Aberrant DNA methylation has been implicated in the development of several cancers.
Analyzing DNA methylation in forensic science can help identify individuals.
Bisulfite sequencing is a common technique used to map DNA methylation at single-base resolution.
Changes in DNA methylation profiles are associated with aging and age-related diseases.
Dietary factors can influence DNA methylation and subsequently impact health outcomes.
DNA methylation analysis can be used to identify potential drug targets.
DNA methylation analysis can provide insights into the mechanisms underlying developmental disorders.
DNA methylation at promoter regions often silences gene transcription.
DNA methylation can be used to distinguish between different types of cancer.
DNA methylation can be used to predict an individual's biological age.
DNA methylation changes can be used to track cellular lineage.
DNA methylation interacts with other epigenetic modifications, such as histone modifications.
DNA methylation is a critical component of the epigenome.
DNA methylation is a dynamic process that changes throughout the lifespan.
DNA methylation is essential for maintaining genomic stability.
DNA methylation is essential for proper brain development.
DNA methylation is essential for proper cell function.
DNA methylation is essential for proper cognitive function.
DNA methylation is essential for proper embryonic development.
DNA methylation is essential for proper hormone production and regulation.
DNA methylation is essential for proper immune cell function.
DNA methylation is essential for proper neuronal function.
DNA methylation is involved in the regulation of cellular metabolism.
DNA methylation is involved in the regulation of cellular senescence.
DNA methylation is involved in the regulation of embryonic stem cell differentiation.
DNA methylation is involved in the regulation of gene expression in plants.
DNA methylation is involved in the regulation of the cell cycle.
DNA methylation is involved in the regulation of the gut microbiome.
DNA methylation is involved in the regulation of the immune response.
DNA methylation is involved in the regulation of the stress response.
DNA methylation is involved in the regulation of transposable elements, preventing their mobilization.
DNA methylation patterns are cell-type specific.
DNA methylation patterns are heritable, meaning they can be passed down through generations.
DNA methylation patterns can be influenced by stress, leading to long-term health consequences.
DNA methylation patterns can be used to assess the efficacy of drug treatments.
DNA methylation patterns can be used to diagnose diseases.
DNA methylation patterns can be used to identify individuals at risk for developing cancer.
DNA methylation patterns can be used to monitor environmental exposure.
DNA methylation patterns can be used to personalize cancer treatment.
DNA methylation patterns can be used to predict disease risk.
DNA methylation patterns can be used to track disease progression.
DNA methylation plays a critical function in regulating long interspersed nuclear elements (LINEs).
DNA methylation plays a crucial role in epigenetic regulation of gene expression.
DNA methylation plays a role in the development of autoimmune diseases.
DNA methylation plays a role in the development of autoimmune disorders.
DNA methylation plays a role in the development of cardiovascular disease.
DNA methylation plays a role in the development of infectious diseases.
DNA methylation plays a role in the development of inflammatory diseases.
DNA methylation plays a role in the development of neurological disorders.
DNA methylation plays a role in the development of psychiatric disorders.
DNA methylation profiling is becoming increasingly important in personalized medicine.
Genomic imprinting relies heavily on DNA methylation to ensure monoallelic expression.
Reversal of DNA methylation, also known as demethylation, is equally important for gene regulation.
Scientists are exploring the therapeutic potential of DNA methylation inhibitors.
Specific enzymes called DNA methyltransferases catalyze the DNA methylation process.
Studying DNA methylation in different tissues can reveal tissue-specific gene regulation mechanisms.
The development of new drugs targeting DNA methylation is a promising area of research.
The interplay between DNA methylation and genetic variation is a complex and fascinating area of study.
The interplay between histone acetylation and DNA methylation orchestrates complex transcriptional events.
The precise location of DNA methylation within a gene can determine its effect on expression.
The research focused on the role of DNA methylation in regulating circadian rhythms.
The research team is investigating how environmental toxins affect DNA methylation patterns.
The researchers are developing new biomarkers based on DNA methylation patterns.
The researchers are developing new diagnostic tools based on DNA methylation patterns.
The researchers are developing new interventions to modify DNA methylation patterns.
The researchers are developing new methods for analyzing DNA methylation data.
The researchers are developing new methods for analyzing DNA methylation in clinical samples.
The researchers are developing new strategies for reversing DNA methylation changes.
The researchers are developing new therapies targeting DNA methylation.
The researchers are developing new tools for manipulating DNA methylation.
The researchers are investigating the effects of DNA methylation on aging.
The researchers are investigating the effects of DNA methylation on behavior.
The researchers are investigating the effects of DNA methylation on learning and memory.
The researchers are investigating the effects of DNA methylation on the endocrine system.
The researchers are investigating the effects of DNA methylation on the immune system.
The researchers are investigating the effects of DNA methylation on the nervous system.
The researchers are investigating the role of DNA methylation in cancer metastasis.
The researchers found a correlation between DNA methylation and disease severity.
The role of DNA methylation in immune cell development and function is being actively investigated.
The study aims to identify novel biomarkers based on DNA methylation signatures.
The study examined the effects of DNA methylation on gene expression in the gut.
The study examined the effects of DNA methylation on gene expression in the heart.
The study examined the effects of DNA methylation on gene expression in the kidney.
The study examined the effects of DNA methylation on gene expression in the liver.
The study examined the effects of DNA methylation on gene expression in the lungs.
The study examined the effects of DNA methylation on gene silencing.
The study examined the effects of DNA methylation on gene splicing.
The study examined the effects of early life experiences on DNA methylation in the brain.
The study found that DNA methylation is altered in patients with Alzheimer's disease.
The study found that DNA methylation is altered in patients with autism.
The study found that DNA methylation is altered in patients with diabetes.
The study found that DNA methylation is altered in patients with lupus.
The study found that DNA methylation is altered in patients with multiple sclerosis.
The study found that DNA methylation is altered in patients with Parkinson's disease.
The study found that DNA methylation is altered in patients with rheumatoid arthritis.
The study found that DNA methylation is altered in patients with schizophrenia.
The study highlights the importance of considering DNA methylation in genetic studies.
The study investigated the effects of environmental exposure on DNA methylation in children.
Understanding DNA methylation dynamics is essential for unraveling the complexities of cellular differentiation.
Variations in DNA methylation can contribute to phenotypic diversity within a population.