Development of a vital fluorescent staining method for monitoring bacterial transport in subsurface environments.

Previous bacterial transport studies have utilized fluorophores which have been shown to adversely affect the physiology of stained cells. This research was undertaken to identify alternative fluorescent stains that do not adversely affect the transport or viability of bacteria. Initial work was performed with a groundwater isolate, Comamonas sp. strain DA001. Potential compounds were first screened to determine staining efficiencies and adverse side effects. 5-(And 6-)-carboxyfluorescein diacetate, succinimidyl ester (CFDA/SE) efficiently stained DA001 without causing undesirable effects on cell adhesion or viability. Members of many other gram-negative and gram-positive bacterial genera were also effectively stained with CFDA/SE. More than 95% of CFDA/SE-stained Comamonas sp. strain DA001 cells incubated in artificial groundwater (under no-growth conditions) remained fluorescent for at least 28 days as determined by epifluorescent microscopy and flow cytometry. No differences in the survival and culturability of CFDA/SE-stained and unstained DA001 cells in groundwater or saturated sediment microcosms were detected. The bright, yellow-green cells were readily distinguished from autofluorescing sediment particles by epifluorescence microscopy. A high throughput method using microplate spectrofluorometry was developed, which had a detection limit of mid-10(5) CFDA-stained cells/ml; the detection limit for flow cytometry was on the order of 1,000 cells/ml. The results of laboratory-scale bacterial transport experiments performed with intact sediment cores and nondividing DA001 cells revealed good agreement between the aqueous cell concentrations determined by the microplate assay and those determined by other enumeration methods. This research indicates that CFDA/SE is very efficient for labeling cells for bacterial transport experiments and that it may be useful for other microbial ecology research as well.

Nucleotide sequence and initial functional characterization of the clcR gene encoding a LysR family activator of the clcABD chlorocatechol operon in Pseudomonas putida.

The 3-chlorocatechol operon clcABD is central to the biodegradative pathway of 3-chlorobenzoate. The clcR regulatory gene, which activates the clcABD operon, was cloned from the region immediately upstream of the operon and was shown to complement an insertion mutation for growth on 3-chlorobenzoate. ClcR activated the clcA promoter, which controls expression of the clcABD operon, in trans by 14-fold in an in vivo promoter probe assay in Pseudomonas putida when cells were incubated with 15 mM 3-chlorobenzoic acid. Specific binding of ClcR to the clcR-clcA intergenic promoter region was observed in a gel shift assay. Nucleotide sequence analysis of the clcR gene predicts a polypeptide of 32.5 kDa, which was confirmed by using specific in vivo 35S labeling of the protein from a T7 promoter-controlled ATG fusion construct. ClcR shares high sequence identity with the LysR family of bacterial regulator proteins and has especially high homology to a subgroup of the family consisting of TcbR (57% amino acid sequence identity), TfdS, CatR, and CatM. ClcR was shown to autoregulate its own production in trans to 35% of unrepressed levels but partially relieved this autorepression under conditions that induced transcription at the clcA promoter. Several considerations indicate that the clcR-clcABD locus is most similar to the tcbR-tcbCDEF regulon.

Roles of CatR and cis,cis-muconate in activation of the catBC operon, which is involved in benzoate degradation in Pseudomonas putida.

In Pseudomonas putida, the catBC operon encodes enzymes involved in benzoate degradation. Previous studies have determined that these enzymes are induced when P. putida is grown in the presence of benzoate. Induction of the enzymes of the catBC operon requires an intermediate of benzoate degradation, cis,cis-muconate, and a regulatory protein, CatR. It has been determined that CatR binds to a 27-bp region of the catBC promoter in the presence or absence of inducer. We have called this the repression binding site. In this study, we used a gel shift assay to demonstrate that the inducer, cis,cis-muconate, increases the affinity of CatR for the catBC promoter region by 20-fold. Furthermore, in the absence of cis,cis-muconate, CatR forms two complexes in the gel shift assay. The inducer cis,cis-muconate confers specificity primarily for the formation of complex 2. DNase I footprinting showed that an additional 27 bp of the catBC promoter region is protected by CatR in the presence of cis,cis-muconate. We have named this second binding site the activation binding site. Methylation interference footprinting determined that in the presence or absence of inducer, five G nucleotides of the catBC promoter region were necessary for CatR interaction with the repression binding site, while a single G residue was important for CatR interaction with the activation binding site in the presence of cis,cis-muconate. Using polymerase chain reaction-generated constructs, we found that the binding of CatR to the repression binding site is independent of the activation binding site. However, binding of CatR to the activation binding site required an intact repression binding site.

Functional analysis of the Pseudomonas putida regulatory protein CatR: transcriptional studies and determination of the CatR DNA-binding site by hydroxyl-radical footprinting.

CatR, a LysR family protein, positively regulates the Pseudomonas putida catBC operon, which is required for growth on benzoate as a sole carbon source. Transcriptional studies show that the catR and catBC promoters are divergent and overlapping by 2 bp. A beta-galactosidase promoter probe vector was constructed to analyze expression from the catR and catBC promoters under induced and uninduced conditions. As predicted, the catBC promoter is expressed only under induced conditions, while the catR promoter is constitutive. CatR has been shown to specifically bind the catRBC promoter region, and this property was used to devise a purification protocol for CatR. Linear M13 DNA containing the catRBC control region was covalently bound to cyanogen bromide-activated Sepharose in order to construct a DNA affinity column. Crude extracts containing hyperproduced CatR protein were then incubated with the affinity resin under binding conditions, and the CatR protein was eluted with 1 M NaCl. CatR was also purified by heparin-agarose chromatography. This highly purified protein was used for gel retardation and hydroxyl-radical footprinting studies. From this analysis, it was shown that CatR binds upstream of the catBC promoter within the transcribed region of catR.

Alginate synthesis by Pseudomonas aeruginosa: a key pathogenic factor in chronic pulmonary infections of cystic fibrosis patients.

Pulmonary infection by mucoid, alginate-producing Pseudomonas aeruginosa is the leading cause of mortality among patients suffering from cystic fibrosis. Alginate-producing P. aeruginosa is uniquely associated with the environment of the cystic fibrosis-affected lung, where alginate is believed to increase resistance to both the host immune system and antibiotic therapy. Recent evidence indicates that P. aeruginosa is most resistant to antibiotics when the infecting cells are present as a biofilm, as they appear to be in the lungs of cystic fibrosis patients. Inhibition of the protective alginate barrier with nontoxic compounds targeted against alginate biosynthetic and regulatory proteins may prove useful in eradicating P. aeruginosa from this environment. Our research has dealt with elucidating the biosynthetic pathway and regulatory mechanism(s) responsible for alginate synthesis by P. aeruginosa. This review summarizes reports on the role of alginate in cystic fibrosis-associated pulmonary infections caused by P. aeruginosa and provides details about the biosynthesis and regulation of this exopolysaccharide.

Nucleotide sequencing and characterization of Pseudomonas putida catR: a positive regulator of the catBC operon is a member of the LysR family.

Pseudomonas putida utilizes the catBC operon for growth on benzoate as a sole carbon source. This operon is positively regulated by the CatR protein, which is encoded from a gene divergently oriented from the catBC operon. The catR gene encodes a 32.2-kilodalton polypeptide that binds to the catBC promoter region in the presence or absence of the inducer cis-cis-muconate, as shown by gel retardation studies. However, the inducer is required for transcriptional activation of the catBC operon. The catR promoter has been localized to a 385-base-pair fragment by using the broad-host-range promoter-probe vector pKT240. This fragment also contains the catBC promoter whose -35 site is separated by only 36 nucleotides from the predicted CatR translational start. Dot blot analysis suggests that CatR binding to this dual promoter-control region, in addition to inducing the catBC operon, may also regulate its own expression. Data from a computer homology search using the predicted amino acid sequence of CatR, deduced from the DNA sequence, showed CatR to be a member of a large class of procaryotic regulatory proteins designated the LysR family. Striking homology was seen between CatR and a putative regulatory protein, TfdS.

Identification of nucleotides critical for activity of the Pseudomonas putida catBC promoter.

Pseudomonas putida utilizes the catBC operon, which encodes cis,cis-muconate lactonizing enzyme I (MLEI; EC 5.5.1.1) and muconolactone isomerase (MI; EC 5.3.3.4), for growth on benzoate as a sole carbon source. This operon is positively regulated, and the promoter is located 64 bp upstream of the catB translational start site. Using site-specific mutagenesis, we identified nucleotides that influenced the induction of this promoter. Promoter activity was monitored with the promoter probe vector pKT240. Transcription of mRNA from mutant promoters was determined by primer extension mapping. Comparison of the initiation start site of mutant promoters with that of the wild-type promoter identified a single functional promoter.

Mutational analysis of the lac regulatory region: second-site changes that activate mutant promoters.

Second-site mutations that restored activity to severe lacP1 down-promoter mutants were isolated. This was accomplished by using a bacteriophage f1 vector containing a fusion of the mutant E. coli lac promoters with the structural gene for chloramphenicol acetyltransferase (CAT), so that a system was provided for selecting phage revertants (or pseudorevertants) that conferred resistance of phage-infected cells to chloramphenicol. Among the second-site changes that relieved defects in mutant lac promoters, the only one that restored lacP1 activity was a T----G substitution at position -14, a weakly conserved site in E. coli promoters. Three other sequence changes, G----A at -2, A----T at +1, and C----A at +10, activated nascent promoters in the lac regulatory region. The nascent promoters conformed to the consensus rule, that activity is gained by sequence changes toward homology with consensus sequences at the -35 and -10 regions of the promoter. However, the relative activities of some promoters cannot be explained solely by consideration of their conserved sequence elements.