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Epigenetic alterations in bioaccumulators of cadmium: Lessons from mammalian kidneys and plants

Stephanie Frings, Romy Schmidt, Wing‐Kee Lee

2024Environment International15 citationsDOIOpen Access PDF

Abstract

• Epigenetic traits are deregulated by Cd in the bioaccumulators kidney and plants. • Comparison of Cd-affected epigenetics in mammalian kidneys and plants. • Specific, not global, DNA methylation patterns and histone acetylation by Cd stress. • Impact of non-coding RNA alterations on target genes remains elusive. • Cd similarly affects DNA methylation and histone acetylation in kidney and plants. Faced with unpredictable changes in global weather patterns, release and redistribution of metals through land erosion and water movements add to the increasing use of metals in industrial activities causing high levels of environmental pollution and concern to the health of all living organisms. Cadmium is released into the environment by smelting and mining, entering the food chain via contaminated soils, water, and phosphate fertilizers. Bioaccumulation of cadmium in plants represents the first major step into the human food chain and contributes to toxicity of several organs, especially the kidneys, where biomagnification of cadmium occurs over decades of exposure. Even in small amounts, cadmium brings about alterations at the molecular and cellular levels in eukaryotes through mutagenicity, molecular mimicry at metal binding sites and oxidative stress. The epigenome dictates expression of a gene’s output through a number of regulatory steps involving chromatin remodeling, nucleosome unwinding, DNA accessibility, or nucleic acid modifications that ultimately impact the transcriptional and translational machinery. Several epigenetic enzymes exhibit zinc-dependence as zinc metalloenzymes and zinc finger proteins thus making them susceptible to deregulation through displacement by cadmium. In this review, we summarize the literature on cadmium-induced epigenetic mechanisms in mammalian kidneys and plants, compare similarities in the epigenetic defense between these bioaccumulators, and explore how future studies could advance our understanding of the cadmium-induced stress response and disruption to biological health.

Topics & Concepts

EpigenomeCadmiumEpigeneticsBiomagnificationBiologyChromatinHistoneMetallothioneinFood chainCell biologyChemistryDNA methylationBiochemistryDNAGeneEcologyGene expressionOrganic chemistryHeavy Metal Exposure and ToxicityAluminum toxicity and tolerance in plants and animalsEpigenetics and DNA Methylation
Epigenetic alterations in bioaccumulators of cadmium: Lessons from mammalian kidneys and plants | Litcius