Structural Insights into Nox4 and Nox2: Motifs Involved in Function and Cellular Localization

Regulated generation of reactive oxygen species (ROS) is primarily accomplished by NADPH oxidases (Nox). Nox1 to Nox4 form a membrane-associated heterodimer with p22^phox, creating the docking site for assembly of the activated oxidase. Signaling specificity is achieved by interaction with a complex network of cytosolic components. Nox4, an oxidase linked to cardiovascular disease, carcinogenesis, and pulmonary fibrosis, deviates from this model by displaying constitutive H₂O₂ production without requiring known regulators. Extensive Nox4/Nox2 chimera screening was initiated to pinpoint structural motifs essential for ROS generation and Nox subcellular localization. In summary, a matching B loop was crucial for catalytic activity of both Nox enzymes. Substitution of the carboxyl terminus was sufficient for converting Nox4 into a phorbol myristate acetate (PMA)-inducible phenotype, while Nox2-based chimeras never gained constitutive activity. Changing the Nox2 but not the Nox4 amino terminus abolished ROS generation. The unique heterodimerization of a functional Nox4/p22^phox Y121H complex was dependent on the D loop. Nox4, Nox2, and functional Nox chimeras translocated to the plasma membrane. Cell surface localization of Nox4 or PMA-inducible Nox4 did not correlate with O₂⁻ generation. In contrast, Nox4 released H₂O₂ and promoted cell migration. Our work provides insights into Nox structure, regulation, and ROS output that will aid inhibitor design.The family of NADPH oxidases consists of seven members termed Nox/Duox that differ in their tissue expression profiles, modes of activation, reactive oxygen species (ROS) outputs, and physiological functions. Understanding their distinguishing features is a prerequisite for rational inhibitor design and thus targeted intervention in ROS-mediated pathophysiologies (4). The coexpression of different Nox isoforms, each with potentially distinct functional profiles, in the same cell type necessitates a more discriminating approach than application of pan-Nox inhibitors. Detailed structure-function studies are necessary to identify unique regions and their impact with respect to catalytic function or localization of the enzyme. All Nox/Duox enzymes share a Nox backbone with six predicted transmembrane domains and an intracellular carboxyl-terminal domain which harbors FAD and NADPH binding sites. Nox5 and Duox1/2 enzymes contain additional structural elements such as amino terminal EF-hand motifs, a hallmark of their regulation by the intracellular calcium concentration (13, 30).The founding member of the NADPH oxidase family, the phagocyte oxidase, consists of membrane-bound Nox2 in a complex with the smaller subunit p22^phox (3). Heterodimerization of these two proteins is required for maturation and translocation of the enzyme complex to the plasma membrane or to intracellular vesicles. The Nox family members Nox1, Nox3, and Nox4 follow this paradigm (1, 14, 21, 25, 31). Heterodimer formation and association of the Nox/p22^phox complex at particular cellular membranes is essential for catalytic activity, i.e., for ROS generation. Nox2, and to a lesser degree Nox1 and Nox3, remain dormant under resting conditions and rely on stimulus-dependent translocation and assembly of oxidase components such as p47^phox and p67^phox, or NoxO1 and NoxA1 in the case of Nox1 and Nox3 (16). These steps, together with activation and translocation of the GTPase Rac, ultimately lead to the assembled, catalytically active oxidase and to ROS generation.Nox4 differs from the usual theme of multimeric assembly of active NADPH oxidases found in Nox1 to Nox3 (21, 22, 28, 32). Constitutive H₂O₂ production by Nox4 localized at perinuclear vesicles has been reported (1, 21, 28). Since NADPH oxidases catalyze the one-electron reduction of molecular oxygen to superoxide anion, the current dogma suggests that Nox4 generates intracellular superoxide. The superoxide produced will then dismutate rapidly to H₂O₂, diffusing from the cell into the extracellular milieu. Cytosolic proteins, which regulate the activity of Nox1 to Nox3 by binding to the carboxyl-terminal domains of Nox1 to Nox3, seem to be irrelevant for Nox4 function. The membrane-bound subunit p22^phox is to date the only known protein associated with Nox1 to Nox4. Heterodimerization, translocation, and enzymatic function of these oxidases require p22^phox. Recent structure-function analyses of complexes between Nox2 or Nox4 and the subunit p22^phox documented specific regions and amino acid residues in p22^phox necessary for complex formation and oxidase activity (35, 37). Interestingly, a p22^phox mutant (p22^phox Y121H) is capable of distinguishing between Nox1 to Nox3 and Nox4 by forming a functional complex only with Nox4, further suggesting unique structural features in Nox4 (35).In this study, we expand structure-function analysis of the oxidase complex by comparing Nox4/Nox2 chimeric enzymes with respect to NADPH oxidase activity, type of reactive oxygen species produced, requirement for additional oxidase components, and detailed subcellular localization.     

Teaching acid/base physiology in the laboratory

Acid/base homeostasis is one of the most difficult subdisciplines of physiology for medical students to master. A different approach, where theory and practice are linked, might help students develop a deeper understanding of acid/base homeostasis. We therefore set out to develop a laboratory exercise in acid/base physiology that would provide students with unambiguous and reproducible data that clearly would illustrate the theory in practice. The laboratory exercise was developed to include both metabolic acidosis and respiratory alkalosis. Data were collected from 56 groups of medical students that had participated in this laboratory exercise. The acquired data showed very consistent and solid findings after the development of both metabolic acidosis and respiratory alkalosis. All results were consistent with the appropriate diagnosis of the acid/base disorder. Not one single group failed to obtain data that were compatible with the diagnosis; it was only the degree of acidosis/alkalosis and compensation that varied.     

Metabolic engineering of Agrobacterium sp. strain ATCC 31749 for production of an α-Gal epitope

Background  

Oligosaccharides containing a terminal Gal-α1,3-Gal moiety are collectively known as α-Gal epitopes. α-Gal epitopes are integral components of several medical treatments under development, including flu and HIV vaccines as well as cancer treatments. The difficulty associated with synthesizing the α-Gal epitope hinders the development and application of these treatments due to the limited availability and high cost of the α-Gal epitope. This work illustrates the development of a whole-cell biocatalyst for synthesizing the α-Gal epitope, Gal-α1,3-Lac.     

Thermodynamic and Kinetic Characterization of Duplex Formation between 2′-O, 4′-C-Methylene-modified Oligoribonucleotides,DNA and RNA

2′-O,4′-C-methylene-linked ribonucleotide derivatives, named LNA (locked nucleic acid) and BNA (bridged nucleic acid) are nucleic acid analogoues that have shown high-affinity recognition of DNA and RNA, and the employment of LNA oligomers for antisense activity, gene regulation and nucleic acid diagnostics seems promising. Here we show kinetic and thermodynamic results on the interaction of a series of 10 bases long LNA–DNA mixmers, gabmers as well as full length LNA’s with the complementary DNA, RNA and LNA oligonucleotides in the presence and absence of 10 mM Mg²⁺- ions. Our results show no significant differences in the reaction thermodynamics and kinetics between the LNA species, only a tendency to stronger duplex formation with the gabmer and mixmer. Introduction of a few LNA’s thus may be a better strategy, than using full length LNA’s to obtain an oligonucleotide that markedly increases the strength of duplexes formed with the complementary DNA and RNA.     

TLR4-mediated survival of macrophages is MyD88 dependent and requires TNF-alpha autocrine signalling

Modulation of macrophage survival is a critical factor in the resolution of inflammatory responses. Exposure to LPS protects innate immune cells against apoptosis, although the precise pathways responsible for prolongation of macrophage survival remain to be fully established. The goal of this study was to characterize the mechanism of TLR4-mediated survival of murine bone marrow-derived macrophages upon M-CSF withdrawal in more detail. Using a combination of knockout mice and pharmacological inhibitors allowed us to show that TLR4 and TLR2 stimulation promotes long-term survival of macrophages in a MyD88-, PI3K-, ERK-, and NF-kappaB-dependent manner. LPS-induced long-term, but not short-term, survival requires autocrine signaling via TNF-alpha and is facilitated by a general cytoprotective program, similar to that mediated by M-CSF. TLR4-mediated macrophage survival is accompanied by a remarkable up-regulation of specific cell surface markers, suggesting that LPS stimulation leads to the differentiation of macrophages toward a mixed macrophage/dendritic cell-like phenotype.     

On the mechanism of cerebral accumulation of cholestanol in patients with cerebrotendinous xanthomatosis

The most serious consequence of sterol 27-hydroxylase deficiency in humans [cerebrotendinous xanthomatosis (CTX)] is the development of cholestanol-containing brain xanthomas. The cholestanol in the brain may be derived from the circulation or from 7alpha-hydroxylated intermediates in bile acid synthesis, present at 50- to 250-fold increased levels in plasma. Here, we demonstrate a transfer of 7alpha-hydroxy-4-cholesten-3-one across cultured porcine brain endothelial cells (a model for the blood-brain barrier) that is approximately 100-fold more efficient than the transfer of cholestanol. Furthermore, there was an efficient conversion of 7alpha-hydroxy-4-cholesten-3-one to cholestanol in cultured neuronal and glial cells as well as in monocyte-derived macrophages of human origin. It is concluded that the continuous intracellular production of cholestanol from a bile acid precursor capable of rapidly passing biomembranes, including the blood-brain barrier, is likely to be of major importance for the accumulation of cholestanol in patients with CTX. Such a mechanism also fits well with the observation that treatment with chenodeoxycholic acid, which normalizes the level of the bile acid precursor, results in a reduction of cholestanol-containing xanthomas even in the brain.     

Prenylated acetophenones from Melicope obscura and Melicope obtusifolia ssp. obtusifolia var. arborea and their distribution in Rutaceae

Four prenylated acetophenones 2,6-dihydroxy-4-geranyloxyacetophenone (1), 4-geranyloxy-2,6,β-trihydroxyacetophenone (2), 2,6-dihydroxy-4-geranyloxy-3-prenylacetophenone (3), and 4-geranyloxy-3-prenyl-2,6,β-trihydroxyacetophenone (4) have for the first time been isolated from Melicope obscura (1 and 2) and Melicope obtusifolia ssp. obtusifolia var. arborea (3 and 4). The distribution of prenylated acetophenones in Rutaceae is reviewed and the results, including the new records, indicate that prenylated acetophenones are valuable as chemotaxonomic markers for the subfamily Rutoideae, tribe Xanthoxyleae sensu Engler.     

Small molecule ago-allosteric modulators of the human glucagon-like peptide-1 (hGLP-1) receptor

Following our previous publication describing the biological profiles, we herein describe the structure-activity relationships of a core set of quinoxalines as the hGLP-1 receptor agonists. The most potent and efficacious compounds are 6,7-dichloroquinoxalines bearing an alkyl sulfonyl group at the C-2 position and a secondary alkyl amino group at the C-3 position. These findings serve as a valuable starting point for the discovery of more drug-like small molecule agonists for the hGLP-1 receptor.     

Repeated inhalations of diesel exhaust particles and oxidatively damaged DNA in young oxoguanine DNA glycosylase (OGG1) deficient mice

DNA repair may prevent increased levels of oxidatively damaged DNA from prolonged oxidative stress induced by, e.g. exposure to diesel exhaust particles (DEP). We studied oxidative damage to DNA in broncho-alveolar lavage cells, lungs, and liver after 4 × 1.5 h inhalations of DEP (20 mg/m³) in Ogg1^- / -  and wild type (WT) mice with similar extent of inflammation. DEP exposure increased lung levels of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) in Ogg1^- / -  mice, whereas no effect on 8-oxodG or oxidized purines in terms of formamidopyrimidine DNA glycosylase (FPG) sites was observed in WT mice. In both unexposed and exposed Ogg1^- / -  mice the level of FPG sites in the lungs was 3-fold higher than in WT mice. The high basal level of FPG sites in Ogg1^- / -  mice probably saturated the assay and prevented detection of DEP-generated damage. In conclusion, Ogg1^- / -  mice have elevated pulmonary levels of FPG sites and accumulate genomic 8-oxodG after repeated inhalations of DEP.