Recently, whole-cell biosensors have become a favorable alternative to conventional chemical methods for monitoring heavy metal pollution in public health and ecosystems. However, the inherent trade-off between sensitivity and specificity has hindered their development over decades. Here, I generated a sensitive, specific, and high-response whole- cell biosensor for cadmium ions through genetic engineering of Escherichia coli. Genetic modules harboring CadR homologs and the cognate promoters were introduced into E. coli for cadmium detection. Reconfiguring the metal transport system of E. coli enabled the enrichment of intracellular cadmium ions, thereby enhancing the sensitivity of E. coli bearing CadR homologs to detect cadmium ions. Also, depriving interfering metal species in the engineered E. coli allowed it to respond to cadmium ions specifically. The resulting cadmium biosensor exhibited a detection limit of 3 nM, a linear response range from 0 to 200 nM, and a maximal 777-fold signal change. In addition, a smartphone-assisted method capable of measuring cadmium ions in irrigation water and human urine was developed. This assay was cost-effective, user-friendly and scalable to screen large amounts of agricultural and medical samples. Moreover, fluorescence polarization measurement was performed to dissect the molecular basis of metal reactivity of two CadR homologs in vitro. Collectively, my thesis work contributes to the develpoment of a cadmium biosensor and underscores the potential and value of whole-cell biosensors.