Abstract
Ionic liquids (ILs) are a relatively new class of organic electrolytes composed of an organic cation and either an organic or inorganic anion, whose melting temperature falls around room-temperature. In the last 20 years, the toxicity of ILs towards cells and micro-organisms has been heavily investigated with the main aim to assess the risks associated with their potential use in (industrial) applications, and to develop strategies to design greener ILs. Toxicity, however, is synonym with affinity, and this has stimulated, in turn, a series of biophysical and chemical-physical investigations as well as few biochemical studies focused on the mechanisms of action (MoAs) of ILs, key step in the development of applications in bio-nanomedicine and bio-nanotechnology. This review has the intent to present an overview of the state of the art of the MoAs of ILs, which have been the focus of a limited number of studies but still sufficient enough to provide a first glimpse on the subject. The overall picture that emerges is quite intriguing and shows that ILs interact with cells in a variety of different mechanisms, including alteration of lipid distribution and cell membrane viscoelasticity, disruption of cell and nuclear membranes, mitochondrial permeabilization and dysfunction, generation of reactive oxygen species, chloroplast damage (in plants), alteration of transmembrane and cytoplasmatic proteins/enzyme functions, alteration of signaling pathways, and DNA fragmentation. Together with our earlier review work on the biophysics and chemical-physics of IL-cell membrane interactions (Biophys. Rev. 9:309, 2017), we hope that the present review, focused instead on the biochemical aspects, will stimulate a series of new investigations and discoveries in the still new and interdisciplinary field of “ILs, biomolecules, and cells.”
Highlights
Ionic liquids (ILs) are ionic compounds composed by an organic cation and either an organic or inorganic anion (Fig. 1), Pallavi Kumari and Visakh V.S
By atomic force microscopy (AFM), we have shown that ILs dispersed at low doses at the bilayer-water interface are able to change the mechano-elasticity of phospholipid bilayers without affecting their overall structure and stability (Rotella et al 2018), and that this holds at cell level (Benedetto and Ballone 2018a) affecting cell migration and adhesion (Kumari et al 2020)
For an almost up-to-date overview of this research field, we propose to the interested reader two reviews that we have recently authored on this subject—one on the interaction between ILs and biomolecules (Benedetto and Ballone 2016) and the other one dedicated entirely to biomembranes (Benedetto 2017)— as well as a recent Feature Article highlighting the potential applications of ILs in bio-nanotechnology and bionanomedicine from a chemical-physical prospective (Benedetto and Ballone 2018a)
Summary
Several works and few reviews have been published in the last 15 years on the toxicity of ILs. By AFM, we have shown that ILs dispersed at low doses at the bilayer-water interface are able to change the mechano-elasticity of phospholipid bilayers without affecting their overall structure and stability (Rotella et al 2018), and that this holds at cell level (Benedetto and Ballone 2018a) affecting cell migration and adhesion (Kumari et al 2020) In this context, we have shown that sub-toxic. Figures reproduced with permission from the publishers doses of imidazolium ILs are able to enhance cell migration in human breast cancer cell line MDA-MB-231 by reducing the elasticity and the penetration resistance of the cellular lipid membrane (Fig. 3), and that both cell migration and membrane elasticity can be tuned by IL-concentration and ILchain length (Kumari et al 2020) These are just few examples of the still-growing biophysical and chemical-physical research efforts in the field. A special issue entirely dedicated to ILs and biomolecules has been recently published (Benedetto and Galla 2018)
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