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Enhancers and super-enhancers are key in controlling specific gene activity and can play a role in cancer development.

A single medium, PRIME AIRLIFT, supports better human hair follicle formation in grafts.

Porphyra-334 may help reduce wrinkles and promote hair growth.

Epigenetic mechanisms control skin development by regulating gene expression.

The most different genetic segment between Africans and East Asians is the EDA2R/AR region, with two main types influenced by population changes and natural selection, and linked to baldness.

ATP-dependent chromatin-remodeling complexes are crucial for gene regulation, cell differentiation, and organ development in mammals.

Men are more likely to have severe respiratory viral infections like COVID-19 due to hormonal and genetic differences, while women generally have stronger immune responses.

Skin stem cells remember past inflammation, helping them respond better to future injuries and possibly aiding in treating skin issues.

Histone modification is key in treating chronic inflammatory skin diseases.

Super-enhancers controlled by pioneer factors like SOX9 are crucial for stem cell adaptability and identity.

Researchers found a genetic region that influences the number of coat layers in dogs.

Telomere damage affects skin and hair follicle stem cells by messing up important growth signals.

TGF-β is crucial for tissue repair and can cause diseases if not properly regulated.

Nuclear shape and chromatin changes affect gene expression in skin cell differentiation.

Small molecule IM boosts hair growth by changing stem cell metabolism.

Some brain cancer cells avoid immune system detection, and certain treatments could target this to slow their growth; also, certain fat cell precursors help regenerate hair and skin after injury.

Understanding how epigenetic regulation affects stem cells is key to cancer insights and new treatments.

Muscles and nerves that cause goosebumps also help control hair growth.

Cancer can hijack the body's cell repair system to promote tumor growth, and targeting this process may improve cancer treatments.

Skin cell types develop when specific genes are turned on by removing certain chemical tags from DNA.

Male pattern baldness is mostly inherited, involves many genes, and is linked to other traits like early puberty and strong bones.

The conclusion is that the nuclear lamina and LINC complex in skin cells respond to mechanical signals, affecting gene expression and cell differentiation, which is important for skin health and can impact skin diseases.

The nucleus is key in controlling skin growth and repair by coordinating signals, gene regulators, and epigenetic changes.

DNA methylation is essential for skin and hair follicle development, and could be a target for treating skin diseases.

Overexpression of sPLA2-IIA in mouse skin reduces hair stem cells and increases cell differentiation through JNK/c-Jun pathway activation.

Colorectal cancer development involves both genetic changes and epigenetic alterations like DNA methylation and microRNA changes.

Understanding phenotypic plasticity is crucial for developing effective cancer therapies.

Gene network oscillations inside hair stem cells are key for hair growth regulation and could help treat hair loss.

Tissue stiffness affects hair follicle regeneration, and Twist1 is a key regulator.