Szu-Yun Chen scite author profile

Abstract. Trigger factor (TF) is a highly conserved multi-domain molecular chaperone that exerts its chaperone activity at the ribosomal tunnel exit from which newly synthesized nascent chains emerge. TF also displays promiscuous substrate binding for a large number of cytosolic proteins independent of ribosome binding. We asked how TF recognizes a variety of substrates while existing in a monomer–dimer equilibrium. Paramagnetic nuclear magnetic resonance (NMR) and electron spin resonance (ESR) spectroscopy were used to show that dimeric TF displays a high degree of structural polymorphism in solution. A series of peptides has been generated to quantify their TF binding affinities in relation with their sequence compositions. The results confirmed a previous predication that TF preferentially binds to peptide fragments that are rich in aromatic and positively charged amino acids. NMR paramagnetic relaxation enhancement analysis showed that TF utilizes multiple binding sites, located in the chaperone domain and part of the prolyl trans–cis isomerization domain, to interact with these peptides. Dimerization of TF effectively sequesters most of the substrate binding sites, which are expected to become accessible upon binding to the ribosome as a monomer. As TF lacks ATPase activity, which is commonly used to trigger conformational changes within molecular chaperones in action, the ribosome-binding-associated disassembly and conformational rearrangements may be the underlying regulatory mechanism of its chaperone activity.

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Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone

Huang¹,

Lai²,

Chen³

et al. 2021

Preprint

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Abstract. Trigger factor (TF) is a highly conserved multi-domain molecular chaperone that exerts its chaperone activity at the ribosomal tunnel exit from which newly synthesized nascent chains emerge. TF also displays promiscuous substrate binding for a large number of cytosolic proteins independent of ribosome binding. We asked how TF recognizes a variety of substrates while existing in a monomer-dimer equilibrium. Paramagnetic NMR, electron spin resonance spectroscopy and chemical crosslink show that dimeric TF displays a high degree of structural polymorphism in solution. A series of peptides has been generated to quantify their TF binding affinities in relation with their sequence compositions. The results confirmed a previous predication that TF preferentially binds to peptide fragments that are rich in aromatic and positively charged amino acids. NMR paramagnetic relaxation enhancement analysis showed that TF utilizes multiple binding sites, located in the chaperone domain and part of the prolyl trans/cis isomerisation domain, to interact with these peptides. Dimerization of TF effectively sequesters most of substrate binding sites, which are expected to become accessible upon binding to the ribosome as a monomer. As TF lacks ATPase activity, which is commonly used to trigger conformational changes within molecular chaperones in action, the ribosome-binding-associated disassembly and conformational rearrangements may be the underlying regulatory mechanism of its chaperone activity.

show abstract

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Supplementary material to "Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone"

Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone

Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone

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Szu-Yun Chen

The effects of woodchip biochar application on crop yield, carbon sequestration and greenhouse gas emissions from soils planted with rice or leaf beet

Supplementary material to &quot;Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone&quot;

Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone

Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone

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Supplementary material to "Structural polymorphism and substrate promiscuity of a ribosome-associated molecular chaperone"