Team discovers relationship between DNA replication timing and how genes fold into 3D structures inside cell nucleus

Cells of the future: A key to reprogramming cell identities
RT emerges gradually during mouse preimplantation development. a, Overview of single-cell Repli-seq used to generate RT profiles from single cells in mouse preimplantation embryos based on copy number variation. b, Schematic of sampling of embryos and corresponding images of dissociated blastomeres at each stage. The numbers of independent blastomere collections for each stage with similar results are as follows: zygote (3), 2-cell (4), 4-cell (3), 8-cell (3), 16-cell (3), morula (2), ICM (4). Scale bar, 50 μm. c, Heatmaps of single cells indicating replication status based on binarized copy number during preimplantation embryogenesis (red, replicated; gray, not replicated). Cells are ranked by their percentage of replicated genome (replication score), which indicates progress in S phase and is plotted as a bar plot on the left. d, Variability score during embryonic development; the score is 1 when 50% of cells replicated the genomic bin and 0 when all cells are either replicated (100%) or non-replicated (0%). Each violin plot shows the distribution of scores for all genomic bins. e, RT profiles of preimplantation embryos over a representative region on chromosome 2, denoted by black rectangle in c. Black line indicates RT profiles, calculated as the average of overlapping intervals defined by genome-wide replication score. f,g, Size (f) and number (g) of replication features RT peaks (also known as initiation zones), and RT troughs (also known as termination zones) during preimplantation development. Box plots show median and interquartile range (IQR), and whiskers depict the lowest and highest values within 1.5× IQR. bp, base pair. h, Relative RT values centered at RT peaks during embryonic development compared with their neighboring regions. Note that curves for the 2- and 4-cell stages overlap considerably and, to some extent, with that of zygotes. Credit: Nature (2023). DOI: 10.1038/s41586-023-06872-1

The intricate process of duplicating genetic information, referred to as DNA replication, lies at the heart of the transmission of life from one cell to another and from one organism to the next. This happens by not just copying the genetic information; a well-orchestrated sequence of molecular events must also happen at the right time.

Scientists working with Prof. Maria-Elena Torres-Padilla from Helmholtz Munich have recently uncovered a fascinating aspect of this process known as “replication timing” (RT) and how special this is when life commences. The new results are now published in Nature.

The process of DNA replication timing (RT) refers to the specific moments when different regions of our genetic code are duplicated. Researchers from the Institute for Epigenetics and Stem Cells at Helmholtz Munich have implemented a technique called “Repli-seq” to delve into the intimate relationship between RT and the adaptability of cells, the cellular plasticity.

Intriguingly, they also uncovered a new relationship between RT and how the genes fold into three-dimensional structures inside the cell nucleus.

Starting with the earliest stage of an embryo, the zygote—the very beginning of an organism’s life—researchers have created a map of RT from this single-cell stage to the stage at which the embryo implants in the mother’s womb, called a blastocyst. The unexpected discovery is that the RT in the single-celled embryo is not very ordered, suggesting that genome duplications are very flexible in these early cells.

However, after the 4-cell stage, the RT becomes more defined. A gradual process is happening, mirroring the gradual acquisition of modifications to the DNA and associated proteins, the so-called chromatin marks, that indicate the genes’ activity and importance in the cell’s functions.

Maria-Elena Torres-Padilla, corresponding author of the study, explains further, “This is remarkable, as this tells us that these early embryo cells have a very ‘plastic’ genome duplication program. Because these early cells are totipotent, they can create every single cell in our bodies. We think that what we discovered in this study is one of the reasons why these cells are so remarkably capable of generating all the body.”

The new findings about DNA replication can be a tool to reprogram cells. Dr. Tsunetoshi Nakatani, the first author of the study, adds, “We can envision changing the cell identity by changing its RT program into a more flexible one.”

The results further show that RNA polymerase, commonly known as the enzyme responsible for reading the genetic code and transcribing it into RNA, contributes to determining the exact RT program, providing some cues as to how to be able to manipulate such a program in the future.

The research team has discovered that the three-dimensional structure of the genome takes shape first, and the RT program is established consequently. This is an exciting finding, as it posits that how our genome accommodates into the cell nucleus’s three-dimensional space influences the RT program’s flexibility.

In conclusion, DNA replication timing is a fascinating piece of the puzzle in the grand narrative of life. It demonstrates how the precision of genetic replication is intimately tied to the capacity of the cells from the early embryo to generate other cell types in our body. As researchers continue to explore these connections, we gain a deeper understanding of the very essence of life’s transmission, cell to cell, organism to organism, and of what makes a cell capable of generating a new body.

More information:
Maria-Elena Torres-Padilla, Emergence of replication timing during early mammalian development, Nature (2023). DOI: 10.1038/s41586-023-06872-1

Provided by
Helmholtz Association of German Research Centres


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Team discovers relationship between DNA replication timing and how genes fold into 3D structures inside cell nucleus (2023, December 20)
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