Folding of the Pit1 homeodomain near the speed limit

Banachewicz, Wiktor; Johnson, Christopher M.; Fersht, Alan R.

doi:10.1073/pnas.1017832108

Cited by 10 publications

(12 citation statements)

References 24 publications

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“…The value of ΔG D-N for wild type calculated from the global fit is 4.2 kcal mol −1 , and from the free fit, with a larger error, 4 kcal mol −1 . 2 H∕H-exchange data previously gave a value of 4-5 kcal mol −1 (14).…”

Section: Resultsmentioning

confidence: 99%

“…The folding kinetics of wild-type Pit1 resembles that of EnHD, which folds via a discrete intermediate in which the HTH motif is an autonomous, stable domain, whose formation and stability are uncoupled from that of H1 (14). But, a detailed Φ-value analysis shows clearly that formation of its intermediate has the formation of all three helices closely coupled.…”

Section: Discussionmentioning

confidence: 99%

“…We have found that Pit1, the 63-residue homeodomain from pituitary-specific transcription factor (13), folds in better separated phases of 2.3 and 46 μs with more convenient fluorescence changes from its endogenous Trp probe, Trp48, analogous to that in EnHD (14). The 2.3-μs phase is a partly diffusion-limited collapse of the denatured state to give a folding intermediate, I.…”

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confidence: 99%

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Malleability of folding intermediates in the homeodomain superfamily

Banachewicz

Religa

Schaeffer

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Members of the homeodomain superfamily are three-helix bundle proteins whose second and third helices form a helix-turn-helix motif (HTH). Their folding mechanism slides from the ultrafast, three-state framework mechanism for the engrailed homeodomain (EnHD), in which the HTH motif is independently stable, to an apparent two-state nucleation-condensation model for family members with an unstable HTH motif. The folding intermediate of EnHD has nearly native HTH structure, but it is not docked with helix1. The determinant of whether two-or three-state folding was hypothesized to be the stability of the HTH substructure. Here, we describe a detailed Φ-value analysis of the folding of the Pit1 homeodomain, which has similar ultrafast kinetics to that of EnHD. Formation of helix1 was strongly coupled with formation of HTH, which was initially surprising because they are uncoupled in the EnHD folding intermediate. However, we found a key difference between Pit1 and EnHD: The isolated peptide corresponding to the HTH motif in Pit1 was not folded in the absence of H1. Independent molecular dynamics simulations of Pit1 unfolding found an intermediate with H1 misfolded onto the HTH motif. The Pit1 folding pathway is the connection between that of EnHD and the slower folding homeodomains and provides a link in the transition of mechanisms from two-to three-state folding in this superfamily. The malleability of folding intermediates can lead to unstable substructures being stabilized by a variety of nonnative interactions, adding to the continuum of folding mechanisms.protein folding | temperature jump | diffusion collision | transition state T he nucleation-condensation mechanism was proposed from a Φ-value analysis of the folding of the protein chymotrypsin inhibitor 2 (CI2) (1, 2). The individual elements of secondary structure in CI2 are not independently stable, leading to highly cooperative formation of structure in the transition state (TS) for folding in which the helix is the best-formed region, stabilized by long-range interactions. No element of secondary structure is fully formed in the TS and its folding is kinetically two-state (3). It was hypothesized that multistate folding requires independently stable elements of structure or an unstable element of structure being stabilized by interacting with other elements. At the other extreme, the three-helix engrailed homeodomain, EnHD, is a small protein that folds ultrafast via a stable intermediate in line with the framework mechanism, whereby secondary structure forms first followed by docking of the helices (4, 5). Its folding intermediate consists of helix1 (H1) being helical but not docked on to the helix2-turn-helix3 (HTH) DNA binding motif (5, 6). The HTH motif is independently stable in the on-pathway intermediate (7). Studies of other members of the homoedomain superfamily show a slide from this multistate framework folding mechanism to two-state folding and nucleation condensation for members with less stable HTH motifs, consistent with our earlier hypoth...

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Malleability of folding intermediates in the homeodomain superfamily

Banachewicz

Religa

Schaeffer

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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“…Recent advances in stem cell technology have led to the emergence of methods for differentiation of PSCs into multipotent retinal progenitor cells (RPCs), retinal pigment epithelium (RPE), and photoreceptor-like cells (Buchholz et al, 2009; Meyer et al, 2009, 2011; Osakada et al, 2009; Lamba and Reh, 2011). In addition, disease-specific iPSCs have been derived from patients affected by RP (RP-iPSCs) carrying mutations in RP1 , RP9 , PRPH2 , or RHO genes (Jin et al, 2011; Tucker et al, 2011). Interestingly, in contrast with their normal counterpart, RP-iPSC-derived rod photoreceptor cells degenerated with extended culture period.…”

Section: Applicationsmentioning

confidence: 99%

“…Importantly, the degeneration of rod photoreceptors carrying RP9 mutations was counteracted by the antioxidant α-tocopherol but not in those carrying RP1 , PRPH2 , or RHO mutations supporting the idea that the efficacy of the molecule depends on the genetic mutations (Jin et al, 2011). In an other study, the genetic analysis of the RP-iPSCs lead to the identification of the cilia-related gene male germ cell-associated kinase ( MAK ) gene as a cause of RP (Tucker et al, 2011). Similarly, iPSCs has been established from patients affected by gyrate atrophy, an autosomal recessive eye disease characterized by progressive loss of vision due to retinal degeneration.…”

Section: Applicationsmentioning

confidence: 99%

Human Pluripotent Stem Cells: Applications and Challenges in Neurological Diseases

Hibaoui¹,

Féki²

2012

Front. Physio.

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The ability to generate human pluripotent stem cells (hPSCs) holds great promise for the understanding and the treatment of human neurological diseases in modern medicine. The hPSCs are considered for their in vitro use as research tools to provide relevant cellular model for human diseases, drug discovery, and toxicity assays and for their in vivo use in regenerative medicine applications. In this review, we highlight recent progress, promises, and challenges of hPSC applications in human neurological disease modeling and therapies.

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Quantum conformational transition in biological macromolecule

Luo

2017

Quant. Biol.

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Background: Recently we proposed a quantum theory on the conformational change of biomolecule, deduced several equations on protein folding rate from the first principles and discussed the experimental tests of the theory. The article is a review of these works. Methods: Based on the general equation of the conformation-transitional rate several theoretical results are deduced and compared with experimental data through bioinformatics methods. Results: The temperature dependence and the denaturant concentration dependence of the protein folding rate are deduced and compared with experimental data. The quantitative relation between protein folding rate and torsional mode number (or chain length) is deduced and the obtained formula can be applied to RNA folding as well. The quantum transition theory of two-state protein is successfully generalized to multi-state protein folding. Then, how to make direct experimental tests on the quantum property of the conformational transition of biomolecule is discussed, which includes the study of protein photo-folding and the observation of the fluctuation of the fluorescence intensity emitted from the protein folding/unfolding event. Finally, the potential applications of the present quantum folding theory to molecular biological problems are sketched in two examples: the glucose transport across membrane and the induced pluripotency in stem cell. Conclusions: The above results show that the quantum mechanics provides a unifying and logically simple theoretical starting point in studying the conformational change of biological macromolecules. The far-reaching results in practical application of the theory are expected.

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Folding of the Pit1 homeodomain near the speed limit

Cited by 10 publications

References 24 publications

Malleability of folding intermediates in the homeodomain superfamily

Malleability of folding intermediates in the homeodomain superfamily

Human Pluripotent Stem Cells: Applications and Challenges in Neurological Diseases

Quantum conformational transition in biological macromolecule

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