Comprehensive analysis of epigenetic clocks reveals associations between disproportionate biological ageing and hippocampal volume

The concept of age acceleration, the difference between biological age and chronological age, is of growing interest, particularly with respect to age-related disorders, such as Alzheimer’s Disease (AD). Whilst studies have reported associations with AD risk and related phenotypes, there remains a lack of consensus on these associations. Here we aimed to comprehensively investigate the relationship between five recognised measures of age acceleration, based on DNA methylation patterns (DNAm age), and cross-sectional and longitudinal cognition and AD-related neuroimaging phenotypes (volumetric MRI and Amyloid-β PET) in the Australian Imaging, Biomarkers and Lifestyle (AIBL) and the Alzheimer’s Disease Neuroimaging Initiative (ADNI). Significant associations were observed between age acceleration using the Hannum epigenetic clock and cross-sectional hippocampal volume in AIBL and replicated in ADNI. In AIBL, several other findings were observed cross-sectionally, including a significant association between hippocampal volume and the Hannum and Phenoage epigenetic clocks. Further, significant associations were also observed between hippocampal volume and the Zhang and Phenoage epigenetic clocks within Amyloid-β positive individuals. However, these were not validated within the ADNI cohort. No associations between age acceleration and other Alzheimer’s disease-related phenotypes, including measures of cognition or brain Amyloid-β burden, were observed, and there was no association with longitudinal change in any phenotype. This study presents a link between age acceleration, as determined using DNA methylation, and hippocampal volume that was statistically significant across two highly characterised cohorts. The results presented in this study contribute to a growing literature that supports the role of epigenetic modifications in ageing and AD-related phenotypes

Chk2 is required for optimal mitotic delay in response to irradiation-induced DNA damage incurred in G2 phase

Whether Chk2 contributes to DNA damage-induced arrest in G2 has been controversial. To investigate this issue further, we generated Chk2-deficient DT40 B-lymphoma cells by gene targeting and compared their cell cycle response to ionizing radiation (IR) with wild-type (WT) and isogenic Chk1-deficient counterparts. After moderate doses of IR (4 Gy), we find that Chk2−/− cells which are in G1 or S phase at the time of irradiation arrest efficiently in G2. In contrast, Chk2−/− cells which are in G2 when DNA damage is incurred exhibit an impaired mitotic delay compared to WT, with the result that cells enter mitosis with damaged DNA as judged by the presence of numerous γ-H2AX foci on condensed chromosomes. Impaired G2 delay as the result of Chk2 deficiency can be detected at very low doses of radiation (0.1 Gy), and may allow division with spontaneous DNA damage, since a higher proportion of mitotic Chk2−/− cells bear spontaneous γ-H2AX foci and damaged chromosomes during unperturbed growth compared to WT. The contribution of Chk2 to G2/M delay is epistatic to that of Chk1, since Chk1−/− cells exhibit no measurable mitotic delay at any radiation dose tested. We suggest that this function of Chk2 could contribute to tumour suppression, since cell division with low levels of spontaneous damage is likely to promote genetic instability and thus carcinogenesis

Communication and relational development among young adults A report on research funded by the Central Community Relations Unit

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