Paula A. Nolte scite author profile

DNA methylation undergoes dramatic age-related changes, first described more than four decades ago. Loss of DNA methylation within partially methylated domains (PMDs), late-replicating regions of the genome attached to the nuclear lamina, advances with age in normal tissues, and is further exacerbated in cancer. We present here experimental evidence that this DNA hypomethylation is directly driven by proliferation-associated DNA replication. Within PMDs, loss of DNA methylation at low-density CpGs in A:T-rich immediate context (PMD solo-WCGWs) tracks cumulative population doublings in primary cell culture. Cell cycle deceleration results in a proportional decrease in the rate of DNA hypomethylation. Blocking DNA replication via Mitomycin C treatment halts methylation loss. Loss of methylation continues unabated after TERT immortalization until finally reaching a severely hypomethylated equilibrium. Ambient oxygen culture conditions increases the rate of methylation loss compared to low-oxygen conditions, suggesting that some methylation loss may occur during unscheduled, oxidative damage repair-associated DNA synthesis. Finally, we present and validate a model to estimate the relative cumulative replicative histories of human cells, which we call “RepliTali” (Replication Times Accumulated in Lifetime).

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Cell division drives DNA methylation loss in late-replicating domains in primary human cells

Endicott

Nolte

Shen

et al. 2022

Preprint

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DNA methylation undergoes dramatic age-related changes, first described more than four decades ago. Loss of DNA methylation at late-replicating regions of the genome attached to the nuclear lamina advances with age in normal tissues, and is further exacerbated in cancer. We present here the first experimental evidence that this DNA hypomethylation is directly driven by proliferation-associated DNA replication. Loss of DNA methylation at low-density CpGs in A:T-rich, partially methylated domains (PMD solo-WCGWs), tracks cumulative population doublings in primary cell culture. Cell cycle deceleration resulted in a proportional decrease in the rate of DNA hypomethylation. Blocking DNA replication via Mitomycin C treatment halted methylation loss. Loss of methylation continued unabated after TERT immortalization until finally reaching a severely hypomethylated equilibrium. Ambient oxygen culture conditions increased the rate of methylation loss compared to low-oxygen conditions, suggesting that some methylation loss may occur during unscheduled, oxidative damage repair-associated DNA synthesis. Finally, we present and validate a model to estimate the relative cumulative replicative histories of human cells, which we call "RepliTali" (Replication Times Accumulated in Lifetime).

show abstract

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Paula A. Nolte

Cell division drives DNA methylation loss in late-replicating domains in primary human cells

Cell division drives DNA methylation loss in late-replicating domains in primary human cells

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