The type III secretion system (T3SS) is a macromolecular ‘injectisome’, that allows bacterial pathogens to transport virulence proteins into the eukaryotic host cell. This macromolecular complex is constituted by connected ring-like structures that span both bacterial membranes. The crystal structures of the periplasmic domain of the outer membrane (OM) secretin EscC and the inner membrane (IM) protein PrgH reveal the conservation of a modular fold among the three proteins which form the OM and IM rings of the T3SS. This leads to the hypothesis that this conserved fold provides a common ring-building motif that allows for the assembly of the variably sized OM and IM rings characteristic of the T3SS. Utilizing an integrated structural and experimental approach, ring-models for the periplasmic domain of EscC were generated and placed in the context of the assembled T3SS, providing evidence for direct interaction between the OM and IM ring components and an unprecedented span of the OM secretin.
The type III secretion (T3S) injectisome is a specialized protein nanomachine that is critical for the pathogenicity of many Gram-negative bacteria, including purveyors of plague, typhoid fever, whooping cough, sexually transmitted infections and major nosocomial infections. This syringe-shaped 3.5-MDa macromolecular assembly spans both bacterial membranes and that of the infected host cell. The internal channel formed by the injectisome allows for the direct delivery of partially unfolded virulence effectors into the host cytoplasm. The structural foundation of the injectisome is the basal body, a molecular lock-nut structure composed predominantly of three proteins that form highly oligomerized concentric rings spanning the inner and outer membranes. Here we present the structure of the prototypical Salmonella enterica serovar Typhimurium pathogenicity island 1 basal body, determined using single-particle cryo-electron microscopy, with the inner-membrane-ring and outer-membrane-ring oligomers defined at 4.3 Å and 3.6 Å resolution, respectively. This work presents the first, to our knowledge, high-resolution structural characterization of the major components of the basal body in the assembled state, including that of the widespread class of outer-membrane portals known as secretins.
The transcription factor RovA of Yersinia pseudotuberculosis and analogous proteins in other Enterobacteriaceae activate the expression of virulence genes that play a crucial role in stress adaptation and pathogenesis. In this study, we demonstrate that the RovA protein forms dimers independent of DNA binding, stimulates RNA polymerase, most likely via its C-terminal domain, and counteracts transcriptional repression by the histone-like protein H-NS. As the molecular function of the RovA family is largely uncharacterized, random mutagenesis and terminal deletions were used to identify functionally important domains. Our analysis showed that a winged-helix motif in the center of the molecule is essential and directly involved in DNA binding. Terminal deletions and amino acid changes within both termini also abrogate RovA activation and DNA-binding functions, most likely due to their implication in dimer formation. Finally, we show that the last four amino acids of RovA are crucial for activation of gene transcription. Successive deletions of these residues result in a continuous loss of RovA activity. Their removal reduced the capacity of RovA to activate RNA polymerase and abolished transcription of RovA-activated promoters in the presence of H-NS, although dimerization and DNA binding functions were retained. Our structural model implies that the final amino acids of RovA play a role in protein-protein interactions, adjusting RovA activity.
Nascent polypeptide-associated complex (NAC) was identified in eukaryotes as the first cytosolic factor that contacts the nascent polypeptide chain emerging from the ribosome. NAC is highly conserved from yeast to humans. Mutations in NAC cause severe embryonically lethal phenotypes in mice, Drosophila, and Caenorhabditis elegans. NAC was suggested to protect the nascent chain from inappropriate early interactions with cytosolic factors. Eukaryotic NAC is a heterodimer with two subunits sharing substantial homology with each other. All sequenced archaebacterial genomes exhibit only one gene homologous to the NAC subunits. Here we present the first archaebacterial NAC homolog. It forms a homodimer, and as eukaryotic NAC it is associated with ribosomes and contacts the emerging nascent chain on the ribosome. We present the first crystal structure of a NAC protein revealing two structural features: (i) a novel unique protein fold that mediates dimerization of the complex, and (ii) a ubiquitin-associated domain that suggests a yet unidentified role for NAC in the cellular protein quality control system via the ubiquitination pathway. Based on the presented structure we propose a model for the eukaryotic heterodimeric NAC domain.In eukaryotes nascent polypeptide-associated complex (NAC) 1 is a very abundant heterodimeric cytosolic protein complex composed of ␣-and NAC, which show substantial homology with each other (1). It was originally characterized as the first ribosome-associated protein to contact the emerging polypeptide chain (2). Protease protection assays further suggested that NAC might function as a shield for newly synthesized polypeptides against inappropriate interaction with cytosolic factors (3). It was proposed that cycles of binding and releasing NAC would expose the polypeptide to the cytosol in "quantal units," rather than amino acid by amino acid. NAC would thus contribute to fidelity in cotranslational processes such as targeting and folding. NAC was also shown to play a role in regulation of ribosome access to the translocation pore in the endoplasmic reticulum membrane in cotranslational protein translocation (4 -6). Still, the cellular function of NAC seems to be diverse and is probably not restricted to translation, because transcription-related functions have been suggested for the human ␣NAC subunit (7). In addition, yeast NAC was shown to play a role in the import of proteins into mitochondria (8). The importance of the in vivo function of NAC is emphasized by early embryonically lethal phenotypes of NAC mutants in mice, Drosophila melanogaster, and Caenorhabditis elegans (9, 10). Furthermore, intracellular levels of the individual NAC subunits change dramatically in the context of several human diseases, such as Alzheimer disease, Trisomy 21, AIDS, and malignant brain tumors, and a role for NAC in apoptosis was only recently proposed (11)(12)(13)(14).The two subunits of eukaryotic NAC show substantial homology to each other. Two recent comparative studies of completed archaeal genome...
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