Avaliação do perfil de sensibilidade de Klebsiella pneumoniae resistente aos carbapenêmicos e à polimixina B frente a polimixina B modificada pela complexação ao íon metálico cobre

Vecchi, Rafael

January 2019

Orientador: James Venturini / Resumo: Devido ao crescente isolamento de espécimes de Klebsiella pneumoniae resistentes a praticamente todas as classes de drogas antimicrobianas, a busca por novas drogas que sejam alternativa terapêutica para o tratamento das infecções por eles causadas se torna relevante. Nesse contexto, a complexação de íons metálicos a drogas antimicrobianas é uma das abordagens empregadas, uma vez que é possível gerar novas drogas com atividade superior as drogas já existentes. No presente estudo, foi realizada a síntese de metalofármaco por reação de coordenação entre sulfato de polimixina B e cobre (II). O produto desta reação foi caracterizado e sua atividade antimicrobiana frente a espécimes de K. pneumoniae resistentes aos carbapenêmicos e à polimixina B foi avaliada. Os resultados demonstraram que as concentrações inibitórias mínimas (MIC) do complexo sintetizado foram menores em relação aos MICs de polimixina B para 44,44% dos espécimes avaliados; para 33,33% dos espécimes os MIC’s foram equivalentes, e para 22,23% dos espécimes os MIC’s do complexo foram superiores aos MIC’s da polimixina B. Esses resultados são promissores, uma vez que houve um incremento na atividade bacteriana da polimixina complexada ao metal para quase metade dos espécimes avaliados, mostrando que a síntese de novas drogas antimicrobianas através da complexação de íons metálicos é uma técnica que deve ser mais explorada. Além disso, nossos resultados devem conduzir a novos estudos que visem a melhor compreensão da... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Due to the increasing isolation of Klebsiella pneumoniae specimens resistant to virtually all classes of antimicrobial drugs, the research for new drugs that are alternative therapeutics for the treatment of infections caused by them becomes relevant. In this context, the complexation of metal ions to antimicrobial drugs is one of the approaches used, since it is possible to generate new drugs with higher activity than existing drugs. In the present study, metallodrugs synthesis was performed by a coordination reaction between polymyxin B sulfate and copper (II). The product of this reaction was characterized and its antimicrobial activity against specimens of K. pneumoniae resistant to carbapenems and polymyxin B was evaluated. The results showed that the minimum inhibitory concentrations (MIC) of the synthesized complex were lower than the polymyxin B MICs for 44.44% of the evaluated specimens; for 33.33% of the specimens the MICs were equivalent, and for 22.23% of the specimens the MICs of the complex were superior to the MICs of polymyxin B. These results are encouraging, since there was an increase in the bacterial activity of metal complexed polymyxin for almost half of the evaluated specimens, showing that the synthesis of new antimicrobial drugs through the complexation of metallic ions is a technique that should be further explored. In addition, our results should lead to further studies aiming to a better understanding of the structure, mechanisms of action, toxicit... (Complete abstract click electronic access below) / Mestre

polimixina B

complexo com cobre

multirresistência

Klebsiella pneumoniae.

polymyxin B

copper complex

multidrug-resistance

The role of p53 in the drug resistance phenotype of childhood neuroblastoma

Xue, Chengyuan, School of Women?s & Children?s Health, UNSW

January 2007

The development of resistance to chemotherapeutic drugs is the main obstacle to the successful treatment of many cancers, including childhood neuroblastoma, the most common solid tumour of infants. One factor that may play a role in determining response of neuroblastoma tumours to therapeutic agents is the p53 tumour suppressor gene. A number of previous studies have suggested that this tumour suppressor protein is inactive in neuroblastoma due to its cytoplasmic sequestration. This thesis therefore has examined the functionality of p53 and its role in determining drug response of neuroblastoma cells. An initial study was undertaken that characterised an unusually broad multidrug resistance (MDR) phenotype of a neuroblastoma cell line (IMR/KAT100). The results demonstrated that the MDR phenotype of the IMR/KAT100 cells was associated with the acquisition of mutant p53. To explore the role of p53 in drug resistance further, p53-deficient variants in cell lines with wild-type p53 were generated by transduction of p53-suppressive constructs encoding either shRNA or a dominant-negative p53 mutant. Analysis of these cells indicated that: (i) in contrast to previous reports, wild-type p53 was fully functional in all neuroblastoma lines tested, as evidenced by its activation and nuclear translocation in response to DNA damage, transactivation of target genes and control of cell cycle checkpoints; (ii) inactivation of p53 in neuroblastoma cells resulted in establishment of an MDR phenotype; (iii) knockdown of mutant p53 did not revert the drug resistance phenotype, suggesting it is determined by loss of wild-type function rather than gain of mutant function; (iv) p53-dependent cell senescence, the primary response of S-type neuroblastoma cells to DNA damage, is replaced, after p53 inactivation, by mitotic catastrophe and subsequent apoptosis. In contrast to neuroblastoma, p53 suppression had no effect or increased drug susceptibility in several other tumour cell types, indicating the importance of tissue context for p53- mediated modulation of tumour cell sensitivity to treatment. Taken together, these data provide strong evidence for p53 having a role in mediating drug resistance in neuroblastoma and suggest that p53 status may be an important prognostic marker of treatment response in this disease.

Neuroblastoma -- Genetic aspects.

Drug resistance in cancer cells.

Multidrug resistance.

p53 antioncogene.

Tumors in children.

The Regulation of Multidrug Resistance Phosphoglycoprotein (MDR1/P-gp) and Breast Cancer Resistance Protein (BCRP) in the Human Placenta

Rainey, Jenna

04 May 2011

Multidrug resistance phosphoglycoprotein (MDR1/P-gp) and breast cancer resistance protein (BCRP) were first isolated in chemoresistant cancer cells and have since been found in a variety of normal tissue, including the placenta. The potential function of MDR1/P-gp and BCRP in the human placenta is to protect the fetus from maternally circulating endogenous steroids and hormones, therapeutic drugs and toxins. The objective of this study was to examine the role of maternal steroids in the regulation of MDR1/P-gp and BCRP in the human placenta. Trophoblast cells were isolated from term placenta tissues and immunohistochemistry, western blot analysis and transport studies were used to determine the effect of maternal steroids on MDR1/P-gp and BCRP regulation. Maternal steroids, present at high concentrations in maternal serum, did not have an effect on BCRP in human syncytiotrophoblast. Estrogen and progesterone did not alter MDR1/P-gp levels in human syncytiotrophoblast, but cortisol significantly decreased MDR1/P-gp levels.

Breast Cancer Resistance Protein (BCRP)

Human Placenta

Multidrug Resistance Protein 1 (MDR1) and Glycosphingolipids Biosynthesis: Advantages for Therapeutics

De Rosa, Maria Fabiana

03 March 2010

ABC drug transporter, MDR1, is a drug flippase that moves a variety of hydrophobic molecules from the inner to the outer leaflet of the plasma membrane. We have previously reported that MDR1 can function as a glycolipid flippase, being one of the mechanisms responsible for the translocation of glucosylceramide into the Golgi for neutral, but not acidic, glycosphingolipids (GSLs) synthesis. The interplay between GSLs and MDR1 could provide a whole new spectrum of innovative therapeutic options. We found that cell surface MDR1 partially co-localized with globotriaosyl ceramide (Gb3) in MDR1 transfected cells. Inhibition of GSL biosynthesis results in the loss of drug resistance and of cell surface MDR1. We speculated that an association of MDR1 and cell surface GSLs, in particular Gb3, may be functional at the cell surface, as MDR1 partitions into plasma membrane lipid rafts regulating MDR1 function. We therefore tested adamantyl Gb3 (adaGb3), a water soluble analog of Gb3, on MDR1 functions. AdaGb3 was able to inhibit MDR1-mediated rhodamine 123 drug efflux from MDR1 expressing cells, like cyclosporin A (CsA), a classical MDR1 inhibitor. AdaGb3 was also able to reverse vinblastine drug resistance in cell culture, whereas adamantyl galactosylceramide had no effect on drug resistance. The strong MDR1 reversal effects of adaGb3, as well as its favourable in vivo features make it a possible choice for inhibition of MDR1 to increase bioavailability of drugs across the intestinal epithelium (De Rosa et al., 2008). Thus, specific GSL analogs provide a new approach to MDR reversal. We have previously shown that MDR1 inhibitor CsA depletes Fabry cell lines of Gb3, the characteristic GSL accumulated in this disease, by preventing its de novo synthesis, and can also deplete Gaucher lymphoid cell lines of accumulated GlcCer (Mattocks et al., 2006). Liver and heart sections of Fabry mice treated with third generation MDR1 inhibitors showed significantly less Gb3 than liver and heart sections of untreated Fabry mice. Thus, MDR1 inhibition offers a potential alternative therapeutic approach not only for Fabry disease given the extraordinary cost of conventional enzyme replacement therapy, but also for other neutral GSL storage diseases, such as Gaucher disease.

P-glycoprotein

Multidrug Resistance

glycosphingolipids

Fabry disease

Adamantyl Gb3

0379

0419

0487

Multidrug Resistance Protein 1 (MDR1) and Glycosphingolipids Biosynthesis: Advantages for Therapeutics

De Rosa, Maria Fabiana

03 March 2010

ABC drug transporter, MDR1, is a drug flippase that moves a variety of hydrophobic molecules from the inner to the outer leaflet of the plasma membrane. We have previously reported that MDR1 can function as a glycolipid flippase, being one of the mechanisms responsible for the translocation of glucosylceramide into the Golgi for neutral, but not acidic, glycosphingolipids (GSLs) synthesis. The interplay between GSLs and MDR1 could provide a whole new spectrum of innovative therapeutic options. We found that cell surface MDR1 partially co-localized with globotriaosyl ceramide (Gb3) in MDR1 transfected cells. Inhibition of GSL biosynthesis results in the loss of drug resistance and of cell surface MDR1. We speculated that an association of MDR1 and cell surface GSLs, in particular Gb3, may be functional at the cell surface, as MDR1 partitions into plasma membrane lipid rafts regulating MDR1 function. We therefore tested adamantyl Gb3 (adaGb3), a water soluble analog of Gb3, on MDR1 functions. AdaGb3 was able to inhibit MDR1-mediated rhodamine 123 drug efflux from MDR1 expressing cells, like cyclosporin A (CsA), a classical MDR1 inhibitor. AdaGb3 was also able to reverse vinblastine drug resistance in cell culture, whereas adamantyl galactosylceramide had no effect on drug resistance. The strong MDR1 reversal effects of adaGb3, as well as its favourable in vivo features make it a possible choice for inhibition of MDR1 to increase bioavailability of drugs across the intestinal epithelium (De Rosa et al., 2008). Thus, specific GSL analogs provide a new approach to MDR reversal. We have previously shown that MDR1 inhibitor CsA depletes Fabry cell lines of Gb3, the characteristic GSL accumulated in this disease, by preventing its de novo synthesis, and can also deplete Gaucher lymphoid cell lines of accumulated GlcCer (Mattocks et al., 2006). Liver and heart sections of Fabry mice treated with third generation MDR1 inhibitors showed significantly less Gb3 than liver and heart sections of untreated Fabry mice. Thus, MDR1 inhibition offers a potential alternative therapeutic approach not only for Fabry disease given the extraordinary cost of conventional enzyme replacement therapy, but also for other neutral GSL storage diseases, such as Gaucher disease.

P-glycoprotein

Multidrug Resistance

glycosphingolipids

Fabry disease

Adamantyl Gb3

0379

0419

0487

The Regulation of Multidrug Resistance Phosphoglycoprotein (MDR1/P-gp) and Breast Cancer Resistance Protein (BCRP) in the Human Placenta

Rainey, Jenna

04 May 2011

Multidrug resistance phosphoglycoprotein (MDR1/P-gp) and breast cancer resistance protein (BCRP) were first isolated in chemoresistant cancer cells and have since been found in a variety of normal tissue, including the placenta. The potential function of MDR1/P-gp and BCRP in the human placenta is to protect the fetus from maternally circulating endogenous steroids and hormones, therapeutic drugs and toxins. The objective of this study was to examine the role of maternal steroids in the regulation of MDR1/P-gp and BCRP in the human placenta. Trophoblast cells were isolated from term placenta tissues and immunohistochemistry, western blot analysis and transport studies were used to determine the effect of maternal steroids on MDR1/P-gp and BCRP regulation. Maternal steroids, present at high concentrations in maternal serum, did not have an effect on BCRP in human syncytiotrophoblast. Estrogen and progesterone did not alter MDR1/P-gp levels in human syncytiotrophoblast, but cortisol significantly decreased MDR1/P-gp levels.

Breast Cancer Resistance Protein (BCRP)

Human Placenta

Multiple Drug Resistance Mechanisms In Imatinib Resistat Human Chronic Myeloid Leukemia Cells

Baran, Yusuf

01 August 2006

In this study, mechanisms of resistance to Imatinib-induced apoptosis in human K562 and Meg-1 chronic myeloid leukemia (CML) cells were examined. Continuous exposure of cells to step-wise increasing concentrations of Imatinib resulted in the selection of 0.2 and 1 &amp / #956 / M imatinib resistant cells. Measurement of endogenous ceramide levels showed that treatment with Imatinib increased the generation of C18-ceramide significantly, which is mainly synthesized by the human longevity assurance gene 1 (hLASS1), in sensitive, but not in resistant cells. Mechanistically, analysis of mRNA and enzyme activity levels of hLASS1 in the absence or presence of Imatinib did not show any significant differences in the resistant cells when compared to its sensitive counterparts, suggesting that accumulation and/or metabolism, but not the synthesis of ceramide, might be altered in resistant cells. iv Indeed, further studies demonstrated that expression levels, and enzyme activity of sphingosine kinase-1 (SK-1), increased significantly in resistant K562 or Meg-1 cells. The expression levels of glucosyl ceramide synthase (GCS) also increased in resistant cells, comparing to the sensitive counterparts, which indicates conversion of pro-apoptotic ceramide to glucosyl ceramide. Expression analyses of BCR-ABL gene demonstrated that expression levels of BCR-ABL gene increased gradually as the cells acquired the resistance. However, Nucleotide sequence analyses of ABL kinase gene revealed that there was no mutation in Imatinib binding region of the gene in resistant cells. There was also an increase in expression levels of MDR1 gene in resistant cells, which transport the toxic substances outside of cells. In conclusion, these data show, for the first time, a role for endogenous ceramide synthesis via hLASS1 in Imatinib-induced apoptosis, and those alterations of the balance between the levels of ceramide and S1P. Mainly the overexpression of SK-1 seems to result in resistance to Imatinib in K562 cells. The cellular resistance may also result from conversion of ceramide to glucosyl ceramide, from overexpression of BCR-ABL and MDR1 genes but not due to mutations in Imatinib binding site of ABL kinase.

QH Genetics 426-470

Fabrication Of Poly (dl-lactic-co-glycolic Acid) Nanoparticles And Synthetic Peptide Drug Conjugate For Anti-cancer Drug Delivery

Sen, Gulseren Petek

01 January 2010

Cancer is a group of diseases in which normal cells are converted to cells capable of autonomous growth and invasion. In the chemotherapeutic control of cancer, drugs are usually given systemically so they reach toxic levels in healthy cells as well as cancer cells. This causes serious side effects. Another important problem with chemotherapy is resistance developed to cytotoxic drugs (multi drug resistance). Doxorubicin (Dox) occupies a central position in the treatment of breast cancer. However doxorubicin induced cardiac toxicity is associated with a high incidence of morbidity and mortality. Resistance of malignant tumors to Dox is another important cause of treatment failure in patients with cancer. One approach to overcome Dox-related toxicity is to use polymeric drug carriers, which direct the Dox away from heart tissue, and allow usage of lower dosages. In this present study two different anti-cancer drug delivery methods were evaluated. Dox was encapsulated in PLGA microparticles by single and double microemulsion solvent evaporation techniques. The highest entrapment of doxorubicin within PLGA microspheres obtained by optimization of process parameters. A sustained release of doxorubicin was obtained for 20 days. Several protein transduction domains are known to have the ability to pass through biological membranes. One such peptide is HIV-1 TAT. In this study TAT was evaluated for its ability to carry Dox into Dox resistant MCF-7 tumor cells. Dox peptide conjugate was more potent than free drug. The concentration of drug in resistant cancer cells was increased indicating a partial reversal of drug resistance.

QH General Biology 301-705

ABCC2 (cMOAT) : role in 4-hydroxycyclophosphamide elimination from the liver and survival of high dose cyclophosphamide regimens /

Qiu, Ruolun.

January 2003

Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 101-113).

Role of caveolin-1 in multidurg resistance in hepatocellularcarcinoma

Wong, Wing-sum, Winnie., 王詠心.

January 2011

published_or_final_version / Pathology / Master / Master of Medical Sciences

Membrane proteins.

Liver - Cancer - Molecular aspects.

Drug resistance in cancer cells.

Multidrug resistance.