In vitro anthelmintic activity of aqueous leaf extract of Annona muricata L. (Annonaceae) against Haemonchus contortus from sheep.

Despite the overall progress of sheep farming in Brazil, infections with the gastrointestinal parasite Haemonchus contortus represent one the most important problems in sheep production, aggravated by the increasing resistance of nematodes to traditional anthelmintic drugs caused by inadequate sheep flock management by breeders. Ethnopharmacological data indicate Annona muricata as a promising alternative for the control of gastrointestinal nematodes because of its general anthelmintic properties. The aim of this work was to evaluate the in vitro anthelmintic effects of A. muricata aqueous leaf extract against eggs, infective larvae and adult forms of parasitic nematode H. contortus. At higher doses, A. muricata extract showed 84.91% and 89.08% of efficacy in egg hatch test (EHT) and larval motility test (LMT), respectively. In the adult worm motility test, worms were completely immobilized within the first 6-8 h of nematode exposition to different dilutions of extract. Phytochemical analysis indicated the presence of phenolic compounds in A. muricata aqueous leaf extract that may be responsible for the anthelmintic effects observed. Moreover those results validate the traditional use of A. muricata as a natural anthelmintic and then the pharmacological potential of its compounds for future in vivo investigations

Aspectos moleculares da transmissão sináptica

O Sistema Nervoso Central produz o nosso estado consciente mediante um contínuo fluxo de informações e armazenamento de memórias ao longo da vida, a partir de diferentes estímulos externos. Ao mesmo tempo, controla a concentração dos nossos fluidos internos e o trabalho de músculos e glândulas. A transmissão sináptica é o processo básico de toda esta atividade. Bilhões de neurônios se comunicam entre si via milhares de sinapses, e cada sinapse, por sua vez, é uma estrutura regulada independentemente. A partir desta complexidade, em lugar de caos, surge uma singular ordem na informação processada pelo cérebro. A secreção de neurotransmissores na zona ativa da sinapse é o evento primário da comunicação interneuronal. Este processo é regulado por um tráfego de membranas altamente orquestrado dentro do terminal présináptico. Os neurotransmissores são armazenados em vesículas sinápticas. A despolarização de um terminal nervoso por um potencial de ação resulta na abertura de canais de cálcio, operados por voltagem. O influxo de Ca resultante deflagra a exocitose, que é uma rápida fusão de vesículas com a membrana plasmática, liberando neurotransmissores para a fenda sináptica. A exocitose envolve a junção de proteínas intrínsecas das membranas plasmáticas, vesicular e pré-sináptica, mediante proteínas específicas de ancoragem e fusão na zona ativa (SNARE). Em seguida à liberação, as membranas das vesículas são rapidamente reincorporadas via endocitose e recicladas dentro do terminal sináptico. O terminal é, portanto, uma unidade autônoma que contém todos os elementos requeridos para a exocitose das vesículas, as proteínas responsáveis pela biossíntese do neurotransmissor e recaptação das vesículas. Uma vez liberado, o neurotransmissor difunde através da fenda sináptica e interage com proteínas receptoras na membrana do neurônio póssináptico produzindo, em uma fração de milissegundo, uma permeabilidade intensa e temporária aos íons Na + e K+, provocando a despolarização total de cerca de 100 mV desde um potencial de repouso em torno de -60mV. Isto gera um potencial de ação que se difunde ao longo da membrana do neurônio pós-sináptico, podendo alcançar o seu próprio  erminal e deflagrar novo movimento de Ca 2+ para o citosol, gerando um novo potencial. Várias proteínas dentro do terminal pós-sináptico estão envolvidas neste processo. É geralmente aceito que os processos de aprendizado e memória resultam de mudanças estruturais e bioquímicas em sinapses específicas que alteram a liberação de neurotransmissores e a ação pós-sináptica. Tais alterações podem ser registradas eletrofisiologicamente como uma potenciação ou depressão de duração longa (LTP ou LTD) ou a combinação de ambas. The Central Nervous System produces our conscious state out of various externa inputs in a continuous stream of information and storing a lifetime of memories, while keeping track of the concentration of our internal fluids and the work of muscles and glands. Synaptic transmission is the key process of all that activity. Billions of neurons communicate with each other via thousands of synapses, each of which is independently regulated. From that complexity, instead of chaos, arises the pristine order of information processed by the brain. The secretion of neurotransmitters at the synaptic active zone is the primary event of interneuronal communication. This process is regulated by a highly orchestrated cycle of membrane trafficking within the presynaptic nerve terminal. Neurotransmitters are stored in synaptic vesicles. Depolarization of the nerve terminal by an action potential results in the opening of voltage-gated Ca 2+ channels. The resulting influx of calcium ions triggers exocytosis which is a rapid fusion of the vesicles with the plasma membrane, releasing neurotransmitters into the synaptic cleft. Exocytosis involves the linking of intrinsic membrane proteins of the vesicle and the plasma membranes by specific docking and fusion, the SNARE proteins, at the active zone. The vesicle membranes are rapidly retrieved by endocytosis and the synaptic vesicles recycled within the nerve terminal. The nerve terminal is thus an autonomous unit that contains all elements required for synaptic vesicle exocytosis and proteins responsible for neurotransmitter biosynthesis and vesicular uptake. Once the neurotransmitter have been released, diffuses across the synaptic cleft and combines with receptor molecules in the membrane of the postsynaptic neuron producing, in a fraction millisecond, a large transient increased permeability to Na + and K+ ions, provoking a net depolarization to about 100mV from the resting potential of about -60mV. This generates an action potential which spreads along the surface of the postsynaptic cell membrane which in turn may trigger Ca 2+ movement to the cytosol in the synaptic terminal to generate a new response. Several proteins inside the post synaptic terminal are involved in this process. It is generally accepted that learning and memory result from structural and biochemical changes in specific synapses which alter neurotransmitter release and post synaptic action. These alterations are perceivable electrophysiologically as a long term potentiation (LTP),long term depression (LTD), or a combination of both.&nbsp

Anticonvulsant and GABA uptake inhibition properties of venom fractions from the spiders Parawixia bistriata and Scaptocosa raptoria

In this article we describe an in vivo anticonvulsant effect from denatured crude venom and partially isolated fractions from two spiders: Parawixia bistriata and Scaptocosa raptoria. Intracerebroventricular injections of these venoms and fractions abolished rat convulsive tonic-clonic seizures induced by picrotoxin, bicuculline and pentylenetetrazole, and also, inhibited GABA uptake in synaptosomes of rat cerebral cortex. the venoms described in this work seems to be promising tools for the study of the GABAergic system, and may be a potential source for new anticonvulsant drugs.Univ São Paulo, Lab Neurobiol & Peconhas, Dept Biol, Fac Filosofia,Ciencias & Letras Ribeirao Preto, BR-14049901 São Paulo, BrazilUniv São Paulo, Fac Med Ribeirao Preto, Lab Neuroquim, Dept Bioquim, BR-14049901 São Paulo, BrazilUniversidade Federal de São Paulo, Dept Biofis, São Paulo, BrazilUniversidade Federal de São Paulo, Dept Biofis, São Paulo, BrazilWeb of Scienc

Characterization of the actions of AvTx 7 isolated from Agelaia vicina (Hymenoptera : Vespidae) wasp venom on synaptosomal glutamate uptake and release

It has previously been shown that the denatured crude extract of Agelaia vicina wasp venom inhibits glutamate and GABA uptake in rat cerebral cortex synaptosomes. To identify the components responsible for these effects, the neurotoxin AvTx 7 (molecular weight of 1210 Da) was isolated from A. vicina venom and its effects on glutamate neurotransmission investigated. AvTx 7 inhibits glutamate uptake in a dose-dependent and uncompetitive manner. AvTx 7 was found to stimulate the glutamate release in the presence of calcium and sodium channel blockers, suggesting that its action is not mediated through these channels. AvTx 7 potentiates glutamate release in the presence of K+ channel blockers tetraethylammoniurn and 4-aminopyridine, indicating that the toxin may act through these drugs-sensible K+ channels. We suggest that AvTx 7 can be a valuable tool to enhance our understanding of K+ channels' involvement in the release of glutamate. (C) 2004 Wiley Periodicals, Inc.Univ São Paulo, Fac Philosophy Sci & Literature, Lab Neurobiol & Venoms, Ribeirao Preto, SP, BrazilUniv São Paulo, Sch Med, Lab Neurobiol & Venoms, Neurochem Lab, Ribeirao Preto, SP, BrazilOregon Hlth Sci Univ, Vollum Inst, Portland, OR 97201 USAUniversidade Federal de São Paulo, Dept Biophys, São Paulo, SP, BrazilUniversidade Federal de São Paulo, Dept Biophys, São Paulo, SP, BrazilWeb of Scienc

Essential oils of Citrus aurantifolia, Anthemis nobile and Lavandula officinalis: in vitro anthelmintic activities against Haemonchus contortus.

Infections of sheep with gastrointestinal parasites, especially Haemonchus contortus, have caused serious losses in livestock production, particularly after the emergence of resistance to conventional anthelmintics. The search for new anthelmintic agents, especially those of botanical origin, has grown substantially due to the perspective of less contamination of meat and milk, as well as other advantages related to their cost and accessibility in less developed countries. The aim of this study was to evaluate the in vitro anthelmintic activity of essential oils of the plant species Citrus aurantifolia, Anthemis nobile and Lavandula officinalis against the main developmental stages of the parasite H. contortus

Snake venom phospholipase A(2) inhibitors: Medicinal chemistry and therapeutic potential

Phospholipases A(2) (PLA(2)s) are commonly found in snake venoms from Viperidae, Hydrophidae and Elaphidae families and have been extensively studied due to their pharmacological and physiopathological effects in living organisms. This article reports a review on natural and artificial inhibitors of enzymatic, toxic and pharmacological effects induced by snake venom PLA(2)s. These inhibitors act on PLA(2)S through different mechanisms, most of them still not completely understood, including binding to specific domains, denaturation, modification of specific amino acid residues and others. Several substances have been evaluated regarding their effects against snake venoms and isolated toxins, including plant extracts and compounds from marine animals, mammals and snakes serum plasma, in addition to poly or monoclonal antibodies and several synthetic molecules. Research involving these inhibitors may be useful to understand the mechanism of action of PLA(2)s and their role in envenomations caused by snake bite. Furthermore, the biotechnological potential of PLA(2) inhibitors may provide therapeutic molecular models with antiophidian activity to supplement the conventional serum therapy against these multifunctional enzymes