Structural homology between rbs repressor and ribose binding protein implies functional similarity.

The deduced amino acid sequence of the rbs repressor, RbsR, of Escherichia coli is homologous over its C-terminal 272 residues to the entire sequence of the periplasmic ribose binding protein. RbsR is also homologous to a family of bacterial repressor proteins including LacI. This implies that the structure of the repressor consists of a two-domain binding protein portion attached to a DNA-binding domain having the four-helix structure of the LacI headpiece. The implications of these relationships to the mechanism of this class of repressors are discussed.     

AbrB modulates expression and catabolite repression of a Bacillus subtilis ribose transport operon.

A Bacillus subtilis ribose transport operon (rbs) was shown to be subject to AbrB-mediated control through direct AbrB-DNA binding interactions in the vicinity of the promoter. Overproduction of AbrB was shown to relieve catabolite repression of rbs during growth in the presence of poorer carbon sources such as arabinose but had much less effect when cells were grown in the presence of glucose, a rapidly metabolizable carbon source. A ccpA mutation relieved catabolite repression of rbs under all conditions tested. One of the AbrB-binding sites on the rbs promoter contains the putative site of action for the B. subtilis catabolite repressor protein CcpA, suggesting that competition for binding to this site could be at least partly responsible for modulating rbs expression during carbon-limited growth.     

Ribokinase from Escherichia coli K12. Nucleotide sequence and overexpression of the rbsK gene and purification of ribokinase

The nucleotide sequence of a 1455-base pair TaqI-HinfI fragment of the rbs operon of Escherichia coli K12 has been determined. It includes the 3' terminus of rbsB (the gene for ribose-binding protein) and the entire rbsK gene, encoding ribokinase. Potential consensus promoter sequences and a stable stem-loop structure are present in the rbsB-rbsK intercistronic region. The regulatory significance of these sequence features is discussed with respect to the rbs operon. rbsK has been cloned downstream from the Serratia marcescens trp promoter on a multicopy plasmid. Cells harboring this plasmid, when grown on minimal ribose plus ampicillin, express ribokinase at the level of 2% of the soluble protein, and induction with indoleacrylic acid raises ribokinase levels another 8-fold. Ribokinase has been purified to homogeneity (216 mumol/min/mg) from a strain harboring this plasmid. Protein sequence analyses of peptides generated by cyanogen bromide cleavage and o-iodosobenzoic acid cleavage confirmed the translation initiation site and the reading frame of the DNA sequence. Amino acid compositions of native ribokinase and the C-terminal dodecapeptide agree with the predicted amino acid compositions, confirming the accuracy of the DNA sequence and the translation termination site.     

Nucleotide sequence of the gene encoding the repressor for the histidine utilization genes of Klebsiella aerogenes.

The hutC gene of Klebsiella aerogenes encodes a repressor that regulates expression of the histidine utilization (hut) operons. The DNA sequence of a region known to contain hutC was determined and shown to contain two long rightward-reading open reading frames (ORFs). One of these ORFs was identified as the 3' portion of the hutG gene. The other ORF was the hutC gene. The repressor predicted from the hutC sequence contained a helix-turn-helix motif strongly similar to that seen in other DNA-binding proteins, such as lac repressor and the catabolite gene activator protein. This motif was located in the N-terminal portion of the protein, and this portion of the protein seemed to be sufficient to allow repression of the hutUH operon but insufficient to allow interaction with the inducer. The presence of a promoterlike sequence and a ribosome-binding site immediately upstream of the hutC gene explained the earlier observation that hutC can be transcribed independently of the other hut operon genes. The predicted amino acid sequence of hut repressor strongly resembled that of the corresponding protein from Pseudomonas putida (S. L. Allison and A. T. Phillips, J. Bacteriol. 172:5470-5476, 1990). An unexpected, leftward-reading ORF extending from about the middle of hutC into the preceding (hutG) gene was also detected. The deduced amino acid sequence of this leftward ORF was quite distinct from that of an unexpected ORF of similar size found immediately downstream of the P. putida hutC gene. The nonstandard codon usage of this leftward ORF and the expression of repressor activity from plasmids with deletions in this region made it unlikely that this ORF was necessary for repressor activity.     

Mechanisms causing rapid and parallel losses of ribose catabolism in evolving populations of Escherichia coli B

Twelve populations of Escherichia coli B all lost D-ribose catabolic function during 2,000 generations of evolution in glucose minimal medium. We sought to identify the population genetic processes and molecular genetic events that caused these rapid and parallel losses. Seven independent Rbs(-) mutants were isolated, and their competitive fitnesses were measured relative to that of their Rbs(+) progenitor. These Rbs(-) mutants were all about 1 to 2% more fit than the progenitor. A fluctuation test revealed an unusually high rate, about 5 x 10(-5) per cell generation, of mutation from Rbs(+) to Rbs(-), which contributed to rapid fixation. At the molecular level, the loss of ribose catabolic function involved the deletion of part or all of the ribose operon (rbs genes). The physical extent of the deletion varied between mutants, but each deletion was associated with an IS150 element located immediately upstream of the rbs operon. The deletions apparently involved transposition into various locations within the rbs operon; recombination between the new IS150 copy and the one upstream of the rbs operon then led to the deletion of the intervening sequence. To confirm that the beneficial fitness effect was caused by deletion of the rbs operon (and not some undetected mutation elsewhere), we used P1 transduction to restore the functional rbs operon to two Rbs(-) mutants, and we constructed another Rbs(-) strain by gene replacement with a deletion not involving IS150. All three of these new constructs confirmed that Rbs(-) mutants have a competitive advantage relative to their Rbs(+) counterparts in glucose minimal medium. The rapid and parallel evolutionary losses of ribose catabolic function thus involved both (i) an unusually high mutation rate, such that Rbs(-) mutants appeared repeatedly in all populations, and (ii) a selective advantage in glucose minimal medium that drove these mutants to fixation.     

Substituting an alpha-helix switches the sequence-specific DNA interactions of a repressor

It has been suggested that many DNA-binding proteins use an alpha-helix for specific sequence recognition. We have used amino acid sequence homologies to identify the presumptive DNA-recognition helices in two related proteins whose structures are unknown--the repressor and cro protein of bacteriophage 434. The 434 repressor and cro protein each bind to three similar sites in the rightward phage 434 operator, OR, and they make different contacts in each binding site, as revealed by the chemical probe dimethyl sulfate. We substituted the putative recognition alpha-helix of 434 repressor with the putative recognition alpha-helix of 434 cro protein to create a hybrid protein named repressor*. The specific DNA contacts made by repressor* are like those of 434 cro protein.     

Studies of the repressor (BlaI) of β-lactamase synthesis in Staphylococcus aureus

Purified BlaI, the putative repressor of the β-lactamase operon in Staphylococcus aureus , binds specifically to two regions of dyad symmetry (operators) located in the blaZ–blaR1 intergenic region. BlaI binds with similar affinity to the two regions and to the related sequence upstream of the mec gene found in methicillin-resistant strains of S. aureus , providing physical evidence for the cross-talk previously observed between these systems. A change from a lysine in the N-terminus of BlaI to an alanine or deletion of the C-terminal 23 amino acids severely reduces its DNA-binding ability, demonstrating the functional importance of both the N- and C-termini. An operator DNA–protein complex observed with crude cell lysates from repressed cells, indistinguishable from that observed with purified BlaI, was eliminated by induction of the β-lactamase operon. Furthermore, BlaI is proteolytically cleaved in response to the addition of inducer in a blaR1 -dependent manner, providing primary evidence for the molecular basis of induction. Thus, BlaI is shown to be the repressor of the β-lactamase system.     

Regulation of the glyoxylate bypass operon: cloning and characterization of iclR.

In Escherichia coli, expression of the glyoxylate bypass operon appears to be controlled, in part, by the product of iclR+. Mutations in iclR have been found to yield constitutive expression of this operon, suggesting that iclR+ encodes a repressor protein. We have cloned iclR+ by taking advantage of its tight genetic linkage with the glyoxylate bypass operon. The clone complemented a mutant allele of iclR in trans, restoring an inducible phenotype for this operon. Deletion analysis identified a region of ca. 900 base pairs that was necessary and sufficient for complementation. The nucleotide sequence of the insert was then determined. Translation of this sequence revealed an open reading frame capable of encoding a protein with Mr 29,741 preceded by a potential Shine-Dalgarno ribosome-binding site. The deduced amino acid sequence includes a region at the amino terminus that may form a helix-turn-helix motif, a structure found in many DNA-binding domains.     

Radiation damage to a DNA-binding protein. Combined circular dichroism and molecular dynamics simulation analysis

The E. coli lactose operon, the paradigm of gene expression regulation systems, is the best model for studying the effect of radiation on such systems. The operon function requires the binding of a protein, the repressor, to a specific DNA sequence, the operator. We have previously shown that upon irradiation the repressor loses its operator binding ability. The main radiation-induced lesions of the headpiece have been identified by mass spectrometry. All tyrosine residues are oxidized into 3,4-dihydroxyphenylalanine (DOPA). In the present study we report a detailed characterization of the headpiece radiation-induced modification. An original approach combining circular dichroism measurements and the analysis of molecular dynamics simulation of headpieces bearing DOPA-s instead of tyrosines has been applied. The CD measurements reveal an irreversible modification of the headpiece structure and stability. The molecular dynamics simulation shows a loss of stability shown by an increase in internal dynamics and allows the estimation of the modifications due to tyrosine oxidation for each structural element of the protein. The changes in headpiece structure and stability can explain at least in part the radiation-induced loss of binding ability of the repressor to the operator. This conclusion should hold for all proteins containing radiosensitive amino acids in their DNA-binding site.     

Escherichia coli gene purR encoding a repressor protein for purine nucleotide synthesis. Cloning, nucleotide sequence, and interaction with the purF operator

The Escherichia coli gene purR, encoding a repressor protein, was cloned by complementation of a purR mutation. Gene purR on a multicopy plasmid repressed expression of purF and purF-lacZ and reduced the growth rate of host cells by limiting the rate of de novo purine nucleotide synthesis. The level of a 1.3-kilobase purR mRNA was higher in cells grown with excess adenine, suggesting that synthesis of the repressor may be regulated. The chromosomal locus of purR was mapped to coordinate 1755-kb on the E. coli restriction map (Kohara, Y., Akiyama, K., and Isono, K. (1987) Cell 50, 495-508). Pur repressor bound specifically to purF operator DNA as determined by gel retardation and DNase I footprinting assays. The amino acid sequence of Pur repressor was derived from the nucleotide sequence. Pur repressor subunit contains 341 amino acids and has a calculated Mr of 38,179. Pur repressor is 31-35% identical with the galR and cytR repressors and 26% identical with the lacI repressor. These four repressors are likely homologous. Amino acid sequence similarity is greatest in an amino-terminal region presumed to contain a DNA-binding domain. A similarity is also noted in the operator sites for these repressors.     

Cloning and nucleotide sequence of the Bacillus subtilis ansR gene, which encodes a repressor of the ans operon coding for L-asparaginase and L-aspartase.

Previous work has shown that expression of the Bacillus subtilis ans operon which codes for L-asparaginase and L-aspartase, is both increased and made insensitive to repression by NH4+ by the aspH1 mutation. In current work, the gene in which the aspH1 mutation resides has been identified and sequenced; this gene, termed ansR, is immediately upstream of, but transcribed in the opposite direction from, the ans operon. The promoter region of ansR contains -10 and -35 sequences similar to those recognized by RNA polymerase containing the major vegetative-cell sigma factor sigma A, and ansR appears to be monocistronic. The ansR gene codes for a 116-residue protein, but the aspH1 mutant allele has an additional guanine residue at codon 55, resulting in generation of a truncated polypeptide of only 58 residues. Insertional inactivation of ansR resulted in a phenotype identical to that of the aspH1 mutant. The predicted amino acid sequence of the ansR gene product (AnsR) was homologous to that of the repressor of B. subtilis prophage PBSX, and a helix-turn-helix motif, characteristic of many DNA-binding proteins, was present in the AnsR amino-terminal region. These results suggest that ansR codes for a repressor of the ans operon.     

Radiation-induced oxidative damage to the DNA-binding domain of the lactose repressor

Understanding the cellular effects of radiation-induced oxidation requires the unravelling of key molecular events, particularly damage to proteins with important cellular functions. The Escherichia coli lactose operon is a classical model of gene regulation systems. Its functional mechanism involves the specific binding of a protein, the repressor, to a specific DNA sequence, the operator. We have shown previously that upon irradiation with gamma-rays in solution, the repressor loses its ability to bind the operator. Water radiolysis generates hydroxyl radicals (OH* radicals) which attack the protein. Damage of the repressor DNA-binding domain, called the headpiece, is most likely to be responsible of this loss of function. Using CD, fluorescence spectroscopy and a combination of proteolytic cleavage with MS, we have examined the state of the irradiated headpiece. CD measurements revealed a dose-dependent conformational change involving metastable intermediate states. Fluorescence measurements showed a gradual degradation of tyrosine residues. MS was used to count the number of oxidations in different regions of the headpiece and to narrow down the parts of the sequence bearing oxidized residues. By calculating the relative probabilities of reaction of each amino acid with OH. radicals, we can predict the most probable oxidation targets. By comparing the experimental results with the predictions we conclude that Tyr7, Tyr12, Tyr17, Met42 and Tyr47 are the most likely hotspots of oxidation. The loss of repressor function is thus correlated with chemical modifications and conformational changes of the headpiece.     

Deoxyribonucleic acid-binding studies on the hut repressor and mutant forms of the hut repressor of Salmonella typhimurium.

In Salmonella typhimurium the genes coding for the enzymes of histidine utilization (hut) are clustered in two adjacent operons, hutMIGC and hut(P,R,Q)UH. A single repressor, the product of the C gene, regulates both operons by binding at two operator sites, one near M and one in (P,R,Q). The deoxyribonucleic acid (DNA)-binding activity of the repressor was measured using DNA's containing separate operators. The repressor had greater activity when assayed using DNA containing the operator of the (P,R,Q)UH operon than when assayed using DNA containing the operator of the MIGC operon. The binding to either operator was absent in the presence of the inducer, urocanate. The DNA-binding activities were also determined for two super-repressors. The super-repressors had altered DNA-binding properties, although the self-regulated nature of the repressors complicated the analysis of the results. A purfication procedure for the wild-type repressor is presented. The purified repressor was somewhat unstable, and additional experiments using it were not performed.