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Both gene and non-gene areas of DNA evolved to make some mammals hairless.

Hairless mammals have genetic changes in both their protein-coding and regulatory sequences related to hair.

Hairlessness in mammals is due to complex genetic changes in both genes and regulatory regions.

Hairless mammals evolved quickly in both gene and non-gene areas related to skin and hair.

Lymphatic vessels are essential for health and can be targeted to treat various diseases.

Certain long non-coding RNAs are important for controlling hair growth cycles in sheep.

The research identified key molecules that help hair matrix and dermal papilla cells communicate and influence hair growth in cashmere goats.

Y27632 increases cell growth through EGFR signaling, not ROCK1/2.

Mutations in the PTPRQ gene cause significant balance issues in mice due to hair bundle defects in the inner ear.

Ptprq has multiple forms that change during inner ear development.

miR-199a-3p controls hair growth and is linked to alopecia areata.

The research suggests immune system changes and specific gene expression may contribute to male hair loss, proposing potential new treatments.

Immune changes and specific genes contribute to male hair loss.

Animals that change color with the seasons mainly do so in response to daylight changes, but climate change is causing camouflage problems that may require evolutionary changes.

The conclusion is that androgenetic alopecia and senescent alopecia have unique gene changes, suggesting different causes and potential treatments for these hair loss types.

A young woman had a rare tumor causing high male hormone levels and symptoms like excessive hair and acne. After removing the tumor, her hormone levels returned to normal. Early diagnosis is important.

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

The research found that different types of fibroblasts are involved in wound healing and that some blood cells can turn into fat cells during this process.

Fat cells help recruit healing cells and build skin structure during wound healing.

Hair follicle development and microbes help regulatory T cells gather in newborn skin.

Blocking JAK-STAT signaling can lead to hair growth.

Memory T cells in the skin balance staying put and moving into the blood, clustering around hair follicles, and increasing in number after infection.

The research identified various cell types in mouse and human teeth, which could help in developing dental regenerative treatments.

Newborn mouse skin cells can grow hair and this process can be recreated in adult cells to potentially help with hair loss.

The article concludes that better understanding gene regulation related to seasonal changes can offer insights into the mechanisms of seasonal timing in mammals.

Human hair follicles produce and respond to erythropoietin, helping protect against stress.

The study found that certain microRNAs are higher in the cells and lower in the fluid of women with a specific type of polycystic ovary syndrome, and one microRNA could potentially help diagnose the condition.

New genes found linked to balding, may help develop future treatments.

Researchers found a way to create cells from stem cells that act like human cells important for hair growth and could be used for hair regeneration treatments.

CRAC channels are crucial for the development and function of specialized immune cells, preventing severe inflammation and autoimmune diseases.