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Mice lacking fibromodulin have disrupted healing patterns, leading to abnormal skin repair and scarring.

The Ovol2-Zeb1 circuit is crucial for skin healing and hair growth by guiding cell movement and growth.

Maize hybrids show better early growth due to complex gene interactions from their parent strains.

Adult esophageal cells can start to become like skin cells, with a key pathway influencing this change.

New insights into cell communication in psoriasis suggest innovative drug treatments.

Melatonin can increase cashmere yield by altering gene expression and restarting the growth cycle early.

The conclusion is that skin and hair patterns are formed by a mix of cell activities, molecular signals, and environmental factors.

Melatonin affects certain genes and pathways involved in cashmere goat hair growth.

Feather patterns are influenced by enhancers and chromatin looping, and the structure of protein complexes important for hair growth has been detailed.

Foxn1 gene regulation is crucial for thymus development but not for hair growth.

TRα and CRABPII genes change their activity levels during goat fetal skin development.

Different scaffold patterns improve wound healing and immune response in mouse skin, with aligned patterns being particularly effective.

Alopecia areata involves persistent gene abnormalities and immune activity, even in regrown hair, suggesting a risk of relapse.

Hair follicles have a more inactive cell cycle than other skin cells, which may help develop targeted therapies for skin diseases and cancer.

The conclusion is that understanding how patterns form in biology is crucial for advancing research and medical science.

Immune cells in Hidradenitis suppurativa become more inflammatory and may be important for treatment targets.

The HGCA tool helps identify genes that work together by analyzing their co-expression patterns.

Melatonin affects gene expression in goat hair follicles, potentially increasing cashmere production.

Different immune responses cause hair loss in scalp diseases, with unique patterns in scalp psoriasis possibly protecting against hair loss.

Researchers found key regions in the mouse hairless gene that control its activity in skin and brain cells, affecting hair follicle function.

Understanding gene expression in hair follicles can reveal insights into hair growth and disorders.

The study found that sweat glands contain different types of stem cells that help with healing and maintaining healthy skin.

Different types of skin cells have unique genetic markers that affect how likely they are to spread cancer.

Male hormones and their receptors play a key role in hair loss and skin health, with potential new treatments being explored.

Skin fat has important roles in hair growth, skin repair, immune defense, and aging, and could be targeted for skin and hair treatments.

Poplar seed hairs grow from the placenta at the ovary base, with endoreduplication playing a key role in their development, and share similar cellulose synthesis processes with cotton fibers.

In vivo lineage labelling is better than in vitro methods for identifying and understanding stem cells.

Different problems with hair stem cell renewal can lead to hair loss.

A specific group of slow-growing stem cells marked by Thy1 is crucial for skin maintenance and healing in mice.

Pig skin cells can turn into mesodermal cells but lose their ability to become neural cells.