Assembly of dimeric myeloperoxidase during posttranslational maturation in human leukemic HL-60 cells

[Enzymatic and bactericidal activity of monomeric and dimeric forms of myeloperoxidase]

This study was carried out to compare the enzymatic and bactericidal activity of mature, dimeric myeloperoxidase (MPO) and its monomeric form. Dimeric MPO was isolated from HL-60 cells. Hemi-MPO obtained from dimeric MPO by reductive cleavage of a disulfide bond between protomeric subunits was used as the monomeric form. Both peroxidase and halogenating (chlorinating) activities of MPO were assayed, each of them by two methods. Bactericidal activity of the MPO/Н2О2/Cl- system was tested using the Escherichia coli laboratory strain DH5a. No difference in the enzymatic and bactericidal activity between dimeric MPO and hemi-MPO was found. Both forms of the enzyme also did not differ in the resistance to HOCl, the main product of MPO. HOCl caused a dose-dependent decrease in peroxidase and chlorinating activity, and the pattern of this decrease was identical for dimeric MPO and hemi-MPO. At equal heme concentration, a somewhat higher bactericidal effect was observed for the hemi-MPO/Н2О2/Cl- system compared with the dimeric MPO/Н2О2/Cl- system. However, this is most likely not related to some specific property of hemi-MPO and can be accounted for by the higher probability of contacting between bacterial surface and hemi-MPO molecules due to their two-fold greater number relative to that of dimeric MPO molecules at the same heme concentration. By using Western-blotting with antibodies to MPO, we showed, for the first time, that the dimeric molecule of MPO could be cleaved into two monomeric subunits by HOCl, most probably due to oxidation of the disulfide bond between these subunits. This finding suggests that appearance in blood of MPO corresponding in mass to its monomer may result from the damage of dimeric MPO by reactive halogen species, especially upon their overproduction underlying oxidative/halogenative stress in inflammatory diseases.

Biosynthesis of human myeloperoxidase

Members of Chordata peroxidase subfamily [1] expressed in mammals, including myeloperoxidase (MPO), eosinophil peroxidase (EPO), lactoperoxidase (LPO), and thyroid peroxidase (TPO), express conserved motifs around the heme prosthetic group essential for their activity, a calcium-binding site, and at least two covalent bonds linking the heme group to the protein backbone. Although most studies of the biosynthesis of these peroxidases have focused on MPO, many of the features described occur during biosynthesis of other members of the protein subfamily. Whereas MPO biosynthesis includes events typical for proteins generated in the secretory pathway, the importance and consequences of heme insertion are events uniquely associated with peroxidases. This Review summarizes decades of work elucidating specific steps in the biosynthetic pathway of human MPO. Discussion includes cotranslational glycosylation and subsequent modifications of the N-linked carbohydrate sidechains, contributions by molecular chaperones in the endoplasmic reticulum, cleavage of the propeptide from proMPO, and proteolytic processing of protomers and dimerization to yield mature MPO. Parallels between the biosynthesis of MPO and TPO as well as the impact of inherited mutations in the MPO gene on normal biosynthesis will be summarized. Lastly, specific gaps in our knowledge revealed by this review of our current understanding will be highlighted.

Structure of human promyeloperoxidase (proMPO) and the role of the propeptide in processing and maturation

Myeloperoxidase (MPO) is synthesized by neutrophil and monocyte precursor cells and contributes to host defense by mediating microbial killing. Although several steps in MPO biosynthesis and processing have been elucidated, many questions remained, such as the structure-function relationship of monomeric unprocessed proMPO versus the mature dimeric MPO and the functional role of the propeptide. Here we have presented the first and high resolution (at 1.25 Å) crystal structure of proMPO and its solution structure obtained by small-angle X-ray scattering. Promyeloperoxidase hosts five occupied glycosylation sites and six intrachain cystine bridges with Cys-158 of the very flexible N-terminal propeptide being covalently linked to Cys-319 and thereby hindering homodimerization. Furthermore, the structure revealed (i) the binding site of proMPO-processing proconvertase, (ii) the structural motif for subsequent cleavage to the heavy and light chains of mature MPO protomers, and (iii) three covalent bonds between heme and the protein. Studies of the mutants C158A, C319A, and C158A/C319A demonstrated significant differences from the wild-type protein, including diminished enzymatic activity and prevention of export to the Golgi due to prolonged association with the chaperone calnexin. These structural and functional findings provide novel insights into MPO biosynthesis and processing.

Proconvertase proteolytic processing of an enzymatically active myeloperoxidase precursor

Optimal and efficient killing of ingested microbes by human neutrophils is mediated in large part by the action of hypochlorous acid produced by the myeloperoxidase-H(2)O(2)-chloride system in phagosomes. Myeloperoxidase gene transcription is limited to early myeloid precursors in the bone marrow, when myeloperoxidase is synthesized and stored in azurophilic granules for subsequent release from stimulated neutrophils. Promyeloperoxidase, the 90 kDa myeloperoxidase precursor synthesized in the endoplasmic reticulum (ER), contains a 125-amino acid pro-region whose function and fate during myeloperoxidase biosynthesis are unknown. Promyeloperoxidase has two fates during myeloperoxidase biosynthesis; the majority undergoes proteolytic processing to generate mature myeloperoxidase, while the remainder is constitutively secreted from the cells in bone marrow. We used a promyelocytic cell line that produces endogenous myeloperoxidase as well as human embryonic kidney cells stably expressing normal and mutant forms of myeloperoxidase to examine proteolytic processing of promyeloperoxidase. We demonstrated that CMK-RVKR, an inhibitor of subtilisin-like proteinases, blocked cleavage of the pro-peptide of promyeloperoxidase in a post-ER compartment. Mutants with alanine substitution of basic residues in the predicted proteinase cleavage site failed to undergo maturation to normal myeloperoxidase subunits and were arrested at the promyeloperoxidase stage. Whereas specific mutants varied as to their stability, secreted promyeloperoxidase from the mutants retained the capacity to generate hypochlorous acid. Taken together, these studies demonstrate proconvertase-dependent cleavage of promyeloperoxidase as an essential step in normal proteolytic processing and granule targeting of myeloperoxidase. Furthermore, although mutations in the proteinase cleavage site reduced intracellular stability of the mutants, the integrity of the heme group was not compromised, as chlorinating activity was retained in the secreted promyeloperoxidase.

Myeloperoxidase and its contributory role in inflammatory vascular disease

Myeloperoxidase (MPO), a heme protein abundantly expressed in polymorphonuclear neutrophils (PMN), has long been viewed to function primarily as a bactericidal enzyme centrally linked to innate host defense. Recent observations now extend this perspective and suggest that MPO is profoundly involved in the regulation of cellular homeostasis and may play a central role in initiation and propagation of acute and chronic vascular inflammatory disease. For example, low levels of MPO-derived hypochlorous acid (HOCl) interfere with intracellular signaling events, MPO-dependent oxidation of lipoproteins modulates their affinity to macrophages and the vessel wall, MPO-mediated depletion of endothelial-derived nitric oxide (NO) impairs endothelium-dependent vasodilatation, and nitrotyrosine (NO(2)Tyr) formation by MPO sequestered into the vessel wall may affect matrix protein structure and function. Future studies are needed to further elucidate the significance of MPO in the development of acute and chronic vascular disease and to evaluate MPO as a potential target for treatment.

Cytochrome P450 CYP1A1 accumulates in the cytosol of kidney and brain and is activated by heme

Cytochrome P450 CYP1A1 is expressed in most tissues. In brain and kidney, its function remains unclear because its enzymatic activity is barely measurable. Here, we report on the localization of CYP1A1 in the cytosol of kidney and brain, as revealed by immunoblotting with anti-CYP1A1 antibodies and by 7-ethoxyresorufin deethylation (EROD). Hematin (8 microM) added in vitro to cytosol increased the EROD-activity 10-fold in brain olfactory bulb and 7-fold in kidney, presumably by reconstitution of apocytochrome. Succinylacetone, an inhibitor of heme biosynthesis, increased the ratio of cytosolic to microsomal EROD activity of transiently expressed CYP1A1 in COS-1 cells from 1:1 to nearly 6:1. This indicates a strong decrease of microsomal activity with increasing succinylacetone concentration. CYP1A1 activities correlated with CYP1A1 protein assessed by immunoblotting. We conclude that the availability of heme is a limiting factor of P450 function in extrahepatic tissue. Our data further suggest that reduced availability of heme limits the incorporation of P450s into brain endoplasmic reticulum. These observations are important when assessing the function of P450s in extrahepatic tissue.

Impact of missense mutations on biosynthesis of myeloperoxidase

We have examined the biosynthesis of normal and mutant forms of myeloperoxidase (MPO) in order to gain insights into the critical features of normal biogenesis of MPO. The expression of wild-type and mutant forms of MPO in a stably transfected cell line devoid of endogenous MPO as well as in established human promyelocytic cell lines has allowed understanding of several features of MPO biosynthesis. It is clear that heme insertion into apoproMPO is necessary for proper folding, egress from the endoplasmic reticulum (ER), and eventual entry into the maturation pathway. In addition, molecular chaperones calreticulin and calnexin interact with normal MPO precursors in a sequential and regulated fashion. Studies of naturally occurring mutants, specifically missense mutations underlying inherited MPO deficiency, and mutations in putatively important residues in MPO have highlighted special features of the ER quality control system in the context of MPO biosynthesis. With identification of additional genotypes of MPO deficiency and the recent solution of MPO crystal structure at 1.8 A, this approach provides a powerful technique to assess structure-function relationships in MPO that are likely applicable to other members of the family of animal peroxidases.

Immunochemical, 32P-postlabeling, and GC/MS detection of 4-aminobiphenyl-DNA adducts in human peripheral lung in relation to metabolic activation pathways involving pulmonary N-oxidation, conjugation, and peroxidation

4-Aminobiphenyl (ABP) is a recognized human bladder carcinogen, whose presence in cigarette smoke results in DNA adduct formation in the human urothelium. Since preliminary studies indicated that even higher levels of ABP-DNA adducts may be present in human peripheral lung, we utilized a sensitive immunochemical assay, in combination with 32P-postlabeling, to quantify the major 4-aminobiphenyl (ABP)-DNA adduct, N-(guan-8-yl)-ABP, in surgical samples of peripheral lung tissue from smokers and ex-smokers. No differences in adduct levels were detected between smokers and ex-smokers by immunoassay. In contrast, the 32P-postlabeling method showed statistically significant differences between adduct levels in smokers and ex-smokers; however, a relatively high background of smoking-related adducts chromatograph near the major ABP adducts and may compromise estimation of the level of ABP-DNA adducts in smokers. Furthermore, the levels measured by 32P-postlabeling were 20- to 60-fold lower than that measured by immunoassay. Since 32P-postlabeling may underestimate and immunochemical assays may overestimate adduct levels in the lung, selected samples were also evaluated by GC/MS. The immunochemical and GC/MS data were concordant, leading us to conclude that N-(guan-8-yl)-ABP adducts were not related to smoking status. Since ABP-DNA adduct levels in human lung did not correlate with smoking status as measured by immunoassay and GC/MS, the metabolic activation capacity of human lung microsomes and cytosols was examined to determine if another exposure (e.g., 4-nitrobiphenyl) might be responsible for the adduct. The rates of microsomal ABP N-oxidation were below the limit of detection, which was consistent with a lack of detectable cytochrome P4501A2 in human lung. N-Hydroxy-ABP O-acetyltransferase (but not sulfotransferase) activity was detected in cytosols and comparative measurements of N-acetyltransferase (NAT) using p-aminobenzoic acid and sulfamethazine indicated that NAT1 and NAT2 contributed to this activity. 4-Nitrobiphenyl reductase activity was found in lung microsomes and cytosols, with the reaction yielding ABP and N-hydroxy-ABP. Lung microsomes also demonstrated high peroxidative activation of ABP, benzidine, 4,4'-methylene-bis(2-chloroaniline), 2-aminofluorene, and 2-naphthylamine. The preferred co-oxidant was hydrogen peroxide and the reaction was strongly inhibited by sodium azide but not by indomethacin or eicosatetraynoic acid, which suggested the primary involvement of myeloperoxidase rather than prostaglandin H synthase or lipoxygenase. This was confirmed by immunoinhibition and immunoprecipitation studies using solubilized human lung microsomes and antisera specific for myeloperoxidase. These data suggest that ABP-DNA adducts in human lung result from some environmental exposure to 4-nitrobiphenyl. The bioactivation pathways appear to involve: (1) metabolic reduction to N-hydroxy-ABP and subsequent O-acetylation by NAT1 and/or NAT2; and (2) metabolic reduction to ABP and subsequent peroxidation by myeloperoxidase. The myeloperoxidase activity appears to be the highest peroxidase activity measured in mammalian tissue and is consistent with the presence of neutrophils and polymorphonuclear leukocytes surrounding particulate matter derived from cigarette smoking.

X-ray absorption and resonance raman spectroscopy of human myeloperoxidase at neutral and acid pH

Myeloperoxidase (MPO), an important enzyme in the oxygen-dependent host defense system of human polymorphonuclear leukocytes, utilizes hydrogen peroxide to catalyze the production of hypochlorous acid, an oxidizing bactericidal agent. While MPO shows significant sequence homology with other peroxidases and this homology is particularly striking among the active-site residues, MPO exhibits unusual spectral features and the unique ability to catalyze the oxidation of chloride ions. We have investigated the MPO active-site with X-ray absorption (XAS) and resonance Raman (RRS) spectroscopies at neutral pH and also at the physiological acidic pH (pH approximately 3) and have compared these results with those of horseradish peroxidase (HRP). At pH 7.5, XAS results show that the iron heme active site is 6-coordinate where the distal ligand is likely nitrogen or oxygen, but not sulfur. The heme is distorted compared to HRP, other peroxidases, and heme compounds, but at pH approximately 3, the distal ligand is lost and the heme is less distorted. RRS results under identical pH conditions show that the skeletal core-size sensitive modes and v3 are shifted to higher frequency at pH approximately 3 indicating a 6- to 5-coordination change of high spin ferric heme. In addition, a new band at 270 cm(-1) is observed at pH approximately 3 which is consistent with the loss of the sixth ligand. The higher symmetry of the heme at pH approximately 3 is reflected by a single v4 mode in the (RRS) spectrum. HRP also loses its loosely associated distal water at this pH, but little change in heme distortion is observed. This change suggests that loss of the distal ligand in MPO releases stress on the heme which may facilitate binding of chloride ion.

Uptake of recombinant myeloperoxidase, free or fused to Fc gamma, by macrophages enhances killing activity toward micro-organisms

A chimeric antibody-like molecule consisting of the human myeloperoxidase (rMPO) fused to the second and third constant-sequence (CH2 and CH3) Fc domains of human immunoglobulin G-1 has been constructed and expressed in Chinese hamster ovary (CHO) cells. This fusion molecule was designed to combine the binding specificity of Fc with the antimicrobial properties of rMPO. The rMPO-Fc fusion dimerized through the Fc fragment, while retaining the enzymatic activity of rMPO. The chimeric molecule was glycosylated and most of the propeptide was eliminated, indicating a better processing of the polypeptide than for rMPO alone. Both rMPO and rMPO-Fc bound to and were internalized by macrophage-like U937 promonocytic cells. Unexpectedly, the chimera failed to bind to the Fc receptor but interacted with a higher affinity than rMPO with the same binding sites. The presence of the Fc fragment in the chimera, in addition, did not extend the plasma half-life of the fusion protein. In vitro, rMPO-Fc exhibited a stronger killing effect than rMPO toward Candida albicans in the presence of either H202 alone or human macrophages. In vivo, rMPO-Fc similarly conferred a better protection than rMPO in a lethal model of murine cowdriosis. These properties could be related to the Fc-induced dimerization of the fusion protein in CHO cells.

Calreticulin functions as a molecular chaperone in the biosynthesis of myeloperoxidase

Myeloperoxidase (MPO), a lysosomal heme protein found exclusively in neutrophils and monocytes, is necessary for efficient oxygen-dependent microbicidal activity. Acquisition of heme by the heme-free MPO precursor apopro-MPO appears to be a prerequisite for its subsequent proteolytic processing and advancement along the biosynthetic pathway to mature MPO. We present data indicating that calreticulin (CRT), a high capacity calcium-binding protein residing in the lumen of the endoplasmic reticulum of a wide variety of cells, interacts specifically with fully glycosylated apopro-MPO. Biosynthetically radiolabeled CRT (60 kDa) and apopro-MPO (90 kDa) were coprecipitated from PLB 985 cells by monospecific antiserum against CRT when the immunoprecipitations were performed either under nondenaturing conditions or following reversible crosslinking. Nonglycosylated MPO precursors synthesized in the presence of tunicamycin did not interact with CRT. The CRT-apopro-MPO interaction was restricted to an early phase of MPO biosynthesis, and CRT did not interact with the later appearing, heme-containing species of MPO, i.e. pro-MPO or the heavy subunit of mature MPO. These data show that CRT participates in the post-translational processing of MPO, perhaps by maintaining apopro-MPO in a conformation competent to accommodate insertion of the heme group. In this general way, CRT shares certain functional properties with the structurally homologous transmembrane calcium-binding endoplasmic reticulum protein calnexin. Both interact with glycosylated biosynthetic precursors of proteins selectively expressed in specialized cells.

Myeloperoxidase gene expression in normal granulopoiesis and acute leukemias

Myeloperoxidase (MPO) is an abundant heme protein found in granulocytes and monocytes, which plays an important role in host defense against infection. MPO enzyme activity as determined by light microscopic cytochemistry has long been an important marker used in the diagnosis of acute leukemias and other hematopoietic disorders. Recently, MPO expression has been studied at the electron microscopic level, and monoclonal antibodies (mAbs) against MPO protein have been developed. Furthermore, techniques and probes for analysing MPO expression at the RNA level are now available. This has made possible more extensive studies of MPO expression in a wide range of neoplastic and preneoplastic blood disorders. This review will discuss the fundamental biology of MPO as well as recent developments in our understanding of MPO expression in leukemic cells and cell lines of various lineages.

Expression of recombinant myeloperoxidase using a baculovirus expression system

Myeloperoxidase (MPO) is a glycosylated heme-containing enzyme present in the azurophilic granules of normal human polymorphonuclear neutrophils. This enzyme plays a major role in the microbicidal activity of the host defense system by catalyzing the formation of the potent oxidant, hypochlorous acid. Although the amino acid sequence of MPO has been deduced from the cDNA, the structural basis for the observed heterogeneity of this enzyme is not known. Furthermore, the nature of the prosthetic group and its mode of linkage to the apoprotein has not been determined. To address questions regarding the structural features of MPO, which arise during the complex posttranslational processing of this enzyme, we utilized a baculovirus system to express MPO in Sf9 insect cells. Two glycosylated, single-chain precursor species of MPO were observed: an 84 kDa species that was secreted and a 74 kDa species that was cell-associated. This is the first report of an expression system in which a cell-associated MPO precursor undergoes posttranslational proteolytic processing.

Human hemi-myeloperoxidase. Initial chlorinating activity at neutral pH, compound II and III formation, and stability towards hypochlorous acid and high temperature

Human neutrophilic myeloperoxidase (MPO) is involved in the defence mechanism of the body against micro-organisms. The enzyme catalyses the generation of the strong oxidant hypochlorous acid (HOCl) from hydrogen peroxide and chloride ions. In normal neutrophils MPO is present in the dimeric form (140 kDa). The disulphide-linked protomers each consist of a heavy subunit and a light one. Reductive alkylation converts the dimeric enzyme into two promoters, 'hemi-myeloperoxidase'. We studied the initial activities of human dimeric MPO and hemi-MPO at the physiological pH of 7.2 and found no significant differences in chlorinating activity. These results indicate that, at least at neutral pH, the protomers of MPO function independently. The absorption spectra of MPO compounds II and III, both inactive forms concerning HOCl generation, and the rate constants of their formation were the same for dimeric MPO and hemi-MPO, but hemi-MPO required a slightly larger excess of H2O2 for complete conversion. Hemi-MPO was less stable at a high temperature (80 degrees C) as compared to the dimeric enzyme. Furthermore, the resistance of the chlorinating activity of hemi-MPO against its oxidative product hypochlorous acid was somewhat lower (IC50 = 32 microM HOCl) compared to dimeric MPO (IC50 = 50 microM HOCl). The higher stability of dimeric MPO in the presence of its oxidative product compared to that of monomeric MPO might be the reason for the occurrence of MPO as a dimer.

Structural and biological properties of human recombinant myeloperoxidase produced by Chinese hamster ovary cell lines

The cDNA encoding human myeloperoxidase carries three ATG codons in frame; 144, 111 and 66 bp upstream from the proprotein DNA sequence. In order to determine the most efficient signal sequence, three cDNA modules starting at each of the ATG were cloned into an eucaryotic expression vector and stably expressed in Chinese hamster ovary cell lines. In all three cases, recombinant human myeloperoxidase (recMPO) was secreted into the culture medium of transfected cells, indicating that each of the signal peptides functions efficiently. One of the recombinant cell lines, which was amplified using methotrexate, overexpresses enzymatically active recMPO up to 6 micrograms.ml-1.day-1. The recombinant product was purified by a combination of ion-exchange and metal-chelate chromatography, and characterized in terms of molecular mass, amino-terminal amino acid analysis, glycosylation, physicochemical properties and biological activity. The data show that recMPO is secreted essentially as a monomeric, heme-containing, single-chain precursor of 84 kDa which exhibits peroxidase activity. Amino-terminal analysis indicated that cleavage of the signal peptide occurs between amino acids 48 and 49. In addition, recMPO appeared to be glycosylated up to the last stage of sialylation, to an extent similar to that of the natural enzyme. Specific activity measurements as well as stability data, in various pH, temperature, ionic strength and reducing conditions, indicated that the recombinant single-chain enzyme behaves essentially in the same way as the natural two-chain molecule. Finally, recMPO was shown to exert potent cytotoxicity towards Escherichia coli when provided with its physiological substrates, i.e. hydrogen peroxide and chloride ions.