Biosynthesis, transport and processing of myeloperoxidase in the human leukaemic promyelocytic cell line HL-60 and normal marrow cells.

The processing and intracellular transport of myeloperoxidase were studied in the human promyelocytic leukaemia cell line HL-60 and in normal marrow cells labelled with [35S]methionine or [14C]leucine. Myeloperoxidase was precipitated with antimyeloperoxidase serum; the immunoprecipitates were subjected to sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and radiolabelled myeloperoxidase visualized by fluorography. During a 1 h pulse, myeloperoxidase was labelled in a chain of apparent Mr 90 000. With a subsequent chase, the Mr 90 000 polypeptide disappeared and was replaced by chains of Mr 62 000 and 12 400 corresponding roughly to the size of neutrophil myeloperoxidase subunits. The identification of the radioactive polypeptides as different forms of myeloperoxidase was established also by the similarity in patterns generated by partial proteolysis with V8 proteinase from Staphylococcus aureus. Processing of myeloperoxidase in HL-60 was slow; mature polypeptides were significantly increased only after 6 h. Another myeloperoxidase chain of apparent Mr 82 000 was an intermediate precursor or degradation form. Pulse-chase experiments in combination with sucrose-density-gradient separations of homogenates showed that the Mr 90 000 precursor was located in light density organelles only and not in granule fractions, whereas the Mr 82 000 precursor was located only in intermediate density organelles, suggesting that the latter is a product of the former. Processed mature myeloperoxidase was concentrated in the granule fraction, but some occurred in lower density organelles, which may indicate processing during intracellular transport. Only the Mr 90 000 polypeptide was secreted into the culture medium; this was also the only form found in the cytosol fraction.     

Preferential localisation of elastase in cytosol of human myeloid leukemia HL-60 cells.

The subcellular distribution of the elastase in human myeloid leukemia HL-60 cells was studied in comparison with that in normal leukocytes. On differential centrifugation, most of the elastase activity of HL-60 cell lysates was recovered in the 105,000 x g supernatant, while that of human peripheral blood leukocyte lysates was recovered in the 500 x g precipitate (azurophil granule-rich fraction). Moreover, on Percoll density gradient centrifugation, the elastase activity in HL-60 cell extracts was recovered in the lightest fraction with none in the azurophil granule-rich fractions, whereas most of the activity in leukocyte extracts was recovered in the azurophil granule-rich fractions. This subcellular localization of elastase did not change when HL-60 cells differentiated into monocytes and granulocytes by induction with 12-O-tetradecanoyl phorbol-13-acetate and retinoic acid, respectively. Furthermore, on Sephadex G-75 gel filtration, the elastase activity in HL-60 cell extracts was eluted earlier than that in leukocyte extracts. The size estimation indicated that the elastase of HL-60 cells was 36-30 kDa, corresponding to the size of an elastase precursor reported. The relevance of a large form of the elastase in HL-60 cells to its subcellular localization is discussed.     

Evidence for the involvement of an acidic compartment in the processing of myeloperoxidase in human promyelocytic leukemia HL-60 cells

The observation that myeloperoxidase precursor and larger intermediate (Mr 91,000 and 81,000, respectively) were extracted in the presence of detergent from isolated granule fractions of human promyelocytic leukemia HL-60 cells under mildly acidic conditions was investigated. In contrast, under conditions of neutral pH, only the Mr 74,000 intermediate and mature species were extracted. Extraction of the Mr 91,000 and 81,000 forms was also enhanced in the presence of EDTA. Kinetic studies of the processing of the different myeloperoxidase species confirmed the intermediate nature of the Mr 81,000 and 74,000 forms. Support for a role of an acidic intracellular compartment was obtained through evidence that the acid-extractable precursor and intermediates accumulated in HL-60 cells which had been treated with 1 microM monensin. Under these conditions, the production of mature heavy (Mr 63,000) and light (Mr 13,500) subunits of myeloperoxidase was consistently inhibited by greater than 40% over a 16-h period. The effects of monensin on processing of myeloperoxidase were completely reversed if monensin was removed during this 16-h period. These data support the idea that an acidic compartment may be involved in the transport of myeloperoxidase precursors to azurophil granules and/or their processing to a smaller intermediate form (Mr 74,000) of the enzyme.     

Selective cytotoxicity of 3-amino-l-tyrosine correlates with peroxidase activity

Summary In the presence of 3-amino-l-tyrosine (3-AT), abundant brown pigment forms in human HL-60 cells, but not in a variety of other cell lines, which are reported to be lower in mean myeloperoxidase (MPO) content than HL-60. Cells were assessed for peroxidase activity with an ABTS-based colorimetric assay and compared to values obtained with known amounts of human myeloperoxidase. HL-60 cells were estimated to contain the equivalent of 37.1 ng myeloperoxidase/10⁶ cells versus 26.1 and 5.0 ng/10⁶ cells for human K562 and murine RAW 264.7 cell lines, respectively. HL-60 cells exhibited a nearly 60% inhibition of proliferation and >70% reduction in cell viability after 4 d of culture in the presence of 100 μg 3-AT per ml. Higher concentrations of 3-AT (up to 400 μg/ml) for 4 d reduced HL-60 proliferation by 80% and decreased viability to 1–3%. Comparable levels of cytotoxicity were achieved in KG-1 cells after 7 d with 200 or 400 μg 3-AT per ml. K562 cells exhibited a 40% reduction in cell number after 7 d with 400 μg 3-AT per ml, but concentrations less than 400 μg/ml did not significantly affect K562 proliferation. K562 viability remained unchanged with doses of 3-AT up to 400 μg/ml. RAW 264.7 cells exhibited unchanged viability and proliferation in the presence of 3-AT at concentrations up to 400 μg 3-AT per ml. K562, KG-1, and RAW 264.7 cells exhibited no evidence of brown pigment formation in the presence of 3-AT and medium containing 10% fetal bovine serum. However, RAW 264.7 cells that were converted to protein-free medium and exposed to 3-AT exhibited intense brown pigment in some cell nuclei. A high percentage of HL-60 cells treated with 3-AT exhibited membrane blebbing, pyknosis, and nuclear fragmentation, which was not observed among other 3-AT-treated cell lines. A mechanism involving toxic intermediates of peroxidase-mediated “aminomelanin” formation is hypothesized.     

Long-term bovine hematopoietic engraftment with clone-derived stem cells

Therapeutic cloning by somatic cell nuclear transfer offers potential for treatment of a wide range of degenerative disease. Nuclear transplantation with neo (r)-marked somatic nuclei from 10-13-year-old cows was used to generate cloned bovine fetuses. Clone fetal liver (FL) hematopoietic stem cells (HSC) were transplanted into two busulfan-treated and one untreated nuclear donor cows. Hematopoiesis was monitored over 13-16 months by in vitro progenitor and HSC assays. Chimerism was demonstrated by PCR in blood, marrow, lymph nodes, and endothelium, peaking at levels of 9-17% in blood granulocytes but at lower levels in lymphocyte subsets (0.1-0.01%). Circulating progenitors showed high levels of chimerism (up to 60% neo (r+)) with persisting fetal features. At sacrifice, the animal that had no pre-transplant myelosupression showed persisting donor cells in blood and lymph nodes, and in marrow 0.25% of progenitor cells and a detectable fraction of stem cells were neo (r+). The fetal HSC showed a 10-fold competition advantage over adult HSC. Cloning generated histocompatible HSC capable of long-term multilineage engraftment in a large animal model.     

Isolation and characterization of an unprocessed extracellular myeloperoxidase in HL-60 cell cultures

Extracellular myeloperoxidase of human myeloid leukemia HL-60 cells was purified to homogeneity from its culture supernatant by ammonium sulfate fractionation, CM-Sepharose column chromatography, and monoclonal antibody-Sepharose affinity column chromatography. The yield of enzyme activity was 38% that of the ammonium sulfate fraction. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the purified preparation gave a single band of approximately 84 kDa. Analysis of protein blot with antibodies specific for the light and heavy chains of myeloperoxidase indicated that the enzyme contained a light and a heavy chain in a single polypeptide. The amino-terminal amino acid sequence of the enzyme began at amino acid residue 155 of the 745-amino acid sequence predicted from myeloperoxidase cDNA, indicating that the enzyme consisted of 591 amino acids. Sucrose density gradient centrifugation of the enzyme showed that the enzyme was a monomeric form. In pulse-chase experiments on HL-60 cells with [35S]methionine, pulse-labeled myeloperoxidase precursors were shown to be processed to a light chain and a heavy chain of cellular enzyme. During a 3-day chase period, newly formed processed monomeric enzyme was converted to a dimeric form.     

Differences in distribution of ribonuclease isoenzymes in cytosol and granules in normal human granulocytes and in granulocytes of patients with chronic granulocytic leukemia (CGL)

Distribution of ribonuclease (RNAase), acid phosphatase (acid Ph-ase) and beta glucuronidase (BGU) between the granule, cytosol-soluble and post-granule fractions in normal human granulocytes and in granulocytes of chronic granulocytic leukemia (CGL) was studied. CGL granulocytes were found to display relative RNAase activity 1.2 times higher, relative acid Ph-ase activity 2.5 times higher than normal granulocytes. The granule fraction of CGL granulocytes showed 1.4 times higher relative RNAase activity but 0.87 times lower acid Ph-ase activity and the same BGU activity as normal granulocytes. On the other hand, the supernatant soluble fraction of CGL granulocytes showed 4.4 times higher relative RNAase activity, 1.2 times higher relative acid Ph-ase activity and BGU 2.2 times higher than in cytosol soluble fraction of normal granulocytes. Thus, cytosol soluble fraction of CGL granulocytes show a relative activity of the lysosomal enzymes studied which is remarkably higher than in normal granulocytes. The percentage distribution of RNAase, acid Ph-ase and BGU showed that CGL granulocytes contain only 36% of total RNAase activity versus 46% of that in normal ones. On the other hand, CGL granulocytes in cytosol soluble fraction will contain 48% of total RNAase versus 29% of total RNAase in cytosol of normal granulocytes. The isoenzyme profiles of RNAase of granule fractions were similar in normal and CGL granulocytes, while the RNAase isoenzyme profiles of cytosol fractions were different for normal and CGL granulocytes, indicating that some essential part of CGL granulocyte cytosol RNAase differs from RNAase contained in granules and in cytosol of normal granulocytes.     

The secretory granule protein syncollin localizes to HL-60 cells and neutrophils.

The secretory granule protein syncollin was first identified in the exocrine pancreas where a population of the protein is associated with the luminal surface of the zymogen granule membrane. In this study we provide first morphological and biochemical evidence that, in addition to its pancreatic localization, syncollin is also present in neutrophilic granulocytes of rat and human origin. By immunohistological studies, syncollin was detected in neutrophilic granulocytes of the spleen. Furthermore, syncollin is expressed by the promyelocytic HL-60 cells, where it is stored in azurophilic granules and in a vesicular compartment. These findings were confirmed by fractionation experiments and immunoelectron microscopy. Treatment with a phorbol ester triggered the release of syncollin indicating that in HL-60 cells it is a secretory protein that can be mobilized upon stimulation. A putative role for syncollin in host defense is discussed.     

Evading apoptosis by calcitriol-differentiated human leukemic HL-60 cells is not mediated by changes in CD95 receptor system but by increased sensitivity of these cells to insulin

Previous studies revealed that 1,25-dihydroxyvitamin D(3) (calcitriol)-induced differentiation of human promyelocytic leukemia cells leads to an increased resistance of the cells to apoptosis-inducing agents. However many attempts were made to explain it, the mechanism underlying this effect still remains unclear. Our results suggest that the acquired resistance to apoptosis-inducing agents in HL-60 cells is not mediated by the CD95 receptor/ligand system. The expression of CD95 on the surface of HL-60 cells is very low and does not change during the calcitriol-induced differentiation of HL-60 cells. Studies presented here provide a strong indication that this receptor is unable to transmit the death signal in either differentiated or undifferentiated HL-60 cells. We therefore asked if evading apoptosis by differentiated human leukemia HL-60 cells may be caused by their increased sensitivity to growth factors contained in fetal calf serum. This study demonstrates that HL-60 promyelocytic leukemia cells, differentiated by exposure to calcitriol, undergo apoptosis in serum-free conditions. As low as 1% of fetal calf serum is enough to prevent cell death of differentiated HL-60 cells. The ability of 1% fetal calf serum to prevent apoptosis can be blocked by the specific inhibitor of phosphatidylinositol 3-kinase, LY294002. We then tried to find out which component of fetal calf serum may be able to prevent serum-free cell death of differentiated cells. It appeared that serum-free cell death of differentiated HL-60 cells is reversed by addition of 10 microM insulin to the culture medium. The antiapoptotic activity of insulin can be inhibited by LY294002. Moreover, insulin increases the viability of differentiated, but not of undifferentiated, HL-60 cells.     

Rab27a is a key component of the secretory machinery of azurophilic granules in granulocytes

Neutrophils kill micro-organisms using microbicidal products that they release into the phagosome or into the extracellular space. The secretory machinery utilized by neutrophils is poorly characterized. We show that the small GTPase Rab27a is an essential component of the secretory machinery of azurophilic granules in granulocytes. Rab27a-deficient mice have impaired secretion of MPO (myeloperoxidase) into the plasma in response to lipopolysaccharide. Cell fractionation analysis revealed that Rab27a and the Rab27a effector protein JFC1/Slp1 (synaptotagmin-like protein 1) are distributed principally in the low-density fraction containing a minor population of MPO-containing granules. By immunofluorescence microscopy, we detected Rab27a and JFC1/Slp1 in a minor subpopulation of MPO-containing granules. Interference with the JFC1/Slp1-Rab27a secretory machinery impaired secretion of MPO in permeabilized neutrophils. The expression of Rab27a was dramatically increased when promyelocytic HL-60 cells were differentiated into granulocytes but not when they were differentiated into monocytes. Down-regulation of Rab27a in HL-60 cells by RNA interference did not affect JFC1/Slp1 expression but significantly decreased the secretion of MPO. Neither Rab27a nor JFC1/Slp1 was integrated into the phagolysosome membrane during phagocytosis. Neutrophils from Rab27a-deficient mice efficiently phagocytose zymosan opsonized particles and deliver MPO to the phagosome. We conclude that Rab27a and JFC1/Slp1 permit MPO release into the surrounding milieu and constitute key components of the secretory machinery of azurophilic granules in granulocytes. Our results suggest that the granules implicated in cargo release towards the surrounding milieu are molecularly and mechanistically different from those involved in their release towards the phagolysosome.     

Ascorbate free radical and its role in growth control

Summary Ascorbate and its free radical potentiates proliferation of HL-60 cells in serum-limiting media. Dehydroascorbate does not affect growth. This stimulation of growth is due to a general shortening of the cell cycle. The incubation of HL-60 cells with ascorbate free radical produces a significant change of the redox potential of cells. The presence of cells in culture media avoids the total oxidation of ascorbate, and also HL-60 cells induce the short-term stabilization of ascorbate. Ascorbate free radical potentiates also the onset of DNA synthesis in CCL39 cells induced by fetal calf serum, although itself does not affect quiescense to proliferation transition. This transition induced by fetal calf serum also potentiates the capacity of CCL39 cells to stabilize ascorbate. We discuss here the role of ascorbate free radical on growth control by its reduction by the plasma membrane redox system and its meaning for cell physioslogy.     

Suppression of ethanolamine-containing glycerophospholipid synthesis in HL-60 cells during retinoic acid-induced differentiation.

Synthesis and degradation of glycerophospholipids in HL-60 cells and retinoic acid (RA)-treated HL-60 cells were examined. The synthesis of each subclass of ethanolamine-containing glycerophospholipids was extremely suppressed in RA-treated HL-60 cells, while that of other glycerophospholipids was not seriously affected. A pulse-chase experiment revealed that about 88% of 1,2-diacyl and 28% of 1-alkenyl-2-acyl glycerophosphoethanolamine were degraded during 4 days in RA-treated HL-60 cells. These characteristics of metabolism observed in RA-treated HL-60 cells might be responsible for the change of subclass composition of ethanolamine-containing glycerophospholipids in HL-60 cells during differentiation to granulocytes.     

Expression of catalase and myeloperoxidase genes in hydrogen peroxide-resistant HL-60 cells.

We studied the expression of catalase and myeloperoxidase genes in the hydrogen peroxide-resistant variants of human myeloid leukemia HL-60 cells HP50-2 and HP100-1. Southern blot hybridization with catalase and myeloperoxidase cDNA probes indicated that the copy number of the catalase gene in HP50-2 and HP100-1 cells was two and eight times, respectively, higher than that in HL-60 cells, whereas the copy number of the myeloperoxidase gene was the same. The amplified catalase and c-myc genes in HP100-1 cells were not decreased by treatment of the cells with inhibitors of poly(ADP-Ribose) polymerase, such as nicotinamide and benzamide. RNA blot hybridization with cDNA probes indicated that the content of catalase mRNA in HP50-2 and HP100-1 cells was four and 16 times higher, respectively, than that in HL-60 cells. By contrast, the content of myeloperoxidase mRNA in HP50-2 and HP100-1 cells was only a few percent of that in HL-60 cells. Furthermore, fluorescent in situ hybridization of a catalase cDNA probe to chromosomes indicated that the catalase gene in HP100-1 was amplified in the p13 region of a derivative chromosome 11. These results indicate that the increased synthesis of catalase in these resistant cells is mainly due to increased expression of the catalase gene, and that the lack of myeloperoxidase synthesis in these cells is due to the absence of its mRNA.     

The effect of glutathione on HL-60 treated with dimethylsulfoxide,butyric acid or 12-O-tetradecanoylphorbol-13-acetate

HL-60 promyelocytic leukemic cells can be induced to differentiate into granulocytes or macrophages. Reduced glutathione lyses undifferentiated HL-60 cells but has minimal effect on their differentiated counterparts. The addition of reduced glutathione to HL-60 promyelocytic leukemic cells retards cell growth and lyses cells. HL-60 cells can be induced to differentiate into granulocytes with dimethylsulfoxide butyric acid or into macrophages with 12-O-tetradecanoylphorbol-13-acetate. After treatment of HL-60 cells with these inducing agents the HL-60 cells become unresponsive to the effects of glutathione.     

Induction of the differentiation of HL-60 promyelocytic leukemia cells by L-ascorbic acid

The present study was undertaken to examine the effect of L-ascorbic acid (LAA) on the growth of HL-60 promyelocytic leukemia cells, besides induction of apoptosis. LAA (> or = 10(-4) M) was found to markedly inhibit the proliferation of HL-60 in liquid culture and clonogenicity in semisolid culture. Moreover, LAA-treated HL-60 showed activity to produce chemiluminescence and expressed CD 66b cell surface antigens, indicating that LAA induces the differentiation of HL-60 mainly into granulocytes. The results are supported by morphological changes of LAA-treated HL-60 into segmented neutrophils. Therefore, the inhibitory effect of LAA on the growth of HL-60 cells seems to arise from the induction of differentiation. To assess the potential role of LAA, cells were exposed to oxygen radical scavengers in the absence or presence of LAA. Catalase abolished and superoxide dismutase promoted LAA-induced differentiation of HL-60. Thus, H2O2 produced as a result of LAA treatment seems to play a major role in induction of HL-60 differentiation.     

Large-scale purification of myeloperoxidase from HL60 promyelocytic cells: characterization and comparison to human neutrophil myeloperoxidase

A large-scale purification procedure was developed for the isolation of myeloperoxidase from HL60 promyelocytic cells in culture. Initial studies showed the bulk of peroxidase-positive myeloperoxidase activity to be located in the cetyltrimethylammonium bromide solubilized particulate fraction of cell homogenates. The myeloperoxidase was then chromatographically purified using concanavalin A followed by gel filtration. SDS-PAGE analysis of the final preparation showed the presence of only two proteins with molecular masses of approximately 55 and 15 kDa, corresponding to the large and small subunits of myeloperoxidase. These data, along with Reinheit Zahl (RZ) values (A(430)/A(280)) of greater than or equal to 0.72, indicate that the myeloperoxidase prepared by this method is apparently homogeneous. Preparations routinely yielded 12-20 mg of pure myeloperoxidase per 10 ml of cell pellet. The HL60 myeloperoxidase was shown to be indistinguishable from purified human neutrophil myeloperoxidase by size exclusion chromatography, analytical ultracentrifugation, SDS-PAGE, Western blot, and NH(2)-terminal sequence analysis. The activities of the two myeloperoxidase samples, as measured using either the tetramethylbenzidine or the taurine chloramine assay, were indistinguishable. Finally, both enzymes responded identically to dapsone and aminobenzoic acid hydrazide, known inhibitors of myeloperoxidase. A protocol is presented here for the rapid, large-scale purification of myeloperoxidase from cultured HL60 cells, as well as evidence for the interchangeability of this myeloperoxidase and that purified from human neutrophils.     

Characterization of the formyl peptide chemotactic receptor appearing at the phagocytic cell surface after exposure to phorbol myristate acetate

We examined the biochemistry and subcellular source of new formyl peptide chemotactic receptor appearing at the human neutrophil and differentiated HL-60 (d-HL-60) cell surface after stimulation with phorbol myristate acetate (PMA). Formyl peptide receptor was analyzed by affinity labeling with formyl-norleu-leu-phe-norleu-[125I]iodotyr-lys and ethylene glycol bis(succinimidyl succinate) followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and densitometric analysis of autoradiographs. PMA, a specific granule secretagogue, increases affinity labeling of formyl peptide receptors on the neutrophil surface by 100%, and on d-HL-60, which lack specific granule markers, by 20%. Papain treatment markedly reduces surface labeling of formyl peptide receptor in both neutrophils and d-HL-60, and results in the appearance of a lower m.w. membrane-bound receptor fragment. PMA stimulation of papain-treated cells increases uncleaved surface receptor on neutrophils by 400%, and on d-HL-60 by only 45%. This newly appearing receptor is the same apparent m.w. (55,000 to 75,000 for neutrophils; 62,000 to 80,000 for d-HL-60) and yields the same papain cleavage product (Mr, 31,000 for neutrophils; Mr, 29,000 for d-HL-60) as receptor on the surface of unstimulated cells. Formyl peptide receptor detected by affinity labeling in neutrophil specific granule-enriched subcellular fractions is identical to receptor found on the surface of unstimulated cells appearing as equal amounts of two isoelectric forms (isoelectric points, 5.8 and 6.2) at Mr 55,000 to 70,000. There is twice as much receptor present in the specific granule-enriched fraction per cell equivalent compared with plasma membrane. Azurophil granules contain trace amounts of receptor. Similar analysis of neutrophils treated with papain before subcellular fractionation shows that papain cleaved receptor fragment is detectable almost exclusively in the plasma membrane-enriched fraction. Most of the affinity-labeled formyl peptide receptor present in specific granule enriched fraction is present in membranes other than plasma membrane or Golgi membrane, because specific granule-enriched fraction contains only a small amount of plasma membrane marker and an amount of Golgi membrane marker equal to that found in plasma membrane-enriched fraction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Development of specific functionally active receptors for platelet-activating factor in HL-60 cells following granulocytic differentiation

A human promyelocytic leukemia cell line (undifferentiated HL-60 cells) as well as a granulocyte form of HL-60 cells induced in vitro by exposure to dimethyl sulfoxide were examined for binding, metabolism, and biological responses to platelet-activating factor (PAF). Undifferentiated and differentiated HL-60 cells each exhibit a high capacity to incorporate and metabolize [3H]PAF at 37 degrees C; however, the amount of [3H]PAF that is assimilated by both cell populations is greatly reduced and its metabolism abolished at less than or equal to 4 degrees C. At 0 degrees C HL-60 granulocytes bind more [3H]PAF than their undifferentiated counterparts. Binding to differentiated cells reaches equilibrium within 80 min and is saturable, reversible and specific; PAF receptor antagonists WEB 2086, L-659,989, BN 52021, and kadsurenone abolish this specific [3H]PAF binding. In contrast, [3H]PAF uptake by undifferentiated HL-60 cells is neither saturable nor sensitive to specific receptor antagonists. Scatchard analyses reveal 5850 +/- 850 binding sites per differentiated HL-60 cell with a dissociation constant of 0.66 +/- 0.15 nM. In the presence of cytochalasin B, PAF (200 nM) induces degranulation only in differentiated cells and this response also is blocked by PAF receptor antagonists. Our results demonstrate that HL-60 cells develop specific and functionally active PAF receptors only after chemically induced differentiation into granulocytes.