Molecular Insights of p47phox Phosphorylation Dynamics in the Regulation of NADPH Oxidase Activation and Superoxide Production

Phagocyte superoxide production by a multicomponent NADPH oxidase is important in host defense against microbial invasion. However inappropriate NADPH oxidase activation causes inflammation. Endothelial cells express NADPH oxidase and endothelial oxidative stress due to prolonged NADPH oxidase activation predisposes many diseases. Discovering the mechanism of NADPH oxidase activation is essential for developing novel treatment of these diseases. The p47^phox is a key regulatory subunit of NADPH oxidase; however, due to the lack of full protein structural information, the mechanistic insight of p47^phox phosphorylation in NADPH oxidase activation remains incomplete. Based on crystal structures of three functional domains, we generated a computational structural model of the full p47^phox protein. Using a combination of in silico phosphorylation, molecular dynamics simulation and protein/protein docking, we discovered that the C-terminal tail of p47^phox is critical for stabilizing its autoinhibited structure. Ser-379 phosphorylation disrupts H-bonds that link the C-terminal tail to the autoinhibitory region (AIR) and the tandem Src homology 3 (SH3) domains, allowing the AIR to undergo phosphorylation to expose the SH3 pocket for p22^phox binding. These findings were confirmed by site-directed mutagenesis and gene transfection of p47^phox−/− coronary microvascular cells. Compared with wild-type p47^phox cDNA transfected cells, the single mutation of S379A completely blocked p47^phox membrane translocation, binding to p22^phox and endothelial O₂^⨪ production in response to acute stimulation of PKC. p47^phox C-terminal tail plays a key role in stabilizing intramolecular interactions at rest. Ser-379 phosphorylation is a molecular switch which initiates p47^phox conformational changes and NADPH oxidase-dependent superoxide production by cells.     

Conformational changes in p47 upon activation highlighted by mass spectrometry coupled to hydrogen/deuterium exchange and limited proteolysis

The neutrophil NADPH oxidase is an enzymatic complex involved in innate immunity. Phosphorylation of p47^phox promotes its translocation with p67^phox and p40^phox, followed by membrane interaction and assembly with flavocytochrome b₅₅₈ into a functional complex. To characterise p47^phox conformational changes during activation, we used wild-type and the S303/304/328E triple mutant mimicking the phosphorylated state. Hydrogen/deuterium exchange and limited proteolysis coupled to mass spectrometry were used to discriminate between the various structural models. An increase in deuteration confirmed that p47^phox adopts an open and more flexible conformation after activation. Limited proteolysis correlated this change with increased auto-inhibitory region (AIR) accessibility. These results establish a structural link between the AIR release and the exposure of the Phox homology (PX) domain.     

p47phox Molecular Activation for Assembly of the Neutrophil NADPH Oxidase Complex

The p47^phox cytosolic factor from neutrophilic NADPH oxidase has always been resistant to crystallogenesis trials due to its modular organization leading to relative flexibility. Hydrogen/deuterium exchange coupled to mass spectrometry was used to obtain structural information on the conformational mechanism that underlies p47^phox activation. We confirmed a relative opening of the protein with exposure of the SH3 Src loops that are known to bind p22^phox upon activation. A new surface was shown to be unmasked after activation, representing a potential autoinhibitory surface that may block the interaction of the PX domain with the membrane in the resting state. Within this surface, we identified 2 residues involved in the interaction with the PX domain. The double mutant R162A/D166A showed a higher affinity for specific phospholipids but none for the C-terminal part of p22^phox, reflecting an intermediate conformation between the autoinhibited and activated forms.     

Mechanism for phosphorylation-induced activation of the phagocyte NADPH oxidase protein p47(phox). Triple replacement of serines 303, 304, and 328 with aspartates disrupts the SH3 domain-mediated intramolecular interaction in p47(phox), thereby activating the oxidase

Activation of the superoxide-producing phagocyte NADPH oxidase requires interaction between p47(phox) and p22(phox), which is mediated via the SH3 domains of the former protein. This interaction is considered to be induced by exposure of the domains that are normally masked by an intramolecular interaction with the C-terminal region of p47(phox). Here we locate the intramolecular SH3-binding site at the region of amino acid residues 286-340, where Ser-303, Ser-304, and Ser-328 that are among several serines known to become phosphorylated upon cell stimulation exist. Simultaneous replacement of the three serines in p47(phox) with aspartates or glutamates, each mimicking phosphorylated residues, is sufficient for disruption of the intramolecular interaction and resultant access to p22(phox). The triply mutated proteins are also capable of activating the NADPH oxidase without in vitro activators such as arachidonate under cell-free conditions. In a whole-cell system where expression of the wild-type p47(phox) reconstitutes the stimulus-dependent oxidase activity, substitution of the kinase-insensitive residue alanine for Ser-328 as well as for Ser-303/Ser-304 leads to a defective production of superoxide. These findings suggest that phosphorylation of the three serines in p47(phox) induces a conformational change to a state accessible to p22(phox), thereby activating the NADPH oxidase.     

Conformational changes in truncated p47phox proteins monitored by fluorescent labeling

The leukocyte NADPH oxidase of neutrophils is a membrane-bound enzyme that catalyzes the reduction of oxygen to O^– ₂ at the expense of NADPH. During activation, the cytosolic oxidase components p47^phox and p67^phox, each containing two Src homology 3 (SH3) domains, migrate to the plasma membrane. p47^phox and p67^phox associate with cytochrome b₅₅₈, a membrane-integrated flavohemoprotein, to assemble the active oxidase. Oxidase activation can be mimicked in a cell-free system using an anionic amphiphile, such as sodium dodecyl sulfate or arachidonic acid, as an activating agent. Activators of the oxidase in vitro cause exposure of the SH3 domains of p47^phox, which has probably been masked by the C-terminal region of this protein in a resting state. We show here that the fluorescence exhibited by the covalently labeled N,N-di-methyl-N(iodoacetyl)-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl) ethyleneamine (IANBD) was increased when N-terminal-truncated p47^phox-(SH3)₂-C was treated with anionic amphiphiles. This finding was similar to the results obtained with the full-length p47^phox. However, the fluorescence of C-terminal-truncated p47^phox-N-(SH3)₂ and that of both C-terminal and N-terminal truncated p47^phox-(SH3)₂ were not altered by the activators. These results indicate that the C-terminal region of p47^phox is a primary target of the conformational change during the activation of NADPH oxidase.     

Role for the first SH3 domain of p67 in activation of superoxide-producing NADPH oxidases

The membrane-bound NADPH oxidase in phagocytes, gp91^phox (a.k.a. Nox2), produces superoxide, a precursor of microbicidal oxidants, thereby playing a crucial role in host defense. Activation of gp91^phox/Nox2 requires assembly with the cytosolic proteins p67^phox and p47^phox, each containing two SH3 domains. Although the C-terminal SH3 domain of p67^phox is responsible for binding to p47^phox, little is known about the role for the first (N-terminal) SH3 domain [SH3(N)]. Here we show that truncation of p67^phox-SH3(N), but not substitution of arginine for the invariant residue Trp-277 in SH3(N), results in an impaired activation of gp91^phox/Nox2. The impairment is overcome by higher expression of an SH3(N)-defective p67^phox in cells, suggesting that SH3(N) primarily increases the affinity of p67^phox for the oxidase complex. On the other hand, p67^phox-SH3(N) is not involved in activation of Nox1 and Nox3, closely-related homologues of gp91^phox/Nox2. Thus p67^phox-SH3(N) specifically functions in gp91^phox/Nox2 activation probably via facilitating oxidase assembly.     

Functional analysis of two-amino acid substitutions in gp91<Emphasis Type="Italic">phox</Emphasis> in a patient with X-linked flavocytochrome <Emphasis Type="Italic">b</Emphasis><Subscript>558</Subscript>-positive chronic granulomatous disease by means of transgenic PLB-985 cells

Chronic granulomatous disease (CGD) is a rare inherited disorder in which phagocytes lack NADPH oxidase activity. The most common form is caused by mutations in the CYBB gene encoding gp91phox protein, the heavy chain of cytochrome b₅₅₈, which is the redox element of NADPH oxidase. In some rare cases, the mutated gp91phox is normally expressed but no NADPH oxidase can be detected. This type of CGD is called X91⁺ CGD. We have previously reported an X⁺ CGD case with a double-missense mutation in gp91phox. Transgenic PLB-985 cells have now been made to study the impact of each single mutation on oxidase activity and assembly to rule out a possible new polymorphism in the CYBB gene. The His303Asn/Pro304Arg gp91phox transgenic PLB-985 cells exactly mimic the phenotype of the neutrophils of the X⁺ CGD patient. The His303Asn mutation is sufficient to inhibit oxidase activity in intact cells and in a broken cell system, whereas in the Pro304Arg mutant, residual activity suggests that the Pro304Arg substitution is less devastating to oxidase activity than the His303Asn mutation. The study of NADPH oxidase assembly following the in vitro and in vivo translocation of cytosolic factors p47phox and p67phox has demonstrated that, in the double mutant and in the His303Asn mutant, NADPH oxidase assembly is abolished, although the translocation is only attenuated in Pro304Arg mutant cells. Thus, even though the His303Asn mutation has a more severe inhibitory effect on NADPH oxidase activity and assembly than the Pro304Arg mutation, neither mutation can be considered as a polymorphism.Clara Bionda and Xing Jun Li contributed equally to this work     

Ethers and esters derived from apocynin avoid the interaction between p47phox and p22phox subunits of NADPH oxidase: evaluation in?vitro and in silico

NOX (NADPH oxidase) plays an important role during several pathologies because it produces the superoxide anion (O₂^•−), which reacts with NO (nitric oxide), diminishing its vasodilator effect. Although different isoforms of NOX are expressed in ECs (endothelial cells) of blood vessels, the NOX2 isoform has been considered the principal therapeutic target for vascular diseases because it can be up-regulated by inhibiting the interaction between its p47phox (cytosolic protein) and p22phox (transmembrane protein) subunits. In this research, two ethers, 4-(4-acetyl-2-methoxy-phenoxy)-acetic acid (1) and 4-(4-acetyl-2-methoxy-phenoxy)-butyric acid (2) and two esters, pentanedioic acid mono-(4-acetyl-2-methoxy-phenyl) ester (3) and heptanedioic acid mono-(4-acetyl-2-methoxy-phenyl) ester (4), which are apocynin derivatives were designed, synthesized and evaluated as NOX inhibitors by quantifying O₂^•− production using EPR (electron paramagnetic resonance) measurements. In addition, the antioxidant activity of apocynin and its derivatives were determined. A docking study was used to identify the interactions between the NOX2′s p47phox subunit and apocynin or its derivatives. The results showed that all of the compounds exhibit inhibitory activity on NOX, being 4 the best derivative. However, neither apocynin nor its derivatives were free radical scavengers. On the other hand, the in silico studies demonstrated that the apocynin and its derivatives were recognized by the polybasic SH3A and SH3B domains, which are regions of p47phox that interact with p22phox. Therefore this experimental and theoretical study suggests that compound 4 could prevent the formation of the complex between p47phox and p22phox without needing to be activated by MPO (myeloperoxidase), this being an advantage over apocynin.     

NADPH-oxidase activation and cognition in Alzheimer disease progression

Superoxide production via NADPH-oxidase (NOX) has been shown to play a role in a variety of neurological disorders, including Alzheimer disease (AD). To improve our understanding of the NOX system and cognitive impairment, we studied the various protein components of the phagocytic isoform (gp91^phox, or NOX2) in the frontal and temporal cortex of age- and postmortem-matched samples. Individuals underwent antemortem cognitive testing and postmortem histopathologic assessment to determine disease progression and assignment to one of the following groups: no cognitive impairment (NCI), preclinical AD, mild cognitive impairment (MCI), early AD, and mild-to-moderate AD. Biochemical methods were used to determine overall NOX activity as well as levels of the various subunits (gp91^phox, p67^phox, p47^phox, p40^phox, and p22^phox). Overall enzyme activity was significantly elevated in the MCI cohort in both cortical regions compared to the NCI cohort. This activity level remained elevated in the AD groups. Only the NOX cytosolic subunit proteins (p67^phox, p47^phox, and p40^phox ) were significantly elevated with disease progression; the membrane-bound subunits (gp91^phox and p22^phox) remained stable. In addition, there was a robust correlation between NOX activity and the individual's cognitive status such that as the enzyme activity increased, cognitive performance decreased. Collectively, these data show that upregulated NADPH-oxidase in frontal and temporal cortex suggests that increases in NOX-associated redox pathways might participate in early pathogenesis and contribute to AD progression.     

Molecular basis of phosphorylation-induced activation of the NADPH oxidase

The multi-subunit NADPH oxidase complex plays a crucial role in host defense against microbial infection through the production of reactive oxygen species. Activation of the NADPH oxidase requires the targeting of a cytoplasmic p40-p47-p67(phox) complex to the membrane bound heterodimeric p22-gp91(phox) flavocytochrome. This interaction is prevented in the resting state due to an auto-inhibited conformation of p47(phox). The X-ray structure of the auto-inhibited form of p47(phox) reveals that tandem SH3 domains function together to maintain the cytoplasmic complex in an inactive form. Further structural and biochemical data show that phosphorylation of p47(phox) activates a molecular switch that relieves the inhibitory intramolecular interaction. This permits p47(phox) to interact with the cytoplasmic tail of p22(phox) and initiate formation of the active, membrane bound enzyme complex.     

S-Nitrosylation of p47phox enhances phosphorylation by casein kinase 2

Abstract

Objectives: Leukocyte NADPH oxidase, which is active in neutrophils, is a membrane-bound enzyme that catalyzes the reduction of oxygen to O₂^? by using NADPH as an electron donor. Previously, we reported that casein kinase 2 (CK2), a ubiquitous and highly conserved Ser/Thr kinase, is responsible for p47^phox phosphorylation and that phosphorylation of p47^phox by CK2 regulates the deactivation of NADPH oxidase.

Methods: Here, we report that the residue Cys¹⁹⁶ of p47^phox is a target of S-nitrosylation by S-nitrosothiol and peroxynitrite and that this modification enhanced phosphorylation of p47^phox by CK2. Results: S-Nitrosylated p47^phox enhanced CK2 b subunit binding, presumably due to alterations in protein conformation.

Discussion: Taken together, we propose that S-nitrosylation of p47^phox regulates the deactivation of NADPH oxidase via enhancement of p47^phox phosphorylation by CK2     

A Prenylated p47phox-p67phox-Rac1 Chimera Is a Quintessential NADPH Oxidase Activator: MEMBRANE ASSOCIATION AND FUNCTIONAL CAPACITY*

The superoxide-generating NADPH oxidase complex of resting phagocytes includes cytochrome b₅₅₉, a membrane-associated heterodimer composed of two subunits (Nox2 and p22^phox), and four cytosolic proteins (p47^phox, p67^phox, Rac, and p40^phox). Upon stimulation, the cytosolic components translocate to the membrane, as the result of a series of interactions among the cytosolic components and among the cytosolic components and cytochrome b₅₅₉ and its phospholipid environment. We described the construction of a tripartite chimera (trimera) consisting of strategic domains of p47^phox, p67^phox, and Rac1, in which interactions among cytosolic components were replaced by fusion (Berdichevsky, Y., Mizrahi, A., Ugolev, Y., Molshanski-Mor, S., and Pick, E. (2007) J. Biol. Chem. 282, 22122–22139). We now fused green fluorescent protein (GFP) to the N terminus of the trimera and found the following. 1) The GFP-p47^phox-p67^phox-Rac1 trimera activates the oxidase in amphiphile-dependent and -independent (anionic phospholipid-enriched membrane) cell-free systems. 2) Geranylgeranylation of the GFP-trimera makes it a potent oxidase activator in unmodified (native) membranes and in the absence of amphiphile. 3) Prenylated GFP-trimera binds spontaneously to native membranes (as assessed by gel filtration and in-line fluorometry), forming a tight complex capable of NADPH-dependent, activator-independent superoxide production at rates similar to those measured in canonical cell-free systems. 4) Prenylation of the GFP-trimera supersedes completely the dependence of oxidase activation on the p47^phox phox homology domain and, partially, on the Rac1 polybasic domain, but the requirement for Trp¹⁹³ in p47^phox persists. Prenylated GFP-p47^phox-p67^phox-Rac1 trimera acts as a quintessential single molecule oxidase activator of potential use in high throughput screening of inhibitors.     

Phosphorylation of p22phox on Threonine 147 Enhances NADPH Oxidase Activity by Promoting p47phox Binding

NADPH oxidase comprises both cytosolic and membrane-bound subunits, which, when assembled and activated, initiate the transfer of electrons from NADPH to molecular oxygen to form superoxide. This activity, known as the respiratory burst, is extremely important in the innate immune response as indicated by the disorder chronic granulomatous disease. The regulation of this enzyme complex involves protein-protein and protein-lipid interactions as well as phosphorylation events. Previously, our laboratory demonstrated that the small membrane subunit of the oxidase complex, p22^phox, is phosphorylated in neutrophils and that its phosphorylation correlates with NADPH oxidase activity. In this study, we utilized site-directed mutagenesis in a Chinese hamster ovarian cell system to determine the phosphorylation sites within p22^phox. We also explored the mechanism by which p22^phox phosphorylation affects NADPH oxidase activity. We found that mutation of threonine 147 to alanine inhibited superoxide production in vivo by more than 70%. This mutation also blocked phosphorylation of p22^phox in vitro by both protein kinase C-α and -δ. Moreover, this mutation blocked the p22^phox-p47^phox interaction in intact cells. When phosphorylation was mimicked in vivo through mutation of Thr-147 to an aspartyl residue, NADPH oxidase activity was recovered, and the p22^phox-p47^phox interaction in the membrane was restored. Maturation of gp91^phox was not affected by the alanine mutation, and phosphorylation of the cytosolic component p47^phox still occurred. This study directly implicates threonine 147 of p22^phox as a critical residue for efficient NADPH oxidase complex formation and resultant enzyme activity.     

Consequences of the constitutive NOX2 activity in living cells: Cytosol acidification,apoptosis, and localized lipid peroxidation

The phagocyte NADPH oxidase (NOX2) is a key enzyme of the innate immune system generating superoxide anions (O₂^?-), precursors of reactive oxygen species. The NOX2 protein complex is composed of six subunits: two membrane proteins (gp91^phox and p22^phox) forming the catalytic core, three cytosolic proteins (p67^phox, p47^phox and p40^phox) and a small GTPase Rac. The sophisticated activation mechanism of the NADPH oxidase relies on the assembly of cytosolic subunits with the membrane-bound components. A chimeric protein, called ‘Trimera’, composed of the essential domains of the cytosolic proteins p47^phox (aa 1–286), p67^phox (aa 1–212) and full-length Rac1Q61L, enables a constitutive and robust NOX2 activity in cells without the need of any stimulus. We employed Trimera as a single activating protein of the phagocyte NADPH oxidase in living cells and examined the consequences on the cell physiology of this continuous and long-term NOX activity. We showed that the sustained high level of NOX activity causes acidification of the intracellular pH, triggers apoptosis and leads to local peroxidation of lipids in the membrane. These local damages to the membrane correlate with the strong tendency of the Trimera to clusterize in the plasma membrane observed by FRET-FLIM microscopy.     

Expression of components of the superoxide generating NADPH oxidase by human leucocytes and other cells

Summary NADPH oxidase of phagocytic leucocytes contains a membrane cytochromeb with two subunits, gp91 ^phox and p22 ^phox , together with three cytosolic proteins, p47 ^phox , p67 ^phox and p2 ^rac . The presence of some of these components has been sought in non-phagocytes, using Western blot analysis for protein expression and PCR to amplify and detect mRNA. All components were detected in EBV-transformed B lymphocytes and peripheral blood B lymphocytes. Fibroblasts and human kidney mesangial cells contained mRNA for p67 ^phox , p47 ^phox , and p22 ^phox but not gp91 ^phox . Levels of expression varied with growth conditions, but it appears possible than an isozyme of cytochromeb which lacks gp9 ^phox is present in these cells. Proteins of p47 ^phox and p67 ^phox were expressed, in low concentrations, in these two cell types. Expression of mRNA for p47 ^phox and p67 ^phox was found to be widespread in many cell types.Abbreviations IL-1 interleukin 1 - PMA phorbol myristate acetate - CGD chronic granulomatous disease - EBV-BL Epstein-Barr virus transformed B-lymphocytes - PBBL peripheral blood B lymphocytes     

A Fluorescently Tagged C-Terminal Fragment of p47phox Detects NADPH Oxidase Dynamics during Phagocytosis

The assembly of cytosolic p47^phox and p67^phox with flavocytochrome b₅₅₈ at the membrane is crucial for activating the leukocyte NADPH oxidase that generates superoxide for microbial killing. p47^phox and p67^phox are linked via a high-affinity, tail-to-tail interaction involving a proline-rich region (PRR) and a C-terminal SH3 domain (SH3b), respectively, in their C-termini. This interaction mediates p67^phox translocation in neutrophils, but is not required for oxidase activity in model systems. Here we examined phagocytosis-induced NADPH oxidase assembly, showing the sequential recruitment of YFP-tagged p67^phox to the phagosomal cup, and, after phagosome internalization, a probe for PI(3)P followed by a YFP-tagged fragment derived from the p47^phox PRR. This fragment was recruited in a flavocytochrome b₅₅₈-dependent, p67^phox-specific, and PI(3)P-independent manner. These findings indicate that p47PRR fragment probes the status of the p67^phox SH3b domain and suggest that the p47^phox/p67^phox tail-to-tail interaction is disrupted after oxidase assembly such that the p67^phox-SH3b domain becomes accessible. Superoxide generation was sustained within phagosomes, indicating that this change does not correlate with loss of enzyme activity. This study defines a sequence of events during phagocytosis-induced NADPH oxidase assembly and provides experimental evidence that intermolecular interactions within this complex are dynamic and modulated after assembly on phagosomes.     

Role of the phospholipid binding sites,PX of p47phox and PB region of Rac1, in the formation of the phagocyte NADPH oxidase complex NOX2

In phagocytes, superoxide anion (O₂⁻), the precursor of reactive oxygen species, is produced by the NADPH oxidase complex to kill pathogens. Phagocyte NADPH oxidase consists of the transmembrane cytochrome b₅₅₈ (cyt b₅₅₈) and four cytosolic components: p40^phox, p47^phox, p67^phox, and Rac1/2. The phagocyte activation by stimuli leads to activation of signal transduction pathways. This is followed by the translocation of cytosolic components to the membrane and their association with cyt b₅₅₈ to form the active enzyme.To investigate the roles of membrane-interacting domains of the cytosolic proteins in the NADPH oxidase complex assembly and activity, we used giant unilamellar phospholipid vesicles (GUV). We also used the neutrophil-like cell line PLB-985 to investigate these roles under physiological conditions. We confirmed that the isolated proteins must be activated to bind to the membrane. We showed that their membrane binding was strengthened by the presence of the other cytosolic partners, with a key role for p47^phox. We also used a fused chimera consisting of p47^phox(aa 1–286), p67^phox(aa 1–212) and Rac1Q61L, as well as mutated versions in the p47^phox PX domain and the Rac polybasic region (PB). We showed that these two domains have a crucial role in the trimera membrane-binding and in the trimera assembly to cyt b₅₅₈. They also have an impact on O₂.- production in vitro and in cellulo: the PX domain strongly binding to GUV made of a mix of polar lipids; and the PB region strongly binding to the plasma membrane of neutrophils and resting PLB-985 cells.     

Rac1-NADPH oxidase-regulated generation of reactive oxygen species mediates glutamate-induced apoptosis in SH-SY5Y human neuroblastoma cells

Reactive oxygen species (ROS) are known to play an important role in glutamate-induced neuronal cell death. In the present study, we examined whether NADPH oxidase serves as a source of ROS production and plays a role in glutamate-induced cell death in SH-SY5Y human neuroblastoma cells. Stimulation of the cells with glutamate (100 mM) induced apoptotic cell death and increase in the level of ROS, and these effects of glutamate were significantly suppressed by the inhibitors of the NADPH oxidase, diphenylene iodonium, apocynin, and neopterine. In addition, RT-PCR revealed that SH-SY5Y cells expressed mRNA of gp91^phox, p22^phox and cytosolic p47^phox, p67^phox and p40^phox, the components of the plasma membrane NADPH oxidase. Treatment with glutamate also resulted in activation and translocation of Rac1 to the plasma membrane. Moreover, the expression of Rac1N17, a dominant negative mutant of Rac1, significantly blocked the glutamate-induced ROS generation and cell death. Collectively, these results suggest that the plasma membrane-bound NADPH oxidase complex may play an essential role in the glutamate-induced apoptotic cell death through increased production of ROS.     

Regulation of the NADPH-oxidase complex of phagocytic leukocytes. Recent insights from structural biology,molecular genetics,and microscopy

The NADPH-oxidase complex is a multisubunit enzyme complex that catalyzes the formation of superoxide (O₂^–) by phagocytic leukocytes. This paper reviews some of the major advances in understanding the assembly and regulation of this enzyme system that have occurred during the past decade. For example, novel domains/motifs have been identified in p47-phox (PX and super SH3 domains) and p67-phox (tetratricopeptide repeat motifs). X-ray crystallography and NMR spectroscopy have provided detailed structural data on these domains and how p47-phox and p67-phox interact with p22-phox and activated Rac, respectively. Site-directed mutagenesis and knockout experiments have identified the critical phosphorylation sites in p47-phox, revealed an activation domain in p67-phox, and demonstrated that a specific pathway exists for activating Rac to participate in oxidase assembly/activation. Cytochemistry and immunofluorescence microscopy have provided new insights into the assembly of the oxidase and reveal a level of complexity not previously appreciated.John A. Badwey has recently died     

Identification of phosphorylation sites in the COOH‐terminal tail of the μ‐opioid receptor

Phosphorylation is considered a key event in the signalling and regulation of the μ opioid receptor (MOPr). Here, we used mass spectroscopy to determine the phosphorylation status of the C‐terminal tail of the rat MOPr expressed in human embryonic kidney 293 (HEK‐293) cells. Under basal conditions, MOPr is phosphorylated on Ser³⁶³ and Thr³⁷⁰, while in the presence of morphine or [D‐Ala2, NMe‐Phe4, Gly‐ol5]‐enkephalin (DAMGO), the COOH terminus is phosphorylated at three additional residues, Ser³⁵⁶, Thr³⁵⁷ and Ser³⁷⁵. Using N‐terminal glutathione S transferase (GST) fusion proteins of the cytoplasmic, C‐terminal tail of MOPr and point mutations of the same, we show that, in vitro, purified G protein‐coupled receptor kinase 2 (GRK2) phosphorylates Ser³⁷⁵, protein kinase C (PKC) phosphorylates Ser³⁶³, while CaMKII phosphorylates Thr³⁷⁰. Phosphorylation of the GST fusion protein of the C‐terminal tail of MOPr enhanced its ability to bind arrestin‐2 and ‐3. Hence, our study identifies both the basal and agonist‐stimulated phospho‐acceptor sites in the C‐terminal tail of MOPr, and suggests that the receptor is subject to phosphorylation and hence regulation by multiple protein kinases.