3Outer membrane proteins (OMPs) play important roles in Gram-negative bacteria, mitochondria and chloroplasts in nutrition transport, protein import, secretion, and other fundamental biological processes [1][2][3] . Dysfunction of mitochondria outer membrane proteins are linked to disorders such as diabetes, Parkinsons and other neurodegenerative diseases 4,5 . The OMPs are inserted and folded correctly into the outer membrane (OM) by the conserved OMP85 family proteins [6][7][8] , suggesting that similar insertion mechanisms may be used in Gram-negative bacteria, mitochondria and chloroplasts.In Gram-negative bacteria, OMPs are synthesized in the cytoplasm, and are transported across the inner membrane by SecYEG into the periplasm 8,9 . The seventeen kilodalton (kDa) protein (Skp) and the survival factor A (SurA) chaperones escort the unfolded OMPs across the periplasm to the β-barrel assembly machinery (BAM), which is responsible for insertion and assembly of OMPs into the OM 10-12 . InEscherichia coli, the BAM complex consists of BamA and four lipoprotein subunits, BamB, BamC, BamD and BamE. BamA is comprised of five N-terminal polypeptide transport-associated (POTRA) domains and a C-terminal OMP transmembrane barrel, while the four lipoproteins are affixed to the membrane by N-terminal lipid-modified cysteines. Of these subunits, BamA and BamD are essential 3,6 . One copy of each of these five proteins is required to form the BAM complex with an approximate molecular weight of 200 kDa (Extended Data Fig. 1). In vitro reconstitution of the E.coli BAM complex and functional assays showed that all five subunits are required to obtain the maximum activity of BAM [13][14][15][16] . Furthermore, comparison of the two complexes reveals that the periplasmic units are rotated with respect to the barrel, which appears to be linked to significant conformational changes in the β-strands β1C-β6C of the barrel. Taken together this suggests a novel insertion mechanism whereby rotation of the BAM periplasmic ring promotes insertion of OMPs into the OM. To our knowledge, this is the first reported crystal structure of an intramembrane barrel with a lateral-open conformation.Unique architecture of two E. coli BAM complexes X-ray diffraction data of selenomethionine labelled crystals were collected to 3.9Ångström (Å) resolution and the BAM structure was determined by singlewavelength anomalous dispersion (SAD) and manual molecular replacement (Methods, Extended Data Table 1). The first structure contained four proteins: BamA, BamC, BamD and BamE (Fig. 1a-c), with the electron density and crystal packing indicating that the BamB is absent in the complex. This was confirmed by SDS-PAGE analysis of the crystals (Extended Data Fig. 1 and Supplementary Data Fig. S1). In this model, BamA, BamC, BamD and BamE contain residues E22-I806, C25-K344, E26-S243, and C20-E110, respectively. The machinery is approximately 115 Å in length, 84 Å in width and 132 Å in height (Fig. 1a). 5The architecture of BamACDE resembles a top hat with a...
Lipopolysaccharide (LPS) is essential for most Gram-negative bacteria and has crucial roles in protection of the bacteria from harsh environments and toxic compounds, including antibiotics. Seven LPS transport proteins (that is, LptA-LptG) form a trans-envelope protein complex responsible for the transport of LPS from the inner membrane to the outer membrane, the mechanism for which is poorly understood. Here we report the first crystal structure of the unique integral membrane LPS translocon LptD-LptE complex. LptD forms a novel 26-stranded β-barrel, which is to our knowledge the largest β-barrel reported so far. LptE adopts a roll-like structure located inside the barrel of LptD to form an unprecedented two-protein 'barrel and plug' architecture. The structure, molecular dynamics simulations and functional assays suggest that the hydrophilic O-antigen and the core oligosaccharide of the LPS may pass through the barrel and the lipid A of the LPS may be inserted into the outer leaflet of the outer membrane through a lateral opening between strands β1 and β26 of LptD. These findings not only help us to understand important aspects of bacterial outer membrane biogenesis, but also have significant potential for the development of novel drugs against multi-drug resistant pathogenic bacteria.
BackgroundSweet potato (Ipomoea batatas L. [Lam.]) ranks among the top six most important food crops in the world. It is widely grown throughout the world with high and stable yield, strong adaptability, rich nutrient content, and multiple uses. However, little is known about the molecular biology of this important non-model organism due to lack of genomic resources. Hence, studies based on high-throughput sequencing technologies are needed to get a comprehensive and integrated genomic resource and better understanding of gene expression patterns in different tissues and at various developmental stages.Methodology/Principal FindingsIllumina paired-end (PE) RNA-Sequencing was performed, and generated 48.7 million of 75 bp PE reads. These reads were de novo assembled into 128,052 transcripts (≥100 bp), which correspond to 41.1 million base pairs, by using a combined assembly strategy. Transcripts were annotated by Blast2GO and 51,763 transcripts got BLASTX hits, in which 39,677 transcripts have GO terms and 14,117 have ECs that are associated with 147 KEGG pathways. Furthermore, transcriptome differences of seven tissues were analyzed by using Illumina digital gene expression (DGE) tag profiling and numerous differentially and specifically expressed transcripts were identified. Moreover, the expression characteristics of genes involved in viral genomes, starch metabolism and potential stress tolerance and insect resistance were also identified.Conclusions/SignificanceThe combined de novo transcriptome assembly strategy can be applied to other organisms whose reference genomes are not available. The data provided here represent the most comprehensive and integrated genomic resources for cloning and identifying genes of interest in sweet potato. Characterization of sweet potato transcriptome provides an effective tool for better understanding the molecular mechanisms of cellular processes including development of leaves and storage roots, tissue-specific gene expression, potential biotic and abiotic stress response in sweet potato.
SummaryLipopolysaccharide (LPS) is essential for the vitality of most Gram-negative bacteria and plays an important role in bacterial multidrug resistance. The LptD/E translocon inserts LPS into the outer leaflet, the mechanism of which is poorly understood. Here, we report mutagenesis, functional assays, and molecular dynamics simulations of the LptD/E complex, which suggest two distinct pathways for the insertion of LPS. The N-terminal domain of LptD comprises a hydrophobic slide that injects the acyl tails of LPS directly into the outer membrane through an intramembrane hole, while the core oligosaccharide and O-antigen pass a lumen gate that triggers the unzipping of the lateral opening between strands β1C and β26C of the barrel of LptD, to finalize LPS insertion. Mutation of the LPS transport related residues or block of the LPS transport pathways results in the deaths of Escherichia coli. These findings are important for the development of novel antibiotics.
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