The dependence of Escherichia coli asparaginase II formation on cyclic AMP and cyclic AMP receptor protein.

The amount of asparaginase II in an Escherichia coli wild-type strain (cya+, crp+) markedly increased upon a shift from aerobic to anaerobic growth. However, no such increase occurred in a mutant (cya) lacking cyclic AMP synthesis unless supplemented with exogenous cyclic AMP. Since a mutant (crp) deficient in cyclic AMP receptor protein also did not support the anaerobic formation of this enzyme, it is concluded that the formation of E. coli asparaginase II depends on both cyclic AMP and cyclic AMP receptor protein.     

A monoclonal antibody that inhibits cyclic AMP binding by the Escherichia coli cyclic AMP receptor protein

The monoclonal antibody (mAb) 64D1 was found to inhibit cAMP binding by the cAMP receptor protein (CRP) from Escherichia coli (Li, X.-M., and Krakow, J. S. (1985) J. Biol. Chem. 260, 4378-4383). CRP is relatively resistant to attack by the Staphylococcus aureus V8 protease, chymotrypsin, trypsin, and subtilisin whereas both mAb 64D1-CRP and cAMP-CRP are attacked by these proteases yielding N-terminal core fragments. The fragment patterns resulting from proteolysis of mAb 64D1-CRP and cAMP-CRP differ indicating that the CRP in each complex is in a different conformation. The data presented indicate that the preferred conformation of the antigenic site for mAb 64D1 is present in unliganded CRP. Binding of mAb 64D1 to CRP is inhibited at high cAMP concentration. Formation of a stable cAMP-CRP-lac P+-RNA polymerase open promoter complex resistant to dissociation by mAb 64D1 occurs at a much lower cAMP concentration. The observed increase in resistance to mAb 64D1 may reflect a possible conformational change in CRP effected by contact with RNA polymerase in the open promoter complex.     

Cooperative non-specific DNA binding of the N-terminal core of the cyclic AMP receptor protein of Escherichia coli and its modulation by cyclic AMP

The non-specific DNA binding of CRP and its N-terminal core, alpha CRP, to a 298 base pair DNA fragment, in the presence and absence of cAMP, has been studied using the nitrocellulose filter binding technique and analysed quantitatively using the theory of Clore et al. [J. Mol. Biol. (1982) 155, 447-466]. It is shown that both CRP and alpha CRP bind cooperatively to DNA. At an ionic strength of 100 mM and pH 7.5, the intrinsic equilibrium association constant for the binding of alpha CRP to DNA is approximately 10-times smaller than that for CRP, but the cooperativity parameter is approximately 17-times larger for alpha CRP than CRP. cAMP exerts its effect solely on the intrinsic equilibrium constant and does not alter the cooperativity. In the case of alpha CRP, cAMP reduces the intrinsic equilibrium association constant by a factor of 3, in contrast to the case of CRP where cAMP increases it by a factor of 3. The possible location of the DNA binding site present in the N-terminal core of CRP is discussed in the light of crystallographic data on the cAMP . CRP complex [McKay et al. (1982) J. Biol. Chem. 257, 9518-9524].     

Differential regulation by cyclic AMP of starvation protein synthesis in Escherichia coli

Of the 30 carbon starvation proteins whose induction has been previously shown to be important for starvation survival of Escherichia coli, two-thirds were not induced in cya or crp deletion mutants of E. coli at the onset of carbon starvation. The rest were induced, although not necessarily with the same temporal pattern as exhibited in the wild type. The starvation proteins that were homologous to previously identified heat shock proteins belonged to the latter class and were hyperinduced in delta cya or delta crp mutants during starvation. Most of the cyclic AMP-dependent proteins were synthesized in the delta cya mutant if exogenous cyclic AMP was added at the onset of starvation. Furthermore, beta-galactosidase induction of several carbon starvation response gene fusions occurred only in a cya+ genetic background. Thus, two-thirds of the carbon starvation proteins of E. coli require cyclic AMP and its receptor protein for induction; the rest do not. The former class evidently has no role in starvation survival, since delta cya or delta crp mutants of either E. coli or Salmonella typhimurium survived starvation as well as their wild-type parents did. The latter class, therefore, is likely to have a direct role in starvation survival. This possibility is strengthened by the finding that nearly all of the cya- and crp-independent proteins were also induced during nitrogen starvation and, as shown previously, during phosphate starvation. Proteins whose synthesis is independent of cya- and crp control are referred to as Pex (postexponential).     

Binding of the cyclic AMP receptor protein of Escherichia coli to RNA polymerase.

Fluorescence polarization studies were used to study the interaction of a fluorescein-labelled conjugate of the Escherichia coli cyclic AMP receptor protein (F-CRP) and RNA polymerase. Under conditions of physiological ionic strength, F-CRP binds to RNA polymerase holoenzyme in a cyclic AMP-dependent manner; the dissociation constant was about 3 microM in the presence of cyclic AMP and about 100 microM in its absence. Binding to core RNA polymerase under the same conditions was weak (Kdiss. approx. 80-100 microM) and independent of cyclic AMP. Competition experiments established that native CRP and F-CRP compete for the same binding site on RNA polymerase holoenzyme and that the native protein binds about 3 times more strongly than does F-CRP. Analytical ultracentrifuge studies showed that CRP binds predominantly to the monomeric rather than the dimeric form of RNA polymerase.     

Steady-state and time-resolved fluorescence studies of conformational changes induced by cyclic AMP and DNA binding to cyclic AMP receptor protein from Escherichia coli.

cAMP receptor protein (CRP), allosterically activated by cAMP, regulates the expression of several genes in Escherichia coli. As binding of cAMP leads to undefined conformational changes in CRP, we performed a steady-state and time-resolved fluorescence study to show how the binding of the ligand influences the structure and dynamics of the protein. We used CRP mutants containing a single tryptophan residue at position 85 or 13, and fluorescently labeled with 1,5-I-AEDANS attached to Cys178. Binding of cAMP in the CRP-(cAMP)2 complex leads to changes in the Trp13 microenvironment, whereas its binding in the CRP-(cAMP)4 complex alters the surroundings of Trp85. Time-resolved anisotropy measurements indicated that cAMP binding in the CRP-(cAMP)2 complex led to a substantial increase in the rotational mobility of the Trp13 residue. Measurement of fluorescence energy transfer (FRET) between labeled Cys178 and Trp85 showed that the binding of cAMP in the CRP-(cAMP)2 complex caused a substantial increase in FRET efficiency. This indicates a decrease in the distance between the two domains of the protein from 26.6 A in apo-CRP to 18.7 A in the CRP-(cAMP)2 complex. The binding of cAMP in the CRP-(cAMP)4 complex resulted in only a very small increase in FRET efficiency. The average distance between the two domains in CRP-DNA complexes, possessing lac, gal or ICAP sequences, shows an increase, as evidenced by the increase in the average distance between Cys178 and Trp85 to approximately 20 A. The spectral changes observed provide new structural information about the cAMP-induced allosteric activation of the protein.     

Regulation of membrane functions and fatty acid composition in Escherichia coli by cyclic AMP receptor protein.

Adenosine 3′,5′-cyclic monophosphate (cAMP) has been shown to be involved in regulating a number of membrane functions in Escherichia coli cells, including various respiratory and transport activities. In this report we show that this regulation is mediated by the cAMP receptor protein (CRP). In addition, data are presented which show that the cAMP-CRP system is involved in regulating the E. coli fatty acid composition.