Structural Basis of Transcription Factor YhaJ for DNT Detection

Overview

Journal iScience

Publisher Cell Press

Date 2023 Oct 12

PMID 37822509

Authors

Myeongbin Kim

Ryun Kang

Tae Jin Jeon

Seong Eon Ryu

Affiliations

Soon will be listed here.

Abstract

Detection of landmines without harming personnel is a global issue. The bacterial transcription factor YhaJ selectively detects metabolites of explosives, and it can be used as a key component of DNT biosensors. However, the wild-type YhaJ has a binding affinity that is not sufficient for the detection of trace amounts of explosives leaked from landmines buried in the soil. Here, we report crystal structures of the effector-binding domain of YhaJ in both the apo- and effector-bound forms. A structural comparison of the two forms revealed that the loop above the primary effector-binding site significantly switches its conformation upon effector binding. The primary effector-binding site involves hydrophobic and polar interactions, having specificity to hydroxyl-substituted benzene compounds. The structures explain the mechanism of activity-enhancing mutations and provide information for the rational engineering of YhaJ biosensors for the sensitive detection of explosives.

Citing Articles

High-affinity promotor binding of YhaJ mediates a low signal leakage for effective DNT detection.

Kim M, Kang R, Park H, Cho E, Lee H, Ryu S Front Microbiol. 2025; 15():1510655.

PMID: 39831117 PMC: 11739112. DOI: 10.3389/fmicb.2024.1510655.

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