James G. Harman scite author profile

The CRP:cAMP complex functions as a transcription factor that facilitates RNA polymerase recognition of several bacterial promoters. Detailed crystal structure information is available for CRP:(cAMP)2 and for CRP:(cAMP)2 complexed with DNA. In the crystalline environment, CRP:(cAMP)2 subunits are asymmetrically related; one subunit has a closed conformation and the other has an open conformation. The CRP:(cAMP)2 complexed with DNA shows both subunits in a closed conformation. We have studied the molecular dynamics of CRP:(cAMP)2 in noncrystalline environments. CRP:(cAMP)2 was simulated for 625 ps in vacuo and for 140 ps in solution. The crystal structure of CRP:(cAMP)2 in the absence of DNA was used as the initial conformation. Molecule optimal dynamic coordinates (MODCs) (García A, 1992, Phys Rev Lett 68:2696) were used to analyze protein conformations sampled during the course of the simulations. Two MODCs define a transition of the open subunit to a closed subunit conformation during the first 125 ps of simulation in vacuo; the resulting subunit conformation is similar to that observed in CRP:(cAMP)2:DNA crystals. Simulation of CRP:(cAMP)2 in solution showed that a transition from the open to the closed state also occurs when water is explicitly included in the calculations. These calculations suggest that the asymmetric conformation of CRP:(cAMP)2 is stabilized by crystal lattice interactions. The predicted solution conformation is more symmetric, with both subunits in a closed conformation.

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Mutagenesis of the cyclic AMP receptor protein ofEscherichia coli: targeting positions 83, 127 and 128 the cyclic nucleotide binding pocket

Lee

Glasgow

Leu

et al. 1994

Nucl Acids Res

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The cyclic 3', 5' adenosine monophosphate (cAMP) binding pocket of the cAMP receptor protein (CRP) of Escherichia coli was mutagenized to substitute cysteine or glycine for serine 83; cysteine, glycine, isoleucine, or serine for threonine 127; and threonine or alanine for serine 128. Cells that expressed the binding pocket residue-substituted forms of CRP were characterized by measurements of beta-galactosidase activity. Purified wild-type and mutant CRP preparations were characterized by measurement of cAMP binding activity and by their capacity to support lacP activation in vitro. CRP structure was assessed by measurement of sensitivity to protease and DTNB-mediated subunit crosslinking. The results of this study show that cAMP interactions with serine 83, threonine 127 and serine 128 contribute to CRP activation and have little effect on cAMP binding. Amino acid substitutions that introduce hydrophobic amino acid side chain constituents at either position 127 or 128 decrease CRP discrimination of cAMP and cGMP. Finally, cAMP-induced CRP structural change(s) that occur in or near the CRP hinge region result from cAMP interaction with threonine 127; substitution of threonine 127 by cysteine, glycine, isoleucine, or serine produced forms of CRP that contained, independently of cAMP binding, structural changes similar to those of the wild-type CRP:cAMP complex.

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Cyclic AMP in prokaryotes

1992

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Cyclic AMP (cAMP) is found in a variety of prokaryotes including both eubacteria and archaebacteria. cAMP plays a role in regulating gene expression, not only for the classic inducible catabolic operons, but also for other categories. In the enteric coliforms, the effects of cAMP on gene expression are mediated through its interaction with and allosteric modification of a cAMP-binding protein (CRP). The CRP-cAMP complex subsequently binds specific DNA sequences and either activates or inhibits transcription depending upon the positioning of the complex relative to the promoter. Enteric coliforms have provided a model to explore the mechanisms involved in controlling adenylate cyclase activity, in regulating adenylate cyclase synthesis, and in performing detailed examinations of CRP-cAMP complex-regulated gene expression. This review summarizes recent work focused on elucidating the molecular mechanisms of CRP-cAMP complex-mediated processes. For other bacteria, less detail is known. cAMP has been implicated in regulating antibiotic production, phototrophic growth, and pathogenesis. A role for cAMP has been suggested in nitrogen fixation. Often the only data that support cAMP involvement in these processes includes cAMP measurement, detection of the enzymes involved in cAMP metabolism, or observed effects of high concentrations of the nucleotide on cell growth.

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James G. Harman

Allosteric regulation of the cAMP receptor protein

Cyclic AMP in prokaryotes.

Simulations of CRP:(cAMP)₂ in noncrystalline environments show a subunit transition from the open to the closed conformation

Mutagenesis of the cyclic AMP receptor protein ofEscherichia coli: targeting positions 83, 127 and 128 the cyclic nucleotide binding pocket

Cyclic AMP in prokaryotes

Contact Info

Product

Resources

About

James G. Harman

Allosteric regulation of the cAMP receptor protein

Cyclic AMP in prokaryotes.

Simulations of CRP:(cAMP)2 in noncrystalline environments show a subunit transition from the open to the closed conformation

Mutagenesis of the cyclic AMP receptor protein ofEscherichia coli: targeting positions 83, 127 and 128 the cyclic nucleotide binding pocket

Cyclic AMP in prokaryotes

Contact Info

Product

Resources

About

Simulations of CRP:(cAMP)₂ in noncrystalline environments show a subunit transition from the open to the closed conformation