Search

Your search keyword '"Tadele, Dagim"' showing total 16 results
Start Over Author "Tadele, Dagim" Language english
16 results on '"Tadele, Dagim"'

1. Early response evaluation by single cell signaling profiling in acute myeloid leukemia

Author

Tislevoll, Benedicte Sjo, Hellesøy, Monica, Fagerholt, Oda Helen Eck, Gullaksen, Stein-Erik, Srivastava, Aashish, Birkeland, Even, Kleftogiannis, Dimitrios, Ayuda-Durán, Pilar, Piechaczyk, Laure, Tadele, Dagim Shiferaw, Skavland, Jørn, Baliakas, Panagotis, Hovland, Randi, Andresen, Vibeke, Seternes, Ole Morten, Tvedt, Tor Henrik Anderson, Aghaeepour, Nima, Gavasso, Sonia, Porkka, Kimmo, Jonassen, Inge, Fløisand, Yngvar, Enserink, Jorrit, Blaser, Nello, and Gjertsen, Bjørn Tore

Published
2023
Full Text
View/download PDF

2. Author Correction: Early response evaluation by single cell signaling profiling in acute myeloid leukemia

Author

Tislevoll, Benedicte Sjo, Hellesøy, Monica, Fagerholt, Oda Helen Eck, Gullaksen, Stein-Erik, Srivastava, Aashish, Birkeland, Even, Kleftogiannis, Dimitrios, Ayuda-Durán, Pilar, Piechaczyk, Laure, Tadele, Dagim Shiferaw, Skavland, Jørn, Baliakas, Panagotis, Hovland, Randi, Andresen, Vibeke, Seternes, Ole Morten, Tvedt, Tor Henrik Anderson, Aghaeepour, Nima, Gavasso, Sonia, Porkka, Kimmo, Jonassen, Inge, Fløisand, Yngvar, Enserink, Jorrit, Blaser, Nello, and Gjertsen, Bjørn Tore

Published
2023
Full Text
View/download PDF

7. Using birth-death processes to infer tumor subpopulation structure from live-cell imaging drug screening data.

Author

Wu, Chenyu, Gunnarsson, Einar Bjarki, Myklebust, Even Moa, Köhn-Luque, Alvaro, Tadele, Dagim Shiferaw, Enserink, Jorrit Martijn, Frigessi, Arnoldo, Foo, Jasmine, and Leder, Kevin

Subjects
DATA integrity, HIGH throughput screening (Drug development), ANTINEOPLASTIC agents, TUMORS, THERAPEUTICS
Abstract

Tumor heterogeneity is a complex and widely recognized trait that poses significant challenges in developing effective cancer therapies. In particular, many tumors harbor a variety of subpopulations with distinct therapeutic response characteristics. Characterizing this heterogeneity by determining the subpopulation structure within a tumor enables more precise and successful treatment strategies. In our prior work, we developed PhenoPop, a computational framework for unravelling the drug-response subpopulation structure within a tumor from bulk high-throughput drug screening data. However, the deterministic nature of the underlying models driving PhenoPop restricts the model fit and the information it can extract from the data. As an advancement, we propose a stochastic model based on the linear birth-death process to address this limitation. Our model can formulate a dynamic variance along the horizon of the experiment so that the model uses more information from the data to provide a more robust estimation. In addition, the newly proposed model can be readily adapted to situations where the experimental data exhibits a positive time correlation. We test our model on simulated data (in silico) and experimental data (in vitro), which supports our argument about its advantages. Author summary: One of the main reasons tumors can be difficult to treat is the presence of multiple subpopulations each with a distinct response to a given therapy. In particular some of these subpopulations are able to evade anti-cancer therapies and give rise to treatment resistant disease. Therefore it is vitally important to be able to identify these subpopulations and furthermore quantify their response to a therapy of interest, i.e., to quantify a tumors subpopulation structure. A potential tool for quantifying a tumors subpopulation structure are so called high-throughput drug screens (HTDS). In these screens a patients tumor sample is collected and then conditioned to grow in vitro where it can be exposed to a variety of drugs at different concentration levels. In the present work we develop statistical tools that create quantitative estimates of tumor population substructure based on HTDS data. These estimators have better precision than previous results, and furthermore are able to more accurately identify smaller subpopulations than previous estimators. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

8. Diverse mutant selection windows shape spatial heterogeneity in evolving populations.

Author

King, Eshan S., Tadele, Dagim S., Pierce, Beck, Hinczewski, Michael, and Scott, Jacob G.

Subjects
*TRANSMISSIBLE tumors, *GENOTYPE-environment interaction, *DRUG therapy, *DRUG resistance, *BIOLOGICAL fitness, *HERBICIDE resistance
Abstract

Mutant selection windows (MSWs), the range of drug concentrations that select for drug-resistant mutants, have long been used as a model for predicting drug resistance and designing optimal dosing strategies in infectious disease. The canonical MSW model offers comparisons between two subtypes at a time: drug-sensitive and drug-resistant. In contrast, the fitness landscape model with N alleles, which maps genotype to fitness, allows comparisons between N genotypes simultaneously, but does not encode continuous drug response data. In clinical settings, there may be a wide range of drug concentrations selecting for a variety of genotypes in both cancer and infectious diseases. Therefore, there is a need for a more robust model of the pathogen response to therapy to predict resistance and design new therapeutic approaches. Fitness seascapes, which model genotype-by-environment interactions, permit multiple MSW comparisons simultaneously by encoding genotype-specific dose-response data. By comparing dose-response curves, one can visualize the range of drug concentrations where one genotype is selected over another. In this work, we show how N-allele fitness seascapes allow for N * 2N−1 unique MSW comparisons. In spatial drug diffusion models, we demonstrate how fitness seascapes reveal spatially heterogeneous MSWs, extending the MSW model to more fully reflect the selection of drug resistant genotypes. Furthermore, using synthetic data and empirical dose-response data in cancer, we find that the spatial structure of MSWs shapes the evolution of drug resistance in an agent-based model. By simulating a tumor treated with cyclic drug therapy, we find that mutant selection windows introduced by drug diffusion promote the proliferation of drug resistant cells. Our work highlights the importance and utility of considering dose-dependent fitness seascapes in evolutionary medicine. Author summary: Drug resistance in infectious disease and cancer is a major driver of mortality. While undergoing treatment, the population of cells in a tumor or infection may evolve the ability to grow despite the use of previously effective drugs. Researchers hypothesize that the spatial organization of these disease populations may contribute to drug resistance. In this work, we analyze how spatial gradients of drug concentration impact the evolution of drug resistance. We consider a decades-old model called the mutant selection window (MSW), which describes the drug concentration range that selects for drug-resistant cells. We show how extending this model with continuous dose-response data, which describes how different types of cells respond to drug, improves the ability of MSWs to predict evolution. This work helps us understand how the spatial organization of cells, such as the organization of blood vessels within a tumor, may promote drug resistance. In the future, we may use these methods to optimize drug dosing to prevent resistance or leverage known vulnerabilities of drug-resistant cells. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

9. A cell competition-based small molecule screen identifies a novel compound that induces dual c-Myc depletion and p53 activation.

Author

Tadele, Dagim Shiferaw, Robertson, Joseph, Crispin, Richard, Herrera, Maria C., Chlubnová, Markéta, Piechaczyk, Laure, Ayuda-Durán, Pilar, Singh, Sachin Kumar, Gedde-Dahl, Tobias, Fløisand, Yngvar, Skavland, Jørn, Wesche, Jørgen, Gjertsen, Bjørn-Tore, and Enserink, Jorrit M.

Subjects
*SMALL molecules, *DNA topoisomerase II, *PROTEIN-tyrosine kinase inhibitors, *CHRONIC myeloid leukemia, *DNA topoisomerase I, *HEMATOPOIETIC stem cells, *P53 protein
Abstract

Breakpoint Cluster Region-Abelson kinase (BCR-Abl) is a driver oncogene that causes chronic myeloid leukemia and a subset of acute lymphoid leukemias. Although tyrosine kinase inhibitors provide an effective treatment for these diseases, they generally do not kill leukemic stem cells (LSCs), the cancer-initiating cells that compete with normal hematopoietic stem cells for the bone marrow niche. New strategies to target cancers driven by BCR-Abl are therefore urgently needed. We performed a small molecule screen based on competition between isogenic untransformed cells and BCR-Abl-transformed cells and identified several compounds that selectively impair the fitness of BCR-Abl-transformed cells. Interestingly, systems-level analysis of one of these novel compounds, DJ34, revealed that it induced depletion of c-Myc and activation of p53. DJ34-mediated c-Myc depletion occurred in a wide range of tumor cell types, including lymphoma, lung, glioblastoma, breast cancer, and several forms of leukemia, with primary LSCs being particularly sensitive to DJ34. Further analyses revealed that DJ34 interferes with c-Myc synthesis at the level of transcription, and we provide data showing that DJ34 is a DNA intercalator and topoisomerase II inhibitor. Physiologically, DJ34 induced apoptosis, cell cycle arrest, and cell differentiation. Taken together, we have identified a novel compound that dually targets c-Myc and p53 in a wide variety of cancers, and with particularly strong activity against LSCs. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

11. Drug-screening and genomic analyses of HER2-positive breast cancer cell lines reveal predictors for treatment response.

Author

Jernström, Sandra, Hongisto, Vesa, Leivonen, Suvi-Katri, Due, Eldri Undlien, Tadele, Dagim Shiferaw, Edgren, Henrik, Kallioniemi, Olli, Perälä, Merja, Mælandsmo, Gunhild Mari, and Sahlberg, Kristine Kleivi

Subjects
BREAST cancer treatment, GENETICS of breast cancer, BREAST cancer prognosis, HER2 gene, GENOMICS, DRUG use testing
Abstract

Background: Approximately 15%-20% of all diagnosed breast cancers are characterized by amplified and overexpressed HER2 (= ErbB2). These breast cancers are aggressive and have a poor prognosis. Although improvements in treatment have been achieved after the introduction of trastuzumab and lapatinib, many patients do not benefit from these drugs. Therefore, in-depth understanding of the mechanisms behind the treatment responses is essential to find alternative therapeutic strategies. Materials and methods: Thirteen HER2 positive breast cancer cell lines were screened with 22 commercially available compounds, mainly targeting proteins in the ErbB2-signaling pathway, and molecular mechanisms related to treatment sensitivity were sought. Cell viability was measured, and treatment responses between the cell lines were compared. To search for response predictors and genomic and transcriptomic profiling, PIK3CA mutations and PTEN status were explored and molecular features associated with drug sensitivity sought. Results: The cell lines were divided into three groups according to the growth-retarding effect induced by trastuzumab and lapatinib. Interestingly, two cell lines insensitive to trastuzumab (KPL4 and SUM190PT) showed sensitivity to an Akt1/2 kinase inhibitor. These cell lines had mutation in PIK3CA and loss of PTEN, suggesting an activated and druggable Akt-signaling pathway. Expression levels of five genes (CDC42, MAPK8, PLCG1, PTK6, and PAK6) were suggested as predictors for the Akt1/2 kinase-inhibitor response. Conclusion: Targeting the Akt-signaling pathway shows promise in cell lines that do not respond to trastuzumab. In addition, our results indicate that several molecular features determine the growth-retarding effects induced by the drugs, suggesting that parameters other than HER2 amplification/expression should be included as markers for therapy decisions. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

12. The balance between intrinsic and ecological fitness defines new regimes in eco-evolutionary population dynamics.

Author

Barker-Clarke RJ, Gray JM, Strobl MAR, Tadele DS, Maltas J, Hinczewski M, and Scott JG

Abstract

Selection upon intrinsic fitness differences is one of the most basic mechanisms of evolution, fundamental to all biology. Equally, within macroscopic populations and microscopic environments, ecological interactions influence evolution. Direct experimental evidence of ecological selection between microscopic agents continues to grow. Whilst eco-evolutionary dynamics describes how interactions influence population fitness and composition, we build a model that allows ecological aspects of these interactions to fall on a spectrum independent of the intrinsic fitness of the population. With our mathematical framework, we show how ecological interactions between mutating populations modify the estimated evolutionary trajectories expected from monoculture fitnesses alone. We derive and validate analytical stationary solutions to our partial differential equations that depend on intrinsic and ecological terms, and mutation rates. We determine cases in which these interactions modify evolution in such ways as to, for example, maintain or invert existing monoculture fitness differences. This work discusses the importance of understanding ecological and intrinsic selection effects to avoid misleading conclusions from experiments and defines new ways to assess this balance from experimental results. Using published experimental data, we also show evidence that real microbiological systems can span intrinsic fitness dominant and ecological-effect dominant regimes and that ecological contributions can change with an environment to exaggerate or counteract the composite populations' intrinsic fitness differences.

Published
2024
Full Text
View/download PDF

13. Frequency-dependent ecological interactions increase the prevalence, and shape the distribution, of pre-existing drug resistance.

Author

Maltas J, Tadele DS, Durmaz A, McFarland CD, Hinczewski M, and Scott JG

Abstract

The evolution of resistance remains one of the primary challenges for modern medicine from infectious diseases to cancers. Many of these resistance-conferring mutations often carry a substantial fitness cost in the absence of treatment. As a result, we would expect these mutants to undergo purifying selection and be rapidly driven to extinction. Nevertheless, pre-existing resistance is frequently observed from drug-resistant malaria to targeted cancer therapies in non-small cell lung cancer (NSCLC) and melanoma. Solutions to this apparent paradox have taken several forms from spatial rescue to simple mutation supply arguments. Recently, in an evolved resistant NSCLC cell line, we found that frequency-dependent ecological interactions between ancestor and resistant mutant ameliorate the cost of resistance in the absence of treatment. Here, we hypothesize that frequency-dependent ecological interactions in general play a major role in the prevalence of pre-existing resistance. We combine numerical simulations with robust analytical approximations to provide a rigorous mathematical framework for studying the effects of frequency-dependent ecological interactions on the evolutionary dynamics of pre-existing resistance. First, we find that ecological interactions significantly expand the parameter regime under which we expect to observe pre-existing resistance. Next, even when positive ecological interactions between mutants and ancestors are rare, these resistant clones provide the primary mode of evolved resistance because even weak positive interaction leads to significantly longer extinction times. We then find that even in the case where mutation supply alone is sufficient to predict pre-existing resistance, frequency-dependent ecological forces still contribute a strong evolutionary pressure that selects for increasingly positive ecological effects (negative frequency-dependent selection). Finally, we genetically engineer several of the most common clinically observed resistance mechanisms to targeted therapies in NSCLC, a treatment notorious for pre-existing resistance. We find that each engineered mutant displays a positive ecological interaction with their ancestor. As a whole, these results suggest that frequency-dependent ecological effects can play a crucial role in shaping the evolutionary dynamics of pre-existing resistance.

Published
2024
Full Text
View/download PDF

15. GRP94 rewires and buffers the FLT3-ITD signaling network and promotes survival of acute myeloid leukemic stem cells.

Author

Zhang B, Durán PA, Piechaczyk L, Fløisand Y, Safont MMS, Karlsen IT, Fandalyuk Z, Tadele D, Mierlo PV, Rowe AD, Robertson JM, Gjertsen BT, McCormack E, and Enserink JM

Abstract

Internal tandem duplications in the tyrosine kinase receptor FLT3 (FLT3-ITD) are among the most common lesions in acute myeloid leukemia and there exists a need for new forms of treatment. Using ex vivo drug sensitivity screening, we found that FLT3-ITD+ patient cells are particularly sensitive to HSP90 inhibitors. While it is well known that HSP90 is important for FLT3-ITD stability, we found that HSP90 family members play a much more complex role in FLT3-ITD signaling than previously appreciated. First, we found that FLT3-ITD activates the unfolded protein response, leading to increased expression of GRP94/HSP90B1. This results in activation of a nefarious feedback loop, in which GRP94 rewires FLT3-ITD signaling by binding and retaining FLT3-ITD in the endoplasmic reticulum, leading to aberrant activation of downstream signaling pathways and further inducing the unfolded protein response. Second, HSP90 family proteins protect FLT3-ITD+ acute myeloid leukemia cells against apoptosis by alleviating proteotoxic stress, and treatment with HSP90 inhibitors results in proteotoxic overload that triggers unfolded protein response-induced apoptosis. Importantly, leukemic stem cells are strongly dependent upon HSP90 for their survival, and the HSP90 inhibitor ganetespib causes leukemic stem cell exhaustion in patient-derived mouse xenograft models. Taken together, our study reveals a molecular basis for HSP90 addiction of FLT3-ITD+ acute myeloid leukemia cells and provides a rationale for including HSP90 inhibitors in the treatment regime for FLT3-ITD+ acute myeloid leukemia., (Copyright © 2018, Ferrata Storti Foundation.)

Published
2018
Full Text
View/download PDF

16. Drug-screening and genomic analyses of HER2-positive breast cancer cell lines reveal predictors for treatment response.

Author

Jernström S, Hongisto V, Leivonen SK, Due EU, Tadele DS, Edgren H, Kallioniemi O, Perälä M, Mælandsmo GM, and Sahlberg KK

Abstract

Background: Approximately 15%-20% of all diagnosed breast cancers are characterized by amplified and overexpressed HER2 (= ErbB2). These breast cancers are aggressive and have a poor prognosis. Although improvements in treatment have been achieved after the introduction of trastuzumab and lapatinib, many patients do not benefit from these drugs. Therefore, in-depth understanding of the mechanisms behind the treatment responses is essential to find alternative therapeutic strategies., Materials and Methods: Thirteen HER2 positive breast cancer cell lines were screened with 22 commercially available compounds, mainly targeting proteins in the ErbB2-signaling pathway, and molecular mechanisms related to treatment sensitivity were sought. Cell viability was measured, and treatment responses between the cell lines were compared. To search for response predictors and genomic and transcriptomic profiling, PIK3CA mutations and PTEN status were explored and molecular features associated with drug sensitivity sought., Results: The cell lines were divided into three groups according to the growth-retarding effect induced by trastuzumab and lapatinib. Interestingly, two cell lines insensitive to trastuzumab (KPL4 and SUM190PT) showed sensitivity to an Akt1/2 kinase inhibitor. These cell lines had mutation in PIK3CA and loss of PTEN , suggesting an activated and druggable Akt-signaling pathway. Expression levels of five genes ( CDC42 , MAPK8 , PLCG1 , PTK6 , and PAK6 ) were suggested as predictors for the Akt1/2 kinase-inhibitor response., Conclusion: Targeting the Akt-signaling pathway shows promise in cell lines that do not respond to trastuzumab. In addition, our results indicate that several molecular features determine the growth-retarding effects induced by the drugs, suggesting that parameters other than HER2 amplification/expression should be included as markers for therapy decisions., Competing Interests: Disclosure The authors report no conflicts of interest in this work.

Published
2017
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results