An Automated and Highly Sensitive Chemiluminescence Immunoassay for Diagnosing Mushroom Poisoning

Mushrooms containing Amanita peptide toxins are the major cause of mushroom poisoning, and lead to approximately 90% of deaths. Phallotoxins are the fastest toxin causing poisoning among Amanita peptide toxins. Thus, it is imperative to construct a highly sensitive quantification method for the rapid diagnosis of mushroom poisoning. In this study, we established a highly sensitive and automated magnetic bead (MB)-based chemiluminescence immunoassay (CLIA) for the early, rapid diagnosis of mushroom poisoning. The limits of detection (LODs) for phallotoxins were 0.010 ng/ml in human serum and 0.009 ng/ml in human urine. Recoveries ranged from 81.6 to 95.6% with a coefficient of variation <12.9%. Analysis of Amanita phalloides samples by the automated MB-based CLIA was in accordance with that of HPLC-MS/MS. The advantages the MB-based CLIA, high sensitivity, repeatability, and stability, were due to the use of MBs as immune carriers, chemiluminescence as a detection signal, and an integrated device to automate the whole process. Therefore, the proposed automated MB-based CLIA is a promising option for the early and rapid clinical diagnosis of mushroom poisoning.

TOXIC AND IMMUNE ALLERGIC RESPONSES OF ANT VENOM TOXINS: A REVIEW

Present review article explains ant venom components and its allergic and biological effects in man and animals. Red ants or small fire ants secrete and inject venom very swiftly to defend their nest against predators, microbial pathogens, and competitors and to hunt the prey. Ant venom is a mixture of various organic compounds, including peptides, enzymes, and polypeptide toxins. It is highly toxic, allergic, invasive and venomous. It imposes sever paralytic, cytolytic, haemolytic, allergenic, pro-inflammatory, insecticidal, antimicrobial, and pain-producing pharmacologic activities after infliction. Victims show red ring-shaped allergic sign with regional swelling marked with intense pain. Ant venom also contains several hydrolases, oxidoreductases, proteases, Kunitz-like polypeptides, and inhibitor cysteine knot (ICK)-like (knottin) neurotoxins and insect defensins. Ant venom toxins/proteins generate allergic immune responses and employ eosinophils and produce Th2 cytokines, response. These compounds from ant venom could be used as a potential source of new anticonvulsants molecules. Ant venoms contain many small, linear peptides, an untapped source of bioactive peptide toxins. The remarkable insecticidal activity of ant venom could be used as a promising source of additional bio-insecticides and therapeutic agents.

The antimicrobial peptide MK58911-NH2 acts on planktonic, biofilm and intramacrophage cells of Cryptococcus neoformans

Cryptococcosis is associated with high rates of morbidity and mortality, especially in AIDS patients. Its treatment is carried out by combining amphotericin B and azoles or flucytosine, which cause unavoidable toxicity issues to the host. Thus, the urgency in obtaining new antifungals drives the search for antimicrobial peptides (AMPs). This study aimed to extend the understanding of the mechanism of action of an AMP analog from wasps peptide toxins, MK58911-NH2, on Cryptococcus neoformans . It was also evaluated if MK58911-NH2 can act on cryptococcal cells in macrophages, biofilms, and an immersion zebrafish model of infection. Finally, we investigated the structure-antifungal action and the toxicity relation of MK58911-NH2 fragments and a derivative of this peptide (MH58911-NH2). The results demonstrated that MK58911-NH2 did not alter the fluorescence intensity of cell wall - binding dye calcofluor or capsule- binding dye 18b7 antibody-FITC of C. neoformans , but rather reduced the number and size of fungal cells. This activity reduced the fungal burden of C. neoformans both in macrophages and in zebrafish embryos as well as within biofilms. Three fragments of the MK58911-NH2 peptide showed no activity against Cryptococcus or toxicity in lung cells. The derivative peptide MH58911-NH2, in which the lysine residues of MK58911-NH2 were replaced by histidine, reduced the activity against extracellular and intracellular C. neoformans . On the other hand, it was active against biofilm, and reducing toxicity. In summary, the results showed that peptide MK58911-NH2 could be a promising agent against cryptococcosis. The work also opens a perspective for the verification of the antifungal activity of other derivatives.

Itch in Hymenoptera Sting Reactions

Insect stings and the resulting itch are a ubiquitous problem. Stings by members of the insect order Hymenoptera, which includes sawflies, wasps, bees and ants, and especially by bees and wasps are extremely common, with 56–94% of the population being stung at least once in their lifetime. The complex process of venom activity and inflammation causes local reactions with pain and pruritus, sometimes anaphylactic reactions and more seldomly, as in case of numerous stings, systemic intoxication. We reviewed the literature regarding itch experienced after Hymenoptera stings, but found no study that placed a specific focus on this topic. Hymenoptera venoms are composed of many biologically active substances, including peptide toxins and proteinaceous toxins. Peptide toxins from bee venom cause cell lysis and ion channel modulation in the peripheral and central nervous systems, while toxins from wasp venom induce mast cell degranulation and chemotaxis of polymorphonuclear leukocytes in the skin. The proteinaceous toxins cause a disruption of the cell membranes and necrotic cell death, degradation of hyaluronan (an extracellular matrix glycosaminoglycan), increased vascular permeability, hemolysis, as well as activated platelet aggregation. Mediators which could be directly involved in the venom-induced pruritus include histamine and tryptase released from mast cells, interleukin-4 and interleukin-13 from Th2 lymphocytes, as well as leukotriene C4. We postulate that a pruriceptive itch is induced due to the pharmacological properties of Hymenoptera venoms.

Drosophila nicotinic acetylcholine receptor subunits and their native interactions with insecticidal peptide toxins

Drosophila nicotinic acetylcholine receptors (nAChRs) are ligand-gated ion channels that present a target for insecticides. However, a better understanding of receptor subunit composition is needed for effective design of insecticides. Peptide neurotoxins are known to block nAChRs by binding to its target subunits. To facilitate the analysis of nAChRs we used a CRISPR/Cas9 strategy to generate null alleles for all ten nAChR subunit genes. We studied interactions of nAChR subunits with peptide neurotoxins by larval injections and styrene maleic acid lipid particles (SMALPs) pull-down assays. For the null alleles we determined the effects of α-Bungarotoxin (α-Btx) and ω-Hexatoxin-Hv1a (Hv1a) administration, identifying potential receptor subunits implicated in the binding of these toxins. We employed pull-down assays to confirm α-Btx interactions with the Dα5, Dα6, Dα7 subunits. Finally, we report the localization of fluorescent tagged endogenous Dα6 during nervous system development. Taken together this study elucidates native Drosophila nAChR subunit interactions with insecticidal peptide toxins.

Phosphoproteomics Identifies Significant Biomarkers Associated with the Proliferation and Metastasis of Prostate Cancer

The spider peptide toxins HNTX-III and JZTX-I are a specific inhibitor and activator of TTX-S VGSCs, respectively. They play important roles in regulating MAT-LyLu cell metastasis in prostate cancer. In order to identify key biomarkers involved in the regulation of MAT-LyLu cell metastasis, iTRAQ-based quantitative phosphoproteomics analysis was performed on cells treated with HNTX-III, JZTX-I and blank. A total of 554 unique phosphorylated proteins and 1779 distinct phosphorylated proteins were identified, while 55 and 36 phosphorylated proteins were identified as differentially expressed proteins in HNTX-III and JZTX-I treated groups compared with control groups. Multiple bioinformatics analysis based on quantitative phosphoproteomics data suggested that the differentially expressed phosphorylated proteins and peptides were significantly associated with the migration and invasion of prostate tumors. Specifically, the toxins HNTX-III and JZTX-I have opposite effects on tumor formation and metastasis by regulating the expression and phosphorylation level of causal proteins. Herein, we highlighted three key proteins EEF2, U2AF2 and FLNC which were down-regulated in HNTX-III treated cells and up-regulated in JZTX-I treated cells. They played significant roles in cancer related physiological and pathological processes. The differentially expressed phosphorylated proteins identified in this study may serve as potential biomarkers for precision medicine for prostate cancer in the near future.

A comprehensive review of peptide toxins vs synthetic modulators of BK channels in Epilepsy

BK channels, or voltage-gated Ca2+ channels, are essential regulators of neuronal excitability and muscular contractions, all of which are abnormal in epilepsy, a chronic neuronal disease. The form, frequency, and transmission of action potentials (APs), as well as neurotransmitter release from presynaptic terminals, are all influenced by BK channels found in the plasma membrane of neurons. Over the last two decades, several naturally occurring BK channel modulators have attracted a lot of attention. The structural and pharmacological properties of BK channel blockers are discussed in this article. The properties of various venom peptide toxins from scorpions and snakes are first identified, with a focus on their distinctive structural motifs, such as their disulfide bond formation pattern, the binding interface between the toxin and the BK channel, and the functional consequences of the toxins' blockage of BK channels. Then, several non-peptide BK channel blockers are discussed, along with their molecular formula and pharmacological impact on BK channels. The precise categorization and explanations of these BK channel blockers are hoped to provide mechanistic insights into BK channel blockade. The structures of peptide toxins and non-peptide compounds may serve as models for the development of new channel blockers, as well as aid in the optimization of lead compounds for use in neurological disorders.

ANTIAPOPTOTIC POTENTIAL OF SPIDER TOXINS

Arthropod peptide toxins rich in disulfide bonds are one of the potential sources of bioactive substances. Due to their structure, toxins have increased stability and are able to bind to ion channels, blocking them or changing the gating mechanism. Some spider toxins bind to different types of calcium channels. Calcium ions, in turn, play an important role in many cellular processes, namely, apoptosis. The aim of this paper is to investigate the effect of a number of toxins – arachnid ion-channel blockers in – on intracellular processes associated with the induction of apoptosis in mammalian cells. Materials and Methods. Toxins ω-hexatoxin-Hv1a, ω-theraphotoxin-Hhn2a were used in the study, as they are inhibitors of L- and P/Q-type calcium channels, respectively. Apoptosis was induced using the AC-1001H3 peptide. The authors used fluorescence microscopy to study the effect of toxins on the apoptosis level, oxidative stress, and mitochondrial potential in CHO-K1 cells. Results. The authors observed that incubation of cells with toxins (10 nM) and AC-1001H3 peptide led to increased ROI intracellular concentration, which should have induced apoptotic mechanisms. However, the effect was the opposite. In addition, there was an increase in the mitochondrial potential level. Despite this, the used toxins blocked apoptosis caused by AC-1001H3 and reduced the natural apoptosis level in the CHO-K1 cells. Conclusion. The study demonstrated the antiapoptotic effect of some arthropod peptide toxins. The studied toxins can be used in the treatment of pathologies associated with the activation of apoptotic mechanisms. Keywords: apoptosis, spider toxin, peptide. Пептидные токсины членистоногих, богатые дисульфидными связями, являются одним из потенциальных источников биоактивных веществ. За счет своей структуры токсины обладают повышенной стабильностью и способны связываться с ионными каналами, блокируя их или изменяя механизм стробирования. Ряд токсинов пауков способен связываться с кальциевыми каналами разных типов. Ионы кальция в свою очередь играют важную роль во многих процессах в клетке, одним из которых является апоптоз. Цель работы – исследовать влияние ряда токсинов – блокаторов ионных каналов паукообразных – на внутриклеточные процессы, связанные с индукцией апоптоза в клетках млекопитающих. Материалы и методы. В исследовании использовались токсины ω-hexatoxin-Hv1a, ω-theraphotoxin-Hhn2a, которые являются ингибиторами кальциевых каналов L- и P/Q-типов соответственно. Индукция апоптоза проводилась с использованием пептида AC-1001H3. Изучалось влияние токсинов на уровень апоптоза, оксидативного стресса и митохондриального потенциала в клетках линии CHO-K1 с использованием методов флуоресцентной микроскопии. Результаты. Было установлено, что инкубация клеток с токсинами в концентрации 10 нМ и индуктором апоптоза AC-1001H3 приводила к росту внутриклеточной концентрации активных форм кислорода, что должно индуцировать апоптотические механизмы, однако эффект был противоположным. Кроме того, происходило повышение уровня митохондриального потенциала. Несмотря на это использованные токсины блокировали апоптоз, вызванный AC-1001Н3, и снижали уровень естественного апоптоза в культуре клеток CHO-K1. Выводы. Проведенное исследование продемонстрировало антиапоптотический эффект ряда пептидных токсинов членистоногих. Изученные токсины могут найти применение при лечении патологии, связанной с активацией апоптотических механизмов. Ключевые слова: апоптоз, токсин паука, пептид.