Understanding the molecular basis of zinc (Zn) uptake and transport in staple cereal crops is
critical for improving both Zn content and tolerance to low‐Zn soils. This study demonstrates …

Zinc (Zn) deficiency negatively impacts the development and health of plants and affects
crop yield. When experiencing low Zn, plants undergo an adaptive response to maintain Zn …

Low zinc (Zn) in soils reduces yield and grain Zn content. Regulation of ZRT/IRT‐like protein
(ZIP) family genes is a major mechanism in plant adaptation to low and fluctuating Zn in soil …

Zinc deficiency is a common problem leading to severe decreases in grain yield and has
detrimental effects on nutritional quality in cereals. Wild emmer wheat, Triticum turgidum ssp …

It is estimated that nearly 50% of the world's population is at risk of zinc (Zn) deficiency. The
challenge is therefore to increase the Zn content in edible plant parts in order to improve the …

High expression of zinc (Z n)‐regulated, iron‐regulated transporter‐like protein (ZIP) genes
increases root Z n uptake in dicots, leading to high accumulation of Z n in shoots. However …

Zinc (Zn) is an essential element for plants but limited information is currently available on
the molecular basis for Zn2+ transport in crop species. To expand the knowledge on Zn2+ …

Zinc (Zn) is essential for normal plant growth and development. The Zn‐regulated
transporter, iron‐regulated transporter (IRT)‐like protein (ZIP) family members are involved …

Zinc (Zn) depletion adversely affects plant growth. To avoid lethal depletion of cellular Zn,
plants have evolved mechanisms to adjust the expression of genes associated with Zn …

Zinc is an essential mineral for humans and plants and is involved in many physiological
and biochemical processes. In humans, Zn deficiency has been associated with retarded …