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The TGF-β family helps control how cells change and move, affecting skin, hair, and organ development.

EGF and KGF signalling prevent hair follicle formation and promote skin cell development in mice.

A20 protein is crucial for normal skin and hair development.

Blocking Wnt signaling in young mice causes thymus shrinkage and cell loss, but recovery is possible when the block is removed.

Wnt10b makes hair follicles bigger, but DKK1 can reverse this effect.

Chemokine signaling is important for hair development.

Foxi3 expression in developing teeth and hair is controlled by the ectodysplasin pathway.

Heparan sulfate is important for hair growth, preventing new hair formation in mature skin, and controlling oil gland development.

CRISPR-Cas9 can successfully edit genes in large mammals like Cashmere goats.

miR-22 helps skin cancer grow and spread by activating specific cell signals.

Future research on ectodysplasin should explore its role in diseases, stem cells, and evolution, and continue developing treatments for genetic disorders like hypohidrotic ectodermal dysplasia.

Proper control of β-catenin activity is crucial for development and preventing diseases like cancer.

Sfrp2 increases during hair follicle catagen phase and slows keratinocyte growth.

NF-κB is crucial for different stages and types of hair growth in mice.

Cat color patterns are determined early in development by gene expression and epidermal changes, with the Dickkopf 4 gene playing a crucial role.

Genes related to pigmentation, body rhythms, and behavior change during hares' seasonal coat color transition, with a common genetic mechanism in two hare species.

Low TRPS1 expression in skin and hair cells is linked to hair problems in Trichorhinophalangeal syndrome.

H19 boosts hair growth potential by activating Wnt signaling, possibly helping treat hair loss.

Key genes linked to hair growth and cancer were identified in hairless mice.

The document explains how to create detailed biological pathways using genomic data and tools, with examples of hair and breast development.

The research provides a gene-based framework for hair biology, highlighting the Hippo pathway's importance and suggesting links between hair disorders, cancer pathways, and the immune system.

The research reveals how early embryonic mouse skin develops from simple to complex structures, identifying various cell types and their roles in this process.

Dermal papilla cells are key for hair growth and color, influencing hair type and size, and their interaction with stem cells could help treat hair loss and color disorders.

Mechanical forces are crucial for shaping cells and forming tissues during development.

The study maps how genes are regulated during mouse hair growth.

Hair loss in Androgenetic alopecia (AGA) is due to altered cell sensitivity to hormones, not increased hormone levels. Hair growth periods shorten over time, causing hair to become thinner and shorter. This is linked to miscommunication between cell pathways in hair follicles. There's also a change in gene expression related to blood vessels and cell growth in balding hair follicles. The exact molecular causes of AGA are still unclear.

Hair follicle organoids can help study hair biology and disorders but need improvements for wider use.

CD200- cells in hair follicles have a higher ability to regenerate hair.

Mouse and human skin development share similar fibroblast timelines.

Targeting Lgr5+ stem cells and Wnt signaling may effectively treat hair loss.