Songjie Zhang scite author profile

Globular proteins are usually in equilibrium with unfolded conformations, whereas kinetically stable proteins (KSPs) are conformationally trapped by their high unfolding transition state energy. Kinetic stability (KS) could allow proteins to maintain their activity under harsh conditions, increase a protein's half-life, or protect against misfolding-aggregation. Here we show the development of a simple method for quantifying a protein's KS that involves incubating a protein in SDS at high temperature as a function of time, running the unheated samples on SDS-PAGE, and quantifying the bands to determine the time-dependent loss of a protein's SDS resistance. Six diverse proteins, including two monomer, two dimers, and two tetramers, were studied by this method, and the kinetics of the loss of SDS resistance correlated linearly with their unfolding rate determined by circular dichroism. These results imply that the mechanism by which SDS denatures proteins involves conformational trapping, with a trapping rate that is determined and limited by the rate of protein unfolding. We applied the SDS trapping of proteins (S-TraP) method to superoxide dismutase (SOD) and transthyretin (TTR), which are highly KSPs with native unfolding rates that are difficult to measure by conventional spectroscopic methods. A combination of S-TraP experiments between 75 and 90 °C combined with Eyring plot analysis yielded an unfolding half-life of 70 ± 37 and 18 ± 6 days at 37 °C for SOD and TTR, respectively. The S-TraP method shown here is extremely accessible, sample-efficient, cost-effective, compatible with impure or complex samples, and will be useful for exploring the biological and pathological roles of kinetic stability.

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Do Prokaryotes Have More Kinetically Stable Proteins Than Eukaryotic Organisms?

Xia

Zhang

Solina

et al. 2010

Biochemistry

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Upon folding, some proteins become conformationally trapped, presumably to protect against aggregation or premature degradation. To probe the occurrence of this property, known as kinetic stability, we used a diagonal two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis method to probe biologically diverse organisms. The results show that kinetic stability is prevalent in prokaryotes, especially thermophiles, but uncommon in eukaryotic organisms, thereby suggesting that this property might be crucial for the adaptation and survival of less complex prokaryotic organisms.

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Identifying kinetically stable proteins with capillary electrophoresis

et al. 2010

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Unlike most proteins, which are in equilibrium with partially and globally unfolded conformations, kinetically stable proteins (KSPs) are trapped in their native conformations and are often resistant to harsh environment. Based on a previous correlation between kinetic stability (KS) and a protein's resistance to sodium dodecyl sulfate (SDS), we show here a simple method to identify KSPs by SDS-capillary electrophoresis (CE). Control non-KSPs were fully denatured by SDS and formed protein:SDS complexes that exhibited similar mobility in CE. In contrast, KSPs bound fewer SDS molecules, and showed a very different migration time and peak pattern in CE, thereby providing some insight about the structural heterogeneity of SDS:protein complexes and the relative KS of the various proteins.

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Sarkosyl: A milder detergent than SDS for identifying proteins with moderately high hyperstability using gel electrophoresis

Thibeault

Patrick

Martin

et al. 2019

Analytical Biochemistry

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Proteomics Analysis of Kinetically Stable Proteins

Xia¹,

Manning²,

Zhang³

et al. 2012

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Songjie Zhang

Quantifying the Kinetic Stability of Hyperstable Proteins via Time-Dependent SDS Trapping

Do Prokaryotes Have More Kinetically Stable Proteins Than Eukaryotic Organisms?

Identifying kinetically stable proteins with capillary electrophoresis

Sarkosyl: A milder detergent than SDS for identifying proteins with moderately high hyperstability using gel electrophoresis

Proteomics Analysis of Kinetically Stable Proteins

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