Molecular analysis of the phosphoenolpyruvate-dependent l-sorbose: phosphotransferase system from Klebsiella pneumoniae and of its multidomain structure

We have cloned a 3.4 kb DNA fragment from the chromosome of Klebsiella pneumoniae that codes for a phosphoenolpyruvate-dependent l-sorbose: phosphotransferase system (PTS). The cloned fragment was sequenced and four open reading frames coding for 135 (sorF), 164 (sorB), 266 (sorA) and 274 (sorM) amino acids, respectively, were found. The corresponding proteins could be detected in a T7 overexpression system, which yielded molecular masses of about 14000 for SorF, 19000 for SorB, 25000 for SorA and 27000 for SorM. SorF and SorB have all the characteristics of soluble and intracellular proteins in accordance with their functions as EIIA^Sor and EIIB^Sor domains of the l-sorbose PTS. SorA and SorM, by contrast, are strongly hydrophobic, membrane-bound proteins with two to five putative transmembrane helices that alternate with a series of hydrophilic loops. They correspond to domains EIIC^Sor and EIID^Sor. The four proteins of the l-sorbose PTS resemble closely (27%–60%) the four subunits of a d-fructose PTS (EIIA^Lev, EIIB^Lev, EIIC^Lev, and EIID^Lev) from Bacillus subtilis and the three subunits of the d-mannose PTS (EIIA,B^Man, EIIC^Man, and EIID^Man) from Escherichia coli K-12. The three systems constitute a new PTS family, and sequence comparisons revealed highly conserved structures for the membranebound proteins. A consensus sequence for the membrane proteins was used to postulate a model for their integration into the membrane.     

Activity of the Enterococcus faecalis EIIA PTS component and its strong interaction with EIIB

Eubacteria can import and simultaneously phosphorylate a range of different carbohydrates by means of sugar specific phosphoenolpyruvate (PEP) dependent sugar phosphotransferase systems (PTSs). Here, we report the biochemical characterization of the gluconate specific PTS component EIIA^gnt from Enterococcus faecalis and its unexpectedly strong complex with EIIB^gnt. We analyze the activity of the complex regarding phosphoryl transfer using kinetic measurements and demonstrate by mutagenesis that His-9 of EIIA^gnt is essential for this process and represents most likely the phosphoryl group carrier of EIIA^gnt. With a combination of isothermal titration calorimetry (ITC), analytical ultracentrifugation (AUC), native gel electrophoresis and chemical crosslinking experiments we show that EIIA^gnt and EIIB^gnt form a strong 2:2 heterotetrameric complex, which seems to be destabilized upon phosphorylation of EIIB^gnt.     

TheEscherichia coli mannitol permease as a model for transport via the bacterial phosphotransferase system

The bacterial phosphoenolpyruvate-dependent carbohydrate phosphotransferase system (PTS) consists of several proteins whose primary functions are to transport and phosphorylate their substrates. The complexity of the PTS undoubtedly reflects its additional roles in chemotaxis to PTS substrates and in regulation of other metabolic processes in the cell. The PTS permeases (Enzymes II) are the membrane-associated proteins of the PTS that sequentially recognize, transport, and phosphorylate their specific substrates in separate steps, and theEscherichia coli mannitol permease is one of the best studied of these proteins. It consists of two cytoplasmic domains (EIIA and EIIB) involved in mannitol phosphorylation and an integral membrane domain (EIIC) which is sufficient to bind mannitol, but which transports mannitol at a rate that is dependent on phosphorylation of the EIIA and EIIB domains. Recent results show that several residues in a hydrophilic, 85-residue segment of the EIIC domain are important for the binding, transport, and phosphorylation of mannitol. This segment may be at least partially exposed to the cytoplasm of the cell. A model is proposed in which this region of the EIIC domain is crucial in coupling phosphorylation of the EIIB domain to transport through the EIIC domain of the mannitol permease.     

Molecular analysis of the phosphoenolpyruvate-dependent l-sorbose: phosphotransferase system from Klebsiella pneumoniae and of its multidomain structure

We have cloned a 3.4 kb DNA fragment from the chromosome of Klebsiella pneumoniae that codes for a phosphoenolpyruvate-dependent l-sorbose: phosphotransferase system (PTS). The cloned fragment was sequenced and four open reading frames coding for 135 (sorF), 164 (sorB), 266 (sorA) and 274 (sorM) amino acids, respectively, were found. The corresponding proteins could be detected in a T7 overexpression system, which yielded molecular masses of about 14000 for SorF, 19000 for SorB, 25000 for SorA and 27000 for SorM. SorF and SorB have all the characteristics of soluble and intracellular proteins in accordance with their functions as EIIA^Sor and EIIB^Sor domains of the l-sorbose PTS. SorA and SorM, by contrast, are strongly hydrophobic, membrane-bound proteins with two to five putative transmembrane helices that alternate with a series of hydrophilic loops. They correspond to domains EIIC^Sor and EIID^Sor. The four proteins of the l-sorbose PTS resemble closely (27%–60%) the four subunits of a d-fructose PTS (EIIA^Lev, EIIB^Lev, EIIC^Lev, and EIID^Lev) from Bacillus subtilis and the three subunits of the d-mannose PTS (EIIA,B^Man, EIIC^Man, and EIID^Man) from Escherichia coli K-12. The three systems constitute a new PTS family, and sequence comparisons revealed highly conserved structures for the membranebound proteins. A consensus sequence for the membrane proteins was used to postulate a model for their integration into the membrane.     

The phosphotransferase protein EIIA(Ntr) modulates the phosphate starvation response through interaction with histidine kinase PhoR in Escherichia coli

Many Proteobacteria possess the paralogous PTS^Ntr, in addition to the sugar transport phosphotransferase system (PTS). In the PTS^Ntr phosphoryl‐groups are transferred from phosphoenolpyruvate to protein EIIA^Ntr via the phosphotransferases EI^Ntr and NPr. The PTS^Ntr has been implicated in regulation of diverse physiological processes. In Escherichia coli, the PTS^Ntr plays a role in potassium homeostasis. In particular, EIIA^Ntr binds to and stimulates activity of a two‐component histidine kinase (KdpD) resulting in increased expression of the genes encoding the high‐affinity K⁺ transporter KdpFABC. Here, we show that the phosphate (pho) regulon is likewise modulated by PTS^Ntr. The pho regulon, which comprises more than 30 genes, is activated by the two‐component system PhoR/PhoB under conditions of phosphate starvation. Mutants lacking EIIA^Ntr are unable to fully activate the pho genes and exhibit a growth delay upon adaptation to phosphate limitation. In contrast, pho expression is increased above the wild‐type level in mutants deficient for EIIA^Ntr phosphorylation suggesting that non‐phosphorylated EIIA^Ntr modulates pho. Protein interaction analyses reveal binding of EIIA^Ntr to histidine kinase PhoR. This interaction increases the amount of phosphorylated response regulator PhoB. Thus, EIIA^Ntr is an accessory protein that modulates the activities of two distinct sensor kinases, KdpD and PhoR, in E. coli.     

Structure of the Enterococcus faecalis EIIA PTS component

In Eubacteria, the utilization of a number of extracellular carbohydrates is mediated by sugar specific phosphoenolepyruvate (PEP) dependent sugar phosphotransferase systems (PTSs), which simultaneously import und phosphorylate their target sugars. Here, we report the crystal structure of the EIIA^gnt component of the so far little investigated Enterococcus faecalis gluconate specific PTS. The crystal structure shows a tightly interacting dimer of EIIA^gnt which is structurally similar to the related EIIA^man from Escherichia coli. Homology modeling of E. faecalis HPr, EIIB^man and their complexes with EIIA^man suggests that despite moderate sequence identity between EIIA^man and EIIA^gnt, the active sites closely match the situation observed in the E. coli system with His-9 of EIIA^gnt being the likely phosphoryl group carrier. We therefore propose that the phosphoryl transfer reactions involving EIIA^gnt proceed according to a mechanism analog to the one described for E. coli EIIA^man.     

Relationship between pseudo-HPr and the PEP: fructose phosphotransferase system in Salmonella typhimurium and Escherichia coli

Summary We have studied in Salmonella typhimurium and Escherichia coli the properties of pseudo-HPr suppressor mutations. These mutations suppressed the defects in a ptsH mutant which lacks HPr, one of the enzymes of the phosphoenolpyruvate: carbohydrate phosphotransferase system. The suppressor mutation was mapped in S. typhimurium at 3 min, closely linked to leu. The corresponding chromosomal fragment of 1.7 kb from S. typhimurium and E. coli (extending clockwise from ilvH) was cloned. In a maxicell system a protein with an approximate molecular weight of 36,000 was synthesized. Pseudo-HPr suppressor mutations (fruR) and a deletion extending clockwise from leu resulted in the constitutive expression of the fru operon containing the genes for II^Fru (fruA), III^Fru (fruB), fructose 1-phosphate kinase (fruK) and pseudo-HPr (fruF). fruR probably codes for a repressor of the fru operon. Tn10 mutagenesis revealed the following order of genes in the fru operon: fruB-(fruK, fruF)-fruA. Pseudo-HPr activity could replace HPr in PEP-dependent phosphorylation of PTS carbohydrates. III^Fru could be phosphorylated both via HPr and pseudo-HPr, since mutants lacking pseudo-HPr activity were still able to phosphorylate fructose in the presence of added HPr. Both the pseudo-HPr suppressor mutations at 3 min and the deletion extending from leu had an additional phenotype. Introduction of these mutations or deletions was always accompanied by disappearance of PEP synthase activity. Complementation of such a mutant with the cloned fragments reversed both phenotypes at the same time. Possibly, the fruR gene product acts as an activator of the gene coding for PEP synthase.     

Screening of l‐histidine‐based ligands to modify monolithic supports and selectively purify the supercoiled plasmid DNA isoform

The growing demand of pharmaceutical‐grade plasmid DNA (pDNA) suitable for biotherapeutic applications fostered the development of new purification strategies. The surface plasmon resonance technique was employed for a fast binding screening of l ‐histidine and its derivatives, 1‐benzyl‐l ‐histidine and 1‐methyl‐l ‐histidine, as potential ligands for the biorecognition of three plasmids with different sizes (6.05, 8.70, and 14 kbp). The binding analysis was performed with different isoforms of each plasmid (supercoiled, open circular, and linear) separately. The results revealed that the overall affinity of plasmids to l ‐histidine and its derivatives was high (K_D > 10⁻⁸ M), and the highest affinity was found for human papillomavirus 16 E6/E7 (K_D = 1.1 × 10⁻¹⁰ M and K_D = 3.34 × 10⁻¹⁰ M for open circular and linear plasmid isoforms, respectively). l ‐Histidine and 1‐benzyl‐l ‐histidine were immobilized on monolithic matrices. Chromatographic studies of l ‐histidine and 1‐benzyl‐l ‐histidine monoliths were also performed with the aforementioned samples. In general, the supercoiled isoform had strong interactions with both supports. The separation of plasmid isoforms was achieved by decreasing the ammonium sulfate concentration in the eluent, in both supports, but a lower salt concentration was required in the 1‐benzyl‐l ‐histidine monolith because of stronger interactions promoted with pDNA. The efficiency of plasmid isoforms separation remained unchanged with flow rate variations. The binding capacity for pDNA achieved with the l ‐histidine monolith was 29‐fold higher than that obtained with conventional l ‐histidine agarose. Overall, the combination of either l ‐histidine or its derivatives with monolithic supports can be a promising strategy to purify the supercoiled isoform from different plasmids with suitable purity degree for pharmaceutical applications. Copyright © 2015 John Wiley & Sons, Ltd.     

From fruitless to sex: On the generation and diversification of an innate behavior

Male sexual behavior in Drosophila melanogaster, largely controlled by the fruitless (fru) gene encoding the male specific Fru^M protein, is among the best studied animal behaviors. Although substantial studies suggest that Fru^M specifies a neuronal circuitry governing all aspects of male sexual behaviors, recent findings show that Fru^M is not absolutely necessary for such behaviors. We propose that another regulatory gene doublesex encoding the male-specific Dsx^M protein builds a core neuronal circuitry that possesses the potential for courtship, which could be either induced through adult social experience or innately manifested during development by Fru^M expression in a broader neuronal circuitry. Fru^M expression levels and patterns determine the modes of courtship behavior from innate heterosexual, homosexual, bisexual, to learned courtship. We discuss how Fru^M expression is regulated by hormones and social experiences and tunes functional flexibility of the sex circuitry. We propose that regulatory genes hierarchically build the potential for innate and learned aspects of courtship behaviors, and expression changes of these regulatory genes among different individuals and species with different social experiences ultimately lead to behavioral diversification.