Florian Haberl scite author profile

Extensive molecular-dynamics simulations show that the distance between the centers of gravity of the two equivalent helices 3 in the DNA-binding heads of the dimer of the tetracycline-repressor protein (TetR) can be used as a reliable diagnostic of induction. This is not, however, true for X-ray structures, but only for molecular-dynamics simulations. This is suggested to be because TetR is inherently flexible along the coordinate of the allosteric change (as is always likely to be the case for allosteric proteins), so that crystal-packing forces can determine the conformation of the protein. However, the time scale of the allosteric rearrangement in the absence of DNA-complexation is found to be of the order of tens of nanoseconds, so that rearrangements can be observed reproducibly in 100 ns simulations. Metastable (pre-equilibrium) conformations of TetR have been observed for up to 60 ns. The likely equilibrium processes and key features of the TetR system are discussed.

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GPT-3 Models are Poor Few-Shot Learners in the Biomedical Domain

Moradi¹,

Blagec²,

Haberl³

et al. 2021

Preprint

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Molecular Dynamics Characterization of the Structures and Induction Mechanisms of a Reverse Phenotype of the Tetracycline Receptor

et al. 2007

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Molecular-dynamics simulations have been used to investigate the mechanism of induction of a mutant (revTetR) of the tetracycline repressor protein (TetR) that shows the reverse phenotype (i.e., it is induced in the absence of tetracyclines and not in their presence). Low-frequency, normal-mode analyses demonstrate that the reverse phenotype is reproduced by the simulations on the basis of criteria established for wild-type TetR. The reverse phenotype is caused by the fact that the DNA-binding heads in revTetR are closer than the ideal distance needed for DNA-binding when no inducer is present. This distance increases on binding an inducer. Whereas this distance increase makes the interhead distance too large in wild-type TetR, it increases to the ideal value in revTetR. Thus, the mechanism of induction is the same for the two proteins, but the consequences are reversed because of the smaller interhead distance in revTetR when no inducer is present.

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Investigating Protein-Protein and Protein-Ligand Interactions by Molecular Dynamics Simulations

Haberl

Othersen

Seidel

et al.

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Florian Haberl

Induction of the tetracycline repressor: Characterization by molecular‐dynamics simulations

GPT-3 Models are Poor Few-Shot Learners in the Biomedical Domain

Molecular Dynamics Characterization of the Structures and Induction Mechanisms of a Reverse Phenotype of the Tetracycline Receptor

Investigating Protein-Protein and Protein-Ligand Interactions by Molecular Dynamics Simulations

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