Efeitos da 5-iodotubercidina em linhagens de melanoma humano parentais e resistentes ao inibidor de BRAF / Effects of 5-iodotubercidin on human melanoma lines of parental and resistant to the BRAF inhibitor

Stephanie Cristine Carvalho dos Santos

13 February 2019

O melanoma é responsável por menos de 5% dos cânceres de pele, porém, 95% das mortes ocorrem devido a ocorrência de metástases. O melanoma metastático é refratário às terapias convencionais e rapidamente adquire resistência às terapias como as oncogene-dirigidas, como o inibidor de BRAF, da via de MAPK. Estudos prévios de screening in silico do nosso grupo, onde se utilizou as bases de dados TCGA e GEO, identificaram o gene adenosina quinase (ADK) como sendo diferencialmente expresso entre o melanoma invasivo e os nevus. A 5-iodotubercidina (5-ITu) é um potente inibidor farmacológico da ADK que dentre os diversos efeitos relatados na literatura destaca-se pelo potencial genotóxico. Os danos no DNA são os principais ativadores de checkpoint do ciclo celular, que levam a parada do ciclo celular transitória ou permanente, além de induzir morte celular, levando a hipótese de que ADK possa ser potencial agente anti-melanoma. Este trabalho objetivou avaliar a expressão do gene ADK em melanomas humanos e quimiorresistentes ao inibidor de BRAF (iBRAF), avaliou os impactos de 5-ITu sobre a proliferação, progressão do ciclo celular e morte celular e por fim avaliamos sua capacidade de aumentar a sensibilidade das células. Foi realizado PCR em tempo real para avaliar os níveis de expressão de mRNA de ADK em linhagens de melanoma e na cultura primária de melanócitos; a fim de avaliar a citotoxicidade de 5-ITu foram realizados os ensaios de exclusão por azul de tripan e de apoptose - Anexina V e PI e em modelo de esferoide, usando live/dead; também foi avaliada a influência de 5-ITu sobre a capacidade clonogênica e seus efeitos sobre a proliferação celular, a partir dos ensaios de ciclo celular e avaliação de marcadores de proliferação por imunofluorescência; as linhagens foram submetidas a diferentes regimes de tratamento com 5-ITu e o iBRAF, a fim de avaliar a curva de crescimento e a sensibilidade ao iBRAF por MTT níveis de expressão de mRNA de ADK maiores nas linhagens tumorais em relação aos melanócitos. 5-ITu mostrou-se capaz de inibir a proliferação (IC50) das linhagens de melanoma em concentrações de 1,9 a 3,5 µM. 5-ITu não foi capaz de induzir inviabilidade celular, apesar de reduzir a quantidade de células viáveis em todas as condições de tratamento, também não foi capaz de induzir aumento significativo de células apoptóticas, nem mesmo necróticas. No entanto, o tratamento com 5-ITu reduziu a capacidade clonogênica de linhagens de melanoma e promoveu parada de ciclo celular nas fases G1 e G2/M, levou ao aumento da população subG1. O tratamento com 5-ITu promoveu a redução da expressão de marcadores de proliferação, como ki67, e a combinação de tratamentos 5-ITu e iBraf foi capaz de aumentar o tempo de dobramento das linhagens de melanoma, embora tenha se mostrado incapaz de sensibilizar as células de melanoma ao tratamento com iBRAF. Desse modo, pode-se concluir que 5-ITu induz o efeito citostático e se mostra um potente agente antiproliferativo para melanoma parental e resistente. / Melanoma accounts for less than 5% of skin cancers, but 95% of deaths occur due to metastases. Metastatic melanoma is refractory to conventional therapies and rapidly acquires resistance to therapies such as oncogene-directed, such as the BRAF inhibitor, of the MAPK pathway. Previous studies of screening in silico of our group, using the databases TCGA and GEO, identified the adenosine kinase gene (ADK) as differentially expressed between invasive melanoma and nevus. 5-iodotubercidin (5-ITu) is a potent pharmacological inhibitor of ADK that among the several effects reported in the literature stands out for the genotoxic potential. DNA damage is the main activator of the cell cycle checkpoint, which leads to transient or permanent cell cycle arrest, in addition to inducing cell death, leading to the hypothesis that ADK may be a potential anti-melanoma agent. This work aimed to evaluate the expression of the ADK gene in human melanomas and chemoresistants to the BRAF inhibitor (iBRAF), evaluated the impacts of 5-ITu on proliferation, cell cycle progression and cell death and finally we evaluated its ability to increase the sensitivity of cells. Real-time PCR was performed to assess the levels of ADK mRNA expression in melanoma lines and primary melanocyte culture; in order to evaluate the cytotoxicity of 5-ITu, the trypan blue and apoptosis - Annexin V and PI exclusion and blue spheroid models were performed using live / dead; the influence of 5-ITu on the clonogenic capacity and its effects on cell proliferation, from the cell cycle assays and the evaluation of proliferation markers by immunofluorescence; the cell lines were submitted to different treatment regimens with 5-ITu and iBRAF in order to evaluate the growth curve and the sensitivity to iBRAF by MTT levels of mRNA expression of ADK higher in the tumor lines in relation to the melanocytes. 5-ITu was able to inhibit the proliferation (IC 50) of melanoma lines at concentrations of 1.9 to 3.5 181;M. 5-ITu was not able to induce cell non-viability, although it reduced the amount of viable cells in all treatment conditions, nor was it able to induce a significant increase in apoptotic or even necrotic cells. However, treatment with 5-ITu reduced the clonogenic capacity of melanoma cells and promoted cell cycle arrest in the G1 and G2 / M phases, leading to an increase in the subG1 population. Treatment with 5-ITu promotes the reduction of expression of proliferation markers, such as ki67, and the combination of 5-ITu and iBRAF treatments was able to increase the doubling time of melanoma cells, although it has been shown to be unable to sensitize melanoma cells to treatment with iBRAF. Thus, it can be concluded that 5-ITu induces the cytostatic effect and shows a potent antiproliferative agent for parental and resistant melanoma.

5-Iodotubercidina

Adenosina quinase

Agente citostático

Checkpoint

Danos no DNA

Melanoma

Resistência

5-Iodotubercidin

Adenosine Kinase

Checkpoint

Cytostatic agent

DNA Damage

Melanoma

Resistance

Efeitos da 5-iodotubercidina em linhagens de melanoma humano parentais e resistentes ao inibidor de BRAF / Effects of 5-iodotubercidin on human melanoma lines of parental and resistant to the BRAF inhibitor

Santos, Stephanie Cristine Carvalho dos

13 February 2019

O melanoma é responsável por menos de 5% dos cânceres de pele, porém, 95% das mortes ocorrem devido a ocorrência de metástases. O melanoma metastático é refratário às terapias convencionais e rapidamente adquire resistência às terapias como as oncogene-dirigidas, como o inibidor de BRAF, da via de MAPK. Estudos prévios de screening in silico do nosso grupo, onde se utilizou as bases de dados TCGA e GEO, identificaram o gene adenosina quinase (ADK) como sendo diferencialmente expresso entre o melanoma invasivo e os nevus. A 5-iodotubercidina (5-ITu) é um potente inibidor farmacológico da ADK que dentre os diversos efeitos relatados na literatura destaca-se pelo potencial genotóxico. Os danos no DNA são os principais ativadores de checkpoint do ciclo celular, que levam a parada do ciclo celular transitória ou permanente, além de induzir morte celular, levando a hipótese de que ADK possa ser potencial agente anti-melanoma. Este trabalho objetivou avaliar a expressão do gene ADK em melanomas humanos e quimiorresistentes ao inibidor de BRAF (iBRAF), avaliou os impactos de 5-ITu sobre a proliferação, progressão do ciclo celular e morte celular e por fim avaliamos sua capacidade de aumentar a sensibilidade das células. Foi realizado PCR em tempo real para avaliar os níveis de expressão de mRNA de ADK em linhagens de melanoma e na cultura primária de melanócitos; a fim de avaliar a citotoxicidade de 5-ITu foram realizados os ensaios de exclusão por azul de tripan e de apoptose - Anexina V e PI e em modelo de esferoide, usando live/dead; também foi avaliada a influência de 5-ITu sobre a capacidade clonogênica e seus efeitos sobre a proliferação celular, a partir dos ensaios de ciclo celular e avaliação de marcadores de proliferação por imunofluorescência; as linhagens foram submetidas a diferentes regimes de tratamento com 5-ITu e o iBRAF, a fim de avaliar a curva de crescimento e a sensibilidade ao iBRAF por MTT níveis de expressão de mRNA de ADK maiores nas linhagens tumorais em relação aos melanócitos. 5-ITu mostrou-se capaz de inibir a proliferação (IC50) das linhagens de melanoma em concentrações de 1,9 a 3,5 µM. 5-ITu não foi capaz de induzir inviabilidade celular, apesar de reduzir a quantidade de células viáveis em todas as condições de tratamento, também não foi capaz de induzir aumento significativo de células apoptóticas, nem mesmo necróticas. No entanto, o tratamento com 5-ITu reduziu a capacidade clonogênica de linhagens de melanoma e promoveu parada de ciclo celular nas fases G1 e G2/M, levou ao aumento da população subG1. O tratamento com 5-ITu promoveu a redução da expressão de marcadores de proliferação, como ki67, e a combinação de tratamentos 5-ITu e iBraf foi capaz de aumentar o tempo de dobramento das linhagens de melanoma, embora tenha se mostrado incapaz de sensibilizar as células de melanoma ao tratamento com iBRAF. Desse modo, pode-se concluir que 5-ITu induz o efeito citostático e se mostra um potente agente antiproliferativo para melanoma parental e resistente. / Melanoma accounts for less than 5% of skin cancers, but 95% of deaths occur due to metastases. Metastatic melanoma is refractory to conventional therapies and rapidly acquires resistance to therapies such as oncogene-directed, such as the BRAF inhibitor, of the MAPK pathway. Previous studies of screening in silico of our group, using the databases TCGA and GEO, identified the adenosine kinase gene (ADK) as differentially expressed between invasive melanoma and nevus. 5-iodotubercidin (5-ITu) is a potent pharmacological inhibitor of ADK that among the several effects reported in the literature stands out for the genotoxic potential. DNA damage is the main activator of the cell cycle checkpoint, which leads to transient or permanent cell cycle arrest, in addition to inducing cell death, leading to the hypothesis that ADK may be a potential anti-melanoma agent. This work aimed to evaluate the expression of the ADK gene in human melanomas and chemoresistants to the BRAF inhibitor (iBRAF), evaluated the impacts of 5-ITu on proliferation, cell cycle progression and cell death and finally we evaluated its ability to increase the sensitivity of cells. Real-time PCR was performed to assess the levels of ADK mRNA expression in melanoma lines and primary melanocyte culture; in order to evaluate the cytotoxicity of 5-ITu, the trypan blue and apoptosis - Annexin V and PI exclusion and blue spheroid models were performed using live / dead; the influence of 5-ITu on the clonogenic capacity and its effects on cell proliferation, from the cell cycle assays and the evaluation of proliferation markers by immunofluorescence; the cell lines were submitted to different treatment regimens with 5-ITu and iBRAF in order to evaluate the growth curve and the sensitivity to iBRAF by MTT levels of mRNA expression of ADK higher in the tumor lines in relation to the melanocytes. 5-ITu was able to inhibit the proliferation (IC 50) of melanoma lines at concentrations of 1.9 to 3.5 181;M. 5-ITu was not able to induce cell non-viability, although it reduced the amount of viable cells in all treatment conditions, nor was it able to induce a significant increase in apoptotic or even necrotic cells. However, treatment with 5-ITu reduced the clonogenic capacity of melanoma cells and promoted cell cycle arrest in the G1 and G2 / M phases, leading to an increase in the subG1 population. Treatment with 5-ITu promotes the reduction of expression of proliferation markers, such as ki67, and the combination of 5-ITu and iBRAF treatments was able to increase the doubling time of melanoma cells, although it has been shown to be unable to sensitize melanoma cells to treatment with iBRAF. Thus, it can be concluded that 5-ITu induces the cytostatic effect and shows a potent antiproliferative agent for parental and resistant melanoma.

5-Iodotubercidin

5-Iodotubercidina

Adenosina quinase

Adenosine Kinase

Agente citostático

Checkpoint

Checkpoint

Cytostatic agent

Danos no DNA

DNA Damage

Melanoma

Melanoma

Resistance

Resistência

Targeting the nucleotide metabolism of the mammalian pathogen Trypanosoma brucei

Vodnala, Munender

January 2013

Trypanosoma brucei causes African sleeping sickness in humans and Nagana in cattle. There are no vaccines available against the disease and the current treatment is also not satisfactory because of inefficacy and numerous side effects of the used drugs. T. brucei lacks de novo synthesis of purine nucleosides; hence it depends on the host to make its purine nucleotides. T. brucei has a high affinity adenosine kinase (TbAK), which phosphorylates adenosine, deoxyadenosine (dAdo), inosine and their analogs. RNAi experiments confirmed that TbAK is responsible for the salvage of dAdo and the toxicity of its substrate analogs. Cell growth assays with the dAdo analogs, Ara-A and F-Ara-A, suggested that TbAK could be exploited for drug development against the disease. It has previously been shown that when T. brucei cells were cultivated in the presence of 1 mM deoxyadenosine (dAdo), they showed accumulation of dATP and depletion of ATP nucleotides. The altered nucleotide levels were toxic to the trypanosomes. However the salvage of dAdo in trypanosomes was dramatically reduced below 0.5 mM dAdo. Radiolabeled dAdo experiments showed that it (especially at low concentrations) is cleaved to adenine and converted to ATP. The recombinant methylthioadenosine phosphorylase (TbMTAP) cleaved methylthioadenosine, dAdo and adenosine into adenine and sugar-1-P in a phosphate-dependent manner. The trypanosomes became more sensitive to dAdo when TbMTAP was down-regulated in RNAi experiments. The RNAi experiments confirmed that trypanosomes avoid dATP accumulation by cleaving dAdo. The TbMTAP cleavage-resistant nucleoside analogs, FANA-A and Ara-A, successfully cured T. brucei-infected mice. The DNA building block dTTP can be synthesized either via thymidylate synthase in the de novo pathway or via thymidine kinase (TK) by salvage synthesis. We found that T. brucei and three other parasites contain a tandem TK where the gene sequence was repeated twice or four times in a single open reading frame. The recombinant T. brucei TK, which belongs to the TK1 family, showed broad substrate specificity. The enzyme phosphorylated the pyrimidine nucleosides thymidine and deoxyuridine, as well as the purine nucleosides deoxyinosine and deoxyguanosine. When the repeated sequences of the tandem TbTK were expressed individually as domains, only domain 2 was active. However, the protein could not dimerize and had a 5-fold reduced affinity to its pyrimidine substrates but a similar turnover number as the full-length enzyme. The expressed domain 1 was inactive and sequence analysis revealed that some active residues, which are needed for substrate binding and catalysis, are absent. Generally, the TK1 family enzymes form dimers or tetramers and the quaternary structure is linked to the affinity for the substrates. The covalently linked inactive domain-1 helps domain-2 to form a pseudodimer for the efficient binding of substrates. In addition, we discovered a repetition of an 89-bp sequence in both domain 1 and domain 2, which suggests a genetic exchange between the two domains. T. brucei is very dependent on de novo synthesis via ribonucleotide reductase (RNR) for the production of dNTPs. Even though T. brucei RNR belongs to the class Ia RNR family and contains an ATP-binding cone, it lacks inhibition by dATP. The mechanism behind the RNR activation by ATP and inactivation by dATP was a puzzle for a long time in the ~50 years of RNR research. We carried out oligomerization studies on mouse and E. coli RNRs, which belongs to the same family as T. brucei, to get an understanding of the molecular mechanism behind overall activity regulation. We found that the oligomerization status of RNRs and overall activity mechanism are interlinked with each other. / Targeting the nucleotide metabolism of the mammalian pathogen Trypanosoma brucei.

Trypanosoma brucei

adenosine kinase

thymidine kinase

methylthioadenosine phosphorylase

mouser ribonucleotide reductase

E. coli ribonucleotide reductase

RNR

Ara-A

F-Ara-A

dNTP

NTP

doexynucleotide metabolism

nucleosides

nucleoside kinases

allosteric regulation

Salvage and de novo synthesis of nucleotides in Trypanosoma brucei and mammalian cells /

Fijolek, Artur,

January 2008

Diss. (sammanfattning) Umeå : Umeå universitet, 2008. / Härtill 3 uppsatser.

DNA precursor biosynthesis-allosteric regulation and medical applications /

Rofougaran, Reza,

January 2008

Diss. (sammanfattning) Umeå : Univ., 2008. / Härtill 4 uppsatser.

GEMINIVIRUSES AS MODELS TO STUDY THE ESTABLISHMENT AND MAINTENANCE OF DNA METHYLATION

Jackel, Jamie Nicole

23 August 2013

No description available.

Molecular Biology

Plant Biology

Virology

RNA polymerase IV

RNA polymerase V

DNA methylation

histone methylation

geminivirus

DRB proteins

Dicer-like proteins

Argonaute proteins

silencing suppressor

AL2

L2

Adenosine Kinase

methyl cycle