N-Acetylcysteine reverses silver nanoparticle intoxication in rats.

The increasing use of silver nanoparticles (AgNPs) in consumer products raises the risk of human toxicity. Currently, there are no therapeutic options or established treatment protocols in cases of AgNPs intoxication. We demonstrated previously that thiol antioxidants compounds can reverse the cytotoxicity induced by AgNPs in Huh-7 hepatocarcinoma cells. Here, we investigated the use of N-acetylcysteine (NAC) against the systemic toxic effects of AgNPs (79.3 nm) in rats. Biochemical, histopathological, hematological, and oxidative parameters showed that a single intravenous injection of AgNPs (5 mg/kg b.w.) induced deleterious effects such as hepatotoxicity, potentially as a result of AgNPs accumulation in the liver. Treatment with a single intraperitoneal injection of NAC (1 g/kg b.w.) one hour after AgNPs exposure significantly attenuated all toxic effects evaluated and altered the bioaccumulation and release patterns of AgNPs in rats. The findings show that NAC may be a promising candidate for clinical management of AgNPs intoxication.

Venom of the Phoneutria nigriventer spider alters the cell cycle, viability, and migration of cancer cells

The mechanisms of cancer involve changes in multiple biological pathways. Multitarget molecules, which are components of animal venoms, are therefore a potential strategy for treating tumors. The objective of this study was to screen the effects of Phoneutria nigriventer spider venom (PnV) on tumor cell lines. Cultured human glioma (NG97), glioblastoma (U-251) and cervix adenocarcinoma (HeLa) cells, and nontumor mouse fibroblasts (L929) were treated with low (14?µg/ml) and high (280?µg/ml) concentrations of PnV, and analyzed through assays for cell viability (thiazolyl blue tetrazolium blue), proliferation (carboxyfluorescein succinimidyl ester), death (annexin V/propidium iodide [Pi]), the cell cycle (Pi), and migration (wound healing and transwell assay). The venom decreased the viability of U-251 cells, primarily by inducing cell death, and reduced the viability of NG97 cells, primarily by inhibiting the cell cycle. The migration of all the tumor cell lines was delayed when treated with venom. The venom significantly affected all the tumor cell lines studied, with no cytotoxic effect on normal cells (L929), although the nonglial tumor cell (HeLa) was less sensitive to PnV. The results of the current study suggest that PnV may be composed of peptides that are highly specific for the multiple targets involved in the hallmarks of cancer. Experiments are underway to identify these molecules.

Venom of the Phoneutria nigriventer spider alters the cell cycle, viability, and migration of cancer cells

The mechanisms of cancer involve changes in multiple biological pathways. Multitarget molecules, which are components of animal venoms, are therefore a potential strategy for treating tumors. The objective of this study was to screen the effects of Phoneutria nigriventer spider venom (PnV) on tumor cell lines. Cultured human glioma (NG97), glioblastoma (U-251) and cervix adenocarcinoma (HeLa) cells, and nontumor mouse fibroblasts (L929) were treated with low (14?µg/ml) and high (280?µg/ml) concentrations of PnV, and analyzed through assays for cell viability (thiazolyl blue tetrazolium blue), proliferation (carboxyfluorescein succinimidyl ester), death (annexin V/propidium iodide [Pi]), the cell cycle (Pi), and migration (wound healing and transwell assay). The venom decreased the viability of U-251 cells, primarily by inducing cell death, and reduced the viability of NG97 cells, primarily by inhibiting the cell cycle. The migration of all the tumor cell lines was delayed when treated with venom. The venom significantly affected all the tumor cell lines studied, with no cytotoxic effect on normal cells (L929), although the nonglial tumor cell (HeLa) was less sensitive to PnV. The results of the current study suggest that PnV may be composed of peptides that are highly specific for the multiple targets involved in the hallmarks of cancer. Experiments are underway to identify these molecules.

Methanolic extract of Rhinella schneideri (Anura: Bufonidae) poison causes ultrastructural changes in nerve terminals of phrenic nerve-diaphragm preparations in mice / Extracto metanólico de Rhinella schneideri (Anura: Bufonidae) causa cambios ultraestructurales en las terminaciones nerviosas de preparaciones de nervio frénico de ratón

Abstract Rhinella schneideri (or Bufo paracnemis), popularly known in Brazil as cururu toad, is also found in other countries in South America. The cardiovascular effects of this poison are largely known and recently was shown that it is capable to affect the neuromuscular junction on avian and mice isolated preparation. In this work, we used transmission electron microscopy to investigate the ultrastructure of the motor nerve terminal and postsynaptic junctional folds of phrenic nerve-hemidiaphragm preparations incubated for either 5 or 60 min with the methanolic extract of R. schneideri (50 µg/mL). In addition, the status of the acetylcholine receptors (AChR) was examined by TRITC-α-bungarotoxin immunofluorescence location at the endplate membrane. The results show that 5 min of incubation with the gland secretion extract significantly decreased (32 %) the number of synaptic vesicles into the motor nerve terminal, but did not decrease the electron density on the top of the junctional folds where nicotinic receptors are concentrated; however, 60 min of incubation led to significant nerve terminal reloading in synaptic vesicles whereas the AChR immunoreactivity was not as marked as in control and after 5 min incubation. Muscle fibers were well-preserved but intramuscular motor axons were not. The findings corroborated pharmacological data since the decrease in the number of synaptic vesicles (5 min) followed by recovery (60 min) is in accordance with the transient increase of MEPPs frequency meaning increased neurotransmitter release. These data support the predominant presynaptic mode of action of the R. schneideri, but do not exclude the possibility of a secondary postsynaptic action depending on the time the preparation is exposed to poison. Rev. Biol. Trop. 66(3): 1290-1297. Epub 2018 September 01.

Resumen Rhinella schneideri (o Bufo paracnemis), conocido popularmente en Brasil como sapo cururu, también se encuentra en otros países de América del Sur. Los efectos cardiovasculares de este veneno son ampliamente conocidos y recientemente se demostró que es capaz de afectar la unión neuromuscular en la preparación aislada de aves y ratones. En este trabajo, utilizamos microscopía electrónica de transmisión para investigar la ultraestructura de la terminación nerviosa motora y pliegues de unión postsináptica de preparaciones de nervio frénico-hemidiafragma incubadas durante 5 o 60 min con el extracto metanólico de R. schneideri (50 μg/mL). Además, se examinó el estado de los receptores de acetilcolina (AChR) mediante la ubicación de inmunofluorescencia de TRITC-α-bungarotoxina en la membrana de la placa terminal. Los resultados muestran que 5 min de incubación con el extracto de secreción de glándula disminuyeron significativamente (32 %) el número de vesículas sinápticas en el terminal del nervio motor, pero no disminuyeron la densidad electrónica en la parte superior de los pliegues de unión donde se concentran los receptores nicotínicos. Sin embargo, 60 min de incubación condujeron a una recarga significativa de los terminales nerviosos en las vesículas sinápticas, mientras que la inmunorreactividad del AChR no fue tan marcada como en el control y después de 5 min de incubación. Las fibras musculares estaban bien conservadas, pero los axones motores intramusculares no. Los hallazgos corroboraron los datos farmacológicos ya que la disminución en el número de vesículas sinápticas (5 min) seguida de recuperación (60 min) está de acuerdo con el aumento transitorio de la frecuencia de MEPPs, lo que significa una mayor liberación de neurotransmisores. Estos datos apoyan el modo de acción presináptico predominante de R. schneideri, pero no excluyen la posibilidad de una acción postsináptica secundaria dependiendo del tiempo en que la preparación esté expuesta al veneno.

Age-Related Modulations of AQP4 and Caveolin-1 in the Hippocampus Predispose the Toxic Effect of Phoneutria nigriventer Spider Venom.

We have previously demonstrated that Phoneutria nigriventer venom (PNV) causes blood-brain barrier (BBB) breakdown, swelling of astrocytes end-feet and fluid permeation into brain interstitium in rats. Caveolae and water channels respond to BBB alterations by co-participation in shear stress response and edema formation/resolution. Herein, we showed post-natal developmental-related changes of two BBB-associated transporter proteins: the endothelial caveolin-1 (Cav-1), the major scaffolding protein from caveolae frame, and the astroglial aquaporin-4 (AQP4), the main water channel protein expressed in astrocytic peri-vascular end-feet processes, in the hippocampus of rats intraperitoneally-administered PNV. Western blotting protein levels; immunohistochemistry (IHC) protein distribution in CA1, CA2, and CA3 subfields; and gene expression by Real Time-Polymerase Chain Reaction (qPCR) were assessed in post-natal Day 14 (P14) and 8-10-week-old rats over critical periods of envenomation. The intensity and duration of the toxic manifestations indicate P14 neonate rats more vulnerable to PNV than adults. Histologically, the capillaries of P14 and 8-10-week-old rats treated with PNV showed perivascular edema, while controls did not. The intensity of the toxic manifestations in P14 decreases temporally (2 > 5 > 24 h), while inversely the expression of AQP4 and Cav-1 peaked at 24 h when clinically PNV-treated animals do not differ from saline controls. IHC of AQP4 revealed that hippocampal CA1 showed the least expression at 2 h when toxic manifestation was maximal. Subfield IHC quantification revealed that in P14 rats Cav-1 peaked at 24 h when toxic manifestations were absent, whereas in 8-10-week-old rats Cav-1 peaked at 2 h when toxic signs were highest, and progressively attenuated such increases until 24 h, remaining though significantly above baseline. Considering astrocyte-endothelial physical and functional interactions, we hypothesize that age-related modulations of AQP4 and Cav-1 might be linked both to changes in functional properties of astrocytes during post-natal development and in the BBB breakdown induced by the venom of P. nigriventer.

Ultrastructural aspects of mouse nerve-muscle preparation exposed to Bothrops jararacussu and Bothrops bilineatus venoms and their toxins BthTX-I and Bbil-TX: Unknown myotoxic effects.

Bites by Bothrops snakes normally induce local pain, haemorrhage, oedema and myonecrosis. Mammalian isolated nerve-muscle preparations exposed to Bothrops venoms and their phospholipase A2 toxins (PLA2 ) can exhibit a neurotoxic pattern as increase in frequency of miniature end-plate potentials (MEPPs) as well as in amplitude of end-plate potentials (EPPs); neuromuscular facilitation followed by complete and irreversible blockade without morphological evidence for muscle damage. In this work, we analysed the ultrastructural damage induced by Bothrops jararacussu and Bothrops bilineatus venoms and their PLA2 toxins (BthTX-I and Bbil-TX) in mouse isolated nerve-phrenic diaphragm preparations (PND). Under transmission electron microscopy (TEM), PND preparations previously exposed to B. jararacussu and B. bilineatus venoms and BthTX-I and Bbil-TX toxins showed hypercontracted and loosed myofilaments; unorganized sarcomeres; clusters of edematous sarcoplasmic reticulum and mitochondria; abnormal chromatin distribution or apoptotic-like nuclei. The principal affected organelles, mitochondria and sarcoplasmic reticulum, were those related to calcium buffering and, resulting in sarcomeres and myofilaments hypercontraction. Schwann cells were also damaged showing edematous axons and mitochondria as well as myelin sheath alteration. These ultrastructural changes caused by both of Bothrops venoms and toxins indicate that the neuromuscular blockade induced by them in vitro can also be associated with nerve and muscle degeneration.

Low-Level Laser Therapy (904 nm) Counteracts Motor Deficit of Mice Hind Limb following Skeletal Muscle Injury Caused by Snakebite-Mimicking Intramuscular Venom Injection.

Myotoxins present in Bothrops venom disrupt the sarcolemma of muscle fibers leading to the release of sarcoplasmic proteins and loss of muscle homeostasis. Myonecrosis and tissue anoxia induced by vascularization impairment can lead to amputation or motor functional deficit. The objective of this study was to investigate the dynamic behavior of motor function in mice subjected to injection of Bothrops jararacussu venom (Bjssu) and exposed to low-level laser therapy (LLLT). Male Swiss mice received Bjssu injection (830 µg/kg) into the medial portion of the right gastrocnemius muscle. Three hours later the injected region was irradiated with diode semiconductor Gallium Arsenide (GaAs- 904 nm, 4 J/cm²) laser following by irradiation at 24, 48 and 72 hours. Saline injection (0.9% NaCl) was used as control. Gait analysis was performed 24 hours before Bjssu injection and at every period post-Bjssu using CatWalk method. Data from spatiotemporal parameters Stand, Maximum Intensity, Swing, Swing Speed, Stride Length and Step Cycle were considered. The period of 3 hours post venom-induced injury was considered critical for all parameters evaluated in the right hindlimb. Differences (p<0.05) were concentrated in venom and venom + placebo laser groups during the 3 hours post-injury period, in which the values of stand of most animals were null. After this period, the gait characteristics were re-established for all parameters. The venom + laser group kept the values at 3 hours post-Bjssu equal to that at 24 hours before Bjssu injection indicating that the GaAs laser therapy improved spatially and temporally gait parameters at the critical injury period caused by Bjssu. This is the first study to analyze with cutting edge technology the gait functional deficits caused by snake envenoming and gait gains produced by GaAs laser irradiation. In this sense, the study fills a gap on the field of motor function after laser treatment following snake envenoming.

Sildenafil (Viagra®) down regulates cytokines and prevents demyelination in a cuprizone-induced MS mouse model.

Sildenafil induces cGMP accumulation through phosphodiesterase-5 (PDE5) inhibition. cGMP-pathways protect oligodendrocytes and modulate astroglial and microglial reactions. Microglia and astrocytes play an important role in perpetuating multiple sclerosis (MS), a chronic inflammatory disease characterized by demyelination. Therefore, sildenafil can be a potential tool for MS treatment. The present study investigated the effects of sildenafil on the myelin structure and astrocyte/microglia-mediated neuroinflammation in an animal model of MS. Cuprizone-induced demyelination and neuroinflammation in rodents has been widely used as a model for MS. Herein, five male C57BL/6 mice (7-10 weeks old) were used per group. Over a 4-week period, the different groups received the following: (1) cuprizone (0.2%) mixed into the chow; (2) cuprizone in the chow and sildenafil (Viagra®; 3, 25 or 50mg/kg) in the drinking water; or (3) pure chow and water (control group). Cerebella were analyzed using transmission electron microscopy, western blotting, immunohistochemistry and luxol fast blue staining. Cuprizone induced tissue damage, with an increase in GFAP, Iba-1 and COX-2 and demyelination in comparison to the control group. However, cuprizone did not affect the expression of cytokines (TNF-α, IFN-γ, IL-1ß and IL-2). Sildenafil reduced GFAP (25 and 50mg/kg) and Iba-1 expression (25mg/kg) in comparison to the cuprizone group, indicating the modulation of astrocytes and microglia, respectively. Sildenafil preserved myelin and axons ultrastructure and strongly reduced IFN-γ, TNF-α, IL-1ß, IL-2 and COX-2 expression in comparison to the control and/or cuprizone groups. The results demonstrate a protective effect of sildenafil in the cerebellum. Thus, well-designed clinical trials may demonstrate that the oral administration of sildenafil can be suitable for individuals with MS and other neuroinflammatory/neurodegenerative diseases, providing additional benefits to current treatments.

A study of the myotoxicity of bothropstoxin-i using manganese in mouse phrenic nerve-diaohragm and extensor digitorum longus preparations

Bothropstoxin-I (BthTX-I) from Bothrops jararacussu snake venom has a predominantly postsynaptic action that is responsible for this toxin´s myotoxicity. However, BthTX-I also has a presynaptic action that is counteracted by Mn2+, a reversible neuromuscular blocker that acts predominantly presynaptically. In this work, we used two nerve-muscle preparations (mouse phrenic nerve-diaphragm - PND and extensor digitorum longus - EDL) to investigate the ability of Mn2+ to protect against the myotoxicity of BthTX-I. The preparations were incubated with Tyrode solution (control), BthTX-I, or Mn2+ alone. BthTX-I (1.4 µM) produced irreversible blockade in both preparations, whereas the blockade by Mn2+ (0.9 mM) was total and reversible in PND but just partially reversible in EDL. Pretreating the preparations with Mn2+ resulted in 100% and 80% protection against BthTX-I-induced blockade, respectively. However, when Mn2+ (0.9 or 1.8 mM) and BthTX-I (1.4 µM) were co-incubated for 30 min before testing, the blockade was faster and sustained. Washing the preparations resulted in complete, sustained recovery in those exposed to 1.8 mM Mn2+ but not to 0.9 mM Mn2+. Morphological analysis showed that the extent of fiber damage by BthTXI (1.4 µM) was 82% (PND) and 68.5% (EDL), and that Mn2+ (0.9 mM) afforded 40% protection in both preparations and reduced the increase in muscle fiber cross-sectional area by 20% and 15%, respectively, compared to BthTX-I alone. Mn2+ (0.9 mM) significantly attenuated the release of creatine kinase by BthTXI. The low creatine kinase activity resulted from a protective action of Mn2+ on the sarcolemma and from direct inactivation of the released enzyme. These results show that Mn2+ prevents membrane disruption by BthTX-I and can protect against the myotoxicity and neurotoxicity caused by this toxin.

Early histopathological changes in bone marrow of Paracoccidioides brasiliensis-infected mice

The involvement of bone marrow in the pathology of experimental P. brasiliensis infection in BALB/c mice was investigated. The histopathological features of bone marrow induced by the fungus were correlated with hematological changes in peripheral blood from 1 to 28 days post-infection. Intense lymphopenia and moderate neutrophilia were detected. The early changes in bone marrow included (i) maturation arrest characterized by an increase immature blood cell precursors, mainly of granulocytic origin, (ii) intense vascular congestion when compared with the vessels of normal marrow, and (iii) an increased number of megakaryocytes. The normal histological pattern of bone marrow was restored by 28 days post-infection. No histologically recognizable lesion, such as granuloma formation or an abnormal cellular infiltrate, which could indicate the presence of the P. brasiliensis in bone marrow, was observed. In addition, special stains were unable to detect the fungus. The mechanisms responsible for the alterations described here are still unclear but are probably related to more general phenomena affecting the host rather than the direct damage of the precursors cells by P. brasiliensis.

Electrophysiological and ultrastructural analysis of the neuromuscular blockade and miotoxicity induced by the Micrurus nigrocinctus snake venom

Micrurus nigrocinctus is the most abundant coral snake in Central America. The venom of this specie induced a concentration-dependent (10-20 mug/ml) depolarization in the isolated mouse phrenic nerve-diaphragm preparations incubated ate 37 degree. D-Tubocurrarine (10 mug/ml) and alpha betaungarotoxin (3-5 mug/ml) were able to partially protect against the depolarization induced by the venom (10 mug/ml), suggesting the involvement of subsynaptic cholinergic receptors. This venom (10 mug/ml) also increased the frequency and amplitude of miniature end-plate potentials (mepps) during the first 10-20 min of incubation. Subsequently, the mepps progressively decreased and disappeared after 60 min. These responses were accompanied by ultrastructural changes involving the nerve terminals, the subsynaptic junctional folds and the muscle mitochondria. The synaptic gutter was shallow and, very often, "shrunken" terminal with omega-shaped axolemmal identations and a decreased number of synaptic vecicles were present. A common finding was the presence of numerous finger-like, membrane-bounded bodies interposed between the terminal and the Schwann cells or postsynaptic sarcolemma. The preincubation of the venom with specific antivenom or the incubation of the preparations at room temperature (24-26 degree) reduced the number and intensity of the ultrastructural alterations. The last finding suggests the involvement of a enzymatic process, probably a phospholipase A2, present in the venom. There was a good correlation between the electrophysiological and ultrastructural effects induced by the venom which allow us to conclude that M. nigrocinctus venom has a presynaptic action in the initial stages of intoxication followed by sub- and postsynaptic effects, the last being the most important cause of neuromuscular blockade. A direct action of the venom on muscle fibers may also contributes to the irreversible blockade.

Electrophysiological and ultrastructural analysis of the neuromuscular blockade and miotoxicity induced by the Micrurus nigrocinctus snake venom

Micrurus nigrocinctus is the most abundant coral snake in Central America. The venom of this specie induced a concentration-dependent (10-20 mug/ml) depolarization in the isolated mouse phrenic nerve-diaphragm preparations incubated ate 37 degree. D-Tubocurrarine (10 mug/ml) and alpha betaungarotoxin (3-5 mug/ml) were able to partially protect against the depolarization induced by the venom (10 mug/ml), suggesting the involvement of subsynaptic cholinergic receptors. This venom (10 mug/ml) also increased the frequency and amplitude of miniature end-plate potentials (mepps) during the first 10-20 min of incubation. Subsequently, the mepps progressively decreased and disappeared after 60 min. These responses were accompanied by ultrastructural changes involving the nerve terminals, the subsynaptic junctional folds and the muscle mitochondria. The synaptic gutter was shallow and, very often, "shrunken" terminal with omega-shaped axolemmal identations and a decreased number of synaptic vecicles were present. A common finding was the presence of numerous finger-like, membrane-bounded bodies interposed between the terminal and the Schwann cells or postsynaptic sarcolemma. The preincubation of the venom with specific antivenom or the incubation of the preparations at room temperature (24-26 degree) reduced the number and intensity of the ultrastructural alterations. The last finding suggests the involvement of a enzymatic process, probably a phospholipase A2, present in the venom. There was a good correlation between the electrophysiological and ultrastructural effects induced by the venom which allow us to conclude that M. nigrocinctus venom has a presynaptic action in the initial stages of intoxication followed by sub- and postsynaptic effects, the last being the most important cause of neuromuscular blockade. A direct action of the venom on muscle fibers may also contributes to the irreversible blockade. (AU)

Influence of protein malnutrition on histochemically-delected compounds in the liver of rats

Weanling (21-day-old) Norvegicus Wistar male rats were submitted to protein malnutrition for 120 days, and after this period the livers were studied with morphohistochemical techniques. When compared to controls, protein-deprived rats showed a wide cytoplasmic vacuolization of hepatocytes due to fatty degeneration. They also had lower rates of glucose-6-phosphatase activity, resulting in higher glycogen stores. There also minor changes in elastic and reticular fibrils. Other histochemically-delected compounds, such as glycosaminoglycans, reducing radicals and iron stores have not apparently changed, despite impaired protein intake. Morphohistochemical changes exhibited a zonal lobular heterogeneity. The results suggest that protein malnutrition can alter rat liver structure and function by affecting carbohydrate, protein and lipid metabolism. This study also highlights the hepatic lobular metabolic heterogeneity and its modulation when submitted to adverse conditions.