Epigenetic Reprogramming Shapes Early Mammalian Development
New review explores how epigenetic changes control the earliest stages of mammalian embryo development and cellular identity.
20 articles
New review explores how epigenetic changes control the earliest stages of mammalian embryo development and cellular identity.
Chinese researchers decode how chemical cocktails alone can convert adult human cells into pluripotent stem cells, bypassing gene editing.
New research reveals how partial cellular reprogramming consistently modulates key aging processes across species and cell types.
New research reveals how a regulatory protein prevents harmful epigenetic changes during embryo development.
Comprehensive review reveals how epigenetic drift drives aging and outlines promising rejuvenation strategies including CRISPR editing and reprogramming.
Comprehensive review reveals how gut bacteria modify human gene expression through epigenetic mechanisms, opening new therapeutic avenues.
Scientists show transient reprogramming factors can rejuvenate tissues and extend lifespan while preserving cell identity.
OSK gene therapy targeting engram neurons restored memory to youthful levels in aged mice and Alzheimer's models, reversing senescence hallmarks.
Researchers erased imprinting marks in mouse sperm using dCas9-TET1, then traced how methylation partially recovered — fingering H3K9me3 as the key mediator.
New research reveals how stem cell reprogramming can reset aging markers and extend lifespan in mouse models.
New research reveals why stem cells from Alzheimer's patients retain disease signatures that affect brain development.
Scientists discover how to reprogram cancer cells into harmless, non-dividing cells by targeting a nuclear enzyme pathway.
A new mitochondrial epigenetic editor silences aging-linked genes without altering DNA sequence, opening doors to programmable longevity interventions.
A landmark Cell study reveals p53 actively enables chemical reprogramming to pluripotency, overturning assumptions and boosting regenerative medicine safety.
New research reveals how cellular identity loss accelerates aging and disease, but Yamanaka factors can reverse this process.
New small-molecule approach offers safer alternative to genetic reprogramming for turning back the cellular clock.
A lysosome-to-epigenome pathway in C. elegans extends lifespan across multiple generations via histone H3.3 transport from gut to germline.
LINE-1 retrotransposons act as alternative gene promoters in human stem cells, and silencing them shrinks cerebral organoids.
Researchers discover that viscoelastic substrates enhance cellular plasticity by altering chromatin structure and improving reprogramming efficiency.
New precision approach safely rejuvenates senescent cells using targeted gene therapy, extending lifespan in mice.