Abstract Zinc (Zn) deficiency is recognized as a global crisis as it is observed in half of all agricultural soils. However, the molecular mechanisms that drive plant physiological responses to soil Zn deficiency are not well understood. We used an untargeted metabolomics approach to search for metabolites exuded from roots during Zn deficiency stress, which led to the discovery of a collection of secreted small defensin-like peptides in Arabidopsis thaliana (named Zinc-Deficiency Responsive Peptides (ZDRPs)). Phylogenetic analysis and untargeted metabolomics revealed ZDRPs in at least eleven accessions of A. thaliana and nine members of the Brassicaceae family. Analysis of Arabidopsis gene mutants and overexpressing lines, in combination with chemical complementation experiments, unveiled a critical role of these peptides in plant root growth. We hypothesize that Brassicaceae secreted peptides enable plants to expand their root mass to reach Zn-rich soil layers and optimize Zn uptake. These data reveal a critical relationship between plant survival, Zn status, root morphology and peptide production. Taken together, our results expand our knowledge regarding micronutrient deficiency responses in plants and could enable in engineering approaches to make plants more resilient to low Zn conditions. Significance Zinc deficiency is the most abundant micronutrient deficiency affecting about 50% of arable lands thus presenting a high burden for plant health and agriculture globally. In this study, we reveal a metabolic strategy by Brassicaceae to deal with low Zn concentrations. We characterize the role of peptides expressed upon zinc deficiency in a variety of important crop plants. The discovery of a cryptic class of peptides that are made by plant roots specifically suffering from Zn deficiency provides critical insight into the molecular mechanisms by which plants dynamically acclimate to nutrient-limited soils. The identification of peptides actively secreted by zinc-deprived plants has translational value for sustainable agriculture, human health, and bioengineering approaches to enable tolerance to low zinc.