A Correlation Between the Eight Grade Students\u27 Participation in English Extracurricular Activities and Their Speaking Ability at SMPN 6 Pekanbaru

This research is aimed at investigating whether there is a correlation between between students\u27 participation in English Extracurricular at school and their speaking ability at SMPN 6 Pekanbaru. This research used simple random sampling. The researcher found that extracurricular activity can improve students\u27 speaking ability at school. The result showed that coefficient correlation between two variable is 0,84, which means there is positive correlation between two variables. The researcher suggests the English teachers to pay more attention on the other factor that influencing speaking ability, such as: extracurricular activit

Functional characterization of SbmA, a bacterial inner membrane transporter required for importing the antimicrobial peptide Bac7(1-35)

SbmA is an inner membrane protein of Gram-negative bacteria that is involved in the internalization of glycopeptides and prokaryotic and eukaryotic antimicrobial peptides, as well as of peptide nucleic acid (PNA) oligomers. The SbmA homolog BacA is required for the development of Sinorhizobium meliloti bacteroids within plant cells and favors chronic infections with Brucella abortus and Mycobacterium tuberculosis in mice. Here, we investigated functional features of SbmA/BacA using the proline-rich antimicrobial peptide Bac7(1-35) as a substrate. Circular dichroism and affinity chromatography studies were used to investigate the ability of SbmA to bind the peptide, and a whole-cell transport assay with fluorescently labeled peptide allowed the determination of transport kinetic parameters with a calculated Km value of 6.95±0.89 μM peptide and a Vmax of 53.91±3.17 nmol/min/mg SbmA. Use of a bacterial two-hybrid system coupled to SEC-MALLS (size exclusion chromatography coupled with multiangle laser light scattering) analyses established that SbmA is a homodimer in the membrane, and treatment of the cells with arsenate or ionophores indicated that the peptide transport mediated by SbmA is driven by the electrochemical gradient. Overall, these results shed light on the SbmA-mediated internalization of peptide substrates and suggest that the transport of an unknown substrate(s) represents the function of this protein

The dimeric form of the unphosphorylated response regulator BaeR

Bacterial response regulators (RRs) can regulate the expression of genes that confer antibiotic resistance; they contain a receiver and an effector domain and their ability to bind DNA is based on the dimerization state. This is triggered by phosphorylation of the receiver domain by a kinase. However, even in the absence of phosphorylation RRs can exist in equilibrium between monomers and dimers with phosphorylation shifting the equilibrium toward the dimer form. We have determined the crystal structure of the unphosphorylated dimeric BaeR from Escherichia coli. The dimer interface is formed by a domain swap at the receiver domain. In comparison with the unphosphorylated dimeric PhoP from Mycobacterium tuberculosis, BaeR displays an asymmetry of the effector domains

Conformational Changes of the Antibacterial Peptide ATP Binding Cassette Transporter McjD Revealed by Molecular Dynamics Simulations

The ATP binding cassette (ABC) transporters form one of the largest protein superfamilies. They use the energy of ATP hydrolysis to transport chemically diverse ligands across membranes. An alternating access mechanism in which the transporter switches between inward- and outward-facing conformations has been proposed to describe the translocation process. One of the main open questions in this process is the degree of opening of the transporter at different stages of the transport cycle, as crystal structures and biochemical data have suggested a wide range of distances between nucleotide binding domains. Recently, the crystal structure of McjD, an antibacterial peptide ABC transporter from Escherichia coli, revealed a new occluded intermediate state of the transport cycle. The transmembrane domain is closed on both sides of the membrane, forming a cavity that can accommodate its ligand, MccJ25, a lasso peptide of 21 amino acids. In this work, we investigate the degree of opening of the transmembrane cavity required for ligand translocation. By means of steered molecular dynamics simulations, the ligand was pulled from the internal cavity to the extracellular side. This resulted in an outward-facing state. Comparison with existing outward-facing crystal structures shows a smaller degree of opening in the simulations, suggesting that the large conformational changes in some crystal structures may not be necessary even for a large substrate like MccJ25

Structure of an antibacterial peptide ATP-binding cassette transporter in a novel outward occluded state

Enterobacteriaceae produce antimicrobial peptides for survival under nutrient starvation. Microcin J25 (MccJ25) is an antimicrobial peptide with a unique lasso topology. It is secreted by the ATPbinding cassette (ABC) exporter McjD, which ensures self-immunity of the producing strain through efficient export of the toxic mature peptide from the cell. Here we have determined the crystal structure of McjD from Escherichia coli at 2.7-angstrom resolution, which is to the authors' knowledge the first structure of an antibacterial peptide ABC transporter. Our functional and biochemical analyses demonstrate McjD-dependent immunity to MccJ25 through efflux of the peptide. McjD can directly bind MccJ25 and displays a basal ATPase activity that is stimulated by MccJ25 in both detergent solution and proteoliposomes. McjD adopts a new conformation, termed nucleotide-bound outward occluded. The new conformation defines a clear cavity; mutagenesis and ligand binding studies of the cavity have identified Phe86, Asn134, and Asn302 as important for recognition of MccJ25. Comparisons with the inward-open MsbA and outward-open Sav1866 structures show that McjD has structural similarities with both states without the intertwining of transmembrane (TM) helices. The occluded state is formed by rotation of TMs 1 and 2 toward the equivalent TMs of the opposite monomer, unlike Sav1866 where they intertwine with TMs 3-6 of the opposite monomer. Cysteine cross-linking studies on the McjD dimer in inside-out membrane vesicles of E. coli confirmed the presence of the occluded state. We therefore propose that the outwardoccluded state represents a transition intermediate between the outward-open and inward-open conformation of ABC exporters

Conformational Changes of the Antibacterial Peptide ATP Binding Cassette Transporter McjD Revealed by Molecular Dynamics Simulations

The ATP binding cassette (ABC) transporters form one of the largest protein superfamilies. They use the energy of ATP hydrolysis to transport chemically diverse ligands across membranes. An alternating access mechanism in which the transporter switches between inward- and outward-facing conformations has been proposed to describe the translocation process. One of the main open questions in this process is the degree of opening of the transporter at different stages of the transport cycle, as crystal structures and biochemical data have suggested a wide range of distances between nucleotide binding domains. Recently, the crystal structure of McjD, an antibacterial peptide ABC transporter from <i>Escherichia coli</i>, revealed a new occluded intermediate state of the transport cycle. The transmembrane domain is closed on both sides of the membrane, forming a cavity that can accommodate its ligand, MccJ25, a lasso peptide of 21 amino acids. In this work, we investigate the degree of opening of the transmembrane cavity required for ligand translocation. By means of steered molecular dynamics simulations, the ligand was pulled from the internal cavity to the extracellular side. This resulted in an outward-facing state. Comparison with existing outward-facing crystal structures shows a smaller degree of opening in the simulations, suggesting that the large conformational changes in some crystal structures may not be necessary even for a large substrate like MccJ25

Structure and mechanism of the chalcogen-detoxifying protein TehB fromEscherichia coli

The oxyanion derivatives of the chalcogens tellurium and selenium are toxic to living organisms even at very low levels. Bacteria have developed mechanisms to overcome their toxicity by methylating them. The structure of TehB from Escherichia coli has been determined in the presence of the cofactor analogues SAH (S-adenosylhomocysteine) and sinefungin (a non-hydrolysable form of S-adenosyl-L-methionine) at 1.48 Å (1 Å=0.1 nm) and 1.9 Å respectively. Interestingly, our kinetic data show that TehB does not discriminate between selenium or tellurite oxyanions, making it a very powerful detoxifying protein. Analysis of the active site has identified three conserved residues that are capable of binding and orientating the metals for nucleophilic attack: His176, Arg177 and Arg184. Mutagenesis studies revealed that the H176A and R184A mutants retained most of their activity, whereas the R177A mutant had 65% of its activity abolished. Based on the structure and kinetic data we propose an SN2 nucleophilic attack reaction mechanism. These data provide the first molecular understanding of the detoxification of chalcogens by bacteria

Structural basis for natural product selection and export by bacterial ABC transporters

Bacteria under stress produce ribosomally synthesized and post-translationally modified peptides (RiPPs) to target closely related species, such as the lasso peptide microcin J25 (MccJ25). These peptides are also toxic to the producing organisms that utilize dedicated ABC transporters to achieve self-immunity. MccJ25 is exported by the Escherichia coli ABC transporter McjD through a complex mechanism of recognition that has remained elusive. Here, we used biomolecular NMR to study this interaction and identified a region of the toxic peptide that is crucial to its recognition by the ABC transporter. Our study provides evidence that McjD is highly specific to MccJ25 and not to other RiPPs or antibiotics, unlike multidrug ABC transporters. Additionally, we show that MccJ25 is not exported by another natural product ABC transporter. Therefore, we propose that specific interactions between natural product ABC transporters and their substrate provides them with their high degree of specificity. Taken together, these findings suggest that ABC transporters might have acquired structural elements in their binding cavity to recognize and allow promiscuous export of a larger variety of compounds

Structural basis for antibacterial peptide self-immunity by the bacterial ABC transporter McjD

Certain pathogenic bacteria produce and release toxic peptides to ensure either nutrient availability or evasion from the immune system. These peptides are also toxic to the producing bacteria that utilize dedicated ABC transporters to provide self‐immunity. The ABC transporter McjD exports the antibacterial peptide MccJ25 in Escherichia coli. Our previously determined McjD structure provided some mechanistic insights into antibacterial peptide efflux. In this study, we have determined its structure in a novel conformation, apo inward‐occluded and a new nucleotide‐bound state, high‐energy outward‐occluded intermediate state, with a defined ligand binding cavity. Predictive cysteine cross‐linking in E. coli membranes and PELDOR measurements along the transport cycle indicate that McjD does not undergo major conformational changes as previously proposed for multi‐drug ABC exporters. Combined with transport assays and molecular dynamics simulations, we propose a novel mechanism for toxic peptide ABC exporters that only requires the transient opening of the cavity for release of the peptide. We propose that shielding of the cavity ensures that the transporter is available to export the newly synthesized peptides, preventing toxic‐level build‐up