Article,

Trypanosome lytic factor, a subclass of high-density lipoprotein, forms cation-selective pores in membranes
Molina-Portela, Maria del Pilar; Lugli, Elena B; Recio-Pinto, Esperanza; Raper, Jayne
2005 Dec;144(2):218-226, Molecular & biochemical parasitology
Trypanosome lytic factor 1 (TLF1) is a subclass of human high-density lipoprotein that kills some African trypanosomes thereby protecting humans from infection. We have shown that TLF1 is a 500 kDa HDL complex composed of lipids and at least seven different proteins. Here we present evidence outlining a new paradigm for the mechanism of lysis; TLF1 forms cation-selective pores in membranes. We show that the replacement of external Na+ (23 Da) with the larger tetramethylammonium+, choline+ and tetraethylammonium+ ions (74 Da, 104 Da and 130 Da) ameliorates the osmotically driven swelling and lysis of trypanosomes by TLF1. Confirmation of cation pore-formation was obtained using small unilamellar vesicles incubated with TLF1; these showed the predicted change in membrane potential expected from an influx of sodium ions. Using planar lipid bilayer model membranes made from trypanosome lipids, which allow the detection of single channels, we found that TLF1 forms discrete ion-conducting channels (17 pS) that are selective for potassium ions over chloride ions. We propose that the initial influx of extracellular Na+ down its concentration gradient promotes the passive entry of Cl- through preexisting Cl- channels. The net influx of both Na+ and Cl- create an osmotic imbalance that leads to passive water diffusion. This loss of osmoregulation results in cytoplasmic vacuolization, cell swelling and ultimately trypanosome lysis
— id: 62362, year: 2005, vol: 144, page: 218, stat: Journal Article,

Effects of Kv1.1 channel glycosylation on C-type inactivation and simulated action potentials
Sutachan, Jhon J; Watanabe, Itaru; Zhu, Jing; Gottschalk, Allan; Recio-Pinto, Esperanza; Thornhill, William B
2005 Oct 5;1058(1-2):30-43, Brain research
Kv1.1 channels are brain glycoproteins that play an important role in repolarization of action potentials. In previous work, we showed that lack of N-glycosylation, particularly lack of sialylation, of Kv1.1 affected its macroscopic gating properties and slowed activation and C-type inactivation kinetics and produced a depolarized shift in the steady-state activation curve. In our current study, we used single channel analysis to investigate voltage-independent C-type inactivation in both Kv1.1 and Kv1.1N207Q, a glycosylation mutant. Both channels underwent brief and long-lived closures, and the lifetime and frequency of the long-lived closed states were voltage-independent and similar for both channels. We found that, as in macroscopic measurements, Kv1.1N207Q exhibited a approximately 8 mV positive shift in its single channel fractional open time (fo) and a shallower fo-voltage slope compared with Kv1.1. Data suggested that C-type inactivation reflected the equilibration time with at least two slow voltage-independent long-lived closed states that followed the rapid activation process. In addition, data simulation indicated that the C-type inactivation process reflected the equilibration time between the open state and at least two long-lived closed states. Moreover, the faster macroscopic current decay in Kv1.1 mostly reflected a slower equilibration time in these channels as compared with Kv1.1N207Q. Finally, action potential simulations indicated that the N207Q mutation broaden the action potential and decreased the interspike interval. The shape of the action potential was not significantly affected by C-type inactivation, however, for a given channel, C-type inactivation increased the interspike interval. Data and simulations suggested that excitable cells could use differences in K(+) channel glycosylation degree as an additional mechanism to increase channel functional diversity which could modify cell excitability
— id: 94383, year: 2005, vol: 1058, page: 30, stat: Journal Article,

Isoflurane reduces the carbachol-evoked Ca2+ influx in neuronal cells
Corrales, Alexandra; Xu, Fang; Garavito-Aguilar, Zayra V; Blanck, Thomas J J; Recio-Pinto, Esperanza
2004 Oct;101(4):895-901, Anesthesiology
BACKGROUND: The authors previously reported that the isoflurane-caused reduction of the carbachol-evoked cytoplasmic Ca transient increase ([Ca]cyt) was eliminated by K or caffeine-pretreatment. In this study the authors investigated whether the isoflurane-sensitive component of the carbachol-evoked [Ca]cyt transient involved Ca influx through the plasma membrane. METHODS: Perfused attached human neuroblastoma SH-SY5Y cells were exposed to carbachol (1 mm, 2 min) in the absence and presence of isoflurane (1 mm) and in the absence and presence of extracellular Ca (1.5 mm). The authors studied the effect of the nonspecific cationic channel blocker La (100 microm), of the L-type Ca channel blocker nitrendipine (10 microm), and of the N-type Ca channel blocker omega-conotoxin GVIA (0.1 microm) on isoflurane modulation of the carbachol-evoked [Ca]cyt transient. [Ca]cyt was detected with fura-2 and experiments were carried out at 37 degrees C. RESULTS: Isoflurane reduced the peak and area of the carbachol-evoked [Ca]cyt transient in the presence but not in the absence of extracellular Ca. La had a similar effect as the removal of extracellular Ca. Omega-conotoxin GVIA and nitrendipine did not affect the isoflurane sensitivity of the carbachol response although nitrendipine reduced the magnitude of the carbachol response. CONCLUSIONS: The current data are consistent with previous observations in that the carbachol-evoked [Ca]cyt transient involves both Ca release from intracellular Ca stores and Ca entry through the plasma membrane. It was found that isoflurane attenuates the carbachol-evoked Ca entry. The isoflurane sensitive Ca entry involves a cationic channel different from the L- or N- type voltage-dependent Ca channels. These results indicate that isoflurane attenuates the carbachol-evoked [Ca]cyt transient at a site at the plasma membrane that is distal to the muscarinic receptor
— id: 45503, year: 2004, vol: 101, page: 895, stat: Journal Article,

Differential thapsigargin-sensitivities and interaction of Ca2+ stores in human SH-SY5Y neuroblastoma cells
Garavito-Aguilar, Zayra V; Recio-Pinto, Esperanza; Corrales, Alexandra V; Zhang, Jin; Blanck, Thomas J J; Xu, Fang
2004 Jun 18;1011(2):177-186, Brain research
In human SH-SY5Y neuroblastoma cells, two distinct intracellular Ca2+ stores, a KCl-/caffeine-sensitive and a carbachol-/IP3-sensitive store, were demonstrated previously. In this study, responses of these two intracellular Ca2+ stores to thapsigargin were characterized. Ca2+-release from these stores was evoked either by high K+ (100 mM KCl) or by 1 mM carbachol, and changes in the intracellular Ca2+ level were monitored using Fura-2 fluorimetry. A sequential stimulation protocol (KCl-->carbachol or vice versa) allowed evaluation of the individual contribution of different Ca2+ stores to the evoked intracellular Ca2+ ([Ca2+]i)-transients and the dynamic interaction between them. Thapsigargin (0.05 nM - 20 microM) alone induced a [Ca2+]i-transient. Both the carbachol- and the KCl-evoked [Ca2+]i-transients were inhibited by thapsigargin, but with very different sensitivities. Thapsigargin inhibited the carbachol-evoked [Ca2+]i-transients with (IC50 = 0.353 nM) or without (IC50 = 0.448 nM) a KCl-prestimulation, but an additional small component, with a much lower sensitivity (IC50=4814 nM), was observed in the absence of a KCl-prestimulation. In contrast, the KCl-evoked [Ca2+]i-transients displayed only one component with a very low sensitivity to thapsigargin in both absence (IC50=3343 nM) and presence (IC50=6858 nM) of a carbachol-prestimulation. These findings suggest that the sarco-/endoplasmic reticular Ca2+ ATPases associated with the KCl-/caffeine- and carbachol-/IP3-sensitive intracellular Ca2+ stores differ from each other, either in types or in their post-translational modification. Such difference might play important role in the regulation of neuronal Ca2+ homeostasis
— id: 44521, year: 2004, vol: 1011, page: 177, stat: Journal Article,

Differentiation of an adult neuron cell line increases susceptibility to rabies infection
Martinez-Gutierrez, Marlen; Barrera, Gladys A; Aponte, Samanda L; Baquero, Johanna; Beltran, Magda Y; Recio-Pinto, Esperanza; Jaramillo, Antonio C; Castellanos, Jaime E
2004 Mar;24(1):97-103, Biomedica
A wide variety of in vitro models have been used for studying rabies infection, however, currently, no central nervous system (CNS) adult neuron cultures are available. The current study determined the susceptibility to rabies infection in an adult CNS neuron cell line (CAD-R1). Cultures of CAD-R1 cells were held for 5 days in medium containing serum (undifferentiated CAD-R1 cells) or in serum-free medium (differentiated CAD-R1 cells). They were then infected with highly neurotropic rabies virus (RV) strain (CVS), obtained from fibroblastic cells (CVS-BHK) or from adult mouse brain (CVS-MB). Undifferentiated and differentiated cells were infected with the two RV strains, but the percentage of infected cells in differentiated cultures was significantly greater (83% and 79%, respectively) than in undifferentiated cells (51% and 60%) (Student's t test<0.05). Susceptibility to infection apparently depended on cellular differentiation state, possibly due to acquisition of additional morphological and biochemical characteristics during the differentiation process that made them more susceptible to RV infection. Therefore, CAD R1 cells may represent a good model for RV infection, making them a useful tool for studying RV neurotropism, infection pathogeny, isolation of street virus or producing safer and most potent vaccines
— id: 44520, year: 2004, vol: 24, page: 97, stat: Journal Article,

G-Protein Activation Decreases the Isoflurane Inhibition of N-type Ca2+ Currents. An Increase in the Isoflurane Blocking Potency of N-type Ca2+ Currents May Contribute to the Known Neuroprotection Action of Isoflurane During Ischemia
Recio-Pinto, Esperanza; Nikonorov, Igor M; Blanck, Thomas J J
2004 Jan;16(1):105-107, Journal of neurosurgical anesthesiology
— id: 41882, year: 2004, vol: 16, page: 105, stat: Journal Article,

Ganglioside GD1a increases the excitability of voltage-dependent sodium channels
Salazar, Blanca C; Castano, Santiago; Sanchez, Julio C; Romero, Miryam; Recio-Pinto, Esperanza
2004 Sep 24;1021(2):151-158, Brain research
The effect of the negatively charged ganglioside GD1a, one of the major brain gangliosides [H. Beitinger, W. Probst, R. Hilbig, H. Rahmann, Seasonal variability of sialo-glycoconjugates in the brain of the Djungarian hamster (Phodopus sungorus). Comp. Biochem. Physiol., B 86 (1987) 377-384] on the function of brain derived BTX-modified voltage-dependent sodium channel was studied using the planar lipid bilayer system. Bilayers were formed either with a mixture of neutral phospholipids (4 phosphoethanolamine (PE):1 phosphocholine (PC)) alone or with one containing 6% of the disialoganglioside GD1a. The permeation and activation properties of the channels were measured in the presence of symmetrical 200 mM NaCl. We found that the single channel conductance was not affected by GD1a, whereas the steady-state activation curve displayed a hyperpolarizing shift in the presence of GD1a. Since the lipid distribution in these membranes is symmetrical, then the GD1a effect on sodium channels may result either from an induction of channel conformational changes or from an asymmetrical interaction between the channel (extracellular vs. intracellular channel aspect) and GD1a. Regardless of the mechanism, the data indicate that differences in ganglioside content in neuronal cells may contribute to the previously observed sodium channel functional variability within (soma, dentritic, axon hillock) and between neuronal cells as well as to excitability changes in those physiological and pathological conditions where changes in the neuronal ganglioside content occur
— id: 44519, year: 2004, vol: 1021, page: 151, stat: Journal Article,

Glycosylation affects the protein stability and cell surface expression of Kv1.4 but Not Kv1.1 potassium channels. A pore region determinant dictates the effect of glycosylation on trafficking
Watanabe, Itaru; Zhu, Jing; Recio-Pinto, Esperanza; Thornhill, William B
2004 Mar 5;279(10):8879-8885, Journal of biological chemistry
Kv1.1 and Kv1.4 potassium channels are plasma membrane glycoproteins involved in action potential repolarization. We have shown previously that glycosylation affects the gating function of Kv1.1 and that a pore region determinant of Kv1.1 and Kv1.4 affects their cell surface trafficking negatively or positively, respectively. Here we investigated the role of N-glycosylation of Kv1.1 and Kv1.4 on their protein stability, cellular localization pattern, and trafficking to the cell surface. We found that preventing N-glycosylation of Kv1.4 decreased its protein stability, induced its high partial intracellular retention, and decreased its cell surface protein levels, whereas it had little or no effect on these parameters for Kv1.1. Exchanging a trafficking pore region determinant between Kv1.1 and Kv1.4 reversed these effects of glycosylation on these chimeric channels. Thus it appeared that the Kv1.4 pore region determinant and the sugar tree attached to the S1-S2 linker showed some type of dependence in promoting proper trafficking of the protein to the cell surface, and this dependence can be transferred to chimeric Kv1.1 proteins that contain the Kv1.4 pore. Understanding the different trafficking programs of Kv1 channels, and whether they are altered by glycosylation, will highlight the different posttranslational mechanisms available to cells to modify their cell surface ion channel levels and possibly their signaling characteristics
— id: 48189, year: 2004, vol: 279, page: 8879, stat: Journal Article,

The permeation and activation properties of brain sodium channels change during development
Castillo, Cecilia; Thornhill, William B; Zhu, Jing; Recio-Pinto, Esperanza
2003 Aug 12;144(1):99-106, Brain research. Developmental brain research
BTX-modified sodium channels from 15-day embryonic (E15) rat forebrains were studied in planar lipid bilayers. Compared to postnatal sodium channels, E15 channels had a lower maximal single channel conductance, whereas their permeation pathway sensed a comparable surface charge density and had a similar apparent binding affinity for sodium ions. The steady-state activation curve of E15 channels was significantly more hyperpolarized and had a shallower slope than postnatal channels. The apparent BTX binding affinity was significantly lower for E15 channels than for postnatal channels. Finally, E15 channel alpha-subunits displayed a lower apparent molecular weight, and a lower sialylation level than postnatal sodium channel alpha-subunits. Together with previous studies, our data suggested that the observed functional differences between E15 and postnatal voltage-dependent sodium channels cannot be explained solely by the observed differences in channel sialylation, and hence they also appeared to reflect the presence of other channel structural differences
— id: 41884, year: 2003, vol: 144, page: 99, stat: Journal Article,

Isoflurane reduction of carbachol-evoked cytoplasmic calcium transients is dependent on caffeine-sensitive calcium stores
Corrales, Alexandra; Xu, Fang; Garavito-Aguilar, Zayra; Blanck, Thomas J J; Recio-Pinto, Esperanza
2003 Oct;99(4):882-888, Anesthesiology
BACKGROUND: Many muscarinic functions are relevant to anesthesia, and alterations in muscarinic activity affect the anesthetic/analgesic potency of various drugs. Volatile anesthetics have been shown to depress muscarinic receptor function, and inhibition of the muscarinic signaling pathway alters the minimal alveolar anesthetic concentration of inhaled anesthetics. The purpose of this investigation was to determine in a neuronal cell which source of Ca2+ underlying the carbachol-evoked transient increase in cytoplasmic Ca2+ was reduced by isoflurane. METHODS: Experiments were performed at 37 degrees C on continuously perfused monolayers of human neuroblastoma SH-SY5Y cells using Fura-2 as the cytoplasmic Ca2+ indicator. Carbachol (1 mm) was applied to evoke a transient increase in cytoplasmic Ca2+. RESULTS: Isoflurane (1 mm) reduces the carbachol-evoked transient increase in cytoplasmic Ca2+, and this isoflurane action is eliminated when the cells are continuously stimulated with 200 mm KCl or pretreated with 10 mm caffeine or 200 microm ryanodine. CONCLUSIONS: Isoflurane reduction of the carbachol-evoked transient increase in cytoplasmic Ca2+ requires full caffeine-sensitive Ca2+ stores and Ca2+ release from the caffeine-sensitive stores through the ryanodine-sensitive Ca2+ release channels. The results indicate that isoflurane interferes with a muscarinic Ca2+ signaling through a mechanism downstream from the muscarinic receptors
— id: 39057, year: 2003, vol: 99, page: 882, stat: Journal Article,

G-protein activation decreases isoflurane inhibition of N-type Ba2+ currents
Nikonorov, Igor M; Blanck, Thomas J J; Recio-Pinto, Esperanza
2003 Aug;99(2):392-399, Anesthesiology
BACKGROUND: G-protein activation mediates inhibition of N-type Ca2+ currents. Volatile anesthetics affect G-protein pathways at various levels, and activation of G-proteins has been shown to increase the volatile anesthetic potency for inhibiting the electrical-induced contraction in ileum. The authors investigated whether isoflurane inhibition of N-type Ba2+ currents was mediated by G-protein activation. METHODS: N-type Ba2+ currents were measured in the human neuronal SH-SY5Y cell line by using the whole cell voltage-clamp method. RESULTS: Isoflurane was found to have two effects on N-type Ba2+ currents. First, isoflurane reduced the magnitude of N-type Ba2+ currents to a similar extent (IC50 approximately 0.28 mm) in the absence and presence of GDPbetaS (a nonhydrolyzable GDP analog). Interestingly, GTPgammaS (a nonhydrolyzable GTP analog and G-protein activator) in a dose-dependent manner reduced the isoflurane block; 120 microm GTPgammaS completely eliminated the block of 0.3 mm isoflurane and reduced the apparent isoflurane potency by approximately 2.4 times (IC50 approximately 0.68 mm). Pretreatment with pertussis toxin or cholera toxin did not eliminate the GTPgammaS-induced protection against the isoflurane block. Furthermore, isoflurane reduced the magnitude of voltage-dependent G-protein-mediated inhibition of N-type Ba2+ currents, and this effect was eliminated by pretreatment with pertussis toxin or cholera toxin. CONCLUSIONS: It was found that activation of G-proteins in a neuronal environment dramatically reduced the isoflurane potency for inhibiting N-type Ba2+ currents and, in turn, isoflurane affected the G-protein regulation of N-type Ba2+ currents
— id: 37575, year: 2003, vol: 99, page: 392, stat: Journal Article,

Molecular cloning and expression of a Kv1.1-like potassium channel from the electric organ of Electrophorus electricus
Thornhill, W B; Watanabe, I; Sutachan, J J; Wu, M B; Wu, X; Zhu, J; Recio-Pinto, E
2003 Nov 1;196(1):1-8, Journal of membrane biology
Electrocytes from the electric organ of Electrophorus electricus exhibited sodium action potentials that have been proposed to be repolarized by leak currents and not by outward voltage-gated potassium currents. However, patch-clamp recordings have suggested that electrocytes may contain a very low density of voltage-gated K(+) channels. We report here the cloning of a K(+) channel from an eel electric organ cDNA library, which, when expressed in mammalian tissue culture cells, displayed delayed-rectifier K(+) channel characteristics. The amino-acid sequence of the eel K(+) channel had the highest identity to Kv1.1 potassium channels. However, different important functional regions of eel Kv1.1 had higher amino-acid identity to other Kv1 members, for example, the eel Kv1.1 S4-S5 region was identical to Kv1.5 and Kv1.6. Northern blot analysis indicated that eel Kv1.1 mRNA was expressed at appreciable levels in the electric organ but it was not detected in eel brain, muscle, or cardiac tissue. Because electrocytes do not express robust outward voltage-gated potassium currents we speculate that eel Kv1.1 channels are chronically inhibited in the electric organ and may be functionally recruited by an unknown mechanism
— id: 41881, year: 2003, vol: 196, page: 1, stat: Journal Article,

Actions of general anesthetics on voltage-gated ion channels
Topf N; Recio-Pinto E; Blanck TJJ; Hennings HCJr
Neural mechanisms of anesthesia Totowa NJ : Humana, 2003,
— id: 3141, year: 2003, vol: , page: 299, stat: Chapter,

Glycosylation affects rat Kv1.1 potassium channel gating by a combined surface potential and cooperative subunit interaction mechanism
Watanabe, Itaru; Wang, Hong-Gang; Sutachan, Jhon J; Zhu, Jing; Recio-Pinto, Esperanza; Thornhill, William B
2003 Jul 1;550(Pt 1):51-66, Journal of physiology
The effect of glycosylation on Kv1.l potassium channel function was investigated in mammalian cells stably transfected with Kv1.l or Kv1.1N207Q. Macroscopic current analysis showed that both channels were expressed but Kv1.1N207Q, which was not glycosylated, displayed functional differences compared with wild-type, including slowed activation kinetics, a positively shifted V 1/2, a shallower slope for the conductance versus voltage relationship, slowed C-type inactivation kinetics, and a reduced extent of and recovery from C-type inactivation. Kv1. 1N207Q activation properties were also less sensitive to divalent cations compared with those of Kv1.l. These effects were largely due to the lack of trans-Golgi added sugars, such as galactose and sialic acid, to the N207 carbohydrate tree. No apparent change in ionic current deactivation kinetics was detected inKv1.1N207Q compared with wild-type. Our data, coupled with modelling, suggested that removal of the N207 carbohydrate tree had two major effects. The first effect slowed the concerted channel transition from the last dosed state to the open state without changing the voltage dependence of its kinetics. This effect contributed to the G-V curve depolarization shift and together with the lower sensitivity to divalent cations suggested that the carbohydrate tree and its negatively charged sialic acids affected the negative surface charge density on the channel's extracellular face that was sensed by the activation gating machinery. The second effect reduced a cooperativity factor that slowed the transition from the open state to the dosed state without changing its voltage dependence. This effect accounted for the shallower G-V slope, and contributed to the depolarized G-V shift, and together with the inactivation changes it suggested that the carbohydrate tree also affected channel conformations. Thus N-glycosylation, and particularly terminal sialylation, affected Kv1.l gating properties both by altering the surface potential sensed by the channel's activation gating machinery and by modifying conformational changes regulating cooperative subunit interactions during activation and inactivation. Differences in glycosylation pattern among closely related channels may contribute to their functional differences and affect their physiological roles
— id: 41885, year: 2003, vol: 550, page: 51, stat: Journal Article,

Local anesthetics modulate neuronal calcium signaling through multiple sites of action
Xu, Fang; Garavito-Aguilar, Zayra; Recio-Pinto, Esperanza; Zhang, Jin; J Blanck, Thomas J
2003 May;98(5):1139-1146, Anesthesiology
BACKGROUND: Local anesthetics (LAs) are known to inhibit voltage-dependent Na+ channels, as well as K+ and Ca2+ channels, but with lower potency. Since cellular excitability and responsiveness are largely determined by intracellular Ca2+ availability, sites along the Ca2+ signaling pathways may be targets of LAs. This study was aimed to investigate the LA effects on depolarization and receptor-mediated intracellular Ca2+ changes and to examine the role of Na+ and K+ channels in such functional responses. METHODS: Effects of bupivacaine, ropivacaine, mepivacaine, and lidocaine (0.1-2.3 mm) on evoked [Ca2+](i) transients were investigated in neuronal SH-SY5Y cell suspensions using Fura-2 as the intracellular Ca2+ indicator. Potassium chloride (KCl, 100 mm) and carbachol (1 mm) were individually or sequentially applied to evoke increases in intracellular Ca2+. Coapplication of LA and Na+/K+ channel blockers was used to evaluate the role of Na+ and K+ channels in the LA effect on the evoked [Ca2+](i) transients. RESULTS: All four LAs concentration-dependently inhibited both KCl- and carbachol-evoked [Ca2+](i) transients with the potency order bupivacaine > ropivacaine > lidocaine >/= mepivacaine. The carbachol-evoked [Ca2+](i) transients were more sensitive to LAs without than with a KCl prestimulation, whereas the LA-effect on the KCl-evoked [Ca2+](i) transients was not uniformly affected by a carbachol prestimulation. Na+ channel blockade did not alter the evoked [Ca2+](i) transients with or without a LA. In the absence of LA, K+ channel blockade increased the KCl-, but decreased the carbachol-evoked [Ca2+](i) transients. A coapplication of LA and K+ channel blocker resulted in larger inhibition of both KCl- and carbachol-evoked [Ca2+](i) transients than by LA alone. CONCLUSIONS: Different and overlapping sites of action of LAs are involved in inhibiting the KCl- and carbachol-evoked [Ca2+](i) transients, including voltage-dependent Ca2+ channels, a site associated with the caffeine-sensitive Ca2+ store and a possible site associated with the IP(3)-sensitive Ca2+ store, and a site in the muscarinic pathway. K+ channels, but not Na+ channels, seem to modulate the evoked [Ca2+](i) transients, as well as the LA-effects on such responses
— id: 37576, year: 2003, vol: 98, page: 1139, stat: Journal Article,

Allowed N-glycosylation sites on the Kv1.2 potassium channel S1-S2 linker: implications for linker secondary structure and the glycosylation effect on channel function
Zhu, Jing; Watanabe, Itaru; Poholek, Amanda; Koss, Matthew; Gomez, Barbara; Yan, Chaowen; Recio-Pinto, Esperanza; Thornhill, William B
2003 Nov 1;375(Pt 3):769-775, Biochemical journal
N-glycosylation is a post-translational modification that plays a role in the trafficking and/or function of some membrane proteins. We have shown previously that N-glycosylation affected the function of some Kv1 voltage-gated potassium (K+) channels [Watanabe, Wang, Sutachan, Zhu, Recio-Pinto and Thornhill (2003) J. Physiol. (Cambridge, U.K.) 550, 51-66]. Kv1 channel S1-S2 linkers vary in length but their N-glycosylation sites are at similar relative positions from the S1 or S2 membrane domains. In the present study, by a scanning mutagenesis approach, we determined the allowed N-glycosylation sites on the Kv1.2 S1-S2 linker, which has 39 amino acids, by engineering N-glycosylation sites and assaying for glycosylation, using their sensitivity to glycosidases. The middle section of the linker (54% of linker) was glycosylated at every position, whereas both end sections (46% of linker) near the S1 or S2 membrane domains were not. These findings suggested that the middle section of the S1-S2 linker was accessible to the endoplasmic reticulum glycotransferase at every position and was in the extracellular aqueous phase, and presumably in a flexible conformation. We speculate that the S1-S2 linker is mostly a coiled-loop structure and that the strict relative position of native glycosylation sites on these linkers may be involved in the mechanism underlying the functional effects of glycosylation on some Kv1 K+ channels. The S3-S4 linker, with 16 amino acids and no N-glycosylation site, was not glycosylated when an N-glycosylation site was added. However, an extended linker, with an added N-linked site, was glycosylated, which suggested that the native linker was not glycosylated due to its short length. Thus other ion channels or membrane proteins may also have a high glycosylation potential on a linker but yet have similarly positioned native N-glycosylation sites among isoforms. This may imply that the native position of the N-glycosylation site may be important if the carbohydrate tree plays a role in the folding, stability, trafficking and/or function of the protein
— id: 41883, year: 2003, vol: 375, page: 769, stat: Journal Article,

Lidocaine stabilizes the open state of CNS voltage-dependent sodium channels
Castaneda-Castellanos, David R; Nikonorov, Igor; Kallen, Roland G; Recio-Pinto, E
2002 Mar 28;99(2):102-113, Brain research. Molecular brain research
We have previously reported that the lidocaine action is different between CNS and muscle batrachotoxin-modified Na+ channels [Salazar et al., J. Gen. Physiol. 107 (1996) 743-754; Brain Res. 699 (1995) 305-314]. In this study we examined lidocaine action on CNS Na+ currents, to investigate the mechanism of lidocaine action on this channel isoform and to compare it with that proposed for muscle Na+ currents. Na+ currents were measured with the whole cell voltage clamp configuration in stably transfected cells expressing the brain alpha-subunit (type IIA) by itself (alpha-brain) or together with the brain beta(1)-subunit (alphabeta(1)-brain), or the cardiac alpha-subunit (hH1) (alpha-cardiac). Lidocaine (100 microM) produced comparable levels of Na+ current block at positive potentials and of hyperpolarizing shift of the steady-state inactivation curve in alpha-brain and alphabeta(1)-brain Na+ currents. Lidocaine accelerated the rates of activation and inactivation, produced an hyperpolarizing shift in the steady-state activation curve and increased the current magnitude at negative potentials in alpha-brain but not in alphabeta(1)-brain Na+ currents. The lidocaine action in alphabeta(1)-brain resembled that observed in alpha-cardiac Na+ currents. The lidocaine-induced increase in current magnitude at negative potentials and the hyperpolarizing shift in the steady-state activation curve of alpha-brain, are novel effects and suggest that lidocaine treatment does not always lead to current reduction/block when it interacts with Na+ channels. The data are explained by using a modified version of the model proposed by Vedantham and Cannon [J. Gen. Physiol., 113 (1999) 7-16] in which we postulate that the difference in lidocaine action between alpha-brain and alphabeta(1)-brain Na+ currents could be explained by differences in the lidocaine action on the open channel state
— id: 41886, year: 2002, vol: 99, page: 102, stat: Journal Article,

The neuronal lipid membrane permeability was markedly increased by bupivacaine and mildly affected by lidocaine and ropivacaine
Pardo, Luis; Blanck, Thomas J J; Recio-Pinto, Esperanza
2002 Nov 29;455(2-3):81-90, European journal of pharmacology
We investigated the local anesthetic action on ionic membrane conductance (membrane conductance) and selectivity in membranes formed with neuronal phospholipids in the absence and presence of cholesterol. In membranes without cholesterol, 1 mM bupivacaine and ropivacaine increased the membrane conductance approximately 4.5-fold; and 5 mM lidocaine, ropivacaine and bupivacaine increased the membrane conductance by 2.7-, 2.8- and 22.2-fold, respectively. In the presence of cholesterol, 5 mM ropivacaine had no effect, lidocaine decreased the membrane conductance by 2-fold, and bupivacaine increased the membrane conductance by 17-fold. Local anesthetics did not affect the ion selectivity in membranes without cholesterol, but they all decreased the Na(+) selectivity in membranes with cholesterol. Cholesterol reduced the lidocaine- and ropivacaine-induced membrane conductance increase by eliminating or reversing the Na(+) conductance increase and by lowering the Cl(-) conductance increase. In the absence of cholesterol, 5 mM bupivacaine increased both Na(+) conductance (38-fold) and Cl(-) conductance (19-fold), while in the presence of cholesterol it only increased Cl(-) conductance (26-fold). Of the local anesthetics studied, ropivacaine was the least membrane toxic while bupivacaine was the most toxic
— id: 37577, year: 2002, vol: 455, page: 81, stat: Journal Article,

CNS voltage-dependent Na(+) channel expression and distribution in an undifferentiated and differentiated CNS cell line
Castaneda-Castellanos DR; Cano M; Wang JK; Corbett A; Benson D; Blanck TJ; Thornhill WB; Recio-Pinto E
2000 Jun 2;866(1-2):281-285, Brain research
Upon serum removal, CAD-R1 cells undergo neurite outgrowth and an increase in voltage-dependent Na(+) current (VDNaC) density without changing their activation and inactivation properties. Insulin and endothelial cell growth supplement inhibited the increase in VDNaC density but not the neurite outgrowth. RI, RII, RIII Na(+) channel proteins were expressed in CAD-R1 cells. These proteins exhibited both similar and different distribution and clustering patterns which suggested the channel's structural differences play a role in channel distribution
— id: 37578, year: 2000, vol: 866, page: 281, stat: Journal Article,

Halothane and isoflurane augment depolarization-induced cytosolic CA2+ transients and attenuate carbachol-stimulated CA2+ transients
Xu F; Zhang J; Recio-Pinto E; Blanck TJ
2000 Jun;92(6):1746-1756, Anesthesiology
BACKGROUND: Neuronal excitability is in part determined by Ca2+ availability that is controlled by regulatory mechanisms of cytosolic Ca2+ ([Ca2+]cyt). Alteration of any of those mechanisms by volatile anesthetics (VAs) may lead to a change in presynaptic transmission and postsynaptic excitability. Using a human neuroblastoma cell line, the effects of halothane and isoflurane on cytosolic Ca2+ concentration ([Ca2+]cyt) in response to K+ and carbachol stimulation were investigated. METHODS: Volatile anesthetic (0.05-1 mm) action on stimulated [Ca2+]cyt transients were monitored in suspensions of SH-SY5Y cells loaded with fura-2. Potassium chloride (KCl; 100 mm) was used to depolarize and activate Ca2+ entry through voltage-dependent calcium channels; 1 mm carbachol was used to activate muscarinic receptor-mediated inositol triphosphate (IP3)-dependent intracellular Ca2+ release. Sequential stimulations, KCl followed by carbachol and vice versa, were used to investigate interactions between intracellular Ca2+ stores. RESULTS: Halothane and isoflurane in clinically relevant concentrations enhanced the K+-evoked [Ca2+]cyt transient whether intracellular Ca2+ stores were full or partially depleted. In contrast, halothane and isoflurane reduced the carbachol-evoked [Ca2+]cyt transient when the intracellular Ca2+ stores were full but had no effect when the Ca2+ stores were partially depleted by KCl stimulation. CONCLUSIONS: Volatile anesthetics acted on sites that differently affect the K+- and carbachol-evoked [Ca2+]cyt transients. These data suggest the involvement of an intracellular Ca2+ translocation from the caffeine-sensitive Ca2+ store to the inositol triphosphate-sensitive Ca2+ store that was altered by halothane and isoflurane
— id: 23988, year: 2000, vol: 92, page: 1746, stat: Journal Article,

Lidocaine accessibility to the open state of brain Na+ channels increases during development
Diaz ME; Recio-Pinto E; Salazar BC; Castillo C
1998 Mar;39(2):199-210, Japanese heart journal
During postnatal brain development, the function of Na+ channels undergoes changes. We investigated at the single channel level whether the lidocaine sensitivity of the open state of brain Na+ channels changed during development and the underlying kinetic differences of the lidocaine-induced open channel block between brain and muscle Na+ channels. The lidocaine affinity for the open channel state was found to be about 30% higher in 15 day old than in newborn channels and reflected a higher binding rate constant in 15 day old channels. When compared with reported values from adult muscle Na+ channels, lidocaine blocked the open state of brain channels with about ten times higher potency and reflected a lower unbinding rate constant in brain channels. These results indicate that the conformations of the channel structures defining the lidocaine accessibility to its binding site must undergo changes during brain development and that the conformations of the channel structures interacting with lidocaine must be different in brain and muscle channels
— id: 41887, year: 1998, vol: 39, page: 199, stat: Journal Article,

The effects of halothane on single human neuronal L-type calcium channels
Nikonorov IM; Blanck TJ; Recio-Pinto E
1998 Apr;86(4):885-895, Anesthesia & analgesia
We investigated halothane's effects on the function of L-type Ca2+ channels in a human neuronal cell line, SH-SY5Y, by using the cell-attached patch voltage clamp configuration and Ba2+ as the charge carrier. In multiple-channel patches, halothane decreased the peak and persistent Ba2+ currents, accelerated the rate of inactivation, and slowed the rate of activation. Single-channel analysis showed that halothane (0.14-1.26 mM) increased the latency time for the first channel opening, increased the lifetime of nonconducting events, increased the proportion of short-lived open events, decreased the lifetime of the two open populations, and increased the percentage of current traces without channel activity. All of the observed halothane effects contribute to the halothane-induced decrease in macroscopic Ba2+ currents. The halothane concentration producing 50% reduction (IC50) of the peak Ba2+ current was 0.80 mM (approximately 1.9 hypothetical minimum alveolar anesthetic concentration [H-MAC] at 28 degrees C) and of the persistent Ba2+ current was 0.69 mM (approximately 1.7 H-MAC). The halothane effects did not always occur together, and the Hill slope of 1.6 suggested the presence of more than one interaction site or of more than one population of L-type Ca2+ channels. Halothane reduces L-type Ca2+ channel currents in human neuronal cells primarily through the stabilization of nonconducting states such as closed (before and after channel opening) and inactivated states. Implications: Calcium is a signaling molecule in neurons. We measured the effect of halothane on Ba2+ (a Ca2+ surrogate) movement into a human neuron-like cell electronically. Ba2+ entry through the L-type channel was depressed. Halothane decreased the likelihood of the channel opening and enhanced the rate at which the channel closed and inactivated. These actions of halothane are probably related to its anesthetic action
— id: 23990, year: 1998, vol: 86, page: 885, stat: Journal Article,

Volatile anaesthetic effects on calcium conductance of planar lipid bilayers formed with synthetic lipids or extracted lipids from sarcoplasmic reticulum
Andoh T; Blanck TJ; Nikonorov I; Recio-Pinto E
1997 Jan;78(1):66-74, British journal of anaesthesia
Volatile anaesthetics are known to increase leakage of calcium from the light fraction of skeletal sarcoplasmic reticulum (L-SR) which has no calcium release channels. To explore the role of the lipid environment, we have examined the effect of volatile anaesthetics on calcium conductance (gCa) of lipid membranes. Planar lipid bilayers were formed with a mixture of synthetic phospholipids and cholesterol, resembling the composition of SR membranes, or with lipids extracted from skeletal L-SR, gCa was estimated by calculating the calcium transference number (tCa) using diffusion potential measurements. Membranes formed with L-SR-extracted lipids had a higher gCa than membranes formed with synthetic lipids. Volatile anaesthetics increased total conductance and gCa in a dose-dependent manner, but did not affect tCa or membrane specific capacitance. In membranes formed with L-SR-extracted lipids, isoflurane induced the largest increase in gCa (1260 (SEM 304) % increase, n = 4, 0.94 mmol litre-1), followed by enflurane (264 (75)%, n = 5, 1.88 mmol litre-1) and halothane (53 (33)%, n = 5; 1.54 mmol litre-1). In membranes formed with synthetic lipids, volatile anaesthetic-induced increases in gCa followed the same trend but were larger. Volatile anaesthetics increased gCa without changing the ionic selectivity of membranes. However, the magnitude of the increase in gCa in the presence of volatile anaesthetics cannot account for the previously observed calcium leakage from L-SR vesicles. Therefore, the volatile anaesthetic-induced increase in calcium leakage in L-SR vesicles must be mediated via other pathways involving membrane proteins
— id: 23992, year: 1997, vol: 78, page: 66, stat: Journal Article,

Changes in sodium channel function during postnatal brain development reflect increases in the level of channel sialidation
Castillo C; Diaz ME; Balbi D; Thornhill WB; Recio-Pinto E
1997 Dec 19;104(1-2):119-130, Brain research. Developmental brain research
Developmental changes of forebrain sodium channels were studied at three postnatal ages: P0, P15 and adult (P30/P180). Electrophysiological analysis determined that the midpoint potential of activation was -64, -75 and -81 mV for P0, P15 and adult channels, respectively. At negative potentials, gating state changes were observed in all channels; at positive potentials they were observed in most P0 (72%) and to a lower extent in older channels (25%). A long non-conductive state was displayed with a higher frequency in P0 than in older channels. Immunoblot analysis determined that the apparent molecular weight was approximately 227, approximately 241 and approximately 246 kDa for P0, P15 and adult channels, respectively. Upon neuraminidase treatment, which cleaves sialic acids, these differences in molecular weight were abolished. The data suggest that these developmental changes in the function of forebrain sodium channels correlate with changes in the channel's sialidation level
— id: 41888, year: 1997, vol: 104, page: 119, stat: Journal Article,

Anemone toxin II unmasks two conductance states in neuronal sodium channels
Castillo C; Piernavieja C; Recio-Pinto E
1996 Sep 16;733(2):231-242, Brain research
Anemone toxin II (ATX)-modified voltage-dependent neuronal sodium channels were studied in planar lipid bilayers. ATX-modified channels displayed two predominant conducting states: a short-lived (ms-s) high-conductance (approximately 65 pS) state and a long-lived (s-min) low-conductance (approximately 10 pS) state. The high-conductance state underwent brief closures (ms) and the low-conductance state underwent long closures (s). The probability of detecting these states was time- and voltage-dependent. The channel's fractional open time (fo) due to the high-conductance state increased with depolarization and had a midpoint potential (Va) of -36 mV and an apparent gating charge (Za) of 2.8. The channel's fo due to the low-conductance state increased with depolarization and had a Va of +13 mV and a Za of 1.4. At positive potentials, ATX-modified channels slowly (minutes) entered an absorbing non-conducting state. The permeability ratio of Na+/K+ was 2 and 4 for the low- and high-conductance states, respectively. The saxitoxin analog C3 blocked ATX-modified sodium channels with high affinity (Kd(60-90 mV) = 410 nM, 0.5 M NaCl). The data suggest that upon a depolarization step, ATX-modified channels enter rapidly (ms) into a high-conductance state and more slowly (s-min) into a low-conductance state. Also as the membrane potential becomes more positive, the equilibrium is shifted from the high- to the low-conductance state and from the conducting states to an absorbing non-conducting state
— id: 41890, year: 1996, vol: 733, page: 231, stat: Journal Article,

Interactions between anemone toxin II and veratridine on single neuronal sodium channels
Castillo C; Piernavieja C; Recio-Pinto E
1996 Sep 16;733(2):243-252, Brain research
The nature of the known positive cooperativity between alkaloid and alpha-polypeptide toxins on macroscopic sodium currents was studied at the single-channel level. We have previously characterized the single-channel function of veratridine (VTD)-modified and anemone toxin II (ATX)-modified channels from lobster leg nerve. VTD and ATX are known to potentiate each other's effects in stimulating 22Na flux into vesicles containing sodium channels from lobster leg nerve. These channels, therefore, provided an excellent model for further investigation of the interactions between the toxins. A variety of such interactions were found, some of which would contribute to the positive cooperativity between these toxins. These included first, a decrease in the frequency of occurrence, but not in the lifetime, of the long channel closed state (minute range). This effect resulted in a hyperpolarization shift of the voltage dependence of the overall channel fractional open time. The second effect was a decrease in the apparent-unbinding rate of ATX at -60 mV. These interactions, which could not have been predicted by the effects of the individual toxins, were observed at negative but not at positive potentials, and led to increases in sodium channel currents. Some of the observed interactions could not contribute to the positive cooperativity between these toxins. These included the elimination of the high-conductance state of ATX-modified channels, the predominance of the VTD effect on the voltage dependence of the fast-process, the predominance of the ATX effect on the rate of decay of sodium currents at +60 mV, and the resulting intermediate toxin effect on the level of the noisy open state
— id: 41889, year: 1996, vol: 733, page: 243, stat: Journal Article,

Multiple open channel states revealed by lidocaine and QX-314 on rat brain voltage-dependent sodium channels
Salazar BC; Castillo C; Diaz ME; Recio-Pinto E
1996 Jun;107(6):743-754, Journal of general physiology
We have recently reported that brain sodium channels display periods with high (low-Kd) and low (high-Kd) levels of lidocaine-induced open channel block (Salazar, B.C., D.O. Flash, J.L. Walewski, and E. Recio-Pinto. 1995. Brain Res. 699:305-314). In the present study, we further characterize this phenomenon by studying the effects of the permanently charged lidocaine analogue, QX-314. We found that the detection of high- and low-Kd periods does not require the presence of the uncharged form of lidocaine. The level of block, for either period, at various QX-314 concentrations indicated the presence of a single local anesthetic binding site. Increasing the concentration of QX-314 decreased the lifetime of the high-Kd periods while it increased the lifetime of the low-Kd periods. These results could be best fitted to a model with two open channel conformations that display different local anesthetic Kd values (low and high Kd), and in which the channel area defining the local anesthetic Kd consists of multiple interacting regions. Amplitude distribution analysis showed that changes in the Kd values reflected changes in the kon rates, without changes in the koff rates. Both lidocaine and QX-314 were found to be incapable of blocking small-channel subconductance states (5-6 pS). Changes in the local anesthetic kon rates for blocking the fully open state and the lack of local anesthetic block of the small subconductance state are consistent with the presence of channel conformational changes involving the intracellular permeation pathway leading to the local anesthetic binding site
— id: 41891, year: 1996, vol: 107, page: 743, stat: Journal Article,

Lidocaine has different effects and potencies on muscle and brain sodium channels
Salazar BC; Flash DO; Walewski JL; Recio-Pinto E
1995 Nov 20;699(2):305-314, Brain research
Lidocaine effects were studied at the single channel level on batrachotoxin-activated eel electroplax (muscle-derived) and on rat brain sodium channels in planar lipid bilayers to investigate whether these effects were the same on structurally different sodium channels. Lidocaine blocked the open state of brain channels with the same voltage dependence, but with 15-times as high a potency as muscle-derived channels. In brain channels, but not muscle-derived ones, the level of the open channel block showed periods of relief. Lidocaine at microM concentrations stabilized the highest conductance state in both channel types and at mM concentrations stabilized subconductance-like states in electroplax, but not in brain channels. In both channel types, lidocaine increased the lifetime and rate of entry to a long-nonconducting state. Since both channel types were studied under identical lipid and ionic conditions, the observed functional differences in the lidocaine action (effects, potency) must reflect channel structural differences
— id: 41892, year: 1995, vol: 699, page: 305, stat: Journal Article,

Alkaloid-modified sodium channels from lobster walking leg nerves in planar lipid bilayers
Castillo C; Villegas R; Recio-Pinto E
1992 Jun;99(6):897-930, Journal of general physiology
Alkaloid-modified, voltage-dependent sodium channels from lobster walking leg nerves were studied in planar neutral lipid bilayers. In symmetrical 0.5 M NaCl the single channel conductance of veratridine (VTD) (10 pS) was less than that of batrachotoxin (BTX) (16 pS) modified channels. At positive potentials, VTD- but not BTX-modified channels remained open at a flickery substate. VTD-modified channels underwent closures on the order of milliseconds (fast process), seconds (slow process), and minutes. The channel fractional open time (f(o)) due to the fast process, the slow process, and all channel closures (overall f(o)) increased with depolarization. The fast process had a midpoint potential (V(a)) of -122 mV and an apparent gating charge (z(a)) of 2.9, and the slow process had a V(a) of -95 mV and a z(a) of 1.6. The overall f(o) was predominantly determined by closures on the order of minutes, and had a V(a) of about -24 mV and a shallow voltage dependence (z(a) approximately 0.7). Augmenting the VTD concentration increased the overall f(o) without changing the number of detectable channels. However, the occurrence of closures on the order of minutes persisted even at super-saturating concentrations of VTD. The occurrence of these long closures was nonrandom and the level of nonrandomness was usually unaffected by the number of channels, suggesting that channel behavior was nonindependent. BTX-modified channels also underwent closures on the order of milliseconds, seconds, and minutes. Their characterization, however, was complicated by the apparent low BTX binding affinity and by an apparent high binding reversibility (channel disappearance) of BTX to these channels. VTD- but not BTX-modified channels inactivated slowly at high positive potentials (greater than +30 mV). Single channel conductance versus NaCl concentrations saturated at high NaCl concentrations and was non-Langmuirian at low NaCl concentrations. At all NaCl concentrations the conductance of VTD-modified channels was lower than that of BTX-modified channels. However, this difference in conductance decreased as NaCl concentrations neared zero, approaching the same limiting value. The permeability ratio of sodium over potassium obtained under mixed ionic conditions was similar for VTD (2.46)- and BTX (2.48)-modified channels, whereas that obtained under bi-ionic conditions was lower for VTD (1.83)- than for BTX (2.70)-modified channels. Tetrodotoxin blocked these alkaloid-modified channels with an apparent binding affinity in the nanomolar range
— id: 41893, year: 1992, vol: 99, page: 897, stat: Journal Article,

The role of nonprotein domains in the function and synthesis of voltage-gated sodium channels
Levinson SR; Thornhill WB; Duch DS; Recio-Pinto E; Urban BW
1990 ;2(5):33-64, Ion channels
— id: 41895, year: 1990, vol: 2, page: 33, stat: Journal Article,

Neuraminidase treatment modifies the function of electroplax sodium channels in planar lipid bilayers
Recio-Pinto E; Thornhill WB; Duch DS; Levinson SR; Urban BW
1990 Nov;5(5):675-684, Neuron
Sodium channels from several sources are covalently modified by unusually large numbers of negatively charged sialic acid residues. In the present studies, purified electroplax sodium channels were treated with neuraminidase to remove sialic acid residues and then examined for functional changes in planar lipid bilayers. Neuraminidase treatment resulted in a large depolarizing shift in the average potential required for channel activation. Additionally, desialidated channels showed a striking increase in the frequency of reversible transitions to subconductance states. Thus it appears that sialic acid residues play a significant role in the function of sodium channels, possibly through their influence on the local electric field and/or conformational stability of the channel molecule
— id: 41894, year: 1990, vol: 5, page: 675, stat: Journal Article,

Veratridine modification of the purified sodium channel alpha-polypeptide from eel electroplax
Duch DS; Recio-Pinto E; Frenkel C; Levinson SR; Urban BW
1989 Nov;94(5):813-831, Journal of general physiology
In the interest of continuing structure-function studies, highly purified sodium channel preparations from the eel electroplax were incorporated into planar lipid bilayers in the presence of veratridine. This lipoglycoprotein originates from muscle-derived tissue and consists of a single polypeptide. In this study it is shown to have properties analogous to sodium channels from another muscle tissue (Garber, S. S., and C. Miller. 1987. Journal of General Physiology. 89:459-480), which have an additional protein subunit. However, significant qualitative and quantitative differences were noted. Comparison of veratridine-modified with batrachotoxin-modified eel sodium channels revealed common properties. Tetrodotoxin blocked the channels in a voltage-dependent manner indistinguishable from that found for batrachotoxin-modified channels. Veratridine-modified channels exhibited a range of single-channel conductance and subconductance states. The selectivity of the veratridine-modified sodium channels for sodium vs. potassium ranged from 6-8 in reversal potential measurements, while conductance ratios ranged from 12-15. This is similar to BTX-modified eel channels, though the latter show a predominant single-channel conductance twice as large. In contrast to batrachotoxin-modified channels, the fractional open times of these channels had a shallow voltage dependence which, however, was similar to that of the slow interaction between veratridine and sodium channels in voltage-clamped biological membranes. Implications for sodium channel structure are discussed
— id: 41897, year: 1989, vol: 94, page: 813, stat: Journal Article,

Pentobarbital suppresses human brain sodium channels
Frenkel C; Duch DS; Recio-Pinto E; Urban BW
1989 Nov;6(2-3):211-216, Brain research. Molecular brain research
Ion channels, key components in neuronal signal transmission and processing, are likely to be important molecular sites of anesthetic action. Sodium channels from human brain tissue were incorporated into planar lipid bilayers in the presence of batrachotoxin and exposed to the anesthetic pentobarbital. This barbiturate, in a dose-dependent manner and at clinically relevant concentrations, reduced fractional channel open time independent of membrane potential, and interfered with the steady-state activation process
— id: 41896, year: 1989, vol: 6, page: 211, stat: Journal Article,

Human brain sodium channels in bilayers
Duch DS; Recio-Pinto E; Frenkel C; Urban BW
1988 Nov;464(3):171-177, Brain research
Sodium channels from human cortex were fused into planar lipid bilayers in the presence of batrachotoxin, and their single channel properties examined. Single channel slope conductance averaged 26 ps; tetrodotoxin block of the channels was voltage dependent with a K1/2 at 0 mV of 51 nM. The channel was asymmetrically selective for sodium over potassium. The permeability ratio (PNa/PK) equalled 3.3 when potassium was present only on the intracellular side of the channel, but it was 5.7 with potassium on the extracellular side. The average channel activation gating midpoint was -91 mV. These results indicate that sodium channels from human brain can be successfully studied both electrophysiologically and pharmacologically with the planar bilayer system
— id: 41898, year: 1988, vol: 464, page: 171, stat: Journal Article,

Insulin and insulinlike growth factor receptors regulating neurite formation in cultured human neuroblastoma cells
Recio-Pinto E; Ishii DN
1988 Mar;19(3):312-320, Journal of neuroscience research
The functional role of brain insulin and insulinlike growth factor (IGF) receptors is being sought. Recently it has been found that these ligands are members of a newly identified family of neuritogenic polypeptides. We studied the relationship between 125I-insulin and 125I-IGF binding and their capacity to enhance neurite formation in cultured human neuroblastoma SH-SY5Y cells. The binding of 125I-insulin was temperature-dependent and heterogeneous. The Scatchard plot and dissociation rate were both consistent with the presence of two types of sites. There appeared to be about 900 high affinity sites per cell with a Kd of about 3 nM. This compared favorably with the half-maximal concentration of 4 nM for enhancement of neurite formation. The type I IGF sites were also present. Physiologic concentrations of insulin clearly enhanced neurite formation through the insulin sites, whereas physiologic concentrations of IGF-I and IGF-II enhanced through the IGF sites. Cross-occupancy of sites was observed at supraphysiologic concentrations, providing a reasonable explanation for the broad dose-response curves for these ligands. These results support the suggestion that one function of insulin and IGF receptors in neural tissues may be to modulate neurite formation
— id: 41899, year: 1988, vol: 19, page: 312, stat: Journal Article,

Insulin and related growth factors: effects on the nervous system and mechanism for neurite growth and regeneration
Recio-Pinto E; Ishii DN
1988 ;12(4):397-414, Neurochemistry international
The neurobiological, behavioral and electrical effects of insulin and insulinlike growth factors (IGFs) are reviewed. Emphasis is placed on the emerging evidence that insulin and IGFs are members of a supergene family whose encoded polypeptides are functionally related not only as growth factors but also as neuroactive agents. The neurophysiology of insulin and its homologs is more fully illuminated through comparison against the classic neurotrophic agent, nerve growth factor (NGF). The IGFs and NGF are strongly implicated as having important roles in nerve regeneration, based on an examination of their neurotrophic properties and pattern of gene expression following nerve injury. The elucidation of the molecular mechanism by which neuritogenic polypeptides modulate neurite growth may eventually contribute to our understanding of the architectural development of neural circuitries on which higher animal behavior rests, and also provide the basis for new therapeutic approaches to nervous system injuries and disorders. The recent studies showing that these neuritogenic polypeptides may share a common mechanism involving elevation of tubulin transcripts, due at least in part to stabilization, are discussed. A substantial body of evidence now implicates phosphorylation as the receptor-mediated transmembrane event triggered by the neuritogenic polypeptides.
— id: 41906, year: 1988, vol: 12, page: 397, stat: Journal Article,

Role of insulin, insulin-like growth factors, and nerve growth factor in neurite formation
Ishii DN; Recio-Pinto E
Insulin, insulin-like growth factors, and their receptors in the central nervous system New York : Plenum Press, 1987,
— id: 3142, year: 1987, vol: , page: 315, stat: Chapter,

Purified and unpurified sodium channels from eel electroplax in planar lipid bilayers
Recio-Pinto E; Duch DS; Levinson SR; Urban BW
1987 Sep;90(3):375-395, Journal of general physiology
Highly purified sodium channel protein from the electric eel, Electrophorus electricus, was reconstituted into liposomes and incorporated into planar bilayers made from neutral phospholipids dissolved in decane. The purest sodium channel preparations consisted of only the large, 260-kD tetrodotoxin (TTX)-binding polypeptide. For all preparations, batrachotoxin (BTX) induced long-lived single-channel currents (25 pS at 500 mM NaCl) that showed voltage-dependent activation and were blocked by TTX. This block was also voltage dependent, with negative potentials increasing block. The permeability ratios were 4.7 for Na+:K+ and 1.6 for Na+:Li+. The midpoint for steady state activation occurred around -70 mV and did not shift significantly when the NaCl concentration was increased from 50 to 1,000 mM. Veratridine-induced single-channel currents were about half the size of those activated by BTX. Unpurified, nonsolubilized sodium channels from E. electricus membrane fragments were also incorporated into planar bilayers. There were no detectable differences in the characteristics of unpurified and purified sodium channels, although membrane stability was considerably higher when purified material was used. Thus, in the eel, the large, 260-kD polypeptide alone is sufficient to demonstrate single-channel activity like that observed for mammalian sodium channel preparations in which smaller subunits have been found
— id: 41900, year: 1987, vol: 90, page: 375, stat: Journal Article,

The sodium channel from Electrophorus electricus
Levinson SR; Duch DS; Urban BW; Recio-Pinto E
1986 ;479(5):162-178, Annals of the New York Academy of Sciences
— id: 41902, year: 1986, vol: 479, page: 162, stat: Journal Article,

Effects of insulin, insulin-like growth factor-II, and nerve growth factor on neurite formation and survival in cultured sympathetic and sensory neurons
Recio-Pinto E; Rechler MM; Ishii DN
1986 May;6(5):1211-1219, Journal of neuroscience
Insulin and the insulin-like growth factors (IGFs) may directly affect the development of the nervous system. NGF, IGF-II, and insulin's effects on neurite formation and neuronal survival were studied in peripheral ganglion cell cultures from chick embryos. Neurite outgrowth was enhanced in a dose-dependent manner by insulin and IGF-II in sympathetic cell cultures. The half-maximally effective concentration, ED50, was about 0.4-0.6 nM for both polypeptides, and concentrations as low as 10 pM were active. However, in sensory neurons the ED50 for neurite outgrowth was about 30 nM for insulin and 0.1 nM for IGF-II, suggesting that these factors may have selective effects in different neuronal tissues. Neither serum nor the presence of non-neuronal cells was required for the response in sympathetic neurons. The specific anti-NGF antiserum inhibited the neurite outgrowth response to NGF but not to insulin nor IGF-II. Insulin and IGF-II additionally supported survival of sensory and sympathetic neurons; however, insulin was not as efficacious as NGF. The combination of high concentrations of NGF and insulin was no better than NGF alone in supporting sympathetic cell survival, or neurite outgrowth. This indicates that insulin acts on the same, or a subpopulation, of NGF-responsive neurons. These results support the hypothesis that insulin and its homologs belong to a broad family of neuritogenic polypeptides
— id: 41901, year: 1986, vol: 6, page: 1211, stat: Journal Article,

Neurite formation modulated by nerve growth factor, insulin, and tumor promoter receptors
Ishii DN; Recio-Pinto E; Spinelli W; Mill JF; Sonnenfeld KH
1985 Apr;26(1-2):109-127, International journal of neuroscience
Until recently, nerve growth factor could be considered the only neurotrophic factor with an established physiological role. We discuss the emerging evidence indicating that the insulinlike factors may constitute a family of related neurotrophic proteins, and the observations suggesting that the receptor for the phorbol ester tumor promoters is closely associated with neuronal differentiation. The emphasis of the discussion is placed on neurite formation under multiple modulation by insulinlike factors, nerve growth factor, and tumor promoter receptors in sensory, sympathetic and human neuroblastoma cells
— id: 41903, year: 1985, vol: 26, page: 109, stat: Journal Article,

Effects of insulin, insulin-like growth factor-II and nerve growth factor on neurite outgrowth in cultured human neuroblastoma cells
Recio-Pinto E; Ishii DN
1984 Jun 8;302(2):323-334, Brain research
The identification of biologically important and chemically well-defined substances that can promote axon and dendrite formation would improve present understanding of the development of the nervous system. Physiological concentrations of insulin and insulin-like growth factor-II (IGF-II) reversibly enhanced neurite outgrowth (NTO) in human neuroblastoma SH-SY5Y cells cultured in media with and without serum. Nerve growth factor (NGF), in contrast, did not enhance NTO in serum-free media. Furthermore, anti-NGF antiserum inhibited NGF but not insulin-enhanced NTO. Insulin increased [3H]leucine and [3H]uridine uptake. These increases, together with increased NTO, were inhibited by cycloheximide and actinomycin D, respectively. The inhibition of NTO by cycloheximide was reversible. Human neuroblastoma cell lines that were responsive by NTO to NGF were also responsive to insulin, with the exception of line CHP-270. Moreover, cell lines unresponsive by NTO to NGF, and to tumor promoters, were uniformly unresponsive to insulin. These findings suggest that there are common defects in distal sites, because specific NGF and tumor promotor receptors are present in these lines. Insulin increased [3H]thymidine uptake in SH-SY5Y and CHP-100 cells. However, the enhancement of NTO by insulin and IGF-II in SH-SY5Y cells was independent of the cellular proliferation rate. Our results, together with the observations of others, suggest that insulin and IGF-II may modulate NTO in the nervous system
— id: 41904, year: 1984, vol: 302, page: 323, stat: Journal Article,

Insulin and insulin-like growth factor II permit nerve growth factor binding and the neurite formation response in cultured human neuroblastoma cells
Recio-Pinto E; Lang FF; Ishii DN
1984 Apr;81(8):2562-2566, Proceedings of the National Academy of Sciences of the United States of America
In serum-free medium, SH-SY5Y human neuroblastoma cells specifically and reversibly lost the capacity to bind 125I-labeled nerve growth factor (NGF) to the high-affinity sites (slow sites) and to respond by neurite outgrowth, unless physiological concentrations of insulin or insulin-like growth factor II were present. In serum-containing medium, anti-insulin antiserum decreased the neurite formation response to NGF, and insulin supplementation increased the number of available NGF slow sites. The low-affinity NGF fast sites are absent from SH-SY5Y cells and did not emerge on treatment with insulin. Insulin potentiated the induction of neurites by NGF in rat pheochromocytoma PC12 cells also. These results implicate a wider role for insulin and its homologs in the nervous system
— id: 41905, year: 1984, vol: 81, page: 2562, stat: Journal Article,