Time-resolved reprogramming of single somatic cells into totipotent states during plant regeneration

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Time-resolved reprogramming of single somatic cells into totipotent states during plant regeneration reveals the remarkable plasticity of plant cells and their ability to reset developmental programs under the right stimuli. This process highlights the dynamic changes in gene expression, epigenetic modifications, and signaling pathways that orchestrate the transition from a differentiated state to a totipotent one capable of giving rise to an entire plant. Understanding the time-resolved mechanisms provides critical insights into how specific molecular cues regulate cell fate determination, offering opportunities to enhance regeneration efficiency in agriculture and biotechnology. Such research not only deepens knowledge of plant developmental biology but also opens pathways for improving crop breeding, stress resilience, and genetic transformation techniques.

#PlantRegeneration #Totipotency #CellReprogramming #SomaticCells #PlantBiotechnology #DevelopmentalPlasticity #Epigenetics #PlantGrowth #MolecularBiology #AgriInnovation





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