Large-conductance Ca- and voltage-activated K (BK) channels play many physiological roles ranging from the maintenance of smooth muscle tone to hearing and neurosecretion. BK channels are tetramers in which the pore-forming α subunit is coded by a single gene (Slowpoke, KCNMA1). In this review, we first highlight the physiological importance of this ubiquitous channel, emphasizing the role that BK channels play in different channelopathies. We next discuss the modular nature of BK channel-forming protein, in which the different modules (the voltage sensor and the Ca binding sites) communicate with the pore gates allosterically. In this regard, we review in detail the allosteric models proposed to explain channel activation and how the models are related to channel structure. Considering their extremely large conductance and unique selectivity to K, we also offer an account of how these two apparently paradoxical characteristics can be understood consistently in unison, and what we have learned about the conduction system and the activation gates using ions, blockers, and toxins. Attention is paid here to the molecular nature of the voltage sensor and the Ca binding sites that are located in a gating ring of known crystal structure and constituted by four COOH termini. Despite the fact that BK channels are coded by a single gene, diversity is obtained by means of alternative splicing and modulatory β and γ subunits. We finish this review by describing how the association of the α subunit with β or with γ subunits can change the BK channel phenotype and pharmacology.
Phosphatidylinositol 4,5-bisphosphate (PIP2) plays a central role in the activation of several transient receptor potential (TRP) channels. The role of PIP2 on temperature gating of thermoTRP channels has not been explored in detail, and the process of temperature activation is largely unexplained. In this work, we have exchanged different segments of the C-terminal region between coldsensitive (TRPM8) and heat-sensitive (TRPV1) channels, trying to understand the role of the segment in PIP2 and temperature activation. A chimera in which the proximal part of the C-terminal of TRPV1 replaces an equivalent section of TRPM8 C-terminal is activated by PIP2 and confers the phenotype of heat activation. PIP2, but not temperature sensitivity, disappears when positively charged residues contained in the exchanged region are neutralized. Shortening the exchanged segment to a length of 11 aa produces voltage-dependent and temperature-insensitive channels. Our findings suggest the existence of different activation domains for temperature, PIP2, and voltage. We provide an interpretation for channel-PIP2 interaction using a full-atom molecular model of TRPV1 and PIP2 docking analysis. chimera ͉ temperature activation ͉ C-terminal domain ͉ molecular model P hosphatidylinositol 4,5-bisphosphate (PIP 2 ) acts as a second messenger phospholipid and is the source of another three lipidic-derived messengers (DAG, IP 3 , PIP 3 ). Although the amount of PIP 2 in the membrane is very low, it is able to regulate the activity of ion channels transporters and enzymes (1-3). Several TRP channels reveal some degree of PIP 2 dependence. PIP 2 depletion inhibits TRPM7, TRPM5, TRPM8, TRPV5, and TRPM4 currents (4-9). In the case of TRPM8, some key positively charged residues present in a well conserved sequence contained in the C-terminal region of TRP channels, the TRP domain, were found to be crucial in determining the apparent affinity of PIP 2 activation (7). Residues K995, R998, and R1008 in the TRP box and TRP domain are critically involved in the activation of TRPM8 by PIP 2 . The hydrolysis of PIP 2 also constitutes an important mechanism for the Ca 2ϩ -dependent desensitization of TRPM8 (6, 7). Because of the high sequence similarity among TRP channels in the TRP domain region, it has been proposed that the family of TRP channels possesses a common PIP 2 -binding site located on its proximal C terminus (7, 10, 11). Different from its counterparts, TRPV1 shows a PLC/ NGF-dependent inhibition (12), where binding of NGF to trkA is coupled to PLC activation that leads to PIP 2 hydrolysis. Mutagenesis experiments suggested the presence of a PIP 2 -dependent inhibitory domain (13). In this model, the sensitization observed in TRPV1 is explained on the basis of PIP 2 hydrolysis as it acts as a tonical inhibitor. An alternative model has been proposed for the inhibition based on NGF-dependent phosphorylation of the TRPV1 C-terminal domain and a subsequent increase in membrane expression (14). These observations, together with the finding that...
Temperature sensing is one of the oldest capabilities of living organisms, and is essential for sustaining life, because failure to avoid extreme noxious temperatures can result in tissue damage or death. A subset of members of the transient receptor potential (TRP) ion channel family is finely tuned to detect temperatures ranging from extreme cold to noxious heat, giving rise to thermoTRP channels. Structural and functional experiments have shown that thermoTRP channels are allosteric proteins, containing different domains that sense changes in temperature, among other stimuli, triggering pore opening. Although temperature-dependence is well characterized in thermoTRP channels, the molecular nature of temperature-sensing elements remains unknown. Importantly, thermoTRP channels are involved in pain sensation, related to pathological conditions. Here, we provide an overview of thermoTRP channel activation. We also discuss the structural and functional evidence supporting the existence of an intrinsic temperature sensor in this class of channels, and we explore the basic thermodynamic principles for channel activation. Finally, we give a view of their role in painful pathophysiological conditions.
Rotaviruses (RVs) are nonenveloped, 11-segmented, double-stranded RNA viruses that are major pathogens associated with acute gastroenteritis. Group A, B, and C RVs have been isolated from humans; however, intergroup gene reassortment does not occur for reasons that remain unclear. This restriction might reflect the failure of the viral RNA-dependent RNA polymerase (RdRp; VP1) to recognize and replicate the RNA of a different group. To address this possibility, we contrasted the sequences, structures, and functions of RdRps belonging to RV groups A, B, and C (A-VP1, B-VP1, and C-VP1, respectively). We found that conserved amino acid residues are located within the hollow center of VP1 near the active site, whereas variable, group-specific residues are mostly surface exposed. By creating a three-dimensional homology model of C-VP1 with the A-VP1 crystallographic data, we provide evidence that these RV RdRps are nearly identical in their tertiary folds and that they have the same RNA template recognition mechanism that differs from that of B-VP1. Consistent with the structural data, recombinant A-VP1 and C-VP1 are capable of replicating one another's RNA templates in vitro. Nonetheless, the activity of both RdRps is strictly dependent upon the presence of cognate RV core shell protein A-VP2 or C-VP2, respectively. Together, the results of this study provide unprecedented insight into the structure and function of RV RdRps and support the notion that VP1 interactions may influence the emergence of reassortant viral strains.
BackgroundNanotechnology is a science that involves imaging, measurement, modeling and a manipulation of matter at the nanometric scale. One application of this technology is drug delivery systems based on nanoparticles obtained from natural or synthetic sources. An example of these systems is synthetized from poly(3-hydroxybutyrate-co-3-hydroxyvalerate), which is a biodegradable, biocompatible and a low production cost polymer. The aim of this work was to investigate the uptake mechanism of PHBV nanoparticles in two different epithelial cell lines (HeLa and SKOV-3).ResultsAs a first step, we characterized size, shape and surface charge of nanoparticles using dynamic light scattering and transmission electron microscopy. Intracellular incorporation was evaluated through flow cytometry and fluorescence microscopy using intracellular markers. We concluded that cellular uptake mechanism is carried out in a time, concentration and energy dependent way. Our results showed that nanoparticle uptake displays a cell-specific pattern, since we have observed different colocalization in two different cell lines. In HeLa (Cervical cancer cells) this process may occur via classical endocytosis pathway and some internalization via caveolin-dependent was also observed, whereas in SKOV-3 (Ovarian cancer cells) these patterns were not observed. Rearrangement of actin filaments showed differential nanoparticle internalization patterns for HeLa and SKOV-3. Additionally, final fate of nanoparticles was also determined, showing that in both cell lines, nanoparticles ended up in lysosomes but at different times, where they are finally degraded, thereby releasing their contents.ConclusionsOur results, provide novel insight about PHBV nanoparticles internalization suggesting that for develop a proper drug delivery system is critical understand the uptake mechanism.Electronic supplementary materialThe online version of this article (doi:10.1186/s12951-016-0241-6) contains supplementary material, which is available to authorized users.
SUMMARYRotavirus NSP2 is an abundant nonstructural RNA-binding protein essential for forming the viral factories that support replication of the double-stranded RNA genome. NSP2 exists as stable doughnut-shaped octamers within the infected cell, representing the tail-to-tail interaction of two tetramers. Extending diagonally across the surface of each octamer are four highly basic grooves that function as binding sites for single-stranded RNA. Between the N and C-terminal domains of each monomer is a deep electropositive cleft containing a catalytic site that hydrolyzes the γ-β phosphoanhydride bond of any NTP. The catalytic site has similarity to those of the histidine triad (HIT) family of nucleotide-binding proteins. Due to the close proximity of the grooves and clefts, we investigated the possibility that the RNA-binding activity of the groove promoted the insertion of the 5′-triphosphate moiety of the RNA into the cleft, and the subsequent hydrolysis of its γ-β phosphoanhydride bond. Our results show that NSP2 hydrolyzes the γP from RNAs and NTPs through Mg 2+ -dependent activities that proceed with similar reaction velocities, that require the catalytic His 225 residue, and that produce a phosphorylated intermediate. Competition assays indicate that although both substrates enter the active site, RNA is the preferred substrate due to its higher affinity for the octamer. The RTPase activity of NSP2 may account for the absence of 5′-terminal γP on the (−) strands of the dsRNA genome segments. This is the first report of a HIT-like protein with a multifunctional catalytic site, capable of accommodating both NTPs and RNAs during γP hydrolysis.
Summary• The family of voltage-gated potassium channels in plants presumably evolved from a common ancestor and includes both inward-rectifying (K in ) channels that allow plant cells to accumulate K + and outward-rectifying (K out ) channels that mediate K + efflux. Despite their close structural similarities, the activity of K in channels is largely independent of K + and depends only on the transmembrane voltage, whereas that of K out channels responds to the membrane voltage and the prevailing extracellular K + concentration. Gating of potassium channels is achieved by structural rearrangements within the last transmembrane domain (S6).• Here we investigated the functional equivalence of the S6 helices of the K in channel KAT1 and the K out channel SKOR by domain-swapping and site-directed mutagenesis. Channel mutants and chimeras were analyzed after expression in Xenopus oocytes.• We identified two discrete regions that influence gating differently in both channels, demonstrating a lack of functional complementarity between KAT1 and SKOR. Our findings are supported by molecular models of KAT1 and SKOR in the open and closed states.• The role of the S6 segment in gating evolved differently during specialization of the two channel subclasses, posing an obstacle for the transfer of the K + -sensor from K out to K in channels.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.