Expansion of Bacteriophages Is Linked to Aggravated Intestinal Inflammation and Colitis

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Assembly of photoactive orange carotenoid protein from its domains unravels a carotenoid shuttle mechanism

The photoswitchable orange carotenoid protein (OCP) is indispensable for cyanobacterial photoprotection by quenching phycobilisome fluorescence upon photoconversion from the orange OCP^O to the red OCP^R form. Cyanobacterial genomes frequently harbor, besides genes for orange carotenoid proteins (OCPs), several genes encoding homologs of OCP’s N- or C-terminal domains (NTD, CTD). Unlike the well-studied NTD homologs, called Red Carotenoid Proteins (RCPs), the role of CTD homologs remains elusive. We show how OCP can be reassembled from its functional domains. Expression of Synechocystis OCP-CTD in carotenoid-producing Escherichia coli yielded violet-colored proteins, which, upon mixing with the RCP-apoprotein, produced an orange-like photoswitchable form that further photoconverted into a species that quenches phycobilisome fluorescence and is spectroscopically indistinguishable from RCP, thus demonstrating a unique carotenoid shuttle mechanism. Spontaneous carotenoid transfer also occurs between canthaxanthin-coordinating OCP-CTD and the OCP apoprotein resulting in formation of photoactive OCP. The OCP-CTD itself is a novel, dimeric carotenoid-binding protein, which can coordinate canthaxanthin and zeaxanthin, effectively quenches singlet oxygen and interacts with the Fluorescence Recovery Protein. These findings assign physiological roles to the multitude of CTD homologs in cyanobacteria and explain the evolutionary process of OCP formation.

     

Hydrogen-induced structural changes at the nickel site of the regulatory [NiFe] hydrogenase from Ralstonia eutropha detected by X-ray absorption spectroscopy

For the first time, the nickel site of the hydrogen sensor of Ralstonia eutropha, the regulatory [NiFe] hydrogenase (RH), was investigated by X-ray absorption spectroscopy (XAS) at the nickel K-edge. The oxidation state and the atomic structure of the Ni site were investigated in the RH in the absence (air-oxidized, RH(ox)) and presence of hydrogen (RH(+H2)). Incubation with hydrogen is found to cause remarkable changes in the spectroscopic properties. The Ni-C EPR signal, indicative of Ni(III), is detectable only in the RH(+H2) state. XANES and EXAFS spectra indicate a coordination of the Ni in the RH(ox) and RH(+H2) that pronouncedly differs from the one in standard [NiFe] hydrogenases. Also, the changes induced by exposure to H(2) are unique. A drastic modification in the XANES spectra and an upshift of the K-edge energy from 8339.8 (RH(ox)) to 8341.1 eV (RH(+H2)) is observed. The EXAFS spectra indicate a change in the Ni coordination in the RH upon exposure to H(2). One likely interpretation of the data is the detachment of one sulfur ligand in RH(+H2) and the binding of additional (O,N) or H ligands. The following Ni oxidation states and coordinations are proposed: five-coordinated Ni(II)(O,N)(2)S(3) for RH(ox) and six-coordinated Ni((III))(O,N)(3)X(1)S(2) [X being either an (O,N) or H ligand] for RH(+H2). Implications of the structural features of the Ni site of the RH in relation to its function, hydrogen sensing, are discussed.     

NiFe hydrogenase active site biosynthesis: identification of Hyp protein complexes in Ralstonia eutropha

Biosynthesis of the NiFe hydrogenase active site is a complex process involving the action of the Hyp proteins: HypA-HypF. Here we investigate the mechanism of NiFe site biosynthesis in Ralstonia eutropha by examining the interactions between HypC, HypD, HypE, and HypF1. Using an affinity purification procedure based on the Strep-tag II, we purified HypC and HypE from different genetic backgrounds as complexes with other hydrogenase-related proteins and characterized them using immunological analysis. Copurification of HypC and HoxH, the active site-containing subunit of the soluble hydrogenase in R. eutropha, from several different genetic backgrounds suggests that this complex forms early in the maturation process. With respect to the Hyp proteins, it is shown that HypE and HypF1 formed a stable complex both in vivo and in vitro. Furthermore, HypC and HypD functioned as a unit. Together, they were able to interact with HypE to form a range of complexes probably varying in stoichiometry. The HypC/HypD/HypE complexes did not involve HypF1 but appeared to be more stable when HypF1 was also present in the cells. We hypothesize that HypF1 is able to modify some component of the HypC/HypD/HypE complex. Since we have also seen that HypF1 and HypE form a complex, it is likely that HypF1 modifies HypE. On the basis of these results, we propose a complete catalytic cycle for HypE. First, it is modified by HypF1, and then it can form a complex with HypC/HypD. This activated HypE/HypC/HypD complex could then decompose by donating active site components to the immature hydrogenase and regenerate unmodified HypE.     

The role of the active site-coordinating cysteine residues in the maturation of the H2-sensing [NiFe] hydrogenase from Ralstonia eutropha H16

The H₂-splitting active site of [NiFe] hydrogenases is tightly bound to the protein matrix via four conserved cysteine residues. In this study, the nickel-binding cysteine residues of HoxC, the large subunit of the H₂-sensing regulatory hydrogenase (RH) from Ralstonia eutropha, were replaced by serine. All four mutant proteins, C60S, C63S, C479S, and C482S, were inactive both in H₂ sensing and H₂ oxidation and did not adopt the native oligomeric structure of the RH. Nickel was bound only to the C482S derivative. The assembly of the [NiFe] active site is a complex process that requires the function of at least six accessory proteins. Among these proteins, HypC has been shown to act as a chaperone for the large subunit during the maturation process. Immunoblot analysis revealed the presence of a strong RH-dependent HypC-specific complex in extracts containing the C60S, C63S, and C482S derivatives, pointing to a block in maturation for these mutant proteins. The lack of this complex in the extract containing C479S indicates that this specific cysteine residue might be crucial for the interaction between HoxC and HypC.This work is dedicated to Prof. H.G. Schlegel on the occasion of his 80th birthday.     

Analysis of proteomic changes induced upon cellular differentiation of the human intestinal cell line Caco-2

The human intestinal cell line Caco-2 is a well-established model system to study cellular differentiation of human enterocytes of intestinal origin, because these cells have the capability to differentiate spontaneously into polarized cells with morphological and biochemical features of small intestinal enterocytes. Therefore, the cells are widely used as an in vitro model for the human intestinal barrier. In this study, a proteomic approach was used to identify the molecular marker of intestinal cellular differentiation. The proteome of proliferating Caco-2 cells was compared with that of fully differentiated cells. Two-dimensional gel analysis yielded 53 proteins that were differently regulated during the differentiation process. Pathway analysis conducted with those 34 proteins that were identified by matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) analysis revealed subsets of proteins with common molecular and cellular function. It was shown that proteins involved in xenobiotic and drug metabolism as well as in lipid metabolism were upregulated upon cellular differentiation. In parallel, proteins associated with proliferation, cell growth and cancer were downregulated, reflecting the loss of the tumorigenic phenotype of the cells. Thus, the proteomic approach in combination with a literature-based pathway analysis yielded valuable information about the differentiation process of Caco-2 cells on the molecular level that contributes to the understanding of the development of colon cancer or inflammatory diseases such as ulcerative colitis--diseases associated with an imbalanced differentiation process of intestinal cells.     

A model system for [NiFe] hydrogenase maturation studies: Purification of an active site-containing hydrogenase large subunit without small subunit

The large subunit HoxC of the H2-sensing [NiFe] hydrogenase from Ralstonia eutropha was purified without its small subunit. Two forms of HoxC were identified. Both forms contained iron but only substoichiometric amounts of nickel. One form was a homodimer of HoxC whereas the second also contained the Ni-Fe site maturation proteins HypC and HypB. Despite the presence of the Ni-Fe active site in some of the proteins, both forms, which lack the Fe-S clusters normally present in hydrogenases, cannot activate hydrogen. The incomplete insertion of nickel into the Ni-Fe site provides direct evidence that Fe precedes Ni in the course of metal center assembly.