Interplay of the PtsN (EIIA(Ntr)) protein of Pseudomonas putida with its target sensor kinase KdpD.

The nitrogen phosphotransferase system (PTS(Ntr) ) of Pseudomonas putida is a multi-component regulatory device that participates in controlling a variety of physiological processes in a post-translational fashion. A general survey of genes regulated by PtsN exposed transcription of the kdpFABC operon is most conspicuously affected. Measurements of kdpFp promoter activity in different pts mutants showed that PtsN is responsible for repression of kdpFABC transcription. This effect could be assigned mainly to PtsN∼P, depending on the external K(+) concentration. Bacterial two-hybrid assays demonstrated that kdpFp regulation is implemented through direct interaction of the PtsN protein with the sensor kinase KdpD of the KdpD/KdpE two-component system. Interaction between KdpD and PtsN was detectable with a PtsN variant that imitates the non-phosphorylated form as well as with a PtsN type mimicking the phosphorylated form of PtsN. These results raise a regulatory scenario in which the Kdp system is regulated by the action of PtsN through direct interaction with the sensor kinase KdpD, and the outcome of such an interaction depends on the phosphorylation state of PtsN as well as on the external K(+) concentration.

Recombinant bacteria for environmental release: what went wrong and what we have learnt from it.

From a biotechnological point of view, bacteria can be seen as either pathogens to target with new drugs or as biocatalysts for large-scale processes in industry, agriculture or the environment. The last includes the exploitation of bacterial activities for bioremediation of toxic waste either in situ or ex situ. The onset of genetic engineering in the late 70s opened the possibility of tailoring recombinant bacteria for environmental release, aimed at biodegradation of otherwise recalcitrant chemicals. However, a few decades later the outcome of this prospect has been quite meager. The literature counts very few cases where the use of genetically engineered bacteria has been proven to be more efficient than natural microorganisms in elimination of recalcitrant compounds under natural (not laboratory) conditions. Fortunately, the emergence of Systems and Synthetic Biology in the last few years is helping to identify what were the caveats of the former approaches and how to correct them. In addition, robust design concepts imported from process engineering provides fresh approaches to the challenge of designing microorganisms á la carte for environmental applications.

Improvement of recombinant protein yield by a combination of transcriptional amplification and stabilization of gene expression.

We explored the use of a cascade circuit for heterologous gene expression that consists of a regulatory module with a salicylate-inducible system that controls the expression of a second regulator, xylS2, whose product is activated by common inducers. Activation and increasing the concentration of the second regulator synergistically induced heterologous genes downstream of the Pm promoter in the expression module. This module can be placed in multicopy vectors or in the chromosome of a host strain by means of minitransposons. Using reporter genes, we evaluated gene regulation capacity and gross production of the system with different configurations. The highest yield was obtained when the expression module was in a multicopy plasmid after a 6-h induction. However, expression modules in plasmids showed low stability after induction even with selective pressure. The chromosomal configuration had the lowest basal levels and induced levels comparable to those of plasmid configurations, resulting in accumulation of more than 10% of the total protein. Unlike the configurations in plasmids, the yield was maintained for at least 3 days even without selective pressure. In conclusion, the cascade system in the chromosome configuration is more efficient for long-term fermentation because of the great stability of the overexpressing phenotype in spite of the high levels of expression.

Deciphering the action of aromatic effectors on the prokaryotic enhancer-binding protein XylR: a structural model of its N-terminal domain.

The prokaryotic enhancer-binding protein XylR is the central regulator of the toluene degradation pathway in Pseudomonas species. Copious genetic and biochemical data indicate that the N-terminal domain of the protein (domain A) interacts directly with m-xylene, which renders the protein competent as a transcriptional activator. Single-site and shuffling mutants of XylR or homologues have been reported to change or expand their effector profiles. Here, we follow a fold recognition approach to generate three-dimensional models of the domain A of XylR and DmpR with the purpose of deciphering the molecular activity of this protein family. The model is based on the crystallographic data of the rat catechol O-methyltransferase, a typical alpha/beta fold, consisting of eight alpha-helices and seven beta-strands. The fold identification is supported by physico-chemical properties of conserved amino acids, distribution of residues characteristic of the sequence families and confrontation with experimental data. The model not only provides a rationale for understanding published experimental data, but also suggests the molecular mechanism of the activation step and is a potentially useful conceptual tool for designing regulators with predefined inducer specificities.

A la carte transcriptional regulators: unlocking responses of the prokaryotic enhancer-binding protein XylR to non-natural effectors.

To investigate the activation mechanism of the enhancer-binding protein XylR encoded by the TOL plasmid of Pseudomonas putida mt-2, a combinatorial library was generated composed of shuffled N-terminal A domains of the homologous regulators DmpR, XylR and TbuT, reassembled within the XylR structure. When the library was screened in vivo for responsiveness to non-effectors bulkier than one aromatic ring (such as biphenyl) or bearing an entirely different distribution of electronegative groups (e.g. nitrotoluenes), protein variants were found that displayed an expanded inducer range including the new effectors. Although the phenotypes endowed with the corresponding changes were largely similar, the modifications involved different sites within the A domain. The positions of the mutations within a structural model of the A domain suggest that expansion of the inducer profile can be brought about not only by changes in the effector pocket of the protein but also by unlocking steps of the signal transmission mechanism that follows effector binding. These results provide a rationale for evolving in vitro regulators à la carte that are responsive to predetermined, natural or xenobiotic chemical species.

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.

Role of ptsO in carbon-mediated inhibition of the Pu promoter belonging to the pWW0 Pseudomonas putida plasmid.

An investigation was made into the role of the ptsO gene in carbon source inhibition of the Pu promoter belonging to the Pseudomonas putida upper TOL (toluene degradation) operon. ptsO is coexpressed with ptsN, the loss of which is known to render Pu unresponsive to glucose. Both ptsN and ptsO, coding for the phosphoenolpyruvate:sugar phosphotransferase system (PTS) family proteins IIA(Ntr) and NPr, respectively, have been mapped adjacent to the rpoN gene of P. putida. The roles of these two genes in the responses of Pu to glucose were monitored by lacZ reporter technology with a P. putida strain engineered with all regulatory elements in monocopy gene dosage. In cells lacking ptsO, Pu activity seemed to be inhibited even in the absence of glucose. A functional relationship with ptsN was revealed by the phenotype of a double ptsN ptsO mutant that was equivalent to the phenotype of a mutant with a single ptsN disruption. Moreover, phosphorylation of the product of ptsO seemed to be required for C inhibition of Pu, since an H15A change in the NPr sequence that prevents phosphorylation of this conserved amino acid residue did not restore the wild-type phenotype. A genomic search for proteins able to phosphorylate ptsO revealed the presence of two open reading frames, designated ptsP and mtp, with the potential to encode PTS type I enzymes in P. putida. However, neither an insertion in ptsP nor an insertion in mtp resulted in a detectable change in inhibition of Pu by glucose. These results indicate that some PTS proteins have regulatory functions in P. putida that are independent of their recognized role in sugar transport in other bacteria.

New insights into the activation of o-xylene biodegradation in Pseudomonas stutzeri OX1 by pathway substrates.

The regulation of the tou operon of Pseudomonas stutzeri OX1, for degradation of toluene and o-xylene via phenolic intermediates, has been faithfully reconstructed in vitro with purified proteins. The set-up included the prokaryotic enhancer-binding protein TouR, the sigma54-dependent PToMO promoter and the sigma54-containing RNA polymerase. With this system we prove that direct binding of 2-methylphenol (o-cresol) to TouR is the only regulatory step for activation of PToMO in response to aromatic effectors, thereby ruling out the involvement of other factors or a need for protein processing. In addition, we found that while TouR failed entirely to activate PToMO in the absence of inducers, the protein had per se a very significant ATPase activity, which was only moderately increased by o-cresol addition. The results presented here support the view that TouR-like proteins are particularly suitable as evolutionary assets to endow recently evolved pathways for the degradation of environmental pollutants with an optimal degree of transcriptional regulation.

Formation of disulphide bonds during secretion of proteins through the periplasmic-independent type I pathway.

In this work, we have investigated whether the bacterial type I secretion pathway, which does not have a periplasmic intermediate of the secreted protein, allows the formation of disulphide bridges. To this end, the formation of disulphide bonds has been studied in an antibody single-chain Fv (scFv) fragment secreted by the Escherichia coli haemolysin (Hly) transporter (a paradigm of type I secretion). The scFv antibody fragment was used as a disulphide bond and protein-folding reporter, as it contains two disulphide bridges that are required for its correct folding (i.e. to preserve its antigen-binding activity). We show that an scFv-HlyA hybrid secreted by Hly type I transporter (TolC, HlyB, HlyD) is accumulated in the extracellular medium with the disulphide bonds correctly formed. Neither periplasmic and inner membrane-bound Dsb enzymes (e.g. DsbC, DsbG, DsbB and DsbD) nor cytoplasmic thioredoxins (TrxA and TrxC) were required for scFv-HlyA oxidation. However, a mutation of the thioredoxin reductase gene (trxB), which leads to the cytoplasmic accumulation of the oxidized forms of thioredoxins, had a specific inhibitory effect on the Hly-dependent secretion of disulphide-containing proteins. These data suggest that premature cytoplasmic oxidation of the substrate may interfere with the secretion process. Taken together, these results indicate not only that the type I system tolerates secretion of disulphide-containing proteins, but also that disulphide bonds are specifically formed during the passage of the polypeptide through the export conduit.

The limits to genomic predictions: role of sigma(N) in environmental stress survival of Pseudomonas putida.

Based on genomic data and on the phenotypes of an FlhF mutant of Pseudomonas putida, the alternative sigma factor sigma(N) (sigma(54)) has been proposed to play a key role in survival to various nutritional and environmental stresses in this bacterium. Quite in contrast, we show that unlike sigma(S) (sigma(38)) the loss of sigma(N) does not impair to any significant extent the ability of P. putida to survive long-term starvation. rpoN mutants (lacking sigma(N)) are indistinguishable from the wild-type with respect to solvent tolerance, resistance to heat shock or sensitivity to hydrogen peroxide. These data suggest that while sigma(N) is a key component of expression of alternative biodegradative pathways for unusual carbon sources (i.e. m-xylene or dimethylphenols), its loss does not compromise bacterial endurance to gross types of environmental stress. Moreover, these results point out the limitations, if not the deception, of genomic predictions when confronted with experimental data.

The essential HupB and HupN proteins of Pseudomonas putida provide redundant and nonspecific DNA-bending functions.

A protein mixture containing two major components able to catalyze a beta-recombination reaction requiring nonspecific DNA bending was obtained by fractionation of a Pseudomonas putida extract. N-terminal sequence analysis and genomic data base searches identified the major component as an analogue of HupB of Pseudomonas aeruginosa and Escherichia coli, encoding one HU protein variant. The minor component of the fraction, termed HupN, was divergent enough from HupB to predict a separate DNA-bending competence. The determinants of the two proteins were cloned and hyperexpressed, and the gene products were purified. Their activities were examined in vitro in beta-recombination assays and in vivo by complementation of the Hbsu function of Bacillus subtilis. HupB and HupN were equally efficient in all tests, suggesting that they are independent and functionally redundant DNA bending proteins. This was reflected in the maintenance of in vivo activity of the final sigma54 Ps promoter of the toluene degradation plasmid, TOL, which requires facilitated DNA bending, in DeltahupB or DeltahupN strains. However, hupB/hupN double mutants were not viable. It is suggested that the requirement for protein-facilitated DNA bending is met in P. putida by two independent proteins that ensure an adequate supply of an essential cellular activity.

Evidence of multiple regulatory functions for the PtsN (IIA(Ntr)) protein of Pseudomonas putida.

The ptsN gene of Pseudomonas putida encodes IIA(Ntr), a protein of the phosphoenol pyruvate:sugar phosphotransferase (PTS) system which is required for the C source inhibition of the sigma(54)-dependent promoter Pu of the TOL (toluate degradation) plasmid pWW0. Using two-dimensional gel electrophoresis, we have examined the effect of ptsN disruption on the general expression pattern of P. putida. To this end, cells were grown in the presence or absence of glucose, and a 1,117-spot subset of the P. putida proteome was used as a reference for comparisons. Among all gene products whose expression was lowered by this carbon source (247 spots [about 22%]), only 6 behaved as Pu (i.e., were depressed in the ptsN background). This evidenced only a minor role for IIA(Ntr) in the extensive inhibition of gene expression in P. putida caused by glucose. However, the same experiments revealed a large incidence of glucose-independent effects brought about by the ptsN mutation. As many as 108 spots (ca. 9% of the cell products analyzed) were influenced, positively or negatively, by the loss of IIA(Ntr). By matching this pattern with that of an rpoN::OmegaKm strain of P. putida, which lacks the sigma(54) protein, we judge that most proteins whose expression was affected by ptsN were unrelated to the alternative sigma factor. These data suggest a role of IIA(Ntr) as a general regulator, independent of the presence of repressive carbon sources and not limited to sigma(54)-dependent genes.

Metabolic engineering of bacteria for environmental applications: construction of Pseudomonas strains for biodegradation of 2-chlorotoluene.

In this article, we illustrate the challenges and bottlenecks in the metabolic engineering of bacteria destined for environmental bioremediation, by reporting current efforts to construct Pseudomonas strains genetically designed for degradation of the recalcitrant compound 2-chlorotoluene. The assembled pathway includes one catabolic segment encoding the toluene dioxygenase of the TOD system of Pseudomonas putida F1 (todC1C2BA), which affords the bioconversion of 2-chlorotoluene into 2-chlorobenzaldehyde by virtue of its residual methyl-monooxygenase activity on o-substituted substrates. A second catabolic segment encoded the entire upper TOL pathway from pWW0 plasmid of P. putida mt-2. The enzymes, benzyl alcohol dehydrogenase (encoded by xylB) and benzaldehyde dehydrogenase (xylC) of this segment accept o-chloro-substituted substrates all the way down to 2-chlorobenzoate. These TOL and TOD segments were assembled in separate mini-Tn5 transposon vectors, such that expression of the encoded genes was dependent on the toluene-responsive Pu promoter of the TOL plasmid and the cognate XylR regulator. Such gene cassettes (mini-Tn5 [UPP2] and mini-Tn5 [TOD2]) were inserted in the chromosome of the 2-chlorobenzoate degraders Pseudomonas aeruginosa PA142 and P. aeruginosa JB2. GC-MS analysis of the metabolic intermediates present in the culture media of the resulting strains verified that these possessed, not only the genetic information, but also the functional ability to mineralise 2-chlorotoluene. However, although these strains did convert the substrate into 2-chlorobenzoate, they failed to grow on 2-chlorotoluene as the only carbon source. These results pinpoint the rate of the metabolic fluxes, the non-productive spill of side-metabolites and the physiological control of degradative pathways as the real bottlenecks for degradation of certain pollutants, rather than the theoretical enzymatic and genetic fitness of the recombinant bacteria to the process. Choices to address this general problem are discussed.

The role of the interdomain B linker in the activation of the XylR protein of Pseudomonas putida.

In the presence of toluene and other structural analogues, the enhancer binding protein XylR activates the sigma54 promoter Pu of the TOL (toluene degradation) plasmid pWW0 of Pseudomonas putida. Introduction of amino acid changes Val-219Asp and Ala-220Pro, which enter a proline kink at the interdomain region (B linker) between the A (signal reception) module and the central portion of XylR, originated a protein with unforeseen properties. These included a minor ability to activate Pu in the absence of aromatic effectors, a much higher responsiveness to m-xylene and a significant response to a large collection of aromatic inducers. Such changes could not be attributed to variations in XylR expression levels or to the fortuitous creation of a novel promoter, but to a genuine change in the properties of the activator. Structural predictions suggested that the mutation entirely disrupted an otherwise probable coiled-coil structure. A second directed mutant within the same region consisting of a major replacement of amino acids A220-N221 by the peptide HHHR produced an even more exacerbated phenotype. These data support a model in which the linker B region influences the effector profile by modifying at a distance the operative shape of the effector pocket and fixing the protein in an intermediate step of the activation process.

Specific secretion of active single-chain Fv antibodies into the supernatants of Escherichia coli cultures by use of the hemolysin system.

A simple method for the nontoxic, specific, and efficient secretion of active single-chain Fv antibodies (scFvs) into the supernatants of Escherichia coli cultures is reported. The method is based on the well-characterized hemolysin transport system (Hly) of E. coli that specifically secretes the target protein from the bacterial cytoplasm into the extracellular medium without a periplasmic intermediate. The culture media that accumulate these Hly-secreted scFv's can be used in a variety of immunoassays without purification. In addition, these culture supernatants are stable over long periods of time and can be handled basically as immune sera.

In vivo and in vitro effects of (p)ppGpp on the sigma(54) promoter Pu of the TOL plasmid of Pseudomonas putida.

The connection between the physiological control of the sigma(54)-dependent Pu promoter of the TOL plasmid pWW0 of Pseudomonas putida and the stringent response mediated by the alarmone (p)ppGpp has been examined in vivo an in vitro. To this end, the key regulatory elements of the system were faithfully reproduced in an Escherichia coli strain and assayed as lacZ fusions in various genetic backgrounds lacking (p)ppGpp or overexpressing relA. Neither the responsiveness of Pu to 3-methyl benzylalcohol mediated by its cognate activator XylR nor the down-regulation of the promoter by rapid growth were affected in relA/spoT strains to an extent which could account for the known physiological control that governs this promoter. Overexpression of the relA gene [predicted to increase intracellullar (p)ppGpp levels] did, however, cause a significant gain in Pu activity. Since such a gain might be the result of indirect effects, we resorted to an in vitro transcription system to assay directly the effect of ppGpp on the transcriptional machinery. Although we did observe a significant increase in Pu performance through a range of sigma(54)-RNAP concentrations, such an increase never exceeded twofold. The difference between these results and the behavior of the related Po promoter of the phenol degradation plasmid pVI150 could be traced to the different promoter sequences, which may dictate the type of metabolic signals recruited for the physiological control of sigma(54)-systems.