AaIT: from neurotoxin to insecticide

AaIT is a single chain neurotoxic polypeptide derived from the venom of the Buthid scorpion Androctonus australis Hector, composed of 70 amino acids cross-linked by four disulfide bridges. Its strict selectivity for insects has been documented by toxicity, electrophysiological and ligand receptor binding assays. These last have shown that various insect neuronal membranes possess a single class of non-interacting AaIT binding sites of high affinity (K(D) = 1-3(n)M) and low capacity (0.5-2.0 pmol/mg prot.). The fast excitatory paralysis induced by AaIT is a result of a presynaptic effect, namely the induction of a repetitive firing in the terminal branches of the insect's motor nerves resulting in a massive and uncoordinated stimulation of the respective skeletal muscles. The neuronal repetitive activity is attributed to an exclusive and specific perturbation of sodium conductance as a consequence of toxin binding to external loops of the insect voltage-dependent sodium channel and modification of its gating mechanism. From a strictly agrotechnical point of view AaIT involvement in plant protection has taken the following two complementary forms: firstly, as a factor for the genetic engineering of insect infective baculoviruses resulting in potent and selective bio-insecticides. The efficacy of the AaIT-expressing, recombinant baculovirus is attributed mainly to its ability to continuously provide and translocate the gene of the expressed toxin to the insect central nervous system; secondly, based on the pharmacological flexibility of the voltage-gated sodium channel, as a device for insecticide resistance management. Channel mutations conferring resistance to a given class of insecticidal agents (such as the KDR phenomenon) may greatly increase susceptibility to the AaIT expressing bioinsecticides. Thus the AaIT is a pharmacological tool for the study of insect neuronal excitability and chemical ecology and the development of new approaches to insect control.     

Microtubules support production of starvation-induced autophagosomes but not their targeting and fusion with lysosomes

Autophagy is a major catabolic pathway in eukaryotic cells whereby the lack of amino acids induces the formation of autophagosomes, double-bilayer membrane vesicles that mediate delivery of cytosolic proteins and organelles for lysosomal degradation. The biogenesis and turnover of autophagosomes in mammalian cells as well as the molecular mechanisms underlying induction of autophagy and trafficking of these vesicles are poorly understood. Here we utilized different autophagic markers to determine the involvement of microtubules in the autophagic process. We show that autophagosomes associate with microtubules and concentrate near the microtubule-organizing center. Moreover, we demonstrate that autophagosomes, but not phagophores, move along these tracks en route for degradation. Disruption of microtubules leads to a significant reduction in the number of mature autophagosomes but does not affect their life span or their fusion with lysosomes. We propose that microtubules serve to deliver only mature autophagosomes for degradation, thus providing a spatial barrier between phagophores and lysosomes.     

BCKDK regulates the TCA cycle through PDC in the absence of PDK family during embryonic development

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Acute tolerance to the excitatory effect of enkephalin microinjections into hippocampus.

Microinjections of 1–20 μg of leu-enkephalin were done in the dorsal hippocampus of cats and rats in acute experiments. Long lasting epileptiform changes in the hippocampal EEG were produced. These changes were prevented by previous microinjections of naloxone at the same site. When repeated microinjections of the same dose of enkephalin which initially was epileptogenic were done a progressive loss of effectiveness of the drug was observed. Also, progressively higher doses of enkephalin were necessary to produce effects comparable to the effect of the initial injection. These results suggest that acute tolerance may develop to the epileptogenic effect of leu-enkephalin in hippocampus.     

Similarities between the akinesia induced by carbachol microinjections into the pontine reticular formation and neuroleptic catalepsy.

We reported previously that microinjections of carbachol directly into the pontine reticular formation of rats induced intense akinesia. In the present article we report results of tests for rigidity, righting, bracing and clinging which were conducted with the purpose to characterize behaviorally this type of akinesia. After injections of 5-15 micrograms/0.5 microliter of carbachol into the pontine reticular formation the rats were cataleptic, were not rigid when equilibrium was not challenged, had strong righting reflexes and strong bracing and clinging responses. This type of akinesia is different from the catatonia induced by systemic morphine (20 mg/kg IP), but similar to the catalepsy induced by systemic injections of haloperidol (5 mg/kg IP). It is thus suggested that the cataleptic state produced by topical carbachol in the pons is related to the dopaminergic mechanisms important for the cataleptic effect of the neuroleptic drugs.     

Tumor Reliance on Cytosolic versus Mitochondrial One-Carbon Flux Depends on Folate Availability

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