Search Results (236)

α-Latrotoxin stimulates neurotransmitter release by binding to a presynaptic receptor and then forming ion-permeable membrane pores and/or stimulating the receptor, latrophilin-1, or Adhesion G-protein-coupled receptor type L1 (ADGRL1). To avoid pore formation, we use the mutant α-latrotoxin (LTX^N4C), which does not form pores and only acts through ADGRL1. ADGRL1 is cleaved into an N-terminal fragment (NTF) and a C-terminal fragment (CTF), which behave as independent cell-surface proteins, reassociating upon binding LTX^N4C. We investigated the role of the NTF-CTF association in LTX^N4C action, using perfluorooctanoic acid (PFOA). We demonstrate that at low concentrations (≤100 μM) PFOA does not adversely affect ADGRL1-expressing neuroblastoma cells or inhibit LTX^N4C binding. However, it causes the dissociation of the NTF-CTF complexes, independent redistribution of the fragments on the cell surface, and their separate internalization. PFOA also promotes the dissociation of NTF-CTF complexes induced by LTX^N4C binding. When applied to mouse neuromuscular junctions, PFOA inhibits LTX^N4C-induced neurotransmitter release in a concentration-dependent manner. Our results indicate that ADGRL1 can mediate LTX^N4C signaling only while its fragments remain associated. These findings explain some aspects of receptor-dependent toxin action and contribute to a mechanistic understanding of ADGRL1 functions in neurons. Full article

Background: Tariquidar (Tq) is an inhibitor of the multidrug resistance (MDR) proteins relevant to ATP-binding cassette transporters (ABC transporters), which suppresses the ATP-dependent efflux of a variety of hydrophilic and amphipathic compounds, including anticancer drugs. Tq is a representative of a new generation of MDR inhibitors with high affinity to ABC proteins. However, there are still no data on the possible effect of Tq on mitochondria as an important target in the regulation of cell death or survival. Methods: We investigated the influence of Tq on the Ca²⁺-dependent mitochondrial permeability transition pore (mPTP). The effect of Tq was assessed using several parameters, including the calcium load, membrane potential, and mitochondrial swelling. To evaluate the specific targets of Tq, selective inhibitors of components of the mitochondrial pore were used, including adenine nucleotides, carboxyatractylozide (Catr) and bongkrekic acid (BA), oligomycin, and cyclosporine A. Results: Tq decreased the calcium retention capacity, activated mitochondrial swelling, and lowered the influence of ADP and ATP, the inhibitors of the Ca²⁺-induced pore opening, at their low concentrations. These effects of Tq were observed in both calcium-load and swelling assays, thus mimicking the effect of Catr, a selective inhibitor of adenine nucleotide translocase (ANT). Tq also decreased the protective effect of BA, an inhibitor of ANT and mPTP, on the calcium retention capacity of mitochondria. Further, Tq dose-dependently decreased the inhibitory effect of a low ATP concentration but not of high concentrations, at which the effect of Tq was activated by oligomycin, an inhibitor of F-ATP synthase. Conclusions: The influence of Tq extends to mitochondria, specifically to the regulation of membrane permeability, promoting the activation of pore opening, probably through an interaction with ANT, a component of the pore-forming complex. The effect of Tq on the opening of mPTP is strongly dependent on the concentrations of adenine nucleotides and, consequently, on the functional state of mitochondria. The direct influence of Tq on mitochondria can be considered as a new activity that promotes the sensitization of cells to various treatments and stimuli. Full article

Calcium is a versatile ion that regulates diverse intracellular processes, including cell death and survival, cytokine and chemokine production, lipid scrambling, and immune cell activation. In regulated necrosis, an early increase in cytosolic calcium is a hallmark of pathways such as pyroptosis, necroptosis, and ferroptosis, and resembles the calcium surge triggered by pore-forming toxins. The complexity of calcium signaling is orchestrated by specialized channels in various cellular compartments and calcium-binding proteins that respond to localized calcium concentrations. However, the coordination of this intricate code during regulated necrosis and its connections to other calcium-driven processes remains poorly understood. This review provides an overview of the molecular mechanisms of calcium signaling in regulated necrosis, analyzing parallels with pore-forming toxin-mediated membrane damage to uncover nodes that are shared by these seemingly independent pathways. We also discuss advanced techniques for studying calcium dynamics, with high precision, that can be applied to study regulated necrosis. Calcium signaling emerges as a central hub where necrotic cell death pathways converge, shaping the unique signatures of dying cells and influencing their communication with the immune system. This integrated perspective highlights the complex and multifaceted role of calcium in cells and its implications for fundamental cellular processes. Full article

Cone snails are a large group of marine gastropods that produce a complex mixture of toxic compounds to hunt prey and defend against predators. The majority of the venom comprises small toxic peptides named conotoxins, which target membrane receptors. In contrast, a smaller part of the venom contains larger proteins and conoproteins, which are thought to be involved in conotoxin maturation and the envenomation process, respectively. Interestingly, many species of cone snails contain conoporins, which are similar to actinoporins—pore-forming toxins found in sea anemones. These actinoporin-like proteins (ALPs) have recently been detected in many molluscan species, and only a few have been experimentally characterized. Due to being highly expressed in the venom gland of many cone snail species, conoporins are thought to play an important part in the envenomation process. Despite this, the exact function of conoporins is currently unknown. We propose several hypotheses aiming to elucidate their biological role. Full article

Recent work has identified biomphalysin (BM) protein from the snail Biomphalaria glabrata as a cytolytic toxin against the Schistosoma mansoni parasite. Ex vivo interactome studies further evidenced BM’s ability to bind bacterial outer membrane proteins, but its specific antibacterial mechanisms and selectivity remain unclear. Accordingly, this study aims to elucidate the interaction between BM and two model bacteria with distinct cell surface architectures: Escherichia coli (Gram−) and Micrococcus luteus (Gram+). Employing a multiscale approach, we used in vivo single-molecule force spectroscopy (SMFS) to probe molecular interactions at the single cell level. Combined with cell aggregation assays, immunoblotting and Atomic Force Microscopy (AFM) imaging, SMFS results evidenced a selective interaction of BM from snail plasma with M. luteus but not E. coli. Exposure of M. luteus to BM compromised cell surface integrity and induced cell aggregation. These effects correlated with a patch-like distribution of BM on M. luteus reminiscent of pore-forming toxins, as revealed by the anti-BM antibody-functionalized AFM tip. Overall, this work highlights the utility of SMFS in dissecting host–pathogen molecular dialogs. It reveals BM’s selective action against M. luteus, potentially via surface clustering, and it shows spatially heterogeneous responses to the toxin within and between individual cells. Full article

Hyperosmolality-gated calcium-permeable cation channel protein denoted as OSCA, which are mechanosensitive pore-forming ion channels, play a pivotal role in plants’ responses to abiotic stressors. Notopterygium franchetii, an endemic perennial plant species distributed in the Qinghai–Tibetan Plateau and its adjacent high-altitude regions, is likely to have undergone adaptive evolution in response to extreme abiotic stress conditions. The current study was conducted to characterize the genome-wide characteristics and phylogenetic evolution of the OSCA gene family in N. franchetii and identify its response patterns to drought and high-temperature stresses. We examined the gene family’s structural features, phylogenetic relationships, and response to abiotic stresses. The N. franchetii genome had 29 OSCA gene family members on 11 chromosomes. Subcellular localization showed they were mainly in the cell membrane, and a promoter cis-acting element study found that the OSCA gene family contained methyl jasmonate, abscisic acid, and various adversity and hormone response components. Under drought stress, most of the NofOSCAs genes showed a tendency to increase over time in the roots of N. franchetii, while in the aboveground parts, most of the NofOSCAs genes showed a tendency to increase and then decrease. The expression of different NofOSCAs genes in N. franchetii also showed alternating changes under high-temperature stress. Nine members of NofOSCAs were found to be linked to the PPI network, and these members were involved in membrane structure, transmembrane transport, and ion channel function. Our analysis of differential expression revealed that the expression of OSCA genes differed among the different N. franchetii tissues, with the roots exhibiting the highest average expression level, and many genes displayed tissue-specific high expression patterns. These results provided novel insights into the phylogenetic evolution and abiotic stress response mechanisms in the high-altitude medicinal herb N. franchetii. Full article

K. alvarezii is a red macroalgae cultivated on a large scale in Asian countries. In Brazil, it is cultivated in states such as Piaui, Rio de Janeiro, and São Paulo due to the high economic value for the food industry given the high concentrations of carrageenan, a hydrocolloid formed mainly by carbohydrates, used as a gelling agent and emulsifier. Therefore, to aggregate value to its protein content, the goal was to identify the proteins from K. alvarezii and biotechnological potentials against human pathogens. The protein extract produced Na⁺-acetate buffer was the most efficient in inhibiting the growth of C. parapsilosis and C. krusei. The analysis of the mechanism of action revealed that proteins from K. alvarezii cause severe damage to cellular morphology, including the effect on the cell wall and membrane, as indicated by scanning electron microscopy (SEM). Fluorescence microscopy agreed with the SEM results, revealing an increase in membrane permeabilization and pore formation, in addition to high levels of ROS, followed by apoptosis triggered by caspase 3/7. Regarding the characterization of proteins, biochemical analysis revealed the presence of proteolytic enzymes and those involved in ROS metabolism. Proteomic analysis by LC-ESI-MS/MS identified 336 proteins involved in processes such as energetic and nucleotide metabolism, defense against (a)biotic stress, and protein folding. Our results revealed that K. alvarezii proteins presented potential against C. parapsilosis and C. krusei. Full article

Gram-negative bacteria release outer membrane vesicles (OMVs) that deliver various molecules, including virulence factors, to interact with their host. Recent studies have suggested that OMVs may also serve as carriers for RNAs, particularly small regulatory noncoding RNAs (sRNAs). For these RNAs to function effectively, they typically require a protein cofactor, Hfq, known as an RNA chaperone. In previous work, using molecular imaging, Circular Dichroism CD, and InfraRed FTIR spectroscopies, we demonstrated that Hfq interacts with the bacterial inner membrane and forms pores, suggesting a possible role in translocating RNA from the cytoplasm to periplasm and then to OMVs. In this study, we expand on our previous findings and provide evidence that RNA molecules bind to the Escherichia coli inner membrane in an Hfq-dependent manner. Moreover, we show that the lipid nature, in particular the presence of a cardiolipin-rich domain, is crucial for this interaction. These results reveal a new aspect of RNA translocation through the inner membrane, for further packaging in OMVs, and underscore the importance of Hfq in this mechanism. Full article

The perivitellin-2 (PV2) from snails is an unusual neuro and enterotoxin comprising a pore-forming domain of the Membrane Attack Complex and Perforin Family (MACPF) linked to a lectin. While both domains have membrane binding capabilities, PV2’s mechanism of action remains unclear. We studied the apple snail Pomacea maculata PV2’s (PmPV2’s) interaction with lipid membranes using various biophysical and cell biology approaches. In vitro studies showed that PmPV2 toxicity decreased when cholesterol (Chol) was diminished from enterocyte cell membranes. Chol enhanced PmPV2 association with phosphatidylcholine membranes but did not induce pore formation. In contrast, using rat brain lipid models, rich in glycolipids, PmPV2 exhibited high affinity and induced vesicle permeabilization. Negative stain electron microscopy and atomic force microscopy confirmed the formation of pore-like structures in brain lipid vesicles. Our findings suggest that Chol is a necessary lipid component and point to PmPV2–glycolipid interactions as potential activators critical to triggering PmPV2’s pore-forming activity, providing insights into this novel toxin’s mechanism. Full article

During sexual reproduction, the freshwater ciliate Tetrahymena thermophila sheds membrane-bound vesicles into the extracellular environment (cEMVs: ciliary extracellular micro-vesicles). We provide evidence that 100 nm vesicles shed from the cilia of starved cells promote mating between cells of complementary mating types. A proteomic analysis revealed that these EMVs are decorated with mating-type proteins expressed from the MAT locus, proteins that define a cell’s sex (one of seven). Once the mating junction is established between cells, smaller 60 nm vesicles (junction vesicles) appear within the extracellular gap that separates mating partners. Junction vesicles (jEMVs) may play a role in remodeling the mating junction through which gametic pronuclei are exchanged. Evidence is presented demonstrating that cells must be able to internalize extracellular signals via some form of endocytosis in order to trigger conjugation. Finally, an evolutionarily conserved fusogen (Hap2) implicated in pore formation also appears necessary for jEMV processing. This system offers an excellent opportunity for studies on ectosome shedding, intercellular signaling and shed vesicle uptake by macro-pinocytosis, as they relate to sexual reproduction in the ciliate Tetrahymena thermophila. Full article

Voltage-gated Ca²⁺ (Ca_V) channels are transmembrane proteins comprising the pore-forming subunit Ca_Vα₁ and the ancillary proteins Ca_Vα₂δ and Ca_Vβ. They are expressed in various tissues, including the nervous system, where they regulate Ca²⁺ entry in response to membrane potential changes. The increase in intracellular Ca²⁺ allows for regulating cell excitability and releasing neurotransmitters, among other cellular events. Leucine-rich repeat kinase 2 (LRRK2) is a serine–threonine kinase involved in vesicular mobilization. Previously, it has been shown that LRRK2 regulates neurotransmission by phosphorylating the Ca_Vβ auxiliary subunit of the Ca_V2.1 (P/Q-type) presynaptic channels. However, it is unknown whether the kinase can regulate the activity of other Ca_V channel subtypes, such as Ca_V1.3 (L-type), which play a significant role in the excitability of dopaminergic neurons in the substantia nigra pars compacta (SNc) and whose dysregulation contributes to neurodegeneration in Parkinson’s disease (PD). Here, we found potential phosphorylation sites for LRRK2 in Ca_Vβ₃ and examined how these molecules interact. We used immunoprecipitation and electrophysiology in HEK-293 cells expressing recombinant Ca_V1.3 channels, both with and without wild-type LRRK2 or its LRRK2^G2019S mutation, which plays a role in familial PD through a possible gain-of-toxic-function mechanism. Our results show that LRRK2^G2019S significantly increases current density through Ca_V1.3 channels, and this effect depends on the presence of Ca_Vβ₃. Site-directed mutagenesis revealed that phosphorylation at S152 in the sequence of Ca_Vβ₃ is necessary and sufficient to explain the abnormal regulation of the channels mediated by LRRK2^G2019S. These data provide new insights into the molecular regulation that mutant LRRK2 may exert on L-type Ca_V1.3 channels, which determine pacemaker activity in dopaminergic neurons of the SNc and may, therefore, play a relevant role in the molecular pathophysiology of PD. Full article

Pore-forming peptides are promising antimicrobial and anticancer agents due to their membrane selectivity and biodegradability. Our prior work identified peptide M159, which permeabilized synthetic phosphatidylcholine liposomes without mammalian cell toxicity. Here, we report that the D-type variant (D-M159) induces apoptosis in HeLa cells under starvation. To explore its anticancer mechanism, we analyzed D-M159 cytotoxicity, intracellular uptake, and apoptotic pathways via flow cytometry, confocal microscopy, and Western blot. Calcium dynamics and mitochondrial function were examined via specific labeling and functional assays. Results revealed that D-M159 exhibited starvation-dependent, dose-responsive cytotoxicity and triggered apoptosis in HeLa cells. Mechanistic studies indicated that D-M159 entered the cells via caveolin-dependent and caveolae-dependent endocytosis pathways and induced endoplasmic reticulum stress in HeLa cells by up-regulating proteins such as ATF6, p-IRE1, PERK, GRP78, and CHOP. Meanwhile, D-M159 promoted the expression of IP3R1, GRP75, and VDAC1, which led to mitochondrial calcium iron overload, decreased mitochondrial membrane potential, and increased reactive oxygen species (ROS) generation, thereby activating the mitochondrial apoptotic pathway and inducing the aberrant expression of Bax, Bcl-2, Caspase-9, and Caspase-3. This study showed that D-M159 synergistically induced apoptosis in starved HeLa cells through endoplasmic reticulum stress and mitochondrial dysfunction, demonstrating its potential as a novel anticancer agent. Full article

Continental rift zones on the early Earth provided essential conditions for the emergence of the first cells. These conditions included an abundant supply of raw materials, cyclic fluctuations in pressure and temperature over millions of years, and transitions of gases between supercritical and subcritical phases. While evidence supports vesicle formation and the chemical evolution of peptides, the mechanism by which information was stored remains unresolved. This study proposes a model illustrating how interactions among organic molecules may have enabled the encoding of amino acid sequences in RNA. The model highlights the interplay between three key molecular components: a proto-tRNA, the vesicle membrane, and short peptides. The vesicle membrane acted as a reservoir for hydrophobic amino acids and facilitated their attachment to proto-tRNA. As a single strand, proto-tRNA also served as proto-mRNA, enabling it to be read by charged tRNAs. By replicating this information and arranging RNA strands, the first functional peptides such as pore-forming proteins may have formed, thus improving the long-term stability of the vesicles. This model further outlines how these vesicles may have evolved into the earliest cells, with enzymes and larger RNA molecules giving rise to tRNA and ribosomal structures. Shearing forces may have facilitated the first cellular divisions, representing a pre-LUCA stage. Full article

As a porous crystalline material, covalent organic frameworks (COFs) have attracted significant attention due to their extraordinary features, such as an ordered pore structure and excellent stability. Synthesized through the aldehyde amine condensation reaction, TpPa-1 COFs (Triformylphloroglucinol-p-Phenylenediamine-1 COFs) were blended with cellulose acetate (CA) to form a casting solution. The TpPa-1 COF/CA ultrafiltration membrane was then prepared using the non-solvent-induced phase inversion (NIPS) method. The influence of TpPa-1 COFs content on the hydrophilicity, stability and filtration performance of the modified membrane was studied. Due to the hydrophilic groups in TpPa-1 COFs and the network structure formed by covalent bonds, the modified CA membranes exhibited higher hydrophilicity and lower protein adsorption compared with the pristine CA membrane. The porous crystalline structure of TpPa-1 COFs increased the water permeation path in the CA membrane, improving the permeability of the modified membrane while maintaining an outstanding bovine serum albumin (BSA) rejection. Furthermore, the addition of TpPa-1 COFs reduced protein adsorption on the CA membrane and overcame the trade-off between permeability and selectivity in CA membrane bioseparation applications. This approach provides a sustainable method for enhancing membrane performance while enhancing the application of membranes in protein purification. Full article

α-Latrotoxin (αLTX) causes exhaustive release of neurotransmitters from nerve terminals in the absence of extracellular Ca²⁺ (Ca²⁺_e). To investigate the mechanisms underlying this effect, we loaded mouse neuromuscular junctions with BAPTA-AM. This membrane-permeable Ca²⁺-chelator demonstrates that Ca²⁺_e-independent effects of αLTX require an increase in cytosolic Ca²⁺ (Ca²⁺_cyt). We also show that thapsigargin, which depletes Ca²⁺ stores, induces neurotransmitter release, but inhibits the effect of αLTX. We then studied αLTX’s effects on Ca²⁺_cyt using neuroblastoma cells expressing signaling-capable or signaling-incapable variants of latrophilin-1, a G protein-coupled receptor of αLTX. Our results demonstrate that αLTX acts as a cation ionophore and a latrophilin agonist. In model cells at 0 Ca²⁺_e, αLTX forms membrane pores and allows the influx of Na⁺; this reverses the Na⁺-Ca²⁺ exchanger, leading to the release of stored Ca²⁺ and inhibition of its extrusion. Concurrently, αLTX stimulates latrophilin signaling, which depletes a Ca²⁺ store and induces transient opening of Ca²⁺ channels in the plasmalemma that are sensitive to inhibitors of store-operated Ca²⁺ entry. These results indicate that Ca²⁺ release from intracellular stores and that Ca²⁺ influx through latrophilin-activated store-operated Ca²⁺ channels contributes to αLTX actions and may be involved in physiological control of neurotransmitter release at nerve terminals. Full article