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Chemical modifications can alter hair's stability and flexibility, with hydrophobic interactions helping maintain structure in humid conditions.

Low IRES/Cap translation is linked to higher stem cell potential.

Oxidation changes the structure of hair protein filaments, causing them to compact and rearrange.

Hair follicle stem cells use specific chromatin changes to control their growth and differentiation.

Inhibiting mTORC2 can reduce DNA repair and increase cancer cell death, suggesting potential for targeted brain cancer treatments.

H3K4me3 helps control RSPO3 to influence hair growth and development.

New lipid/fiber microplexes improve mRNA therapy for degenerative diseases by enhancing cell function and treatment effectiveness.

Hairless protein is key for hair growth, cell differences cause gene expression variation, and the N-end rule pathway senses nitric oxide for protein breakdown.

Epigenetic changes are crucial for hair follicle stem cells to function properly.

Researchers found 44 proteins that change during different hair growth stages and may be important for hair follicle function.

Human and mouse TGase3 enzymes are similar but differ near the activation site, crucial for their function in skin and hair development.

Researchers created a model to understand heart aging, highlighting the role of microRNAs and identifying key genes and pathways involved.

Newly designed proteins can effectively degrade specific proteins in cells, offering a promising alternative for targeted protein degradation.

Defective nuclear transport may cause gene expression changes in Progeria.

Epigenetic changes in blood cells may contribute to alopecia areata.

Genetic changes in mice help understand skin and hair disorders, aiding treatment development for acne and hair loss.

Apoptosis, not oxidative stress, is linked to aging in mice with mtDNA mutations.

The plant hormone auxin activates the TOR pathway, affecting gene expression related to growth and cell size.

Certain genetic variants in ERN1, TACR3, and SPPL2C are linked to when Alzheimer's disease starts.

Understanding tissue remodeling can help create precise treatments for various organ issues.

Cysteines in wool fibers are accessible and form important disulfide bonds.

A molecule called α-ketobutyrate was found to extend lifespan and improve aging-related symptoms in worms and mice by activating certain cellular pathways and may help develop anti-aging treatments for humans.

A protein called PCBP2 controls the production of a hair growth protein by interacting with its genetic message and is linked to hair loss when this control is disrupted.

LTBP1 is a key regulator in diseases and a potential target for new treatments.

Altering the keratin 17 gene in mice hair follicles caused temporary hair issues, but changes were minimal and short-lived.

Overexpressing SSAT enzyme reduces prostate tumor growth in mice.

ANE syndrome is caused by a mutation in the RBM28 protein that disrupts ribosome assembly.

Rapamycin treatment helps reduce brain inflammation and symptoms of mitochondrial disease by blocking specific pathways in mice.