The in vitro effects of nicotine and selected antibiotics, tunicamycin and thapsigargin on human Breast carcinoma (mcf-7) cells.

Isaacs, Rabia

January 2012

>Magister Scientiae - MSc / Cancer is defined as the abnormal growth of genetically mutated or perturbant cells. Nicotine is a known cancer promoter and an apoptotic suppressor. This alkaloid acts on the nicotinic acetylcholine receptors which affects the ubiquitin-proteasome protein degradation pathway and ultimately hinders apoptosis. The endoplasmic reticulum (ER) is an interconnecting organelle which synthesises proteins and its quality control processes ensures the proper protein folding, post-translational modifications and conformation of secretory and trans-membrane proteins. Studies demonstrated that the antibiotic, Tunicamycin (Tm) and the sesquiterpene lactone, Thapsigargin (Tg) causes ER stress and consequently cellular arrest. Tm interferes with N-glycosylation of newly synthesised proteins triggering the unfolded protein response, while Tg inhibits intracellular Ca2+ ATPases resulting in increased cytosolic Ca2+. Studies showed that these compounds have potential pro-apoptotic effects. The combinatorial effects of nicotine, Tm and Tg may produce antagonistic or synergistic effects and provide a therapeutic tool against breast cancer. The aim of the study was to determine the apoptotic effects of nicotine, Tm, and Tg on human breast carcinoma (MCF-7) at various time intervals and further to elucidate whether selected ratios of their combinations resulted in synergistic or antagonistic effects.

Nicotine

Tunicamycin

Endoplasmic reticulum

Thapsigargin

Apoptosis

Role of an Isoform of Zhangfei/CREBZF in the Apoptotic Pathway of the Unfolded Protein Response

Yip, Wan Kong

13 September 2012

The unfolded protein response (UPR) is a well conserved mechanism in eukaryotes that protects organisms from the damaging effects of endoplasmic reticulum (ER) stresses. Activation of the UPR will lead to two outcomes. It first attempts to restore cellular functions by enhancing protein folding capacity, inhibiting protein synthesis and promoting degradation of harmful proteins (the pro-survival pathway). However, if the stressful conditions are prolonged or severe, apoptosis will be induced (the pro-apoptotic pathway). The present study suggests that an isoform of the cellular protein Zhangfei (ZF, CREBZF) is linked to the pro-apoptotic pathway in the UPR by using DNA, protein and cell viability analyses. This isoform is known as the short-tail ZF (stZF). We demonstrated that stZF can be induced by prolonged ER stress. The protein of stZF is stable under ER stress and it has the ability to promote programmed cell death in the early stage of apoptosis through the induction of CHOP, a protein that plays a key role in the pro-apoptotic pathway of the UPR.

Apoptosis

CREBZF

Zhangfei

Unfolded Protein Response

ER stress

Tunicamycin

Perturbation of glycoprotein expression and processing in multidrug resistant cells : modulation of drug transport and cytotoxicity by Tunicamycin

Hiss, Donavon Charles

11 April 2017

No description available.

Drug resistance

Glycoproteins - antagonists

inhibitors

Antineoplastic Agents - pharmacodynamics

Neoplasms - drug therapy

Tunicamycin - therapeutic use

Dissecting tunicamycin biosynthesis : a potent carbohydrate processing enzyme inhibitor

Wyszynski, Filip Jan

January 2010

Tunicamycin nucleoside antibiotics were the first known to target the formation of peptidoglycan precursor lipid I in bacterial cell wall biosynthesis. They have also been used extensively as inhibitors of protein N-glycosylation in eukaryotes, blocking the biogenesis of early intermediate dolichyl-pyrophosphoryl-N-acetylglucosamine. Despite their unusual structures and useful biological properties, little is known about their biosynthesis. Elucidating the metabolic pathway of tunicamycins and gaining an understanding of the enzymes involved in key bond forming processes would not only be of great academic value in itself, it would also unlock a comprehensive toolbox of biosynthetic machinery for the production of tunicamycin analogues which have the potential to act as novel therapeutic antibiotics or as specific inhibitors of medicinally important NDP-dependent glycosyltransferases. I – Cloning the tunicamycin biosynthetic gene cluster. We report identification of the tunicamycin biosynthetic genes in Streptomyces chartreusis following genome sequencing and a chemically-guided strategy for in silico genome mining that allowed rapid identification and unification of an operon fractured across contigs. Heterologous expression established a likely minimal gene set necessary for antibiotic production, from which a detailed metabolic pathway for tunicamycin biosynthesis is proposed. II – Natural product isolation and degradation. We have developed efficient methods for the isolation of tunicamycins from liquid culture in preparative quantities. A subsequent relay synthesis furnished advanced biosynthetic intermediates for use as precursors in the production of tunicamycin analogues and as substrates for the in vitro characterisation of individual Tun enzymes. III – Functional characterisation of tun gene products. Individual tun gene products were over-expressed and purified from recombinant E. coli hosts, allowing in vitro functional studies to take place. An NMR assay of biosynthetic enzyme TunF showed it acted as a UDP-GlcNAc-4-epimerase. Putative glycosyltransferase TunD showed hydrolytic activity towards substrate UDP-GlcNAc but failed to accept to the expected natural acceptor substrate, providing unexpected insights into the ordering of biosynthetic events in the tunicamycin pathway. Initial studies into the over-expression of the putative sugar N-deacetylase TunE were also described. IV – Towards synthesis of tunicamycin fragments. Investigations into a novel synthesis of D-galactosamine – a structural motif within tunicamycin – led to the unexpected observation of inverted regioselectivity upon RhII-catalysed C-H insertion of a D-mannose-derived sulfamate. This was the first example of N-insertion at the beta- rather than gamma-C-H based on conformation alone and warranted further investigation. The X-ray structure of a key sulfamate precursor offered valuable insights as to the source of this unique selectivity.

547.7

Proibitina e a resposta a mecanismos de estresse em melanoma e sua relação com a via E2F1 / Prohibitin and the response to stress mechanisms in melanoma and its relationship with the E2F1 pathway

Tortelli Junior, Tharcisio Citrangulo

14 June 2013

Entre todos os cânceres de pele, o melanoma está entre os menos comuns, mas é responsável pela maior parte das mortes. No caso da doença metastática, não há um tratamento satisfatório capaz de prolongar a vida do paciente. Isso leva à necessidade de novas estratégias e de novos tratamentos que possam reverter a quimiorresistência do tumor. Entre as proteínas que têm seu perfil de expressão modificado no melanoma está a proibitina, cuja expressão aumenta durante a progressão tumoral. Proibitina é uma chaperona mitocondrial pertencente a uma família de proteínas que possuem um resíduo hidrofóbico SPFH, que confere a ela uma capacidade de ancoragem e de organização de espaços em membranas. Além disso, no compartimento nuclear, é um inibidor da família de fatores de transcrição E2F, juntamente com a proteína retinoblastoma (Rb). Em melanomas, proibitina localiza-se no citoplasma, associada à mitocôndria, e no núcleo. No citoplasma, proibitina faz parte da resposta a diversas drogas, como cisplatina, dacarbazina, temozolamida, vimblastina e tunicamicina pode estar relacionado com o aumento de espécies reativas de oxigênio (ROS), já que essas drogas podem de alguma forma induzir ROS intracelular. O aumento de expressão de proibitina, nesse contexto, poderia fazer parte de uma resposta protetora da mitocôndria, o que em última análise protegeria a célula contra a morte celular, já que a inibição de proibitina sensibiliza a célula ao tratamento com cisplatina ou tunicamicina. Além disso, o estresse provocado pela privação de soro fetal bovino em linhagens de melanoma leva ao aumento de expressão de proibitina e é acompanhado pela indução de ROS. No núcleo, proibitina esta colocalizada com MCM5 e MCM7, mas não MCM2. A inibição de proibitina leva ao aumento de expressão de metaloproteinases de matriz extracelular, não só em melanomas, mas também em linhagens de câncer de mama e de câncer de pulmão. Ainda, proibitina parece estar relacionada com o fenômeno da transição epitélio mesênquima, já que a inibição de proibitina leva ao aumento de expressão de marcadores mesenquimais como N-caderina e vimentina e a perda de expressão de marcadores epiteliais, como a E-caderina. Outras funções controladas por E2F1 que proibitina pode estar modulando são a capacidade de E2F1 induzir reparo de DNA devido a lesões causadas por radiação UVB e a indução de senescência. A inibição de proibitina em linhagem de câncer de pulmão protegeu a célula contra o dano genotóxico causado pela radiação UVB, pelo aumento da proteína de reparo de DNA Gadd45a, que é induzida por E2F1. Ainda, a inibição de proibitina diminuiu a quantidade de células senescência induzida por adriamicina em linhagens de melanoma. Ainda, a expressão de proibitina responde a fatores do microambiente tumoral como TGF?, IL4 e LPS juntamente com INF? e, além disso, têm sua expressão diminuída durante a maturação de macrófagos. Esses resultados mostram que proibitina pode atuar protegendo o tumor ou bloqueando vias importantes para seu desenvolvimento, dependendo da sua compartimentalização subcelular / Among all skin cancers, melanoma is the least common, but is responsible for most deaths. In metastatic disease, no satisfactory treatment can prolong the patient\'s life. This leads to the need for new strategies and new treatments that may reverse tumor chemoresistance. Among proteins that have their expression profile altered in melanoma is prohibitin whose expression increases during tumor progression. Prohibitin is a mitochondrial chaperone belonging to a family of proteins which possess a hydrophobic residue SPFH, which gives it a capacity for anchorage and organization in membrane regions. Furthermore, in the nuclear compartment, prohibitin is an inhibitor of the E2F transcription factor family, together with the retinoblastoma protein (Rb). In melanomas, prohibitin is located in the cytoplasm, associated to the mitochondria, and inside the nucleus. In the cytoplasm, prohibitin is part of the response to various drugs such as cisplatin, dacarbazine, temozolomide, vinblastine and tunicamycin and may be associated with increased reactive oxygen species (ROS), since these drugs can somehow induce intracellular ROS. Prohibitin overxpression in this context could be part of a protective response of the mitochondria, which ultimately protect cells against death, as prohibitin inhibition sensitizes cells to cisplatin or tunicamycin treatment. Moreover, the stress caused by deprivation of fetal bovine serum in melanoma cell lines leads to prohibitin overexpression and is accompanied by ROS induction. In the nucleus, prohibitin is colocalized to MCM5 and MCM7, but not to MCM2. Inhibition of prohibitin leads to increased expression of matrix metalloproteinases, not only on melanomas but also on breast cancer and lung cancer cell lines. Further, prohibitin appears to be related to the phenomenon of epithelial mesenchymal transition, since prohibitin inhibition leads to increased expression of mesenchymal markers such as N-cadherin and vimentin and loss of expression of epithelial markers, such as E-cadherin. Other functions controlled by E2F1 that are modulated by prohibitin include be the ability of E2F1 to induce DNA repair against UVB radiation and the induction of cellular senescence. Inhibition of prohibitin in lung cancer cell line protected against genotoxic damage caused by UVB radiation, due to DNA repair protein Gadd45a overexpression, which is induced by E2F1. Also, prohibitin inhibition decreased the amount of cell senescence induced by adriamycin in melanoma cell line. Further, prohibitin expression is triggered by tumor microenvironmental factors such as TGF?, IL4, and LPS together with INF? and, in addition, prohibitin expression decreases during macrophages maturation. These results show that prohibitin may act protecting the tumor or blocking pathways important for its development, depending on its subcellular compartment distribution

Cisplatin

Cisplatina

E2F1 transcription factor

Epithelial-mesenchymal transition

Fator de transcrição E2F1

Melanoma

Melanoma

Mitochondrias

Mitocôndrias

Prohibitin

Proibitina

Senescence

Senescência

Transição epitélial-mesênquimal

Tunicamicina

Tunicamycin

Proibitina e a resposta a mecanismos de estresse em melanoma e sua relação com a via E2F1 / Prohibitin and the response to stress mechanisms in melanoma and its relationship with the E2F1 pathway

Tharcisio Citrangulo Tortelli Junior

14 June 2013

Entre todos os cânceres de pele, o melanoma está entre os menos comuns, mas é responsável pela maior parte das mortes. No caso da doença metastática, não há um tratamento satisfatório capaz de prolongar a vida do paciente. Isso leva à necessidade de novas estratégias e de novos tratamentos que possam reverter a quimiorresistência do tumor. Entre as proteínas que têm seu perfil de expressão modificado no melanoma está a proibitina, cuja expressão aumenta durante a progressão tumoral. Proibitina é uma chaperona mitocondrial pertencente a uma família de proteínas que possuem um resíduo hidrofóbico SPFH, que confere a ela uma capacidade de ancoragem e de organização de espaços em membranas. Além disso, no compartimento nuclear, é um inibidor da família de fatores de transcrição E2F, juntamente com a proteína retinoblastoma (Rb). Em melanomas, proibitina localiza-se no citoplasma, associada à mitocôndria, e no núcleo. No citoplasma, proibitina faz parte da resposta a diversas drogas, como cisplatina, dacarbazina, temozolamida, vimblastina e tunicamicina pode estar relacionado com o aumento de espécies reativas de oxigênio (ROS), já que essas drogas podem de alguma forma induzir ROS intracelular. O aumento de expressão de proibitina, nesse contexto, poderia fazer parte de uma resposta protetora da mitocôndria, o que em última análise protegeria a célula contra a morte celular, já que a inibição de proibitina sensibiliza a célula ao tratamento com cisplatina ou tunicamicina. Além disso, o estresse provocado pela privação de soro fetal bovino em linhagens de melanoma leva ao aumento de expressão de proibitina e é acompanhado pela indução de ROS. No núcleo, proibitina esta colocalizada com MCM5 e MCM7, mas não MCM2. A inibição de proibitina leva ao aumento de expressão de metaloproteinases de matriz extracelular, não só em melanomas, mas também em linhagens de câncer de mama e de câncer de pulmão. Ainda, proibitina parece estar relacionada com o fenômeno da transição epitélio mesênquima, já que a inibição de proibitina leva ao aumento de expressão de marcadores mesenquimais como N-caderina e vimentina e a perda de expressão de marcadores epiteliais, como a E-caderina. Outras funções controladas por E2F1 que proibitina pode estar modulando são a capacidade de E2F1 induzir reparo de DNA devido a lesões causadas por radiação UVB e a indução de senescência. A inibição de proibitina em linhagem de câncer de pulmão protegeu a célula contra o dano genotóxico causado pela radiação UVB, pelo aumento da proteína de reparo de DNA Gadd45a, que é induzida por E2F1. Ainda, a inibição de proibitina diminuiu a quantidade de células senescência induzida por adriamicina em linhagens de melanoma. Ainda, a expressão de proibitina responde a fatores do microambiente tumoral como TGF?, IL4 e LPS juntamente com INF? e, além disso, têm sua expressão diminuída durante a maturação de macrófagos. Esses resultados mostram que proibitina pode atuar protegendo o tumor ou bloqueando vias importantes para seu desenvolvimento, dependendo da sua compartimentalização subcelular / Among all skin cancers, melanoma is the least common, but is responsible for most deaths. In metastatic disease, no satisfactory treatment can prolong the patient\'s life. This leads to the need for new strategies and new treatments that may reverse tumor chemoresistance. Among proteins that have their expression profile altered in melanoma is prohibitin whose expression increases during tumor progression. Prohibitin is a mitochondrial chaperone belonging to a family of proteins which possess a hydrophobic residue SPFH, which gives it a capacity for anchorage and organization in membrane regions. Furthermore, in the nuclear compartment, prohibitin is an inhibitor of the E2F transcription factor family, together with the retinoblastoma protein (Rb). In melanomas, prohibitin is located in the cytoplasm, associated to the mitochondria, and inside the nucleus. In the cytoplasm, prohibitin is part of the response to various drugs such as cisplatin, dacarbazine, temozolomide, vinblastine and tunicamycin and may be associated with increased reactive oxygen species (ROS), since these drugs can somehow induce intracellular ROS. Prohibitin overxpression in this context could be part of a protective response of the mitochondria, which ultimately protect cells against death, as prohibitin inhibition sensitizes cells to cisplatin or tunicamycin treatment. Moreover, the stress caused by deprivation of fetal bovine serum in melanoma cell lines leads to prohibitin overexpression and is accompanied by ROS induction. In the nucleus, prohibitin is colocalized to MCM5 and MCM7, but not to MCM2. Inhibition of prohibitin leads to increased expression of matrix metalloproteinases, not only on melanomas but also on breast cancer and lung cancer cell lines. Further, prohibitin appears to be related to the phenomenon of epithelial mesenchymal transition, since prohibitin inhibition leads to increased expression of mesenchymal markers such as N-cadherin and vimentin and loss of expression of epithelial markers, such as E-cadherin. Other functions controlled by E2F1 that are modulated by prohibitin include be the ability of E2F1 to induce DNA repair against UVB radiation and the induction of cellular senescence. Inhibition of prohibitin in lung cancer cell line protected against genotoxic damage caused by UVB radiation, due to DNA repair protein Gadd45a overexpression, which is induced by E2F1. Also, prohibitin inhibition decreased the amount of cell senescence induced by adriamycin in melanoma cell line. Further, prohibitin expression is triggered by tumor microenvironmental factors such as TGF?, IL4, and LPS together with INF? and, in addition, prohibitin expression decreases during macrophages maturation. These results show that prohibitin may act protecting the tumor or blocking pathways important for its development, depending on its subcellular compartment distribution

Cisplatina

Fator de transcrição E2F1

Melanoma

Mitocôndrias

Proibitina

Senescência

Transição epitélial-mesênquimal

Tunicamicina

Cisplatin

E2F1 transcription factor

Epithelial-mesenchymal transition

Melanoma

Mitochondrias

Prohibitin

Senescence

Tunicamycin

The Transient Receptor Potential Canonical 3 (TRPC3) Channel: Novel Role in Endothelial Cell Apoptosis and its Impact on Atherosclerosis

Ampem, Prince Tuffour

03 October 2017

No description available.

Biomedical Research

TRPC3

ER stress

Unfolded protein response

apoptosis

Endothelial cells

Atherosclerosis

Calcium influx

CAMKII

STAT1

JNK

Coronary artery disease

lesion

Thapsigargin

Tunicamycin

Pyr10

Apoe knockout

transgenic mouse

Semi-synthesis and biological evaluations of tunicamycin lipid analogues and investigation of the tunicamycin biosynthetic pathway

Wang, Hua

January 2014

Tunicamycins are potent antimicrobial agents but are also toxic to mammalian cells, which render them clinically impractical to use to treat infectious diseases. Instead, they have been used extensively as biochemical tools to study the N-linked glycosylation of proteins. However, despite such a routine application, their inhibitory mechanisms are still not clear. The central objective of this thesis was to develop novel tunicamycin analogues that are non-toxic to eukaryotic cells that could serve as potential antimicrobial drug candidates. We hypothesised that if we retain the lipid character of tunicamycin structure and modify the GlcNAc moiety then the antimicrobial activity would be retained but the tunicamycins inhibitory action towards GPT would be abolished, thus diminishing tunicamycins cytotoxicity towards mammalian cells. <b>I - Semi-synthesis of the Tunicamycin Core Scaffolds and Lipid Analogues</b> Semi-synthetic strategies were devised for isolating tunicamycin core scaffolds and for the selective addition of lipid chains at the 10'-N and 2"-N positions of tunicamycin, yielding the first library of novel tunicamycin lipid analogues. <b>II - Biological Evaluations of the Tunicamycin Core Scaffolds and Lipid Analogues</b> For the first time, the antibacterial activity of tunicamycins was shown to be dependent on the presence of a lipid chain. The tunicamycin core scaffolds were shown to lack antibacterial activity and cytotoxicity. More importantly, the library of tunicamycin lipid analogues with lipid chain length from seven to twelve carbons showed titrated antibacterial activity profile. Furthermore, the tunicamycin lipid analogues were not only found to have potent antibacterial and anti-M. tuberculosis activities but were non-cytotoxic compared to tunicamycins. The relative therapeutic index calculated for the tunicamycin lipid analogues was up to several thousand folds more than tunicamycins. <b>III - Investigation of the tunB and tunF Knockout in the tun Gene Cluster</b> The tunB and tunF single knockout mutations were made in the tun gene cluster by PCR-targeting and then heterologously expressed in S. coelicolor. The tunB knockout successfully abolished tunicamycin biosynthesis and showed evidence by MS the first existence of exo-glycal intermediates in sugar biology, further supporting the discovery of TunA as a novel NDP-sugar 5,6-dehydrogenase. <b>IV - Investigation of the TunD and TunE Enzymatic Activities in Tunicamycin Biosynthetic Pathway</b> The recapitulation of TunD glycosyltransferase and TunE deacetylase activities in vitro were attempted. Recombinant TunD was refolded from insoluble TunD inclusion bodies, while TunE was isolated in small quantities. However, no TunD and TunE activities were found using proposed intermediates. The co-translation of the tun gene cluster and the formation of multi-protein complex are proposed to be involved in the tunicamycin biosynthesis.

615.3

Transformação genética de cana-de-açúcar por biolística e Agrobacterium tumefaciens visando estudar o mecanismo de morte celular programada / Genetic transformation of sugarcane by biolistic and Agrobacterium tumefaciens to study the mechanism of programmed cell death

Melotto-Passarin, Danila Montewka

08 April 2009

A cana-de-açúcar é uma das principais culturas agrícolas plantadas no Brasil e apresenta significativa importância sócio-econômica e agroindustrial ao país. O cenário mundial encontrase bastante favorável no que concerne à comercialização de seus dois principais produtos derivados, o açúcar e o álcool, impulsionando o desenvolvimento do setor sucroalcooleiro nacional. Neste sentido, o melhoramento genético da cana-de-açúcar aparece como base fundamental para o desenvolvimento de novas variedades para a manutenção e incremento dos agronegócios da agroindústria sucroalcooleira. Técnicas de engenharia genética, como a transformação genética nuclear, estão trazendo excelentes resultados no melhoramento genético da cultura, permitindo diminuir o custo e o tempo de obtenção de novas variedades. Baseando-se na importância em se obter variedades tolerantes a diferentes estresses bióticos e abióticos que induzem perturbações metabólicas e ativam o processo de morte celular programada, o presente trabalho teve por objetivo transformar geneticamente a variedade de cana-de-açúcar RB835089 com o cDNA do gene AtBI-1 isolado de Arabidopsis thaliana, visando suprimir a indução do mecanismo de morte celular sob condição de estresse. Para isto, calos embriogênicos foram utilizados como explante alvo, empregando-se dois métodos de transformação, a cotransformação por biolística, e o mediado por Agrobacterium tumefaciens no qual foram testadas duas técnicas: (a) inoculação direta dos calos em suspensão bacteriana; e (b) agrobiolística que é o bombardeamento dos calos com partículas de tungstênio seguido da inoculação em suspensão bacteriana. A proteína AtBI-1 (Bax inhibitor-1) apresenta homólogos em outros organismos e está localizada na membrana do retículo endoplasmático. Ela apresenta funções citoprotetoras modulando o mecanismo de morte celular programada induzida por estresses bióticos e abióticos. Como resultados deste trabalho, diferentes taxas de eficiência da transformação genética foram obtidas pelo método mediado por A. tumefaciens nas duas técnicas testadas, sendo que suas taxas foram superiores às alcançadas pelo método de co-transformação por biolística. A expressão heteróloga do cDNA do gene AtBI-1 em cana-de-açúcar atenuou a indução das vias de morte celular em presença do antibiótico tunicamicina, indutor do estresse no retículo endoplasmático, sendo comprovado pela maior tolerância ao estresse das plantas transgênicas quando comparadas com as plantas não transformadas que foram afetas no crescimento do sistema radicular, conteúdo de clorofila total, apresentando sintomas típicos de morte celular programada como clorose foliar e morfologia irregular das raízes, com consequente morte do sistema radicular. / Sugarcane is one of the main crops planted in Brazil and presents significant socioeconomic and agribusiness importance to the country. The world scene is quite favorable as regards the marketing of its two main products, sugar and alcohol, driving the development of the national sugar-alcohol sector. Therefore, the sugarcane genetic breeding appears as the fundamental base for developing new varieties for the maintenance and increase of agribusiness in the sugarcane agroindustry. Genetic engineering techniques, such as the nuclear genetic transformation, are providing excellent results in genetic breeding of this crop allowing reducing the cost and time to obtain new varieties. Based on the importance of obtaining varieties tolerant to different biotic and abiotic stresses that induce metabolic disturbances and activate the process of programmed cell death, this work aimed to transform sugarcane variety RB835089 with the cDNA of AtBI-1 gene, isolated from Arabidopsis thaliana, to suppress the induction of the cell death mechanism under stress condition. For this, embryogenic calli were used as target explant, by using two methods of transformation, the cotransformation by biolistic, and mediated by Agrobacterium tumefaciens in which two techniques were tested: (a) direct inoculation of calli in bacterial suspension; (b) agrobiolistic which is the bombardment of calli with tungstein particles followed by inoculation in bacterial suspension. The AtBI-1 protein (Bax inhibitor-1) presents homologs in other organisms and is located in the endoplasmic reticulum membranes. It has cytoprotective functions by modulating the mechanism of programmed cell death induced by biotic and abiotic stresses. As results of this work, different efficiency rates in genetic transformation were obtained in the method mediated by A. tumefaciens in the two techniques tested, and that their rates were higher than those achieved using the cotransformation by biolistic. The heterologous expression of cDNA of AtBI-1 gene in sugarcane attenuated the induction of cell death pathways in the presence of tunicamycin antibiotic, an inducer of stress in the endoplasmic reticulum, being proven by the increased stress tolerance of transgenic plants compared with sugarcane wild type that were affected in the root growth, total chlorophyll content, showing typical symptoms of programmed cell death such as leaf chlorosis and irregular morphology of the roots, with subsequent death of the root system.

Abiotic stress

Agrobacterium tumefaciens

AtBI-1 gene

Bactérias gram-negativas

biolistic

Biolística

Biologia molecular vegetal

Cana-de-açúcar

Genetic transformation

Genética molecular vegetal

Programmed cell death

Sugarcane

Tunicamycin antibiotic.

Variação genética em plantas.

Transformação genética de cana-de-açúcar por biolística e Agrobacterium tumefaciens visando estudar o mecanismo de morte celular programada / Genetic transformation of sugarcane by biolistic and Agrobacterium tumefaciens to study the mechanism of programmed cell death

Danila Montewka Melotto-Passarin

08 April 2009

A cana-de-açúcar é uma das principais culturas agrícolas plantadas no Brasil e apresenta significativa importância sócio-econômica e agroindustrial ao país. O cenário mundial encontrase bastante favorável no que concerne à comercialização de seus dois principais produtos derivados, o açúcar e o álcool, impulsionando o desenvolvimento do setor sucroalcooleiro nacional. Neste sentido, o melhoramento genético da cana-de-açúcar aparece como base fundamental para o desenvolvimento de novas variedades para a manutenção e incremento dos agronegócios da agroindústria sucroalcooleira. Técnicas de engenharia genética, como a transformação genética nuclear, estão trazendo excelentes resultados no melhoramento genético da cultura, permitindo diminuir o custo e o tempo de obtenção de novas variedades. Baseando-se na importância em se obter variedades tolerantes a diferentes estresses bióticos e abióticos que induzem perturbações metabólicas e ativam o processo de morte celular programada, o presente trabalho teve por objetivo transformar geneticamente a variedade de cana-de-açúcar RB835089 com o cDNA do gene AtBI-1 isolado de Arabidopsis thaliana, visando suprimir a indução do mecanismo de morte celular sob condição de estresse. Para isto, calos embriogênicos foram utilizados como explante alvo, empregando-se dois métodos de transformação, a cotransformação por biolística, e o mediado por Agrobacterium tumefaciens no qual foram testadas duas técnicas: (a) inoculação direta dos calos em suspensão bacteriana; e (b) agrobiolística que é o bombardeamento dos calos com partículas de tungstênio seguido da inoculação em suspensão bacteriana. A proteína AtBI-1 (Bax inhibitor-1) apresenta homólogos em outros organismos e está localizada na membrana do retículo endoplasmático. Ela apresenta funções citoprotetoras modulando o mecanismo de morte celular programada induzida por estresses bióticos e abióticos. Como resultados deste trabalho, diferentes taxas de eficiência da transformação genética foram obtidas pelo método mediado por A. tumefaciens nas duas técnicas testadas, sendo que suas taxas foram superiores às alcançadas pelo método de co-transformação por biolística. A expressão heteróloga do cDNA do gene AtBI-1 em cana-de-açúcar atenuou a indução das vias de morte celular em presença do antibiótico tunicamicina, indutor do estresse no retículo endoplasmático, sendo comprovado pela maior tolerância ao estresse das plantas transgênicas quando comparadas com as plantas não transformadas que foram afetas no crescimento do sistema radicular, conteúdo de clorofila total, apresentando sintomas típicos de morte celular programada como clorose foliar e morfologia irregular das raízes, com consequente morte do sistema radicular. / Sugarcane is one of the main crops planted in Brazil and presents significant socioeconomic and agribusiness importance to the country. The world scene is quite favorable as regards the marketing of its two main products, sugar and alcohol, driving the development of the national sugar-alcohol sector. Therefore, the sugarcane genetic breeding appears as the fundamental base for developing new varieties for the maintenance and increase of agribusiness in the sugarcane agroindustry. Genetic engineering techniques, such as the nuclear genetic transformation, are providing excellent results in genetic breeding of this crop allowing reducing the cost and time to obtain new varieties. Based on the importance of obtaining varieties tolerant to different biotic and abiotic stresses that induce metabolic disturbances and activate the process of programmed cell death, this work aimed to transform sugarcane variety RB835089 with the cDNA of AtBI-1 gene, isolated from Arabidopsis thaliana, to suppress the induction of the cell death mechanism under stress condition. For this, embryogenic calli were used as target explant, by using two methods of transformation, the cotransformation by biolistic, and mediated by Agrobacterium tumefaciens in which two techniques were tested: (a) direct inoculation of calli in bacterial suspension; (b) agrobiolistic which is the bombardment of calli with tungstein particles followed by inoculation in bacterial suspension. The AtBI-1 protein (Bax inhibitor-1) presents homologs in other organisms and is located in the endoplasmic reticulum membranes. It has cytoprotective functions by modulating the mechanism of programmed cell death induced by biotic and abiotic stresses. As results of this work, different efficiency rates in genetic transformation were obtained in the method mediated by A. tumefaciens in the two techniques tested, and that their rates were higher than those achieved using the cotransformation by biolistic. The heterologous expression of cDNA of AtBI-1 gene in sugarcane attenuated the induction of cell death pathways in the presence of tunicamycin antibiotic, an inducer of stress in the endoplasmic reticulum, being proven by the increased stress tolerance of transgenic plants compared with sugarcane wild type that were affected in the root growth, total chlorophyll content, showing typical symptoms of programmed cell death such as leaf chlorosis and irregular morphology of the roots, with subsequent death of the root system.

Bactérias gram-negativas

Biolística

Biologia molecular vegetal

Cana-de-açúcar

Genética molecular vegetal

Variação genética em plantas.

Abiotic stress

Agrobacterium tumefaciens

AtBI-1 gene

biolistic

Genetic transformation

Programmed cell death

Sugarcane

Tunicamycin antibiotic.