Database of articles cited by EMDB/PDB/SASBDB data

Keywords
Structure methods	All X-ray diffraction NMR electron microscopy small angle scattering neutron diffraction fiber diffraction powder diffraction infrared spectroscopy EPR fluorescence transfer theoretical model Hybrid
Author
Journal
IF	>30 >20 >10 >5 all

Title	Dynamic Metabolons Using Stimuli-Responsive Protein Cages.
Journal, issue, pages	J Am Chem Soc, Vol. 146, Issue 10, Page 6686-6696, Year 2024
Publish date	Mar 13, 2024
Authors	Wei Kang / Xiao Ma / Huawei Zhang / Juncai Ma / Chunxue Liu / Jiani Li / Hanhan Guo / Daping Wang / Rui Wang / Bo Li / Chuang Xue /
PubMed Abstract	Naturally evolved metabolons have the ability to assemble and disassemble in response to environmental stimuli, allowing for the rapid reorganization of chemical reactions in living cells to meet ...Naturally evolved metabolons have the ability to assemble and disassemble in response to environmental stimuli, allowing for the rapid reorganization of chemical reactions in living cells to meet changing cellular needs. However, replicating such capability in synthetic metabolons remains a challenge due to our limited understanding of the mechanisms by which the assembly and disassembly of such naturally occurring multienzyme complexes are controlled. Here, we report the synthesis of chemical- and light-responsive protein cages for assembling synthetic metabolons, enabling the dynamic regulation of enzymatic reactions in living cells. Particularly, a chemically responsive domain was fused to a self-assembled protein cage subunit, generating engineered protein cages capable of displaying proteins containing cognate interaction domains on their surfaces in response to small molecular cues. Chemical-induced colocalization of sequential enzymes on protein cages enhances the specificity of the branched deoxyviolacein biosynthetic reactions by 2.6-fold. Further, by replacing the chemical-inducible domain with a light-inducible dimerization domain, we created an optogenetic protein cage capable of reversibly recruiting and releasing targeted proteins onto and from the exterior of the protein cages in tens of seconds by on-off of blue light. Tethering the optogenetic protein cages to membranes enables the formation of light-switchable, membrane-bound metabolons, which can repeatably recruit-release enzymes, leading to the manipulation of substrate utilization across membranes on demand. Our work demonstrates a powerful and versatile strategy for constructing dynamic metabolons in engineered living cells for efficient and controllable biocatalysis.
External links	J Am Chem Soc / PubMed:38425051
Methods	EM (single particle)
Resolution	3.44 - 3.68 Å
Structure data	36228 8jga EMDB-36228, PDB-8jga: Cryo-EM structure of Mi3 fused with FKBP Method: EM (single particle) / Resolution: 3.68 Å 36230 8jgc EMDB-36230, PDB-8jgc: Cryo-EM structure of Mi3 fused with LOV2 Method: EM (single particle) / Resolution: 3.44 Å
Source	Thermotoga maritima (bacteria) thermotoga maritima (strain atcc 43589 / dsm 3109 / jcm 10099 / nbrc 100826 / msb8) (bacteria) homo sapiens (human) aegilops tauschii subsp. strangulata (plant)
Keywords	LYASE / protein cage Scaffold