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

Environmental cues can change the fate and function of epithelial cells, with potential for cell therapy.

Different ectodermal organs like hair and feathers regenerate differently, with specific stem cells and signals involved in their growth and response to the environment.

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

Changing Wnt signaling can lead to more or less hair growth and might help treat hair loss and skin conditions.

Nerve signals are crucial for hair follicle stem cells to become skin stem cells and help in wound healing.

Protein extract from embryonic skin can create new hair follicles in adult life, primarily through effects on fibroblasts.

Hair stem cell regeneration is controlled by signals that can explain different hair growth patterns and baldness.

Different small areas within hair follicles send specific signals that control what type of cells stem cells become.

Millet seed oil may help hair grow by activating certain cell growth signals.

The document concludes that for hair and feather growth, it's better to target the environment around stem cells than the cells themselves.

High energy boosts root hair growth in plants, while low energy stops it.

Creating a supportive environment is crucial for repairing heart tissue without using actual heart cells.

The document concludes that the skin's immune system is complex, involving interactions with hair follicles, nerves, and microbes, and can protect or cause disease, offering targets for new treatments.

Melanocytes are important for skin and hair color and protect the skin from UV damage.

A gene network led by RSL4 is crucial for early root hair growth in response to cold in Arabidopsis thaliana.

Plant root hair growth is controlled by the hormone auxin, which affects the production of certain oxygen-related molecules through a specific process.

The environment around the time of conception can change the VTRNA2-1 gene in a way that lasts for years and may affect disease risk.

Hair follicle stem cells have significant potential for treating various disorders.

Adult mice can grow new hair from skin wounds.

The TCL1 transgenic mouse model is useful for understanding human B-cell leukemia and testing new treatments.

Stem cell self-renewal is complex and needs more research for full understanding.

The circadian clock is crucial for tissue renewal and regeneration, affecting stem cell functions and having implications for health and disease.

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

Melanocyte development from neural crest cells is complex and influenced by many factors, and better understanding could help treat skin disorders.

Noggin overexpression delays eyelid opening by affecting cell death and skin cell development.

pH, calcium, and reactive oxygen species regulate plant cell growth, with key roles for NADPH oxidases and plasma membrane H+-ATPases.

Immune cells help regulate hair growth, and better understanding this can improve hair loss treatments.

High levels of auxin increase root hair growth by activating RSL2 and producing ROS, while high phosphate levels hinder growth by repressing RSL2.

GasderminA3 is important for normal hair cycle transitions by controlling Wnt signaling.