TKI sensitivity patterns of novel kinase-domain mutations suggest therapeutic opportunities for patients with resistant ALK+ tumors

Amin, Amit Dipak, Li, Lingxiao, Rajan, Soumya S., Gokhale, Vijay, Groysman, Matthew J., Pongtornpipat, Praechompoo, Tapia, Edgar O., Wang, Mengdie, Schatz, Jonathan H.

25 April 2016

The anaplastic lymphoma kinase (ALK) protein drives tumorigenesis in subsets of several tumors through chromosomal rearrangements that express and activate its C-terminal kinase domain. In addition, germline predisposition alleles and acquired mutations are found in the full-length protein in the pediatric tumor neuroblastoma. ALK-specific tyrosine kinase inhibitors (TKIs) have become important new drugs for ALK-driven lung cancer, but acquired resistance via multiple mechanisms including kinase-domain mutations eventually develops, limiting median progression-free survival to less than a year. Here we assess the impact of several kinase-domain mutations that arose during TKI resistance selections of ALK+ anaplastic large-cell lymphoma (ALCL) cell lines. These include novel variants with respect to ALK-fusion cancers, R1192P and T1151M, and with respect to ALCL, F1174L and I1171S. We assess the effects of these mutations on the activity of six clinical inhibitors in independent systems engineered to depend on either the ALCL fusion kinase NPM-ALK or the lung-cancer fusion kinase EML4-ALK. Our results inform treatment strategies with a likelihood of bypassing mutations when detected in resistant patient samples and highlight differences between the effects of particular mutations on the two ALK fusions.

anaplastic lymphoma kinase

drug resistance

crizotinib

ceritinib

alectinib

Neuroblastome, résistance in vivo à l'irinotecan et voie de signalisation ALK / Neuroblastoma, in vivo resistance to irinotecan and ALK signaling pathway

Bousseton, Munier

07 June 2012

Les neuroblastomes, même de haut risque répondent bien à la chimiothérapie initiale mais deviendront fréquemment résistants au traitement. Les inhibiteurs de topoisomérase I représentent un outil thérapeutique important dans la prise en charge des neuroblastomes réfractaires. Pour étudier la résistance aux inhibiteurs de topoisomérase I acquise dans un contexte thérapeutique, un modèle murin de neuroblastome résistant au CPT-11 a été développé. La chimiorésistance est connue comme un phénomène multifacoriel. Nous avons donc utilisé plusieurs approches pour mieux caractériser les mécanismes à l'origine de la résistance dans notre modèle. Une approche génomique a permis d'identifier la dérégulation de la voie de signalisation formée du récepteur ALK et de deux ligands PTN et MDK. Alors que ALK est décrit comme gène majeur de prédisposition au neuroblastome, principalement par le biais de mutations activatrices, nous avons démontré que l'activation du récepteur survenait par des mécanismes alternatifs aux mutations dans une large majorité de cas et participerait à l'initiation de la maladie. En revanche, nous n'avons pas pu prouver l'implication de ce récepteur dans la progression de la maladie ou dans sa réponse au traitement. Il semble que la régulation de ALK soit complexe et le rôle exact de ce récepteur dans la progression du neuroblastome reste à établir. En revanche, nous avons démontré l'importance du ligand MDK dans la régulation de l'expression et de l'activation de ALK ainsi que dans le contrôle de la survie des cellules neuroblastiques. Inhiber cette cytokine représente une stratégie thérapeutique intéressante, complémentaire des thérapies anti-ALK, actuellement en développement clinique dans le neuroblastome. D’autre part, la caractérisation phénotypique du modèle a permis de mettre en évidence une signalisation altérée des dommages à l'ADN associée à une instabilité génétique accrue dans les tumeurs résistantes. Celles-ci présentent également une modification de progression dans le cycle cellulaire et une proportion plus importante de cellules quiescentes. Au final, ce travail a permis d'identifier différents mécanismes de résistance qui représentent des marqueurs de réponse au traitement et des cibles thérapeutiques intéressantes dans le neuroblastome. / Neuroblastoma, including high-risk cases, show a good initial response to chemotherapy but will frequently become resistant to treatment. Topoisomerase I inhibitors represent an important therapeutic option for refractory neuroblastoma. To study the reisitance to topoisomerase I inhibitors acquired in a therapeutic setting, we developed in vivo a resistant model to irinotecan (CPT-11). Chemoresistance is known as a multifactorial phenomenon. We have therefore used several approaches to better characterize mechanisms leading to resistance in our model. A genomic approach enabled us to identify the deregulation of a signaling pathway, constituted with a receptor (ALK) and two lignads (PTN and MDK). While ALK is decsribed as a major neuroblastoma predisposition gene, mainly through activating mutations, we demonstrated that the activation of ALK occurs via mechanisms others than mutation in a large majority of cases. Moreover ALK activation is an important event in the initiation of the disease. However, we couldn’t prouve the implication of the receptor in the progression of the disease or in its response to treatment. It seems that the regulation of ALK is complex and its precise role in the progression of neuroblastoma remains to be precisely defined. Nevertheless, we have demonstrated the importance of MDK, one of ALK ligands in the regulation of the expression and activation of ALK as well as in the control of the neuroblastoma cells survival. The inhibition of the cytokine, MDK represents an interesting therapeutic strategy, complementary to anti-ALK therapies, currently in clinical development in neuroblastoma. On another hand, the phenotypic characterization of the model, showed an alteration of the signaling of DNA damage and an increased genomic instability in the resistant tumors. Those tumors also harbor a modification in the cell cycle progression, particularly an increased proportion of quiescent cells. Finally, this work enables us to identify several resistance mechanism that represent markers of response to chemotherapy and relevant therapeutic targets in neuroblastoma.

Neuroblastome

Résistance

Anaplastique Lymphoma Kinase

Neuroblastoma

Resistance

Anaplastic Lymphoma Kinase

Quantitative mikroskopische Analyse der Regulationsmechanismen der Anaplastic Lymphoma Kinase in Neuroblastomzellen / Quantitative microscopic analysis of the regulatory mechanisms of the anaplastic lymphoma kinase in neuroblastoma

Schumacher, Marten

13 January 2020

No description available.

610

Neuroblastom

ALK

Anaplastic Lymphoma Kinase

F1174

R1275

Y1604

I1250

neuroblastoma

ALK

anaplastic lymphoma kinase

F1174

I1250

R1275

Y1604

Medizin (PPN619874732)

Exploiting Drosophila as a model system for studying anaplastic lymphoma kinase in vivo

Eriksson, Therese

January 2010

Anaplastic Lymphoma Kinase (ALK) is a Receptor Tyrosine Kinase (RTK) and an oncogene associated with several human diseases, but its normal function in humans and other vertebrates is unclear. Drosophila melanogaster has an ALK homolog, demonstrating that the RTK has been conserved throughout evolution. This makes Drosophila a suitable model organism for studying not only Drosophila ALK function, but also to study mammalian forms of ALK. In Drosophila the ligand Jeb activates ALK, initiating signaling crucial for visceral mesoderm development. The activating ligand for mammalian ALK is unclear, and for this reason Drosophila was employed in a cross-species approach to investigate whether Drosophila Jeb can activate mouse ALK. Jeb is unable to activate mouse ALK, and therefore mouse ALK is unable to substitute for and rescue the Drosophila ALK mutant phenotype. This suggests that there has been significant evolution in the ALK-ligand relationship between the mouse and Drosophila. In humans ALK has recently been shown to be involved in the development of neuroblastoma, a cancer tumor in children. I have developed a Drosophila model for examining human gain of function ALK mutants found in neuroblastoma patients. The various ALK variants have acquired point mutations in the kinase domain that have been predicted to activate the RTK in a constitutive and ligand independent manner. When expressed in the fly eye, active human ALK mutants result in a rough eye phenotype, while inactive wild type ALK does not, due to the lack of an activating ligand in the fly. In this way  several of the ALK mutations identified in neuroblastoma patients could be confirmed to be activated in a ligand independent manner. Moreover, a novel ALK mutant; ALKF1174S, was discovered in a neuroblastoma patient and was in the Drosophila model shown to be a gain of function mutation, and a previously predicted gain of function mutation; ALKI1250T, was shown to be a kinase dead mutation. This fly model can also be used for testing ALK selective inhibitors, for identifying activating ligands for human ALK and for identifying conserved components of the ALK signaling pathway. Gut musculature development in Drosophila is dependent on ALK signaling, while somatic muscle development is not. Proteins of the Wasp-Scar signaling network regulate Arp2/3-complex mediated actin polymerization, and I have investigated their function in visceral and somatic muscle fusion. I found that Verprolin and other members of this protein family are essential for somatic but not visceral muscle development. Despite fusion defects in both tissues in Verprolin and other examined mutants, gut development proceeds, suggesting that fusion is not crucial for visceral mesoderm development. Hence the actin polymerization machinery functions in both somatic and visceral muscle fusion, but this process only appears to be essential in somatic muscle development. / Exploiting Drosophila as a model system for studying Anaplastic Lymphoma Kinase in vivo

Anaplastic lymphoma kinase

Receptor tyrosine kinase

Jeb

neuroblastoma

actin polymerization

Wasp

Scar

Vrp1

Arp2/3

Molecular biology

Molekylärbiologi

Anaplastic Lymphoma Kinase mutations and downstream signalling

Schönherr, Christina

January 2012

The oncogene Anaplastic Lymphoma Kinase (ALK) is a Receptor Tyrosine Kinase (RTK) and was initially discovered as the fusion protein NPM (nucleophosmin)-ALK in a subset of Anaplastic Large Cell Lymphomas (ALCL). Since then more fusion proteins have been identified in a variety of cancers. Further, overexpression of ALK due to gene amplification has been observed in many malignancies, amongst others neuroblastoma, a pediatric cancer. Lately, activating point mutations in the kinase domain of ALK have been described in neuroblastoma patients and neuroblastoma cell lines. In contrast, the physiological function of ALK is still unclear, but ALK is suggested to play a role in the normal development and function of the nervous system. By employing cell culture based approaches, including a tetracycline-inducible PC12 cell system and the in vivo D. melanogaster model system, we aimed to analyze the downstream signalling of ALK and its role in neuroblastoma. First, we wished to analyze whether ALK is able to activate the small GTPase Rap1 contributing to differentiation/proliferation processes. Activated ALK recruits a complex of the GEF C3G and CrkL and activates C3G by tyrosine phosphorylation. This activated complex is able to activate Rap1 resulting either in neurite outgrowth in PC12 cells or proliferation of neuroblastoma cells suggesting a potential role in the oncogenesis of neuroblastoma driven by gain-of-function mutant ALK. Next, we could show that seven investigated ALK mutations with a high probability of being oncogenic (G1128A, I1171N, F1174L, F1174S, R1192P, F1245C and R1275Q), are true gain-of-function mutations, respond differently to ALK inhibitors and have different transforming ability. Especially the F1174S mutation correlates with aggressive disease development. However, the assumed active germ line mutation I1250T is in fact a kinase dead mutation and suggested to act as a dominant-negative receptor. Finally, ALK mutations are most frequently observed in MYCN amplified tumours correlating with a poor clinical outcome. Active ALK regulates mainly the initiation of MYCN transcription in human neuroblastoma cell lines. Further, ALK gain-of-function mutants and MYCN synergize in transforming NIH3T3 cells. Overall, somatic mutations appear to be more aggressive than germ line mutations, implying a different impact on neuroblastoma. Further, successful application of ALK inhibitors suggests a promising future for the development of patient-specific treatments for neuroblastoma patients.

Anaplastic Lymphoma Kinase

oncogene

RTK

neuroblastoma

crizotinib

NVP-TAE684

gain-of-function

MYCN

transcription factor

small GTPase

Rap1

C3G

PC12 cells

neurite outgrowth

Μελέτη του ρόλου του αυξητικού παράγοντα HARP (Heparin Affin Regulatory Peptide) στην αγγειογένεση in vivo

Δρόσου, Γεωργία

21 April 2008

H HARP (heparin-affin regulatory peptide), γνωστή και ως πλειοτροπίνη (PTN), είναι ένας 18 kDa αυξητικός παράγοντας, ο οποίος έχει υψηλή συγγένεια για την ηπαρίνη. Η HARP έχει πολλαπλές βιολογικές δράσεις, όπως συμμετέχει στη ρύθμιση του κυτταρικού πολλαπλασιασμού, στη μετανάστευση και τη διαφοροποίηση. Επιπλέον η έκφραση της σχετίζεται με την φυσιολογική και καρκινική αγγειογένεση in vitro και in vivo. Στην παρούσα εργασία μελετήθηκε η έκφραση της HARP και των υποδοχέων της, ALK και RPTPβ/ζ, στις διάφορες ημέρες ανάπτυξης της CAM εμβρύου όρνιθας. Επίσης, μελετήθηκε η μείωση της έκφρασης της ενδογενούς HARP, με πλασμίδιο που φέρει την αντινοηματική αλληλουχία (AS-HARP), στην αγγειογένεση in vivo, στη φωσφορυλίωση των Εrk1,2 και στη λεμφαγγειογένεση της CAM εμβρύου όρνιθας. Ανάλυση κατά Western και RT-PCR στις διάφορες ημέρες ανάπτυξης του εμβρύου έδειξε ότι η έκφραση της HARP συμβαδίζει με τη δημιουργία νέων αγγείων στη CAM, ενώ η έκφραση των υποδοχέων της HARP στην CAM φαίνεται να είναι αυξημένη στα πρώτα στάδια ανάπτυξης του ιστού. Επίσης, η μείωση της έκφρασης της HARP μετά τη χορήγηση του πλασμιδίου AS-HARP, μείωσε τα επίπεδα της πρωτεΐνης, το μήκος των αγγείων και τη φωσφορυλίωση των Erk1/2 στο in vivo μοντέλο της CAM εμβρύου όρνιθας. Αντίθετα, η μείωση της έκφρασης της HARP μετά τη χορήγηση του πλασμιδίου AS-HARP, δεν επηρέασε τη λεμφαγγειογένεση της CAM εμβρύου όρνιθας. Σαν τελικό συμπέρασμα προκύπτει ότι η έκφραση της ενδογενούς HARP στην CAM εμβρύου όρνιθας είναι σημαντική για τη φυσιολογική αγγειογένεση in vivo. / Heparin-affin regulatory peptide (HARP), also known as pleiotrophin or heparin-binding growth-associated molecule, is an 18 kDa growth factor that has a high affinity for heparin. HARP is involved in the control of cellular proliferation, migration and differentiation. Moreover, there is a strong correlation between HARP expression and tumor growth and angiogenesis. In the present work, we studied the expression of HARP and its receptors, ALK and RPTPβ/ζ, during development of the chicken embryo chorioallantoic membrane (CAM), in relation to angiogenesis. By western blot analysis and RT-PCR, it was shown that HARP, ALK and RPTPβ/ζ expression increased at days of on-going angiogenesis and decreased at later time points. Transfection of CAMs with an anti-sense HARP gene construct led to a significant decrease in HARP amounts compared to vector control transfected CAMs, a significant decrease in the length of CAM blood vessels, and a decrease in the phosphorylation of Erk1/2. Contrary, transfection of CAMs with the anti-sense HARP gene construct had no influence in lymphangiogenesis of the chicken embryo chorioallantoic membrane (CAM). These data suggest that endogenous HARP is involved in angiogenesis in vivo.

612.13

Fibroblast growth factor

Anaplastic lymphoma kinase

Chorioallantoic membrane

Heparin Affin Regulatory Peptide

Vascular endothelial growth factor

Pleiotrophin

Prospero homeobox-1

Midkine