Group A Streptococcus Secreted Esterase Hydrolyzes Platelet-Activating Factor to Impede Neutrophil Recruitment and Facilitate Innate Immune Evasion

The innate immune system is the first line of host defense against invading organisms. Thus, pathogens have developed virulence mechanisms to evade the innate immune system. Here, we report a novel means for inhibition of neutrophil recruitment by Group A Streptococcus (GAS). Deletion of the secreted esterase gene (designated sse) in M1T1 GAS strains with (MGAS5005) and without (MGAS2221) a null covS mutation enhances neutrophil ingress to infection sites in the skin of mice. In trans expression of SsE in MGAS2221 reduces neutrophil recruitment and enhances skin invasion. The sse deletion mutant of MGAS5005 (Δsse ^MGAS5005) is more efficiently cleared from skin than the parent strain. SsE hydrolyzes the sn-2 ester bond of platelet-activating factor (PAF), converting biologically active PAF into inactive lyso-PAF. K_M and k _cat of SsE for hydrolysis of 2-thio-PAF were similar to those of the human plasma PAF acetylhydrolase. Treatment of PAF with SsE abolishes the capacity of PAF to induce activation and chemotaxis of human neutrophils. More importantly, PAF receptor-deficient mice significantly reduce neutrophil infiltration to the site of Δsse ^MGAS5005 infection. These findings identify the first secreted PAF acetylhydrolase of bacterial pathogens and support a novel GAS evasion mechanism that reduces phagocyte recruitment to sites of infection by inactivating PAF, providing a new paradigm for bacterial evasion of neutrophil responses.     

Transcutaneous electrical stimulation of the spinal cord: non-invasive tool for activation of locomotor circuitry in human

A new tool for locomotor circuitry activation in the non-injured human by transcutaneous electrical spinal cord stimulation (tSCS) has been described. We show that continuous tSCS over T11-T12 vertebrae at 5-40 Hz induced involuntary locomotor-like stepping movements in subjects with their legs in a gravity-independent position. The increase of frequency of tSCS from 5 to 30 Hz augmented the amplitude of evoked stepping movements. The duration of cycle period did not depend on frequency of tSCS. During tSCS the hip, knee and ankle joints were involved in the stepping performance. It has been suggested that tSCS activates the locomotor circuitry through the dorsal roots. It appears that tSCS can be used as a non-invasive method in rehabilitation of spinal pathology.     

High-throughput screening for cellobiose dehydrogenases by Prussian Blue in situ formation

Extracellular fungal flavocytochrome cellobiose dehydrogenase (CDH) is a promising enzyme for both bioelectronics and lignocellulose bioconversion. A selective high-throughput screening assay for CDH in the presence of various fungal oxidoreductases was developed. It is based on Prussian Blue (PB) in situ formation in the presence of cellobiose (<0.25 mM), ferric acetate, and ferricyanide. CDH induces PB formation via both reduction of ferricyanide to ferrocyanide reacting with an excess of Fe3? (pathway 1) and reduction of ferric ions to Fe2? reacting with the excess of ferricyanide (pathway 2). Basidiomycetous and ascomycetous CDH formed PB optimally at pH 3.5 and 4.5, respectively. In contrast to the holoenzyme CDH, its FAD-containing dehydrogenase domain lacking the cytochrome domain formed PB only via pathway 1 and was less active than the parent enzyme. The assay can be applied on active growing cultures on agar plates or on fungal culture supernatants in 96-well plates under aerobic conditions. Neither other carbohydrate oxidoreductases (pyranose dehydrogenase, FAD-dependent glucose dehydrogenase, glucose oxidase) nor laccase interfered with CDH activity in this assay. Applicability of the developed assay for the selection of new ascomycetous CDH producers as well as possibility of the controlled synthesis of new PB nanocomposites by CDH are discussed.     

Mechanism for the transport of ammonia within carbamoyl phosphate synthetase determined by molecular dynamics simulations

Carbamoyl phosphate synthetase (CPS) is a member of the amidotransferase family of enzymes that uses the hydrolysis of glutamine as a localized source of ammonia for biosynthetic transformations. Molecular dynamics simulations for the transfer of ammonia and ammonium through a tunnel in the small subunit of CPS resulted in five successful trajectories for ammonia transfer, while ammonium was immobilized in a water pocket inside the small subunit of the heterodimeric protein. The observed molecular tunnel for ammonia transport is consistent with that suggested by earlier X-ray crystallography and site-directed mutation studies. His-353, Ser-47, and Lys-202, around the active site center in the small subunit, function cooperatively to deliver ammonia from the site of formation to the interface with the large subunit, via the exchange of hydrogen bonds with a critical water cluster within the tunnel. The NH 3 forms and breaks hydrogen bonds to Gly-292, Ser-35, Pro-358, Gly-293, and Thr-37 in a stepwise fashion "macroscopically" as it travels through the hydrophilic passage toward the subunit interface. The potential of mean force calculations along the ammonia transfer pathway indicates a low free-energy path for the translocation of ammonia with two barriers of 3.9 and 5.5 kcal/mol, respectively. These low free-energy barriers are consistent with the delivery of ammonia from the site of formation into a water reservoir toward the exit of the tunnel and migration through the hydrophilic leaving passage, respectively. The high overall free-energy barrier of 22.4 kcal/mol for the transport of ammonium additionally substantiates that the tunnel in the small subunit of CPS is not an ammonium but an ammonia channel.     

Conserved lysine residues of the membrane subunit NuoM are involved in energy conversion by the proton-pumping NADH:ubiquinone oxidoreductase (Complex I)

Analysis of the amino acid sequences of subunits NuoM and NuoN in the membrane domain of Complex I revealed a clear common pattern, including two lysines that are predicted to be located within the membrane, and which are important for quinone reductase activity. Site-directed mutations of the amino acid residues E144, K234, K265 and W243 in this pattern were introduced into the chromosomal gene nuoM of Escherichia coli Complex I. The activity of mutated Complex I was studied in both membranes and in purified Complex I. The quinone reductase activity was practically lost in K234A, K234R and E144A, decreased in W243A and K265A but unchanged in E144D. Complex I from all these mutants contained 1 mol tightly bound ubiquinone per mol FMN like wild type enzyme. The mutant enzymes E144D, W243A and K265A had wild type sensitivity to rolliniastatin and complete proton-pumping efficiency of Complex I. Remarkably, the subunits NuoL and NuoH in the membrane domain also appear to contain conserved lysine residues in transmembrane helices, which may give a clue of the mechanism of proton translocation. A tentative principle of proton translocation by Complex I is suggested based on electrostatic interactions of lysines in the membrane subunits.     

Electrostatic interactions between FeS clusters in NADH:ubiquinone oxidoreductase (Complex I) from Escherichia coli

The redox properties of the cofactors of NADH:ubiquinone oxidoreductase (complex I) from Escherichia coli were studied by following the changes in electron paramagnetic resonance (EPR) and optical spectra upon electrochemical redox titration of the purified protein. At neutral pH, the FMN cofactor had a midpoint redox potential ( E m) approximately -350 mV ( n = 2). Binuclear FeS clusters were well-characterized: N1a was titrated with a single ( n = 1) transition, and E m = -235 mV. In contrast, the titration of N1b can only be fitted with the sum of at least two one-electron Nernstian curves with E m values of -245 and -320 mV. The tetranuclear clusters can also be separated into two groups, either having a single, n = 1, or more complex redox titration curves. The titration curves of the EPR bands attributed to the tetranuclear clusters N2 ( g = 2.045 and g = 1.895) and N6b ( g = 2.089 and g = 1.877) can be presented by the sum of at least two components, each with E m (app) approximately -200/-300 mV and -235/-315 mV, respectively. The titration of the signals at g = 1.956-1.947 (N3 or N7, E m = -315 mV), g = 2.022, and g = 1.932 (Nx, -365 mV) and the low temperature signal at g = 1.929 (N4 or N5, -330 mV) followed Nernstian n = 1 curves. The observed redox titration curves are discussed in terms of intrinsic electrostatic interactions between FeS centers in complex I. A model showing shifts of E m due to the electrostatic interaction between the centers is presented.     

Slow motions in chicken villin headpiece subdomain probed by cross-correlated NMR relaxation of amide NH bonds in successive residues

The villin headpiece subdomain (HP36) is a widely used system for protein-folding studies. Nuclear magnetic resonance cross-correlated relaxation rates arising from correlated fluctuations of two N-H^N dipole-dipole interactions involving successive residues were measured at two temperatures at which HP36 is at least 99% folded. The experiment revealed the presence of motions slower than overall tumbling of the molecule. Based on the theoretical analysis of the spectral densities we show that the structural and dynamic contributions to the experimental cross-correlated relaxation rate can be separated under certain conditions. As a result, dynamic cross-correlated order parameters describing slow microsecond-to-millisecond motions of N-H bonds in neighboring residues can be introduced for any extent of correlations in the fluctuations of the two bond vectors. These dynamic cross-correlated order parameters have been extracted for HP36. The comparison of their values at two different temperatures indicates that when the temperature is raised, slow motions increase in amplitude. The increased amplitude of these fluctuations may reflect the presence of processes directly preceding the unfolding of the protein.     

Conserved lysine residues of the membrane subunit NuoM are involved in energy conversion by the proton-pumping NADH:ubiquinone oxidoreductase (Complex I)

Analysis of the amino acid sequences of subunits NuoM and NuoN in the membrane domain of Complex I revealed a clear common pattern, including two lysines that are predicted to be located within the membrane, and which are important for quinone reductase activity. Site-directed mutations of the amino acid residues E144, K234, K265 and W243 in this pattern were introduced into the chromosomal gene nuoM of Escherichia coli Complex I. The activity of mutated Complex I was studied in both membranes and in purified Complex I. The quinone reductase activity was practically lost in K234A, K234R and E144A, decreased in W243A and K265A but unchanged in E144D. Complex I from all these mutants contained 1 mol tightly bound ubiquinone per mol FMN like wild type enzyme. The mutant enzymes E144D, W243A and K265A had wild type sensitivity to rolliniastatin and complete proton-pumping efficiency of Complex I. Remarkably, the subunits NuoL and NuoH in the membrane domain also appear to contain conserved lysine residues in transmembrane helices, which may give a clue of the mechanism of proton translocation. A tentative principle of proton translocation by Complex I is suggested based on electrostatic interactions of lysines in the membrane subunits.     

In vivo study of fidelity of DNA double-strand break repair in bacteriophage T4

A method for in vivo studying the fidelity of DNA double-strand break (DSB) repair in bacteriophage T4 has been developed. The frequency of reversion of rII mutations to the wild phenotype was measured in i segC+ x i ets 1 segCDelta crosses, where ets 1 is an insertion in the initial part of the rII gene carrying a sequence recognized by SegC endonuclease; i designates a rIIB or rIIA mutation located at some distance from ets 1, and segCDelta is a deletion in the segC gene. In such cross, a DSB occurs in the site of ets 1. Their repair involves genetic recombination and DNA replication in the neighborhood of ets 1. In parallel, the frequency of reversion of the same i mutant in the absence of DSBs is measured in i x i self-crosses. Reversions of different types (base substitutions, deletions, insertions) can be studied with the use of structurally different i mutations located at varying distances from ets 1. The reversion frequencies were determined for three rIIB mutations and one rIIA mutation. The results obtained suggest that DSB repair in bacteriophage T4 is a process of high fidelity with the rate of errors that does not essentially exceed that in the case of usual phage multiplication.