Quiescent Tumor Cells Research Articles

Targeting Dormant Disseminated Tumor Cells and their Permissive Niche by Pro-Resolving Mediators Derived from Resolution-Phase Macrophages.

Metastatic breast cancer (BC) can recur years after initial treatments and arise from quiescent disseminated tumor cells (QDTC) that resist conventional therapies. To date there are no treatments to target QDTCs. Previously, the fibrotic-like niche (FLN) enriched with Type I collagen (Col-I) was shown to be required for the switch of QDTC to overt metastases. Here, we examined whether artificially reinstating resolution of inflammation, by using soluble mediators secreted by ex-vivo generated pro-resolving macrophages (CM-Mres), will prevent FLN establishment and in turn hinder QDTC outgrowth. Our findings indicate that CM-Mres promoted immune silencing at the metastatic site as part of the resolution process and inhibited the FLN resulting in the inhibition of the metastatic outgrowth in vitro and in vivo. This was due to inhibition of fibroblasts to myofibroblasts differentiation independent of TGFβ1 canonical signaling and the abolishment of Col-I expression. Furthermore, CM-Mres eliminated myofibroblasts as part of the resolution process by inducing an increase in reactive oxygen species (ROS) via NADPH oxidase leading to DNA damage and apoptosis. Moreover, ROS-mediated apoptosis was also induced by CM-Mres in the dormant and outgrowing DTCs. Overall, our findings suggest for the first time that pro-resolving mediators can target both QDTCs and their permissive niche thus preventing BC from recurring. SIGNIFICANCE: Since conventional therapies fail to eradicate QDTCs. Future identification of the pro-resolving mediators secreted by pro-resolving macrophages may serve as a basis for novel therapeutic strategies targeting QDTCs and their metastatic niche.

EPCO-02. HIGH CELLULAR PLASTICITY STATE OF HUMAN MEDULLOBLASTOMA LOCAL RECURRENCE AND DISTANT DISSEMINATION

Abstract Medulloblastoma (MB) is a heterogeneous pediatric brain tumor with variable clinical outcomes. Since current treatments facing limitations due to tumor resistance, less than 10% of relapsed patients survive beyond five years, with poorly understood recurrence mechanisms. To obtain cellular diversity and genetic characters in primary and recurrent MB, we conducted comprehensive analyses utilizing the single-cell/nucleus RNA sequencing (sc/snRNA-seq), snATAC-seq and spatial transcriptomics, complemented with bulk RNA sequencing and matched primary-recurrent whole exon profiles. SHH and Group_3 subgroups revealed distinct cellular subsets, including cycling, differentiated and quiescent tumor cells. Recurrent or disseminated MB displayed a dramatically different cellular ecosystem compared to primary tumors, with varying proportions of shared cell types. Local recurrence exhibited a higher enrichment of cycling tumor cells, while differentiated subset was notably present in disseminated lesions, indicating that local recurrences harbored the stronger proliferative capacity, whereas disseminations relatively well differentiated. Additionally, chromosomal alterations were assessed, reflecting distinct genetic subclones, such as chr7q gain and chr11 loss in Group_3 disseminations. Notably, the emergence of a subpopulation termed “high cellular plasticity (HCP)” during MB progression was noted, characterized by dynamic adaptability and stemness properties. As validated, HCP state was associated with increased chromatin accessibility, contributing to tumor recurrence and immune microenvironment remodeling. Functionally, inhibiting markers associated with HCP cells, such as PTPRZ1, efficiently suppressed MB metastasis in preclinical models. In conclusion, our findings fill the critical knowledge gaps in understanding the cellular diversity, chromosomal alterations and biological dynamics in MB recurrence and dissemination, offering potential therapeutic interventions.

Abstract 704: Targeting hypoxic survival pathways to overcome radiotherapy-related treatment resistance

Abstract Tumor cells undergo biological adaptations in order to survive stress conditions, such as hypoxia and nutrient deprivation. These biological adaptations include the activation of hypoxic survival pathways that play an important role in acquiring radioresistance which becomes most challenging with treatment regimens using high doses of radiation/fraction (e.g., hypofractionated radiotherapy). Therefore, inhibiting key regulators within these pathways and thereby exploiting these survival mechanisms, gives rise to new potential drug targets for combined treatment modalities. This novel strategy investigated in our laboratory relies on the concept of biological cooperation: while ionizing radiation kills primarily well-oxygenated cells, such inhibitors of survival kinases will drive quiescent tumor cells under hypoxia and/or nutrient deprivation either directly into cell death or into re-entry into a proliferative and thereby more ionizing radiation-sensitive state. One of the survival kinases we are investigating in combination with ionizing radiation (IR) is DYRK1B (dual-specificity tyrosine regulated kinase 1B). We demonstrated that the expression of DYRK1B was upregulated under serum-starvation and hypoxia, but not in response to IR. The small molecule DYRK1B inhibitor AZ191 and shRNA-mediated DYRK1B knockdown significantly reduced proliferative activity and clonogenicity of SW620 tumor cells alone and in combination with IR under serum-starved conditions, which correlated with increased ROS levels and DNA damage. Furthermore, AZ191 successfully targeted the hypoxic core of tumor spheroids while IR preferentially targeted normoxic cells in the rim of the spheroids. A combined treatment effect was also observed in patient-derived colorectal carcinoma organoids but not in healthy tissue organoids. This data shows that inhibition of DYRK1B in quiescent tumor cells could drive tumor cells on their own into crisis or into a more radiosensitive cell cycle phase and thus supports our strategy of biological cooperation. In the continuation of this project, we have performed a drug-screen with approx. 3’000 clinically relevant compounds in colorectal tumor cells lines under normoxic and hypoxic conditions in order to explore additional hypoxia-mediated survival pathways contributing to radioresistance. Thereby we aim to identify novel combined treatment modalities to overcome radiotherapy-induced hypoxia and hypoxia-related resistance mechanisms. Citation Format: Claire Beckers, Lazaros Vasilikos, Alba Sanchez-Fernandez, Lorena Moor, Martin Pruschy. Targeting hypoxic survival pathways to overcome radiotherapy-related treatment resistance [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 704.

Abstract A074: Targeting dormant disseminated tumor cells and their permissive niche by pro-resolving mediators derived from resolution-phase macrophages

Abstract Metastatic breast cancer can recur years after primary tumor resection and adjuvant therapy and appears to arise from quiescent disseminated tumor cells (QDTC) that persist at distant sites and resist conventional therapies. To date there are no treatments to target QDTCs. Previously, the fibrotic-like microenvironment enriched with Type I collagen (Col-I) was shown to be required for the switch of QDTC to metastatic outgrowth in lungs of mice. Here, we examined whether soluble mediators secreted by ex-vivo generated pro-resolving CD11blow macrophages (CM-Mres) will reinstate resolution of inflammation thus inhibiting the establishment of the fibrotic-like-niche and in turn prevent the emergence of QDTC to metastatic outgrowth. Our findings indicate that CM-Mres promoted immune silencing of alveolar macrophages at the metastatic site where dormant DTCs reside. Immune silencing is one of the hallmarks of resolution of inflammation. Furthermore, CM-Mres inhibited the establishment of a fibrotic-like niche resulting in the inhibition of the metastatic outgrowth in vitro and in vivo. This was due to inhibition of fibroblasts differentiation to myofibroblasts independent of TGFbeta1 canonical signaling and abolishment of Col-I expression. Furthermore, CM-Mres deactivated myofibroblasts as part of the resolution process by inducing an increase in reactive oxygen species (ROS) via activation of NADPH oxidase. This in turn induced DNA damage leading to Go/G1 arrest and intrinsic apoptosis. Similarly, apoptosis mediated by oxidative stress was induced by CM-Mres in dormant and outbreaking QDTCs. Taken together our results demonstrate for the first time that by reinstating resolution of inflammation via physiological mediators, secreted by pro-resolving macrophages, can prevent metastatic outgrowth of QDTCs at their permissive site. Since conventional therapies fail to eradicate dormant DTCs and their transition to clinical metastasis, our findings hold great promise in the quest to identify novel strategies to prevent or treat recurrent metastatic disease. Citation Format: Odelya Gilon, Keren Weidenfeld, Hadell Samara, Yonatan Feuermann, Sagie Schif-Zuck, Sergei Butenko, Edmond Sabo, Amiram Ariel, Dalit Barkan. Targeting dormant disseminated tumor cells and their permissive niche by pro-resolving mediators derived from resolution-phase macrophages [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Breast Cancer Research; 2023 Oct 19-22; San Diego, California. Philadelphia (PA): AACR; Cancer Res 2024;84(3 Suppl_1):Abstract nr A074.

The emerging role of osteoclasts in the treatment of bone metastases: rationale and recent clinical evidence.

The occurrence of bone metastasis is a grave medical concern that substantially impacts the quality of life in patients with cancer. The precise mechanisms underlying bone metastasis remain unclear despite extensive research efforts, and efficacious therapeutic interventions are currently lacking. The ability of osteoclasts to degrade the bone matrix makes them a crucial factor in the development of bone metastasis. Osteoclasts are implicated in several aspects of bone metastasis, encompassing the formation of premetastatic microenvironment, suppression of the immune system, and reactivation of quiescent tumor cells. Contemporary clinical interventions targeting osteoclasts have proven effective in mitigating bone-related symptoms in patients with cancer. This review comprehensively analyzes the mechanistic involvement of osteoclasts in bone metastasis, delineates potential therapeutic targets associated with osteoclasts, and explores clinical evidence regarding interventions targeting osteoclasts.

Identification of ATF3 as a novel protective signature of quiescent colorectal tumor cells

Colorectal cancer (CRC) is the third most common cancer and the second leading cause of death in the world. In most cases, drug resistance and tumor recurrence are ultimately inevitable. One obstacle is the presence of chemotherapy-insensitive quiescent cancer cells (QCCs). Identification of unique features of QCCs may facilitate the development of new targeted therapeutic strategies to eliminate tumor cells and thereby delay tumor recurrence. Here, using single-cell RNA sequencing, we classified proliferating and quiescent cancer cell populations in the human colorectal cancer spheroid model and identified ATF3 as a novel signature of QCCs that could support cells living in a metabolically restricted microenvironment. RNA velocity further showed a shift from the QCC group to the PCC group indicating the regenerative capacity of the QCCs. Our further results of epigenetic analysis, STING analysis, and evaluation of TCGA COAD datasets build a conclusion that ATF3 can interact with DDIT4 and TRIB3 at the transcriptional level. In addition, decreasing the expression level of ATF3 could enhance the efficacy of 5-FU on CRC MCTS models. In conclusion, ATF3 was identified as a novel marker of QCCs, and combining conventional drugs targeting PCCs with an option to target QCCs by reducing ATF3 expression levels may be a promising strategy for more efficient removal of tumor cells.

Metastasis Unleashed: Hyposialylation Empowers Chemo-Evasive Circulating Tumor Cell Clusters in Breast Cancer.

Therapy resistance is frequently observed in cancer patients with distant metastases and effective management of metastatic disease remains challenging. Unraveling the cellular mechanisms and molecular targets fueling metastatic spread is crucial for advancing cancer therapies. In a recent issue of Cancer Discovery, Dashzeveg and colleagues revealed that loss of terminal sialylation in glycoproteins within circulating tumor cell clusters is a dynamic process that contributes to cellular dormancy, facilitates evasion of chemotherapy, and enhances metastatic seeding. Furthermore, the study identifies the glycoprotein podocalyxin (PODXL) as a potential target for counteracting the metastasis of quiescent tumor cells associated with paclitaxel treatment in triple-negative breast cancer.

Dynamic Glycoprotein Hyposialylation Promotes Chemotherapy Evasion and Metastatic Seeding of Quiescent Circulating Tumor Cell Clusters in Breast Cancer.

This study discovers that dynamic loss of terminal sialylation in glycoproteins of CTC clusters contributes to the fate of cellular dormancy, advantageous evasion to chemotherapy, and enhanced metastatic seeding. It identifies PODXL as a glycoprotein substrate of ST6GAL1 and a candidate target to counter chemoevasion-associated metastasis of quiescent tumor cells. This article is featured in Selected Articles from This Issue, p. 1949.

Computational Modeling to Determine the Effect of Phenotypic Heterogeneity in Tumors on the Collective Tumor–Immune Interactions

Tumor immunotherapy aims to maintain or enhance the killing capability of CD8+ T cells to clear tumor cells. The tumor-immune interactions affect the function of CD8+ T cells. However, the effect of phenotype heterogeneity of a tumor mass on the collective tumor-immune interactions is insufficiently investigated. We developed the cellular-level computational model based on the principle of cellular Potts model to solve the case mentioned above. We considered how asymmetric division and glucose distribution jointly regulated the transient changes in the proportion of proliferating/quiescent tumor cells in a solid tumor mass. The evolution of a tumor mass in contact with T cells was explored and validated by comparing it with previous studies. Our modeling exhibited that proliferating/quiescent tumor cells, exhibiting distinct anti-apoptotic and suppressive behaviors, redistributed within the domain accompanied by the evolution of a tumor mass. Collectively, a tumor mass prone to a quiescent state weakened the collective suppressive functions of a tumor mass on cytotoxic T cells and triggered a decline of apoptosis of tumor cells. Although quiescent tumor cells did not sufficiently do their inhibitory functions, the possibility of long-term survival was improved due to their interior location within a mass. Overall, the proposed model provides a useful framework to investigate collective-targeted strategies for improving the efficiency of immunotherapy.

Abstract 5947: Tumor cells escape cell death after radiotherapy by senescence - a mechanism that can be counteracted with zinc oxide nanoparticles

Abstract Radiotherapy is still an important pillar for the therapy of head and neck squamous cell carcinoma (HNSCC); however, local recurrences arise in 15-50% of patients. During radiotherapy, there is a risk that individual tumor cells survive and proliferate again after a period of dormancy. Growing evidence suggests that senescence may play a key role in this context. We investigated in vitro radiotherapy-induced senescence and found that quiescent tumor cells survived treatment with 16 Gy. Those cells exhibited characteristics of senescence, yet were able to regain their proliferative capacity, and senescence was associated with radioresistance. During radiotherapy, the cells of the tumor stroma are inevitably irradiated as well. It is already known that cancer-associated fibroblasts (CAFs) can promote tumor progression. However, their contribution to the survival of senescent tumor cells after radiotherapy is unknown so far. Furthermore, the association between radiotherapy-induced senescence and recurrences raises the question of how residual, senescent tumor cells can be eliminated to prevent the development of a recurrence at an early stage. These aspects were the subject of the study presented here. To study the interaction between tumor cells and CAFs during their response to irradiation, both cell types were irradiated with 16 Gy in vitro individually and in co-culture. Subsequently, proliferation, cell death, morphological characteristics, and the secretome were analyzed. Additionally, we investigated whether senescent tumor cells can be targeted by treatment with zinc oxide nanoparticles. We could show that not only the tumor cells but also the CAFs go into a senescent state in response to irradiation, seen by loss of proliferation, increased senescence-associated β-galactosidase activity, and typical morphological characteristics. The secretome analysis revealed that the co-culture of tumor cells with CAFs significantly altered the repertoire of cytokines released upon irradiation, indicating intense communication between the cell types during their response to irradiation. Therefore, it is important for future studies on radiotherapy-induced senescence to include the tumor stroma as well. Finally, we demonstrated that senescent tumor cells were vulnerable to cell death induced by treatment with zinc oxide nanoparticles, which thus could potentially contribute to eliminating residual tumor cells after radiotherapy. This study revealed that radiotherapy-induced senescence in tumor cells and associated fibroblasts could well be a therapeutic problem, as senescent tumor cells are not targetable by radiotherapy anymore. In the future, zinc oxide nanoparticles may help to counteract this escape mechanism to prevent recurrences. Citation Format: Nadine Wiesmann, Rita Gieringer, Johannes Kupka, Jonas Eckrich, Sebahat Kaya, Peer Kaemmerer, Bilal Al-Nawas, Juergen Brieger. Tumor cells escape cell death after radiotherapy by senescence - a mechanism that can be counteracted with zinc oxide nanoparticles [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5947.

The impact of TP53 status of tumor cells including the type and the concentration of administered 10B delivery agents on compound biological effectiveness in boron neutron capture therapy.

Human head and neck squamous cell carcinoma cells transfected with mutant TP53 (SAS/mp53) or neo vector (SAS/neo) were inoculated subcutaneously into left hind legs of nude mice. After the subcutaneous administration of a 10B-carrier, boronophenylalanine-10B (BPA) or sodium mercaptododecaborate-10B (BSH), at two separate concentrations, the 10B concentrations in tumors were measured using γ-ray spectrometry. The tumor-bearing mice received 5-bromo-2'-deoxyuridine (BrdU) continuously to label all intratumor proliferating (P) tumor cells, then were administered with BPA or BSH. Subsequently, the tumors were irradiated with reactor neutron beams during the time of which 10B concentrations were kept at levels similar to each other. Following irradiation, cells from some tumors were isolated and incubated with a cytokinesis blocker. The responses of BrdU-unlabeled quiescent (Q) and total (= P + Q) tumor cells were assessed based on the frequencies of micronucleation using immunofluorescence staining for BrdU. In both SAS/neo and SAS/mp53 tumors, the compound biological effectiveness (CBE) values were higher in Q cells and in the use of BPA than total cells and BSH, respectively. The higher the administered concentrations were, the smaller the CBE values became, with a clearer tendency in SAS/neo tumors and the use of BPA than in SAS/mp53 tumors and BSH, respectively. The values for BPA that delivers into solid tumors more dependently on uptake capacity of tumor cells than BSH became more alterable. Tumor micro-environmental heterogeneity might partially influence on the CBE value. The CBE value can be regarded as one of the indices showing the level of intratumor heterogeneity.

STEM-27. MECHANOSENSITIVE BRAIN TUMOR CELLS CONSTRUCT BLOOD-TUMOR BARRIER TO MASK CHEMOSENSITIVITY

Abstract Two major obstacles in brain cancer treatment are the blood-tumor barrier (BTB) and quiescent tumor cells. Here we show that Sox2+ tumor cells directly project cellular processes to ensheathe capillaries in medulloblastoma (MB), a process that depends on the mechanosensitive ion channel Piezo2. MB develops a tissue stiffness gradient as a function of distance to capillaries. Sox2+ tumor cells perceive substrate stiffness to sustain local intracellular calcium, actomyosin tension, and adhesion to promote cellular process growth and cell surface sequestration of β-Catenin. Piezo2 knockout reverses WNT/β-Catenin signaling states between Sox2+ tumor cells and endothelial cells, compromises the BTB, reduces the quiescence of Sox2+ tumor cells, and markedly enhances MB response to chemotherapy. Our study reveals that mechanosensitive tumor cells construct the BTB to mask tumor chemosensitivity. Targeting Piezo2 addresses the BTB and tumor quiescence properties that underlie therapy failures in brain cancer.

Mechanosensitive brain tumor cells construct blood-tumor barrier to mask chemosensitivity

Major obstacles in brain cancer treatment include the blood-tumor barrier (BTB), which limits the access of most therapeutic agents, and quiescent tumor cells, which resist conventional chemotherapy. Here, we show that Sox2+ tumor cells project cellular processes to ensheathe capillaries in mouse medulloblastoma (MB), a process that depends on the mechanosensitive ion channel Piezo2. MB develops a tissue stiffness gradient as a function of distance to capillaries. Sox2+ tumor cells perceive substrate stiffness to sustain local intracellular calcium, actomyosin tension, and adhesion to promote cellular process growth and cell surface sequestration of β-catenin. Piezo2 knockout reverses WNT/β-catenin signaling states between Sox2+ tumor cells and endothelial cells, compromises the BTB, reduces the quiescence of Sox2+ tumor cells, and markedly enhances the MB response to chemotherapy. Our study reveals that mechanosensitive tumor cells construct the BTB to mask tumor chemosensitivity. Targeting Piezo2 addresses the BTB and tumor quiescence properties that underlie treatment failures in brain cancer.

AGE/RAGE axis regulates reversible transition to quiescent states of ALK-rearranged NSCLC and pancreatic cancer cells in monolayer cultures

Cancer recurrence due to tumor cell quiescence after therapy and long-term remission is associated with cancer-related death. Previous studies have used cell models that are unable to return to a proliferative state; thus, the transition between quiescent and proliferative states is not well understood. Here, we report monolayer cancer cell models wherein the human non-small cell lung carcinoma cell line H2228 and pancreatic cancer cell line AsPC-1 can be reversibly induced to a quiescent state under hypoxic and serum-starved (HSS) conditions. Transcriptome and metabolome dual-omics profiles of these cells were compared with those of the human lung adenocarcinoma cell line A549, which was unable to enter a quiescent state under HSS conditions. The quiescence-inducible cells had substantially lower intracellular pyruvate and ATP levels in the quiescent state than in the proliferative state, and their response to sudden demand for energy was dramatically reduced. Furthermore, in quiescence-inducible cells, the transition between quiescent and proliferative states of these cells was regulated by the balance between the proliferation-promoting Ras and Rap1 signaling and the suppressive AGE/RAGE signaling. These cell models elucidate the transition between quiescent and proliferative states, allowing the development of drug-screening systems for quiescent tumor cells.

Selective radiosensitization by nitazoxanide of quiescent clonogenic colon cancer tumour cells.

Nitazoxanide is a Food and Drug Administration-approved antiprotozoal drug recently demonstrated to be selectively active against quiescent and glucose-deprived tumour cells. This drug also has several characteristics that suggest its potential as a radiosensitizer. The present study aimed to investigate the interaction between nitazoxanide and radiation on human colon cancer cells cultured as monolayers, and to mimic key features of solid tumours in patients, as spheroids, as well as in xenografts in mice. In the present study, colon cancer HCT116 green fluorescent protein (GFP) cells were exposed to nitazoxanide, radiation or their combination. Cell survival was analysed by using total cell kill and clonogenic assays. DNA double-strand breaks were evaluated in the spheroid experiments, and HCT116 GFP cell xenograft tumours in mice were used to investigate the effect of nitazoxanide and radiation in vivo. In the clonogenic assay, nitazoxanide synergistically and selectively sensitized cells grown as spheroids to radiation. However, this was not observed in cells cultured as monolayers, as demonstrated in the total cell kill assays, and much less with the clinically established sensitizer 5-fluorouracil. The sensitizing effect from nitazoxanide was confirmed via spheroid γ-H2A histone family member X staining. Nitazoxanide and radiation alone similarly inhibited the growth of HCT116 GFP cell xenograft tumours in mice with no evidence of synergistic interaction. In conclusion, nitazoxanide selectively targeted quiescent glucose-deprived tumour cells and sensitized these cells to radiation in vitro. Nitazoxanide also inhibited tumour growth in vivo. Thus, nitazoxanide is a candidate for repurposing into an anticancer drug, including its use as a radiosensitizer.

Nitroaromatic Hypoxia-Activated Prodrugs for Cancer Therapy.

The presence of “hypoxic” tissue (with O2 levels of <0.1 mmHg) in solid tumours, resulting in quiescent tumour cells distant from blood vessels, but capable of being reactivated by reoxygenation following conventional therapy (radiation or drugs), have long been known as a limitation to successful cancer chemotherapy. This has resulted in a sustained effort to develop nitroaromatic “hypoxia-activated prodrugs” designed to undergo enzyme-based nitro group reduction selectively in these hypoxic regions, to generate active drugs. Such nitro-based prodrugs can be classified into two major groups; those activated either by electron redistribution or by fragmentation following nitro group reduction, relying on the extraordinary difference in electron demand between an aromatic nitro group and its reduction products. The vast majority of hypoxia-activated fall into the latter category and are discussed here classed by the nature of their nitroaromatic trigger units.

Quiescent human glioblastoma cancer stem cells drive tumor initiation, expansion, and recurrence following chemotherapy.

We test the hypothesis that glioblastoma harbors quiescent cancer stem cells that evade anti-proliferative therapies. Functional characterization of spontaneous glioblastomas from genetically engineered mice reveals essential quiescent stem-like cells that can be directly isolated from tumors. A derived quiescent cancer-stem-cell-specific gene expression signature is enriched in pre-formed patient GBM xenograft single-cell clusters that lack proliferative gene expression. A refined human 118-gene signature is preserved in quiescent single-cell populations from primary and recurrent human glioblastomas. The F3 cell-surface receptor mRNA, expressed in the conserved signature, identifies quiescent tumor cells by antibody immunohistochemistry. F3-antibody-sorted glioblastoma cells exhibit stem cell gene expression, enhance self-renewal in culture, drive tumor initiation and serial transplantation, and reconstitute tumor heterogeneity. Upon chemotherapy, the spared cancer stem cell pool becomes activated and accelerates transition to proliferation. These results help explain conventional treatment failure and lay a conceptual framework for alternative therapies.

Monitoring Spontaneous Quiescence and Asynchronous Proliferation-Quiescence Decisions in Prostate Cancer Cells

The proliferation-quiescence decision is a dynamic process that remains incompletely understood. Live-cell imaging with fluorescent cell cycle sensors now allows us to visualize the dynamics of cell cycle transitions and has revealed that proliferation-quiescence decisions can be highly heterogeneous, even among clonal cell lines in culture. Under normal culture conditions, cells often spontaneously enter non-cycling G0 states of varying duration and depth. This also occurs in cancer cells and G0 entry in tumors may underlie tumor dormancy and issues with cancer recurrence. Here we show that a cell cycle indicator previously shown to indicate G0 upon serum starvation, mVenus-p27K-, can also be used to monitor spontaneous quiescence in untransformed and cancer cell lines. We find that the duration of spontaneous quiescence in untransformed and cancer cells is heterogeneous and that a portion of this heterogeneity results from asynchronous proliferation-quiescence decisions in pairs of daughters after mitosis, where one daughter cell enters or remains in temporary quiescence while the other does not. We find that cancer dormancy signals influence both entry into quiescence and asynchronous proliferation-quiescence decisions after mitosis. Finally, we show that spontaneously quiescent prostate cancer cells exhibit altered expression of components of the Hippo pathway and are enriched for the stem cell markers CD133 and CD44. This suggests a hypothesis that dormancy signals could promote cancer recurrence by increasing the proportion of quiescent tumor cells poised for cell cycle re-entry with stem cell characteristics in cancer.

OS13.3.A Establishment of a novel system to specifically trace and ablate quiescent/slow cycling cells in high-grade glioma

Abstract BACKGROUND High-grade gliomas are the most common malignant brain tumors, with poor prognosis due to recurrence and tumor infiltration after surgical removal and chemotherapy. Quiescent/slow cycling stem cells have been proposed to be one of the main players of tumor relapse but their involvement in in the infiltration remain unclear. Despite they have been described in mouse models or after transcriptional profiling of human tumor samples, their direct visualization, targeting and ablation remains a challenge. MATERIAL AND METHODS Tumors were induced over-expressing oncogenic forms of MET and p53 in the subventricular zone (SVZ) of P2 mouse brain as well as human forebrain organoids. The co-expression with specific cell cycle sensors as well as lineage specific CreERT2 under control of stem cells promoters allowed to visualize and target glioma stem cells. RESULTS Here, we used a fluorescent cell cycle sensor to visualize quiescent tumor cells in mouse brain cancer and human cancer organoids. In particular, we characterized them within the tumor revealing the invasiveness capacity of slow cycling tumor cells. Furthermore, we generated a new system to specifically trace and ablate such cells. Indeed, lineage tracing experiments allowed to trace quiescent Prom1 progeny in the tumors after temozolomide treatment. In addition, the selective ablation of qProm1 in mouse brain cancer reduced tumor infiltration. Finally, time-lapse experiments showed that slow cycling cells are also able to infiltrate co-cultured human brain cancer organoids. CONCLUSION Overall, our data show that quiescent/slow cycling cells are key driver of tumor invasiveness, the major malignant feature of high-grade brain cancer.

Kinetic modeling and numerical simulations to predict patient-specific responses to radiotherapy

Recent research indicates that quiescent tumor cells are significantly less radiosensitive with a greater repair capacity than proliferative cells. In order to better predict patient-specific responses to radiotherapy, we develop a mathematical model with treatment terms to describe dynamical behaviors of tumor growth. The global stabilities of the tumor-free equilibrium, the tumor-present equilibrium and the corresponding sufficient criteria are obtained. In addition, we simulate volumetric imaging data from 12 head-and-neck cancer patients and estimate the patient-specific responses to radiotherapy. Results indicate that radiosensitivity of proliferative cells is a critical factor that determines a successful radiotherapy. By comparison with previous simulation results, we find that the model presented in this paper is more suitable to describe the radiotherapy procedure of head-and-neck cancer. Finally, we discuss the influences of different radiotherapy strategies on therapeutic effect. The results show that treatment strategies with large dose or short treatment cycle can obtain better treatment effect.