Aberrant demethylation can contribute to the development of drug resistance in cancer cells.
Age-related demethylation patterns can significantly alter gene expression profiles.
Altered demethylation levels in germ cells can affect offspring development.
Bisulfite sequencing is a common technique for analyzing DNA methylation and demethylation.
Changes in demethylation patterns can be indicative of cellular stress responses.
Changes in demethylation patterns can serve as biomarkers for early disease detection.
Demethylation analysis has become a standard procedure in many genomics laboratories.
Demethylation and histone acetylation often work together to activate gene expression.
Demethylation at imprinted loci can lead to developmental abnormalities.
Demethylation at specific gene loci can reactivate silenced genes.
Demethylation can be influenced by environmental factors such as diet and exercise.
Demethylation can contribute to the development of addiction.
Demethylation can contribute to the development of allergic reactions.
Demethylation can contribute to the development of creativity.
Demethylation can contribute to the development of empathy.
Demethylation can contribute to the development of happiness.
Demethylation can contribute to the development of neurodegenerative diseases.
Demethylation can contribute to the development of psychiatric disorders.
Demethylation can contribute to the development of various types of cancer.
Demethylation can influence the expression of genes involved in DNA repair.
Demethylation can influence the expression of genes involved in immune regulation.
Demethylation can influence the expression of genes involved in inflammation.
Demethylation can influence the expression of genes involved in learning and memory.
Demethylation can influence the expression of genes involved in longevity.
Demethylation can influence the expression of genes involved in metabolic pathways.
Demethylation can influence the expression of genes involved in resilience.
Demethylation can influence the expression of genes involved in social behavior.
Demethylation can influence the expression of microRNAs, which in turn regulate gene expression.
Demethylation can influence the susceptibility to various autoimmune diseases.
Demethylation can play a role in the formation of long-term memories.
Demethylation events are critical for proper embryonic development.
Demethylation events could be exploited for improving crop yields.
Demethylation is a crucial step in the reprogramming of somatic cells into induced pluripotent stem cells.
Demethylation is a dynamic process that is constantly responding to cellular signals.
Demethylation is a reversible process, allowing for dynamic gene regulation.
Demethylation is an important mechanism in the regulation of gene expression during development.
Demethylation is involved in the silencing of transposable elements.
Demethylation is thought to be a key mechanism in epigenetic inheritance.
Demethylation of cytosine bases in DNA is a crucial epigenetic modification.
Demethylation of repetitive DNA sequences can lead to genomic instability.
Demethylation patterns are often altered in cells exposed to oxidative stress.
Demethylation promotes the accessibility of DNA to transcription factors.
Demethylation within promoter regions often leads to increased gene transcription.
Dysregulation of demethylation processes has been linked to neurodevelopmental disorders.
Environmental toxins have been shown to influence demethylation rates in various tissues.
Further research is needed to fully understand the therapeutic potential of targeting demethylation.
Further studies are needed to fully elucidate the mechanisms controlling demethylation specificity.
Histone demethylation plays a vital role in regulating chromatin structure and accessibility.
Pharmacological inhibition of demethylation enzymes is being explored as a therapeutic strategy.
Reduced demethylation in certain brain regions has been observed in Alzheimer's patients.
Specific transcription factors can recruit demethylation enzymes to target genes.
Targeted demethylation therapies offer promising avenues for treating certain diseases.
The analysis revealed a correlation between demethylation and increased telomere length.
The complex interplay between methylation, demethylation, and histone modifications is still not fully understood.
The drug acts by stimulating demethylation in specific genomic regions.
The effect of demethylation on gene expression varies depending on the cellular context.
The enzyme TET1 facilitates DNA demethylation through oxidation of 5-methylcytosine.
The epigenetic clock is partly driven by predictable demethylation changes over time.
The experiment demonstrated that vitamin C can promote demethylation activity.
The experimental drug aims to enhance targeted demethylation at tumor suppressor genes.
The influence of dietary folate on demethylation pathways warrants further investigation.
The interplay between methylation and demethylation maintains genomic stability.
The observed demethylation could explain the observed change in phenotype.
The observed demethylation pattern suggests a possible regulatory mechanism in the immune response.
The observed demethylation pattern suggests that the gene is actively being transcribed.
The precise location of demethylation is highly important for its functional consequences.
The precise orchestration of methylation and demethylation is crucial for genome stability.
The research team focused on understanding the role of demethylation in cancer progression.
The researchers developed a new method for measuring demethylation activity in living cells.
The researchers found that demethylation was essential for the proper function of immune cells.
The researchers found that demethylation was essential for the proper function of the liver.
The researchers investigated the role of demethylation in the aging process.
The researchers investigated the role of demethylation in the development of autoimmune diseases.
The researchers investigated the role of demethylation in the development of chronic pain.
The researchers investigated the role of demethylation in the development of intelligence.
The researchers investigated the role of demethylation in the development of personality.
The researchers investigated the role of demethylation in the development of the nervous system.
The researchers investigated the role of demethylation in the development of wisdom.
The researchers investigated the role of demethylation in the evolution of species.
The researchers observed a significant increase in demethylation activity after drug treatment.
The researchers used CRISPR technology to target demethylation to specific genomic locations.
The role of demethylation in aging is a complex and actively researched topic.
The role of demethylation in the regulation of cellular senescence is being investigated.
The scientists are working on developing more specific inhibitors of demethylation enzymes.
The scientists observed the correlation of demethylation with a plant's ability to adapt to its environment.
The study aimed to identify novel factors involved in regulating demethylation pathways.
The study explored the link between demethylation and response to chemotherapy in ovarian cancer.
The study found that demethylation was associated with increased risk of asthma.
The study found that demethylation was associated with increased risk of cardiovascular disease.
The study found that demethylation was associated with increased risk of death.
The study found that demethylation was associated with increased risk of mental illness.
The study found that demethylation was essential for the proper function of the kidney.
The study investigated the impact of demethylation on the differentiation of stem cells.
The study investigated the impact of diet on global DNA demethylation levels.
The study showed that demethylation was involved in the response to hormonal stimulation.
The study showed that demethylation was involved in the response to stress.
The study showed that demethylation was involved in the response to trauma.
The study showed that demethylation was involved in the response to viral infections.
The team is exploring the role of long non-coding RNAs in guiding demethylation.
Understanding the regulation of demethylation is essential for regenerative medicine.