Fructose 1-phosphate is the preferred effector of the metabolic regulator Cra of Pseudomonas putida

The catabolite repressor/activator (Cra) protein is a global sensor and regulator of carbon fluxes through the central metabolic pathways of Gram-negative bacteria. To examine the nature of the effector (or effectors) that signal such fluxes to the protein of Pseudomonas putida, the Cra factor of this soil microorganism has been purified and characterized and its three-dimensional structure determined. Analytical ultracentrifugation, gel filtration, and mobility shift assays showed that the effector-free Cra is a dimer that binds an operator DNA sequence in the promoter region of the fruBKA cluster. Furthermore, fructose 1-phosphate (F1P) was found to most efficiently dissociate the Cra-DNA complex. Thermodynamic parameters of the F1P-Cra-DNA interaction calculated by isothermal titration calorimetry revealed that the factor associates tightly to the DNA sequence 5′-TTAAACGTTTCA-3′ (K_D = 26.3 ± 3.1 nm) and that F1P binds the protein with an apparent stoichiometry of 1.06 ± 0.06 molecules per Cra monomer and a K_D of 209 ± 20 nm. Other possible effectors, like fructose 1,6-bisphosphate, did not display a significant affinity for the regulator under the assay conditions. Moreover, the structure of Cra and its co-crystal with F1P at a 2-Å resolution revealed that F1P fits optimally the geometry of the effector pocket. Our results thus single out F1P as the preferred metabolic effector of the Cra protein of P. putida.     

Characterization of chimeric ADPglucose pyrophosphorylases of Escherichia coli and Agrobacterium tumefaciens. Importance of the C-terminus on the selectivity for allosteric regulators

ADPglucose pyrophosphorylase catalyzes the regulatory step in the pathway for bacterial glycogen synthesis. The enzymes from different organisms exhibit distinctive regulatory properties related to the main carbon metabolic pathway. Escherichia coli ADPglucose pyrophosphorylase is mainly activated by fructose 1,6-bisphosphate (FBP), whereas the Agrobacterium tumefaciens enzyme is activated by fructose 6-phosphate (F6P) and pyruvate. Little is known about the regions determining the specificity for the allosteric regulator. To study the function of different domains, two chimeric enzymes were constructed. "AE" contains the N-terminus (271 amino acids) of the A. tumefaciens ADPglucose pyrophosphorylase and the C-terminus (153 residues) of the E. coli enzyme, and "EA", the inverse construction. Expression of the recombinant wild-type and chimeric enzymes was performed using derivatives of the pET24a plasmid. Characterization of the purified chimeric enzymes showed that the C-terminus of the E. coli enzyme is relevant for the selectivity by FBP. However, this region seems to be less important for the specificity by F6P in the A. tumefaciens enzyme. The chimeric enzyme AE is activated by both FBP and F6P, neither of which affect EA. Pyruvate activates EA with higher apparent affinity than AE, suggesting that the C-terminus of the A. tumefaciens enzyme plays a role in the binding of this effector. The allosteric inhibitor site is apparently disrupted, as a marked desensitization toward AMP was observed in the chimeric enzymes.     

Protocols for RecET-based markerless gene knockout and integration to express heterologous biosynthetic gene clusters in Pseudomonas putida

Pseudomonas putida has emerged as a promising host for the production of chemicals and materials thanks to its metabolic versatility and cellular robustness. In particular, P. putida KT2440 has been officially classified as a generally recognized as safe (GRAS) strain, which makes it suitable for the production of compounds that humans directly consume, including secondary metabolites of high importance. Although various tools and strategies have been developed to facilitate metabolic engineering of P. putida, modification of large genes/clusters essential for heterologous expression of natural products with large biosynthetic gene clusters (BGCs) has not been straightforward. Recently, we reported a RecET-based markerless recombineering system for engineering P. putida and demonstrated deletion of multiple regions as large as 101.7 kb throughout the chromosome by single rounds of recombineering. In addition, development of a donor plasmid system allowed successful markerless integration of heterologous BGCs to P. putida chromosome using the recombineering system with examples of – but not limited to – integrating multiple heterologous BGCs as large as 7.4 kb to the chromosome of P. putida KT2440. In response to the increasing interest in our markerless recombineering system, here we provide detailed protocols for markerless gene knockout and integration for the genome engineering of P. putida and related species of high industrial importance.     

Characterization of starvation‐induced dispersion in Pseudomonas putida biofilms: genetic elements and molecular mechanisms

Pseudomonas putida OUS82 biofilm dispersal was previously shown to be dependent on the gene PP0164 (here designated lapG). Sequence and structural analysis has suggested that the LapG geneproduct belongs to a family of cysteine proteinases that function in the modification of bacterial surface proteins. We provide evidence that LapG is involved in P. putida OUS82 biofilm dispersal through modification of the outer membrane‐associated protein LapA. While the P. putida lapG mutant formed more biofilm than the wild‐type, P. putida lapA and P. putida lapAG mutants displayed decreased surface adhesion and were deficient in subsequent biofilm formation, suggesting that LapG affects LapA, and that the LapA protein functions both as a surface adhesin and as a biofilm matrix component. Lowering of the intracellular c‐di‐GMP level via induction of an EAL domain protein led to dispersal of P. putida wild‐type biofilm but did not disperse P. putida lapG biofilm, indicating that LapG exerts its activity on LapA in response to a decrease in the intracellular c‐di‐GMP level. In addition, evidence is provided that associated to LapA a cellulase‐degradable exopolysaccharide is part of the P. putida biofilm matrix.     

Changes in the activities of aldolase and other enzymes for carbohydrate metabolism during embryonic and postembryonic development of Bombyx mori

Eggs at the early stages of embryogenesis and the larval fat body in Bombyx mori were confirmed to have an aldolase (ALD) isozyme type S. Its activity ratio with substrates fructose 1,6-bisphosphate (FBP) and fructose 1-phosphate (F1P) was 3. This isozyme was considered to be in favor of rather efficient utilization of F1P, since eggs in early stages of embryogenesis and the fat body had high activities of NADP-sorbitol dehydrogenase (NADP-SDH) and NAD-sorbitol dehydrogenase (NAD-SDH) responsible for the polyol pathway generating F1P. On the other hand, eggs at the second half of embryogenesis and the larval and adult muscle (plus epidermal cells and cuticle) possessed an ALD isozyme type F, whose FBP/F1P activity ratio was 10, suggesting that F1P utilization is less effective. This is in agreement with the fact that the NADP-SDH and NAD-SDH activities were low and the phosphofructokinase (PFK) activity was high in eggs at these stages and in muscle. Arch. Insect Biochem. Physiol. 36:139–148, 1997. © 1997 Wiley-Liss, Inc.     

The Wsp intermembrane complex mediates metabolic control of the swim-attach decision of Pseudomonas putida

Pseudomonas putida is a microorganism of biotechnological interest that—similar to many other environmental bacteria—adheres to surfaces and forms biofilms. Although various mechanisms contributing to the swim-attach decision have been studied in this species, the role of a 7-gene operon homologous to the wsp cluster of Pseudomonas aeruginosa—which regulates cyclic di-GMP (cdGMP) levels upon surface contact—remained to be investigated. In this work, the function of the wsp operon of P. putida KT2440 has been characterized through inspection of single and multiple wsp deletion variants, complementation with Pseudomonas aeruginosa's homologues, combined with mutations of regulatory genes fleQ and fleN and removal of the flagellar regulator fglZ. The ability of the resulting strains to form biofilms at 6 and 24 h under three different carbon regimes (citrate, glucose and fructose) revealed that the Wsp complex delivers a similar function to both Pseudomonas species. In P. putida, the key components include WspR, a protein that harbours the domain for producing cdGMP, and WspF, which controls its activity. These results not only contribute to a deeper understanding of the network that regulates the sessile-planktonic decision of P. putida but also suggest strategies to exogenously control such a lifestyle switch.     

Suppression of the ptsH Mutation in Escherichia coli and Salmonella typhimurium by a DNA Fragment from Lactobacillus casei

A DNA fragment from Lactobacillus casei that restores growth to Escherichia coli and Salmonella typhimurium ptsH mutants on glucose and other substrates of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) has been isolated. These mutants lack the HPr protein, a general component of the PTS. Sequencing of the cloned fragment revealed the absence of ptsH homologues. Instead, the complementation ability was located in a 120-bp fragment that contained a sequence homologue to the binding site of the Cra regulator from enteric bacteria. Experiments indicated that the reversion of the ptsH phenotype was due to a titration of the Cra protein, which allowed the constitutive expression of the fructose operon.     

The anoxic electrode-driven fructose catabolism of Pseudomonas putida KT2440

Pseudomonas putida (P. putida) is a microorganism of interest for various industrial processes, yet its strictly aerobic nature limits application. Despite previous attempts to adapt P. putida to anoxic conditions via genetic engineering or the use of a bioelectrochemical system (BES), the problem of energy shortage and internal redox imbalance persists. In this work, we aimed to provide the cytoplasmic metabolism with different monosaccharides, other than glucose, and explored the physiological response in P. putida KT2440 during bioelectrochemical cultivation. The periplasmic oxidation cascade was found to be able to oxidize a wide range of aldoses to their corresponding (keto-)aldonates. Unexpectedly, isomerization of the ketose fructose to mannose also enabled oxidation by glucose dehydrogenase, a new pathway uncovered for fructose metabolism in P. putida KT2440 in BES. Besides the isomerization, the remainder of fructose was imported into the cytoplasm and metabolized. This resulted in a higher NADPH/NADP⁺ ratio, compared to glucose. Comparative proteomics further revealed the upregulation of proteins in the lower central carbon metabolism during the experiment. These findings highlight that the choice of a substrate in BES can target cytosolic and periplasmic oxidation pathways, and that electrode-driven redox balancing can drive these pathways in P. putida under anaerobic conditions.     

Toluene-Degrading Bacteria Are Chemotactic towards the Environmental Pollutants Benzene, Toluene, and Trichloroethylene

The bioremediation of polluted groundwater and toxic waste sites requires that bacteria come into close physical contact with pollutants. This can be accomplished by chemotaxis. Five motile strains of bacteria that use five different pathways to degrade toluene were tested for their ability to detect and swim towards this pollutant. Three of the five strains (Pseudomonas putida F1, Ralstonia pickettii PKO1, and Burkholderia cepacia G4) were attracted to toluene. In each case, the response was dependent on induction by growth with toluene. Pseudomonas mendocina KR1 and P. putida PaW15 did not show a convincing response. The chemotactic responses of P. putida F1 to a variety of toxic aromatic hydrocarbons and chlorinated aliphatic compounds were examined. Compounds that are growth substrates for P. putida F1, including benzene and ethylbenzene, were chemoattractants. P. putida F1 was also attracted to trichloroethylene (TCE), which is not a growth substrate but is dechlorinated and detoxified by P. putida F1. Mutant strains of P. putida F1 that do not oxidize toluene were attracted to toluene, indicating that toluene itself and not a metabolite was the compound detected. The two-component response regulator pair TodS and TodT, which control expression of the toluene degradation genes in P. putida F1, were required for the response. This demonstration that soil bacteria can sense and swim towards the toxic compounds toluene, benzene, TCE, and related chemicals suggests that the introduction of chemotactic bacteria into selected polluted sites may accelerate bioremediation processes.     

An unusual fructose 1,6-bisphosphate-activated lactate dehydrogenase from the ascidian Pyura stolonifera

Lactate dehydrogenase (LDH) was purified from the siphon muscle of the intertidal ascidian Pyura stolonifera. The enzyme is unique among chordate LDHs but resembles some bacterial and platyhelminth LDHs in being activated by fructose 1,6-bisphosphate (FBP). Concentrations of FBP in the range 5μM to 0.5 mM increase V_max of the pyruvate reductase reaction by 130% to 210%, and decrease K_m pyruvate 5 to 11 fold and K_m NADH 2.5 to 5 fold. The enzyme is also activated by inorganic phosphate, but requires a 50 fold higher concentration to attain the maximum activation achieved by 0.5 mM FBP. Of a range of metabolites tested, including other glycolytic sugar phosphates, only FBP and inorganic phosphate activated the enzyme. FBP activation was not observed with 16 representative vertebrate LDH homotetramers, but did occur to a limited extent with LDH from an echinoderm. LDH was the only pyruvate reductase enzyme detected in P. stolonifera siphon muscle, and its activity was much greater than that of phosphorylase or phosphofructokinase. The LDH reaction is utilized by P. Stolonifera during prolonged siphon closure on exposure to air when lactate, but not succinate, accumulates in the siphon muscle. While the ascidian enzyme provides the first example of a FBP activated LDH from a chordate, it remains to be determined if this unusual property has any role in metabolic regulation.     

Comparative assessment of the Euglena gracilis var. saccharophila variant strain as a producer of the β‐1,3‐glucan paramylon under varying light conditions

Euglena gracilis Z and a “sugar loving” variant strain E. gracilis var. saccharophila were investigated as producers of paramylon, a β‐1,3‐glucan polysaccharide with potential medicinal and industrial applications. The strains were grown under diurnal or dark growth conditions on a glucose–yeast extract medium supporting high‐level paramylon production. Both strains produced the highest paramylon yields (7.4–8 g · L^?1, respectively) while grown in the dark, but the maximum yield was achieved faster by E. gracilis var. saccharophila (48 h vs. 72 h). The glucose‐to‐paramylon yield coefficient Y_par/glu = 0.46 ± 0.03 in the E. gracilis var. saccharophila cultivation, obtained in this study, is the highest reported to date. Proteomic analysis of the metabolic pathways provided molecular clues for the strain behavior observed during cultivation. For example, overexpression of enzymes in the gluconeogenesis/glycolysis pathways including fructokinase‐1 and chloroplastic fructose‐1,6‐bisphosphatase (FBP ) may have contributed to the faster rate of paramylon accumulation in E. gracilis var. saccharophila . Differentially expressed proteins in the early steps of chloroplastogenesis pathway including plastid uroporphyrinogen decarboxylases, photoreceptors, and a highly abundant (68‐fold increase) plastid transketolase may have provided the E. gracilis var. saccharophila strain an advantage in paramylon production during diurnal cultivations. In conclusion, the variant strain E. gracilis var. saccharophila seems to be well suited for producing large amounts of paramylon. This work has also resulted in the identification of molecular targets for future improvement of paramylon production in E. gracilis , including the FBP and phosophofructokinase 1, the latter being a key regulator of glycolysis.