Efeito da rapamicina em culturas organotípicas de queratinócitos que expressam oncoproteínas de papiloma vírus humano tipo 16 / Effect of rapamycin in organotypic cultures of keratinocytes expressing oncoproteins of Papillomavirus type 16

Rabachini, Tatiana

14 December 2007

A infecção por HPV de alto risco é considerada um dos principais fatores de risco para o desenvolvimento do carcinoma do colo uterino, um das neoplasias mais freqüentes em mulheres de todo o mundo. As oncoproteínas E6 e E7 de HPV-16 são capazes de induzir a degradação dos genes supressores de tumor p53 e pRb, respectivamente. Mais do que isso, a expressão dessas oncoproteínas está relacionada a alterações na via de PI3K/AKT/mTOR. A proteína quinase mTOR apresenta importante papel no controle da tradução de proteínas e é considerada o principal mediador entre crescimento celular e proliferação. A ativação de mTOR é correlacionada à fosforilação das proteínas eIF4G1 e 4EBP1, aumentando assim a taxa de síntese de proteínas. A Rapamicina é um inibidor específico de mTOR e seus análogos apresentam potente atividade antiproliferativa em um grande número de células tumorais e tumores gerados em animais. Uma vez que as proteínas E6 e E7 são capazes de interagir com diversas proteínas da via que controla a atividade de mTOR optamos por investigar o efeito da rapamicina na proliferação de culturas organotípicas de queratinócitos expressando esses genes. Também avaliamos o efeito dos genes E6 e E7 na atividade de mTOR após o tratamento com essa droga. Para geração de culturas organotípicas de queratinócitos infectamos essas células com vetores retrovirais recombinantes contendo os genes E6 e E7 de HPV-16 em conjunto ou separadamente. Nós também avaliamos o papel da degradação de p53 e pRb na resposta à rapamicina através da utilização de mutantes de E6 e E7 incapazes de induzir a degradação dessas proteínas celulares. Após a infecção dos queratinócitos, os mesmos foram semeados em uma matriz de colágeno. Após 6 dias as culturas foram tratadas com 100ng/ml de rapamicina e permaneceram 60h em contato com a droga. Para análise por imunohistoquímica os tecidos foram fixados em formalina tamponada e emblocados em parafina. A reação de imunohistoquímica foi realizada utilizando os anticorpos contra BrdU, p-4EBP1 (ser 65), p-eIF4G1 (ser 1188) e pAKT (ser 473). Os resultados obtidos ilustram que a rapamicina apresenta efeito antiproliferativo em culturas de queratinócitos contendo o vetor vazio. Por outro lado, culturas contendo o gene E7 são resistentes ao efeito antiproliferativo dessa droga. Essa resistência parece estar relacionada à capacidade de E7 induzir a degradação da proteína pRb, uma vez que em queratinócitos expressando o mutante de E7, incapaz de induzir a degradação dessa proteína, não foi observada resistência. Além disso, a fosforilação de eIF4G e 4EBP1 indica que a expressão de E7 impede que a rapamicina seja capaz de inibir a atividade de mTOR. Esses resultados mostram, pela primeira vez, que o efeito antiproliferativo da rapamicina pode ser superado pela expressão de uma proteína viral, no caso a proteína E7 de HPV-16. / High-risk HPV infection has a major etiologic role in development and progression of cervical cancer, one of the most frequent forms of cancer among women worldwide. HPV-16 E6 and E7 oncoproteins are able to induce degradation of p53 and pRb tumor suppressor proteins respectively. Moreover, the expression of these oncoproteins is related to alterations in the PI3K/AKT/mTOR pathway. The cellular kinase mammalian target of Rapamycin (mTOR) is an important regulator of the cellular protein synthesis machinery and has emerged as a principal mediator of cell growth and proliferation. mTOR activation has been shown to stimulates eIF4G1 and 4EBP1 phosphorylation, thus increasing the rate of protein synthesis. Rapamycin is a specific inhibitor of mTOR signaling pathway and its analogues have demonstrated impressive activity against a broad range of human cancer derived cell lines in culture and in human tumor xenograft models. Since E6 and E7 target several proteins controlling the mTOR pathway we aimed to investigate the effect of Rapamycin in the proliferation of organotypic raft cultures expressing these genes. We also evaluated the effect of E6 and E7 genes in mTOR activity after rapamycin treatment. To generate organotypic culture of keratinocytes we infect these cells with recombinant retroviruses containing HPV-16 E6 and E7 together or separately. We also analyzed the role of p53 and pRb degradation in rapamycin responsiveness by using E6 and E7 mutants lacking the hability to inactivate these cellular proteins. After infection, keratinocytes were seeded on to a collagen matrix. After 6 days, these cultures were treated with 100ng/ml of Rapamycin for 60 hours. BrdU was added in the last 12 hours to evaluate proliferation. For immunohistochemistry analysis tissues were fixed in buffered formalin and embedded in paraffin. Immunohistochemistry reactions against BrdU, p-4EBP1 (ser 65), p-eIF4G1 (ser 1188) and p-AKT (ser 473) were performed The results show that proliferation of organotypic cultures of keratinocytes transduced with empty vector is inhibited by Rapamycin. On the other hand, cultures generated with keratinocytes transduced with E7 gene were completely resistance to the antiproliferative effect of Rapamycin. Moreover, we found that this antiproliferative effect was dependent of Rb degradation since the cells transduced with E7 mutant unable do induce Rb degradation were sensitive. In addition, eIF4G and 4EBP1 phosphorylation indicates that E7 expression impairs mTOR inhibition by rapamycin. AKT phosphorilation indicates that rapamycin resistance could be dependent of Rb inactivation induced by E7 expression. These results show for the first time that the Rapamycin antiproliferative effect is bypassed by the expression of a viral oncogene, in this case the HPV-16 E7. Moreover, E7 expression impairs rapamycin to inactivate mTOR.

Cultura organotípica

HPV

HPV

mTOR

mTOR

Oncogenes

Oncogenes

Organotypic cultures

Rapamicina

Rapamycin

Tradução de proteínas

Translation of protein

Efeito da rapamicina em culturas organotípicas de queratinócitos que expressam oncoproteínas de papiloma vírus humano tipo 16 / Effect of rapamycin in organotypic cultures of keratinocytes expressing oncoproteins of Papillomavirus type 16

Tatiana Rabachini

14 December 2007

A infecção por HPV de alto risco é considerada um dos principais fatores de risco para o desenvolvimento do carcinoma do colo uterino, um das neoplasias mais freqüentes em mulheres de todo o mundo. As oncoproteínas E6 e E7 de HPV-16 são capazes de induzir a degradação dos genes supressores de tumor p53 e pRb, respectivamente. Mais do que isso, a expressão dessas oncoproteínas está relacionada a alterações na via de PI3K/AKT/mTOR. A proteína quinase mTOR apresenta importante papel no controle da tradução de proteínas e é considerada o principal mediador entre crescimento celular e proliferação. A ativação de mTOR é correlacionada à fosforilação das proteínas eIF4G1 e 4EBP1, aumentando assim a taxa de síntese de proteínas. A Rapamicina é um inibidor específico de mTOR e seus análogos apresentam potente atividade antiproliferativa em um grande número de células tumorais e tumores gerados em animais. Uma vez que as proteínas E6 e E7 são capazes de interagir com diversas proteínas da via que controla a atividade de mTOR optamos por investigar o efeito da rapamicina na proliferação de culturas organotípicas de queratinócitos expressando esses genes. Também avaliamos o efeito dos genes E6 e E7 na atividade de mTOR após o tratamento com essa droga. Para geração de culturas organotípicas de queratinócitos infectamos essas células com vetores retrovirais recombinantes contendo os genes E6 e E7 de HPV-16 em conjunto ou separadamente. Nós também avaliamos o papel da degradação de p53 e pRb na resposta à rapamicina através da utilização de mutantes de E6 e E7 incapazes de induzir a degradação dessas proteínas celulares. Após a infecção dos queratinócitos, os mesmos foram semeados em uma matriz de colágeno. Após 6 dias as culturas foram tratadas com 100ng/ml de rapamicina e permaneceram 60h em contato com a droga. Para análise por imunohistoquímica os tecidos foram fixados em formalina tamponada e emblocados em parafina. A reação de imunohistoquímica foi realizada utilizando os anticorpos contra BrdU, p-4EBP1 (ser 65), p-eIF4G1 (ser 1188) e pAKT (ser 473). Os resultados obtidos ilustram que a rapamicina apresenta efeito antiproliferativo em culturas de queratinócitos contendo o vetor vazio. Por outro lado, culturas contendo o gene E7 são resistentes ao efeito antiproliferativo dessa droga. Essa resistência parece estar relacionada à capacidade de E7 induzir a degradação da proteína pRb, uma vez que em queratinócitos expressando o mutante de E7, incapaz de induzir a degradação dessa proteína, não foi observada resistência. Além disso, a fosforilação de eIF4G e 4EBP1 indica que a expressão de E7 impede que a rapamicina seja capaz de inibir a atividade de mTOR. Esses resultados mostram, pela primeira vez, que o efeito antiproliferativo da rapamicina pode ser superado pela expressão de uma proteína viral, no caso a proteína E7 de HPV-16. / High-risk HPV infection has a major etiologic role in development and progression of cervical cancer, one of the most frequent forms of cancer among women worldwide. HPV-16 E6 and E7 oncoproteins are able to induce degradation of p53 and pRb tumor suppressor proteins respectively. Moreover, the expression of these oncoproteins is related to alterations in the PI3K/AKT/mTOR pathway. The cellular kinase mammalian target of Rapamycin (mTOR) is an important regulator of the cellular protein synthesis machinery and has emerged as a principal mediator of cell growth and proliferation. mTOR activation has been shown to stimulates eIF4G1 and 4EBP1 phosphorylation, thus increasing the rate of protein synthesis. Rapamycin is a specific inhibitor of mTOR signaling pathway and its analogues have demonstrated impressive activity against a broad range of human cancer derived cell lines in culture and in human tumor xenograft models. Since E6 and E7 target several proteins controlling the mTOR pathway we aimed to investigate the effect of Rapamycin in the proliferation of organotypic raft cultures expressing these genes. We also evaluated the effect of E6 and E7 genes in mTOR activity after rapamycin treatment. To generate organotypic culture of keratinocytes we infect these cells with recombinant retroviruses containing HPV-16 E6 and E7 together or separately. We also analyzed the role of p53 and pRb degradation in rapamycin responsiveness by using E6 and E7 mutants lacking the hability to inactivate these cellular proteins. After infection, keratinocytes were seeded on to a collagen matrix. After 6 days, these cultures were treated with 100ng/ml of Rapamycin for 60 hours. BrdU was added in the last 12 hours to evaluate proliferation. For immunohistochemistry analysis tissues were fixed in buffered formalin and embedded in paraffin. Immunohistochemistry reactions against BrdU, p-4EBP1 (ser 65), p-eIF4G1 (ser 1188) and p-AKT (ser 473) were performed The results show that proliferation of organotypic cultures of keratinocytes transduced with empty vector is inhibited by Rapamycin. On the other hand, cultures generated with keratinocytes transduced with E7 gene were completely resistance to the antiproliferative effect of Rapamycin. Moreover, we found that this antiproliferative effect was dependent of Rb degradation since the cells transduced with E7 mutant unable do induce Rb degradation were sensitive. In addition, eIF4G and 4EBP1 phosphorylation indicates that E7 expression impairs mTOR inhibition by rapamycin. AKT phosphorilation indicates that rapamycin resistance could be dependent of Rb inactivation induced by E7 expression. These results show for the first time that the Rapamycin antiproliferative effect is bypassed by the expression of a viral oncogene, in this case the HPV-16 E7. Moreover, E7 expression impairs rapamycin to inactivate mTOR.

Cultura organotípica

HPV

mTOR

Oncogenes

Rapamicina

Tradução de proteínas

HPV

mTOR

Oncogenes

Organotypic cultures

Rapamycin

Translation of protein

The cue induced axonal nascent proteome and its translational control mechanisms in neural wiring

Cagnetta, Roberta

January 2018

Axonal protein synthesis is rapidly regulated by extrinsic cues during neural wiring but the full landscape of proteomic changes and their translational control mechanisms remain unknown. The ability to investigate the nascent proteome on subcellular compartments has been hampered by the low sensitivity of existing methodology on quantity-limited samples combined with the difficulty of obtaining sufficient amounts of pure material. By combining pulsed Stable Isotope Labelling by Amino acids in Cell culture (pSILAC) with Single-Pot Solid-Phase-enhanced Sample Preparation (SP3), I have established an approach to characterize the nascent proteome from quantity-limited somaless retinal axons (~2μg) on an unparalleled rapid time-scale (5 min). The results show that a surprisingly large number of proteins (>350) is translated constitutively in axons, many of which are linked to neurological disease. Axons stimulated by different cues (Netrin-1, BDNF, Sema3A) each show a signature set of up/down newly synthesised protein (NSP) changes (>100) within 5 min. Remarkably, conversion of Netrin-1-induced responses from repulsion to attraction triggers opposite translational regulation for 73% of a common subset corresponding to >100 NSPs. Further, I show that pharmacological increase in cAMP, known to induce chemoattractive response, also leads to rapid and wide-scale remodelling of the nascent axonal proteome (~100 NSP changes). I find that the cAMP-elicited NSP changes underlie the attractive turning but are distinct from those induced by the physiological chemoattractant Netrin-1, suggesting that the same type of chemotropic response can be mediated by different protein synthesis-dependent mechanisms. Finally, I show that Sema3A, but not Slit1, triggers a physiological and non-canonical PERK-eIF2α-eIF2B signalling pathway required in neural wiring to elicit the rapid (< 15 min) local translation control of a specific subset of NSPs. Collectively my findings lead to the general conclusion that guidance molecules rapidly induce cue-specific remodelling of the nascent axonal proteome via distinct regulatory mechanisms.

Nuclear translation

Baboo, Sabyasachi

January 2012

In bacteria, protein synthesis can occur tightly coupled to transcription. In eukaryotes, it is believed that translation occurs solely in the cytoplasm; I test whether some occurs in nuclei and find: (1) L-azidohomoalanine (Aha) – a methionine analogue (detected by microscopy after attaching a fluorescent tag using ‘click’ chemistry) – is incorporated within 5 s into nuclei in a process sensitive to the translation inhibitor, anisomycin. (2) Puromycin – another inhibitor that end-labels nascent peptides (detected by immuno-fluorescence) – is similarly incorporated in a manner sensitive to a transcriptional inhibitor. (3) CD2 – a non-nuclear protein – is found in nuclei close to the nascent RNA that encodes it (detected by combining indirect immuno-labelling with RNA fluorescence in situ hybridization using intronic probes); faulty (nascent) RNA is destroyed by a quality-control mechanism sensitive to translational inhibitors. I conclude that substantial translation occurs in the nucleus, with some being closely coupled to transcription and the associated proof-reading. Moreover, most peptides made in both the nucleus and cytoplasm are degraded soon after they are made with half-lives of about one minute. I also collaborated on two additional projects: the purification of mega-complexes (transcription ‘factories’) containing RNA polymerases I, II, or III (I used immuno-fluorescence to confirm that each contained the expected constituents), and the demonstration that some ‘factories’ specialize in transcribing genes responding to tumour necrosis factor α – a cytokine that signals through NFκB (I used RNA fluorescence in situ hybridization coupled with immuno-labelling to show active NFκB is found in factories transcribing responsive genes).

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