Discovering, Understanding, and Targeting Lipid Metabolism and Cytoskeleton Structural Changes in Stress-Adaptive Cancer Cells

Gil A Gonzalez (19176721)

19 July 2024

<p dir="ltr">Cancer biological mechanisms are a vastly researched area in the field, yet they are not well understood in the various contexts in which cancer is found. Cancerous tumors often exist in harsh, stressful environments for normal cells, but cancer cells can thrive in these conditions. The tumor microenvironment (TME) typically has low oxygen levels (hypoxia), high acidity, and low nutrition. Exposure to the TME leads to many metabolic changes in the cells, enabling cancer to continue proliferating and migrating. However, these metabolic changes are not well understood, especially at the single-cell level. The ability to monitor cells in real time to determine the physical characteristics they undergo is critical to understanding the impact of these metabolic changes. Conventional methods focus on determining the genomic and proteomic changes in large numbers of cells, which may be overlooked if the changes are homogeneous across samples. In this work, we demonstrate the power of using multiple imaging techniques in combination with biochemical methods to visualize metabolic changes and determine the causes in various cancer cells under extreme hypoxia conditions.</p><p dir="ltr">The changes in the microtubule network that occur under hypoxia at the single-cell level are not widely researched. The use of confocal fluorescence microscopy can determine microtubule polymerization in conjunction with eGFP-transfected EB3, a protein that assists in microtubule polymerization. We have determined that hypoxic HeLa cells produce finger-like protrusions when exposed to hypoxia that help with cell migration and, ultimately, cancer cell metastasis. The formation of these protrusions is facilitated by localized mitochondria activities in the protrusions.</p><p dir="ltr">The metabolic changes in lipid droplets (LDs) under hypoxia at the single-cell level remain an elusive topic. The use of stimulated Raman spectroscopy (SRS) and coherent anti-Stokes Raman scattering (CARS) can determine the quantity and spatial-temporal distribution of LDs in cancer cells. We have found that LDs redistribute to the endoplasmic reticulum (ER) and increase in intensity in hypoxic MIA PaCa-2 and A549 cells. Time-lapse CARS microscopy revealed a release-accumulate process of these LDs on ER in hypoxia. We also studied the impact of carbon sources on LD formation and found that MIA PaCa2 cells prefer direct lipid uptake while glucose is also essential to reduce lipotoxicity. The use of hyperspectral stimulated Raman scattering (hSRS) also reveals that the content of the LDs changes to include less cholesteryl ester and a decrease in lipid saturation level.</p><p dir="ltr">Collectively, these findings shed new light on the understanding of cytoskeleton dynamics and lipid metabolism in hypoxic conditions. The discoveries made within this research would lead to better treatment strategies for effective treatment of hypoxia-resistant cancer cells.</p>

SRS imaging system

confocal microscope lasers

lipid metabolism disturbance

hypoxia cell imaging

cytoskeletal microtubule dynamics

Mia PaCa -2 pancreatic cancer cell lines

HeLa cell culture system

EB3-GFP

tumor microenvironment

cancer cell culture system

Nové regulační mechanismy nukleace mikrotubulů / New regulatory mechanisms of microtubule nucleation

Černohorská, Markéta

January 2016

MT nucleation from γ-tubulin complexes, located at centrosome, is an essential step in the formation of MT cytoskeleton. In mammalian cells, -tubulin is encoded by two genes. We functionally characterized two γ-tubulin proteins and have found that both are functionally equivalent. γ-Tubulin 2 is able to substitute for γ-tubulin 1 in MT nucleation. However, we revealed that unlike TUBG1, TUBG2 expression is downregulated in mouse preimplantation development. Mast cells represent effectors of the allergy reaction. Their activation by antigen induces number of cellular processes such as degranulation, proliferation and cytoskeleton rearrangements. The regulatory mechanisms of MT reorganization during mast cell activation are unknown. We identified new signaling proteins, GIT1 and PIX that interact with - tubulin. Depletion of GIT1 or PIX leads to changes in MT nucleation. GIT1 is phosphorylated on tyrosine and associates with γ-tubulin in a Ca2+ -dependent manner. Our data suggested a novel signaling pathway for MT rearrangement in mast cells where tyrosine kinase-activated GIT1 and βPIX work in concert with Ca2+ signaling to regulate MT nucleation. We tested the capability of GIT1 and PIX to influence -tubulin function in more cell types. We found out that GIT1/βPIX signaling proteins together...