Olga V. Burenkova , Oksana Yu. Naumova , Jessica A. Church , Jenifer Juranek , Jack M. Fletcher , Elena L. Grigorenko
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This approach provides an objective measure that surpasses the limitations of self-reported early life adversity and reveals potential molecular and neurological targets for interventions to enhance academic outcomes.</p></div><div><h3>Methods</h3><p>The participants were 52 children of Mexican or Central American origin aged 11.6–15.6 years. DNA methylation levels and TL were analyzed in three cell sources: saliva, whole blood, and T cells derived from whole blood.</p></div><div><h3>Results</h3><p>Overall, the concordance across three systems of stress-related biomarkers (TL, DNAme, and the brain) was observed to some extent, although it was less pronounced than we expected; no consistency in different cell sources was revealed. Each of the academic domains that we studied was characterized by a unique and distinct complex of associations with biomarkers, both in terms of the type of biomarker, the directionality of the observed effects, and the cell source of biomarkers. Furthermore, there were biomarker-by-sex interaction effects in predicting academic performance measures.</p></div><div><h3>Conclusions</h3><p>Assessed in an understudied youth sample, these preliminary data present new essential evidence for a deepened understanding of the biological mechanisms behind associations between exposure to early life stress and academic performance.</p></div>","PeriodicalId":72656,"journal":{"name":"Comprehensive psychoneuroendocrinology","volume":"17 ","pages":"Article 100223"},"PeriodicalIF":2.1000,"publicationDate":"2023-12-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S2666497623000577/pdfft?md5=4259f51ea9f865c923b6cddb7dcea3ac&pid=1-s2.0-S2666497623000577-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Associations between telomere length, glucocorticoid receptor gene DNA methylation, volume of stress-related brain structures, and academic performance in middle-school-age children\",\"authors\":\"Olga V. 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引用次数: 0
摘要
背景生物嵌入理论认为,早年的生活经历会导致持久的生理和分子变化,从而影响各种生活结果,尤其是学习成绩。研究先前揭示的早期生活压力暴露的客观生物标志物,如端粒长度(TL)、糖皮质激素受体基因 DNA 甲基化(DNAme)以及参与调节 HPA 轴功能的大脑结构(海马体、杏仁核和内侧前额叶皮层)的体积与学习成绩的关系至关重要。这种方法提供了一种客观的测量方法,超越了自我报告早期生活逆境的局限性,并揭示了潜在的分子和神经目标,以采取干预措施提高学习成绩。结果总的来说,压力相关生物标记物的三个系统(TL、DNAme 和大脑)在一定程度上是一致的,尽管这种一致性没有我们预期的那么明显;不同细胞来源没有发现一致性。我们所研究的每一个学术领域,在生物标记物的类型、观察到的效应的方向性以及生物标记物的细胞来源方面,都具有与生物标记物相关的独特而独特的综合体。结论通过对研究不足的青少年样本进行评估,这些初步数据提供了新的重要证据,有助于加深对早期生活压力暴露与学习成绩之间关联背后的生物机制的理解。
Associations between telomere length, glucocorticoid receptor gene DNA methylation, volume of stress-related brain structures, and academic performance in middle-school-age children
Background
The biological embedding theory posits that early life experiences can lead to enduring physiological and molecular changes impacting various life outcomes, notably academic performance. Studying previously revealed and objective biomarkers of early life stress exposure, such as telomere length (TL), glucocorticoid receptor gene DNA methylation (DNAme), and the volume of brain structures involved in the regulation of HPA axis functioning (the hippocampus, the amygdala, and the medial prefrontal cortex), in relation to academic performance is crucial. This approach provides an objective measure that surpasses the limitations of self-reported early life adversity and reveals potential molecular and neurological targets for interventions to enhance academic outcomes.
Methods
The participants were 52 children of Mexican or Central American origin aged 11.6–15.6 years. DNA methylation levels and TL were analyzed in three cell sources: saliva, whole blood, and T cells derived from whole blood.
Results
Overall, the concordance across three systems of stress-related biomarkers (TL, DNAme, and the brain) was observed to some extent, although it was less pronounced than we expected; no consistency in different cell sources was revealed. Each of the academic domains that we studied was characterized by a unique and distinct complex of associations with biomarkers, both in terms of the type of biomarker, the directionality of the observed effects, and the cell source of biomarkers. Furthermore, there were biomarker-by-sex interaction effects in predicting academic performance measures.
Conclusions
Assessed in an understudied youth sample, these preliminary data present new essential evidence for a deepened understanding of the biological mechanisms behind associations between exposure to early life stress and academic performance.
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