Search Results (202)

Scorpion neurotoxins are small peptides that target ion channels and offer opportunities for novel therapeutic discovery. This study analyzed the functional effects of the venom and toxins from the Costa Rican endemic scorpion, Tityus championi. Initially, crude venom was tested on different isoforms of voltage-gated sodium channels. Our findings revealed that the venom contains toxins that affect mammalian Na_V1.6 and Na_V1.7, as well as the cockroach BgNa_V1 channel. Increased currents through Na_V1.6 and BgNa_V1 channels were associated with bigger window currents and inhibition of inactivation. Decreased Na_V1.7 currents were associated with smaller conductance. Crude venom and TCh3 toxin inhibited action potential generation in invertebrate neurons expressing Na_V1.7-like channels. In these neurons, Tch2 and Tch4 toxins shifted voltage sensitivity to more negative potentials, ultimately widening the window current but decreasing channel availability. Conversely, Tch3 behaved as an inhibitory toxin, closing window currents and decreasing channel availability. Structural modeling showed that Tch3 adopts an αββ fold and binds the S3–S4 loop of Domain II in human Na_V1.7. These data show the diverse effects of scorpion venoms on channels and neurons, characterize its principal toxins, and show that Tch3 has therapeutic potential for pain relief. Full article

Src family tyrosine kinases regulate oocyte maturation and fertilization in many species, yet their physiological roles in Xenopus laevis (X. laevis) remain incompletely defined. Here, we generated three X. laevis Src (xSrc) constructs with defined point mutations allowing for selective immunochemical detection and controlled modulation of kinase activity: wild type (xSrcWT, Arg121His), constitutively active (xSrcKA, Arg121His/Tyr526Phe), and kinase-negative (xSrcKN, Arg121His/Lys294Met). Capped mRNAs were microinjected into immature oocytes, and effects on meiotic maturation and egg activation were analyzed. All constructs produced detectable Src protein within 4–5 h after injection without inducing progesterone-independent maturation. Following progesterone treatment, MAP kinase phosphorylation, CDK1 activation, and germinal vesicle breakdown (GVBD) occurred normally in all groups, although xSrcKA-expressing oocytes showed a modest but reproducible acceleration of MAPK activation and GVBD. Global tyrosine phosphorylation analysis revealed increased phosphorylation of several proteins, including a prominent ~50 kDa substrate, specifically in xSrcKA oocytes. After maturation, oocytes were subjected to artificial activation. xSrcKN-expressing oocytes responded normally to Ca²⁺ ionophore (A23187), indicating that Src activity is not required for direct Ca²⁺-mediated activation. In contrast, xSrcKN oocytes exhibited markedly reduced activation in response to hydrogen peroxide or Cathepsin B, which stimulate membrane-associated signaling pathways. These findings demonstrate that Src kinase activity is required for membrane signal-mediated egg activation but is dispensable for activation driven by direct intracellular Ca²⁺ elevation. Collectively, our results identify Src kinase as a positive regulator of progesterone-induced meiotic maturation and a critical mediator of specific fertilization-like activation pathways in X. laevis. Full article

The transport of metabolites across biological membranes is vital for normal cellular functions, including nutrient uptake, homeostasis, and toxin efflux. In eukaryotes, mitochondrial transporters in the inner mitochondrial membrane (IMM) play a pivotal role in energy production, metabolism, and the biosynthesis of a wide range of compounds. While functional assignments exist for over half of the mitochondrial transporters, emerging high-throughput methodologies underscore the need for reassessment and expansion of the current knowledge, particularly as evidence suggesting functional redundancy and substrate promiscuity has emerged. In this study, we investigated the substrate specificity of five yeast mitochondrial transporters—Crc1 (YOR100c), Ctp1 (YBR291c), Oac1 (YKL120w), Pet9 (YBL030c), and Yhm2 (YMR241w)—via heterologous gene expression in Xenopus laevis oocytes and liquid chromatography-mass spectrometry (LC-MS)-based transport assays. We used two substrate mixtures: a 17-compound organic acid mix and a ¹³C-labeled yeast metabolite extract. Our results revealed broader substrate specificities than previously reported, as partially supported by substrate docking simulations. Pet9 transported several organic acids and amino acids, while Yhm2 showed uptake of nine amino acids and fumaric acid. Additional promiscuous transport activity was observed for Crc1, indicating that these proteins may have more extensive metabolic roles than previously known. This study advances the understanding of yeast mitochondrial transporter function, demonstrating redundancy and broad substrate specificity among mitochondrial carriers. It highlights the importance of utilizing in vivo heterologous systems and physiologically relevant substrate mixtures to elucidate transporter functionality. Full article

The availability of biobanked tissues represents an important resource for translational research; however, functional investigations are generally limited to freshly collected samples. To address this limitation, we developed an innovative strategy to restore functional properties of frozen biopsies by microtransplanting patient-derived membrane proteins into Xenopus laevis oocytes. This study aimed to recover and characterize the physiological properties of human colon cancer cell membranes and to investigate the role of neurotransmitter-related signaling and ion currents in cancer. Membrane incorporation was assessed by immunohistochemical detection of tumor-specific markers, including carcinoembryonic antigen, together with confocal microscopy and ultrastructural analyses. Functional viability was evaluated using two-electrode voltage clamp recordings to assess endogenous calcium-activated chloride currents and responses to selected neurotransmitters. The successful incorporation of colon cancer membranes was confirmed by specific immunoreactivity and ultrastructural features consistent with cancer cell architecture. Although no functional responses to the tested neurotransmitters were detected, oocytes microinjected with cancer membranes showed a marked reduction or complete suppression in endogenous calcium-activated chloride currents. These findings demonstrate that membrane microtransplantation into Xenopus oocytes is a reliable translational approach to functionally investigate cancer cell membranes from frozen biopsies, and suggest that altered chloride channel activity may represent a baseline for new studies to investigate new potential therapeutic targets for colon cancer. Full article

OsHKT1;1, a member of the high-affinity K⁺ transporter (HKT) family, plays a key role in Na⁺ homeostasis and salinity tolerance in rice. In our previous study, multiple potential OsHKT1;1 splicing variants were identified, as well as the full-length (FL) OsHKT1;1 transcript from the salt-tolerant rice Pokkali. However, most previous studies focused solely on the full-length protein, leaving the transport functions of splice variants largely unexamined. In this study, we focused on the splice variant OsHKT1;1-V2 and compared its function and gene expression with those of OsHKT1;1-FL. Two-electrode voltage clamp experiments using Xenopus laevis oocytes revealed that the 1st start codon of OsHKT1;1-V2 is functional to exhibit bidirectional currents in bath solutions containing NaCl. Unlike the Na⁺-selective feature of OsHKT1;1-FL, OsHKT1;1-V2 primarily mediated Cl⁻ transport with weak Na⁺ selectivity, which was supported by the higher Cl⁻ accumulation in OsHKT1;1-V2–expressing oocytes. Subcellular localization analyses using oocytes and Arabidopsis mesophyll cells indicated plasma membrane localization of OsHKT1;1-V2, similar to OsHKT1;1-FL. Functional assays using a yeast mutant further indicated that OsHKT1;1-FL, but not OsHKT1;1-V2, mediates Na⁺ uptake. The same OsHKT1;1 variants were identified in the japonica cultivar Nipponbare, and OsHKT1;1-V2 of the cultivar showed Cl⁻ transport properties similar to the one from Pokkali. Quantitative PCR analyses revealed higher abundance of OsHKT1;1-FL transcripts in Nipponbare than in Pokkali with markedly lower OsHKT1;1-V2 levels in Pokkali under salt stress. This study provides a new insight into HKT-mediated ion homeostasis under salinity stress. Full article

Entomopathogenic nematodes (EPNs), including Steinernema and Heterorhabditis, are obligate insect parasites widely used in biological pest control. However, their efficacy is often limited by susceptibility to environmental stresses like desiccation. Aquaporins (AQPs), channel proteins facilitating water and solute movement across membranes, are hypothesized to play a key role in the osmotic stress response of EPNs. This study identified and cloned three AQP genes (L596_g7661, L596_g18121, and XLOC_007750) from four strains of Steinernema carpocapsae. Bioinformatic analysis confirmed that these AQPs belong to the aquaglyceroporin subfamily and share high sequence homology across strains. Functional characterization in Xenopus oocytes demonstrated that AQP L596_g7661 facilitates glycerol transport. Expression patterns under osmotic dehydration revealed significant upregulation of L596_g7661 and XLOC_007750 in all strains, while L596_g18121 expression remained unchanged. These findings indicate that specific AQPs are involved in the molecular response of S. carpocapsae to osmotic stress, providing crucial insights for breeding resilient EPN strains and enhancing their field application. Full article

R-limonene has been integrated into various pest control practices as a repellent or an insecticide. However, how limonene induces aversion or mortality remains largely unknown. To elucidate the underlying mechanisms, we conducted behavioral, toxicological, and electrophysiological assays in Aedes aegypti, a primary vector of human diseases. To investigate whether limonene acts on voltage-gated sodium channels and/or the Rdl (Resistance to dieldrin) receptor, two major targets of neuroactive insecticides, we characterized the effect of limonene on Ae. aegypti sodium and Rdl channels expressed in Xenopus oocytes. Limonene significantly potentiated GABA-induced chloride currents through Rdl in a concentration-dependent manner but had no effect on sodium channels. For repellency, limonene evoked spatial repellency in wild-type mosquitoes; however, the spatial repellency by limonene was significantly reduced in knockout mutants of Orco^−/− (odorant receptor co-receptor) and TRPA1^−/− (Transient Receptor Protein, subfamily A and member 1). These results indicate that limonene likely targets the Rdl receptor for insecticidal activity and limonene spatial repellency requires both Orco and TRPA1 channels. Our results reveal the involvement of multiple ion channels and receptors in the mosquito nervous system for limonene’s insecticidal and/or spatial repellency actions, highlighting limonene’s potential as a multi-target neuroactive agent for pest control. Full article

The Xenopus oocyte has long served as a versatile and powerful model for dissecting the molecular underpinnings of reproductive and developmental processes. Its large size, manipulability, and well-characterized cell cycle states have enabled generations of researchers to illuminate key aspects of oocyte maturation, fertilization, and early embryogenesis. This review provides an integrated overview of the cellular and molecular events that define the Xenopus oocyte’s transition from meiotic arrest to embryonic activation—or alternatively, to programmed demise if fertilization fails. We begin by exploring the architectural and biochemical landscape of the oocyte, including polarity, cytoskeletal organization, and nuclear dynamics. The regulatory networks governing meiotic resumption are then examined, with a focus on MPF (Cdk1/Cyclin B), MAPK cascades, and translational control via CPEB-mediated cytoplasmic polyadenylation. Fertilization is highlighted as a calcium-dependent trigger for oocyte activation. During fertilization in vertebrates, sperm-delivered phospholipase C zeta (PLCζ) is a key activator of Ca²⁺ signaling in mammals. In contrast, amphibian species such as Xenopus lack a PLCZ1 ortholog and instead appear to rely on alternative protease-mediated signaling mechanisms, including the uroplakin III–Src tyrosine kinase pathway and matrix metalloproteinase (MMP)-2 activity, to achieve egg activation. The review also addresses the molecular fate of unfertilized eggs, comparing apoptotic and necrotic mechanisms and their relevance to reproductive health. Finally, we discuss recent innovations in Xenopus-based technologies such as mRNA microinjection, genome editing, and in vitro ovulation systems, which are opening new avenues in developmental biology and translational medicine. By integrating classic findings with emerging frontiers, this review underscores the continued value of the Xenopus model in elucidating the fundamental processes of life’s origin. We conclude with perspectives on unresolved questions and future directions in oocyte and early embryonic research. Full article

Variants in CLCN3 and CLCN4, encoding the neuronal endosomal Cl⁻/H⁺ antiporters ClC-3 and ClC-4, are linked to neurodevelopmental disorders with broad phenotypic variability. Over sixty CLCN4 variants have been functionally characterized, showing gain- or loss-of-function (GoF or LoF) effects. While ClC-3 can function as a homodimer, ClC-4 depends on heterodimerization with ClC-3 for efficient endosomal trafficking. CLCN4, located on the X chromosome, exhibits diverse pathogenic outcomes: complete LoF variants often cause non-syndromic presentations in hemizygous males and are asymptomatic in heterozygous females, whereas certain missense variants with partial or complete LoF produce severe syndromic phenotypes in both sexes. Here, we demonstrate dominant effects of three CLCN4 variants within ClC-3/ClC-4 heterodimers using two-electrode voltage-clamp recordings in Xenopus laevis oocytes and whole-cell patch-clamp recordings in mammalian cells co-expressing both proteins via a bicistronic IRES construct. Our findings provide the first evidence of dominant-negative CLCN4 effects within ClC-3/ClC-4 complexes and establish a platform for functional analysis of additional disease-associated variants. Full article

The 26S proteasome is the main proteolytic machinery involved in protein degradation, thereby contributing to the homeostasis and stress response of eukaryotic cells. This macromolecular complex consists of a 20S core particle assembled with one or two 19S regulatory particles. Here, we describe the Plasmodium berghei (Pb) proteasome AAA-ATPase regulatory subunit Rpt3 and demonstrate its binding to the Protein Phosphatase 1 catalytic subunit (PP1c), which is one of the major and essential parasite phosphatases. The PbRpt3 protein enhances the activity of PP1c both in vitro and in a Xenopus oocyte heterologous model. Further investigation of this model suggests that the PbRpt3-PP1c interaction may occur outside of the proteasome, and it reveals that the RVxF motifs of PbRpt3 are involved in its binding and regulatory function. Moreover, the ATP-binding capacity of PbRpt3 may also contribute to its phosphatase regulatory activity. In the parasite, reverse genetic studies suggest an essential role for PbRpt3 during erythrocytic cycle of P. berghei, and an interactome analysis confirmed that PbRpt3 belongs to the 19S regulatory particle of the proteasome and may interact with proteins previously shown to be involved in phospholipid binding. Full article

Alpha7 nicotinic receptors (α7-nAChRs) are implicated in many neurological disorders, but how they fold and assemble is not well understood. Unlike native α7-nAChRs, α7-5HT3 chimeras fold efficiently in HEK cells and do not require chaperones RIC3 or TMEM35A (NACHO) for proper assembly. We investigated the effects of swapping 5HT3 and α7-receptor protein sequences on α7-5HT3R chimera surface expression in mammalian HEK293 or Bosc23 cells, or chimeric receptor function using Xenopus laevis oocytes with or without chaperones. α7-5HT3Rs, consisting of human α7-nAChRs with mouse 5HT3 transmembrane domains (TMs) express without chaperones as measured by cell surface alpha-bungarotoxin binding. However, when subunit TMs from α7-nAChRs and 5HT3Rs were mixed, chaperones were required. Substituting the SAP motif prior to the α7-nAChR “Latch” tail sequence for the 5HT3 C-terminal decreased expression relative to α7-nAChRs with chaperones. Chaperone effects on L264 and G265 mutations in M2 were also investigated. Some constructs that express well in HEK293 or Bosc23 cells are nonfunctional in oocytes with or without NACHO. Our data do not support direct binding of RIC3 or NACHO to the α7-nAChR TM4 (M4) region; instead, they emphasize the functional importance of the conserved SAP motif. Full article

In this review we propose the hypothesis that an energy-dissipating process precedes the continuous stimulation of insulin secretion by glucose. This process is mediated by connexin 36 hemichannels (Cx36H), or Cx36 connexons. Cx36H oligomers are expressed at the plasma membrane, and their gating activity (opening) is activated by plasma membrane depolarization after the closure of K⁺ATP channels by glucose (>5 mM) metabolism. This initial depolarization (1st step) might be responsible for the first phase of insulin secretion, with the subsequent opening of Cx36H increasing β-cell plasma membrane permeability, allowing for the efflux of metabolites (less than 1KD) (GABA, adenine nucleotides) and K⁺ (2nd step). This provokes a breakdown of oxidative glucose metabolism and the repolarization of the plasma membrane. As the extracellular glucose concentration increases further (>>5 mM), it exerts a progressive inhibition effect on Cx36H opening, allowing for the continuous stimulation of insulin secretion (3d step, second phase,). The glucose feature of regulating Cx36H closing with sigmoidal kinetics (8 mM IC₅₀ and around 20 mM at maximum) has been confirmed in mouse Cx36 connexin expression in Xenopus oocytes and in mouse islets stimulated by a range of glucose concentrations in the presence of 70 mM KCl. This gating activity was also inhibited by some non-metabolized glucose analogs. Glucose inhibition of Cx3H opening might not only contribute to making the insulin secretory response more specific for glucose but might also play a role in the pulsatility of sustained insulin secretion. Cx36H opening also offers the opportunity to potentiate the secretory effect in vivo by, permeant or not, metabolic stimuli. Confirmation of this novel physiological role for Cx36H in β-cells would place them as new susceptibility locus for type 1 and type 2 diabetes, whose physiological implication in the mechanism of insulin secretion regulation should be evaluated by in vivo studies in diabetic patients. Full article

Diverse neuronal nicotinic acetylcholine receptor (nAChR) subtypes are expressed in hippocampal interneurons. Single-cell analysis of mRNA expression previously revealed prominent co-expression of the α3 and β2 subunits within rat interneurons in the CA1 region. Although the α3 subunit (traditionally expressed together with β4) is usually associated with the peripheral nervous system, its significant co-expression with the β2 subunit in hippocampal interneurons suggests a distinct, potentially novel central nervous system nAChR subtype. We demonstrate that the human α3 and β2 subunits injected into Xenopus laevis oocytes can assemble into at least two functionally distinct subtypes of nAChRs based on different subunit stoichiometries. These subtypes exhibit similar reversal potentials but differ significantly in their desensitization kinetics and acetylcholine (ACh) affinities. The response obtained from a 1:5 α3:β2 mRNA injection ratio shows a higher affinity for ACh and significantly greater desensitization during prolonged ACh application compared to the response obtained from a 5:1 α3:β2 mRNA injection ratio. The identification of distinct functional α3β2 subtypes, characterized by differential desensitization kinetics and ACh affinity, could represent novel targets for the potential development of highly selective cognitive therapeutics for conditions such as Alzheimer’s disease, autism spectrum disorder, and attention deficit hyperactivity disorder, where hippocampal nAChRs are implicated. Full article

Prostate stem cell antigen (PSCA) is a Ly6/uPAR protein that targets neuronal nicotinic acetylcholine receptors (nAChRs). It exists in membrane-tethered and soluble forms, with the latter upregulated in Alzheimer’s disease. We hypothesize that PSCA may be linked to a wider spectrum of neurological diseases and could induce neuroinflammation. Indeed, PSCA expression is significantly upregulated in the brain of patients with multiple sclerosis, Huntington’s disease, Down syndrome, bipolar disorder, and HIV-associated dementia. To investigate PSCA’s structure, pharmacology, and inflammatory function, we produced a correctly folded water-soluble recombinant analog (ws-PSCA). In primary hippocampal neurons and astrocytes, ws-PSCA differently regulates secretion of inflammatory factors and adhesion molecules and induces pro-inflammatory responses by increasing TNFβ secretion. Heteronuclear NMR and ¹⁵N relaxation measurements reveal a classical β-structural three-finger fold with conformationally disordered loops II and III. Positive charge clustering on the molecular surface suggests the functional importance of ionic interactions by these loops. Electrophysiological studies in Xenopus oocytes point on ws-PSCA inhibition of α3β2-, high-, and low-sensitive variants of α4β2- (IC₅₀ ~50, 27, and 15 μM, respectively) but not α4β4-nAChRs, suggesting targeting of the β2 subunit. Ensemble docking and molecular dynamics simulations predict PSCA binding to high-sensitive α4β2-nAChR at α4/β2 and β2/β2 interfaces. Complexes are stabilized by ionic and hydrogen bonds between PSCA’s loops II and III and the primary and complementary receptor subunits, including glycosyl groups. This study gives new structural and functional insights into PSCA’s interaction with molecular targets and provides clues to understand its role in the brain function and mental disorders. Full article

This study aimed to investigate the glycaemic control potential and modulation of GABA-induced chloride currents (I_GABA) of H. revolutum and the possible bioactive xanthones. Fractions from the leaf and stem extracts (dichloromethane and methanol) were assessed for in vitro α-glucosidase-inhibitory potential and their ability to modulate I_GABA (GABAergic effect) through GABA_A receptors heterologously expressed in Xenopus oocytes. Xanthones 4-hydroxy-2,3-dimethoxy-9H-xanthen-9-one (1), 3-hydroxy-2,4-dimethoxy-9H-xanthen-9-one (2) and trans-3-(4-hydroxy-3-methoxyphenyl)-2-(hydroxymethyl)-5-methoxy-2,3-dihydro-7H-[1,4]dioxino[2,3-c]xanthen-7-one (3) were isolated from the stem and tested in the GABA_A receptors assay, but only 3 was assessed for α-glucosidase-inhibitory action. Compared to acarbose (IC₅₀ = 6.16 µM), 3 showed a mild to moderate α-glucosidase-inhibitory activity (IC₅₀ = 45.1 µM), which may be attributed to the absence of a hydroxyl group at its xanthone core. Isomeric compounds 1 and 2 significantly enhanced I_GABA with similar efficacy, while 3 was inactive, which may be attributed to its notable structural difference (cyclic ether substitution) compared to compounds 1 and 2. H. revolutum stem contains xanthones with α-glucosidase-inhibitory potential, which also enhance I_GABA and could be further studied as a medicinal plant for managing GABA_A receptor-mediated mental disorders and/or diabetes. Full article