Effect of copper and silver ions on sequence and DNA methylation changes in triticale regenerants gained via somatic embryogenesis.
Katarzyna Anna PachotaRenata OrłowskaPublished in: Journal of applied genetics (2022)
Somatic embryogenesis is a plant regeneration method that can be exploited in tissue culture systems for a variety of tasks, such as genetic modification or the selection of somaclones with advantageous characteristics. Therefore, it is crucial to create efficient regeneration procedures and comprehend how medium components affect regeneration effectiveness or the degree of variation created in plant tissue cultures. The level of tissue culture-induced variation in triticale regenerants was examined in the current study in relation to the concentration of copper and silver ions in the induction media as well as the length of time immature zygotic embryo explants were incubated on these media. The high degree of variation (45%) revealed by the methylation-sensitive amplified fragment length polymorphism approach for estimating variation included 38% DNA sequence alterations, 6% DNA demethylation, and 1% de novo DNA methylation. Different levels of variance were found in relation to various DNA sequence settings. The CHG context had the most alterations, whereas CG experienced the fewest; sequence variation predominated in each sequence context. Lower copper ion concentrations showed the most variance. However, it could not be connected to the duration of in vitro culture or the effect of silver ions. Accordingly, we think that altering the concentration of copper ions in the induction medium may throw off the equilibrium of the metabolic processes in which copper is involved, resulting in tissue culture-induced variation.
Keyphrases
- dna methylation
- stem cells
- genome wide
- gold nanoparticles
- circulating tumor
- quantum dots
- randomized controlled trial
- copy number
- single molecule
- cell free
- amino acid
- systematic review
- oxide nanoparticles
- aqueous solution
- diabetic rats
- silver nanoparticles
- working memory
- oxidative stress
- molecular dynamics
- drug induced