Expression, inducer spectrum, domain structure, and function of MopR, the regulator of phenol degradation in Acinetobacter calcoaceticus NCIB8250

Regulation of citB expression in Bacillus subtilis: integration of multiple metabolic signals in the citrate pool and by the general nitrogen regulatory system

The tricarboxylic acid (TCA) cycle is one of the major routes of carbon catabolism in Bacillus subtilis. The syntheses of the enzymes performing the initial reactions of the cycle, citrate synthase, and aconitase, are synergistically repressed by rapidly metabolizable carbon sources and glutamine. This regulation involves the general transcription factor CcpA and the specific repressor CcpC. In this study, we analyzed the expression and intracellular localization of CcpC. The synthesis of citrate, the effector of CcpC, requires acetyl-CoA. This metabolite is located at a branching point in metabolism. It can be converted to acetate in overflow metabolism or to citrate. Manipulations of the fate of acetyl-CoA revealed that efficient citrate synthesis is required for the expression of the citB gene encoding aconitase and that control of the two pathways utilizing acetyl-CoA converges in the control of citrate synthesis for the induction of the TCA cycle. The citrate pool seems also to be controlled by arginine catabolism. The presence of arginine results in a severe CcpC-dependent repression of citB. In addition to regulators involved in sensing the carbon status of the cell, the pleiotropic nitrogen-related transcription factor, TnrA, activates citB transcription in the absence of glutamine.

Proteins encoded by Sphingomonas elodea ATCC 31461 rmlA and ugpG genes, involved in gellan gum biosynthesis, exhibit both dTDP- and UDP-glucose pyrophosphorylase activities

The commercial gelling agent gellan is a heteropolysaccharide produced by Sphingomonas elodea ATCC 31461. In this work, we carried out the biochemical characterization of the enzyme encoded by the first gene (rmlA) of the rml 4-gene cluster present in the 18-gene cluster required for gellan biosynthesis (gel cluster). Based on sequence homology, the putative rml operon is presumably involved in the biosynthesis of dTDP-rhamnose, the sugar necessary for the incorporation of rhamnose in the gellan repeating unit. Heterologous RmlA was purified as a fused His6-RmlA protein from extracts prepared from Escherichia coli IPTG (isopropyl-beta-D-thiogalactopyranoside)-induced cells, and the protein was proven to exhibit dTDP-glucose pyrophosphorylase (Km of 12.0 microM for dTDP-glucose) and UDP-glucose pyrophosphorylase (Km of 229.0 microM for UDP-glucose) activities in vitro. The N-terminal region of RmlA exhibits the motif G-X-G-T-R-X2-P-X-T, which is highly conserved among bacterial XDP-sugar pyrophosphorylases. The motif E-E-K-P, with the conserved lysine residue (K163) predicted to be essential for glucose-1-phosphate binding, was observed. The S. elodea ATCC 31461 UgpG protein, encoded by the ugpG gene which maps outside the gel cluster, was previously identified as the UDP-glucose pyrophosphorylase involved in the formation of UDP-glucose, also required for gellan synthesis. In this study, we demonstrate that UgpG also exhibits dTDP-glucose pyrophosphorylase activity in vitro and compare the kinetic parameters of the two proteins for both substrates. DNA sequencing of ugpG gene-adjacent regions and sequence similarity studies suggest that this gene maps with others involved in the formation of sugar nucleotides presumably required for the biosynthesis of another cell polysaccharide(s).

Functional and topological analysis of the Burkholderia cenocepacia priming glucosyltransferase BceB, involved in the biosynthesis of the cepacian exopolysaccharide

The BceB protein of the cystic fibrosis mucoid isolate Burkholderia cenocepacia IST432 is proposed to catalyze the first step of the exopolysaccharide repeat unit assembly. Extracts of Escherichia coli cells overexpressing BceB were shown to contain glycosyltransferase activity and mediate incorporation of glucose-1-phosphate into membrane lipids. The amino acid sequence of BceB exhibits two conserved regions, one comprising two invariant aspartic acid residues (Asp339 and Asp355) that are essential for catalysis, as substantiated by site-directed mutagenesis, and the other comprising a putative Rossmann fold motif. The results of protein topology analysis using PhoA and LacZ fusions supported in silico predictions that BceB has at least six transmembrane segments and two major cytoplasmic loops comprising the conserved regions described above.

Alcaligenes faecalis subsp. phenolicus subsp. nov. a phenol-degrading, denitrifying bacterium isolated from a graywater bioprocessor

A Gram (-) coccobacillary bacterium, J(T), was isolated from a graywater bioprocessor. 16S rRNA and biochemical analysis has revealed strain J(T) closely resembles Alcaligenes faecalis ATCC 8750T and A. faecalis subsp. parafaecalis DSM 13975T, but is a distinct, previously uncharacterized isolate. Strain J(T), along with the type strain of A. faecalis and its previously described subspecies share the ability to aerobically degrade phenol. The degradation rates of phenol for strain J(T) and reference phenol degrading bacteria were determined by photometrically measuring the change in optical density when grown on 0.1% phenol as the sole carbon source, followed by addition of Gibb's reagent to measure depletion of substrate. The phenol degradation rates of strain J(T) was found to exceed that of the phenol hydroxylase group III bacterium Pseudomonas pseudoalcaligenes, with isolate J(T) exhibiting a doubling time of 4.5 h. The presence of the large subunit of the multicomponent phenol hydroxylase gene in strain J(T) was confirmed by PCR. The presence of the nirK nitrite reductase gene as demonstrated by PCR as well as results obtained from nitrite media indicated denitrification at least to N2O. Based on phenotypic, phylogenetic, fatty acid analysis and results from DNA DNA hybridization, we propose assigning a novel subspecies of Alcaligenes faecalis, to be named Alcaligenes faecalis subsp. phenolicus with the type strain J(T) (= DSM 16503) (= NRRL B-41076).

Multiple-mutation reaction: a method for simultaneous introduction of multiple mutations into the glpK gene of Mycoplasma pneumoniae

In Mycoplasma pneumoniae, the UGA opal codon specifies tryptophan rather than a translation stop site. This often makes it difficult to express Mycoplasma proteins in E. coli isolates. In this work, we developed a strategy for the one-step introduction of several mutations. This method, the multiple-mutation reaction, is used to simultaneously replace nine opal codons in the M. pneumoniae glpK gene.

A Peptide Triggers Allostery in Tet Repressor by Binding to a Unique Site

Regulatory proteins often communicate with each other to manage various cellular processes. Such interactions mostly rely on the recognition of small peptide motifs. The activity of other regulatory proteins depends on small molecular weight effectors and allostery. We demonstrate the in vivo regulation of the tetracycline-dependent Tet repressor by an oligopeptide fused to the N or C terminus of thioredoxin A. The binding site of the peptide overlaps but is not identical with the tetracycline binding site. Several TetR mutants that are non-inducible by tetracycline also respond to the peptide. This demonstrates for the first time the conversion of a small molecular weight effector-dependent regulator to a protein-protein contact-dependent potential member of designed signaling chains.

Enhanced biodegradation of phenol by a microbial consortium in a solid-liquid two phase partitioning bioreactor

Two phase partitioning bioreactors (TPPBs) operate by partitioning toxic substrates to or from an aqueous, cell-containing phase by means of second immiscible phase. Uptake of toxic substrates by the second phase effectively reduces their concentration within the aqueous phase to sub-inhibitory levels, and transfer of molecules between the phases to maintain equilibrium results in the continual feeding of substrate based on the metabolic demand of the microorganisms. Conventionally, a single pure species of microorganism, and a pure organic solvent, have been used in TPPBs. The present work has demonstrated the benefits of using a mixed microbial population for the degradation of phenol in a TPPB that uses solid polymer beads (comprised of ethylene vinyl acetate, or EVA) as the second phase. Polymer modification via an increase in vinyl acetate concentration was also shown to increase phenol uptake. Microbial consortia were isolated from three biological sources and, based on an evaluation of their kinetic performance, a superior consortium was chosen that offered improved degradation when compared to a pure strain of Pseudomonas putida ATCC 11172. The new microbial consortium used within a TPPB was capable of degrading high concentrations of phenol (approximately 2000 mg l(-1)), with decreased lag time (10 h) and increased specific rate of phenol degradation (0.71 g phenol g(1) cell h). Investigation of the four-member consortium showed that it consisted of two Pseudomonas sp., and two Acinetobacter sp., and tests conducted upon the individual isolates, as well as paired organisms, confirmed the synergistic benefit of their existence within the consortium. The enhanced effects of the use of a microbial consortium now offer improved degradation of phenol, and open the possibility of the degradation of multiple toxic substrates via a polymer-mediated TPPB system.

Bacterial transcriptional regulators for degradation pathways of aromatic compounds

Human activities have resulted in the release and introduction into the environment of a plethora of aromatic chemicals. The interest in discovering how bacteria are dealing with hazardous environmental pollutants has driven a large research community and has resulted in important biochemical, genetic, and physiological knowledge about the degradation capacities of microorganisms and their application in bioremediation, green chemistry, or production of pharmacy synthons. In addition, regulation of catabolic pathway expression has attracted the interest of numerous different groups, and several catabolic pathway regulators have been exemplary for understanding transcription control mechanisms. More recently, information about regulatory systems has been used to construct whole-cell living bioreporters that are used to measure the quality of the aqueous, soil, and air environment. The topic of biodegradation is relatively coherent, and this review presents a coherent overview of the regulatory systems involved in the transcriptional control of catabolic pathways. This review summarizes the different regulatory systems involved in biodegradation pathways of aromatic compounds linking them to other known protein families. Specific attention has been paid to describing the genetic organization of the regulatory genes, promoters, and target operon(s) and to discussing present knowledge about signaling molecules, DNA binding properties, and operator characteristics, and evidence from regulatory mutants. For each regulator family, this information is combined with recently obtained protein structural information to arrive at a possible mechanism of transcription activation. This demonstrates the diversity of control mechanisms existing in catabolic pathways.

Methylation of 23S rRNA nucleotide G745 is a secondary function of the RlmAI methyltransferase

Several groups of Gram-negative bacteria possess an RlmA(I) methyltransferase that methylates 23S rRNA nucleotide G745 at the N1 position. Inactivation of rlmA(I) in Acinetobacter calcoaceticus and Escherichia coli reduces growth rates by at least 30%, supposedly due to ribosome malfunction. Wild-type phenotypes are restored by introduction of plasmid-encoded rlmA(I), but not by the orthologous Gram-positive gene rlmA(II) that methylates the neighboring nucleotide G748. Nucleotide G745 interacts with A752 in a manner that does not involve the guanine N1 position. When a cytosine is substituted at A752, a Watson-Crick G745-C752 pair is formed occluding the guanine N1 and greatly reducing RlmA(I) methylation. Methylation is completely abolished by substitution of the G745 base. Intriguingly, the absence of methylation in E. coli rRNA mutant strains causes no reduction in growth rate. Furthermore, the slow-growing rlmA(I) knockout strains of Acinetobacter and E. coli revert to the wild-type growth phenotype after serial passages on agar plates. All the cells tested were pseudorevertants, and none of them had recovered G745 methylation. Analyses of the pseudorevertants failed to reveal second-site mutations in the ribosomal components close to nucleotide G745. The results indicate that cell growth is not dependent on G745 methylation, and that the RlmA(I) methyltransferase therefore has another (as yet unidentified) primary function.

Mycoplasma pneumoniae HPr kinase/phosphorylase

HPr kinase/phosphorylase (HPrK/P) is the key regulator of carbon metabolism in many Gram-positive bacteria. It phosphorylates/dephosphorylates the HPr protein of the bacterial phosphotransferase system on a regulatory serine residue in response to the nutrient status of the cell. In Mycoplasma pneumoniae, HPrK/P is one of the very few regulatory proteins encoded in the genome. The regulation of this enzyme by metabolites is unique among HPrK/P proteins studied so far: it is active as a kinase at low ATP concentrations, whereas the proteins from other bacteria need high ATP concentrations as an indicator of a good nutrient supply for kinase activity. We studied the interaction of M. pneumoniae HPrK/P with ATP, Fru1,6P2 and Pi by fluorescence spectroscopy. In agreement with the previously observed unique regulation, we found a very high affinity for ATP (K(d)=5.4 microM) compared with the HPrK/P proteins from other bacteria. The Kd for Fru1,6P2 was three orders of magnitude higher, which explains why Fru1,6P2 has only a weak regulatory effect on M. pneumoniae HPrK/P. Mutations of two important regions in the active site of HPrK/P, the nucleotide binding P-loop and the HPrK/P family signature sequence, had different effects. P-loop region mutations strongly affect ATP binding and thus all enzymatic functions, whereas the signature sequence motif seems to be important for the catalytic mechanism rather than for nucleotide binding.

Integrated regulation in response to aromatic compounds: from signal sensing to attractive behaviour

Deciphering the complex interconnecting bacterial responses to the presence of aromatic compounds is required to gain an integrated understanding of how aromatic catabolic processes function in relation to their genome and environmental context. In addition to the properties of the catabolic enzymes themselves, regulatory responses on at least three different levels are important. At a primary level, aromatic compounds control the activity of specific members of many families of transcriptional regulators to direct the expression of the specialized enzymes for their own catabolism. At a second level, dominant global regulation in response to environmental and physiological cues is incorporated to subvert and couple transcription levels to the energy status of the bacteria. Mediators of these global regulatory responses include the alarmone (p)ppGpp, the DNA-bending protein IHF and less well-defined systems that probably sense the energy status through the activity of the electron transport chain. At a third level, aromatic compounds can also impact on catabolic performance by provoking behavioural responses that allow the bacteria to seek out aromatic growth substrates in their environment.

3- and 4-alkylphenol degradation pathway in Pseudomonas sp. strain KL28: genetic organization of the lap gene cluster and substrate specificities of phenol hydroxylase and catechol 2,3-dioxygenase

The enzymes and genes responsible for the catabolism of higher alkylphenols have not been characterized in aerobic bacteria. Pseudomonas sp. strain KL28 can utilize a wide range of alkylphenols, which include the 4-n-alkylphenols (C(1)-C(5)). The genes, designated as lap (for long-chain alkylphenols), encoding enzymes for the catabolic pathway were cloned from chromosomal DNA and sequenced. The lap genes are located in a 13.2 kb region with 14 ORFs in the order lapRBKLMNOPCEHIFG and with the same transcriptional orientation. The lapR gene is transcribed independently and encodes a member of the XylR/DmpR positive transcriptional regulators. lapB, the first gene in the lap operon, encodes catechol 2,3-dioxygenase (C23O). The lapKLMNOP and lapCEHIFG genes encode a multicomponent phenol hydroxylase (mPH) and enzymes that degrade derivatives of 2-hydroxymuconic semialdehyde (HMS) to TCA cycle intermediates, respectively. The P(lapB) promoter contains motifs at positions -24(GG) and -12(GC) which are typically found in sigma(54)-dependent promoters. A promoter assay using a P(lapB) : : gfp transcriptional fusion plasmid showed that lapB promoter activity is inducible and that it responds to a wide range of (alkyl)phenols. The structural genes encoding enzymes required for this catabolism are similar (42-69 %) to those encoded on a catabolic pVI150 plasmid from an archetypal phenol degrader, Pseudomonas sp. CF600. However, the lap locus does not include genes encoding HMS hydrolase and ferredoxin. The latter is known to be functionally associated with C23O for use of 4-alkylcatechols as substrates. The arrangement of the lap catabolic genes is not commonly found in other meta-cleavage operons. Substrate specificity studies show that mPH preferentially oxidizes 3- and 4-alkylphenols to 4-alkylcatechols. C23O preferentially oxidizes 4-alkylcatechols via proximal (2,3) cleavage. This indicates that these two key enzymes have unique substrate preferences and lead to the establishment of the initial steps of the lap pathway in strain KL28.

Control of the Bacillus subtilis Antiterminator Protein GlcT by Phosphorylation

Bacillus subtilis transports glucose by the phosphotransferase system (PTS). The genes for this system are encoded in the ptsGHI operon, which is induced by glucose and depends on a termination/antitermination mechanism involving a riboswitch and the RNA-binding antitermination protein GlcT. In the absence of glucose, GlcT is inactive, and a terminator is formed in the leader region of the ptsG mRNA. If glucose is present, GlcT can bind to its RNA target and prevent transcription termination. The GlcT protein is composed of three domains, an N-terminal RNA binding domain and two PTS regulation domains, PTS regulation domain (PRD) I and PRD-II. In this work, we demonstrate that GlcT can be phosphorylated by two PTS proteins, HPr and the glucose-specific enzyme II (EIIGlc). HPr-dependent phosphorylation occurs on PRD-II and has a slight stimulatory effect on GlcT activity. In contrast, EIIGlc phosphorylates the PRD-I of GlcT, and this phosphorylation inactivates GlcT. This latter phosphorylation event links the availability of glucose to the expression of the ptsGHI operon via the phosphorylation state of EIIGlc and GlcT. This is the first in vitro demonstration of a direct phosphorylation of an antiterminator of the BglG family by the corresponding PTS permease.

A new variant activator involved in the degradation of phenolic compounds from a strain of Pseudomonas putida

A new variant type of regulatory activator and relevant promoters (designated capR, Pr and Po) involved in the metabolism of phenolic compounds were cloned from Pseudomonas putida KCTC1452 by using PCR. The deduced amino acid sequence of CapR revealed a difference in nine amino acids from the effector binding domain of DmpR. To measure effector specificity, plasmids were constructed in such a way that the expression of luc gene for firefly luciferase or lacZ for beta-galactosidase as a reporter was under the control of capR. When Escherichia coli transformed with the plasmids was exposed to phenol, dramatic increases in the activity of luciferase or beta-galactosidase were observed in a range of 0.01-1 mM. Among various phenolic compounds tested, other effective compounds included catechol, 2-methylphenol, 3-methylphenol, 4-methylphenol, 2-chlorophenol, 4-chlorophenol, 2-nitrophenol, resorcinol, and 2, 5-dimethylphenol. The results indicate that CapR has effector specificity different from other related activators, CatR and DmpR. Waste water and soil potentially containing phenolic compounds were also tested by this system and the results were compared with chemical and GC data. The present results indicate that the biosensor consisting of capR and the promoters may be utilized for the development of a phenolic compounds-specific biosensor in monitoring the environmental pollutant.

Specific binding of the regulatory protein ExpG to promoter regions of the galactoglucan biosynthesis gene cluster of Sinorhizobium meliloti--a combined molecular biology and force spectroscopy investigation

Specific protein-DNA interaction is fundamental for all aspects of gene transcription. We focus on a regulatory DNA-binding protein in the Gram-negative soil bacterium Sinorhizobium meliloti 2011, which is capable of fixing molecular nitrogen in a symbiotic interaction with alfalfa plants. The ExpG protein plays a central role in regulation of the biosynthesis of the exopolysaccharide galactoglucan, which promotes the establishment of symbiosis. ExpG is a transcriptional activator of exp gene expression. We investigated the molecular mechanism of binding of ExpG to three associated target sequences in the exp gene cluster with standard biochemical methods and single molecule force spectroscopy based on the atomic force microscope (AFM). Binding of ExpG to expA1, expG-expD1, and expE1 promoter fragments in a sequence specific manner was demonstrated, and a 28 bp conserved region was found. AFM force spectroscopy experiments confirmed the specific binding of ExpG to the promoter regions, with unbinding forces ranging from 50 to 165 pN in a logarithmic dependence from the loading rates of 70-79000 pN/s. Two different regimes of loading rate-dependent behaviour were identified. Thermal off-rates in the range of k(off)=(1.2+/-1.0) x 10(-3)s(-1) were derived from the lower loading rate regime for all promoter regions. In the upper loading rate regime, however, these fragments exhibited distinct differences which are attributed to the molecular binding mechanism.

Quantitative structure-activity relationship (QSAR) analysis of aromatic effector specificity in NtrC-like transcriptional activators from aromatic oxidizing bacteria

A quantitative structure-activity relationship (QSAR) approach was taken to provide mechanistic insights into the interaction between the chemical structure of inducing compounds and the transcriptional activation of aromatic monooxygenase operons among the XylR/DmpR subclass of bacterial NtrC-like transcriptional regulators. Compared to XylR and DmpR, a broader spectrum of effector compounds was observed for the TbuT system from Ralstonia pickettii PKO1. The results of QSAR analysis for TbuT suggested that a steric effect, rather than hydrophobic or electronic effects, may be the predominant factor in determining aromatic effector specificity, and the active site of the regulator may positively interact not only with the methyl moiety but also with the most electron-rich aryl side of an aromatic effector.

Cloning and sequence analysis of the ces10 gene encoding a Sphingomonas paucimobilis esterase

The ces10 gene of the gellan gum-producing strain Sphingomonas paucimobilis ATCC 31461 was cloned and sequenced. Multi-sequence alignment of the deduced protein indicated that Ces10 belongs to the serine hydrolase family with a potential catalytic triad comprising Ser(153) (within the G-X-S-X-G consensus sequence), His(75) and Asp(125). The mixed block results obtained following pattern search and the low identities detected in a BLAST analysis indicate that Ces10 is significantly different from other characterised bacterial esterases/lipases. Nevertheless, the Ces10 amino acid sequence showed 45% similarity with Rhodococcus sp. heroin esterase and 48% with Bacillus subtilis p-nitrobenzyl esterase. Ces10, with a predicted molecular mass of 30,641 Da, was overproduced in Escherichia coli and purified to homogeneity in a histidine-tagged form. Enzyme assays using p-nitrophenyl-esters (p-NP-esters) with different acyl chain-lengths as the substrate confirmed the anticipated esterase activity. Ces10 exhibited a marked preference for short-chain fatty acids, yielding the highest activity with p-NP-propionate (optimal pH 7.4, optimal temperature 37 degrees C).

Sphingomonas paucimobilis beta-glucosidase Bgl1: a member of a new bacterial subfamily in glycoside hydrolase family 1

The Sphingomonas paucimobilis beta-glucosidase Bgl1 is encoded by the bgl1 gene, associated with an 1308 bp open reading frame. The deduced protein has a potential signal peptide of 24 amino acids in the N-terminal region, and experimental evidence is consistent with the processing and export of the Bgl1 protein through the inner membrane to the periplasmic space. A His(6)-tagged 44.3 kDa protein was over-produced in the cytosol of Escherichia coli from a recombinant plasmid, which contained the S. paucimobilis bgl1 gene lacking the region encoding the putative signal peptide. Mature beta-glucosidase Bgl1 is specific for aryl-beta-glucosides and has no apparent activity with oligosaccharides derived from cellulose hydrolysis and other saccharides. A structure-based alignment established structural relations between S. paucimobilis Bgl1 and other members of the glycoside hydrolase (GH) family 1 enzymes. At subsite -1, the conserved residues required for catalysis by GH1 enzymes are present in Bgl1 with only minor differences. Major differences are found at subsite +1, the aglycone binding site. This alignment seeded a sequence-based phylogenetic analysis of GH1 enzymes, revealing an absence of horizontal transfer between phyla. Bootstrap analysis supported the definition of subfamilies and revealed that Bgl1, the first characterized beta-glucosidase from the genus Sphingomonas, represents a very divergent bacterial subfamily, closer to archaeal subfamilies than to others of bacterial origin.

Expression of the glycolytic gapA operon in Bacillus subtilis: differential syntheses of proteins encoded by the operon

Glycolysis is one of the central routes of carbon catabolism in Bacillus subtilis. Several glycolytic enzymes, including the key enzyme glyceraldehyde-3-phosphate dehydrogenase, are encoded in the hexacistronic gapA operon. Expression of this operon is induced by a variety of sugars and amino acids. Under non-inducing conditions, expression is repressed by the CggR repressor protein, the product of the promoter-proximal gene of the operon. Here, it is shown that the amount of glyceraldehyde-3-phosphate dehydrogenase encoded by the second gene of the operon exceeds that of the CggR repressor by about 100-fold. This differential synthesis was attributed to an mRNA processing event that takes place at the 3' end of the cggR open reading frame and to differential segmental stabilities of the resulting cleavage products. The mRNA specifying the truncated cggR gene is quickly degraded, whereas the downstream processing products encompassing gapA are quite stable. This increased stability is conferred by the presence of a stem-loop structure at the 5' end of the processed mRNAs. Mutations were introduced in the region of the cleavage site. A mutation affecting the stability of the stem-loop structure immediately downstream of the processing site had two effects. First, the steady-state transcript pattern was drastically shifted towards the primary transcripts; second, the stability of the processed mRNA containing the destabilized stem-loop structure was strongly decreased. This results in a reduction of the amount of glyceraldehyde-3-phosphate dehydrogenase in the cell. It is concluded that mRNA processing is involved in differential syntheses of the proteins encoded by the gapA operon.

A novel mode of control of Mycoplasma pneumoniae HPr kinase/phosphatase activity reflects its parasitic lifestyle

Among the few regulatory proteins encoded by Mycoplasma pneumoniae is HPr kinase/phosphatase (HPrK/P), the key regulator of carbon metabolism in low-GC Gram-positive bacteria. The corresponding gene, hprK, and the gene encoding the target protein HPr, ptsH, were overexpressed. In vitro analysis of the purified proteins confirmed ATP-dependent phosphorylation of HPr by HPrK/P. In contrast to HPrK/P of Bacillus subtilis, which is by default a phosphatase and needs high ATP concentrations for kinase activity, the M. pneumoniae enzyme exhibits kinase activity at very low ATP concentrations and depends on P(i) for phosphatase activity. This inverted control of enzymic activity may result from the adaptation to very different ecological niches. While the standard activities of HPrK/P from M. pneumoniae and other Gram-positive bacteria differ, they are both modulated by the concentration of ATP, P(i) and glycolytic intermediates. Site-directed mutagenesis of a potential ATP-binding site and of the HPrK/P signature sequence resulted in four different activity classes: (i) inactive proteins, (ii) enzymes with reduced kinase and phosphatase activities, (iii) enzymes that had lost phosphatase, but not kinase activity, and (iv) enzymes that exhibited increased phosphatase activity.

An AraC/XylS family member at a high level in a hierarchy of regulators for phenol-metabolizing enzymes in Comamonas testosteroni R5

Comamonas testosteroni strain R5 expresses a higher level of phenol-oxygenating activity than any other bacterial strain so far characterized. The expression of the operon encoding multicomponent phenol hydroxylase (mPH), which is responsible for the phenol-oxygenating activity, is controlled by two transcriptional regulators, PhcS and PhcR, in strain R5. In this study, we identified a third transcriptional regulator for the mPH operon (PhcT) that belongs to the AraC/XylS family. While the disruption of phcT in strain R5 significantly reduced the expression of the mPH operon, it did not eliminate the expression. However, the disruption of phcT in strain R5 increased the expression of phcR. The phenol-oxygenating activity was abolished by the disruption of phcR, indicating that PhcT alone was not sufficient to activate the expression of the mPH operon. The disruption of phcS has been shown in our previous study to confer the ability of strain R5 to express the mPH operon in the absence of the genuine substrate for mPH. PhcT was not involved in the gratuitous expression. Strain R5 thus possesses a more elaborate mechanism for regulating the mPH operon expression than has been found in other bacteria.

HPr kinase/phosphatase of Bacillus subtilis: expression of the gene and effects of mutations on enzyme activity, growth and carbon catabolite repression

HPr kinase/phosphatase (HPrK/P) is the key protein in regulation of carbon metabolism in Bacillus subtilis and many other Gram-positive bacteria. Whether this enzyme acts as a kinase or phosphatase is determined by the nutrient status of the cell. Mutational analysis of residues in a Walker A box nucleotide-binding motif revealed that it is not only important for kinase but is also involved in phosphatase activity. In addition, a signature sequence specifically conserved among HPrK/P orthologues is required for phosphatase activity and may be involved in interaction with HPr/HPr-(Ser46)-P. Carbon catabolite repression was abolished in a B. subtilis strain expressing a mutant form of HPrK/P deficient in kinase and phosphatase activities. The growth characteristics of this strain were similar to those of the wild-type. In contrast, B. subtilis strains expressing HPrK/P with partial kinase and no phosphatase activities showed growth impairment but exhibited catabolite repression.

Cloning and characterization of two catechol 1,2-dioxygenase genes from Acinetobacter radioresistens S13

Two novel catechol 1,2-dioxygenase (C 1,2-O) genes have been isolated from an Acinetobacter radioresistens strain that grows on phenol or benzoate as sole carbon and energy source. Designated as catA(A) and catA(B), they encode proteins composed of 314 and 306 amino acids, whose deduced sequences indicate that they have approximately 53% identity, whereas their NH2-terminal and COOH-terminal regions have no sequences in common. This may explain their different thermal and pH stability. Polyclonal antibodies raised against an amino-terminal CatA(A) peptide or the whole CatA(B) protein were used to establish their inducible and differential expression patterns upon bacterial growth in phenol or benzoate. The CatA(A) protein (IsoA) was induced by both phenol and benzoate though with different kinetics, whereas the catA(B) product (IsoB) was constitutively produced at low levels that increased only during growth in the presence of benzoate.

Monitoring intracellular levels of XylR in Pseudomonas putida with a single-chain antibody specific for aromatic-responsive enhancer-binding proteins

We have isolated a recombinant phage antibody (Phab) that binds a distinct epitope of the subclass of the sigma(54)-dependent prokaryotic enhancer-binding proteins that respond directly to aromatic effectors, e.g., those that activate biodegradative operons of Pseudomonas spp. The DNA segments encoding the variable (V) domains of the immunoglobulins expressed by mice immunized with the C-terminal half of TouR (TouRDeltaA) of Pseudomonas stutzeri OX1 were amplified and rearranged in vitro as single-chain Fv (scFv) genes. An scFv library was thereby constructed, expressed in an M13 display system, and subjected to a panning procedure with TouR. One clone (named B7) was selected with high affinity for TouR and XylR (the regulator of the upper TOL operon of the pWW0 plasmid). The epitope recognized by this Phab was mapped to the peptide TPRAQATLLRVL, which seems to be characteristic of the group of enhancer-binding proteins to which TouR and XylR belong and which is located adjacent to the Walker B motif of the proteins. The Phab B7 was instrumental in measuring directly the intracellular levels of XylR expressed from its natural promoter in monocopy gene dosage in Pseudomonas putida under various conditions. Growth stage, the physical form of the protein produced (XylR or XylRDeltaA), and the presence or absence of aromatic inducers in the medium influenced the intracellular pool of these molecules. XylR oscillated from a minimum of approximately 30 molecules (monomers) per cell during exponential phase to approximately140 molecules per cell at stationary phase. Activation of XylR by aromatic inducers decreased the intracellular concentration of the regulator. The levels of the constitutively active variant of XylR named XylRDeltaA were higher, fluctuating between approximately 90 and approximately 570 molecules per cell, depending on the growth stage. These results are compatible with the present model of transcriptional autoregulation of XylR and suggest the existence of mechanisms controlling the stability of XylR protein in vivo.

Analysis of transcription of the bph locus of Burkholderia sp. strain LB400 and evidence that the ORF0 gene product acts as a regulator of the bphA1 promoter

Although gene clusters for the degradation of biphenyls and polychlorobiphenyls have been extensively characterized, comparatively little is known about the regulation of their expression. In the present work, different aspects of transcription of the bph locus of the potent polychlorobiphenyl degrader Burkholderia sp. strain LB400 were investigated. An RNA blot analysis of the entire gene cluster revealed that the transcription of all genes encoding biphenyl catabolic enzymes responded similarly to the presence of biphenyl, succinate or a mixture of the two. One region of the locus, encompassing ORF0, was separately transcribed and differently regulated. A single start position was mapped for this monocistronic transcript. Synthesis of the adjacent RNA, encoding subunits of biphenyl dioxygenase, was strongly biphenyl-inducible. In this case, four major 5'-ends were mapped between 25 and 70 bp upstream of the start codon of gene bphA1. Sequence elements between approximately positions 710 and 1080 upstream were required in cis for full functioning of the respective promoter(s) (P(bphA1)). ORF0(-) mutants of strain LB400 retained the ability to grow on biphenyl, but showed decreased concentrations of bphA1A2 RNA and decreased lacZ expression in strains harbouring a reporter system with a bphA1-lacZ transcriptional fusion. This effect was compensated by the introduction of an intact ORF0 in trans, indicating that the ORF0 gene product mediates activation of P(bphA1).

PhcS represses gratuitous expression of phenol-metabolizing enzymes in Comamonas testosteroni R5

We identified an open reading frame, designated phcS, downstream of the transcriptional activator gene (phcR) for the expression of multicomponent phenol hydroxylase (mPH) in Comamonas testosteroni R5. The deduced product of phcS was homologous to AphS of C. testosteroni TA441, which belongs to the GntR family of transcriptional regulators. The transformation of Pseudomonas aeruginosa PAO1c (phenol negative, catechol positive) with pROR502 containing phcR and the mPH genes conferred the ability to grow on phenol, while transformation with pROR504 containing phcS, phcR, and mPH genes did not confer this ability. The disruption of phcS in strain R5 had no effect on its phenol-oxygenating activity in a chemostat culture with phenol. The phenol-oxygenating activity was not expressed in strain R5 grown in a chemostat with acetate. In contrast, the phenol-oxygenating activity in the strain with a knockout phcS gene when grown in a chemostat with acetate as the limiting growth factor was 66% of that obtained in phenol-grown cells of the strain with a knockout in the phcS gene. The disruption of phcS and/or phcR and the complementation in trans of these defects confirm that PhcS is a trans-acting repressor and that the unfavorable expression of mPH in the phcS knockout cells grown on acetate requires PhcR. These results show that the PhcS protein repressed the gratuitous expression of phenol-metabolizing enzymes in the absence of the genuine substrate and that strain R5 acted by an unknown mechanism in which the PhcS-mediated repression was overcome in the presence of the pathway substrate.

An active role for a structured B-linker in effector control of the sigma54-dependent regulator DmpR

The activities of many prokaryotic sigma54-dependent transcriptional activators are controlled by the N-terminal A-domain of the protein, which is linked to the central transcriptional activation domain via a short B-linker. It used to be thought that these B-linkers simply serve as flexible tethers. Here we show that the B-linker of the aromatic-responsive regulator DmpR and many other regulators of the family contain signature heptad repeats with regularly spaced hydrophobic amino acids. Mutant analysis of this region of DmpR demonstrates that B-linker function is dependent on the heptad repeats and is critical for activation of the protein by aromatic effectors. The phenotypes of DmpR mutants refute the existing model that the level of ATPase activity directly controls the level of transcription it promotes. The mutant analysis also shows that the B-linker is involved in repression of ATPase activity and that allosteric changes upon effector binding are transduced to alleviate both B-linker repression of ATP hydrolysis and A-domain repression of transcriptional activation. The mechanistic implications of these findings for DmpR and other family members are discussed.

Role of the DmpR-mediated regulatory circuit in bacterial biodegradation properties in methylphenol-amended soils

Pathway substrates and some structural analogues directly activate the regulatory protein DmpR to promote transcription of the dmp operon genes encoding the (methyl)phenol degradative pathway of Pseudomonas sp. strain CF600. While a wide range of phenols can activate DmpR, the location and nature of substituents on the basic phenolic ring can limit the level of activation and thus utilization of some compounds as assessed by growth on plates. Here we address the role of the aromatic effector response of DmpR in determining degradative properties in two soil matrices that provide different nutritional conditions. Using the wild-type system and an isogenic counterpart containing a DmpR mutant with enhanced ability to respond to para-substituted phenols, we demonstrate (i) that the enhanced in vitro biodegradative capacity of the regulator mutant strain is manifested in the two different soil types and (ii) that exposure of the wild-type strain to 4-methylphenol-contaminated soil led to rapid selection of a subpopulation exhibiting enhanced capacities to degrade the compound. Genetic and functional analyses of 10 of these derivatives demonstrated that all harbored a single mutation in the sensory domain of DmpR that mediated the phenotype in each case. These findings establish a dominating role for the aromatic effector response of DmpR in determining degradation properties. Moreover, the results indicate that the ability to rapidly adapt regulator properties to different profiles of polluting compounds may underlie the evolutionary success of DmpR-like regulators in controlling aromatic catabolic pathways.

Transcriptional organization and dynamic expression of the hbpCAD genes, which encode the first three enzymes for 2-hydroxybiphenyl degradation in Pseudomonas azelaica HBP1

Pseudomonas azelaica HBP1 degrades the toxic substance 2-hydroxybiphenyl (2-HBP) by means of three enzymes that are encoded by structural genes hbpC, hbpA, and hbpD. These three genes form a small noncontiguous cluster. Their expression is activated by the product of regulatory gene hbpR, which is located directly upstream of the hbpCAD genes. The HbpR protein is a transcription activator and belongs to the so-called XylR/DmpR subclass within the NtrC family of transcriptional activators. Transcriptional fusions between the different hbp intergenic regions and the luxAB genes of Vibrio harveyi in P. azelaica and in Escherichia coli revealed the existence of two HbpR-regulated promoters; one is located in front of hbpC, and the other one is located in front of hbpD. Northern analysis confirmed that the hbpC and hbpA genes are cotranscribed, whereas the hbpD gene is transcribed separately. No transcripts comprising the entire hbpCAD cluster were detected, indicating that transcription from P(hbpC) is terminated after the hbpA gene. E. coli mutant strains lacking the structural genes for the RNA polymerase sigma(54) subunit or for the integration host factor failed to express bioluminescence from P(hbpC)- and P(hbpD)-luxAB fusions when a functional hbpR gene was provided in trans. This pointed to the active role of sigma(54) and integration host factor in transcriptional activation from these promoters. Primer extension analysis revealed that both P(hbpC) and P(hbpD) contain the typical motifs at position -24 (GG) and -12 (GC) found in sigma(54)-dependent promoters. Analysis of changes in the synthesis of the hbp mRNAs, in activities of the 2-HBP pathway enzymes, and in concentrations of 2-HBP intermediates during the first 4 h after induction of continuously grown P. azelaica cells with 2-HBP demonstrated that the specific transcriptional organization of the hbp genes ensured smooth pathway expression.

Purification and catalytic properties of two catechol 1,2-dioxygenase isozymes from benzoate-grown cells of Acinetobacter radioresistens

Two catechol 1,2-dioxygenase (C1,2O) isozymes (IsoA and IsoB) have been purified to homogeneity from a strain of Acinetobacter radioresistens grown on benzoate as the sole carbon and energy source. IsoA and IsoB are both homodimers composed of a single type of subunit with molecular mass of 38,600 and 37,700, Da respectively. In conditions of low ionic strength, IsoA can aggregate as a trimer, in contrast to IsoB, which maintains the dimeric structure, as also supported by the kinetic parameters (Hill numbers). IsoA is identical to the enzyme previously purified from the same bacterium grown on phenol, whereas the IsoB is selectively expressed using benzoate as carbon source. This is the first evidence of the presence of differently expressed C1,2O isozymes in A. radioresistens or more generally of multiple C1,2O isozymes in benzoate-grown Acinetobacter cells. Purified IsoA and IsoB contain approximately 1 iron(III) ion per subunit and both show electronic absorbance and EPR features typical of Fe(III) intradiol dioxygenases. The kinetic properties of the two enzymes such as the specificities toward substituted catechols, the main catalytic parameters, and their behavior in the presence of different kind of inhibitors are, unexpectedly, very similar, in contrast to most of the previously known dioxygenase isozymes.

Genes involved in anaerobic metabolism of phenol in the bacterium Thauera aromatica

Genes involved in the anaerobic metabolism of phenol in the denitrifying bacterium Thauera aromatica have been studied. The first two committed steps in this metabolism appear to be phosphorylation of phenol to phenylphosphate by an unknown phosphoryl donor ("phenylphosphate synthase") and subsequent carboxylation of phenylphosphate to 4-hydroxybenzoate under release of phosphate ("phenylphosphate carboxylase"). Both enzyme activities are strictly phenol induced. Two-dimensional gel electrophoresis allowed identification of several phenol-induced proteins. Based on N-terminal and internal amino acid sequences of such proteins, degenerate oligonucleotides were designed to identify the corresponding genes. A chromosomal DNA segment of about 14 kbp was sequenced which contained 10 genes transcribed in the same direction. These are organized in two adjacent gene clusters and include the genes coding for five identified phenol-induced proteins. Comparison with sequences in the databases revealed the following similarities: the gene products of two open reading frames (ORFs) are each similar to either the central part and N-terminal part of phosphoenolpyruvate synthases. We propose that these ORFs are components of the phenylphosphate synthase system. Three ORFs showed similarity to the ubiD gene product, 3-octaprenyl-4-hydroxybenzoate carboxy lyase; UbiD catalyzes the decarboxylation of a 4-hydroxybenzoate analogue in ubiquinone biosynthesis. Another ORF was similar to the ubiX gene product, an isoenzyme of UbiD. We propose that (some of) these four proteins are involved in the carboxylation of phenylphosphate. A 700-bp PCR product derived from one of these ORFs cross-hybridized with DNA from different Thauera and Azoarcus strains, even from those which have not been reported to grow with phenol. One ORF showed similarity to the mutT gene product, and three ORFs showed no strong similarities to sequences in the databases. Upstream of the first gene cluster, an ORF which is transcribed in the opposite direction codes for a protein highly similar to the DmpR regulatory protein of Pseudomonas putida. DmpR controls transcription of the genes of aerobic phenol metabolism, suggesting a similar regulation of anaerobic phenol metabolism by the putative regulator.

The Sinorhizobium meliloti ExpE1 protein secreted by a type I secretion system involving ExpD1 and ExpD2 is required for biosynthesis or secretion of the exopolysaccharide galactoglucan

In Sinorhizobium meliloti the biosynthesis of the exopolysaccharide galactoglucan (EPS II) is directed by the exp genes. The expD1 and expD2 gene products are homologous to components of type I secretion systems. ExpE1, the gene of which is located adjacent to expD1 and expD2, was detected in S. meliloti cells and culture supernatants. ExpD1 and ExpD2 were required for the secretion of ExpE1, indicating that ExpE1 is secreted by a type I secretion system involving ExpD1 and ExpD2. ExpE1 contains 15 aspartate- and glycine-rich nonapeptide repeats that were suggested to bind Ca(2+). The ability to bind Ca(2+) was demonstrated for a recombinant ExpE1 protein. Extracellular EPS II was not detected in cultures of non-polar expD1, expD2 and expE1 deletion mutants implying that these three genes are required for biosynthesis or secretion of galactoglucan.

HbpR, a new member of the XylR/DmpR subclass within the NtrC family of bacterial transcriptional activators, regulates expression of 2-hydroxybiphenyl metabolism in Pseudomonas azelaica HBP1

The regulation of 2-hydroxybiphenyl and 2,2'-dihydroxybiphenyl degradation in Pseudomonas azelaica is mediated by the regulatory gene, hbpR. The hbpR gene encodes a 63-kDa protein belonging to the NtrC family of prokaryotic transcriptional activators and having the highest homology to members of the XylR/DmpR subclass. Disruption of the hbpR gene in P. azelaica and complementation in trans showed that the HbpR protein was the key regulator for 2-hydroxybiphenyl metabolism. Induction experiments with P. azelaica and Escherichia coli containing luxAB-based transcriptional fusions revealed that HbpR activates transcription from a promoter (P(hbpC)) in front of the first gene for 2-hydroxybiphenyl degradation, hbpC, and that 2-hydroxybiphenyl itself is the direct effector for HbpR-mediated activation. Of several compounds tested, only the pathway substrates 2-hydroxybiphenyl and 2,2'-dihydroxybiphenyl and structural analogs like 2-aminobiphenyl and 2-hydroxybiphenylmethane were effectors for HbpR activation. HbpR is therefore, to our knowledge, the first regulator of the XylR/DmpR class that recognizes biaromatic but not monoaromatic structures. Analysis of a spontaneously occurring mutant, P. azelaica HBP1 Prp, which can grow with the non-wild-type effector 2-propylphenol, revealed a single mutation in the hbpR gene (T613C) leading to a Trp-->Arg substitution at amino acid residue 205. P. azelaica HBP1 derivative strains without a functional hbpR gene constitutively expressed the genes for 2-hydroxybiphenyl degradation when complemented in trans with the hbpR-T613C gene. This suggests the importance of this residue, which is conserved among all members of the XylR/DmpR subclass, for interdomain repression.

Generation of novel bacterial regulatory proteins that detect priority pollutant phenols

The genetic systems of bacteria that have the ability to use organic pollutants as carbon and energy sources can be adapted to create bacterial biosensors for the detection of industrial pollution. The creation of bacterial biosensors is hampered by a lack of information about the genetic systems that control production of bacterial enzymes that metabolize pollutants. We have attempted to overcome this problem through modification of DmpR, a regulatory protein for the phenol degradation pathway of Pseudomonas sp. strain CF600. The phenol detection capacity of DmpR was altered by using mutagenic PCR targeted to the DmpR sensor domain. DmpR mutants were identified that both increased sensitivity to the phenolic effectors of wild-type DmpR and increased the range of molecules detected. The phenol detection characteristics of seven DmpR mutants were demonstrated through their ability to activate transcription of a lacZ reporter gene. Effectors of the DmpR derivatives included phenol, 2-chlorophenol, 2,4-dichlorophenol, 4-chloro-3-methylphenol, 2,4-dimethylphenol, 2-nitrophenol, and 4-nitrophenol.

Specific interaction of the RNA-binding domain of the bacillus subtilis transcriptional antiterminator GlcT with its RNA target, RAT

Expression of the Bacillus subtilis ptsGHI operon is controlled by transcriptional antitermination mediated by the antiterminator protein GlcT. The antiterminator is inactivated in the absence of glucose, presumably by phosphorylation. A conditional terminator in the ptsG mRNA leader region has been identified. Mutations in this terminator resulted in constitutive expression of the operon. The terminator is overlapped by an inverted repeat (called ribonucleic-antiterminator, RAT) which is thought to form a stem-loop structure upon binding of the antiterminator protein GlcT. The N-terminal 60 amino acid residues of GlcT are able to bind to the RAT and prevent transcriptional termination in vivo. Sequence-specific interaction between the RNA-binding domain and the RAT was demonstrated by surface plasmon resonance analysis. Mutations affecting the RNA-binding domain were isolated and will be discussed with respect to their consequences for dimerization and RNA binding.

Novel effector control through modulation of a preexisting binding site of the aromatic-responsive sigma(54)-dependent regulator DmpR

The Pseudomonas derived sigma(54)-dependent DmpR activator regulates transcription of the (methyl)phenol catabolic dmp-operon. DmpR is constitutively expressed, but its transcriptional promoting activity is positively controlled in direct response to the presence of multiple aromatic effectors. Previous work has led to a model in which effector binding by the amino-terminal region of the protein relieves repression of an intrinsic ATPase activity essential for its transcriptional promoting property. Here, we address whether the observed differences in the potencies of the multiple effectors (i) reside at the level of different aromatic binding sites, or (ii) are mediated through differential binding affinities; furthermore, we address whether binding of distinct aromatic effectors has different functional consequences for DmpR activity. These questions were addressed by comparing wild type and an effector specificity mutant of DmpR with respect to effector binding characteristics and the ability of aromatics to elicit ATPase activity and transcription. The results demonstrate that six test aromatics all share a common binding site on DmpR and that binding affinities determine the concentration at which DmpR responds to the presence of the effector, but not the magnitude of the responses. Interestingly, this analysis reveals that the novel abilities of the effector specificity mutant are not primarily due to acquisition of new binding abilities, but rather, they reside in being able to productively couple ATPase activity to transcriptional activation. The mechanistic implications of these findings in terms of aromatic control of DmpR activity are discussed.

Adaptation of Comamonas testosteroni TA441 to utilization of phenol by spontaneous mutation of the gene for a trans-acting factor

Comamonas testosteroni TA441 adapts to utilization of phenol upon incubation with phenol as the major carbon source. Strain TA441 has a cluster of genes (aphKLMNOPQB) encoding the catabolic enzymes phenol hydroxylase and catechol 2,3-dioxygenase, and a divergently transcribed regulatory gene (aphR), but these genes are silent until adaptation occurs. We found another regulatory gene (aphS) downstream of aphR. AphS belongs to the GntR family of transcriptional regulators. All adapted strains were found to have mutations in the aphS gene or in the aphR-aphS intervening region. The adapted strains expressed phenol hydroxylase and catechol 2, 3-dioxygenase activity in the presence of phenol. The transcriptional activity of both the aphK and the aphR promoters was elevated in the adapted strains. A strain whose aphS gene was artificially disrupted was found to be able to grow using phenol, and the cells showed high levels of the above-mentioned transcriptional and enzymatic activities, indicating that adaptation was caused only by the mutation in the aphS gene. Gel retardation analysis revealed that AphS bound to two specific sites in the promoter region between aphK and aphR. These results indicate that the active aphS gene product acts as a trans-acting factor and represses transcription of the aph genes in strain TA441.

Expression of alkane hydroxylase from Acinetobacter sp. Strain ADP1 is induced by a broad range of n-alkanes and requires the transcriptional activator AlkR

In Acinetobacter sp. strain ADP1, alkane degradation depends on at least five essential genes. rubAB and xcpR are constitutively transcribed. Here we describe inducible transcription of alkM, which strictly depends on the presence of the transcriptional activator AlkR. alkR itself is expressed at a low level, while a chromosomally located alkM::lacZ fusion is inducible by middle-chain-length alkanes from heptane to undecane, which do not support growth of ADP1, and by long-chain-length alkanes from dodecane to octadecane, which are used as sources of carbon and energy. The putative AlkM substrate 1-dodecene is also an effective inducer. Products of alkane hydroxylase activity like 1-dodecanol prevent induction of alkM expression. alkM is expressed only in stationary phase, suggesting its dependence on at least one other regulatory mechanism.

Adaptation of Comamonas testosteroni TA441 to utilize phenol: organization and regulation of the genes involved in phenol degradation

Comamonas testosteroni TA441 was not able to grow on phenol as a sole carbon and energy source, but it gained the ability to utilize phenol after a 2-3-week incubation in a medium containing phenol. Phenol hydroxylase (PH) and catechol 2,3-dioxygenase (C230) were highly induced by phenol in the adapted strain designated as strain P1, suggesting that phenol was degraded via the meta-pathway. Gene clusters for phenol degradation were isolated from both strains TA441 and P1. The structural genes encoding multi-component PH and C230 (aphKLMNOPQB), and a regulatory gene of the NtrC family (aphR), were located in a divergent transcriptional organization. The cloned aphKLMNOPQB genes from either strain TA441 or strain P1 produced active PH and C230 enzymes in strain TA441. No difference was found between the strains in the sequences of aphR and the intergenic promoter region of aphK and aphR. However, the transcriptional activities of the aphK and aphR promoters were higher in strain P1 than in strain TA441. The aphK-promoter activity was not observed in aphR mutant strains and these strains could not grow on phenol. The aphR mutant of strain P1 was able to grow on phenol after transformation with a recombinant aphR gene but strain TA441 was not, suggesting that the expression of the aph genes is silenced by an unidentified repressor in strain TA441 and that this repressor is modified in strain P1.

Similarities between the antABC-encoded anthranilate dioxygenase and the benABC-encoded benzoate dioxygenase of Acinetobacter sp. strain ADP1

Acinetobacter sp. strain ADP1 can use benzoate or anthranilate as a sole carbon source. These structurally similar compounds are independently converted to catechol, allowing further degradation to proceed via the beta-ketoadipate pathway. In this study, the first step in anthranilate catabolism was characterized. A mutant unable to grow on anthranilate, ACN26, was selected. The sequence of a wild-type DNA fragment that restored growth revealed the antABC genes, encoding 54-, 19-, and 39-kDa proteins, respectively. The deduced AntABC sequences were homologous to those of class IB multicomponent aromatic ring-dihydroxylating enzymes, including the dioxygenase that initiates benzoate catabolism. Expression of antABC in Escherichia coli, a bacterium that normally does not degrade anthranilate, enabled the conversion of anthranilate to catechol. Unlike benzoate dioxygenase (BenABC), anthranilate dioxygenase (AntABC) catalyzed catechol formation without requiring a dehydrogenase. In Acinetobacter mutants, benC substituted for antC during growth on anthranilate, suggesting relatively broad substrate specificity of the BenC reductase, which transfers electrons from NADH to the terminal oxygenase. In contrast, the benAB genes did not substitute for antAB. An antA point mutation in ACN26 prevented anthranilate degradation, and this mutation was independent of a mucK mutation in the same strain that prevented exogenous muconate degradation. Anthranilate induced expression of antA, although no associated transcriptional regulators were identified. Disruption of three open reading frames in the immediate vicinity of antABC did not prevent the use of anthranilate as a sole carbon source. The antABC genes were mapped on the ADP1 chromosome and were not linked to the two known supraoperonic gene clusters involved in aromatic compound degradation.

Aromatic ligand binding and intramolecular signalling of the phenol-responsive sigma54-dependent regulator DmpR

The Pseudomonas-derived sigma54-dependent regulator DmpR has an amino-terminal A-domain controlling the specificity of activation by aromatic effectors, a central C-domain mediating an ATPase activity essential for transcriptional activation and a carboxy-terminal D-domain involved in DNA binding. In the presence of aromatic effectors, the DmpR protein promotes transcription from the -24, -12 Po promoter controlling the expression of specialized (methyl)phenol catabolic enzymes. Previous analysis of DmpR has led to a model in which the A-domain acts as an interdomain repressor of DmpR's ATPase and transcriptional promoting property until specific aromatic effectors are bound. Here, the autonomous nature of the A-domain in exerting its biological functions has been dissected by expressing portions of DmpR as independent polypeptides. The A-domain of DmpR is shown to be both necessary and sufficient to bind phenol. Analysis of phenol binding suggests one binding site per monomer of DmpR, with a dissociation constant of 16 microM. The A-domain is also shown to have specific affinity for the C-domain and to repress the C-domain mediated ATPase activity in vitro autonomously. However, physical uncoupling of the A-domain from the remainder of the regulator results in a system that does not respond to aromatics by its normal derepression mechanism. The mechanistic implications of aromatic non-responsiveness of autonomously expressed A-domain, despite its demonstrated ability to bind phenol, are discussed.