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Characterization of the IIIa protein of porcine adenovirus type 3Van Kessel, Jill Andrea 26 April 2006
The L1 region of the porcine adenovirus (PAdV)-3 genome encodes a protein of 622 amino acids named IIIa. Although it binds a neighboring group of nine (GON) hexons at the capsid level and cement the icosahedral shell that contains the viral DNA, little is known regarding its function with respect to viral life cycle. Moreover, the known location of IIIa protein in the capsid may help to express targeting ligands for altering the tropism of PAdV-3. The objective of this study was to characterize the IIIa protein of porcine adenovirus Type 3 (PAdV-3). <p> In order to characterize the IIIa protein, polyclonal antisera were raised in rabbits against different regions of IIIa. Anti-IIIa sera detected a specific protein of 70 kDa in PAdV-3 infected cells using Western blot assay. Immunofluorescence studies indicated that IIIa is predominantly localized in the nucleus of PAdV-3 infected cells. Analysis of PAdV-3 IIIa using antibodies specific for N- and C- terminal domains of the protein suggested that although the N-terminus and C-terminal domains of IIIa are immunogenic, they are not exposed on the surface of PAdV-3 virions. These results were further confirmed by our inability to isolate a chimeric PAdV-3 virion containing a heterologous protein fused to the N-terminus or C-terminus of IIIa. <p>Functional analysis suggested that IIIa may transactivate the major late promoter and down regulate the early region (E) 1A promoter. In order to locate the domains of IIIa responsible for different functions, in-frame deleted/truncated forms of IIIa were constructed. Analysis of the deleted/truncated forms of IIIa suggested that a) the sequences located between amino acids 273-410 and between amino acids 410-622b) affect the nuclear localization and transactivation function respectively.<p>Since protein- protein interactions are important for the biological functions of the protein, we determined the interaction of PAdV-3 IIIa with other viral proteins. IIIa was found to interact with DNA binding protein (DBP), E3 13.7 kDa protein, hexon, fiber, and pIX. These results suggest that PAdV3 IIIa may do more in the viral life cycle than merely act as cement between the hexons to maintain capsid stability and may actually be involved in regulating early to late gene transcription at appropriate stages during viral infection.
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Characterization of the IIIa protein of porcine adenovirus type 3Van Kessel, Jill Andrea 26 April 2006 (has links)
The L1 region of the porcine adenovirus (PAdV)-3 genome encodes a protein of 622 amino acids named IIIa. Although it binds a neighboring group of nine (GON) hexons at the capsid level and cement the icosahedral shell that contains the viral DNA, little is known regarding its function with respect to viral life cycle. Moreover, the known location of IIIa protein in the capsid may help to express targeting ligands for altering the tropism of PAdV-3. The objective of this study was to characterize the IIIa protein of porcine adenovirus Type 3 (PAdV-3). <p> In order to characterize the IIIa protein, polyclonal antisera were raised in rabbits against different regions of IIIa. Anti-IIIa sera detected a specific protein of 70 kDa in PAdV-3 infected cells using Western blot assay. Immunofluorescence studies indicated that IIIa is predominantly localized in the nucleus of PAdV-3 infected cells. Analysis of PAdV-3 IIIa using antibodies specific for N- and C- terminal domains of the protein suggested that although the N-terminus and C-terminal domains of IIIa are immunogenic, they are not exposed on the surface of PAdV-3 virions. These results were further confirmed by our inability to isolate a chimeric PAdV-3 virion containing a heterologous protein fused to the N-terminus or C-terminus of IIIa. <p>Functional analysis suggested that IIIa may transactivate the major late promoter and down regulate the early region (E) 1A promoter. In order to locate the domains of IIIa responsible for different functions, in-frame deleted/truncated forms of IIIa were constructed. Analysis of the deleted/truncated forms of IIIa suggested that a) the sequences located between amino acids 273-410 and between amino acids 410-622b) affect the nuclear localization and transactivation function respectively.<p>Since protein- protein interactions are important for the biological functions of the protein, we determined the interaction of PAdV-3 IIIa with other viral proteins. IIIa was found to interact with DNA binding protein (DBP), E3 13.7 kDa protein, hexon, fiber, and pIX. These results suggest that PAdV3 IIIa may do more in the viral life cycle than merely act as cement between the hexons to maintain capsid stability and may actually be involved in regulating early to late gene transcription at appropriate stages during viral infection.
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Geração e análise da imunogenicidade de proteínas recombinantes baseadas nas diferentes formas do antígeno circumsporozoíta de Plasmodium vivax visando o desenvolvimento de uma vacina universal contra malária. / Generation and analysis of the immunogenicity of recombinant proteins based on different forms of the circumsporozoite antigen of Plasmodium vivax for the development of a universal vaccine against malaria.Teixeira, Lais Helena 26 March 2014 (has links)
O P. vivax é a segunda espécie mais prevalente causadora de malária no mundo. Medidas de controle ineficientes exigem o desenvolvimento de novas estratégias de prevenção, como vacinas, novas drogas e novos inseticidas. O objetivo geral do trabalho foi gerar uma formulação vacinal universal com proteínas e adenovírus recombinantes capazes de induzir anticorpos contra as diferentes formas alélicas da proteína circumsporozoíta (CSP) do P. vivax. As proteínas foram produzidas em E. coli e purificadas por cromatografia de afinidade e troca iônica. A obtenção destas proteínas nos permitiu testar qual seria a melhor formulação vacinal para a indução de anticorpos contra as três formas alélicas da proteína CSP de P. vivax (PvCSP). Anticorpos específicos reconheceram esporozoítas do P. vivax por imunofluorescência. Por fim testamos o uso de dois adenovírus recombinantes, um símio e um humano, deficientes em replicação, expressando as três regiões imunodominantes da proteína PvCSP em fusão. Estes foram capazes de induzir resposta imune específica contra as proteínas PvCSP sendo testados em esquema de prime-boost heterólogo, onde camundongos foram primados com os adenovírus e nas doses-reforço receberam a mistura com as três proteínas recombinantes. / The Plasmodium vivax is the second most prevalent species of malaria in the world. Inefficient measures of control used today demand the development of new strategies for prevention, as vaccines, new drugs and new insecticides. The central objective of this thesis was to generate a universal vaccine formulation with proteins and recombinant adenoviral vectors representing the different allelic forms of the circumsporozoite protein (CSP) of the P. vivax. The recombinant proteins were expressed in E. coli and purified. These proteins allowed us to test which would be the best vaccine formulation for the induction of antibodies against the three allelic forms of CSP. The specific antibodies also recognized P. vivax sporozoites by immunofluorescence. Finally we test the use of two recombinant adenoviral vectors, a simian and a human, both replication deficient, expressing a protein containing the repeat regions of the CSP in fusion. These adenoviral vectors induced specific immune response against CSP and were successfully used in an immunization regimen of heterologous prime and boost where in the first dose the mice received recombinant adenoviral vector and in the subsequent doses, the mixture with three recombinant proteins.
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Geração e análise da imunogenicidade de proteínas recombinantes baseadas nas diferentes formas do antígeno circumsporozoíta de Plasmodium vivax visando o desenvolvimento de uma vacina universal contra malária. / Generation and analysis of the immunogenicity of recombinant proteins based on different forms of the circumsporozoite antigen of Plasmodium vivax for the development of a universal vaccine against malaria.Lais Helena Teixeira 26 March 2014 (has links)
O P. vivax é a segunda espécie mais prevalente causadora de malária no mundo. Medidas de controle ineficientes exigem o desenvolvimento de novas estratégias de prevenção, como vacinas, novas drogas e novos inseticidas. O objetivo geral do trabalho foi gerar uma formulação vacinal universal com proteínas e adenovírus recombinantes capazes de induzir anticorpos contra as diferentes formas alélicas da proteína circumsporozoíta (CSP) do P. vivax. As proteínas foram produzidas em E. coli e purificadas por cromatografia de afinidade e troca iônica. A obtenção destas proteínas nos permitiu testar qual seria a melhor formulação vacinal para a indução de anticorpos contra as três formas alélicas da proteína CSP de P. vivax (PvCSP). Anticorpos específicos reconheceram esporozoítas do P. vivax por imunofluorescência. Por fim testamos o uso de dois adenovírus recombinantes, um símio e um humano, deficientes em replicação, expressando as três regiões imunodominantes da proteína PvCSP em fusão. Estes foram capazes de induzir resposta imune específica contra as proteínas PvCSP sendo testados em esquema de prime-boost heterólogo, onde camundongos foram primados com os adenovírus e nas doses-reforço receberam a mistura com as três proteínas recombinantes. / The Plasmodium vivax is the second most prevalent species of malaria in the world. Inefficient measures of control used today demand the development of new strategies for prevention, as vaccines, new drugs and new insecticides. The central objective of this thesis was to generate a universal vaccine formulation with proteins and recombinant adenoviral vectors representing the different allelic forms of the circumsporozoite protein (CSP) of the P. vivax. The recombinant proteins were expressed in E. coli and purified. These proteins allowed us to test which would be the best vaccine formulation for the induction of antibodies against the three allelic forms of CSP. The specific antibodies also recognized P. vivax sporozoites by immunofluorescence. Finally we test the use of two recombinant adenoviral vectors, a simian and a human, both replication deficient, expressing a protein containing the repeat regions of the CSP in fusion. These adenoviral vectors induced specific immune response against CSP and were successfully used in an immunization regimen of heterologous prime and boost where in the first dose the mice received recombinant adenoviral vector and in the subsequent doses, the mixture with three recombinant proteins.
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Recombinant Adenovirus Vaccines, A Comprehensive Investigation of T Cell Immunity / T Cell Biology of Recombinant Adenovirus VaccinesMillar, James 07 1900 (has links)
<p> Vaccination is arguably the most effective tool at our disposal to prevent the morbidity and mortality associated with infectious disease. However, there are currently several infectious diseases, notably HIV, malaria and tuberculosis, for which we do not posses effective vaccines. Further complicating matters, traditional methods to construct vaccines for these diseases have been unsuccessful. Advances in our understanding of adaptive immunity have demonstrated that vaccines for these diseases likely rely upon potent T cell immunity to be effective. Recombinant adenovirus (rAd) vectors have shown great promise as vaccination platforms since they are easily constructed, stable, well-tolerated and elicit robust T cell responses. The robust activity of rAd vectors based on the human serotype 5 virus (rHuAd5) in murine and simian models merits futher investigation as a prototypic T cell vaccine. To this end, we have undertaken a comprehensive evaluation of T cell immunity following rAd vaccination. Our previous observations determined that the CD8+ T cell response produced by rHuAd5 vaccines displayed a prolonged effector phase that was associated with long-lived antigen presentation. We have further investigated the mechanisms underlying the maintenance of this memory population. Our results have revealed that the memory phenotype is not due to continual recruitment of naive CD8+ T cells. Rather, the sustained effector phenotype appears to depend upon prolonged expression of the antigen-encoding transgene from the rHuAd5 vector. Interestingly, transgene expression was only required for 60 days after which point the memory population stabilized. Further investigation of the relationship between antigen structure and the CD8+ T cell response revealed that antigens which traffic through the ER produce a CD8+ T cell response that expands more rapidly and displays a more pronounced contraction phase than antigens which are produced within the cytosol. While the exact mechanism underlying this phenomenon is not known, we suspect that pathways related to ER stress may be involved. Despite the more dramatic contraction phase associated with antigens that traffic through the ER, the memory phenotype was unchanged. Interestingly, the CD4+ T cell response was not influenced by antigen structure and displays a sharp contraction phase regardless of whether the antigen traffics through the ER or is produced in the cytosol. We further investigated the relationship between CD4+ T cell help and CD8+ T cell immunity produced by rHuAd5. Based on the partially-exhausted phenotype of the CD8+ T cells produced by rHuAd5 (diminished TNF-a production and little IL-2 production), we suspected that inadequate CD4+ T cell help may have been responsible. However, removal of CD4+ T cells did not further impair the CD8+ T cell response produced by rHuAd5. Rather, a lack of CD4+ T cell help only impacted the magnitude of the primary CD8+ T cell response generated by rHuAd5; the functionality of the CD8+ T cell population, including the ability to proliferate following secondary stimulation, were not affected by the absence of CD4+ T cells. Thus, although CD8+ T cell expansion following immunization with rHuAd5 is dependent upon the availability of CD4+ T cell help, the memory functions of the CD8+ T cell population appears to be independent of CD4+ T cell help. Finally, we compared the magnitude of the CD8+ T cell response produced by rHuAd5 and recombinant vaccinia virus. Our results demonstrated that the functionality of the early T cell response produced by both vectors were identical. However, the primary transgene-specific CD8+ T cell responses produced by rHuAd5 were significantly larger than rVV because the vector specific responses were negligible in the case of rAd but very strong following rVV inoculation. This research has contributed to our understanding of T cell immunity following rAd immunization and will assist in the construction and implementation of future vaccines. </p> / Thesis / Doctor of Philosophy (PhD)
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Étude de l'autoimmunité contre le foie induite par mimétisme moléculairePiché, Chantal January 2008 (has links)
Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.
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Étude de l'autoimmunité contre le foie induite par mimétisme moléculairePiché, Chantal January 2008 (has links)
Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal
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Targeting the Highly Conserved Sequences in Influenza A VirusHashem, Anwar 23 April 2013 (has links)
All challenges associated with influenza A viruses including antigenic variation in hemagglutinin (HA) and neuraminidase (NA), the evolving drug resistance and the drawbacks of current vaccines hinder our ability to control this constant threat. Furthermore, gene reassortment as well as the direct transmission of highly pathogenic avian viruses to humans can result in an occasional emergence of novel influenza strains with devastating pandemic potential. Therefore, it is crucial to investigate alternative approaches to better control these viruses and to develop new prophylactic and treatment options.
Targeting highly conserved epitopes or antigens among the different subtypes of influenza A virus could offer protection against broad range of influenza viruses, including emerging strains. In my research, I have investigated the potential of broadly neutralizing antibodies against HA and conducted mechanistic study of a prototype vaccine based on the highly conserved nucleoprotein (NP).
We recently found that the 14 amino acids of the amino-terminus of the fusion peptide of influenza HA2 subunit is the only universally conserved sequence in all HA subtypes of influenza A and the two lineages of influenza B viruses. Here, I show that universal antibodies targeting this linear sequence in the viral HA (Uni-1 antibodies) can cross-neutralize multiple subtypes of influenza A virus by inhibiting the pH-dependant fusion of viral and cellular membranes.
It is noted that the influenza NP is a highly conserved antigen and has the potential to induce heterosubtypic immunity against divergent subtypes of influenza A virus. However, NP-based vaccination only affords weak protective immunity compared to HA. This is mostly due to the non-sterilizing immunity induced by NP. Using CD40 ligand (CD40L), a key regulator of the immune system, as both a targeting ligand and a molecular adjuvant, I show that single immunization with recombinant adenovirus carrying a fused gene encoding the secreted NP-CD40L fusion protein provided robust and long-lasting protection against influenza in normal mice. It enhanced both B-cell and T-cell responses and augmented the role of both NP-specific antibodies and CTLs in protection. Importantly, it afforded effective protection in CD40L and CD4 deficient mice, confirming that the induced protection is CD40L-mediated and CD4+ T cell-independent.
The rapid evolution of the influenza A viruses necessitates the development of new alternatives to contain this medically important pathogen. The results of these studies could significantly contribute to future vaccine development and avert the necessity of yearly vaccine updates.
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Targeting the Highly Conserved Sequences in Influenza A VirusHashem, Anwar January 2013 (has links)
All challenges associated with influenza A viruses including antigenic variation in hemagglutinin (HA) and neuraminidase (NA), the evolving drug resistance and the drawbacks of current vaccines hinder our ability to control this constant threat. Furthermore, gene reassortment as well as the direct transmission of highly pathogenic avian viruses to humans can result in an occasional emergence of novel influenza strains with devastating pandemic potential. Therefore, it is crucial to investigate alternative approaches to better control these viruses and to develop new prophylactic and treatment options.
Targeting highly conserved epitopes or antigens among the different subtypes of influenza A virus could offer protection against broad range of influenza viruses, including emerging strains. In my research, I have investigated the potential of broadly neutralizing antibodies against HA and conducted mechanistic study of a prototype vaccine based on the highly conserved nucleoprotein (NP).
We recently found that the 14 amino acids of the amino-terminus of the fusion peptide of influenza HA2 subunit is the only universally conserved sequence in all HA subtypes of influenza A and the two lineages of influenza B viruses. Here, I show that universal antibodies targeting this linear sequence in the viral HA (Uni-1 antibodies) can cross-neutralize multiple subtypes of influenza A virus by inhibiting the pH-dependant fusion of viral and cellular membranes.
It is noted that the influenza NP is a highly conserved antigen and has the potential to induce heterosubtypic immunity against divergent subtypes of influenza A virus. However, NP-based vaccination only affords weak protective immunity compared to HA. This is mostly due to the non-sterilizing immunity induced by NP. Using CD40 ligand (CD40L), a key regulator of the immune system, as both a targeting ligand and a molecular adjuvant, I show that single immunization with recombinant adenovirus carrying a fused gene encoding the secreted NP-CD40L fusion protein provided robust and long-lasting protection against influenza in normal mice. It enhanced both B-cell and T-cell responses and augmented the role of both NP-specific antibodies and CTLs in protection. Importantly, it afforded effective protection in CD40L and CD4 deficient mice, confirming that the induced protection is CD40L-mediated and CD4+ T cell-independent.
The rapid evolution of the influenza A viruses necessitates the development of new alternatives to contain this medically important pathogen. The results of these studies could significantly contribute to future vaccine development and avert the necessity of yearly vaccine updates.
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Notch1-Induced Survival Signaling And Its Implications In Cancer TherapeuticsMungamuri, Sathish Kumar 12 1900 (has links)
Notch receptors and ligands are type I transmembrane proteins that regulate
development and differentiation during cell-cell contact. There are four Notch receptor
homologues and five notch ligands, identified in humans till date. Upon ligand activation, Notch1 intracellular domain (NIC-1) is released into the cytoplasm, which binds to several proteins as well as translocates into the nucleus to effect the Notch signaling. In the absence of the activated Notch signaling, the Notch target genes are kept repressed by the transcriptional repressor C protein binding factor 1 (CBF1) also known as RBPjk or CSL for CBF1/Su(H)/Lag1. RBPjk binds to the sequence “CGTGGGAA” and acts as a
constitutive repressor. Upon ligand dependent activation, NIC-1 enters into the nucler and converts RBPjk from transcriptional repressor to an activator. Notch binding to CSL replaces the SMRT corepressor complex with a coactivator complex including SKIP, Mastermind like 1 (MAML1) (Mastermind in Drosophila), and histone acetyl transferases PCAF, GCN5 and p300 activating the transcription of target genes. Mastermind-like (MAML), a family of transcriptional activator proteins comprising of 3 members 1 to 3, has been shown to be required for Notch signaling. MAML forms a ternary complex with RBPjk-NIC by directly interacting with NIC. In turn, MAML recruits the histone acetyl transferase p300/CBP, which acetylates the histones, thereby altering the structure of chromatin amenable for transcription. Activation of Notch pathway induces oncogenesis, which can be divided into two categories including 1) Inhibition of Apoptosis and 2) Induction of proliferation. In T cells, activation of Notch1 protects cells from T cell receptor, dexamethasone and etoposide-mediated apoptosis, Fas receptor-mediated signaling by up regulating IAP (Inhibitor of Apoptosis) and Bcl-2 families, as well as FLIP (FLICE-like inhibitor protein). Notch signaling also promotes the survival of T cells through maintenance of cell size as well as through the promotion of glucose uptake and metabolism. Notch-1 has been shown to protect against anoikis (apoptosis induced by matrix withdrawal) or p53-mediated apoptosis in immortalized epithelial cells, T cell receptor-induced apoptosis in mature cells and dexamethasone-mediated apoptosis in thymocytes.
This study was carried out to functionally characterize NIC-1 (human Notch1-intracellular domain) as an inhibitor of apoptosis and to evaluate the therapeutic potential of reversal of this apoptosis inhibition. The main objectives of this study are
1. Construction of recombinant adenovirus expressing human Notch1-intracellular domain (Ad-NIC-1) and characterization of NIC-1 as an inhibitor of chemotherapy and p53-induced cytotoxicity and apoptosis.
2. Role of PI3 kinase -Akt/PKB -mTOR pathway in NIC-1-mediated inhibition of p53-induced apoptosis.
3. Essential role of association between mTOR and NIC-1 and the dependent NIC-1 phosphorylation in Notch1-mediated transcription and survival signaling.
4. Identification of NIC-1 as an inhibitor of E1A-induced apoptosis and the role of mTOR in NIC-1-mediated inhibition of E1A-induced apoptosis.
Activated Notch1 was first linked to tumorigenesis through identification of a
recurrent t(7;9)(q34;q34.3) chromosomal translocation involving the human Notch1 gene that is found in a subset of human pre-T-cell acute lymphoblastic leukemia’s (T-ALL). Deregulated Notch signaling is oncogenic, inhibits apoptosis and promotes survival. In order to understand survival signaling induced by Notch1 and its possible role in chemoresistance, we have generated a replication deficient recombinant adenovirus
expressing human Notch1-intracellular domain (Ad-NIC-1) and shown that it produces
functional NIC-1 protein. Using this overexpression system, we characterized that activated Notch1-inhibits chemotherapy and in particular p53 induced apoptosis. Notch1-mediated inhibition of p53-induced apoptosis does not include coactivator squelching. p53 was inefficient in binding to its DNA in NIC-1 overexpressing cells. The levels of
phosphorylation at Ser15, Ser20, and Ser392 of p53 expressed from Ad-p53 significantly
reduced in NIC-1 preinfected cells. These results suggest that NIC-1-mediated inhibition of p53-mediated apoptosis involves reduced DNA binding, reduced nuclear localization and reduced post translational modifications and thus reduced transactivation of its target genes.
Notch1-mediated inhibition of p53 was found to occur mainly through mammalian target of rapamycin (mTOR) using PI3 kinase-Akt/PKB pathway, as the mTOR inhibitor; rapamycin treatment was able to reverse Notch-1 mediated inhibition of p53 and
chemoresistance. Consistent with this, rapamycin failed to reverse NIC-1 induced
chemoresistance in cells expressing rapamycin resistant mTOR. Our results also suggest that the N-terminal HEAT repeat and the kinase function of mTOR are essential for Notch mediated inhibition of p53. Further, ectopic expression of eIF4E, a translational regulator that acts downstream of mTOR, inhibited p53-induced apoptosis and conferred protection against p53-mediated cytotoxicity to similar extent as that of NIC-1 overexpression, but was not reversed by rapamycin, which indicates that eIF4E is the major target of mTOR in Notch1-mediated survival signaling.
Notch1-intracellular domain (NIC-1), following proteolytic cleavage, binds to
RBPjk and regulates transcription. Active NIC-1 located in the nucleus is phosphorylated, which makes it more stable and bind better to RBPjk. NIC-1 was also shown to bind to Deltex1 in the cytoplasm. Next, we studied the requirement of components of Notch1 signaling pathway for this function. By using variety of approaches, we found that both RBPjk and Maml1 and hence transcription activation is required for NIC-1-mediated survival signaling and inhibition of p53 functions. Interestingly, while we found the other Notch1 effector, Deltex1 is also required for above functions, Notch1 failed to activate PI3 kinase -Akt/PKB -mTOR pathway in Deltex1, but not in RBPjk silenced cells. Our results suggest that Notch-Deltex1 pathway activates PI3 kinase. Previous studies show that NIC-1 interacts with Deltex1 and Grb2 interacts with PI3 kinase. Our data shows that Deltex1 interacts with SH3 domain of Grb2. Since Notch1-Deltex1 and PI3 kinase-Grb2 interactions are known, we conclude that Notch1 activation of PI3 kinase involves Deltex1 and Grb2.
We found activated mTOR was able to binds to NIC-1 and regulates its phosphorylation. Inhibition of mTOR either by PI3 kinase inhibitors or mTOR inhibitor treatment or silencing of Akt/PKB or mTOR reduced the phosphorylation of NIC-1 with the concomitant reduction in NIC-1-mediated transcription. Further, endogenous Notch1
receptor activated by the DSL ligand failed to activate transcription efficiently in rapamycin treated cells, implying a positive role for mTOR in mammalian Notch signaling. These studies reveal that Notch1 activates PI3 kinase -Akt/PKB -mTOR signaling through Deltex1 and subsequently activated mTOR modulates Notch1 signaling by direct binding and possibly thorough phosphorylation of the intracellular domain of Notch.
Adenoviral E1A, in the absence of cooperating oncogene, suppresses primary tumor growth and reverses the transformed phenotype of human tumor cells by inducing
apoptosis. E1A requires p53 for efficient induction of apoptosis and was shown to induce apoptosis by down regulating Akt and the activation of pro apoptotic factor p38 MAP kinase. Since our results suggest Notch1 inhibits chemotherapy and p53-induced apoptosis, we analyzed the ability of Notch1 to protect cells from E1A-induced apoptosis. Here we show that NIC-1 suppresses the ability of E1A to induce apoptosis. NIC-1 requires mTOR-dependent signal to inhibit E1A-mediated apoptosis, as the rapamycin, an mTOR inhibitor was able to completely reverse the ability of Notch1 to protect cells against E1A-induced apoptosis. The role of mTOR in NIC-1-mediated survival signaling was further confirmed by using the cells stably expressing rapamycin resistant mTOR. Rapamycin was able to reverse Notch1-mediated protection in cells expressing wild type mTOR but not in rapamycin resistant mTOR expressing cells. We also found that E1A was able to induce apoptosis in cells silenced for the pro apoptotic factor p38 and NIC-1 continued to inhibit E1A-induced apoptosis in these cells. These results confirm that Notch1 requires the activation of mTOR signaling but not p38 MAP kinase for inhibition of E1A-induced apoptosis. These results also suggest that the combination therapy utilizing E1A-mediated gene delivery in combination with inhibition of mTOR pathway may prove successful in treating Notch overexpressing cancers.
Chemotherapy remains a major treatment modality for human cancers. Chemoresistance is a clinical problem that severely limits treatment success. It can be divided into two forms: intrinsic and acquired. Intrinsic resistance is the essence of oncogenic transformation, resulting from activation of oncogenes and the loss of tumor suppressors, and manifests itself as alterations in cell cycle checkpoints and apoptotic pathways. It is now widely accepted that the apoptotic capacity of the cancer cell is crucial in determining the response to chemotherapeutic agents. Indeed, several gene products that regulate apoptosis, i.e., p53, Akt and PI3K are frequently altered in cancer cells. In this study, we identified that cells with aberrant Notch1 signaling are chemoresistant. Activated Notch1 overexpression makes cells resistant to chemotherapy in a wild type p53 dependent manner. Notch protected p53 wild type cells but not p53 mutated or p53 deleted cells against chemotherapy induced cytotoxicity. Further, inactivation of p53 by specific silencing abrogated the ability of NIC-1 to protect H460 cells against adriamycin induced cytotoxicity. Most importantly, NIC-1 mediated chemoresistance can be reversed by blocking PI3 kinase -Akt/PKB -mTOR pathway. Collectively, these results suggest that cancers with activated Notch1 signaling are chemoresistant and provide basis for the reversal of chemoresistance.
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