SummaryPhosphorous is required for all life and microorganisms can extract it from their environment through several metabolic pathways. When phosphate is in limited supply, some bacteria are able to use organic phosphonate compounds, which require specialised enzymatic machinery for breaking the stable carbon-phosphorus (C-P) bond. Despite its importance, the details of how this machinery catabolises phosphonate remain unknown. Here we determine the crystal structure of the 240 kDa Escherichia coli C-P lyase core complex (PhnGHIJ) and show that it is a two-fold symmetric hetero-octamer comprising an intertwined network of subunits with unexpected selfhomologies. It contains two potential active sites that likely couple organic phosphonate compounds to ATP and subsequently hydrolyse the C-P bond. We map the binding site of PhnK on the complex using electron microscopy and show that it binds to PhnJ via a conserved insertion domain. Our results provide a structural basis for understanding microbial phosphonate breakdown.Phosphonate compounds that contain a stable carbon-phosphorus (C-P) bond are utilised as a source of phosphate by microorganisms in many natural environments where the low levels of free and organic phosphate limit growth 1 . The C-P lyase pathway, which converts phosphonate into 5-phosphoribosyl-α-1-diphosphate (PRPP) in an ATP-dependent fashion, is activated upon phosphate starvation in many bacterial species including Escherichia coli 2,3 . The enzymes of this pathway have a very broad substrate specificity enabling the Reprints and permissions information is available at www.nature.com/reprintsUsers may view, print, copy, and download text and data-mine the content in such documents, for the purposes of academic research, subject always to the full Conditions of use:http:// www.nature.com/authors/editorial_policies/license.html#terms 3 Correspondence and requests for materials should be addressed to D.E.B.(deb@mbg.au.dk, phone +45 21669001). Author Contributions. P.S., L.A.P., B.H.J., B.J., and D.E.B. designed and P.S., L.B.V., C.J.R, and B.J. carried out the experiments. P.S., M.K., and D.E.B. determined the crystal and EM structures while C.J.R. and L.A.P. carried out final refinement of the EM structure as well as EM structure validation. P.S, M.K., C.J.R., L.A.P., B.H.J., B.J., and D.E.B. wrote the manuscript.Atomic coordinates and structure factors have been deposited in the Protein Data Bank (PDB) with accession code 4XB6. The EM density map has been deposited in the Electron Microscopy Data Bank (EMDB) with accession code EMD-3033.
Upon infection of Escherichia coli by bacteriophage Qβ, the virus-encoded β-subunit recruits host translation elongation factors EF-Tu and EF-Ts and ribosomal protein S1 to form the Qβ replicase holoenzyme complex, which is responsible for amplifying the Qβ (+)-RNA genome. Here, we use X-ray crystallography, NMR spectroscopy, as well as sequence conservation, surface electrostatic potential and mutational analyses to decipher the roles of the β-subunit and the first two oligonucleotide-oligosaccharide-binding domains of S1 (OB1–2) in the recognition of Qβ (+)-RNA by the Qβ replicase complex. We show how three basic residues of the β subunit form a patch located adjacent to the OB2 domain, and use NMR spectroscopy to demonstrate for the first time that OB2 is able to interact with RNA. Neutralization of the basic residues by mutagenesis results in a loss of both the phage infectivity in vivo and the ability of Qβ replicase to amplify the genomic RNA in vitro. In contrast, replication of smaller replicable RNAs is not affected. Taken together, our data suggest that the β-subunit and protein S1 cooperatively bind the (+)-stranded Qβ genome during replication initiation and provide a foundation for understanding template discrimination during replication initiation.
Pathogenic bacteria, including Pseudomonas aeruginosa, interact with and engage the host plasminogen (Plg) activation system, which encompasses the urokinase (uPA)-type Plg activator, and is involved in extracellular proteolysis, including matrilysis and fibrinolysis. We hypothesized that secreted bacterial proteases might contribute to the activation of this major extracellular proteolytic system, thereby participating in bacterial dissemination. We report that LasB, a thermolysin-like metalloprotease secreted by Ps. aeruginosa, converts the human uPA zymogen into its active form (kcat=4.9 s-1, Km=8.9 microM). Accordingly, whereas the extracellular secretome from the LasB-expressing pseudomonal strain PAO1 efficiently activates pro-uPA, the secretome from the isogenic LasB-deficient strain PDO240 is markedly less potent in pro-uPA activation. Still, both secretomes induce some metalloprotease-independent activation of the human zymogen. The latter involves a serine protease, which we identified via both recombinant protein expression in Escherichia coli and purification from pseudomonal cultures as protease IV (PIV; kcat=0.73 s-1, Km=6.2 microM). In contrast, neither secretomes nor the pure proteases activate Plg. Along with this, LasB converts Plg into mini-Plg and angiostatin, whereas, as reported previously, it processes the uPA receptor, inactivates the plasminogen activator inhibitor 1, and activates pro-matrix metalloproteinase 2. PIV does not target these factors at all. To conclude, LasB and PIV, although belonging to different protease families and displaying quite different substrate specificities, both activate the urokinase-type precursor of the Plg activation cascade. Direct pro-uPA activation, as also reported for other bacterial proteases, might be a frequent phenomenon that contributes to bacterial virulence.
For the last 40 years, “Sanger sequencing” allowed to unveil crucial secrets of life. However, this method of sequencing has been time-consuming, laborious and remains expensive even today. Human Genome Project was a huge impulse to improve sequencing technologies, and unprecedented financial and human effort prompted the development of cheaper high-throughput technologies and strategies called next-generation sequencing (NGS) or whole genome sequencing (WGS). This review will discuss applications of high-throughput methods to study bacteria in a much broader context than simply their genomes. The major goal of next-generation sequencing for a microbiologist is not really resolving another circular genomic sequence. NGS started its infancy from basic structural and functional genomics, to mature into the molecular taxonomy, phylogenetic and advanced comparative genomics. Today, the use of NGS expended capabilities of diagnostic microbiology and epidemiology. The use of RNA sequencing techniques allows studying in detail the complex regulatory processes in the bacterial cells. Finally, NGS is a key technique to study the organization of the bacterial life—from complex communities to single cells. The major challenge in understanding genomic and transcriptomic data lies today in combining it with other sources of global data such as proteome and metabolome, which hopefully will lead to the reconstruction of regulatory networks within bacterial cells that allow communicating with the environment (signalome and interactome) and virtual cell reconstruction.
The RNase D-type 3'-5' exonuclease Rrp6p from Saccharomyces cerevisiae is a nuclear-specific cofactor of the RNA exosome and associates in vivo with Rrp47p (Lrp1p). Here, we show using biochemistry and small-angle X-ray scattering (SAXS) that Rrp6p and Rrp47p associate into a stable, heterodimeric complex with an elongated shape consistent with binding of Rrp47p to the nuclease domain and opposite of the HRDC domain of Rrp6p. Rrp47p reduces the exonucleolytic activity of Rrp6p on both single-stranded and structured RNA substrates without significantly altering the affinity towards RNA or the ability of Rrp6p to degrade RNA secondary structure.
Positive-stranded RNA viruses are common among human pathogenic viruses, which often cooperate with host proteins to fulfill essential functions during infection. One function is replication of the viral genome. The Qβ phage is a positive-stranded RNA virus that infects E.coli. The Qβ replicase holo enzyme comprises the phage-encoded RNA-dependent RNA polymerase (β-subunit) and the host-encoded translation elongation factors, EF-Ts and EF-Tu as well as the ribosomal protein S1. The Qβ replicase has an extraordinary ability to exponentially amplify RNA in vivo and in vitro. A prerequisite for this is release of product and template RNA as single strands that can serve as new templates in subsequent rounds of replication. The role of S1 in the Qβ replicase is not clear. Recently, S1 was found to promote release of single-stranded product in Qβ replicase-mediated RNA synthesis. We have undertaken NMR spectroscopy and crystallization trials to improve our understanding of distinct S1 domains in solution as well as the ribosomeand replicase-binding properties of S1. Expression of distinct S1 domains for NMR spectroscopy has been optimized by use of autoinduction and results in high yields of [13C15N]-labelled protein fragments. These have proven very suitable for NMR studies and spectra revealed both ordered and disordered regions in the protein. Studies are ongoing. The structure of the Qβ core complex was recently determined at 2.5Å resolution. Thus, co-crystallization of the Qβ core in complex with S1 domains was undertaken and different crystal forms were obtained. These initial crystals diffracted to 3.2Å resolution and data processing as well as further optimization of the crystals is ongoing. S1 is thought to bind the β-subunit close to a region lined with basic amino acids, which potentially could facilitate interactions with the template RNA backbone and split it from the product strand. We demonstrate that neutralization of these basic amino acids indeed decrease or abolish infectivity of the Qβ phage. However, only one mutation, R503A affects the exponential replication in vitro. Crystallization of the Qβ holo enzyme bound to a truncated legitimate RNA template will be the next step for investigation of the mechanism of exponential RNA amplification by Qβ replicase.
Phosphorus is an essential element for all living cells and is usually taken up in the form of phosphate. A number of microorganisms, however, are capable of extracting phosphorous from organic phosphonate compounds, which are characterized by a stable carbon-phosphorus (C-P) bond (1). The metabolic pathway responsible for phosphonate degradation is still poorly understood, but the process is known to involve two reactions before the actual C-P bond cleavage, which has been proposed to take place via a radical mechanism. A key component in the process is C-P lyase, an enzyme encoded by phnJ within the phn operon (2). To get a better insight into the mechanism of this complex degradation pathway, we have determined the crystal structure of the core of a multi-subunit enzymatic complex including the C-P lyase component with a total molecular mass of 220 kDa (3). The structure reveals the overall architecture of the C-P lyase and has important implications for our understanding of enzyme mechanism and catalysis.
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