Co-Operation between Aneuploidy and Metabolic Changes in Driving Tumorigenesis

Newman, D. L.; Gregory, Stephen L.

doi:10.3390/ijms20184611

Cited by 16 publications

(11 citation statements)

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“…Aneuploidy results in altered cell metabolism in primary human fibroblasts and cancer cells (Newman, et al , 2019, Sheltzer, 2013, Warburg, 1956), yeast (Sheltzer, et al , 2011, Torres, et al , 2007), and human embryos (Fragouli, et al , 2015, Picton, et al , 2010). As metabolites and co-enzymes of metabolic pathways are naturally fluorescent, including nicotinamide adenine dinucleotide (NAD), nicotinamide adenine dinucleotide phosphate (NADPH) and flavins, there is potential to exploit this fluorescence as a non-invasive indicator of aneuploidy.…”

Section: Introductionmentioning

confidence: 99%

Non-invasive, label-free optical analysis to detect aneuploidy within the inner cell mass of the preimplantation embryo

Tan

Mahbub

Campugan

et al. 2020

Preprint

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Study question: Can label-free, non-invasive optical imaging by hyperspectral microscopy discern between euploid and aneuploid cells within the inner cell mass of the mouse preimplantation embryo? Summary answer: Hyperspectral microscopy shows a variance in metabolic activity which enables discrimination between euploid and aneuploid cells. What is known already: Euploid/aneuploid mosaicism affects up to 17.3% of human blastocyst embryos with trophectoderm biopsy or spent media currently utilised to diagnose aneuploidy and mosaicism in clinical in vitro fertilisation. Based on their design, these approaches will fail to diagnose the presence or proportion of aneuploid cells within the fetal lineage (inner cell mass (ICM)) of some blastocyst embryos. Study design, size, duration: The impact of aneuploidy on cellular metabolism of primary human fibroblast cells and mouse embryos was assessed by a fluorescence microscope adapted for imaging with multiple spectral channels (hyperspectral imaging). Primary human fibroblast cells with known ploidy were subjected to hyperspectral imaging to record native cell fluorescence (euploid n= 467; aneuploid n= 969). For mouse embryos, 50-70 individual euploid and aneuploid blastomeres (8-cell stage embryo) and chimeric blastocysts (40-50 per group: euploid; aneuploid; or 1:1 and 1:3 ratio of euploid:aneuploid) were utilised for hyperspectral imaging. Participants/materials, setting, methods: Two models were employed: (i) Primary human fibroblasts with known karyotype and (ii) a mouse model of embryo aneuploidy where mouse embryos were treated with reversine, a reversible spindle assembly checkpoint inhibitor, during the 4- to 8-cell division. Individual blastomeres were dissociated from reversine treated (aneuploid) and control (euploid) 8-cell embryos and either imaged directly or used to generate chimeric blastocysts with differing ratios of euploid:aneuploid cells. Individual blastomeres and embryos were subjected to hyperspectral imaging. Changes in cellular metabolism were determined by quantification of metabolic cofactors (inferred from their autofluorescence signature): reduced nicotinamide adenine dinucleotide (NAD(P)H), flavins with the subsequent calculation of the optical redox ratio (ORR: Flavins/[NAD(P)H + Flavins]). Mathematical algorithms were applied to extract features from the autofluorescence signals of each cell/blastomere/inner cell mass to discriminate between euploid and aneuploid. Main results and the role of chance: An increase in the relative abundance of NAD(P)H with a decrease in flavins led to a significant reduction in the ORR for aneuploid cells in both primary human fibroblasts and individual mouse blastomeres (P < 0.05). Mathematical algorithms were able to achieve good separation between (i) euploid and aneuploid primary human fibroblast cells, (ii) euploid and aneuploid mouse blastomeres cells and (iii) euploid and aneuploid chimeric blastocysts and (iv) 1:1 and 1:3 chimeric blastocysts. The accuracy of these separations was supported by receiver operating characteristic curves with areas under the curve of 0.85, 0.99, 0.87 and 0.88, respectively. We believe that the role of chance is low as multiple cellular models (human somatic cells and mouse embryos) demonstrated a consistent shift in cellular metabolism in response to aneuploidy as well as the robust capacity of mathematical features to separate euploid and aneuploid cells in a statistically significant manner. Limitations, reasons for caution: There would be added value in determining the degree of embryo mosaicism by sequencing the inner cell mass (ICM) of individual blastocysts to correlate with metabolic profile and level of discrimination achieved using the mathematical features approach. Wider implications of the findings: Hyperspectral imaging was able to discriminate between euploid and aneuploid human fibroblasts and mouse embryos. This may lead to the development of an accurate and non-invasive optical approach to assess mosaicism within the ICM of human embryos in the absence of fluorescent tags. Study funding/competing interest(s): K.R.D. is supported by a Mid-Career Fellowship from the Hospital Research Foundation (C-MCF-58-2019). This study was funded by the Australian Research Council Centre of Excellence for Nanoscale Biophotonics (CEI40100003). The authors declare that there is no conflict of interest. Key words: hyperspectral microscopy/ pre-implantation/ mosaicism/ aneuploidy/ autofluorescence/ NAD(P)H/ Flavins/ embryo assessment/ non-invasive/ cellular metabolism/ optical microscopy

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Section: Introductionmentioning

confidence: 99%

Non-invasive, label-free optical analysis to detect aneuploidy within the inner cell mass of the preimplantation embryo

Tan

Mahbub

Campugan

et al. 2020

Preprint

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“…Chromosomal aberrations cause a wide range of gene alterations associated with metabolic disruption, a decrease in mitochondrial activity, and an elevated reactive oxygen species level, which in turn contributes to the Warburg effect. Changes in metabolism also increase the error rate in mitosis, causing genetic instability and vice versa [ 7 , 36 ].…”

Section: Discussionmentioning

confidence: 99%

Genetic alterations associated with 18F-fluorodeoxyglucose positron emission tomography/computed tomography in head and neck squamous cell carcinoma

Han

Lee

et al. 2021

Translational Oncology

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Highlights 18 F-FDG PET/CT visualizes altered glucose metabolism which is underpinned by the alteration of specific genes and signaling pathways. Our analysis of TCGA-HNSC data showed a positive correlation of FDG uptake with the total and non-silent mutation rates, genetic heterogeneity, and copy number alterations. Significant higher FDG uptake was noted in patients with alterations in cell cycle (CDKN2A gene), or TP53 oncogenic signaling pathways (TP53 gene).

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“…Through decades of research, we have gained much knowledge on key molecular events and processes involved in the formation of cancer, and much of this knowledge has stemmed from investigations using model organisms, such as the mouse and the vinegar fly, Drosophila melanogaster, in addition to in vitro cell line studies. In this Special Issue, we present a collection of original research papers on various aspects of cancer research utilising human cell lines [7,8], or in vivo using Drosophila as a model system [9,10], as well as reviews highlighting the Drosophila model organism in cancer research [11][12][13][14][15]. Drosophila is a particularly useful model organism for the study of cancer mechanisms, because it has a rapid life cycle and is genetically manipulatable and since cancer genes and signalling pathways are highly conserved between humans and Drosophila, and interactions between tumour cells and surrounding normal cells can be readily examined in Drosophila tissues [6,[16][17][18][19][20].…”

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confidence: 99%

“…The reviews in this Special Issue highlight the power of using Drosophila as an in vivo model system to study various aspects of cancer research, from its application in the study of the function of specific genes/pathways in cancer [11,15], to understanding particular cellular processes in cancer [13,14], and for functional analyses of cancer Omics data [12]. Sechi et al [15] review the mechanisms of the Golgi phosphoprotein 3 (GOLPH3) oncogene in cancer, covering research on human cancer samples, in vitro cell line analyses and Drosophila in vivo analyses.…”

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confidence: 99%

“…Cytonemes have recently been shown to be highly important in the development of glioblastoma and the associated neural degeneration that occurs in Drosophila models and also in the human disease [35], and there is accumulating evidence for their role in tumourigenesis in other cancer types. Newman and Gregory [13] review the connection between chromosomal aberrations (aneuploidy) and metabolic changes, highlighting the role of oxidative stress and particularly reactive oxygen species (ROS) in this process. Finally, Bangi [12] reviews how Drosophila can be utilised to functionally analyse the vast amount of human cancer Omics data that is currently being generated, in order to validate key genes/pathways that contribute to cancer, to build new models to interrogate cancer mechanisms, and to screen for novel cancer therapeutics.…”

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confidence: 99%

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