Growth factor activation of ErbB2/ErbB3 signaling pathways regulate the activity of Estrogen Receptors (ER)

Sanchez, Melanie

04 1900

La signalisation par l’estrogène a longtemps été considérée comme jouant un rôle critique dans le développement et la progression des cancers hormono-dépendants tel que le cancer du sein. Deux tiers des cancers du sein expriment le récepteur des estrogènes (ER) qui constitue un élément indiscutable dans cette pathologie. L’acquisition d’une résistance endocrinienne est cependant un obstacle majeur au traitement de cette forme de cancer. L’émergence de cancers hormono-indépendants peut est produite par l’activation de ER en absence d’estrogène, l’hypersensibilité du récepteur aux faibles concentrations plasmique d’estrogène ainsi que l’activation de ER par des modulateurs sélectifs. L’activité du ER est fortement influencée par l’environnement cellulaire tel que l’activation de voie de signalisation des facteurs de croissances, la disponibilité de protéines co-régulatrices et des séquences promotrices ciblées. Présentement, les études ont principalement considérées le rôle de ERα, cependant avec la découverte de ERβ, notre compréhension de la diversité des mécanismes potentiels impliquant des réponses ER-dépendantes s’est améliorée. L’activation des voies des kinases par les facteurs de croissance entraîne le développement d’un phénotype tumoral résistant aux traitements actuels. Nos connaissances des voies impliquées dans l’activation de ER sont restreintes. ERα est considéré comme le sous-type dominant et corrèle avec la plupart des facteurs de pronostic dans le cancer du sein. Le rôle de ERβ reste imprécis. Les résultats présentés dans cette thèse ont pour objectif de mieux comprendre l’implication de ERβ dans la prolifération cellulaire par l’étude du comportement de ERβ et ERα suite à l’activation des voies de signalisation par les facteurs de croissance. Nous démontrons que l’activation des récepteurs de surfaces de la famille ErbB, spécifiquement ErbB2/ErbB3, inhibe l’activité transcriptionnelle de ERβ, malgré la présence du coactivateur CBP, tout en activant ERα. De plus, l’inhibition de ERβ est attribuée à un résidu sérine (Ser-255) situé dans la région charnière, absente dans ERα. Des études supplémentaires de ErbB2/ErbB3 ont révélé qu’ils activent la voie PI3K/Akt ciblant à son tour la Ser-255. En effet, cette phosphorylation de ERβ par PI3K/Akt induit une augmentation de l’ubiquitination du récepteur qui promeut sa dégradation par le système ubiquitine-protéasome. Cette dégradation est spécifique pour ERβ. De façon intéressante, la dégradation par le protéasome requiert la présence du coactivateur CBP normalement requis pour l’activité transcriptionnelle des récepteurs nucléaires. Malgré le fait que l’activation de la voie PI3K/Akt corrèle avec une diminution de l’expression des gènes sous le contrôle de ERβ, on observe une augmentation de la prolifération des cellules cancéreuses. L’inhibition de la dégradation de ERβ réduit cette prolifération excessive causée par le traitement avec Hrgβ1, un ligand de ErbB3. Un nombre croissant d’évidences indique que les voies de signalisations des facteurs de croissance peuvent sélectivement réguler l’activité transcriptionnelle de sous-types de ER. De plus, le ratio ERα/ERβ dans les cancers du sein devient un outil de diagnostique populaire afin de déterminer la sévérité d’une tumeur. En conclusion, la caractérisation moléculaire du couplage entre la signalisation des facteurs de croissance et la fonction des ERs permettra le développement de nouveaux traitements afin de limiter l’apparition de cellules tumorales résistantes aux thérapies endocriniennes actuelles. / It has long been appreciated that estrogenic signaling plays a critical role in the development of hormone-dependent cancers such as breast cancer. Two-thirds of breast cancers express estrogen receptor (ER) which has been demonstrated to play an irrefutable role in tumour development and progression. However the acquisition of endocrine resistance has become a major obstacle in the treatment of hormone-dependent cancers that have acquired a hormone-independent state. Hormone-independent cancers emerge from an array of pathways involving ER activation in the absence of estrogen, hypersensitivity of ER to low serum levels of estrogen and activation by estrogen antagonists. The activity of ER is critically influenced by the cellular environment such as growth factor signaling pathways, availability of coregulatory proteins and the promoter sequence of target genes. The mechanisms studied have mostly considered the role of ERα, however with the discovery of the second subtype, ERβ, the understanding on the diversity of potential mechanisms involving ER-dependent responses have improved. Hormonal-independent activation of ER can occur in estrogen-dependent breast tumours, with concomitant rise in kinase signaling pathways, resulting in the acquisition of a therapeutic resistant phenotype in treated women. Our knowledge is relatively limited on which pathways trigger ER signaling and how these phosphorylation-coupled events affect ER activity. ERα is considered the dominant subtype and correlates with most of the prognostic factors in breast cancers. Conversely the role of ERβ remains unclear. The results presented in this thesis were carried out with the objective of gaining a better understanding of ERβ’s role in cellular proliferation by examining the behavior of ERβ and ERα during the activation of growth factor signaling pathways by cell-surface receptor-tyrosine kinases. We demonstrate here that the activation of cell surface receptors of the ErbB family, specifically ErbB2/ErbB3, inhibits the transcriptional activity of ERβ despite the presence of the coactivator CBP, yet activated ERα. Furthermore the inhibition of ERβ was attributed to a specific serine residue located within the hinge region, not present in ERα. Additional studies of ErbB2/ErbB3-initiated signaling revealed that it triggered the activation of the PI3K/Akt pathway which targeted the serine residue within the hinge region of ERβ. In fact, phosphorylation of ERβ by the PI3K/Akt pathway led to an increase in receptor ubiquitination which promoted its degradation by the ubiquitin-proteasome system which was subtype specific. Interestingly, proteasomal degradation required the presence of the coactivator CBP, which is normally involved in assisting nuclear receptor transcriptional activity. Although the activation of the PI3K/Akt pathway correlated with a decrease in the expression of ERβ target genes it led to an increase in the proliferation of breast cancer cells. Inhibiting the degradation of ERβ reduced the enhanced proliferation of breast cancer cells brought about by the treatment of ErbB3’s ligand, Hrgβ1. Increasing evidence indicates that growth factor signaling pathways can selectively regulate the transcriptional activity of ER subtypes, and the ratio of ERα/ERβ expression in breast tumours is becoming a popular prognostic factor to evaluate the severity of the tumour. Therefore the molecular characterization of the coupling between growth factor signaling and ER function should provide improved therapeutical approaches to overcome or delay the onset of resistance to endocrine therapy in hormone-dependent cancers.

Cancer hormone-dépendant

Récepteurs aux Estrogènes, ER

Facteurs de croissances

Récepteur de tyrosine kinase, RTK

ErbB

CBP/p300

Phosphorylation

Ubiquitination

Mdm2

PI3K/Akt

Hormone-dependent cancer

Estrogen Receptor, ER

Growth factors

receptor tyrosine kinase, RTK

ErbB

CBP/p300

phosphorylation

Ubiquitination

Mdm2

PI3K/Akt

Modificadores de penetrância de mutações germinativas no gene TP53 em famílias brasileiras com diagnóstico clínico da síndrome de Li-Fraumeni e Li-Fraumeni like: impacto dos polimorfismos intragênicos do TP53 e de genes / Genetic modifiers of germline TP53 mutation in Brazilian families with Li-Fraumeni and Li-Fraumeni Like syndromes: impact of TP53 intragenic polymorphisms and p53 regulatory genes

Achatz, Maria Isabel Alves de Souza Waddington

08 December 2008

A síndrome de Li-Fraumeni (LFS) e sua variante like (LFL) são associadas a mutações germinativas no gene TP53 e predispõe ao alto risco para múltiplos tumores em idade jovem. Analisamos 91 famílias LFS/LFL do sul/sudeste do Brasil para mutações germinativas e haplótipos de TP53 (PIN2, PIN3 e PEX4) e MDM2 (309T-G). A mutação R337H ocorreu em 44,4% das famílias avaliadas. Em 750 controles da região a freqüência populacional da mutação foi 0,3%. A genotipagem de oito indivíduos não relacionados R337H-positivos para 29 TAG SNPs intragênicos demonstrou o mesmo haplótipo raro estabelecendo efeito fundador para R337H. O alelo duplicado no PIN3 apresenta impacto modificador e retardo de 17,1 anos na ocorrência de tumores em famílias com mutação no TP53, enquanto o SNP309 MDM2 modula a idade dos sarcomas de partes moles. / Li-Fraumeni syndrome (LFS) and its variant like (LFL) are associated with germline mutations in the TP53 gene and predispose to a variety of cancers at an earlier age. We analyzed 91 LFS/LFL families from southern Brazil for germline mutations in TP53 and polymorphisms in TP53 (PIN2, PIN3, PEX4) and MDM2 (309T-G). The germline TP53 mutation R337H was found in 44.4% of all families included. In 750 controls from the same region, mutation prevalence was 0.3%. Genotyping of eight unrelated R337H-positive individuals for 29 intragenic TAG SNPs showed that they all shared the same rare haplotype confirming the founder effect for the mutation. Duplication of PIN3 had a modifier effect on the age of tumor onset (delay of 17.1 years) in TP53 mutation carriers whereas MDM2 SNP309 modulated age of onset for soft-tissue sarcomas.

Adrenocortical carcinoma

Carcinoma adrenocortical

Deleção de genes

Gene deletion

Genetic polymorphism

Genetic predisposition to disease

Germline mutation

Li-Fraumeni syndrome

Mutação em linhagem germinativa

Polimorfismo genético

Predisposição genética para doença

Proteína supressora de tumor p53

Proteínas proto-oncogênicas c-mdm2

Proto-oncogene proteins c-mdm2

Síndrome de Li-Fraumeni

Tumor suppressor protein p53

Growth factor activation of ErbB2/ErbB3 signaling pathways regulate the activity of Estrogen Receptors (ER)

Sanchez, Melanie

04 1900

La signalisation par l’estrogène a longtemps été considérée comme jouant un rôle critique dans le développement et la progression des cancers hormono-dépendants tel que le cancer du sein. Deux tiers des cancers du sein expriment le récepteur des estrogènes (ER) qui constitue un élément indiscutable dans cette pathologie. L’acquisition d’une résistance endocrinienne est cependant un obstacle majeur au traitement de cette forme de cancer. L’émergence de cancers hormono-indépendants peut est produite par l’activation de ER en absence d’estrogène, l’hypersensibilité du récepteur aux faibles concentrations plasmique d’estrogène ainsi que l’activation de ER par des modulateurs sélectifs. L’activité du ER est fortement influencée par l’environnement cellulaire tel que l’activation de voie de signalisation des facteurs de croissances, la disponibilité de protéines co-régulatrices et des séquences promotrices ciblées. Présentement, les études ont principalement considérées le rôle de ERα, cependant avec la découverte de ERβ, notre compréhension de la diversité des mécanismes potentiels impliquant des réponses ER-dépendantes s’est améliorée. L’activation des voies des kinases par les facteurs de croissance entraîne le développement d’un phénotype tumoral résistant aux traitements actuels. Nos connaissances des voies impliquées dans l’activation de ER sont restreintes. ERα est considéré comme le sous-type dominant et corrèle avec la plupart des facteurs de pronostic dans le cancer du sein. Le rôle de ERβ reste imprécis. Les résultats présentés dans cette thèse ont pour objectif de mieux comprendre l’implication de ERβ dans la prolifération cellulaire par l’étude du comportement de ERβ et ERα suite à l’activation des voies de signalisation par les facteurs de croissance. Nous démontrons que l’activation des récepteurs de surfaces de la famille ErbB, spécifiquement ErbB2/ErbB3, inhibe l’activité transcriptionnelle de ERβ, malgré la présence du coactivateur CBP, tout en activant ERα. De plus, l’inhibition de ERβ est attribuée à un résidu sérine (Ser-255) situé dans la région charnière, absente dans ERα. Des études supplémentaires de ErbB2/ErbB3 ont révélé qu’ils activent la voie PI3K/Akt ciblant à son tour la Ser-255. En effet, cette phosphorylation de ERβ par PI3K/Akt induit une augmentation de l’ubiquitination du récepteur qui promeut sa dégradation par le système ubiquitine-protéasome. Cette dégradation est spécifique pour ERβ. De façon intéressante, la dégradation par le protéasome requiert la présence du coactivateur CBP normalement requis pour l’activité transcriptionnelle des récepteurs nucléaires. Malgré le fait que l’activation de la voie PI3K/Akt corrèle avec une diminution de l’expression des gènes sous le contrôle de ERβ, on observe une augmentation de la prolifération des cellules cancéreuses. L’inhibition de la dégradation de ERβ réduit cette prolifération excessive causée par le traitement avec Hrgβ1, un ligand de ErbB3. Un nombre croissant d’évidences indique que les voies de signalisations des facteurs de croissance peuvent sélectivement réguler l’activité transcriptionnelle de sous-types de ER. De plus, le ratio ERα/ERβ dans les cancers du sein devient un outil de diagnostique populaire afin de déterminer la sévérité d’une tumeur. En conclusion, la caractérisation moléculaire du couplage entre la signalisation des facteurs de croissance et la fonction des ERs permettra le développement de nouveaux traitements afin de limiter l’apparition de cellules tumorales résistantes aux thérapies endocriniennes actuelles. / It has long been appreciated that estrogenic signaling plays a critical role in the development of hormone-dependent cancers such as breast cancer. Two-thirds of breast cancers express estrogen receptor (ER) which has been demonstrated to play an irrefutable role in tumour development and progression. However the acquisition of endocrine resistance has become a major obstacle in the treatment of hormone-dependent cancers that have acquired a hormone-independent state. Hormone-independent cancers emerge from an array of pathways involving ER activation in the absence of estrogen, hypersensitivity of ER to low serum levels of estrogen and activation by estrogen antagonists. The activity of ER is critically influenced by the cellular environment such as growth factor signaling pathways, availability of coregulatory proteins and the promoter sequence of target genes. The mechanisms studied have mostly considered the role of ERα, however with the discovery of the second subtype, ERβ, the understanding on the diversity of potential mechanisms involving ER-dependent responses have improved. Hormonal-independent activation of ER can occur in estrogen-dependent breast tumours, with concomitant rise in kinase signaling pathways, resulting in the acquisition of a therapeutic resistant phenotype in treated women. Our knowledge is relatively limited on which pathways trigger ER signaling and how these phosphorylation-coupled events affect ER activity. ERα is considered the dominant subtype and correlates with most of the prognostic factors in breast cancers. Conversely the role of ERβ remains unclear. The results presented in this thesis were carried out with the objective of gaining a better understanding of ERβ’s role in cellular proliferation by examining the behavior of ERβ and ERα during the activation of growth factor signaling pathways by cell-surface receptor-tyrosine kinases. We demonstrate here that the activation of cell surface receptors of the ErbB family, specifically ErbB2/ErbB3, inhibits the transcriptional activity of ERβ despite the presence of the coactivator CBP, yet activated ERα. Furthermore the inhibition of ERβ was attributed to a specific serine residue located within the hinge region, not present in ERα. Additional studies of ErbB2/ErbB3-initiated signaling revealed that it triggered the activation of the PI3K/Akt pathway which targeted the serine residue within the hinge region of ERβ. In fact, phosphorylation of ERβ by the PI3K/Akt pathway led to an increase in receptor ubiquitination which promoted its degradation by the ubiquitin-proteasome system which was subtype specific. Interestingly, proteasomal degradation required the presence of the coactivator CBP, which is normally involved in assisting nuclear receptor transcriptional activity. Although the activation of the PI3K/Akt pathway correlated with a decrease in the expression of ERβ target genes it led to an increase in the proliferation of breast cancer cells. Inhibiting the degradation of ERβ reduced the enhanced proliferation of breast cancer cells brought about by the treatment of ErbB3’s ligand, Hrgβ1. Increasing evidence indicates that growth factor signaling pathways can selectively regulate the transcriptional activity of ER subtypes, and the ratio of ERα/ERβ expression in breast tumours is becoming a popular prognostic factor to evaluate the severity of the tumour. Therefore the molecular characterization of the coupling between growth factor signaling and ER function should provide improved therapeutical approaches to overcome or delay the onset of resistance to endocrine therapy in hormone-dependent cancers.

Cancer hormone-dépendant

Récepteurs aux Estrogènes, ER

Facteurs de croissances

Récepteur de tyrosine kinase, RTK

ErbB

CBP/p300

Phosphorylation

Ubiquitination

Mdm2

PI3K/Akt

Hormone-dependent cancer

Estrogen Receptor, ER

Growth factors

receptor tyrosine kinase, RTK

ErbB

CBP/p300

phosphorylation

Ubiquitination

Mdm2

PI3K/Akt

Modificadores de penetrância de mutações germinativas no gene TP53 em famílias brasileiras com diagnóstico clínico da síndrome de Li-Fraumeni e Li-Fraumeni like: impacto dos polimorfismos intragênicos do TP53 e de genes / Genetic modifiers of germline TP53 mutation in Brazilian families with Li-Fraumeni and Li-Fraumeni Like syndromes: impact of TP53 intragenic polymorphisms and p53 regulatory genes

Maria Isabel Alves de Souza Waddington Achatz

08 December 2008

A síndrome de Li-Fraumeni (LFS) e sua variante like (LFL) são associadas a mutações germinativas no gene TP53 e predispõe ao alto risco para múltiplos tumores em idade jovem. Analisamos 91 famílias LFS/LFL do sul/sudeste do Brasil para mutações germinativas e haplótipos de TP53 (PIN2, PIN3 e PEX4) e MDM2 (309T-G). A mutação R337H ocorreu em 44,4% das famílias avaliadas. Em 750 controles da região a freqüência populacional da mutação foi 0,3%. A genotipagem de oito indivíduos não relacionados R337H-positivos para 29 TAG SNPs intragênicos demonstrou o mesmo haplótipo raro estabelecendo efeito fundador para R337H. O alelo duplicado no PIN3 apresenta impacto modificador e retardo de 17,1 anos na ocorrência de tumores em famílias com mutação no TP53, enquanto o SNP309 MDM2 modula a idade dos sarcomas de partes moles. / Li-Fraumeni syndrome (LFS) and its variant like (LFL) are associated with germline mutations in the TP53 gene and predispose to a variety of cancers at an earlier age. We analyzed 91 LFS/LFL families from southern Brazil for germline mutations in TP53 and polymorphisms in TP53 (PIN2, PIN3, PEX4) and MDM2 (309T-G). The germline TP53 mutation R337H was found in 44.4% of all families included. In 750 controls from the same region, mutation prevalence was 0.3%. Genotyping of eight unrelated R337H-positive individuals for 29 intragenic TAG SNPs showed that they all shared the same rare haplotype confirming the founder effect for the mutation. Duplication of PIN3 had a modifier effect on the age of tumor onset (delay of 17.1 years) in TP53 mutation carriers whereas MDM2 SNP309 modulated age of onset for soft-tissue sarcomas.

Carcinoma adrenocortical

Deleção de genes

Mutação em linhagem germinativa

Polimorfismo genético

Predisposição genética para doença

Proteína supressora de tumor p53

Proteínas proto-oncogênicas c-mdm2

Síndrome de Li-Fraumeni

Adrenocortical carcinoma

Gene deletion

Genetic polymorphism

Genetic predisposition to disease

Germline mutation

Li-Fraumeni syndrome

Proto-oncogene proteins c-mdm2

Tumor suppressor protein p53

Molecular Genetic Analysis in B-cell Lymphomas : A Focus on the p53 Pathway and p16INK4a

Zainuddin, Norafiza

January 2010

The presence of TP53 mutations has been associated with inferior outcome in diffuse large B-cell lymphoma (DLBCL) and chronic lymphocytic leukemia (CLL). In DLBCL, the impact of the TP53 codon 72 polymorphism and MDM2 SNP309 has not been clearly elucidated, whereas MDM2 SNP309 was suggested as a poor-prognostic marker in CLL. In addition, p16INK4a promoter hypermethylation has been implicated as a negative prognostic factor in DLBCL. The aim of this thesis was to further evaluate these molecular markers in well-characterised materials of DLBCL and CLL. In paper I, we investigated the prognostic role of TP53 mutation, codon 72 polymorphism and MDM2 SNP309 in DLBCL (n=102). The presence of TP53 mutations (12.7%) correlated with a poor lymphoma-specific and progression-free survival, and a particularly pronounced effect was observed in the germinal center subtype. Neither the MDM2 SNP309 nor the TP53 codon 72 polymorphism had an impact on age of onset or survival. In paper II, we applied pyrosequencing to measure the level of p16INK4a methylation in DLBCL (n=113). Thirty-seven percent of cases displayed p16INK4a methylation; however, no clear association could be observed between degree of methylation and clinical characteristics or lymphoma-specific survival. In papers III–IV, we investigated the prognostic role of MDM2 SNP309 (n=418) and TP53 mutation (n=268) in CLL. No correlation was observed between any particular MDM2 SNP309 genotype and time to treatment and overall survival. Furthermore, no association was found between the different MDM2 SNP309 genotypes and established CLL prognostic markers. TP53 mutations were detected in 3.7% of CLL patients; where the majority showed a concomitant 17p-deletion and only three carried TP53 mutations without 17p-deletion. We confirmed a significantly shorter overall survival and time to treatment in patients with both TP53 mutation and 17p-deletion. Altogether, our studies could confirm the negative prognostic impact of TP53 mutations in DLBCL, whereas MDM2 SNP309 and TP53 codon 72 polymorphisms appear to lack clinical relevance. We also question the role of p16INKa methylation as a poor-prognostic factor in DLBCL. Finally, the presence of TP53 mutation in CLL appears to be rare at disease onset and instead arise during disease progression.

Diffuse large B-cell lymphoma

chronic lymphocytic leukemia

TP53 mutation

MDM2 SNP309

codon 72 polymorphism

p16INK4a methylation

Clinical genetics

Klinisk genetik

Molecular biology

Molekylärbiologi

Haematology

Hematologi

Tumour biology

Tumörbiologi

DESIGNING COMBINATION DRUG REGIMENS TO IMPROVE GLIOBLASTOMA CHEMOTHERAPY: A PHARMACOKINETIC PHARMACODYNAMIC MODELING APPROACH

Saugat Adhikari (11267001)

13 August 2021

<p>Despite advancements in therapies, such as surgery, irradiation (IR) and chemotherapy, outcome for patients suffering from glioblastoma (GBM) remains fatal; the median survival time is only about 15 months. Even with novel therapeutic targets, networks and signaling pathways being discovered, monotherapy with such agents targeting such pathways has been disappointing in clinical trials. Poor prognosis for GBM can be attributed to several factors, including failure of drugs to cross the blood-brain-barrier (BBB), tumor heterogeneity, invasiveness, and angiogenesis. Development of tumor resistance, particularly to temozolomide (TMZ) and IR, creates a substantial clinical challenge.</p><p> </p><p>The primary focus of the work described herein was to develop a modeling and simulation approach that could be applied to rationally develop novel combination therapies and dose regimens that mitigate resistance development. Specifically, TMZ was combined with small molecule inhibitors that are either currently in clinical trials or are approved drugs for other cancer types, and which target the disease at various resistance signaling pathways that are induced in response to TMZ monotherapy. To accomplish this objective, an integrated PKPD modeling approach was used. A PK model for each drug was first defined. PK models were subsequently linked to a PD model description of tumor growth dynamics in the presence of a single drug or combinations of drugs. A key outcome of these combined PKPD models was tumor static concentration (TSC) curves of TMZ in combination with small molecule inhibitors that identify combination drug exposures predicted to arrest tumor growth. This approach was applied to TMZ in combination with abemaciclib (a dual CDK4/6 small molecule inhibitor) based on data from a published study evaluating abemaciclib (ACB) efficacy in combination with TMZ in a U87 GBM xenograft model. TSC was also constructed for TMZ in combination with RG7388 (MDM2 inhibitor) based on the data from an in-vivo study that evaluated effects on tumor growth suppression of these small molecule inhibitors in combination with TMZ in GBM 10 patient derived xenografts.</p><p>In GBM 43 mouse xenografts, emergence of resistance to TMZ treatment was identified. Thus, a resistance integrated PKPD model was developed to predict tumor growth kinetics after treatment with TMZ in GBM 43 tumors. Population PK models in immune deficient NOD.Cg-<em>Prkdc^scid Il2rg^tm1Wjl</em>/SzJ (NSG) mice for TMZ and small molecule inhibitors (GDC0068/RG7112) were developed based on a combination of data obtained from an in-vivo study and published sources. Subsequently, PK models were linked to tumor volume data obtained from GBM 43 subcutaneous xenografts. Model parameters quantifying tumor volume dynamics were precisely estimated (coefficient of variation < 40%) compared to a base tumor growth inhibition model in GBM 43 that did not incorporate resistance development. Graphical diagnostics of the resistance incorporated PKPD tumor growth inhibition model demonstrated a superior fit compared to the base model, and accurately captured the emergence of resistance to the TMZ monotherapy treatment observed in the GBM 43 patient derived xenograft model.</p>

Cancer

Chemotherapy

Clinical Pharmacology and Therapeutics

Pharmaceutical Sciences

PKPD Modeling

Pharmacokinetics

Pharmacodynamics

Tumor Growth Inhibition Models

Glioblastoma

Temozolomide

Combination Chemotherapy

MDM2 inhibitor

AKT inhibitor

CDK4/6 Kinase Inhibitor

RG7388

RG7112

GDC0068

Abemaciclib

Mdm2-p53 Signaling in Tissue Homeostasis and the DNA Damage Response: A Dissertation

Gannon, Hugh S.

28 June 2012

The p53 transcription factor responds to various cellular stressors by regulating the expression of numerous target genes involved in cellular processes such as cell cycle arrest, apoptosis, and senescence. As these downstream pathways are harmful to the growth and development of normal cells when prolonged or deregulated, p53 activity needs to be under tight regulatory control. The Mdm2 oncoprotein is the chief negative regulator of p53, and many mouse models have demonstrated that absence of Mdm2 expression leads to constitutive p53 activation in a variety of cell types. While unregulated p53 can be deleterious to cells, functional p53 is essential for tumor suppression, as many human cancers harbor p53 mutations and p53 knockout mice rapidly develop spontaneous tumors. Therefore, the mechanisms that control p53 regulation by Mdm2 are critical to ensure p53 activity in the appropriate cellular context. Many genetically engineered mouse models have been created to analyze p53 and Mdm2 functions and these studies have yielded valuable insights into their physiological roles. This dissertation will describe the generation and characterization of novel mutant Mdm2 mouse models and their use to interrogate the roles of p53-Mdm2 signaling in tissue homeostasis and cell stress responses. Deletion of Mdm2 in epidermal progenitor cells of the skin and hair follicles resulted in progressive hair loss and decreased skin integrity, phenotypes that are characteristic of premature aging. Furthermore, p53 protein levels, p53 target gene expression, and cellular senescence were all upregulated in the skins of these mice, and epidermal stem cell numbers and function were diminished. These results indicate that Mdm2 is necessary to limit p53 activity in adult tissues to ensure normal stem cell function. Additional mouse models used to determine the role of Mdm2 phosphorylation will also be presented. DNA damage triggers an extensive cellular response, including activation of the ATM kinase. ATM activity is necessary for p53 protein stabilization and, therefore, p53 activation, but in vivo evidence suggests that phosphorylation of p53 itself had little effect on p53 stability. ATM was previously shown to phosphorylate MDM2 at serine residue 395 (394 in mice), and we generated knock-in mutant mouse models to study the role of this posttranslational modification in vivo. Absence of this phosphorylation site led to greatly diminished p53 stability and function in response to γ-irradiation and increased spontaneous tumorigenesis in mice. Conversely, a phosphomimic model demonstrated prolonged p53 activation in cells treated with γ-irradiation, which revealed that phosphorylation of this Mdm2 residue controls the duration of the DNA damage response. Therefore, these mouse models have uncovered new roles for the p53-Mdm2 regulatory axis in vivo and will be useful reagents in future studies of posttranslational modifications in oncogene and DNA damage-induced tumorigenesis.

Proto-Oncogene Proteins c-mdm2

Tumor Suppressor Protein p53

Homeostasis

DNA Damage

Cell Transformation

Neoplastic

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cancer Biology

Cell and Developmental Biology

Cells

Genetic Phenomena

Neoplasms

Tissues

A Tale of Two ARFs: Tumor Suppressor and Anti-viral Functions of p14ARF: A Dissertation

Straza, Michael W.

21 May 2010

Animals have evolved complicated and overlapping mechanisms to guard against the development of cancer and infection by pathogenic organisms. ARF, a potent tumor suppressor, positively regulates p53 by antagonizing p53’s negative regulator, MDM2, which in turn results in either apoptosis or cell cycle arrest. ARF also has p53-independent tumor suppressor activity. The CtBP transcriptional co-repressors promote cancer cell survival and migration/invasion. CtBP senses cellular metabolism via a regulatory dehydrogenase domain, and is a target for negative regulation by ARF. ARF targets CtBP to the proteasome for degradation, which results in the up regulation of proapoptotic BH3-only proteins, and p53-independent apoptosis. CtBP inhibition by ARF also up regulates PTEN, reducing cancer cell motility, making CtBP a potential therapeutic target in human cancer. The CtBP dehydrogenase substrate 4-methylthio-2-oxobutyric acid (MTOB) can act as a CtBP inhibitor at high concentrations, and is cytotoxic to cancer cells from a wide variety of tissues. MTOB induced apoptosis was independent of p53, and correlated with the de-repression of the pro-apoptotic CtBP repression target Bik. CtBP over-expression, or Bik silencing, rescued MTOB-induced cell death. MTOB did not induce apoptosis in mouse embryonic fibroblasts (MEFs), but was increasingly cytotoxic to immortalized and transformed MEFs, suggesting that CtBP inhibition may provide a suitable therapeutic index for cancer therapy. In human colon cancer cell peritoneal xenografts, MTOB treatment decreased tumor burden, and induced tumor cell apoptosis. To verify the potential utility of CtBP as a therapeutic target in human cancer the expression of CtBP and its negative regulator ARF was studied in a series of resected human colon adenocarcinomas. CtBP and ARF levels were inversely-correlated, with elevated CtBP levels (compared with adjacent normal tissue) observed in greater than 60% of specimens, with ARF absent in nearly all specimens exhibiting elevated CtBP levels. Targeting CtBP with a small molecule like MTOB may thus represent a useful and widely applicable therapeutic strategy in human malignancies. ARF has long been known to respond to virally encoded oncogenes. Recently, p14ARF was linked to the innate immune response to non-transforming viruses in mice. Therefore a wider role for the ARF pathway in viral infection was considered. Previous studies linking p53 to multiple points of the Human Immunodeficiency Virus-1 (HIV-1) life cycle suggested that ARF may also play a role in the HIV life cycle. In this study the interdependency of ARF and HIV infection was investigated. ARF expression was determined for a variety of cell types upon HIV infection. In every case, ARF levels exhibited dynamic changes upon HIV infection-in most cases ARF levels were reduced in infected cells. The impact of ARF over-expression or silencing by RNAi on HIV infection was also examined. Consistently, p24 levels were increased with ARF overexpression, and decreased when ARF was silenced. Thus ARF and HIV modulate each other, and ARF may paradoxically play a positive role in the HIV life cycle.

Tumor Suppressor Protein p14ARF

Tumor Suppressor Protein p53

Proto-Oncogene Proteins c-mdm2

HIV

C-terminal binding protein

Transaminases

Amino Acids, Peptides, and Proteins

Cancer Biology

Enzymes and Coenzymes

Neoplasms

Therapeutics

Viruses

Phospho-regulation and metastatic potential of Murine Double Minute 2

Batuello, Christopher N.

21 December 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Murine double minute (Mdm2) is a highly modified and multi-faceted protein that is overexpressed in numerous human malignancies. It engages in many cellular activities and is essential for development since deletion of mdm2 is lethal in early stages of embryonic development. The most studied function of Mdm2 is as a negative regulator of the tumor suppressor protein p53. Mdm2 achieves this regulation by binding to p53 and inhibiting p53 transcriptional activity. Mdm2 also functions as an E3 ubiquitin ligase that signals p53 for destruction by the proteasome. Interestingly recent evidence has shown that Mdm2 can also function as an E3 neddylating enzyme that can conjugate the ubiquitin-like molecule, nedd8, to p53. This modification results in inhibition of p53 activity, while maintaining p53 protein levels. While the signaling events that regulate Mdm2 E3 ubiquitin ligase activity have been extensively studied, what activates the neddylating activity of Mdm2 has remained elusive. My investigations have centered on understanding whether tyrosine kinase signaling could activate the neddylating activity of Mdm2. I have shown that c-Src, a non-receptor protein tyrosine kinase that is involved in a variety of cellular processes, phosphorylates Mdm2 on tyrosines 281 and 302. This phosphorylation event increases the half-life and neddylating activity of Mdm2 resulting in a neddylation dependent reduction of p53 transcriptional activity. Mdm2 also has many p53-independent cellular functions that are beginning to be linked to its role as an oncogene. There is an emerging role for Mdm2 in tumor metastasis. Metastasis is a process involving tumor cells migrating from a primary site to a distal site and is a major cause of morbidity and mortality in cancer patients. To date, the involvement of Mdm2 in breast cancer metastasis has only been correlative, with no in vivo model to definitively define a role for Mdm2. Here I have shown in vivo that Mdm2 enhances breast to lung metastasis through the up regulation of multiple angiogenic factors, including HIF-1 alpha and VEGF. Taken together my data provide novel insights into important p53-dependent and independent functions of Mdm2 that represent potential new avenues for therapeutic intervention.

Mdm2

Nedd8

Metastasis

Phosphorylation

c-Src

Cellular signal transduction

Protein-tyrosine kinase -- Inhibitors

p53 antioncogene -- Analysis

Phosphorylation

Metastasis

Antioncogenes

Tumor suppressor proteins

Genetic transcription

Ubiquitin

Proteomics

Post-translational modification

Ligases

mdm2 Amplification in NIH3T3L1 Preadipocytes Leads to Mdm2 Elevation in Terminal Adipogenesis

Litteral, Vaughn

23 July 2008

No description available.

Biochemistry

Biology

Biomedical Research

Cellular Biology

Molecular Biology

Oncology

mdm2

mdm-2

Rb

retinoblastoma

p53

cancer

adipogenesis

liposarcoma

adipose

oncogene

C/EBP

tumor suppressor

NIH3T3L1

NIH3T3-L1

NIH3T3

amplification

chromosomal amplification

Southern

Northern

Western

immunoprecipitation

mdm4

mdmX