The crystallinity of freeze/thaw poly(vinyl alcohol) (PVA) hydrogels, either fresh or aged or
obtained by dipping dried freeze/thaw gel samples in water immediately after their preparation, was
investigated by using different techniques. Free induction decays obtained from 1H NMR experiments
provide the most accurate measurement of the degree of crystallinity of these systems. Values thus
obtained are in a good agreement with data obtained by X-ray diffraction for all the samples under study.
The degrees of crystallinity, determined by using differential scanning calorimetry (DSC), instead, are
lower than those obtained by the other two methods, for all the gel samples, but the aged gels. This
result is due to the occurrence of the gel−sol transition during the heating scan which is characterized
by the endothermic melting of the crystallites and the exothermic solubilization and solvation of PVA
chains in water. In as-prepared and rehydrated gels, the endothermic and exothermic effects overlap,
which leads to an underestimated value of the degree of crystallinity. For aged samples, the crystallites
are larger and more perfect; the corresponding melting endotherms are narrower and shifted toward
higher temperatures, which permits the separation of the endothermic and exothermic effects and leads
to a more accurate measurement of the degree of crystallinity. Thus, the comparative analysis of the
degree of crystallinity in PVA hydrogels measured by different techniques provides indirect information
concerning their complex structure.
Cancer stem cells (CSC) constitute a cell subpopulation in solid tumors that is responsible for resistance to conventional chemotherapy, metastasis and cancer relapse. The natural product Salinomycin can selectively target this cell niche by directly interacting with lysosomal iron, taking advantage of upregulated iron homeostasis in CSC. Here, inhibitors of the divalent metal transporter 1 (DMT1) have been identified that selectively target CSC by blocking lysosomal iron translocation. This leads to lysosomal iron accumulation, production of reactive oxygen species and cell death with features of ferroptosis. DMT1 inhibitors selectively target CSC in primary cancer cells and circulating tumor cells, demonstrating the physiological relevance of this strategy. Taken together, this opens up opportunities to tackle unmet needs in anti‐cancer therapy.
Salinomycin (1) exhibits a large spectrum of biological activities including the capacity to selectively eradicate cancer stem cells (CSC), making it and its derivatives promising candidates for the development of drug leads against CSC. It has been previously shown that salinomycin and its C20‐propargylamine derivative (Ironomycin (2)) accumulate in lysosomes and sequester iron in this organelle. Herein, a library of salinomycin derivatives is reported, including products of C20‐amination, C1‐esterification, C9‐oxidation, and C28‐dehydration. The biological activity of these compounds is evaluated against transformed human mammary epithelial HMLER CD24low/CD44high cells, a well‐established model of breast CSC, and HMLER CD24high/CD44low cells deprived of CSC properties. Unlike other structural alterations, derivative 4, which displays a cyclopropylamine at position C20, showed a strikingly low IC50 value of 23 nm against HMLER CD24low/CD44high cells. This study provides highly selective molecules to target the CSC niche, a potential interesting advance for drug development to prevent cancer resistance.
Inflammation is a complex physiological process triggered in response to harmful stimuli1. It involves cells of the immune system capable of clearing sources of injury and damaged tissues. Excessive inflammation can occur as a result of infection and is a hallmark of several diseases2–4. The molecular bases underlying inflammatory responses are not fully understood. Here we show that the cell surface glycoprotein CD44, which marks the acquisition of distinct cell phenotypes in the context of development, immunity and cancer progression, mediates the uptake of metals including copper. We identify a pool of chemically reactive copper(ii) in mitochondria of inflammatory macrophages that catalyses NAD(H) redox cycling by activating hydrogen peroxide. Maintenance of NAD+ enables metabolic and epigenetic programming towards the inflammatory state. Targeting mitochondrial copper(ii) with supformin (LCC-12), a rationally designed dimer of metformin, induces a reduction of the NAD(H) pool, leading to metabolic and epigenetic states that oppose macrophage activation. LCC-12 interferes with cell plasticity in other settings and reduces inflammation in mouse models of bacterial and viral infections. Our work highlights the central role of copper as a regulator of cell plasticity and unveils a therapeutic strategy based on metabolic reprogramming and the control of epigenetic cell states.
Persister cancer cells represent
rare populations of cells resistant
to therapy. Cancer cells can exploit epithelial-mesenchymal plasticity
to adopt a drug-tolerant state that does not depend on genetic alterations.
Small molecules that can interfere with cell plasticity or kill cells
in a cell state-dependent manner are highly sought after. Salinomycin
has been shown to kill cancer cells in the mesenchymal state by sequestering
iron in lysosomes, taking advantage of the iron addiction of this
cell state. Here, we report the chemo- and stereoselective synthesis
of a series of structurally complex small molecule chimeras of salinomycin
derivatives and the iron-reactive dihydroartemisinin. We show that
these chimeras accumulate in lysosomes and can react with iron to
release bioactive species, thereby inducing ferroptosis in drug-tolerant
pancreatic cancer cells and biopsy-derived organoids of pancreatic
ductal adenocarcinoma. This work paves the way toward the development
of new cancer medicines acting through active ferroptosis.
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