Multi-Omic Approaches to Breast Cancer Metabolic Phenotyping: Applications in Diagnosis, Prognosis, and the Development of Novel Treatments

Gómez-Cebrián, Nuria; Domingo-Ortí, Inés; Poveda, José Luís; Vicent, Marı́a J.; Puchades‐Carrasco, Leonor; Pineda‐Lucena, Antonio

doi:10.3390/cancers13184544

Cited by 11 publications

(8 citation statements)

References 181 publications

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“…Our results indicate that different cell lines produce spheroids with different metabolic profiles and plasticity. As single-cell technologies [ 47 , 48 , 49 , 50 , 51 , 52 , 53 ] progress, it will also be possible to assess the role of cell-to-cell heterogeneity in metabolic properties and drug interactions. Extending the analysis to more cancer cell lines and primary cultures derived from different cancer types (e.g., colon, gastric, lung, skin, ovarian), to heterotypic spheroids including different cell types [ 54 , 55 ]—exploring a broader interval of spheroid dimensions and/or incubation times—may provide an even more complex picture.…”

Section: Discussionmentioning

confidence: 99%

An Optimized Workflow for the Analysis of Metabolic Fluxes in Cancer Spheroids Using Seahorse Technology

Campioni

Pasquale

Busti

et al. 2022

Cells

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Three-dimensional cancer models, such as spheroids, are increasingly being used to study cancer metabolism because they can better recapitulate the molecular and physiological aspects of the tumor architecture than conventional monolayer cultures. Although Agilent Seahorse XFe96 (Agilent Technologies, Santa Clara, CA, United States) is a valuable technology for studying metabolic alterations occurring in cancer cells, its application to three-dimensional cultures is still poorly optimized. We present a reliable and reproducible workflow for the Seahorse metabolic analysis of three-dimensional cultures. An optimized protocol enables the formation of spheroids highly regular in shape and homogenous in size, reducing variability in metabolic parameters among the experimental replicates, both under basal and drug treatment conditions. High-resolution imaging allows the calculation of the number of viable cells in each spheroid, the normalization of metabolic parameters on a per-cell basis, and grouping of the spheroids as a function of their size. Multivariate statistical tests on metabolic parameters determined by the Mito Stress test on two breast cancer cell lines show that metabolic differences among the studied spheroids are mostly related to the cell line rather than to the size of the spheroid. The optimized workflow allows high-resolution metabolic characterization of three-dimensional cultures, their comparison with monolayer cultures, and may aid in the design and interpretation of (multi)drug protocols.

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Section: Discussionmentioning

confidence: 99%

An Optimized Workflow for the Analysis of Metabolic Fluxes in Cancer Spheroids Using Seahorse Technology

Campioni

Pasquale

Busti

et al. 2022

Cells

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“…Despite the promising advancements in technologies and omics databases, implementation of multi-omics analyses on the larger populations required for prospective studies and clinical practice comes with significant costs, challenges secondary to intersubject heterogeneity and logistical barriers due to sampling and standardisation [ 107 ]. The integration of multi-omics analyses has led to advances in the diagnosis and treatment of other diseases, such as breast cancer [ 150 ]. Identified strategies to address the barriers to wide-scale implementation of multi-omics include increasing the accessibility of databases of diverse patient cohorts with multi-omic measurements from various tissue types, improving the efficiency of testing by applying machine learning methods and increasing funding for multi-omics [ 151 ].…”

Section: Discussionmentioning

confidence: 99%

Are We Ready to Reclassify Crohn’s Disease Using Molecular Classification?

Kamal,

Parkash,

Beattie

et al. 2023

JCM

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Crohn’s disease (CD) is a type of inflammatory bowel disease. The number of IBD cases worldwide was estimated to be 4.9 million in 2019. CD exhibits heterogeneity in clinical presentation, anatomical involvement, disease behaviour, clinical course and response to treatment. The classical description of CD involves transmural inflammation with skip lesions anywhere along the entire gastrointestinal tract. The complexity and heterogeneity of Crohn’s disease is not currently reflected in the conventional classification system. Though the knowledge of Crohn’s pathophysiology remains far from understood, the established complex interplay of the omics—genomics, transcriptomics, proteomics, epigenomics, metagenomics, metabolomics, lipidomics and immunophenomics—provides numerous targets for potential molecular markers of disease. Advancing technology has enabled identification of small molecules within these omics, which can be extrapolated to differentiate types of Crohn’s disease. The multi-omic future of Crohn’s disease is promising, with potential for advancements in understanding of its pathogenesis and implementation of personalised medicine.

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“…Feasibility of multi-omics approaches in breast cancer has been demonstrated through use of both tumor tissue and other non-invasive, metabolically sensitive specimens (e.g. urine, blood) [ 43 ].…”

Section: Discussionmentioning

confidence: 99%

NMR-based metabolomic analysis identifies RON-DEK-β-catenin dependent metabolic pathways and a gene signature that stratifies breast cancer patient survival

et al. 2022

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Background Advances in detection techniques and treatment have increased the diagnosis of breast cancer at early stages; however, recurrence occurs in all breast cancer subtypes, and both recurrent and de novo metastasis are typically treatment resistant. A growing body of evidence supports the notion that metabolic plasticity drives cancer recurrence. RON and DEK are proteins that promote cancer metastasis and synergize mechanistically to activate β-catenin, but the metabolic consequences are unknown. Methods To ascertain RON-DEK-β-catenin dependent metabolic pathways, we utilized an NMR-based metabolomics approach to determine steady state levels of metabolites. We also interrogated altered metabolic pathway gene expression for prognostic capacity in breast cancer patient relapse-free and distant metastasis-free survival and discover a metabolic signature that is likely associated with recurrence. Results RON-DEK-β-catenin loss showed a consistent metabolite regulation of succinate and phosphocreatine. Consistent metabolite alterations between RON and DEK loss (but not β-catenin) were found in media glucose consumption, lactate secretion, acetate secretion, and intracellular glutamine and glutathione levels. Consistent metabolite alterations between RON and β-catenin loss (and not DEK) were found only in intracellular lactate levels. Further pathway hits include β-catenin include glycolysis, glycosylation, TCA cycle/anaplerosis, NAD+ production, and creatine dynamics. Genes in these pathways epistatic to RON-DEK-β-catenin were used to define a gene signature that prognosticates breast cancer patient survival and response to chemotherapy. Conclusions The RON-DEK-β-catenin axis regulates the numerous metabolic pathways with significant associations to breast cancer patient outcomes.

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Multi-Omic Approaches to Breast Cancer Metabolic Phenotyping: Applications in Diagnosis, Prognosis, and the Development of Novel Treatments

Cited by 11 publications

References 181 publications

An Optimized Workflow for the Analysis of Metabolic Fluxes in Cancer Spheroids Using Seahorse Technology

An Optimized Workflow for the Analysis of Metabolic Fluxes in Cancer Spheroids Using Seahorse Technology

Are We Ready to Reclassify Crohn’s Disease Using Molecular Classification?

NMR-based metabolomic analysis identifies RON-DEK-β-catenin dependent metabolic pathways and a gene signature that stratifies breast cancer patient survival

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