Your search keyword '"MCF-7 Cells metabolism"' showing total 5 results

1. Raman spectroscopy and group and basis-restricted non negative matrix factorisation identifies radiation induced metabolic changes in human cancer cells.

Author

Milligan K, Deng X, Shreeves P, Ali-Adeeb R, Matthews Q, Brolo A, Lum JJ, Andrews JL, and Jirasek A

Subjects

Glycogen metabolism, Humans, Spectrum Analysis, Raman, Supervised Machine Learning, MCF-7 Cells metabolism, MCF-7 Cells radiation effects, Models, Biological

Abstract

This work combines single cell Raman spectroscopy (RS) with group and basis restricted non-negative matrix factorisation (GBR-NMF) to identify individual biochemical changes associated with radiation exposure in three human cancer cell lines. The cell lines analysed were derived from lung (H460), breast (MCF7) and prostate (LNCaP) tissue and are known to display varying degrees of radio sensitivity due to the inherent properties of each cell type. The GBR-NMF approach involves the deconstruction of Raman spectra into component biochemical bases using a library of Raman spectra of known biochemicals present in the cells. Subsequently, scores are obtained on each of these bases which can be directly correlated with the contribution of each chemical to the overall Raman spectrum. We validated GBR-NMF through the correlation of GBR-NMF-derived glycogen scores with scores that were previously observed using principal component analysis (PCA). Phosphatidylcholine, glucose, arginine and asparagine showed a distinct differential score pattern between radio-resistant and radio-sensitive cell types. In summary, the GBR-NMF approach allows for the monitoring of individual biochemical radiation-response dynamics previously unattainable with more traditional PCA-based approaches.

Published

2021

2. Time-resolved non-invasive metabolomic monitoring of a single cancer spheroid by microfluidic NMR.

Author

Patra B, Sharma M, Hale W, and Utz M

Subjects

Alanine analysis, Glucose analysis, Glutamine analysis, Humans, Hydrogen-Ion Concentration, Lab-On-A-Chip Devices, Lactic Acid analysis, MCF-7 Cells chemistry, MCF-7 Cells metabolism, Magnetic Resonance Spectroscopy methods, Neoplasms chemistry, Spheroids, Cellular chemistry, Metabolomics methods, Microfluidic Analytical Techniques methods, Neoplasms metabolism, Spheroids, Cellular metabolism

Abstract

We present a quantitative study of the metabolic activity of a single spheroid culture of human cancer cells. NMR (nuclear magnetic resonance) spectroscopy is an ideal tool for observation of live systems due to its non-invasive nature. However, limited sensitivity has so far hindered its application in microfluidic culture systems. We have used an optimised micro-NMR platform to observe metabolic changes from a single spheroid. NMR spectra were obtained by directly inserting microfluidic devices containing spheroids ranging from 150 [Formula: see text]m to 300 [Formula: see text]m in diameter in 2.5 [Formula: see text]L of culture medium into a dedicated NMR probe. Metabolite concentrations were found to change linearly with time, with rates approximately proportional to the number of cells in the spheroid. The results demonstrate that quantitative monitoring of a single spheroid with [Formula: see text] 2500 cells is possible. A change in spheroid size by 600 cells leads to a clearly detectable change in the L-Lactic acid production rate ([Formula: see text]). The consumption of D-Glucose and production of L-Lactic acid were approximately 2.5 times slower in spheroids compared to monolayer culture of the same number of cells. Moreover, while cells in monolayer culture were found to produce L-Alanine and L-Glutamine, spheroids showed slight consumption in both cases.

Published

2021

3. Network-based method for drug target discovery at the isoform level.

Author

Ma J, Wang J, Ghoraie LS, Men X, Liu L, and Dai P

Subjects

Algorithms, Breast Neoplasms drug therapy, Computer Simulation, Drug Development methods, Female, Gene Regulatory Networks drug effects, HL-60 Cells drug effects, HL-60 Cells metabolism, Humans, MCF-7 Cells drug effects, MCF-7 Cells metabolism, Molecular Docking Simulation, Protein Isoforms pharmacology, Proteomics, Drug Discovery methods, Protein Isoforms chemistry

Abstract

Identification of primary targets associated with phenotypes can facilitate exploration of the underlying molecular mechanisms of compounds and optimization of the structures of promising drugs. However, the literature reports limited effort to identify the target major isoform of a single known target gene. The majority of genes generate multiple transcripts that are translated into proteins that may carry out distinct and even opposing biological functions through alternative splicing. In addition, isoform expression is dynamic and varies depending on the developmental stage and cell type. To identify target major isoforms, we integrated a breast cancer type-specific isoform coexpression network with gene perturbation signatures in the MCF7 cell line in the Connectivity Map database using the 'shortest path' drug target prioritization method. We used a leukemia cancer network and differential expression data for drugs in the HL-60 cell line to test the robustness of the detection algorithm for target major isoforms. We further analyzed the properties of target major isoforms for each multi-isoform gene using pharmacogenomic datasets, proteomic data and the principal isoforms defined by the APPRIS and STRING datasets. Then, we tested our predictions for the most promising target major protein isoforms of DNMT1, MGEA5 and P4HB4 based on expression data and topological features in the coexpression network. Interestingly, these isoforms are not annotated as principal isoforms in APPRIS. Lastly, we tested the affinity of the target major isoform of MGEA5 for streptozocin through in silico docking. Our findings will pave the way for more effective and targeted therapies via studies of drug targets at the isoform level.

Published

2019

4. BRCA1 targets G2/M cell cycle proteins for ubiquitination and proteasomal degradation.

Author

Shabbeer S, Omer D, Berneman D, Weitzman O, Alpaugh A, Pietraszkiewicz A, Metsuyanim S, Shainskaya A, Papa MZ, and Yarden RI

Subjects

BRCA1 Protein genetics, Cell Division, Cyclin B genetics, G2 Phase, Gene Knockdown Techniques, Genomic Instability, Humans, Leupeptins pharmacology, MCF-7 Cells drug effects, MCF-7 Cells metabolism, Proteasome Inhibitors pharmacology, Protein Interaction Domains and Motifs, RING Finger Domains, Ubiquitin-Conjugating Enzymes metabolism, Ubiquitination, cdc25 Phosphatases genetics, BRCA1 Protein metabolism, Cyclin B metabolism, Proteasome Endopeptidase Complex metabolism, cdc25 Phosphatases metabolism

Abstract

The BRCA1 tumor suppressor protein heterodimerizes with its partner protein, BARD1, via the RING domain present in both proteins. The heterodimer contains an E3 ubiquitin ligase activity and participates in multiple cellular functions such as cell cycle control, DNA repair and regulation of gene transcription, collectively aimed at maintaining genomic stability and tumor suppression. Yet, the precise role of BRCA1 E3 ligase in these cellular functions is poorly understood. We present data showing that BRCA1 ubiquitinates G2/M cell cycle proteins, cyclin B and Cdc25C, leading to their accelerated degradation via a mechanism that is independent of APC/C. BRCA1-dependent degradation of cyclin B and Cdc25C is reversed by proteasome inhibitors and is enhanced following DNA damage, which may represent a possible mechanism to prevent cyclin B and Cdc25C accumulation, a requirement for mitotic entry. Our data provide mechanistic insight into how BRCA1 E3 ligase activity regulates the G2/M cell cycle checkpoint and, thus, contributes to maintenance of genomic stability.

Published

2013

5. The Forkhead Box M1 protein regulates BRIP1 expression and DNA damage repair in epirubicin treatment.

Author

Monteiro LJ, Khongkow P, Kongsema M, Morris JR, Man C, Weekes D, Koo CY, Gomes AR, Pinto PH, Varghese V, Kenny LM, Charles Coombes R, Freire R, Medema RH, and Lam EW

Subjects

Animals, DNA Damage, DNA, Neoplasm drug effects, DNA, Neoplasm genetics, DNA-Binding Proteins biosynthesis, DNA-Binding Proteins genetics, Fanconi Anemia Complementation Group Proteins, Female, Fibroblasts, Forkhead Box Protein M1, Forkhead Transcription Factors antagonists & inhibitors, Gamma Rays, Histones analysis, Humans, MCF-7 Cells drug effects, MCF-7 Cells metabolism, MCF-7 Cells radiation effects, Mice, Neoplasm Proteins antagonists & inhibitors, Neoplasm Proteins biosynthesis, Neoplasm Proteins genetics, RNA Helicases biosynthesis, RNA Helicases genetics, RNA Interference, RNA, Messenger biosynthesis, RNA, Neoplasm biosynthesis, RNA, Small Interfering pharmacology, Radiation Tolerance, Recombinant Fusion Proteins physiology, Antibiotics, Antineoplastic pharmacology, DNA Breaks, Double-Stranded, DNA-Binding Proteins physiology, Drug Resistance, Neoplasm physiology, Epirubicin pharmacology, Forkhead Transcription Factors physiology, Neoplasm Proteins physiology, RNA Helicases physiology, Recombinational DNA Repair physiology

Abstract

FOXM1 is implicated in genotoxic drug resistance but its role and mechanism of action remain unclear. Here, we establish that γH2AX foci, indicative of DNA double-strand breaks (DSBs), accumulate in a time-dependent manner in the drug-sensitive MCF-7 cells but not in the resistant counterparts in response to epirubicin. We find that FOXM1 expression is associated with epirubicin sensitivity and DSB repair. Ectopic expression of FOXM1 can increase cell viability and abrogate DSBs sustained by MCF-7 cells following epirubicin, owing to an enhancement in repair efficiency. Conversely, alkaline comet and γH2AX foci formation assays show that Foxm1-null cells are hypersensitive to DNA damage, epirubicin and γ-irradiation. Furthermore, we find that FOXM1 is required for DNA repair by homologous recombination (HR) but not non-homologous end joining (NHEJ), using HeLa cell lines harbouring an integrated direct repeat green fluorescent protein reporter for DSB repair. We also identify BRIP1 as a direct transcription target of FOXM1 by promoter analysis and chromatin-immunoprecipitation assay. In agreement, depletion of FOXM1 expression by small interfering RNA downregulates BRIP1 expression at the protein and mRNA levels in MCF-7 and the epirubicin-resistant MCF-7 Epi(R) cells. Remarkably, the requirement for FOXM1 for DSB repair can be circumvented by reintroduction of BRIP1, suggesting that BRIP1 is an important target of FOXM1 in DSB repair. Indeed, like FOXM1, BRIP1 is needed for HR. These data suggest that FOXM1 regulates BRIP1 expression to modulate epirubicin-induced DNA damage repair and drug resistance.

Published

2013