DNA bending and expression of the divergent nagE-B operons.

Repression of the divergent nagE - B operons requires NagC binding to two operators which overlap the nagE and nagB promoters, resulting in formation of a DNA loop. Binding of the cAMP/CAP activator to its site, adjacent to the nagE operator, stabilizes the DNA loop in vitro. The DNA of the nagE-B intergenic region is intrinsically bent, with the bend centred on the CAP site. We show that displacement of the CAP site by 6 bp results in complete derepression of the two operons. This derepression is observed even in the absence of cAMP/CAP binding and despite the fact that the two NagC operators are still in phase, demonstrating that the inherently bent structure of the DNA loop is important for repression. Since no interaction between NagC and CAP has been detected, we propose that the role of CAP in the repression loop is architectural, stabilizing the intrinsic bend. The cAMP/CAP complex is necessary for activation of the nagE-B promoters. In this case protein-protein contacts between CAP and RNA polymerase are necessary for full activation, but at least a part of the activation is likely due to an effect of CAP binding altering DNA structure.     

Operator recognition by the ROK transcription factor family members,NagC and Mlc

NagC and Mlc, paralogous members of the ROK family of proteins with almost identical helix-turn-helix DNA binding motifs, specifically regulate genes for transport and utilization of N-acetylglucosamine and glucose. We previously showed that two amino acids in a linker region outside the canonical helix-turn-helix motif are responsible for Mlc site specificity. In this work we identify four amino acids in the linker, which are required for recognition of NagC targets. These amino acids allow Mlc and NagC to distinguish between a C/G and an A/T bp at positions ±11 of the operators. One linker position, glycine in NagC and arginine in Mlc, corresponds to the major specificity determinant for the two proteins. In certain contexts it is possible to switch repression from Mlc-style to NagC-style, by interchanging this glycine and arginine. Secondary determinants are supplied by other linker positions or the helix-turn-helix motif. A wide genomic survey of unique ROK proteins shows that glycine- and arginine-rich sequences are present in the linkers of nearly all ROK family repressors. Conserved short sequence motifs, within the branches of the ROK evolutionary tree, suggest that these sequences could also be involved in operator recognition in other ROK family members.     

Sequence of cloned enzyme IIN-acetylglucosamine of the phosphoenolpyruvate:N-acetylglucosamine phosphotransferase system of Escherichia coli

In Escherichia coli, N-acetylglucosamine (nag) metabolism is joined to glycolysis via three specific enzymes that are the products of the nag operon. The three genes of the operon, nagA, nagB, and nagE, were found to be carried by a colicin plasmid, pLC5-21, from a genomic library of E. coli [Clarke, L., & Carbon, J. (1976) Cell (Cambridge, Mass.) 9,91-99]. The nagE gene that codes for enzyme IIN-acetylglucosamine of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) was sequenced. The nagE sequence is preceded by a catabolite gene activator protein binding site and ends in a putative rho-independent termination site. The amino acid sequence determined from this DNA sequence shows 44% homology to enzymes IIglucose and IIIglucose of the PTS. Enzyme IIN-acetylglucosamine, which has 648 amino acids and a molecular weight of 68,356, contains a histidine at residue 569 which is homologous to the active site of IIIglc. Sequence homologies with enzymes IIglucose, II beta-glucoside, and IIsucrose indicate that residues His-190, His-213, and His-295 of enzyme IInag are also conserved and that His-190 is probably the second active site histidine. Other sequence homologies among these enzymes II suggest that they contain several sequence transpositions. Preliminary models of the enzymes II are proposed.     

Induction of the nag regulon of Escherichia coli by N-acetylglucosamine and glucosamine: role of the cyclic AMP-catabolite activator protein complex in expression of the regulon.

The divergent nag regulon located at 15.5 min on the Escherichia coli map encodes genes necessary for growth on N-acetylglucosamine and glucosamine. Full induction of the regulon requires both the presence of N-acetylglucosamine and a functional cyclic AMP (cAMP)-catabolite activator protein (CAP) complex. Glucosamine produces a lower level of induction of the regulon. A nearly symmetric consensus CAP-binding site is located in the intergenic region between nagE (encoding EIINag) and nagB (encoding glucosamine-6-phosphate deaminase). Expression of both nagE and nagB genes is stimulated by cAMP-CAP, but the effect is more pronounced for nagE. In fact, very little expression of nagE is observed in the absence of cAMP-CAP, whereas 50% maximum expression of nagB is observed with N-acetylglucosamine in the absence of cAMP-CAP. Two mRNA 5' ends separated by about 100 nucleotides were located before nagB, and both seem to be similarly subject to N-acetylglucosamine induction and cAMP-CAP stimulation. To induce the regulon, N-acetylglucosamine or glucosamine must enter the cell, but the particular transport mechanism used is not important.     

Multiple co-regulatory elements and IHF are necessary for the control of fimB expression in response to sialic acid and N-acetylglucosamine in Escherichia coli K-12

Expression of the FimB recombinase, and hence the OFF-to-ON switching of type 1 fimbriation in Escherichia coli, is inhibited by sialic acid (Neu(5)Ac) and by GlcNAc. NanR (Neu(5)Ac-responsive) and NagC (GlcNAc-6P-responsive) activate fimB expression by binding to operators (O(NR) and O(NC1) respectively) located more than 600 bp upstream of the fimB promoter within the large (1.4 kb) nanC-fimB intergenic region. Here it is demonstrated that NagC binding to a second site (O(NC2)), located 212 bp closer to fimB, also controls fimB expression, and that integration host factor (IHF), which binds midway between O(NC1) and O(NC2), facilitates NagC binding to its two operator sites. In contrast, IHF does not enhance the ability of NanR to activate fimB expression in the wild-type background. Neither sequences up to 820 bp upstream of O(NR), nor those 270 bp downstream of O(NC2), are required for activation by NanR and NagC. However, placing the NanR, IHF and NagC binding sites closer to the fimB promoter enhances the ability of the regulators to activate fimB expression. These results support a refined model for how two potentially key indicators of host inflammation, Neu(5)Ac and GlcNAc, regulate type 1 fimbriation.