Global ETD Search

1	Purification and biochemical characterization of the phytotoxin, cactorein, from Phytophthora cactorum Meyer, Debra 18 February 2014 (has links) M.Sc. (Biochemistry) / Please refer to full text to view abstract Phytophthora cactorum Plant toxins
2	Some aspects of the physiological action of phytotoxic compounds Henzell, E. F. January 1955 (has links) No description available. 580 Plant toxins ; Plant physiology
3	Biomimetic syntheses of some neurotoxins from Clitocybe acromelalga Spyvee, Mark Rex January 1995 (has links) No description available. 547
4	The phytotoxicity of some hydrocarbons Ivens, G. W. January 1953 (has links) No description available. 571.9
5	THE USE OF A CHELATING AGENT AS AN ANTAGONIST TO THE CARDIAC TOXICITY OF OLEANDRIN Burton, Lloyd Edward, 1922- January 1964 (has links) No description available. Plant toxins. Chelation therapy. Cardiac glycosides.
6	Efeitos toxicogenéticos e toxicogenômicos do Isotiocianato de Alila (óleo de mostarda) em linhagens celulares de carcinoma de bexiga Sávio, André Luiz Ventura [UNESP] 25 July 2014 (has links) (PDF) Made available in DSpace on 2015-01-26T13:21:21Z (GMT). No. of bitstreams: 0 Previous issue date: 2014-07-25Bitstream added on 2015-01-26T13:30:39Z : No. of bitstreams: 1 000795967.pdf: 970728 bytes, checksum: 1a9dc450a114117aa840a96d9f584e0e (MD5) / Nos últimos anos, tem crescido o interesse pela identificação de compostos naturais com potencial medicinal. O isotiocianato de alila (AITC), encontrado em plantas da família Cruciferae e composto majoritário da semente de mostarda, vem sendo avaliado quanto a sua atividade antineoplásica em bexiga devido à sua alta biodisponibilidade na urina a após ingestão. Neste estudo foram investigadas as atividades toxicogenética e toxicogenômica do AITC em linhagens celulares de carcinoma de bexiga com diferentes status do gene TP53 (RT4 – TP53 selvagem / T24 – TP53 mutado). As concentrações de AITC testadas nos ensaios de citotoxicidade, sobrevivência celular e clonogênica foram 0,005, 0,0625, 0,0725, 0,0825, 0,0925, 0,125 e 0,25 μM; nos testes do cometa, micronúcleo, ciclo celular, apoptose, morfologia e expressão gênica (ANLN, BAX, BCL-2, CDK-1, SMAD4, S100P e TP53) foram utilizadas as concentrações de 0,005, 0,0625, 0,0725, 0,0825 e 0,0925 μM. Os resultados mostraram aumento de danos primários no DNA (teste do cometa) para todas as concentrações testadas do AITC na linhagem T24 e para as concentrações mais altas (0,0725, 0,0825 e 0,0925 μM) na linhagem RT4; não foram observados aumentos nas frequências de células micronucleadas em ambas as linhagens. Nas análises de ciclo celular e apoptose foram observadas a parada do ciclo na fase G2/M para a linhagem T24 e altas taxas de apoptose precoce e necrose na linhagem RT4. Com relação à expressão gênica, houve aumento da expressão de S100P e BAX e diminuição da expressão de BCL-2 na linhagem RT4 e aumento da expressão de BCL-2, BAX e ANLN e diminuição da expressão de S100P na T24. Nenhuma alteração foi identificada para os genes SMAD4 e CDK1 nas duas linhagens tratadas com o AITC. Concluindo, o AITC foi capaz de induzir lesões primárias no DNA de células de ambas as linhagens de carcinoma de bexiga, mas que não se refletiram ... / Compounds obtained from fruits, vegetables and essential oils have been widely used to treat many diseases. The allyl isothiocyanate (AITC), also known as mustard essential oil, is found in plants of the cruciferous family and is abundant in the mustard seeds. Due to its high bioavailability in urine, AITC has been considered as a promising antineoplastic agent against bladder cancer. Therefore, the aims of this study were to investigate the toxicogenetic and toxicogenomic effects of AITC in the wild-type (RT4) and in a mutant (T24) TP53 bladder transitional carcinoma cell lines. AITC was tested at concentrations of 0.005, 0.0625, 0.0725, 0.0825, 0.0925, 0.125 and 0.25 μM in the cytotoxicity and cell and clonogenic survival assays; in the comet and micronucleus assays, flow cytometry, apoptosis and gene expression (ANLN, BAX, BCL-2, CDK-1, SMAD4, S100P e TP53) evaluations the concentrations of 0.005; 0.0625; 0.0725; 0.0825 e 0.0925 μM were used. The results showed increased primary DNA damage in T24 (0.005, 0.0625, 0.0725, 0.0825 and 0.0925 μM) and RT4 (0.0725, 0.0825 and 0.0925 μM) cells. However, no significant difference was detected in the frequency of micronucleated cells. A significant increase of cells at sub-G1 phase (0.0625, 0.0725 and 0.0825 μM) and significant decrease at S phase (0.005, 0.0625, 0.0725 and 0.0825 μM) were observed in RT4 cells after AITC treatments. In T24 cells, an increased sub-G1 rate (0.0725 and 0.0825 μM) and cell cycle arrest at G2 phase (0.0625, 0.0725 and 0.0825 μM) were detected. Furthermore, it was observed increased apoptosis and necrosis rates and increase of S100P and BAX and decrease of BCL-2 expression in the wild type TP53 cells. For the mutated TP53 cell line, increased expression of BCL-2, BAX and ANLN and decreased expression S100P were observed. No change was detected for the SMAD4 and CDK-1 genes. In conclusion, AITC was able to reach DNA and induce primary damage in both bladder ... Bexiga - Câncer Expressão gênica Isotiocianatos Crucifera Toxicologia genética Plantas - Toxinas Óleos vegetais Plant toxins
7	Efeitos toxicogenéticos e toxicogenômicos do Isotiocianato de Alila (óleo de mostarda) em linhagens celulares de carcinoma de bexiga / Sávio, André Luiz Ventura. January 2014 (has links) Orientador: Daysy Maria Fávero Salvadori / Coorientador: Glenda Nicioli da Silva / Banca: Luis Fernando Barbisan / Banca: Denise Crispim Tavares / Resumo: Nos últimos anos, tem crescido o interesse pela identificação de compostos naturais com potencial medicinal. O isotiocianato de alila (AITC), encontrado em plantas da família Cruciferae e composto majoritário da semente de mostarda, vem sendo avaliado quanto a sua atividade antineoplásica em bexiga devido à sua alta biodisponibilidade na urina a após ingestão. Neste estudo foram investigadas as atividades toxicogenética e toxicogenômica do AITC em linhagens celulares de carcinoma de bexiga com diferentes status do gene TP53 (RT4 - TP53 selvagem / T24 - TP53 mutado). As concentrações de AITC testadas nos ensaios de citotoxicidade, sobrevivência celular e clonogênica foram 0,005, 0,0625, 0,0725, 0,0825, 0,0925, 0,125 e 0,25 μM; nos testes do cometa, micronúcleo, ciclo celular, apoptose, morfologia e expressão gênica (ANLN, BAX, BCL-2, CDK-1, SMAD4, S100P e TP53) foram utilizadas as concentrações de 0,005, 0,0625, 0,0725, 0,0825 e 0,0925 μM. Os resultados mostraram aumento de danos primários no DNA (teste do cometa) para todas as concentrações testadas do AITC na linhagem T24 e para as concentrações mais altas (0,0725, 0,0825 e 0,0925 μM) na linhagem RT4; não foram observados aumentos nas frequências de células micronucleadas em ambas as linhagens. Nas análises de ciclo celular e apoptose foram observadas a parada do ciclo na fase G2/M para a linhagem T24 e altas taxas de apoptose precoce e necrose na linhagem RT4. Com relação à expressão gênica, houve aumento da expressão de S100P e BAX e diminuição da expressão de BCL-2 na linhagem RT4 e aumento da expressão de BCL-2, BAX e ANLN e diminuição da expressão de S100P na T24. Nenhuma alteração foi identificada para os genes SMAD4 e CDK1 nas duas linhagens tratadas com o AITC. Concluindo, o AITC foi capaz de induzir lesões primárias no DNA de células de ambas as linhagens de carcinoma de bexiga, mas que não se refletiram ... / Abstract: Compounds obtained from fruits, vegetables and essential oils have been widely used to treat many diseases. The allyl isothiocyanate (AITC), also known as mustard essential oil, is found in plants of the cruciferous family and is abundant in the mustard seeds. Due to its high bioavailability in urine, AITC has been considered as a promising antineoplastic agent against bladder cancer. Therefore, the aims of this study were to investigate the toxicogenetic and toxicogenomic effects of AITC in the wild-type (RT4) and in a mutant (T24) TP53 bladder transitional carcinoma cell lines. AITC was tested at concentrations of 0.005, 0.0625, 0.0725, 0.0825, 0.0925, 0.125 and 0.25 μM in the cytotoxicity and cell and clonogenic survival assays; in the comet and micronucleus assays, flow cytometry, apoptosis and gene expression (ANLN, BAX, BCL-2, CDK-1, SMAD4, S100P e TP53) evaluations the concentrations of 0.005; 0.0625; 0.0725; 0.0825 e 0.0925 μM were used. The results showed increased primary DNA damage in T24 (0.005, 0.0625, 0.0725, 0.0825 and 0.0925 μM) and RT4 (0.0725, 0.0825 and 0.0925 μM) cells. However, no significant difference was detected in the frequency of micronucleated cells. A significant increase of cells at sub-G1 phase (0.0625, 0.0725 and 0.0825 μM) and significant decrease at S phase (0.005, 0.0625, 0.0725 and 0.0825 μM) were observed in RT4 cells after AITC treatments. In T24 cells, an increased sub-G1 rate (0.0725 and 0.0825 μM) and cell cycle arrest at G2 phase (0.0625, 0.0725 and 0.0825 μM) were detected. Furthermore, it was observed increased apoptosis and necrosis rates and increase of S100P and BAX and decrease of BCL-2 expression in the wild type TP53 cells. For the mutated TP53 cell line, increased expression of BCL-2, BAX and ANLN and decreased expression S100P were observed. No change was detected for the SMAD4 and CDK-1 genes. In conclusion, AITC was able to reach DNA and induce primary damage in both bladder ... / Mestre Bexiga - Câncer. Expressão gênica. Isotiocianatos. Crucífera. Toxicologia genética. Plantas - Toxinas. Óleos vegetais. Plant toxins
8	Mechanism of Abrin-Induced Apoptosis and Insights into the Neutralizing Activity of mAb D6F10 Mishra, Ritu January 2014 (has links) (PDF) Abrin is a potent toxin obtained from the seeds of Abrus precatorius. It is a heterodimeric glycoprotein consisting of an A and a B subunit linked together by a disulfide bond. The toxicity of the protein comes from the A subunit harboring RNA-N-glycosidase activity which cleaves the glycosidic bond between the ribose sugar and the adenine at position 4324 in 28S rRNA. The depurination of a specific adenine residue at position 4324 results in loss of conformation of the 28S rRNA at the α sarcin/ricin loop to which elongation factor-2 (EF-2) binds, during the transloction step of translation, leading to inhibition of protein synthesis. The B subunit of abrin is a galactose specific lectin. The lectin activity enables the toxin to gain entry inside cells on binding to receptors with terminal galactose. After entering cells, a few molecules of abrin reach the endoplasmic reticulum (ER) via the retrograde transport, where the disulfide bond between the A and the B subunits gets cleaved. Then the A chain escapes into the cytosol where it binds to its target, the α-sarcin loop of the 28S ribosomal RNA and inhibits protein synthesis. Apart from inhibition of protein synthesis, exposure of cells to abrin leads to the loss of mitochondrial membrane potential (MMP) resulting in the activation of caspases and finally apoptosis. However, whether apoptosis is dependent on the inhibition of protein synthesis has not been elucidated. The major objectives of this study are therefore to delineate the signaling pathways involved in abrin-induced apoptosis. The thesis is divided into 4 Chapters: Chapter 1. provides a overview of the general properties of RIPs, with a brief history, classification, trafficking and biological activities of the toxins. This chapter also discusses their potential use in bio-warfare and the treatments available for management of toxicity. Chapter 2 and 3 discuss the results obtained on studies aimed at gaining insights into the signaling pathways involved in abrin-induced apoptosis. Chapter 4 focuses on the research carried out to understand the mechanisms of neutralization of abrin by the mAb D6F10. Towards the first objective, chapter 2 elucidates the role of endoplasmic reticulum (ER) stress signaling in abrin-induced apoptosis using the human T-cell line, Jurkat as a model system. It could be concluded that the inhibition of protein synthesis by the catalytic A subunit of abrin could result in accumulation of unfolded proteins in the ER leading to ER stress which triggers the unfolded protein response (UPR) pathway. The ER resident trans-membrane sensors IRE1 (Inositol-requiring enzyme 1), PERK (PKR-like ER kinase) and ATF6 (Activating transcription factor 6) are the important players of UPR in mammalian cells. These sensors inhibit translation and increase the levels of chaperones to restore protein homeostasis. However, if the ER stress is prolonged, apoptotic pathways get activated to remove severely damaged cells in which protein folding defects cannot be resolved. Recent studies have shown that endoplasmic reticulum (ER) stress induces apoptosis by activating initiater caspases such as caspase-2 and -8 which eventually trigger mitochondrial membrane potential loss and activation of downstream effector capases-9 and -3. Phosphorylation of eukaryotic initiation factor 2α and upregulation of CHOP [CAAT/enhancer binding protein (C/EBP) homologous protein], important players involved in ER stress signaling by abrin, suggested activation of ER stress in the cells. ER stress is also known to induce apoptosis via stress kinases such as p38 MAPK and JNK. Activation of both the pathways was observed upon abrin treatment and found to be upstream of the activation of caspases. However, abrin-induced apoptosis was found be dependent on p38 MAPK but not JNK. We also observed that abrin induced activation of caspase-2 and caspase-8 and triggered Bid cleavage leading to mitochondrial membrane potential loss and thus connecting the signaling events from ER stress to mitochondrial death machinery. Few toxins belonging to the family of ribosome inactivating proteins such as Shiga toxin have been observed to induce DNA damage in human endothelial cells and activate p53/ATM-dependent signaling pathway in mammalian cells. To further investigate the role of abrin on activation of DNA damage signaling pathway, we analysed the phosphorylation of H2AX and ATM, which are markers for double strand DNA breaks. We observed phosphorylation of H2AX and ATM upon abrin treatment but not when cells were pretreated with the broad spectrum pan caspase inhibitor. This study suggested that the DNA damage observed was an indirect effect of caspase-activated DNase. We concluded from the studies in chapter 2 that inhibition of protein synthesis by abrin can trigger endoplasmic reticulum stress leading to mitochondria-mediated apoptosis. Further studies were conducted to understand the dependence of ER stress on inhibition of protein synthesis and are presented in chapter 3. For this study, we have used an active site mutant of abrin A chain (R167L) which exhibits lower protein synthesis inhibitory activity than the wild type abrin A chain. Recombinant wild type and mutant abrin A chains were expressed in E.coli and purified. Since, abrin A chain requires the B chain for internalization into cells, both wild type and mutant abrin A chains were conjugated to native ricin B chain to generate a hybrid toxin. Next, we have compared the toxic effects of the two conjugates in cells. The rate of inhibition of protein synthesis mediated by the mutant ricin B-rABRA (R167L) conjugate was slower than that of the wild type ricin B-rABRA conjugate but it could trigger ER stress leading to mitochondrial mediated apoptosis in cells though delayed, suggesting that inhibition of protein synthesis is the major factor contributing to abrin-mediated apoptosis. Abrin is extremely lethal and considered as a potential agent for use in biological warfare. Currently, there are no antidotes or effective therapies available for abrin poisoning. Antibody based antitoxins function by either preventing toxin binding to cell surface receptors or by translocation. Antibodies against the B chain of RIPs function by inhibiting the binding of B chain of the toxin to cells, whereas the exact mechanism by which antibodies against A chain function is still not clear. The only known neutralizing monoclonal antibody against abrin A chain, namely, D6F10, was generated in our laboratory and was shown to rescue cells and mice from abrin intoxication. Earlier experiments with confocal microscopy suggested that mAb D6F10 could internalize in HeLa cells along with abrin, suggesting that the antibody can function intracellularly. Chapter 4 discusses the work carried out to delineate the mechanism of intracellular neutralization of abrin by the mAb D6F10. We observed significant reduction in binding and delay in abrin internalization in the presence of the neutralizing monoclonal antibody (mAb) D6F10. Considering that the majority of the abrin after internalization is removed by lysosomal degradation, we studied the fate of abrin in the presence of mAb D6F10. Confocal images did not show any difference in the distribution of abrin in the lysosomes in the absence or presence of antibody. However, the antibody remained persistently colocalized with abrin in the cells, suggesting that the antibody might inhibit enzymatic activity of abrin at its cellular site of action. Abrin Apoptosis Neutralizing Antibodies Abrin-induced Apoptosis Ribosome Inactivating Proteins (RIPs) Abrus precatorius Plant Ribosome Inactivating Proteins Abrin Cytotoxicity Apoptosis Induced by Abrin Plant Toxins Phytotoxin mAb D6F10 Cell Death Cell Biology

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