| Literature DB >> 31548408 |
Xichun Liu1, Qingyuan Hu1, Jinmei Yang2, Shanqing Huang1, Tianbiao Wei1, Weizhong Chen1, Yafeng He1, Dan Wang1, Zhijun Liu3, Kang Wang2, Jianhua Gan4, Hao Chen5.
Abstract
Detoxification of the highly toxic cadmium element is essential for the survival of living organisms.Entities:
Keywords: MerR family; NMR spectroscopy; cadmium transcriptional regulator; cooperative binding; protein crystallography
Year: 2019 PMID: 31548408 PMCID: PMC6789929 DOI: 10.1073/pnas.1908610116
Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN: 0027-8424 Impact factor: 11.205
Fig. 1.Two types of cadmium-binding sites and the allosteric effects triggered by cadmium binding. (A) Cartoon presentations of the Cd/CadR/DNA complex. DNA is colored in orange. The helical axis of DNA is represented as a solid gray line. Cadmium ions are shown as spheres. Close-up view of the first coordination shell of metal-binding sites is shown within the dashed box. (B) Superimposition of crystal structures based on the DBD of a CadR molecule of the metal-free CadR/DNA complex. For clarity, the partner CadR molecule and DNA are omitted. The 3 structures—apo-CadR, metal-free CadR/DNA complex, and Cd/CadR/DNA complex—are in wheat, magenta, and yellow, respectively. The allosteric movements triggered by cadmium binding are represented by dashed and solid arrows. (C) ITC curves showing that CadR has a clear, stepwise binding model toward the cadmium ion. (D) Raman peak of sulfhydryl group (∼2,563 cm−1) in CadR with a different molar ratio of Cd(II) ions.
Fig. 2.Site I and site II are both allosteric sites. (A) The phenylalanine biomarker, Phe49, located at the interface between the DBD and MBD for probing the allosteric motion triggered by cadmium binding in site I and site II. Hydrogen bonds are represented by red dashed lines. (B) NMR spectra of the 19F-labeled protein titrated by cadmium ion. (C) Close up view of the interaction network around the His-tail region. The cadmium ions in sites S2 and S2′ are shown as spheres. The His-tail region (residues 139 to 145, SHVGRSH) is shown as yellow sticks. (D) Schematic model representing the topological arrangement of metal-binding sites and the DBD. The metal-binding sites are connected by the dimerization helices and the His-tail. The dimerization helices (α5 and α5′) are represented by double lines. The allosteric regulation pathways are indicated by arrows. The long-range communication of 2 DBDs through the His-tail is indicated as a wavy line.
Fig. 3.NMR spectroscopy verifying that the His-tail region contributes to cadmium binding in solution. (A) NMR spectra of the 19F-labeled His-tail variant (CadRG142F) titrated by Cd(II) at 298 K. The peaks contributed by 4-19F-Phe49 and 4-19F-Phe142 are assigned as black and red arrows, respectively. The His-tail region is represented by red dashed lines (“off” state) or arrows (“on” state). (B) NMR spectra of full 113Cd-bound CadRWT (Left) and CadRWT-DNA (Right) performed on a 500-MHz spectrometer at 308.5 K in phosphate buffer (relaxation delay, 10 s; number of scans, 8,000). The 113Cd-loaded protein sample is divided into 2 equal parts. One part has the added 25-bp promoter DNA (113Cd-CadRWT-DNA), while the other does not (113Cd-CadRWT). The chemical shift of cadmium-binding sites and the ratio of relative integrated intensity of peaks are indicated by the numbers in black.
Fig. 4.Cooperation of 2 sites triggers the specific selectivity of cadmium ions. (A) Cadmium sensitivity study using the luxAB reporter system in vivo. CadRWT (black) and its variants, CadRN81A (a, blue), CadRC77S/C112S/C119S (b, orange), and CadRH87A/H90A (c, green) are tested. Error bars represent SD. (B) The scaffold of the MBD in CadRWT and CadRH87A/H90A. Glu62 in the DBD is omitted for clarity. Site I and site II are shown as red and magenta circles, respectively. The coordination bonds are shown as dashed lines. (C) A putative model of the partially distorted state promoter (cyan) between the repressor state (magenta) and activator state (yellow). The σ factor and core enzyme of RNAP are colored in marine and gray, respectively. The −10 and −35 elements are indicated by the orange mesh.