Regulation of the nah and sal operons of plasmid NAH7: evidence for a new function in nahR

The catabolism of naphthalene and salicylate is specified by two operons on an 80 Kb metabolic plasmid, NAH7. These operons, nah and sal, are carried on the contiguous 30 Kb EcoRI-A, C fragments, and are under positive control of a regulator region, nahR. Five Nah Sal Tn5 insertion mutants form two complementation groups: A = nahR203, nahR204; and B = nahR201, nahR202, nahR205. The physical and genetic maps assign the nahR location to the 15.7-17.2 Kb region of the EcoRI-A fragment, with suggestion of more than one control gene.     

Nucleotide sequence of plasmid NAH7 gene nahR and DNA binding of the nahR product.

The nah and sal operons of the 80-kilobase-pair (kb) NAH7 plasmid specify catabolism of naphthalene and salicylate under positive regulation by gene nahR. A 1.75-kb fragment (PstI-HindIII) cloned into the pCP13 derivative of vector RK2 complemented in trans five nahR mutations. The fragment sequence contained a 1,122-base-pair open reading frame with a predicted sequence of 374 residues that was rich in basic amino acids with regions similar to known DNA-binding proteins. Clones from the nahR gene region were expressed in mexicells. Plasmid pY1923, carrying the 1.75-kb PstI-HindIII fragment, expressed a protein of Mr ca. 35,000 which bound to the upstream region of gene nahR in a gel electrophoresis DNA-binding assay. Other clones expressed proteins of currently unknown function; pY1311, with the 1.1-kb HindIII fragment, produced a polypeptide with an Mr of 23,000, and pY1812, with the 1.2-kb PstI-SphI fragment, produced a polypeptide (Mr 41,000) which appeared to be a fused nahR-lacZ product.     

Cloning of genes for naphthalene metabolism in Pseudomonas putida.

Plasmid pIG7 DNA cloned in Pseudomonas putida with the broad-host-range vectors pRK290 and pKT240 expresses the genes encoding nephthalene oxidation in the presence of the intermediate substrate, salicylate, or the gratuitous inducer, anthranilate. Two operons, nahAF and nahGK, cloned from the EcoRI fragment A (25 kilobases) are under wild-type regulation by the nahR locus. Deletion plasmids provide a restriction map of both operons. Double transformants containing structural and regulatory cistron nahR in trans are used to demonstrate positive control of expression.     

Analyses of polycyclic aromatic hydrocarbon-degrading bacteria isolated from contaminated soils

Polycyclic aromatic hydrocarbon (PAH)-degrading bacteria isolated from PAH-contaminated soils were analyzed genotypically and phenotypically for their capacity for metabolism of naphthalene and other PAH substrates. The methods used for the analyses were DNA hybridization using NAH7-derived gene probes, PAH spray plate assays, ¹⁴C-PAH mineralization assays, and dioxygenase activity assays. The results of the analyses showed a dominant number of PAH-degrading bacteria with a NAH7-like genotype. The results support the continued use of the nahA probe for contaminated soils to monitor the genetic potential of indigenous microorganisms to degrade PAHs. However, the finding of non-it nahA-hybridizing PAH-degrading bacteria show the limitation of NAH7-derived gene probes. Fifteen percent (13/89) of PAH-degrading bacteria isolated were not detected with the nahA gene probe. Four isolates (designated A5PH1, A8AN3, B1PH2, and B10AN1) did not hybridize with any of the NAH7-derived gene probes ( nahA, nahG, nahH, and nahR) used in this study. Considering the numerous unculturable microorganisms in nature and their potential genotypes, NAH7-derived gene probes may underestimate the microbial potential to catabolize PAHs. This necessitates development of new gene probes for enumeration and isolation of PAH-degrading bacteria to better understand the in situ microbial potential to degrade PAHs.     

Development of a molecular detection method for naphthalene degrading pseudomonads

Abstract: A combined polymerase chain reaction amplification and reverse dot blot assay was designed for the detection of bacterial genes from soil and sediments. Total nucleic acids were directly extracted from soil using a lysozyme/sodium dodecyl sulfate/freeze-thaw method followed by rapid purification through gel electrophoresis. DNA was amplified using a highly stringent polymerase chain reaction with primers directed against the nahR regulatory gene present in plasmid NAH7 of Pseudomonas putida G7. The resulting amplification product was detected colorimetrically by reverse dot blot with an improved sensitivity ten-fold greater than traditional ethidium bromide staining after gel electrophersis. A lower limit of 10³, P. putida G7 cfu (g soil)⁻¹ was detected. This method was successfully employed to detect indigenous naphthalene-degrading bacteria from subsurface sediment collected from different locations of a naphthalene-contaminated site. Similar approaches could be developed for other soil-borne genetic markers.     

Divergent evolution of chloroplast-type ferredoxins

The TOL plasmid pWW0 of Pseudomonas putida encodes a set of enzymes required for the oxidation of toluene to Krebs cycle intermediates. The structural genes for these enzymes are encoded in two operons which comprise the xylCMABN and xylXYZLTEGFJQKIH genes, respectively. The function of the xylT gene has not yet been identified. The nucleotide sequence of xylT was determined in this study and putative gene product was shown to contain a sequence characteristic for chloroplast-type ferredoxins. The nahT gene, the homologue of xylT, present on NAH plasmid NAH7 encoding naphthalene-degrading enzymes, was also sequenced. The sequence conservation between xylT and nahT strongly suggests that both gene products have some physiological function. Chloroplast-type ferredoxins have been discovered in photosynthetic organisms (plants, algae, cyanobacteria and Rhodobacter) and Halobacterium species. Furthermore, chloroplast-type ferredoxin-like sequences have been found in the electron-transfer components of some oxygenases. The sequences of XylT and NahT were compared with those of the previously identified chloroplast-type ferredoxins, in order to examine their evolutionary relationships.     

Role of the catabolite activator protein in the maltose regulon of Escherichia coli.

The maltose regulon consists of three operons controlled by a positive regulatory gene, malT. Deletions of the gene crp were introduced into strains which carried a malT-lacZ hybrid gene. From the observed reduction in beta-galactosidase activity it was concluded that the expression of malT-lacZ, and therefore of malT, is controlled by the catabolite activator protein (CAP), the product of the gene crp. Mutations were obtained which allowed a malT-lacZ hybrid gene to be expressed at a high level even in the absence of CAP. These mutations were shown to be located in or close to the promoter of the malT gene and were called malTp. The malTp mutations were transferred in the cis position to a wild-type malT gene. In the resulting strains, the expression of two of the maltose operons, malEFG and malK-lamB, still required the action of CAP, whereas that of the third operon, malPQ, was CAP independent. Therefore, in wild-type cells, CAP appears to control malPQ expression mainly, if not solely, by regulating the concentration of MalT protein in the cell. On the other hand, it controls the other two operons more stringently, both by regulating malT expression and by a more direct action, probably exerted in the promoters of these operons.     

Electron microscope heteroduplex mapping of naphthalene oxidation genes on the NAH7 and SAL1 plasmids

Introduction of the transposon Tn5 to serve as a marker allows electron microscope heteroduplex mapping of the naphthalene oxidation genes on the approximately 83-kb NAH7 and the related approximately 85-kb SAL1 plasmids. The electron microscope-mapped gene positions on the NAH7 plasmid are in close agreement with those mapped previously by restriction digestion. The SAL1 plasmid can be considered as a mutant NAH7 plasmid which fails to direct the conversion of naphthalene to salicylate because of a mutational block but retains intact coding sequences for salicylate oxidation. Analysis of heteroduplex molecules formed between the SAL1 and NAH7::Tn5 EcoRI fragments and the known NAH7/SAL1 homology strongly suggest that the SAL1 DNA is completely homologous to NAH7 DNA except that a approximately 2.5-kb DNA segment constituting most of the nahA gene is replaced by approximately 4.6-kb nonhomologous DNA.     

The control region of the pdu/cob regulon in Salmonella typhimurium.

The pdu operon encodes proteins for the catabolism of 1,2-propanediol; the nearby cob operon encodes enzymes for the biosynthesis of adenosyl-cobalamin (vitamin B12), a cofactor required for the use of propanediol. These operons are transcribed divergently from distinct promoters separated by several kilobases. The regulation of the two operons is tightly integrated in that both require the positive activator protein PocR and both are subject to global control by the Crp and ArcA proteins. We have determined the DNA nucleotide sequences of the promoter-proximal portion of the pdu operon and the region between the pdu and cob operons. Four open reading frames have been identified, pduB, pduA, pduF, and pocR. The pduA and pduB genes are the first two genes of the pdu operon (transcribed clockwise). The pduA gene encodes a hydrophobic protein with 56% amino acid identity to a 10.9-kDa protein which serves as a component of the carboxysomes of several photosynthetic bacteria. The pduF gene encodes a hydrophobic protein with a strong similarity to the GlpF protein of Escherichia coli, which facilitates the diffusion of glycerol. The N-terminal end of the PduF protein includes a motif for a membrane lipoprotein-lipid attachment site as well as a motif characteristic of the MIP (major intrinsic protein) family of transmembrane channel proteins. We presume that the PduF protein facilitates the diffusion of propanediol. The pocR gene encodes the positive regulatory protein of the cob and pdu operons and shares the helix-turn-helix DNA binding motif of the AraC family of regulatory proteins. The mutations cobR4 and cobR58 cause constitutive, pocR-independent expression of the cob operon under both aerobic and anaerobic conditions. Evidence that each mutation is a deletion creating a new promoter near the normal promoter site of the cob operon is presented.     

Identification of cfxR, an activator gene of autotrophic CO2 fixation in Alcaligenes eutrophus

A regulatory gene, cfxR, involved in the carbon dioxide assimilation of Alcaligenes eutrophus H16 has been characterized through the analysis of mutants. The function of cfxR is required for the expression of two cfx operons that comprise structural genes encoding Calvin cycle enzymes. CfxR (34.8 kDa) corresponds with an open reading frame of 954 bp, with a translational initiation codon 167 bp upstream of the chromosomal cfx operon. The cfx operon and cfxR are transcribed divergently. The N-terminal sequence of CfxR is very similar to those of bacterial regulatory proteins belonging to the LysR family. Heterologous expression of cfxR in Escherichia coli was achieved using the pT7-7 system. Mobility shift experiments demonstrated that CfxR is a DNA-binding protein with a target site upstream of both the chromosomal and the plasmid-encoded cfx operons.     

Lrp, a leucine-responsive protein, regulates branched-chain amino acid transport genes in Escherichia coli.

We investigated the relationship between two regulatory genes, livR and lrp, that map near min 20 on the Escherichia coli chromosome. livR was identified earlier as a regulatory gene affecting high-affinity transport of branched-chain amino acids through the LIV-I and LS transport systems, encoded by the livJ and livKHMGF operons. lrp was characterized more recently as a regulatory gene of a regulon that includes operons involved in isoleucine-valine biosynthesis, oligopeptide transport, and serine and threonine catabolism. The expression of each of these livR- and lrp-regulated operons is altered in cells when leucine is added to their growth medium. The following results demonstrate that livR and lrp are the same gene. The lrp gene from a livR1-containing strain was cloned and shown to contain two single-base-pair substitutions in comparison with the wild-type strain. Mutations in livR affected the regulation of ilvIH, an operon known to be controlled by lrp, and mutations in lrp affected the regulation of the LIV-I and LS transport systems. Lrp from a wild-type strain bound specifically to several sites upstream of the ilvIH operon, whereas binding by Lrp from a livR1-containing strain was barely detectable. In a strain containing a Tn10 insertion in lrp, high-affinity leucine transport occurred at a high, constitutive level, as did expression from the livJ and livK promoters as measured by lacZ reporter gene expression. Taken together, these results suggest that Lrp acts directly or indirectly to repress livJ and livK expression and that leucine is required for this repression. This pattern of regulation is unusual for operons that are controlled by Lrp.