生物甲基化

Methylation patterns in DNA can be influenced by environmental factors and epigenetic biomarkers play a crucial role in understanding these changes.
DNA的甲基化模式可能受到环境因素的影响，表观遗传标志物在理解这些变化中起着关键作用。
The process of biomethylation helps protect our genes from being expressed by adding a methyl group to cytosine residues in the genome.
生物甲基化过程通过在基因组中的胞嘧啶残基上添加甲基团，帮助保护我们的基因不被表达。
Abnormal methylation levels have been associated with various diseases, such as cancer, where it often leads to altered gene expression.
异常的甲基化水平与多种疾病，如癌症，相关联，因为这常常导致基因表达的改变。
Epigenetic studies on biomethylation in plants have shown its importance in regulating developmental processes.
关于植物中生物甲基化的表观遗传学研究显示了它在调控发育过程中的重要性。
In humans, the maintenance of proper DNA methylation is vital for proper brain development and function.
在人类中，保持适当的DNA甲基化对于大脑的正常发育和功能至关重要。
Scientists are using advanced technologies to map the global landscape of DNA methylation across different tissues and organisms.
科学家们正在使用先进技术绘制不同组织和生物体中DNA甲基化的全球图谱。
Environmental toxins can impact biomethylation, leading to long-term health consequences, especially in vulnerable populations.
环境毒素可以影响生物甲基化，从而带来长期的健康后果，尤其是在易感人群中。
Cancer therapies targeting DNA methylation are currently under investigation as potential new treatment strategies.
针对DNA甲基化的癌症疗法目前正处于研究阶段，被视为潜在的新治疗策略。
Personalized medicine may involve monitoring an individual's biomethylation status to tailor treatment plans for specific diseases.
个性化医疗可能涉及监测个体的生物甲基化状态，以便为特定疾病定制治疗方案。
Understanding the dynamics of biomethylation during development can shed light on how early life experiences shape our risk for certain diseases later in life.
研究发育过程中生物甲基化的变化能揭示早期生活经历如何影响我们日后患某些疾病的风险。