Mutations in the araC regulatory gene of Escherichia coli B/r that affect repressor and activator functions of AraC protein.

Mutations in the araC gene of Escherichia coli B/r were isolated which alter both activation of the araBAD operon expression and autoregulation. The mutations were isolated on an araC-containing plasmid by hydroxylamine mutagenesis of plasmid DNA. The mutant phenotype selected was the inability to autoregulate. The DNA sequence of 16 mutants was determined and found to consist of seven different missense mutations located within the distal third of the araC gene. Enzyme activities revealed that each araC mutation had altered both autoregulatory and activator functions of AraC protein. The mutational analysis presented in this paper suggests that both autoregulatory and activator functions are localized to the same determinants of the AraC protein and that the amino acid sequence within the carboxy-terminal region of AraC protein is important for site-specific DNA binding.     

Negative regulation of L-arabinose metabolism in Bacillus subtilis: characterization of the araR (araC) gene.

The Bacillus subtilis araC locus, mapped at about 294 degrees on the genetic map, was defined by mutations conferring an Ara- phenotype to strains bearing the metabolic araA, araB, and araD wild-type alleles (located at about 256 degrees on the genetic map) and by mutants showing constitutive expression of the three genes. In previous work, it has been postulated that the gene in which these mutations lie exerts its effect on the ara metabolic operon in trans, and this locus was named araC by analogy to the Escherichia coli regulatory gene. Here, we report the cloning and sequencing of the araC locus. This region comprises two open reading frames with divergently arranged promoters, the regulatory gene, araC, encoding a 41-kDa polypeptide, and a partially cloned gene, termed araE, which most probably codes for a permease involved in the transport of L-arabinose. The DNA sequence of araC revealed that its putative product is very similar to a number of bacterial negative regulators (the GalR-LacI family). However, a helix-turn-helix motif was identified in the N-terminal region by its identity to the consensus signature sequence of another group of repressors, the GntR family. The lack of similarity between the predicted primary structure of the product encoded by the B. subtilis regulatory gene and the AraC regulator from E. coli and the apparently different modes of action of these two proteins lead us to propose a new name, araR, for this gene. The araR gene is monocistronic, and the promoter region contains -10 and -35 regions (as determined by primer extension analysis) similar to those recognized by RNA polymerase containing the major vegetative cell sigma factor sigmaA. An insertion-deletion mutation in the araR gene leads to constitutive expression of the L-arabinose metabolic operon. We demonstrate that the araR gene codes for a negative regulator of the ara operon and that the expression of araR is repressed by its own product.     

Regulation of the Escherichia coli L-arabinose operon studied by gel electrophoresis DNA binding assay

DNA binding properties of the proteins required for induction of the Escherichia coli L-arabinose operon were measured using a polyacrylamide gel electrophoresis assay. The mechanisms of induction and repression were studied by observing the multiple interactions of RNA polymerase, cyclic AMP receptor protein and araC protein with short DNA fragments containing either the araC or araBAD promoter regions. These studies show that binding of araC protein to the operator site, araO1, directly blocks RNA polymerase binding at the araC promoter, pC. We find that cyclic AMP receptor protein and araC protein do not bind co-operatively at their respective sites to linear DNA fragments containing the pBAD promoter. Nevertheless, both these positive effectors must be present on the DNA to stimulate binding of RNA polymerase. Additionally, binding of the proteins to the DNA is not sufficient; araC protein must also be in the inducing state, for RNA polymerase to bind. Equilibrium binding constraints and kinetics were determined for araC protein binding to the araI and the araO1 sites. In the presence of inducer, L-arabinose, araC protein binds with equal affinity to DNA fragments containing either of these sites. In the presence of anti-inducer, D-fucose, the affinity for both sites is reduced 40-fold. The apparent equilibrium binding constants for both states of the protein vary in parallel with the buffer salt concentration. This result suggests that the inducing and repressing forms of araC protein displace a similar number of cations upon binding DNA.     

Determining residue-base interactions between AraC protein and araI DNA

Depurination/depyrimidation binding-interference experiments (missing contact probing) identified specific candidate residue-base interactions lost by mutants of Escherichia coli L-arabinose operon regulatory protein, AraC, to one of its binding sites, araI. These candidates were then checked more rigorously by comparing the affinities of wild-type and alanine-substituted AraC protein to variants of araI with alterations in the candidate contacted positions. Residues 208 and 212 apparently contact DNA and support, but do not prove the existence of a helix-turn-helix structure in this region of AraC protein whereas contacts by mutants with alterations at positions 256, 257 and 261 which are within another potential helix-turn-helix region do not support the existence of such a structure there. The missing contacts displayed by three AraC mutants are found within two major groove regions of the DNA and are spaced 21 base-pairs apart in a pattern indicating a direct repeat orientation for the subunits of AraC.     

Effect of mutations in the cyclic AMP receptor protein-binding site on araBAD and araC expression.

Maximum expression of the adjacent but divergently transcribed araBAD operon and araC gene requires the presence of cyclic AMP (cAMP) and the cAMP receptor protein (CRP). DNase I protection studies have previously revealed a high-affinity CRP-binding site in the ara regulatory region. Deletion mutations introduced into this site resulted in reduced expression of araBAD and araC. However, other experiments have demonstrated that spacing changes in the ara regulatory region may have multiple effects due to disruption of a DNA loop. Thus, the deletions could have destroyed the CRP-binding site, the ability to form a loop, or both. In the present study, substitution mutations were introduced into the CRP site in order to avoid creating spacing changes. We found that a 3-base-pair substitution resulted in a 30% reduction in araBAD expression, whereas a 6-base-pair substitution resulted in an 80% reduction. Both of these substitution mutations reduced araC expression threefold. We conclude that CRP bound to this site regulates expression in both directions. We found that a spacing change in the CRP site does not alter araBAD expression any more than does a substitution mutation.     

AraC-DNA looping: orientation and distance-dependent loop breaking by the cyclic AMP receptor protein.

The arabinose operon promoter, pBAD, is negatively regulated in the absence of arabinose by AraC protein, which forms a DNA loop by binding to two sites separated by 210 base-pairs, araO2 and araI1. pBAD is also positively regulated by AraC-arabinose and the cyclic AMP receptor protein, CRP. We provide evidence that CRP breaks the araO2-araI1 repression loop in vitro. The ability of CRP to break the loop in vitro and to activate pBAD in vivo is dependent upon the orientation and distance of the CRP binding site relative to araI1. An insertion of one DNA helical turn, 11 base-pairs, between CRP and araI only partially inhibits CRP loop breaking and activation of pBAD, while an insertion of less than one DNA helical turn, 4 base-pairs, not only abolishes CRP activation and loop breaking, but actually causes CRP to stabilize the loop and increases the araO2-mediated repression of pBAD. Both integral and non-integral insertions of greater than one helical turn completely abolish CRP activation and loop breaking in vitro.     

araB Gene and nucleotide sequence of the araC gene of Erwinia carotovora.

The araB and araC genes of Erwinia carotovora were expressed in Escherichia coli and Salmonella typhimurium. The araB and araC genes in E. coli, E. carotovora, and S. typhimurium were transcribed in divergent directions. In E. carotovora, the araB and araC genes were separated by 3.5 kilobase pairs, whereas in E. coli and S. typhimurium they were separated by 147 base pairs. The nucleotide sequence of the E. carotovora araC gene was determined. The predicted sequence of AraC protein of E. carotovora was 18 and 29 amino acids longer than that of AraC protein of E. coli and S. typhimurium, respectively. The DNA sequence of the araC gene of E. carotovora was 58% homologous to that of E. coli and 59% homologous to that of S. typhimurium, with respect to the common region they share. The predicted amino acid sequence of AraC protein was 57% homologous to that of E. coli and 58% homologous to that of S. typhimurium. The 5' noncoding regions of the araB and araC genes of E. carotovora had little homology to either of the other two species.     

Suppressed nonsense mutations in the araC gene of Escherichia coli provide three novel variant proteins.

A total of 400 suppressible mutations have been isolated in the araC gene of Escherichia coli. Based on deletion mapping, growth patterns when suppressed, and intragenic recombination, 37 mutants have been determined to contain unique mutations. Rapid plate assays were developed to test for each of the three AraC protein functions: inducing araBAD, repressing araBAD, and araC self-repression. The 185 mutant proteins, resulting from 37 mutants each suppressed by five different suppressors, were assayed for each of the three AraC functions. These plate assays showed that: (i) for each function, some areas of the gene map are more sensitive to mutation than other areas, and (ii) three of the mutant AraC proteins were unlike previously characterized AraC mutants. Enzyme assays on the mutant proteins confirmed their novel character. The first mutant cannot induce araBAD but retains the capacity to perform both repression functions; and the second and third can each perform one of the two repression functions better than it can perform the other. These characteristics suggest that previously proposed models of ara regulation are incomplete.     

Repression of the araBAD promoter from araO1.

DNA looping between the araO2 and araI sites holds the uninduced or basal level of expression of the araBAD genes from the pBAD promoter at a low level. Despite the presence of another and closer site potentially capable of mediating looping to araI, no repression from this site, called araO1, is observed. Here we show, using both in vivo and in vitro experiments, that the araO1 site is not normally occupied by AraC protein under repressing conditions, but that if AraC protein is overproduced and the araO2 site is absent, araO1 is then occupied and repression of pBAD can be observed.     

Arabinose-leucine deletion mutants of Escherichia coli B-r

The control of ara gene expression was studied in mutants of Escherichia coli B/r containing deletions which fused the l-arabinose gene complex with the leucine operon (the normal gene order being araDABIOC...leuDCBAO). Complementation experiments with stable merodiploids showed that expression of ara genes cis to araC-leu deletions was controlled by the trans-acting product of the araC gene. Expression of ara genes cis to araB-leu deletions was under leucine control. These studies confirm the existence of a region between genes araC and araB essential for normal activator controlled expression of the ara structural genes. One deletion was characterized as an araO-leu deletion. Its effect on ara gene expression was unique in that ara genes were susceptible to potential regulation by both l-arabinose and leucine. These experiments suggest that two different species of messenger ribonucleic acid (mRNA) may be produced for the ara-leu region as a result of this deletion. One, under l-arabinose-activator control, is initiated in the l-arabinose region; the other, under leucine control, is initiated in the leucine region. The latter indicates that araI can be transcribed. Whether araI is transcribed in the former instance (mRNA made under activator control) remains to be established.     

Interaction between mutant alleles of araC of the Escherichia coli B/r L-arabinose operon.

Strains were constructed that contain mutational alterations affecting two distinct functional domains within the araC gene protein. The araCi (catabolite repression insensitivity) and araCh (catabolite repression hypersensitivity) mutations were used to alter the catabolite repression sensitivity domain, and mutation to D-fucose resistance was used to alter the inducer binding domain. araCh, D-fucose-resistant double mutants never exhibited constitutive ara operon expression, whereas all of the araCi, D-fucose-resistant double mutants did exhibit constitutivity. When L-arabinose was used as an inducer, most of the double mutants exhibited the sensitivity to catabolite repression associated with the araCi or araCh mutation. However, when D-fucose was used as an inducer, changes in sensitivity to catabolite repression were observed that were attributed to interactions between the two protein domains. The roles of catabolite activator protein and araC gene protein in the induction of the araBAD operon were discussed.     

Effect of araC gene product on catabolite repression in the L-arabinose regulon.

The araCi protein differs in stability from araC+ protein and alters the concentration of cyclic adenosine-3', 5'-monophosphate required to maximally stimulate L-arabinose isomerase synthesis in an in vitro protein-synthesizing system.     

Studies on the domain structure of the Salmonella typhimurium AraC protein

The Salmonella typhimurium araC gene product is known to be susceptible to proteolytic degradation. Limited cleavage by trypsin, kallikrein, elastase and pronase E yields stable fragments comprising approximately the N-terminal two thirds of the AraC protein. These fragments have in common the ability to dimerize in solution and to bind L-arabinose and D-fucose. Under appropriate conditions, hydrolysis of the AraC protein with Staphylococcus aureus V8 protease leads to a small C-terminal fragment which is able to bind specifically to a synthetic ara consensus sequence. These results indicate that, as with several other prokaryotic gene regulatory proteins, the basic functions of effector binding, subunit interaction and specific DNA binding are segregated into distinct domains of the AraC protein.     

In vivo titration of araC protein.

The requirement for araC protein in the induction of the araBAD operon was investigated. Strains of Escherichia coli carrying an araC(Am) mutation and temperature-sensitive amber suppressors were used to vary the intracellular level of araC protein. The levels of araC protein studied ranged from 0.007 to 1.8 times the normal amount. The results indicate that the normal level of araC protein is just sufficient to provide maximal expression of the araBAD operon.     

Effect of UVC and araC on L5178Y-R and L5178Y-S cells. Nucleoid sedimentation

The effects of UVC radiation (lambda = 254 nm, 85 J/m2) and/or 1-beta-D-arabino-furanosylcytosine (araC, 2 x 10(-3) M, 2 h) on two mouse lymphoma cell lines, UVC-sensitive and X-ray resistant L5178Y-R and UVC-resistant and X-ray sensitive L5178Y-S, were investigated. AraC treatment inhibited the semiconservative DNA replication to 1.4% and 3.8% in L5178Y-R and L5178Y-S cells, respectively, and decreased the sedimentation distance of nucleoids from the cells of both lines. The shortening of sedimentation distances induced by UVC and araC treatment was 8.1 mm for L5178Y-R cells and 11.8 mm for L5178Y-S, and indicated a higher number of DNA breaks in L5178Y-S cells. Assuming that such breaks are the result of the inhibition of DNA repair replication by araC, we conclude that L5178Y-S cells have a greater number of repaired sites than L5178Y-R cells.