Regulatory properties of araC(c) mutants in the L-arabinose operon of escherichia coliB/r.

Merodiploids containing a high-constitutive and a low-constitutive araC(c) allele were assayed for constitutive expression of the ara operon. Low-constitutive araC(c) alleles either were unable to repress the constitutive rate of ara operon expression exhibited by by high-constitutive araC(c) alleles or achieved a partial repression of the high-constitutive rate of operon expression. Either mutation to a low-constitutive araC(c) mutant resulted in a partial or complete loss of repressor function, or subunit mixing between the two araC(c) mutant proteins resulted in a partial or complete dominance of the high-constitutive araC(c) allele. Five of the six araC(c) alleles tested allowed a partial induction of the ara operon in cya crp background. In general, a higher level of ara operon induction was achieved in the cya crp background by high araC(c) alleles than by low araC(c) alleles. Furthermore, several araC(c) mutants exhibited decreased sensitivity to catabolite repression, particularly in the presence of inducer. The results suggest a model in which certain araC(c) gene products can achieve ara operon induction in the presence of either arabinose (inducer) or catabolite activator protein-cyclic adenosine monophosphate, whereas the wild-type araC gene product requires the presence of both of these factors for operon expression.     

Excision of bacteriophage lambda from a site in the arabinose B gene.

A lambda lysogen with the prophage inserted into the arabinose B gene of Escherichia coli strain K-12 has been prepared. Induction of the phage from this lysogen yields viable phage at a frequency 4 X 10(-6) that found for induction of lysogens with phage inserted at the normal attachment site. Over 30% of the phage particles induced from the insertion in ara are arabinose-transducing phage. The excision end points of 62 independently isolated, nondefective araC-transducing phage containing less than the entire araC gene were genetically determined and were found to be randomly distributed through the araC gene. The amount of arabinose deoxyribonucleic acid contained on four selected transducing phage was determined by electron microscopy of deoxyribonucleic acid heteroduplexes, providing a physical map of the araC gene. The efficiency with which these phage transduce araC and araB point mutations was found to be approximately proportional to the homology length available for recombination.     

AraC proteins with altered DNA sequence specificity which activate a mutant promoter in Escherichia coli

We examined the recognition of the araBAD promoter by the AraC protein in the Escherichia coli arabinose operon. A mutant promoter, with base substitutions at positions contacted by AraC, was used to isolate suppressor mutations in araC by direct selection. Two hydroxylamine-induced araC mutations were isolated repeatedly; each contained a single amino acid substitution. When tested against a set of base substitution promoter mutants, one revertant, an Arg to His substitution at residue 250, displayed altered base specificity for a single position within the araBAD promoter. The other revertant, a Cys to Tyr substitution at residue 204, did not show consistent base-specific suppression. Neither demonstrated a higher affinity than the wild type protein for the mutant promoter in vitro. Both proteins suppress mutant sequences by a mechanism that does not appear to involve the formation of new net favorable contacts with the mutant base pairs of the promoter.     

Tight regulation, modulation, and high-level expression by vectors containing the arabinose PBAD promoter.

We have constructed a series of plasmid vectors (pBAD vectors) containing the PBAD promoter of the araBAD (arabinose) operon and the gene encoding the positive and negative regulator of this promoter, araC. Using the phoA gene and phoA fusions to monitor expression in these vectors, we show that the ratio of induction/repression can be 1,200-fold, compared with 50-fold for PTAC-based vectors. phoA expression can be modulated over a wide range of inducer (arabinose) concentrations and reduced to extremely low levels by the presence of glucose, which represses expression. Also, the kinetics of induction and repression are very rapid and significantly affected by the ara allele in the host strain. Thus, the use of this system which can be efficiently and rapidly turned on and off allows the study of important aspects of bacterial physiology in a very simple manner and without changes of temperature. We have exploited the tight regulation of the PBAD promoter to study the phenotypes of null mutations of essential genes and explored the use of pBAD vectors as an expression system.     

Effects of the O2' hydroxyl group on Z-DNA conformation: structure of Z-RNA and (araC)-[Z-DNA

The left-handed Z structures of two hexamers [d(CG)r(CG)d(CG) and d(CG)(araC)d(GCG)] containing ribose and arabinose residues have been solved by X-ray diffraction analysis at 1.5-A resolution. Their conformations closely resemble that of the canonical Z-DNA. The O2' hydroxyl groups of both rC and araC residues form intramolecular hydrogen bonds with N2 of the 5' guanine residue and replace the bridging water molecules in the deep groove of Z-DNA, which stabilize the guanine in the syn conformation. The araC residue can be incorporated into the Z structure readily and facilitates B to Z transition, as supported by UV absorption spectroscopic studies. In contrast, in Z-RNA the ribose of the cytidine residue is twisted in order to form the respective hydrogen bond. The potential biological roles of the modified Z-DNA containing anticancer nucleoside araC and of Z-RNA are discussed.     

Dominance relationships among mutant alleles of regulatory gene araC in the Escherichia coli B/R L-arabinose operon.

The araBAD operon of Escherichia coli B/r is positively and negatively regulated by the araC+ regulatory protein. Mutations in gene araC can result in a variety of different regulatory phenotypes: araC null mutants (those carrying a null allele exhibiting no repressor or activator activity) are unable to achieve operon induction; araC-constitutive (araCc) mutants are partially constitutive, inducible by D-fucose, and resistant to catabolite repression; araCh mutants are hypersensitive to catabolite repression; and araCi mutants are resistant to catabolite repression. Various mutant alleles of gene araC were cloned into a derivative of plasmid pBR322 by in vivo recombination. Various heterozygous araC allelic combinations were constructed by transformation. Analysis of isomerase (araA) specific activity levels under various growth conditions indicated the following dominance relationships with regard to sensitivity to catabolite repression: araCh greater than araC+ greater than (araCc and araCi) greater than araC. It was concluded that the araCh protein may form a repressor complex that is refractory to removal by cyclic AMP receptor protein-cyclic AMP complex. This was interpreted in terms of the known nucleoprotein interactions between ara regulatory proteins and ara regulatory DNA.     

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.     

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.     

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.     

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.     

Human metallothionein-II is synthesized as a stable membrane-localized fusion protein in Escherichia coli

A synthetic gene encoding human metallothionein-II (HMT) was cloned into the specially constructed high-copy-number expression vector, pUA7, and expressed in Escherichia coli. The plasmid construct includes the promoter/operator and regulatory sequences of the Salmonella typhimurium ara operon and part of the 5'-coding and all of the 3'-noncoding regions of the E. coli lpp. Upon induction with arabinose, the resulting Lpp::HMT fusion protein was produced 75,000-fold over uninduced cells, with a relatively stable mRNA (T1/2 of 8.3 min) and a completely stable protein. In addition, over 95% of the final fusion protein was localized in the outer membrane and was capable of binding heavy metals (especially cadmium) in vitro. Cells producing Lpp::HMT bioaccumulated heavy metals (e.g., cadmium) 66-fold over nonproducing cells.     

Constitutive mutations in the controlling site region of the araBAD operon of Escherichia coli B/r that decrease sensitivity to catabolite repression.

Strains of Escherichia coli B/r containing a deletion of the regulatory gene araC are Ara-. Slow-growing revertants of these strains were isolated and designated aralc because they contain a second mutation in a controlling site, aral, that allows for a low level of constitutive expression of the araBAD operon (Englesbert et al., 1969). We mutagenized aralc delta C strains and selected mutants that grow faster in mineral L-arabinose medium. The new mutations, called araXc, map very close to the original aralc mutations and are in the controlling site region between araB and araC. The aralcXc delta C strains have a higher constitutive level of expression of the araBAD operon than the aralc delta C parents. The araXc mutations are cis acting and decrease the araBAD operon's sensitivity to catabolite repression. The araBAD operon is expressed equally well in ara delta C and ara C cya crp backgrounds. The repressor form of ara C protein is able to repress the constitutive synthesis due to the ara Xc allele.     

Selection of AraB and AraC Mutants of Escherichia coli B/r by Resistance to Ribitol

The growth of strain araC(c)67, which produces the enzymes of the ara operon constitutively, is inhibited by the addition of ribitol. Isolation of strains resistant to ribitol yields mutants of either the araB or araC genes. A model to account for the inhibition by ribitol is discussed.     

Arabinose-induction of lac-derived promoter systems for penicillin acylase production in Escherichia coli

Arabinose was shown to serve as an effective inducer for induction of the lac-derived promoters in Escherichia coli using penicillin acylase (PAC) as a model protein. Upon the induction with a conventional inducer, isopropyl-beta-d-thiogalactopyranoside (IPTG), for pac overexpression, which is regulated by the trc or (DE3)/T7 promoter, the production of PAC was limited by the accumulation of PAC precursors (proPAC) as inclusion bodies. Negative cellular responses, such as growth inhibition and cell lysis, were frequently observed, resulting in a low pac expression level and poor culture performance. Interestingly, these technical hurdles can be overcome simply through the use of arabinose as an inducer. The results indicate that arabinose not only induced the lac-derived promoter systems (i.e., trc and (DE3)/T7) for pac (or LL pac) overexpression but also facilitated the posttranslational processing of proPAC for maturation. However, the arabinose-inducibility appears to be host-dependent and becomes less observable in the strains with a mutation in the ara operon. The arabinose-inducibility was also investigated in the expression system with the coexistence of the trc promoter system regulating pac expression and another arabinose-inducible promoter system of araB regulating degP coexpression.     

Effect of substituting arabinonucleosides for deoxynucleotides in the DNA priming strand on the polymerase action of HIV-1 RT

The ability of 5'-DNA-araN-3' chimeras to serve as primers during HIV-1 RT-catalyzed DNA synthesis was assessed. It is shown that while the structural changes imparted by the arabinose units are minimal, the biological outcome is significant. For example, a DNA strand with arabinocytidine (araC) at the 3'-terminus was found to serve as a primer of DNA synthesis but significant pausing of HIV-RT was observed after the addition of 4 dNTP's. This phenomenon was not observed for the analogous DNA primer containing a riboC unit or an all-DNA strand.     

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.