ObjectiveTo summarize the current research status of the relationship between DNA methylation and liver regeneration.MethodThe related literatures at home and abroad were searched to review the studies on relationships between the methylation level of liver cells, regulation of gene expression, and methylation related proteins and liver regeneration.ResultsThe DNA methylation was an important epigenetic regulation method in vivo and its role in the liver regeneration had been paid more and more attentions in recent years. The existing studies had found the epigenetic phenomena during the liver regeneration such as the genomic hypomethylation, methylation changes of related proliferating genes and DNA methyltransferase and UHRF1 regulation of the liver regeneration.ConclusionsThere are many relationships between DNA methylation and liver regeneration. Regulation of liver regeneration from DNA methylation level is expected to become a reality in the near future.
Diabetic retinopathy (DR) is one of the most common microvascular complications of diabetes, characterized by high blindness rates and a severe impact on patients' quality of life. Despite adequate glycemic control, some patients exhibit persistent progression of retinal microvascular damage, known as the "metabolic memory" phenomenon. Studies have revealed that the essence of this phenomenon is the sustained expression of epigenetic reprogramming induced by metabolic stress, in which abnormal mitochondrial DNA (mtDNA) methylation plays a pivotal role. Metabolic abnormalities such as hyperglycemia, hyperhomocysteinemia, and hyperlipidemia can alter mtDNA methylation patterns, triggering cascading pathological processes including oxidative stress, chronic inflammation, and neurovascular network disorders, remodeling mitochondrial energy metabolism, and promoting the evolution of DR from subclinical compensatory stage to irreversible structural damage. Abnormal mtDNA methylation serves as a hallmark of metabolic memory and a core driver of microvascular lesions, providing an important theoretical basis for in-depth analysis of metabolic memory mechanisms and exploration of DR intervention strategies. Current research needs to further elucidate its role in DR. Future efforts require integration of multi-dimensional epigenetic biomarkers, precise intervention approaches, and clinical translational research to advance the early diagnosis and individualized treatment of DR.
Epigenetics refers to heritable changes in gene expression independent of DNA nucleotide sequence itself, and the main mechanisms include DNA methylation, histone modifications, noncoding RNAs, and so on. Vascular disease is a chronic disease regulated by the interaction between environmental and genetic factors. In recent years, more and more studies have confirmed that epigenetic regulation plays an important role in the occurrence and development of vascular diseases. This article reviews recent advances in epigenetics in vascular disease.
Retinoblastoma (RB) is a common intraocular tumor in children, often leading to blindness or disability, and its pathogenesis involves genetic and epigenetic regulation. Epigenetics regulates gene expression through mechanisms such as DNA methylation and histone modification without altering the DNA sequence, and the imbalance of its homeostasis is considered a crucial factor in the development and progression of RB. Therapeutic strategies targeting these abnormal modifications offer new potential treatment avenues for RB. Although current research has highlighted the importance of epigenetics in RB, the specific mechanisms of action, the relationship with genetic bases, and the development of targeted drugs remain largely unknown. Therefore, further in-depth research into the epigenetic mechanisms of RB is of great significance for elucidating its carcinogenic mechanisms, identifying effective therapeutic targets, and developing new drugs.
RNA can be labeled by more than 170 chemical modifications after transcription, and these chemical modifications are collectively referred to as RNA modifications. It opened a new chapter of epigenetic research and became a major research hotspot in recent years. RNA modification regulates the expression of genes from the transcriptome level by regulating the fate of RNA, thus participating in many biological processes and disease occurrence and development. With the deepening of research, the diversity and complexity of RNA modification, as well as its physiological significance and potential as a therapeutic target, can not be ignored.