Further evidence for positive control of the L-arabinose system by gene araC

Cautionary Notes on the Use of Arabinose- and Rhamnose-Inducible Expression Vectors in Pseudomonas aeruginosa

The Pseudomonas aeruginosa virulence factor regulator (Vfr) is a cyclic AMP (cAMP)-responsive transcription factor homologous to the Escherichia coli cAMP receptor protein (CRP). Unlike CRP, which plays a central role in E. coli energy metabolism and catabolite repression, Vfr is primarily involved in the control of P. aeruginosa virulence factor expression. Expression of the Vfr regulon is controlled at the level of vfr transcription, Vfr translation, cAMP synthesis, and cAMP degradation. While investigating mechanisms that regulate Vfr translation, we placed vfr transcription under the control of the rhaBp rhamnose-inducible promoter system (designated P_Rha) and found that P_Rha promoter activity was highly dependent upon vfr. Vfr dependence was also observed for the araBp arabinose-inducible promoter (designated P_BAD). The observation of Vfr dependence was not entirely unexpected. Both promoters are derived from E. coli, where maximal promoter activity is dependent upon CRP. Like CRP, we found that Vfr directly binds to promoter probes derived from the P_Rha and P_BAD promoters in vitro. Because Vfr-cAMP activity is highly integrated into numerous global regulatory systems, including c-di-GMP signaling, the Gac/Rsm system, MucA/AlgU/AlgZR signaling, and Hfq/sRNAs, the potential exists for significant variability in P_Rha and P_BAD promoter activity in a variety of genetic backgrounds, and use of these promoter systems in P. aeruginosa should be employed with caution. IMPORTANCE Heterologous gene expression and complementation constitute a valuable and widely utilized tool in bacterial genetics. The arabinose-inducible P_araBAD (P_BAD) and rhamnose-inducible P_rhaBAD (P_Rha) promoter systems are commonly used in P. aeruginosa genetics and prized for the tight control and dynamic expression ranges that can be achieved. In this study, we demonstrate that the activity of both promoters is dependent upon the cAMP-dependent transcription factor Vfr. While this poses an obvious problem for use in a vfr mutant background, the issue is more pervasive, considering that vfr transcription/synthesis and cAMP homeostasis are highly integrated into the cellular physiology of the organism and influenced by numerous global regulatory systems. Fortunately, the synthetic P_Tac promoter is not subject to Vfr regulatory control.

New insights into hydroxyectoine synthesis and its transcriptional regulation in the broad-salt growing halophilic bacterium Chromohalobacter salexigens

Elucidating the mechanisms controlling the synthesis of hydroxyectoine is important to design novel genetic engineering strategies for optimizing the production of this biotechnologically relevant compatible solute. The genome of the halophilic bacterium Chromohalobacter salexigens carries two ectoine hydroxylase genes, namely ectD and ectE, whose encoded proteins share the characteristic consensus motif of ectoine hydroxylases but showed only a 51.9% identity between them. In this work, we have shown that ectE encodes a secondary functional ectoine hydroxylase and that the hydroxyectoine synthesis mediated by this enzyme contributes to C.␣salexigens thermoprotection. The evolutionary pattern of EctD and EctE and related proteins suggests that they may have arisen from duplication of an ancestral gene preceding the directional divergence that gave origin to the orders Oceanospirillales and Alteromonadales. Osmoregulated expression of ectD at exponential phase, as well as the thermoregulated expression of ectD at the stationary phase, seemed to be dependent on the general stress factor RpoS. In contrast, expression of ectE was always RpoS-dependent regardless of the growth phase and osmotic or heat stress conditions tested. The data presented here suggest that the AraC-GlxA-like EctZ transcriptional regulator, whose encoding gene lies upstream of ectD, plays a dual function under exponential growth as both a transcriptional activator of osmoregulated ectD expression and a repressor of ectE transcription, privileging the synthesis of the main ectoine hydroxylase EctD. Inactivation of ectZ resulted in a higher amount of the total ectoines pool at the expenses of a higher accumulation of ectoine, with maintenance of the hydroxyectoine levels. In addition to the transcriptional control, our results suggest a strong post-transcriptional regulation of hydroxyectoine synthesis. Data on the accumulation of ectoine and hydroxyectoine in rpoS and ectZ strains pave the way for using these genetic backgrounds for metabolic engineering for hydroxyectoine production.

Optimization of fermentation conditions for production of l-arabinose isomerase of Lactobacillus plantarum WU14

As a substitute sweetener for sucrose, d-tagatose is widely used in products, such as health drinks, yogurt, fruit juices, baked goods, confectionery, and pharmaceutical preparations. In the fermentation process of l-AI produced by Lactobacillus plantarum, d-tagatose is produced through biotransformation and this study was based on the fermentation process of Lactobacillus plantarum WU14 producing l-AI to further research the biotransformation and separation process of d-tagatose. The kinetics of cell growth, substrate consumption, and l-arabinose isomerase formation were established by nonlinear fitting, and the fitting degrees were 0.996, 0.994, and 0.991, respectively, which could better reflect the change rule of d-tagatose biotransformation in the fermentation process of L. plantarum WU14. The separation process of d-tagatose was identified by decolorization, protein removal, desalination, and freeze drying, initially. Finally, the volume ratio of whole cell catalysts, d-galactose, and borate was 5:1:2 at 60°C, pH 7.17 through borate complexation; then, after 24 hr of conversion, the yield of d-tagatose was 58 g/L.

Arabinose Alters Both Local and Distal H-D Exchange Rates in the Escherichia coli AraC Transcriptional Regulator

In the absence of arabinose, the dimeric Escherichia coli regulatory protein of the l-arabinose operon, AraC, represses expression by looping the DNA between distant half-sites. Binding of arabinose to the dimerization domains forces AraC to preferentially bind two adjacent DNA half-sites, which stimulates RNA polymerase transcription of the araBAD catabolism genes. Prior genetic and biochemical studies hypothesized that arabinose allosterically induces a helix-coil transition of a linker between the dimerization and DNA binding domains that switches the AraC conformation to an inducing state [Brown, M. J., and Schleif, R. F. (2019) Biochemistry, preceding paper in this issue (DOI: 10.1021/acs.biochem.9b00234)]. To test this hypothesis, hydrogen-deuterium exchange mass spectrometry was utilized to identify structural regions involved in the conformational activation of AraC by arabinose. Comparison of the hydrogen-deuterium exchange kinetics of individual dimeric dimerization domains and the full-length dimeric AraC protein in the presence and absence of arabinose reveals a prominent arabinose-induced destabilization of the amide hydrogen-bonded structure of linker residues (I₁₆₇ and N₁₆₈). This destabilization is demonstrated to result from an increased probability to form a helix capping motif at the C-terminal end of the dimerizing α-helix of the dimerization domain that preceeds the interdomain linker. These conformational changes could allow for quaternary repositioning of the DNA binding domains required for induction of the araBAD promoter through rotation of peptide backbone dihedral angles of just a couple of residues. Subtle changes in exchange rates are also visible around the arabinose binding pocket and in the DNA binding domain.

Ellis Englesberg and the discovery of positive control in gene regulation

Based on his work with the Escherichia coli l-arabinose operon, Ellis Englesberg proposed in 1965 that the regulatory gene araC was an "activator gene" required for positive control of the ara operon. This challenged the widely held belief in a universal mechanism of negative regulation proposed earlier by Jacob and Monod. For years, Englesberg's model was met with deep skepticism. Despite much frustration with complex ad hoc explanations used to challenge his model, Englesberg persisted until the evidence for positive control in ara and other systems became overwhelming. Englesberg's pioneering work enriched the original operon model and had a lasting impact in opening new and exciting ways of thinking about transcriptional regulation.

Construction and Characterization of an E. coli bamD Depletion Strain

The central Bam components BamA and BamD are both essential genes in E. coli, a fact that often confounds genetic analysis using classical methods. The isolation of "depletion strains" in which these genes can be conditionally expressed removes this obstacle and facilitates the in vivo characterization of Bam function. This chapter describes an efficient two-step recombineering method for the construction of such a depletion strain, which contains an arabinose-inducible allele of bamD, using the λ Red system. Additionally, a simple protocol is presented for the depletion of bamD expression in live cells, which is particularly useful for the characterization of mutant alleles of bamD (complementation analysis). In principle, the procedures described can be adapted to produce and characterize depletion strains for any essential gene in E. coli or any other bacterium that is similarly amenable to genome engineering.

Understanding the basis of a class of paradoxical mutations in AraC through simulations

Most mutations at position 15 in the N-terminal arm of the regulatory protein AraC leave the protein incapable of responding to arabinose and inducing the proteins required for arabinose catabolism. Mutations at other positions of the arm do not have this behavior. Simple energetic analysis of the interactions between the arm and bound arabinose do not explain the uninducibility of AraC with mutations at position 15. Extensive molecular dynamics (MD) simulations, carried out largely on the Open Science Grid, were done of the wild-type protein with and without bound arabinose and of all possible mutations at position 15, many of which were constructed and measured for this work. Good correlation was found for deviation of arm position during the simulations and inducibility as measured in vivo of the same mutant proteins. Analysis of the MD trajectories revealed that preservation of the shape of the arm is critical to inducibility. To maintain the correct shape of the arm, the strengths of three interactions observed to be strong in simulations of the wild-type AraC protein need to be preserved. These interactions are between arabinose and residue 15, arabinose and residues 8-9, and residue 13 and residue 15. The latter interaction is notable because residues L9, Y13, F15, W95, and Y97 form a hydrophobic cluster which needs to be preserved for retention of the correct shape.

Active role of the interdomain linker of AraC

Mutations in the interdomain linker of the gene for the AraC regulatory protein of Escherichia coli that severely interfere with the protein's ability either to repress or to activate transcription have been found. These mutations have relatively small effects on the dimerization domain's ability to bind arabinose or to dimerize the protein or on the DNA-binding domain's affinity for a single DNA half-site. The linker mutations, however, dramatically change the affinity of AraC for binding to two direct-repeat DNA half-sites. Less dramatically, the induction-deficient linker variants also display altered DNA sequence selectivity. These results show that changing the sequence of the interdomain linker can profoundly affect the dimerization domain-DNA-binding domain interactions in AraC. The smaller effects on the functions of the individual domains could be the direct result of the linker alterations but more likely are the indirect result of the altered dimerization domain-DNA-binding domain interactions. In summary, the linker does not simply function as a passive and flexible connector between the domains of AraC but, instead, is more directly involved in the protein's dimerization domain-DNA-binding domain interactions.

AraC protein, regulation of the l-arabinose operon in Escherichia coli, and the light switch mechanism of AraC action

This review covers the physiological aspects of regulation of the arabinose operon in Escherichia coli and the physical and regulatory properties of the operon's controlling gene, araC. It also describes the light switch mechanism as an explanation for many of the protein's properties. Although many thousands of homologs of AraC exist and regulate many diverse operons in response to many different inducers or physiological states, homologs that regulate arabinose-catabolizing genes in response to arabinose were identified. The sequence similarities among them are discussed in light of the known structure of the dimerization and DNA-binding domains of AraC.

AraC protein: a love-hate relationship

In the bacterium Escherichia coli, the AraC protein positively and negatively regulates expression of the proteins required for the uptake and catabolism of the sugar L-arabinose. This essay describes how work from my laboratory on this system spanning more than thirty years has aided our understanding of positive regulation, revealed DNA looping (a mechanism that explains many action-at-a-distance phenomena) and, more recently, has uncovered the mechanism by which arabinose shifts AraC from a state where it prefers to bind to two well-separated DNA half-sites and form a DNA loop to a state where it binds to two adjacent half-sites and activates transcription. This work required learning how to assay, purify, and work with a protein possessing highly uncooperative biochemical properties. Present work is focussed on understanding arabinose-responsive mechanism in atomic detail and is also directed towards understanding protein structure and function well enough to be able to engineer the allosteric mechanism seen in AraC onto other proteins.

Regulation of the L-arabinose operon of Escherichia coli

Over forty years of research on the L-arabinose operon of Escherichia coli have provided insights into the mechanism of positive regulation of gene activity. This research also discovered DNA looping and the mechanism by which the regulatory protein changes its DNA-binding properties in response to the presence of arabinose. As is frequently seen in focused research on biological subjects, the initial studies were primarily genetic. Subsequently, the genetic approaches were augmented by physiological and then biochemical studies. Now biophysical studies are being conducted at the atomic level, but genetics still has a crucial role in the study of this system.

DNA bending by AraC: a negative mutant

We sought a mutation in the DNA binding domain of the arabinose operon regulatory protein, AraC, of Escherichia coli that allows the protein to bind DNA normally but not activate transcription. The mutation was isolated by mutagenizing a plasmid overproducing a chimeric leucine zipper-AraC DNA binding domain and screening for proteins that were trans dominant negative with regard to wild-type AraC protein. The mutant with the lowest transcription activation of the araBAD promoter was studied further. It proved to alter a residue that had previously been demonstrated to contact DNA. Because the overproduced mutant protein still bound DNA in vivo, it is deficient in transcription activation for some reason other than absence of DNA binding. Using the phase-sensitive DNA bending assay, we found that wild-type AraC bends DNA about 90 degrees whereas the mutant bends DNA by a smaller amount.

A new method for the analysis of the dynamics of the molecular genetic control systems. II. Application of the method of generalized threshold models in the investigation of concrete genetic systems

Mathematical models of the prokaryotic control systems of tryptophan biosynthesis (both normal and with cloned blocks) and arabinose catabolism have been built using the method of generalized threshold models. Kinetic curves for molecular components (mRNAs, proteins, metabolites) of the systems considered are obtained. It has been shown that the method of generalized threshold models gives a more detailed qualitative picture of the dynamics of the molecular genetic control systems in comparison with the heuristic method of threshold models. The qualitative analysis of the functioning of the following mechanisms of control of the tryptophan biosynthesis: (1) inhibition of the activity of anthranilate synthetase by tryptophan, (2) repression and (3) attenuation of transcription of the tryptophan operon on the basis of the mathematical model of the control system of the tryptophan biosynthesis demonstrates that feedback inhibition is the most operative of the considered mechanisms while repression allows the bacterium to economize intracellular resources. As regards the control system of the arabinose catabolism the results of modelling enable us to state the following. The induction by arabinose within a wide range of parameter values causes two subsystems (araBAD and transport operons) of the arabinose regulon with a low rate of arabinose utilization to pass into a stationary regime and one subsystem (araC operon) to pass into a stable periodical regime. A study of the system characterized by the effective utilization of arabinose has shown that under induction by arabinose stable oscillations with small amplitudes of the concentration of regulatory protein and oscillations with large amplitudes of the concentrations of arabinose-isomerase and transport protein may occur. The period of the oscillation depends on the mean lifetime of the "activator-DNA" complex and on the rate constant of arabinoseisomerase degradation.

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.

Characterization of the Escherichia coli araFGH and araJ promoters

The identities of two cloned, arabinose-inducible promoters were tested by hybridizing promoter DNA fragments with restriction digests of chromosomal DNA containing Mudlac phage inserted in either araFGH or in araE transport operons. One promoter, thought to be araE, is within 10(3) base-pairs of a Mudlac insertion in the araE gene. The second promoter was not found within several thousand base-pairs of either of the known transport genes. This promoter is now named araPJ (araJ). The DNA sequence of the fragment containing the araFGH promoter was determined. The start site of transcription in vivo was located to within +/- 1 base-pair (bp) by S1 nuclease mapping. DNase 1 footprinting revealed that, in comparison with the araBAD and araE promoters, the locations of the AraC and cyclic AMP receptor protein (CRP) binding sites are reversed with CRP lying between AraC and RNA polymerase. The central location of the CRP binding site may explain why the araFGH promoter is more catabolite sensitive than the other ara promoters. AraC and CRP were both required for maximal transcription in vitro, although a low level of transcription was detected with CRP alone. S1 nuclease mapping of mRNA-DNA hybrids from the araJ promoter located the transcription start point to within #/- 3 bp, and demonstrates that the promoter is dependent upon AraC protein and CRP in vivo. DNase footprinting showed that the location of the AraC protein binding site on araJ is adjacent to the RNA polymerase site, as seen at the araBAD and araE promoters. Two CRP sites were observed; one is upstream from the AraC site and one is downstream from the transcription start site.

Alternative DNA loops regulate the arabinose operon in Escherichia coli

The araCBAD regulatory region of Escherichia coli contains two divergently oriented promoters and three sites to which AraC, the regulatory protein of the operon, can bind. This paper presents the results of in vivo dimethyl sulfate "footprinting" experiments to monitor occupancy of the three AraC sites and measurements of activity of the two promoters. These measurements were made both in the absence of the inducer arabinose and at various times after arabinose addition to growing cells containing the wild-type ara regulatory region or the regulatory region containing various deletions and point mutations. The data lead to the conclusion that two different DNA loops can form in the ara regulatory region. These loops are generated by AraC protein molecules binding to two different DNA sites and binding to each other. One of these loops predominates in the absence of arabinose and plays a major role in repressing activity of one of the promoters. Upon the addition of arabinose the amount of the first loop type, the repression loop, decreases and the amount of a second loop increases. Formation of this second loop precludes the counterproductive formation of the repression loop.

Arabinose-induced binding of AraC protein to araI2 activates the araBAD operon promoter

The state of Escherichia coli araI DNA occupancy by AraC protein has been found to change from a two-turn to a four-turn occupancy upon the addition of the inducer arabinose. The araI site is separable into two contiguous regions, araI1 and araI2. araI1 binds both ligand-bound and ligand-free AraC protein, whereas araI2 binds AraC protein in the presence of arabinose only. A mutation in araI and a known mutation in araC led to the loss of araI2 binding, while binding to araI1 was unaffected. Both mutants failed to activate the promoter of the araBAD operon. We propose that araI2 occupancy by AraC protein leads to RNA polymerase recognition of the araBAD promoter and that araI1 acts as a switch mechanism allowing both the repressor and the activator forms of AraC protein to regulate the araBAD promoter.

High-affinity L-arabinose transport operon. Gene product expression and mRNAs

Various portions of the "high-affinity" L-arabinose transport operon were cloned into the plasmid expression vector pKK223-3 and the operon-encoded protein products were identified. The results indicate that three proteins are encoded by this operon. The first is a 33,000 Mr protein that is the product of the promoter-proximal L-arabinose binding protein coding sequence, araF. A 52,000 Mr protein is encoded by sequence 3' to araF and has been assigned to the araG locus. The sequence 3' to araG encodes a 31,000 Mr protein that has been assigned to the araH locus. Both the araG and araH gene products are localized in the membrane fraction of the cell, implying a role in the membrane-associated complex of the high-affinity L-arabinose transport system. Nuclease S1 protection studies indicate that two operon message populations are present in the cell, a full-length operon transcript and a seven- to tenfold more abundant binding protein-specific message. The relative abundance of these two message populations correlates with the differential expression of the binding protein and the membrane-associated proteins of the transport system.

The DNA loop model for ara repression: AraC protein occupies the proposed loop sites in vivo and repression-negative mutations lie in these same sites

Two sets of experiments have been performed to test the DNA loop model of repression of the araBAD operon of Escherichia coli. First, dimethyl sulfate methylation protection measurements on normally growing cells show that the AraC regulatory protein occupies the araI site in the presence and absence of the inducer arabinose. Similarly, the araO2 site is shown to be occupied by AraC protein in the presence and absence of arabinose; however, its occupancy by AraC is greatly reduced when araI and adjacent sequences are deleted. Thus, AraC protein binds to araO2 cooperatively with some other component of the ara system located at least 60 base pairs away. Second, the mutational analysis presented here shows that the DNA components required for repression of araBAD are araI, araO2, and perhaps the araBAD operon RNA polymerase binding site.

Altered DNA contacts made by a mutant AraC protein

Mutant AraC proteins were selected for their ability to induce but not to repress, or their ability to repress but not to induce the araBAD operon. One such unusual mutant is able to bind to the araI site with an affinity only two to three-fold weaker than the wild type AraC protein, but the mutant protein was shown, both in crude extracts and when purified, to contact only two of the three major groove regions of the DNA that are contacted by the wild type protein.

A dimer of AraC protein contacts three adjacent major groove regions of the araI DNA site

Contact sites of AraC protein to the regulatory site araI of the Escherichia coli araBAD operon have been determined by the chemical-interference technique. DNA fragments were chemically modified an average of once per molecule, and fragments that no longer bound AraC were separated by gel electrophoresis from the DNA fragments still able to bind the protein. The contact sites were then determined by comparing the positions of modifications in the two DNA samples. Strong contacts were found with guanines in three consecutive major groove regions and the adjacent phosphates along one side of the DNA. The conserved bases of the AraC-binding DNA consensus sequence are also found in the same positions. The gel electrophoresis assay was used to determine the stoichiometry of binding, and AraC protein was found to bind the araI and araO1 regulatory sites as a dimer. Therefore, AraC appears to bind DNA differently from the other well-characterized regulatory proteins such as phage lambda repressor.

Deletion analysis of the Escherichia coli ara PC and PBAD promoters

Deletions extending various distances into the ara PC-PBAD regulatory region were studied to define the sites required in vivo for the activity of these promoters. Deletions from the PC side entering the CRP site, which is located from -80 to -120 with respect to the PBAD transcription start site, reduced activity of this promoter. Similarly, deletions entering this site from the PBAD side reduced activity of the PC promoter. Cyclic AMP receptor protein bound at this site apparently functions to stimulate transcription of both flanking promoters.

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.

An operator at -280 base pairs that is required for repression of araBAD operon promoter: addition of DNA helical turns between the operator and promoter cyclically hinders repression

A site has been found that is required for repression of the Escherichia coli araBAD operon. This site was detected by the in vivo properties of deletion mutants. In vitro protection studies with DNase I and dimethylsulfate showed that araC protein can specifically bind in this area to nucleotides lying at position -265 to -294 with respect to the araBAD operon promoter (PBAD) transcription start point. The previously known sites of protein binding in the ara operon lie between +20 and -160. Since the properties of deletion strains show that all the sites required for araBAD induction lie between +20 and -110, the new site at -280 exerts its repressive action over an unusually large distance along the DNA. Insertions of -16, -8, 0, 5, 11, 15, 24, and 31 base pairs of DNA between the new site and PBAD were constructed. Repression was impaired in those cases in which half-integral turns of the DNA helix were introduced, but repression was nearly normal for the insertions of 0, +11, and +31 base pairs.

Positive control of the L-rhamnose genetic system in Salmonella typhimurium LT2

A total of 28 L-rhamnose-negative mutants in Salmonella typhimurium LT2 were all linked by P22 transduction and were classified into five groups on the basis of genetic and biochemical experiments. Deletion mapping showed that the gene order was rhaD rhaA rhaB rhaC rhaT . rhaA mutants lacked an inducible L-rhamnose isomerase, rhaB mutants lacked an inducible L- rhamnulokinase , and rhaD mutants were probably defective in L- rhamnulose -1-phosphate aldolase. Mutants that were unable to accumulate L-[14C]rhamnose but could grow on 1% L-rhamnose were designated rhaT to indicate a defect in L-rhamnose transport. Genetic evidence supports the hypothesis that the rhaC gene is a positive regulator of rha gene expression. (i) Pleiotropically negative mutants in the rhaC gene were isolated at a high frequency. (ii) Mutants containing an insertion or deletion within the rhaC gene had a pleiotropically negative phenotype. (iii) Complementation tests indicated that rhaC + was dominant to rhaC -. (iv) Rha+ revertants of deletion and Tn10 insertion mutations in the rhaC gene were isolated.

Genetic characterization of Salmonella typhimurium LT2 ara mutations

Seventeen independently isolated L-arabinose utilization-deficient mutants of Salmonella typhimurium LT2 were characterized. Four complementation groups (araA, araB, araC, and araD) were identified and were equivalent to the same genes in the ara system in Escherichia coli. The order of the four genes was determined to be araD-araA-araB-araC-leu. Two transcription units were found: the araBAD operon was transcribed counterclockwise, and the araC gene was transcribed clockwise.

Histidine operon control region of Klebsiella pneumoniae: analysis with an Escherichia coli promoter-probe plasmid vector

The control region for the histidine operon of Klebsiella pneumoniae was cloned and analyzed with the Escherichia coli promoter-probe plasmid pPV33. A restriction fragment which contained the his control region was identified by its ability to activate the tetracycline resistance (Tcr) gene on this vector. Expression of Tcr by bacteria containing the his promoter-active plasmid was found to be under the attenuation control of the his promoter. DNA sequence analysis of the his control region revealed a base sequence homology of approximately 86% of the analogous DNA sequences of E. coli and Salmonella typhimurium. Most of the base alterations in the K. pneumoniae DNA sequence were found to reside in regions flanking the transcriptional and translational regulatory sites.

Benzyl derivative facilitation of transcription in Escherichia coli at the ara and lac operon promoters: metabolite gene regulation (MGR)

A number of benzyl derivatives have been tested for their ability to induce the expression of the araBAD operon in an Escherichia coli K-12 strain. Those derivatives shown to be stimulatory include: benzoic acid (BA), para-amino benzoic acid (PABA), para-hydroxy benzoic acid (PHBA), ortho-amino benzoic acid (OABA), 3-hydroxy-4-methoxy phenylethylamine (MTA), and 4-hydroxy-3-methoxyphenol acetic acid (HVA). The araC gene product was necessary to facilitate the induction. To further characterize if the inductive effect was mediated at the level of transcription, an araBAD-tetracycline resistant (Tcr) operon fusion plasmid (pAP-B) was employed. Benzyl derivatives which induce expression of the araBAD operon in situ also induced a Tcr phenotype with pAP-B. Both indole acetic acid (IAA) and imidazole (IM), which were previously shown to circumvent the necessity for cAMP in the induction of the araBAD operon, also induced a Tcr phenotype with pAP-B. Induction of lac or other cAMP responding operons with the inducing molecules at the chromosomal level was not detectable when assessed by carbon utilization. However, a lacZYA-Tcr operon fusion plasmid (pLPI) did respond to IAA and several of the inducing benzyl derivatives. Catabolite repression of chromosomal araBAD expression was reversed when the exogenous concentration of OABA was elevated. Similar effects on the Tcr phenotypes conferred by pAP-B and pLP1 were observed when OABA or several other inducing benzyl derivatives were present exogenously.

Carbohydrate metabolism in lactic acid bacteria

The term "lactic acid bacteria" is discussed. An overview of the following topics is given: main pathways of homo- and heterofermentation of hexoses, i.e. glycolysis, bifidus pathway, 6-phosphogluconate pathway; uptake and dissimilation of lactose (tagatose pathway); fermentation of pentoses and pentitols; alternative fates of pyruvate, i.e. splitting to formate and acetate, CO2 and acetate or formation of acetoin and diacetyl; lactate oxidation; biochemical basis for the formation of different stereoisomers of lactate.

Spacing mutations between the Escherichia coli pBAD RNA polymerase binding site and the araC (I) induction site

Mutations in the Escherichia coli promoter PBAD have been constructed which alter the spacing of the adjacent RNA polymerase and araC inducer protein binding sites. While deletion of a single base-pair or small insertions do not detectably affect araC protein binding to DNA and they do not alter the conserved sequence of the RNA polymerase binding site, stimulation of PBAD in vivo is greatly reduced. The experiments suggest that the distance or angle between the two proteins on the DNA is critical for promoter function.

Plasmid-mediated uptake and metabolism of sucrose by Escherichia coli K-12

The conjugative plasmid pUR400 determines tetracycline resistance and enables cells of Escherichia coli K-12 to utilize sucrose as the sole carbon source. Three types of mutants affecting sucrose metabolism were derived from pUR400. One type lacked a specific transport system (srcA); another lacked sucrose-6-phosphate hydrolase (scrB); and the third, a regulatory mutant, expressed both of these functions constitutively (scrR). In a strain harboring pUR400, both transport and sucrose-6-phosphate hydrolase were inducible by fructose, sucrose, and raffinose; if a scrB mutant was used, fructose was the only inducer. These data suggested that fructose or a derivative acted as an endogenous inducer. Sucrose transport and sucrose-6-phosphate hydrolase were subject to catabolite repression; these two functions were not expressed in an E. coli host (of pUR400) deficient in the adenosine 3-,5'-phosphate receptor protein. Sucrose uptake (apparent Km = 10 microM) was dependent on the scrA gene product and on the phosphoenolpyruvate-dependent sugar:phosphotransferase system (PTS) of the host. The product of sucrose uptake (via group translocation) was identified as sucrose-6-phosphate, phosphorylated at C6 of the glucose moiety. Intracellular sucrose-6-phosphate hydrolase catalyzed the hydrolysis of sucrose-6-phosphate (Km = 0.17 mM), sucrose (Km = 60 mM), and raffinose (Km = 150 mM). The active enzyme was shown to be a dimer of Mr 110,000.

Cyclic adenosine 3',5'-monophosphate-mediated hyperinduction of araBAD and lacZYA expression in a crp mutant of Escherichia coli K-12

A spontaneous lac+ revertant of an adenylate cyclase deletion strain of Escherichia coli K-12 was isolated and characterized. This revertant, designated strain KC20, exhibited a pleiotropic suppression of the adenylate cyclase defect, with the crp locus being the site of the suppressor mutation. Cyclic adenosine 3',5'-monophosphate at an exogenous concentration of 1 mM severely inhibited the growth of strain KC20 in minimal media. Lower concentrations of the cyclic nucleotide elicited less pronounced effects. Studies on araBAD and lacZYA expression showed that cyclic adenosine 3',5'-monophosphate elicited an initial dose-dependent hyperinduction of these systems. Hyperinduction of araBAD, in L-arabinose grown cultures of strain KC20, resulted in accumulation of inhibitory concentrations of methylglyoxal. Hyperinduction of lacZYA in lactose-grown cultures of strain KC20 did not result in any such methylglyoxal production.

The araIc mutation in Escherichia coli B/r

The araIc allele is a cis-acting mutation which has been used to define the araBAD promoter in Escherichia coli B/r. Nineteen araIc mutants were originally isolated by Englesberg and co-workers as Ara+ "revertants" of an araC deletion mutant (Englesberg et al. J. Mol. Biol. 43:281-298, 1969). The mutants constitutively expressed araBAD gene products in the absence of functional araC activator protein. Eight of the araIc mutations have been cloned by in vivo recombination onto pBR322-ara hybrid plasmids. Restriction and DNA sequence analysis of these araIc mutations showed that they result from a single base-pair change located at -35 in the araBAD promoter.

Construction of pBR322-ara hybrid plasmids by in vivo recombination

In vivo recombination was used to clone deletions of the araBAD-araC genes of Escherichia coli onto a hybrid pBR322-ara plasmid. Genetic and physical analyses demonstrated that the desired deletions had been recombined onto the plasmid. In addition to permitting a detailed physical analysis of various ara deletions, this procedure has generated a series of plasmid cloning vehicles that can be used to clone, by in vivo recombination, any ara point mutation located within the region covered by the deletions. Hybrid plasmids containing the cloned point mutation can be distinguished from the original cloning vehicle by genetic complementation. The desired recombinant plasmid can be easily obtained because the frequency of recombination between the plasmid ara region and the chromosomal ara region is 0.025%--3%. A plasmid containing a deletion which removes the ara controlling site region and the araC gene was used to clone two types of araBAD promoter mutations and an araC mutation by in vivo recombination. Genetic and physical analysis of these plasmids established that the mutations in question had been recombined on to the ara deletion plasmid. The application of this procedure to the ara genes and to other genetic systems is discussed.

The Escherichia coli L-arabinose operon: binding sites of the regulatory proteins and a mechanism of positive and negative regulation

The locations of DNA binding by the proteins involved with positive and negative regulation of transcription initiation of the L-arabinose operon in Escherichia coli have been determined by the DNase I protection method. Two cyclic AMP receptor protein sites were found, at positions -78 to -107 and -121 to -146, an araC protein--arabinose binding site was found at position -40 to -78, and an araC protein-fucose binding site was found at position -106 to -144. These locations, combined with in vivo data on induction of the two divergently oriented arabinose promoters, suggest the following regulatory mechanism: induction of the araBAD operon occurs when cyclic AMP receptor protein, araC protein, and RNA polymerase are all present and able to bind to DNA. Negative regulation is accomplished by the repressing form of araC protein binding to a site in the regulatory region such that it stimultaneously blocks access of cyclic AMP receptor protein to two sites on the DNA, one site of which serves each of the two promoters. Thus, from a single operator site, the negative regulator represses the two outwardly oriented ara promoters. This regulatory mechanism explains the known positive and negative regulatory properties of the ara promoters.

A new locus (leuK) affecting the regulation of branched-chain amino acid, histidine, and tryptophan biosynthetic enzymes

A locus (leuK) affecting regulation of the leucine operon was selected by isolating a spontaneous Ara+ derivative of an Escherichia coli B/r strain carrying an ara-leu fusion in which the arabinose operon is under leucine control. Genetic analyses by P1 transduction demonstrated that the lesion is located to the right of the galactose operon. Regulation of the biosynthetic enzymes for leucine, isoleucine-valine, histidine, and tryptophan was altered in a strain carrying leuK16. High-level gene expression in the heterozygous merodiploid strain F' leuK+/leuK16) demonstrated the dominance of the mutant allele to the wild-type allele. No apparent effect was observed in the mutant on N-acetylornithinase, a biosynthetic enzyme in the arginine pathway, nor on any of the 18 aminoacyl-tRNA synthetases examined. However, compared with that of the parent strain, the extent of the charging of leucyl-, isoleucyl-, valyl-, histidyl-, and arginyl-tRNA was decreased in the mutant.

Reduced expression of a distal gene of the prn gene cluster in deletion mutants of Aspergillus nidulans: genetic evidence for a dicistronic messenger in an eukaryote

The prn gene cluster involved in L-proline catabolism in Aspergillus nidulans, has the gene order prnA-prnD-regulatory region-prnB-prnC. prnB, prnD, and prnC specify proline permease, proline oxidase, and delta1-pyrroline-5-carboxylate (P5C) dehydrogenase, respectively. prnA is probably a positive regulatory gene whose product is necessary for expression of the prn activities. Proline induces proline permease and P5C dehydrogenase in prnD- mutants which lack proline oxidase, showing that proline does not have to be converted to P5C to act as inducer. Deletion mutations extending from within prnD to within prnB result in considerably reduced expression of prnC, whereas a prnD- prnB- double mutant shows normal prnC expression. This strongly suggests that the deletion mutations eliminate a promotor/initiator site for transcription of a dicistronic messenger for prnB and prnC. The fact that the deletions do not eliminate prnC expression altogether indicates that at least one other species of prnC transcript (monocistronic, tricistronic, or tetracistronic) can be made.

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.

The araC promoter: transcription, mapping and interaction with the araBAD promoter

The start sites of the araC and araBAD gene messenger of E. coli were located by transcription in vitro from short DNA fragments, by high magnification electron microscopy and by genetic mapping. Transcription for these messengers proceeds in opposite directions from the start sites that are 150 base pairs apart. Transcription from the araBAD promoter requires araC protein plus arabinose and CAP protein plus cyclic AMP. In the experiments performed in vitro, inducing the araBAD promoter represses activity of the araC promoter.

Mutations in the L-arabinose operon of Escherichia coli B/r with reduced initiator function

Partial reversion mutants derived from a strain containing a strongly polar initiator-defective mutation (araI1036) in the L-arabinose operon were found to have several characteristics expected of mutants with reduced initiator function. These reversion mutations are cotransduced with the ara region and are probably within the araI region. Furthermore, they permit induction of the L-arabinose operon to a level only one-third of the normal wild-type level. These partially functional initiator regions reduce the expression of structural genes in the cis position only; they function quite independently of wild-type or defective initiator regions in the trans position. These mutants exhibit a two- to threefold increase in the rate of expression of ara operon genes within one-tenth of a generation after a shift of the growth temperature from 28 to 42 degrees C. This suggests that the temperature optimum for initiation of operon expression is higher for the partial revertant strains than it is for strains containing a wild-type initiator region.

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.

The site for catabolite deactivation in the L-arabinose BAD operon in Escherichia coli B/r

A series of deletions beginning in the leu operon and continuing into the araC gene and also into the ara controlling site region were analyzed in reciprocal merodiploids, e.g., F' A2Cc67/B24delta719, F' B24delta719/A2Cc67, for their effects on catabolite deactivation (CD). The results of these experiments are consistent with placing the catabolite gene activator-cyclic AMP sensitive site in the controlling site region between araB and araO. With a deletion mutant, delta1109, that places araBAD under leu control when transcription begins at leuP, the araBAD operon is immune to CD even though araCGA, araP and araI are intact and functional. To focus attention on the fine structure and related functions of this region we propose that the three proteins that function therein have separate sites of action: araI (initiator-site for activator), araP (promoter-site for RNA polymerase) and ara(CGA) (catabolite gene activator-site for CGA-cAMP). None of the eighteen initiator constitutive mutants (Ic) tested have any significant effect on catabolite derepression or on the maximal level of expression of the operon supporting the view that the araI site may be distinct from araP and ARA(CGA). A series of constitutive mutants in the araC gene (Cc) also have no pronounced effect on catabolite deactivation.