Identification of 2-oxohistidine Interacting Proteins Using E. coli Proteome Chips.

Cellular proteins are constantly damaged by reactive oxygen species generated by cellular respiration. Because of its metal-chelating property, the histidine residue is easily oxidized in the presence of Cu/Fe ions and H2O2 via metal-catalyzed oxidation, usually converted to 2-oxohistidine. We hypothesized that cells may have evolved antioxidant defenses against the generation of 2-oxohistidine residues on proteins, and therefore there would be cellular proteins which specifically interact with this oxidized side chain. Using two chemically synthesized peptide probes containing 2-oxohistidine, high-throughput interactome screening was conducted using the E. coli K12 proteome microarray containing >4200 proteins. Ten interacting proteins were identified, and successfully validated using a third peptide probe, fluorescence polarization assays, as well as binding constant measurements. We discovered that 9 out of 10 identified proteins seemed to be involved in redox-related cellular functions. We also built the functional interaction network to reveal their interacting proteins. The network showed that our interacting proteins were enriched in oxido-reduction processes, ion binding, and carbon metabolism. A consensus motif was identified among these 10 bacterial interacting proteins based on bioinformatic analysis, which also appeared to be present on human S100A1 protein. Besides, we found that the consensus binding motif among our identified proteins, including bacteria and human, were located within α-helices and faced the outside of proteins. The combination of chemically engineered peptide probes with proteome microarrays proves to be an efficient discovery platform for protein interactomes of unusual post-translational modifications, and sensitive enough to detect even the insertion of a single oxygen atom in this case.

Protein interactome analysis of iduronic acid-containing glycosaminoglycans reveals a novel flagellar invasion factor MbhA.

Pathogens are able to exploit specific glycosaminoglycans (GAGs), especially iduronic acid (IdoA)-containing GAGs, to invade the host. By analyzing Escherichia coli proteome chip data, we identified the interactomes of three IdoA-containing GAGs: heparin, heparin sulfate (HS), and chondroitin sulfate B (CSB). Using non-IdoA-containing GAG, chondroitin sulfate C, as a negative control, 157 proteins specifically binding with IdoA-containing GAGs were revealed in the present study. These proteins showed functional enrichment in protein synthesis and metabolism. Fifteen proteins which commonly interacts with three IdoA-containing GAGs were further examined. The regular expression for motif showed these common IdoA interactome shared a conserved sequence. Among them, we identified a second flagellar system outer membrane protein, MbhA. The MbhA has Kd values of 8.9 × 10-8 M, 5.3 × 10-7 M, and 1.79 × 10-7 M to interact with heparin, HS, and CSB, respectively. Using flow cytometry, we confirmed that the MbhA protein can bind to human epithelial cells HCT-8. Overexpression of mbhA increased the percentage of invasion in E. coli which lacks a second flagellar system. Moreover, pre-blocking of HCT-8 cells with MbhA inhibited the bacterial invasion, implying the importance of the direct interaction of MbhA and the host cell surface on bacterial invasion. SIGNIFICANCE: We analyzed the Escherichia coli proteomic data to elucidate the interactomes of three different IdoA-containing GAGs (heparin, HS, and CSB) because these IdoA-containing GAGs can mediate bacterial invasion to the host. Through proteomic and systematic analysis, a second flagellar system outer membrane protein, MbhA, was also identified in the present study. Affinity assay confirmed that MbhA can bind to three IdoA-containing GAGs heparin, HS, and CSB. The result of flow cytometry also showed MbhA can interact with human epithelial cells HCT-8. Results of bacteria invasion assay showed overexpression of mbhA promoted the bacterial invasion. Moreover, pre-blocking of HCT-8 cells with MbhA also reduced the percentage of bacterial invasion. These findings correspond well that MbhA is one of invasion factors.

Systematic protein interactome analysis of glycosaminoglycans revealed YcbS as a novel bacterial virulence factor.

Microbial pathogens have evolved several strategies for interacting with host cell components, such as glycosaminoglycans (GAGs). Some microbial proteins involved in host-GAG binding have been described; however, a systematic study on microbial proteome-mammalian GAG interactions has not been conducted. Here, we used Escherichia coli proteome chips to probe four typical mammalian GAGs, heparin, heparan sulphate (HS), chondroitin sulphate B (CSB), and chondroitin sulphate C (CSC), and identified 185 heparin-, 62 HS-, 98 CSB-, and 101 CSC-interacting proteins. Bioinformatics analyses revealed the unique functions of heparin- and HS-specific interacting proteins in glycine, serine, and threonine metabolism. Among all the GAG-interacting proteins, three were outer membrane proteins (MbhA, YcbS, and YmgH). Invasion assays confirmed that mutant E. coli lacking ycbS could not invade the epithelial cells. Introducing plasmid carrying ycbS complemented the invading defects at ycbS lacking E. coli mutant, that can be further improved by overexpressing ycbS. Preblocking epithelial cells with YcbS reduced the percentage of E. coli invasions. Moreover, we observed that whole components of the ycb operon were crucial for invasion. The displacement assay revealed that YcbS binds to the laminin-binding site of heparin and might affect the host extracellular matrix structure by displacing heparin from laminin.

A fast universal immobilization of immunoglobulin G at 4 °C for the development of array-based immunoassays.

To maintain the antibody activity and enhance performance of array-based immunoassays, protein G was used to allow a shorter duration of immunoglobulin G immobilization at 4 °C, with the antibody placed in the appropriate orientation. The multiplexed detection of six pain-related message molecules (PRMMs) was used as examples for the development of array-based immunoassays: substance P, calcitonin gene-related peptide, nerve growth factor, brain-derived neurotrophic factor, tumor necrosis factor-α, and ß-endorphin. Protein G- and non-protein G-coated slides were tested. Compared to non-protein G immunoassays, protein G shortened the antibody immobilization time at 4 °C from overnight to 2 hours. Only protein G-facilitated immunoassays succeeded in simultaneously detecting all six PRMMs with high specificity. Dose-response curves showed that the limits of detection of the protein G-multiplexed immunoassays for the PRMMs was approximately 164, 167, 120, 60, 80, and 92 pg/ml, respectively. Thus, protein G effectively shortens the duration of antibody immobilization at 4 °C, allowing the use of sensitive array-based immunoassays for the simultaneous detection of PRMMs.