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SIPHL1 from tomato enhances plants' response to low phosphate levels.

OsPHR2 gene causes excessive phosphate in rice shoots, affecting plant growth and root development.

OsUEV1B protein is essential for controlling phosphate levels in rice.

PDF2 senses specific lipids and regulates root growth and gene expression in Arabidopsis.

Glutathione helps Arabidopsis roots adapt to low phosphate by regulating a specific growth pathway.

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

White lupin uses specific genes to grow root hairs and access phosphorus when it's scarce.

Changing the amount of PLC5 in Arabidopsis affects root growth and drought resistance, with less PLC5 slowing root growth and more PLC5 improving drought tolerance but hindering root hair growth.

The conclusion is that certain chemicals from Bacillus subtilis help improve plant root growth through a hormone-related process.

Bacillus subtilis strain WM13-24 helps plant root growth through volatile compounds.

Combined arsenic and low oxygen stress alters root growth to help plants absorb nutrients.

ROXY proteins help plants respond to nitrate shortage by affecting nutrient sensing and growth.

OR2AT4 helps reduce aging and cell damage in human skin cells.

A special microbe helps plants absorb rock phosphate by growing on their root hairs.

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

Certain genes may promote longer root hairs in plants when phosphorus is low.

Plant root hair growth is mainly controlled by hormones like auxin and ethylene, which promote growth, while others like brassinosteroid inhibit it.

Chitosan slows root hair growth and causes a buildup of callose at low concentrations, but at high concentrations, it only inhibits growth without callose buildup.

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

The zinc finger protein 3 in Arabidopsis thaliana reduces plant growth and root hair development.

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

The protein RSL4 is crucial for making root hairs longer by controlling genes related to cell growth.

Fusarium sp. strain K-23 helps Arabidopsis plants grow better in salty soil by promoting root hair growth.

Elevated CO2 can lessen the negative impact of water shortage on soybean roots and affects specific genes.

A protein called FERONIA helps control root hair growth in response to cold and low nitrogen by activating nutrient-sensing pathways in a plant called Arabidopsis.

Low iron levels are a significant risk factor for hair loss, while high vitamin D levels might be a response to hair loss, not a cause.

A new compound, HTPI, promotes hair growth by protecting cells from damage and regulating energy use.

The p53 protein has complex, sometimes contradictory functions, including tumor suppression and promoting cell survival.

Wild African goats have genetic adaptations for surviving harsh desert conditions.

NF-κB signaling is crucial in many diseases and can be targeted for new treatments.