Σχεδιασμός, σύνθεση και αποτίμηση βιολογικής δραστικότητας νέων πυρρολοκαρβαζολικών αναλόγων ως πιθανοί αναστολείς της CDK1 / Design, synthesis and evaluation of biological activity of new pyrrolcarbazole analogues as possible CDK1 inhibitors

Σπυρόπουλος, Ευστάθιος Σ.

12 April 2010

Οι κυκλινοεξαρτώμενες κινάσες (CDKs) αποτελούν μία οικογένεια κινασών σερίνης/θρεονίνης, η δραστικότητά των οποίων εξαρτάται από την πρόσδεσή τους σε ρυθμιστικές υπομονάδες (κυκλίνες). Οι CDKs διαδραματίζουν καθοριστικό ρόλο στην ομαλή αλληλοδιαδοχή των σταδίων του κυτταρικού κύκλου οδηγώντας σε φυσιολογικό κυτταρικό πολλαπλασιασμό. Ωστόσο, απορρύθμιση της δράσης τους παρατηρείται σε πολλούς καρκινικούς όγκους με συνέπεια να αποτελούν ελκυστικό στόχο για την καταπολέμηση του καρκίνου. Πληθώρα παραγόντων με ανασταλτική δράση έναντι των CDKs έχουν συντεθεί και μερικοί από αυτούς βρίσκονται σε προχωρημένες φάσεις κλινικών δοκιμών. Επιπλέον πρόσφατα πειράματα γενετικής κατέδειξαν την CDK1 ως επαρκή (σε έλειψη των άλλων CDKs) και πιθανά αναγκαία για την ολοκλήρωση του κυτταρικού κύκλου. Στα πλαίσια της παρούσας μελέτης σχεδιάσθηκε και συντέθηκε μια σειρά υποκατεστημένων πυρρολο[2,3-a]καρβαζολίων, σε μία προσπάθεια βελτίωσης των ιδιοτήτων και μελέτης των σχέσων χημικής δομής– βιολογικής δραστικότητας του 2-(αιθοξυκαρβονυλο)-9-χλωρο- πυρρολο[2,3-a]καρβαζολίου , το οποίο πρόσφατα αποδείχθηκε αναστολέας της CDK1. Συγκεκριμένα συντέθηκαν 3-ακυλαμιδο-, 3- αλκυλσουλφοναμιδο- και 3-αμινο-υποκατεστημένα πυρρολο[2,3- a]καρβαζόλια, καθώς και Ν-αλκυλ-υποκατεστημένα πυρρολο[2,3- a]καρβαζολο-2-καρβοξαμίδια. Η σύνθεση των τελικών αυτών προϊόντων στηρίχτηκε στη σύνθεση ενδιαμέσων κατάλληλα υποκατεστημένων 7-κετο- 4,5,6,7-τετραϋδροϊνδολίων, και στην ινδολοποίηση αυτών κατά Fischer με την ο-χλωρο-φαινυλυδραζίνη. Μελετήθηκε η επίδραση των 3-ακυλαμιδο-υποκατεστημένων παραγώγων στη δραστικότητα του συμπλόκου CDK1/κυκλίνη Β. Όλα τα παράγωγα προκάλεσαν σε συγκέντρωση 100 μΜ αναστολή της δραστικότητας της CDK1 σε ποσοστό από 35 έως 75%. Δραστικότερη εμφανίστηκε η ένωση 1a3. / Cyclin dependent kinases (CDKs) are a subgroup of serine/threonine kinases, whose activity depends upon binding to regulatory subunits (cyclins). CDKs have a crucial role in cell cycle progression and proliferation. Deregulation of their activity is a common feature in human tumors; hence, CDKs represent attractive targets for cancer therapy. A plethora of CDK inhibitors have been synthesized and some of them are already in late phases of clinical trials. Furthermore, recent genetic studies have indicated that CDK1 is sufficient (when in absence of other CDKs) and probably essential to drive the cell cycle. Attempting to improve the structural characteristics and study the structure–activity relationships of 9-chloro-2-(ethoxycarbonyl)- pyrrolo[2,3-a]carbazole, which has been proved as a CDK1 inhibitor, this study focused on the design and synthesis of several substituted pyrrolo[2,3-a]carbazole derivatives. Particularly, 3-acylamido-, 3- alkylsulfonamido- and 3-amino-substituted pyrrolo[2,3-a]carbazoles and N-alkyl-substituted pyrrolo[2,3-a]carbazolo-2-carboxamides comprised synthetic targets of the study. The synthesis of the final products was based on the synthesis of appropriately substituted 7-keto-4,5,6,7- tetrahydroindole intermediates which served as building blocks in Fischer indolization reactions with the o-chloro-phenylhydrazine. The effect of the 3-akylamido- substituted derivatives on the CDK1/cyclin B activity was studied. All derivatives proved to inhibit CDK1 activity, in a range of 35 to 75%. Derivative 1a3 proved the most potent inhibitor of CDK1.

Πυρρολοκαρβαζόλια

Τετραυδροϊνδόλια

Φαρμακευτική χημεία

Αντίδραση Fischer

Ινδολοποίηση

CDK αναστολείς

571.84

Pyrrolcarbazole

CDK

Tetrahydroindoles

Pharmaceutical chemistry

Fischer indole synthesis

CDK inhibitors

Identification et caractérisation de candidats régulateurs du cycle cellulaire chez le dinoflagellé Lingulodinium polyedrum

Bertomeu, Thierry

January 2007

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Cycline

CDK

AAA

Cycle cellulaire

Dinoflagellé

Rythme circadien

Novel Therapeutic Strategies in Lung Cancer

Kurtyka, Courtney A.

17 October 2014

Lung cancer is the leading cause of cancer-related death and the second most diagnosed cancer in the United States. Unfortunately, many patients either do not have any common mutations for which there are already targetable agents, or they eventually become resistant to these compounds. As such, there is a high demand for new, effective methods of treating this disease as well as predicting patient prognosis and potential benefit from chemotherapy. In this work, numerous strategies for treating lung cancer are explored. The first method described here is through the use of a pan-early 2 factor (E2F) inhibitor, HLM006474, which is shown to synergize with paclitaxel in non-small cell lung cancer (NSCLC). Next, we explored the creation and utilization of an E2F signature that is prognostic and predictive of early-stage NSCLC patient benefit from adjuvant chemotherapy (ACT). The third project examined possible targets to enhance sensitivity to cisplatin in NSCLC lacking Kirsten rat sarcoma viral oncogene homolog (KRAS) and epidermal growth factor receptor (EGFR) mutations and anaplastic lymphoma receptor tyrosine kinase (ALK) fusions (triple-negative), for which cisplatin is one of the few treatment options. These studies led to the identification of a kinase that is overexpressed in NSCLC and whose knockdown sensitizes cells to platinum agents.

CDK

cisplatin

E2F

NSCLC

paclitaxel

Cancer Biology

Cell and Developmental Biology

Hodnocení vlivu inhibitorů CDK a FLT3 na aktivitu ABC efluxních transportérů in vitro, vztah k mnohočetné lékové rezistenci / Effect of CDK and FLT3 inhibitors on activity of ABC efflux transporters in vitro, relation to multidrug resistance

Poráč, Jakub

January 2020

Charles University Faculty of Pharmacy in Hradec Králové Department of Pharmacology & Toxicology Student: Jakub Poráč Supervisor: doc. PharmDr. Martina Čečková, Ph.D. Title of diploma thesis: Effect of CDK and FLT3 inhibitors on activity of ABC efflux transporters in vitro, relation to multidrug resistance P-gp and BCRP are transmembrane proteins that form part of a large family of ABC transporters. These are ATP-driven transporters, which main task is to eliminate exogenous and endogenous substances and their metabolites from cells of both, healthy and tumour tissues. This activity is often associated with the expulsion of administered therapeutics and multiple drug resistance (MDR) in tumour cells. A promising therapy of cancer represents a newer class of drugs target the tyrosine kinase (TK), and cyclin-dependent kinases (CDK), which are cell enzymes responsible for the processes of proliferation, apoptosis and differentiation. Cyclin- dependent kinase inhibitors (CDKI) are used in the treatment of breast cancer, but at the same time they form a new group of drugs with the potential for use in hematological malignancies. In the treatment of AML, a new successful approach is TK inhibitors (TKI), which target the mutated FLT3 receptor, specifically the recently approved drugs midostaurin and...

Cyclin J-CDK complexes limit innate immune responses by reducing proinflammatory changes in macrophage metabolism / Cyclin J－CDK複合体はマクロファージの代謝を介し炎症性変化を抑制することで自然免疫応答を調節する

Chong, Yee Kien

25 July 2022

京都大学 / 新制・課程博士 / 博士(医科学) / 甲第24140号 / 医科博第141号 / 新制||医科||9(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 金子 新, 教授 椛島 健治, 教授 松田 道行 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Innate immunity

metabolism

Cyclin J

macrophage

CDK

491

Functional Analysis of the Role of TRF1 Phosphorylation on Threonine 271 and Threonine 371 in Telomere Maintenance / Functional Analysis of TRF1 Phosphorylation in Telomere Maintenance

Ho, Angus

18 November 2016

TRF1, telomeric-repeat binding factor 1, is a component of the six-subunit protein complex, referred to as shelterin, which is essential for not only regulating telomere length maintenance but also protecting mammalian telomeres from being recognized as damaged DNA. TRF1 acts as a negative mediator of telomerase-dependent telomere elongation in telomerase-expressing cells, whereas it promotes alternative lengthening of telomeres (ALT) activity by regulating ALT features including the production of extrachromosomal telomere-repeat (ECTR) DNA such as C-circles, and ALT-associated promyelocytic leukemia bodies, or APBs. The activity of TRF1 is tightly regulated by post-translational modification such as phosphorylation. This thesis sets out to investigate the function of TRF1 phosphorylation on threonine-271 (T271) and threonine-371 in telomere maintenance. The results presented in this thesis demonstrate that TRF1 phosphorylation on T271 positively regulates the association of TRF1 to telomeric DNA in telomerase expressing cells. In ALT cells, TRF1 phosphorylation on both T271 and T371 is shown to be important for the formation of APBs. Furthermore, the work presented here suggests that transcription-associated DNA damage mediates the association of phosphorylated (pT371)TRF1 with APBs. / Thesis / Master of Science (MSc) / TRF1, telomeric-repeat binding factor 1, is a component of the shelterin complex, which is essential for regulating telomere length maintenance and protecting mammalian telomeres from being recognized as damaged DNA. TRF1 acts as a negative mediator of telomerase-dependent telomere elongation in telomerase-expressing cells, whereas it promotes alternative lengthening of telomeres. The activity of TRF1 is tightly regulated by phosphorylation. This thesis sets out to investigate the function of TRF1 phosphorylation on threonine-271 and threonine-371 in telomere maintenance. Understanding how post-translational modifications on TRF1 may be linked to telomere homeostasis will be crucial for our understanding in cancer cell biology.

Telomere

Cancer

TRF1

Biology

DNA repair

ALT

PML bodies

Cdk

Quantitative Analysis of a Cell Cycle Checkpoint in Xenopus laevis Cell-Free Egg Extracts

Auckland, Ian

06 December 2005

In somatic cells, checkpoint pathways trigger cell cycle arrest in response to unreplicated or damaged DNA by inhibiting the activity of cyclin-dependent kinases (Cdks). In the Xenopus laevis embryo, checkpoints are not operational until the midblastula transition (MBT). Studies in cell-free egg extracts indicate that a threshold concentration of nuclei, which approximates the MBT concentration, is required to elicit a checkpoint. The checkpoint response to unreplicated DNA in the extract prevents transition into mitosis by inhibiting Cdk1/cyclin B, causing an increase in the minimum amount of cyclin B necessary to enter mitosis, termed the cyclin threshold. Once the threshold of cyclin is maintained or exceeded, the system will proceed into mitosis after a lag time. We have investigated the relationship between nuclear concentration and cell cycle regulation in the extract. By precisely regulating the concentration of cyclin B and nuclear content in extract samples, we have found 1) the concentration of nuclei affects cyclin B thresholds and lag time of entry into mitosis, 2) elevated cyclin thresholds caused by DNA replication blocks are further increased by increasing the concentration of nuclei, and 3) double-stranded DNA breaks in the extract system do not affect cyclin thresholds or lag time of entry into mitosis within the range of nuclear concentrations that can be efficiently replicated. This data provides evidence of the importance of the nucleocytoplasmic ratio in normal cell cycle progression and its importance for checkpoint acquisition during early Xenopus laevis development. / Master of Science

cell cycle

Xenopus laevis

nucleocytoplasmic ratio

cyclin-dependent kinases (Cdk)

NtCDKG;2, uma proteína multifuncional, relacionada aos processos de transcrição, processamento de RNA e organização do fuso acromático no ciclo celular de Nicotiana tabacum / NtCDKG;2, a multifunctional protein, related to RNA transcription, RNA processing and achromatic spindle organization in Nicotiana tabacum cell cycle

Lubini, Greice

13 December 2016

Os estudos em reprodução e desenvolvimento das plantas, especialmente voltados ao pistilo, são de grande interesse agronômico, econômico e científico. Em nosso laboratório, recentemente, foi identificado e caracterizado SCI1 (Stigma/style Cell-cycle Inhibitor 1), um inibidor do ciclo celular que atua de forma tecido específica no pistilo de Nicotiana tabacum L. e Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). Foi identificada a proteína NtCDKG;2 (N. tabacum Cyclin-dependent Kinase 2) como parceira de interação de NtSCI1 (N . tabacum SCI1), em um ensaio de pull-down (STRINI, 2014). A literatura aponta que os inibidores de ciclo celular regulam o ciclo através da inibição de CDK, o que sugere que NtSCI1 possa regular o ciclo celular através da inibição de NtCDKG;2. O presente estudo mostra análises detalhadas da localização de GFP-NtCDKG;2 em células epiteliais de N. benthamiana. Verificou-se que a proteína NtCDKG;2 está presente no nucleoplasma e também co-localiza em speckles nucleares. Em cultura de células BY2 expressando GFP-NtCDKG;2 de forma estável, foi observado que, durante a metáfase e anáfase, a proteína NtCDKG;2 está junto ao fuso acromático. Adicionalmente, ensaios de BiFC (Bi-molecular Fluorescence Complementation) realizados neste trabalho mostram que a interação entre as proteínas NtCDKG;2 e NtSCI1 ocorre em uma região localizada na periferia nucleolar, durante a interfase. Também foram identificadas possíveis isoformas de NtCDKG;2. A possibilidade da ocorrência de isoformas sugere que, de maneira análoga à sua homóloga em humanos, as isoformas resultantes de NtCDKG;2 possam atuar em diferentes processos. Em busca de parceiros de interação de NtCDKG;2, para identificar em que vias esta proteína atua, foi realizado um screening de uma biblioteca de cDNAs de estigmas e estiletes de N. tabacum, no sistema de duplo-híbrido em leveduras (Y2H). Através desse ensaio, foram identificados diversos parceiros envolvidos com transcrição e processamento de RNA. Dentre as proteínas identificadas, cuja interação foi confirmada neste trabalho, destaca-se a proteína NtCDKF;1, uma proteína que fosforila o CTD da RNA Polimerase II e, dessa forma, auxilia a transcrição e o splicing cotranscricional (HAJHEIDARI et al., 2012). O presente trabalho mostra também a interação entre NtCDKG;2 e a proteína NtCBP1, uma proteína que possui um papel importante na regulação inicial da transcrição de proteínas mediadoras do crescimento do tubo polínico (LI et al., 2015). xx Adicionalmente, o screening de Y2H possibilitou a identificação da interação entre NtCDKG;2 e NtRanBP1, uma proteína chave na formação do fuso acromático que, em humanos, interage com uma isoforma homóloga a NtCDKG;2, a CDK11p46 (MIKOLAJCZYK et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011). Análises in silico realizadas com a sequência de aminoácidos de NtCDKG;2 apontaram motivos de interação com proteína do tipo F-Box, ciclina, CDK, fosfatase, 14-3-3, BRCA1 e indicaram o local provável de interação do complexo CDK-Ciclina com o respectivo inibidor. Foi testada e comprovada a interação entre NtCDKG;2 e a 14-3-3D, por Y2H, uma parceira de NtSCI1. Outra lacuna que precisava ser preenchida é referente à regulação da expressão de NtSCI1. Com este intuito, foram realizadas análises in silico para identificar elementos cis-regulatórios na sequência genômica de NtSCI1. Essas análises indicaram a presença de importantes elementos cis-regulatórios relacionados à identidade meristemática (como WUSCHEL e AINTEGUMENTA), identidade do carpelo (AGAMOUS, BELL) e progressão do ciclo celular (E2F e CDC5). Algumas considerações podem ser feitas associando os resultados obtidos a estudos feitos paralelamente em nosso laboratório: 1) Compilando a localização de NtCDKG;2 em splicing speckles e sua interação com os diferentes parceiros de interação relacionados à transcrição e splicing, sugere-se que NtCDKG;2 também atue nos processos transcricionais e de splicing. 2) Considerando a localização subcelular de NtCDKG;2 durante as diferentes fases do ciclo celular, às análises in silico dessa proteína que identificaram sua possível interação com BRCA1, além da interação confirmada com a proteína NtRanBP1, é possível sugerir que NtCDKG;2 atue, direta ou indiretamente, na organização do fuso acromático de plantas. 3) Propõem-se que NtSCI1 regule a proliferação celular no pistilo através da interação com NtCDKG;2 que se dá no nucléolo das células. Dessa forma, NtSCI1 prenderia NtCDKG;2 no nucléolo e inibiria sua atuação, como na organização do fuso acromático, o que acarretaria inibição da divisão celular. 4) Devido aos motivos cis-regulatórios encontrados na sequência genômica de NtSCI1 e o efeito que a proteína possui desde as fases iniciais do desenvolvimento do pistilo, sugere-se que a expressão desse gene seja regulada por elementos diretamente envolvidos no controle do término do meristema floral e nas vias de desenvolvimento de órgãos florais. / Studies on plant reproduction and development, specifically those related to the pistil, are of great agronomic, economic and scientific interest. In our laboratory, we recently identified and characterized SCI1 (Stigma/style Cell-cycle Inhibitor 1), an inhibitor of the cell cycle which acts tissuespecifically in the pistil of Nicotiana tabacum L. and Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). The NtCDKG;2 (N. tabacum Cyclin-dependent Kinase G; 2) protein was identified as an interaction partner of NtSCI1 (N. tabacum SCI1) in a pulldown assay (STRINI, 2014). The literature suggests that cell cycle inhibitors control the cycle through the inhibition of CDKs, indicating that NtSCI1 might control cell cycle by inhibiting NtCDKG;2. This study shows detailed analysis of GFP-NtCDKG;2 localization in leaf cells of N. benthamiana. The analysis shows that NtCDKG;2 is present in the nucleoplasm and also co-localizes with nuclear speckles. In BY2 cell culture stably expressing GFP-NtCDKG;2, it was observed that NtCDKG;2 is at the achromatic spindle during metaphase and anaphase. Additionally, BiFC (Bimolecular Fluorescence Complementation) assays performed in this study have shown that the interaction of NtCDKG;2 and NtSCI1 occurs in the nucleolar periphery during interphase. Putative isoforms of NtCDKG;2 were also identified. The possible occurrence of these isoforms suggests that, in a similar way to its human homologue, NtCDKG;2 putative isoforms could act in different processes. To identify in which processes this protein could act, a search for NtCDKG;2 interaction partners was performed through the screening of a N. tabacum stigma and style cDNA library in the yeast two-hybrid (Y2H) system. Several partners identified through this assay have roles in RNA transcription and processing. Among the identified partners with interaction confirmed during this work, stands out the NtCDKF;1 protein, a CDK that phosphorylates the RNA polymerase II CTD, and thus, supports transcription and co-transcriptional splicing (HAJHEIDARI et al., 2012). This study also shows the interaction of NtCDKG;2 with NtCBP1, a protein which has an important role in the transcriptional regulation of genes encoding proteins mediating pollen tube growth (LI et al., 2015). Furthermore, the Y2H screening allowed the identification of the interaction of NtCDKG;2 with NtRanBP1, a key protein in the formation of the achromatic spindle which, in humans, interacts with the CDK11p46 isoform (MIKOLAJCZYK xxii et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011), a homologue of NtCDKG;2. In silico analysis of the amino acid sequence of NtCDKG;2 revealed motifs of predicted interaction with F-box proteins, cyclins, CDKs, phosphatases, 14-3-3s, BRCA1, and also pointed the region where the CDK-cyclin complex might interact with its respective inhibitor. The interaction of NtCDKG;2 with 14-3-3D, a known partner of NtSCI1, was tested and confirmed by Y2H. Another gap that needed to be filled is related to the regulation of NtSCI1 expression. To address this issue, in silico analysis to identify cis-regulatory elements was performed in NtSCI1 genomic region. These analyses revealed the presence of important cis-regulatory elements related to meristem identity (such as WUSCHEL and AINTEGUMENTA), carpel identity (AGAMOUS, BELL), and cell cycle progression (E2F and CDC5). Taken together results from this study and parallel studies performed in our laboratory, a few remarks can be made: 1) Taken the localization of NtCDKG;2 in splicing speckles, and its interaction with different proteins involved in transcription and splicing, it is suggested that NtCDKG;2 also has roles on these processes; 2) Considering the subcellular localization of NtCDKG;2 during the different cell cycle phases, the in silico analysis of this protein that predicts its interaction with BRCA1, and the confirmed interaction with NtRanBP1 protein, it is possible to suggest that NtCDKG;2 has a direct or indirect role in the organization of the achromatic spindle in plants; 3) It is proposed that NtSCI1 regulates cell proliferation in the pistil through its interaction with NtCDKG;2, which occurs in the nucleolus. Thus, NtSCI1 could hold NtCDKG;2 in the nucleolus, inhibiting its actions, such as in the organization of the achromatic spindle, resulting in cell division arrest. 4) Due to the cis-regulatory elements found in the genomic sequence of NtSCI1, and the effect of this protein since the initial stages of pistil development, it is suggested that its expression is regulated by elements directly involved in the control of the floral meristem termination and pathways of floral organ development.

achromatic spindle

BiFC

BiFC

CDK

CDK

cell cycle

ciclo celular

fuso acromático

localização subcelular

SCI1

SCI1

subcellular localization

Y2H

Y2H

NtCDKG;2, uma proteína multifuncional, relacionada aos processos de transcrição, processamento de RNA e organização do fuso acromático no ciclo celular de Nicotiana tabacum / NtCDKG;2, a multifunctional protein, related to RNA transcription, RNA processing and achromatic spindle organization in Nicotiana tabacum cell cycle

Greice Lubini

13 December 2016

Os estudos em reprodução e desenvolvimento das plantas, especialmente voltados ao pistilo, são de grande interesse agronômico, econômico e científico. Em nosso laboratório, recentemente, foi identificado e caracterizado SCI1 (Stigma/style Cell-cycle Inhibitor 1), um inibidor do ciclo celular que atua de forma tecido específica no pistilo de Nicotiana tabacum L. e Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). Foi identificada a proteína NtCDKG;2 (N. tabacum Cyclin-dependent Kinase 2) como parceira de interação de NtSCI1 (N . tabacum SCI1), em um ensaio de pull-down (STRINI, 2014). A literatura aponta que os inibidores de ciclo celular regulam o ciclo através da inibição de CDK, o que sugere que NtSCI1 possa regular o ciclo celular através da inibição de NtCDKG;2. O presente estudo mostra análises detalhadas da localização de GFP-NtCDKG;2 em células epiteliais de N. benthamiana. Verificou-se que a proteína NtCDKG;2 está presente no nucleoplasma e também co-localiza em speckles nucleares. Em cultura de células BY2 expressando GFP-NtCDKG;2 de forma estável, foi observado que, durante a metáfase e anáfase, a proteína NtCDKG;2 está junto ao fuso acromático. Adicionalmente, ensaios de BiFC (Bi-molecular Fluorescence Complementation) realizados neste trabalho mostram que a interação entre as proteínas NtCDKG;2 e NtSCI1 ocorre em uma região localizada na periferia nucleolar, durante a interfase. Também foram identificadas possíveis isoformas de NtCDKG;2. A possibilidade da ocorrência de isoformas sugere que, de maneira análoga à sua homóloga em humanos, as isoformas resultantes de NtCDKG;2 possam atuar em diferentes processos. Em busca de parceiros de interação de NtCDKG;2, para identificar em que vias esta proteína atua, foi realizado um screening de uma biblioteca de cDNAs de estigmas e estiletes de N. tabacum, no sistema de duplo-híbrido em leveduras (Y2H). Através desse ensaio, foram identificados diversos parceiros envolvidos com transcrição e processamento de RNA. Dentre as proteínas identificadas, cuja interação foi confirmada neste trabalho, destaca-se a proteína NtCDKF;1, uma proteína que fosforila o CTD da RNA Polimerase II e, dessa forma, auxilia a transcrição e o splicing cotranscricional (HAJHEIDARI et al., 2012). O presente trabalho mostra também a interação entre NtCDKG;2 e a proteína NtCBP1, uma proteína que possui um papel importante na regulação inicial da transcrição de proteínas mediadoras do crescimento do tubo polínico (LI et al., 2015). xx Adicionalmente, o screening de Y2H possibilitou a identificação da interação entre NtCDKG;2 e NtRanBP1, uma proteína chave na formação do fuso acromático que, em humanos, interage com uma isoforma homóloga a NtCDKG;2, a CDK11p46 (MIKOLAJCZYK et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011). Análises in silico realizadas com a sequência de aminoácidos de NtCDKG;2 apontaram motivos de interação com proteína do tipo F-Box, ciclina, CDK, fosfatase, 14-3-3, BRCA1 e indicaram o local provável de interação do complexo CDK-Ciclina com o respectivo inibidor. Foi testada e comprovada a interação entre NtCDKG;2 e a 14-3-3D, por Y2H, uma parceira de NtSCI1. Outra lacuna que precisava ser preenchida é referente à regulação da expressão de NtSCI1. Com este intuito, foram realizadas análises in silico para identificar elementos cis-regulatórios na sequência genômica de NtSCI1. Essas análises indicaram a presença de importantes elementos cis-regulatórios relacionados à identidade meristemática (como WUSCHEL e AINTEGUMENTA), identidade do carpelo (AGAMOUS, BELL) e progressão do ciclo celular (E2F e CDC5). Algumas considerações podem ser feitas associando os resultados obtidos a estudos feitos paralelamente em nosso laboratório: 1) Compilando a localização de NtCDKG;2 em splicing speckles e sua interação com os diferentes parceiros de interação relacionados à transcrição e splicing, sugere-se que NtCDKG;2 também atue nos processos transcricionais e de splicing. 2) Considerando a localização subcelular de NtCDKG;2 durante as diferentes fases do ciclo celular, às análises in silico dessa proteína que identificaram sua possível interação com BRCA1, além da interação confirmada com a proteína NtRanBP1, é possível sugerir que NtCDKG;2 atue, direta ou indiretamente, na organização do fuso acromático de plantas. 3) Propõem-se que NtSCI1 regule a proliferação celular no pistilo através da interação com NtCDKG;2 que se dá no nucléolo das células. Dessa forma, NtSCI1 prenderia NtCDKG;2 no nucléolo e inibiria sua atuação, como na organização do fuso acromático, o que acarretaria inibição da divisão celular. 4) Devido aos motivos cis-regulatórios encontrados na sequência genômica de NtSCI1 e o efeito que a proteína possui desde as fases iniciais do desenvolvimento do pistilo, sugere-se que a expressão desse gene seja regulada por elementos diretamente envolvidos no controle do término do meristema floral e nas vias de desenvolvimento de órgãos florais. / Studies on plant reproduction and development, specifically those related to the pistil, are of great agronomic, economic and scientific interest. In our laboratory, we recently identified and characterized SCI1 (Stigma/style Cell-cycle Inhibitor 1), an inhibitor of the cell cycle which acts tissuespecifically in the pistil of Nicotiana tabacum L. and Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). The NtCDKG;2 (N. tabacum Cyclin-dependent Kinase G; 2) protein was identified as an interaction partner of NtSCI1 (N. tabacum SCI1) in a pulldown assay (STRINI, 2014). The literature suggests that cell cycle inhibitors control the cycle through the inhibition of CDKs, indicating that NtSCI1 might control cell cycle by inhibiting NtCDKG;2. This study shows detailed analysis of GFP-NtCDKG;2 localization in leaf cells of N. benthamiana. The analysis shows that NtCDKG;2 is present in the nucleoplasm and also co-localizes with nuclear speckles. In BY2 cell culture stably expressing GFP-NtCDKG;2, it was observed that NtCDKG;2 is at the achromatic spindle during metaphase and anaphase. Additionally, BiFC (Bimolecular Fluorescence Complementation) assays performed in this study have shown that the interaction of NtCDKG;2 and NtSCI1 occurs in the nucleolar periphery during interphase. Putative isoforms of NtCDKG;2 were also identified. The possible occurrence of these isoforms suggests that, in a similar way to its human homologue, NtCDKG;2 putative isoforms could act in different processes. To identify in which processes this protein could act, a search for NtCDKG;2 interaction partners was performed through the screening of a N. tabacum stigma and style cDNA library in the yeast two-hybrid (Y2H) system. Several partners identified through this assay have roles in RNA transcription and processing. Among the identified partners with interaction confirmed during this work, stands out the NtCDKF;1 protein, a CDK that phosphorylates the RNA polymerase II CTD, and thus, supports transcription and co-transcriptional splicing (HAJHEIDARI et al., 2012). This study also shows the interaction of NtCDKG;2 with NtCBP1, a protein which has an important role in the transcriptional regulation of genes encoding proteins mediating pollen tube growth (LI et al., 2015). Furthermore, the Y2H screening allowed the identification of the interaction of NtCDKG;2 with NtRanBP1, a key protein in the formation of the achromatic spindle which, in humans, interacts with the CDK11p46 isoform (MIKOLAJCZYK xxii et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011), a homologue of NtCDKG;2. In silico analysis of the amino acid sequence of NtCDKG;2 revealed motifs of predicted interaction with F-box proteins, cyclins, CDKs, phosphatases, 14-3-3s, BRCA1, and also pointed the region where the CDK-cyclin complex might interact with its respective inhibitor. The interaction of NtCDKG;2 with 14-3-3D, a known partner of NtSCI1, was tested and confirmed by Y2H. Another gap that needed to be filled is related to the regulation of NtSCI1 expression. To address this issue, in silico analysis to identify cis-regulatory elements was performed in NtSCI1 genomic region. These analyses revealed the presence of important cis-regulatory elements related to meristem identity (such as WUSCHEL and AINTEGUMENTA), carpel identity (AGAMOUS, BELL), and cell cycle progression (E2F and CDC5). Taken together results from this study and parallel studies performed in our laboratory, a few remarks can be made: 1) Taken the localization of NtCDKG;2 in splicing speckles, and its interaction with different proteins involved in transcription and splicing, it is suggested that NtCDKG;2 also has roles on these processes; 2) Considering the subcellular localization of NtCDKG;2 during the different cell cycle phases, the in silico analysis of this protein that predicts its interaction with BRCA1, and the confirmed interaction with NtRanBP1 protein, it is possible to suggest that NtCDKG;2 has a direct or indirect role in the organization of the achromatic spindle in plants; 3) It is proposed that NtSCI1 regulates cell proliferation in the pistil through its interaction with NtCDKG;2, which occurs in the nucleolus. Thus, NtSCI1 could hold NtCDKG;2 in the nucleolus, inhibiting its actions, such as in the organization of the achromatic spindle, resulting in cell division arrest. 4) Due to the cis-regulatory elements found in the genomic sequence of NtSCI1, and the effect of this protein since the initial stages of pistil development, it is suggested that its expression is regulated by elements directly involved in the control of the floral meristem termination and pathways of floral organ development.

BiFC

CDK

ciclo celular

fuso acromático

localização subcelular

SCI1

Y2H

achromatic spindle

BiFC

CDK

cell cycle

SCI1

subcellular localization

Y2H

Cdk2 as a model for studying evolutionary selection and therapeutic responses in proliferating cancer cells / Cdk2 : un modèle pour étudier la sélection évolutive ainsi que des réponses thérapeutiques dans des cellules cancéreuses en cours de prolifération

Bacevic, Katarina

15 January 2016

Les kinases cycline-dépendantes (CDK) sont des protéines régulatrices essentielles du cycle cellulaire. Elles contrôlent la prolifération cellulaire et sont souvent déréglées dans les cancers. De nombreux inhibiteurs de CDKs ont été élaborés et sont actuellement le sujet d'essais cliniques. Bien que Cdk1 soit un régulateur essentiel de cycle cellulaire, Cdk2 n’est pas nécessaire pour la progression du cycle cellulaire, mais favorise la tumorigenèse. Par conséquent, Cdk2 est une cible thérapeutique prometteuse. L’utilisation des inhibiteurs de kinases pour modifier la prolifération cellulaire s’apparente à appliquer une sélection Darwinienne. Cette sélection peut être modélisée mathématiquement. Cette approche a montré que des avantages sélectifs, mêmes marginaux, peuvent être d'une importance majeure dans la compétition inter-cellulaire et la progression du cancer. Selon ce principe, nous avons fait l’hypothèse que le fait que la Cdk2 ait un rôle mineur dans la progression du cycle cellulaire lui confèrerait le statut de cible pertinente pour une thérapie du cancer. Selon cette hypothèse, son inhibition serait bien tolérée, permettant de réduire le niveau d’activité CDK et ainsi agir contre la prolifération déréglée des cellules. Nous avons supposé qu’au lieu d’éliminer entièrement les cellules les plus prolifératives, qui seraient les plus sensibles au traitement, il serait potentiellement intéressant de les exploiter pour concurrencer l’émergence des cellules résistantes, moins prolifératives. L'utilisation d'un traitement continu à faible dose avec les inhibiteurs Cdk2 pourrait permettre de maintenir cet équilibre. L'objectif de la thèse était d'étudier si Cdk2 confère un avantage prolifératif aux cellules cancéreuses, si les cellules peuvent développer une résistance aux inhibiteurs de CDKs, et si oui, déterminer quels étaient les mécanismes de résistance qui permettent de réduire le « fitness » des cellules prolifératives. Pour répondre à ces questions, nous avons généré des lignées cellulaires ayant des degrés variés de résistance à un inhibiteur spécifique de Cdk2 (inhibant également Cdk1 à des concentrations élevées). Nous avons caractérisé leur capacité à proliférer en comparaison avec des cellules parentales et des cellules isogéniques n’exprimant plus Cdk2 en raison d’un « knock-out » du gène. Bien que dans ces premières cellules le gène Cdk2 est retrouvé non muté et que l'expression de la protéine Cdk2 reste inaltérée, l'activité kinase de Cdk2 est diminuée. Les cellules résistantes à l’inhibiteur prolifèrent efficacement in vitro. Cependant, lors des expériences de compétition avec les cellules parentales, sensibles aux inhibiteurs, elles sont perdantes. Ceci montre que le développement d’une résistance à un inhibiteur de kinase entraîne un désavantage sélectif. Malgré une prolifération normale en l’absence de compétiteurs, ce désavantage est mis en évidence dans une population mixte, validant ainsi l’hypothèse de départ. Nous avons constaté que les Cdk2 KO et les cellules résistantes à l’inhibiteur (R50) ont un métabolisme altéré. Ces cellules sont sensibles à l'épuisement des nutriments et du glucose ainsi qu’à l'hypoxie, malgré un taux de consommation d'oxygène normal, ce qui indique une augmentation de la glycolyse aérobique. Les cellules R50 surexpriment la protéine Cdk6, ce qui peut contribuer à la résistance à l'inhibition Cdk2. De plus elles sont sensibles à l’inhibition des Cdk4/6, cibles référencées dans le traitement de certaines classes de cancer du sein. Enfin, les cellules Cdk2 KO présentent un point de contrôle de la phase S perturbé. Ces résultats suggèrent que des inhibiteurs pharmacologiques ciblant Cdk2 pourraient être synergique avec d’autres traitements, par exemple l’inhibition concomitante de la réplication de l'ADN, de la glycolyse, ou de Cdk6. Cela pourrait ainsi diminuer la prolifération des cellules cancéreuses et empêcher l’émergence d'une résistance thérapeutique. / Cyclin-dependent kinases (Cdk) are essential regulators of the cell cycle that support cell proliferation and are often deregulated in cancer. While Cdk1 is an essential regulator of the cell cycle, Cdk2 is not required for cell cycle progression but promotes tumorigenesis. Therefore, Cdk2 is a promising drug target. Many Cdk inhibitors have been developed and are currently undergoing clinical trials. Darwinian selection can be modelled mathematically, and such studies have shown that even marginal selective advantages can be of great importance in outcomes of cell-cell competition and cancer progression. We hypothesised that the non-essential role of Cdk2 for cell cycle progression may mean that it is a good target for cancer therapy as continual inhibition should be tolerated and should counteract deregulated cell proliferation in cancer. However, as with all chemotherapeutic agents, the development of clinical resistance is likely. We further hypothesized that applying a low-dose treatment with Cdk2 inhibitors should minimize chances of developing resistance, by maintaining competition between robustly proliferating cells that are sensitive to treatment, and resistant cells.The aim of the thesis was to investigate whether Cdk2 confers a proliferative advantage to cancer cells, whether cells can develop resistance to Cdk inhibitors, and if so, whether the mechanisms allowing resistance reduce cellular proliferative fitness.To answer these questions, we have created cell lines with varying degrees of resistance to a selective Cdk2 inhibitor (that at high doses, also inhibits Cdk1) and have characterised their proliferation capacity in comparison with parental cells and isogenic Cdk2 knockout cells. Although in these cells the Cdk2 gene is not mutated and the expression of Cdk2 protein remained unaltered, the kinase activity of Cdk2 is decreased. Similarly, Cdk2 gene knockout (Cdk2 KO) cells have reduced sensitivity to Cdk2 inhibition. Inhibitor-resistant cells proliferate efficiently but are outcompeted by parental, inhibitor-sensitive cells in competition experiments, confirming that inhibitor resistance entails a selective disadvantage. We found that the proliferation of both Cdk2 knockout and inhibitor-resistant (R50) cells is sensitive to nutrient and glucose depletion as well as hypoxia, despite a normal oxygen consumption rate, indicating increased aerobic glycolysis. R50 cells have highly upregulated Cdk6, which may contribute to resistance to Cdk2 inhibition. Moreover, they are sensitised to Cdk4/6 inhibition, which is currently authorised as a treatment for some classes of breast cancer. Finally, Cdk2 knockout cells have an impaired S-phase checkpoint. These results suggest that pharmacological inhibitors targeting Cdk2 might be synthetically lethal with other treatments, eg inhibition of DNA replication, of glycolysis, or of Cdk6. This might diminish cancer cell proliferation and prevent emergence of therapeutic resistance.

Cdk2

Cible thérapeutique

Cancer

Inhibiteurs de Cdk

Cycle cellulaire

Évolution

Cdk2

Therapeutic target

Cancer

Cdk inhibitors

Cell cycle

Evolution