Constitutive NADPH oxidase 4 activity resides in the composition of the B-loop and the penultimate C terminus.

Redox regulation of signaling molecules contributes critically to propagation of intracellular signals. The main source providing reactive oxygen species (ROS) for these physiological processes are activated NADPH oxidases (Nox/Duox family). In a pathophysiological context, some NADPH oxidase complexes produce large amounts of ROS either as part of the antimicrobial immune defense or as pathologic oxidative stress in many chronic diseases. Thus, understanding the switch from a dormant, inactive conformation to the active state of these enzymes will aid the development of inhibitors. As exogenously expressed Nox4 represents the only constitutively active enzyme in this family, analysis of structural determinants that permit this active conformation was undertaken. Our focus was directed toward a cell-based analysis of the first intracellular loop, the B-loop, and the C-terminus, two regions of Nox family enzymes that are essential for electron transfer. Mutagenesis of the B-loop identified several unique residues and a polybasic motif that contribute to the catalytic activity of Nox4. By using a multifaceted approach, including Nox4-Nox2 chimeras, mutagenesis, and insertion of Nox2 domains, we show here that the penultimate 22 amino acids of Nox4 are involved in constitutive ROS generation. The appropriate spacing of the C-terminal Nox4 sequence may cooperate with a discrete arginine-based interaction site in the B-loop, providing an intrinsically active interface that could not be disrupted by peptides derived from the Nox4 C-terminus. These results indicate that accessibility for a Nox4-specific peptide inhibitor might be difficult to achieve in vivo.

A novel approach for in vivo measurement of mouse red cell redox status.

Maintenance of a reducing redox balance is a critical physiologic function of red cells (RBC) that can be perturbed in variety of RBC pathologies. Here we describe a new approach to evaluate in vivo RBC redox status using a redox sensitive GFP (roGFP2) sensor under control of a ß-globin mini-promoter, directing expression specifically to erythroid cells. RoGFP2 expressing RBCs demonstrate ratiometric and reversible shifts in fluorescence on exposure to oxidants and reductants. We demonstrate that roGFP2 expressing RBC can be used to monitor thiol redox status during in vitro phenylhydrazine treatment and over the course of in vivo RBC aging, where a shift to a more oxidized state is observed in older cells. Thus, roGFP2 transgenic mice are a new and versatile tool that can be used to probe how RBC redox status responds in the context of drug therapy, physiologic stressors and pathologic states.

Erythropoietin, GDF15, IL6, hepcidin and testosterone levels in a large cohort of elderly individuals with anaemia of known and unknown cause.

Epidemiologic studies have documented an increasing frequency of anaemia in individuals 65 yrs and older. Elderly individuals with anaemia have been categorised into the following: those with chronic disease, those with iron, B12 or folate deficiency and those with anaemia of unknown aetiology (AUE). There is considerable interest and debate as to whether AUE has an inflammatory component, is caused by cytokine dysregulation affecting production or response to erythropoietin (EPO) or iron availability or represents a novel pathologic process. Here, we compare a large cohort of AUE cases with a matched, non-anaemic control group and with individuals who have anaemia of defined cause. IL-6, hepcidin, GDF15, EPO and testosterone levels were compared. IL6 and hepcidin levels did not differ significantly between AUE and control groups, indicating that inflammation or iron restriction is not central feature of anaemia in this group. GDF15 levels were significantly elevated when comparing AUE with controls and were markedly elevated in patients with renal disease. Testosterone levels were lower in men from the AUE group compared with non-anaemic controls. EPO levels in the AUE group were increased relative to controls but were inappropriately low for the degree of anaemia. Our data indicate that an impaired EPO response, in the absence of evidence for iron restriction or inflammation, is characteristic of AUE.

Metabolome Changes during In Vivo Red Cell Aging Reveal Disruption of Key Metabolic Pathways.

Understanding the mechanisms for cellular aging is a fundamental question in biology. Normal red blood cells (RBCs) survive for approximately 100 days, and their survival is likely limited by functional decline secondary to cumulative damage to cell constituents, which may be reflected in altered metabolic capabilities. To investigate metabolic changes during in vivo RBC aging, labeled cell populations were purified at intervals and assessed for abundance of metabolic intermediates using mass spectrometry. A total of 167 metabolites were profiled and quantified from cell populations of defined ages. Older RBCs maintained ATP and redox charge states at the cost of altered activity of enzymatic pathways. Time-dependent changes were identified in metabolites related to maintenance of the redox state and membrane structure. These findings illuminate the differential metabolic pathway usage associated with normal cellular aging and identify potential biomarkers to determine average RBC age and rates of RBC turnover from a single blood sample.

A Dictyostelium long chain fatty acyl coenzyme A-synthetase mediates fatty acid retrieval from endosomes.

We have identified a subset of Dictyostelium endosomes that carry a long chain fatty acyl coenzyme A-synthetase (LC-FACS 1) on their cytosolic surface. Immunofluorescence studies and observations using GFP-fusion proteins collectively suggest that LC-FACS 1 associates with endosomes a few minutes after their formation, remains bound through the acidic phase of endocytic maturation and dissociates early in the phase where the endosomal content is neutralised prior to exocytosis. Mutants in the fcsA gene, encoding the LC-FACS 1 protein, were constructed by homologous recombination. These cells show a strong defect in the intracellular accumulation of fatty acids, either taken up together with the liquid medium or bound to the surface of particles. Because the mutant cells are otherwise fully competent for macropinocytosis and phagocytosis, we conclude that the LC-FACS 1 protein mediates the retrieval of fatty acids from the lumen of endosomes into the cytoplasm.

Assessment of the red cell proteome of young patients with unexplained hemolytic anemia by two-dimensional differential in-gel electrophoresis (DIGE).

Erythrocyte cytosolic protein expression profiles of children with unexplained hemolytic anemia were compared with profiles of close relatives and controls by two-dimensional differential in-gel electrophoresis (2D-DIGE). The severity of anemia in the patients varied from compensated (i.e., no medical intervention required) to chronic transfusion dependence. Common characteristics of all patients included chronic elevation of reticulocyte count and a negative workup for anemia focusing on hemoglobinopathies, morphologic abnormalities that would suggest a membrane defect, immune-mediated red cell destruction, and evaluation of the most common red cell enzyme defects, glucose-6-phosphate dehydrogenase and pyruvate kinase deficiency. Based upon this initial workup and presentation during infancy or early childhood, four patients classified as hereditary nonspherocytic hemolytic anemia (HNSHA) of unknown etiology were selected for proteomic analysis. DIGE analysis of red cell cytosolic proteins clearly discriminated each anemic patient from both familial and unrelated controls, revealing both patient-specific and shared patterns of differential protein expression. Changes in expression pattern shared among the four patients were identified in several protein classes including chaperons, cytoskeletal and proteasome proteins. Elevated expression in patient samples of some proteins correlated with high reticulocyte count, likely identifying a subset of proteins that are normally lost during erythroid maturation, including proteins involved in mitochondrial metabolism and protein synthesis. Proteins identified with patient-specific decreased expression included components of the glutathione synthetic pathway, antioxidant pathways, and proteins involved in signal transduction and nucleotide metabolism. Among the more than 200 proteins identified in this study are 21 proteins not previously described as part of the erythrocyte proteome. These results demonstrate the feasibility of applying a global proteomic approach to aid characterization of red cells from patients with hereditary anemia of unknown cause, including the identification of differentially expressed proteins as potential candidates with a role in disease pathogenesis.

SOD2 deficient erythroid cells up-regulate transferrin receptor and down-regulate mitochondrial biogenesis and metabolism.

BACKGROUND: Mice irradiated and reconstituted with hematopoietic cells lacking manganese superoxide dismutase (SOD2) show a persistent hemolytic anemia similar to human sideroblastic anemia (SA), including characteristic intra-mitochondrial iron deposition. SA is primarily an acquired, clonal marrow disorder occurring in individuals over 60 years of age with uncertain etiology. METHODOLOGY/PRINCIPAL FINDINGS: To define early events in the pathogenesis of this murine model of SA, we compared erythroid differentiation of Sod2⁻/⁻ and normal bone marrow cells using flow cytometry and gene expression profiling of erythroblasts. The predominant transcriptional differences observed include widespread down-regulation of mitochondrial metabolic pathways and mitochondrial biogenesis. Multiple nuclear encoded subunits of complexes I-IV of the electron transport chain, ATP synthase (complex V), TCA cycle and mitochondrial ribosomal proteins were coordinately down-regulated in Sod2⁻/⁻ erythroblasts. Despite iron accumulation within mitochondria, we found increased expression of transferrin receptor, Tfrc, at both the transcript and protein level in SOD2 deficient cells, suggesting deregulation of iron delivery. Interestingly, there was decreased expression of ABCb7, the gene responsible for X-linked hereditary SA with ataxia, a component required for iron-sulfur cluster biogenesis. CONCLUSIONS/SIGNIFICANCE: These results indicate that in erythroblasts, mitochondrial oxidative stress reduces expression of multiple nuclear genes encoding components of the respiratory chain, TCA cycle and mitochondrial protein synthesis. An additional target of particular relevance for SA is iron:sulfur cluster biosynthesis. By decreasing transcription of components of cluster synthesis machinery, both iron utilization and regulation of iron uptake are impacted, contributing to the sideroblastic phenotype.

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 H(2)O(2) 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 O(2)(-) generation. In contrast, Nox4 released H(2)O(2) and promoted cell migration. Our work provides insights into Nox structure, regulation, and ROS output that will aid inhibitor design.

Mutational analysis reveals distinct features of the Nox4-p22 phox complex.

The integral membrane protein p22(phox) forms a heterodimeric enzyme complex with NADPH oxidases (Noxs) and is required for their catalytic activity. Nox4, a Nox linked to cardiovascular disease, angiogenesis, and insulin signaling, is unique in its ability to produce hydrogen peroxide constitutively. To date, p22(phox) constitutes the only identified regulatory component for Nox4 function. To delineate structural elements in p22(phox) essential for formation and localization of the Nox4-p22(phox) complex and its enzymatic function, truncation and point mutagenesis was used. Human lung carcinoma cells served as a heterologous expression system, since this cell type is p22(phox)-deficient and promotes cell surface expression of the Nox4-p22(phox) heterodimer. Expression of p22(phox) truncation mutants indicates that the dual tryptophan motif contained in the N-terminal amino acids 6-11 is essential, whereas the C terminus (amino acids 130-195) is dispensable for Nox4 activity. Introduction of charged residues in domains predicted to be extracellular by topology modeling was mostly tolerated, whereas the exchange of amino acids in predicted membrane-spanning domains caused loss of function or showed distinct differences in p22(phox) interaction with various Noxs. For example, the substitution of tyrosine 121 with histidine in p22(phox), which abolished Nox2 and Nox3 function in vivo, preserved Nox4 activity when expressed in lung cancer cells. Many of the examined p22(phox) mutations inhibiting Nox1 to -3 maturation did not alter Nox4-p22(phox) association, further accenting the differences between Noxs. These studies highlight the distinct interaction of the key regulatory p22(phox) subunit with Nox4, a feature which could provide the basis for selective inhibitor development.

Deletion mutagenesis of p22phox subunit of flavocytochrome b558: identification of regions critical for gp91phox maturation and NADPH oxidase activity.

The heterodimeric flavocytochrome b558, comprised of the two integral membrane proteins p22phox and gp91phox, mediates the transfer of electrons from NADPH to molecular oxygen in the phagocyte NADPH oxidase to generate the superoxide precursor of microbicidal oxidants. This study uses deletion mutagenesis to identify regions of p22phox required for maturation of gp91phox and for NADPH oxidase activity. N-terminal, C-terminal, or internal deletions of human p22phox were generated and expressed in Chinese hamster ovary cells with transgenes for gp91phox and two other NADPH oxidase subunits, p47phox, and p67phox. The results demonstrate that p22phox-dependent maturation of gp91phox carbohydrate, cell surface expression of gp91phox, and the enzymatic function of flavocytochrome b558 are closely correlated. Whereas the 5 N-terminal and 25 C-terminal amino acids are dispensable for these functions, the N-terminal 11 amino acids of p22phox are required, as is a hydrophilic region between amino acids 65 and 90. Upon deletion of 54 residues at the C terminus of p22phox (amino acids 142-195), maturation and cell surface expression of gp91phox was still preserved, although NADPH oxidase activity was absent, as expected, due to removal of a proline-rich domain between amino acids 151-160 that is required for recruitment of p47phox. Antibody binding studies indicate that the extreme N terminus of p22phox is inaccessible in the absence of cell permeabilization, supporting a model in which both the N- and C-terminal domains of p22phox extend into the cytoplasm, anchored by two membrane-embedded regions.