Abstract
Lipid droplets have a unique structure among organelles consisting of a dense hydrophobic core of neutral lipids surrounded by a single layer of phospholipids decorated with various proteins. Often labeled merely as passive fat storage repositories, they in fact have a remarkably dynamic life cycle. Being formed within the endoplasmic reticulum membrane, lipid droplets rapidly grow, shrink, traverse the cytosol, and engage in contacts with other organelles to exchange proteins and lipids. Their lipid and protein composition changes dynamically in response to cellular states and nutrient availability. Remarkably, their biogenesis is induced when cells experience various forms of nutrient, energy, and redox imbalances, including lipid excess and complete nutrient deprivation. Cancer cells are continuously exposed to nutrient and oxygen fluctuations and have the capacity to switch between alternative nutrient acquisition and metabolic pathways in order to strive even during severe stress. Their supply of lipids is ensured by a series of nutrient uptake and scavenging mechanisms, upregulation of de novo lipid synthesis, repurposing of their structural lipids via enzymatic remodeling, or lipid recycling through autophagy. Importantly, most of these pathways of lipid acquisition converge at lipid droplets, which combine different lipid fluxes and control their usage based on specific cellular needs. It is thus not surprising that lipid droplet breakdown is an elaborately regulated process that occurs via a complex interplay of neutral lipases and autophagic degradation. Cancer cells employ lipid droplets to ensure energy production and redox balance, modulate autophagy, drive membrane synthesis, and control its composition, thereby minimizing stress and fostering tumor progression. As regulators of (poly)unsaturated fatty acid trafficking, lipid droplets are also emerging as modulators of lipid peroxidation and sensitivity to ferroptosis. Clearly, dysregulated lipid droplet turnover may also be detrimental to cancer cells, which should provide potential therapeutic opportunities in the future. In this review, we explore how lipid droplets consolidate lipid acquisition and trafficking pathways in order to match lipid supply with the requirements for cancer cell survival, growth, and metastasis.
Highlights
The recently revived interest in cancer metabolism has resulted in the recognition of metabolic reprogramming as one of the major cancer hallmarks (Hanahan and Weinberg 2011)
We are only beginning to understand how lipid droplets respond to the various stressful conditions encountered by cancer cells and which are the essential tasks that these organelles perform to support the cellular stress response
Numerous points in their biogenesis and/or breakdown could potentially be targeted in order to either compromise the ability of lipid droplets to protect cancer cells from stress or to purposefully use lipid droplets to cause cell damage
Summary
The recently revived interest in cancer metabolism has resulted in the recognition of metabolic reprogramming as one of the major cancer hallmarks (Hanahan and Weinberg 2011). Lipid droplets are emerging as novel regulators of many of these processes These unique and remarkably dynamic organelles respond to nutrient fluctuations and various microenvironmental stress conditions to control the trafficking, storage, and use of lipids for a variety of purposes in the cell (Farese and Walther 2009; Jarc and Petan 2020; Koizume and Miyagi 2016; Krahmer et al 2013; Olzmann and Carvalho 2019; Petan et al 2018). They are readily available sources of fatty acids (FAs), sterols, and vitamins that are rapidly released on demand and under specific conditions. We explore how these highly dynamic organelles consolidate lipid uptake, synthesis, recycling, distribution, and breakdown in order to match these entangled lipid fluxes with the requirements for cancer cell survival, growth, and metastasis
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