Fine structural features of eosinophile granulocyte development in human bone marrow. Evidence for granule secretion

Mitochondrial Population in Mouse Eosinophils: Ultrastructural Dynamics in Cell Differentiation and Inflammatory Diseases

Mitochondria are multifunctional organelles of which ultrastructure is tightly linked to cell physiology. Accumulating evidence shows that mitochondrial remodeling has an impact on immune responses, but our current understanding of the mitochondrial architecture, interactions, and morphological changes in immune cells, mainly in eosinophils, is still poorly known. Here, we applied transmission electron microscopy (TEM), single-cell imaging analysis, and electron tomography, a technique that provides three-dimensional (3D) views at high resolution, to investigate mitochondrial dynamics in mouse eosinophils developing in cultures as well as in the context of inflammatory diseases characterized by recruitment and activation of these cells (mouse models of asthma, H1N1 influenza A virus (IAV) infection, and schistosomiasis mansoni). First, quantitative analyses showed that the mitochondrial area decrease 70% during eosinophil development (from undifferentiated precursor cells to mature eosinophils). Mitophagy, a consistent process revealed by TEM in immature but not in mature eosinophils, is likely operating in mitochondrial clearance during eosinophilopoiesis. Events of mitochondria interaction (inter-organelle membrane contacts) were also detected and quantitated within developing eosinophils and included mitochondria-endoplasmic reticulum, mitochondria-mitochondria, and mitochondria-secretory granules, all of them significantly higher in numbers in immature compared to mature cells. Moreover, single-mitochondrion analyses revealed that as the eosinophil matures, mitochondria cristae significantly increase in number and reshape to lamellar morphology. Eosinophils did not change (asthma) or reduced (IAV and Schistosoma infections) their mitochondrial mass in response to inflammatory diseases. However, asthma and schistosomiasis, but not IAV infection, induced amplification of both cristae numbers and volume in individual mitochondria. Mitochondrial cristae remodeling occurred in all inflammatory conditions with the proportions of mitochondria containing only lamellar or tubular, or mixed cristae (an ultrastructural aspect seen just in tissue eosinophils) depending on the tissue/disease microenvironment. The ability of mitochondria to interact with granules, mainly mobilized ones, was remarkably captured by TEM in eosinophils participating in all inflammatory diseases. Altogether, we demonstrate that the processes of eosinophilopoiesis and inflammation-induced activation interfere with the mitochondrial dynamics within mouse eosinophils leading to cristae remodeling and inter-organelle contacts. The understanding of how mitochondrial dynamics contribute to eosinophil immune functions is an open interesting field to be explored.

Granule protein changes and membrane receptor phenotype in maturing human eosinophils cultured from CD34+ progenitors

BACKGROUND

Eosinophils are now recognized as major effector cells in allergic and asthmatic disease with a potent armoury of mediators whose release makes a major contribution to the inflammation underlying these conditions.

OBJECTIVES

The purpose of this study was to compare cultured eosinophils (CE) with normal-density peripheral blood eosinophils (PBE) in terms of their membrane receptor expression and to analyse the expression and storage of the eosinophil granule proteins major basic protein (MBP) and eosinophil cationic protein (ECP) during eosinophil maturation in vitro.

METHODS

Purified human peripheral blood CD34+ cells were cultured in the presence of recombinant human IL-3, IL-5, rhGM-CSF, SCF, and FLT-3 ligand. PBE were isolated by density gradient centrifugation and negative immunomagnetic selection. Expression of CD11b, CD18, CD45, CD45RA, CD45RB, CD45RO, CD69, CD95, IL-5Ralpha, IL-9Ralpha, CCR1, CCR3, and CXCR4 by CE as they matured in culture were assessed by immunostaining and flow cytometry and expression of these receptors compared with freshly isolated PBE. Immunohistochemical staining and labophot-2TM light microscopy determined expression of MBP, ECP, and CD69 during eosinophil maturation.

RESULTS

Positive immunostaining for MBP and ECP was detectable in a proportion (15-20%) of CE as early as 3 days of culture even though these cells were mononuclear in appearance. The numbers of CE positive for both granule proteins increased in rhIL-3 and rhIL-5 treated cells to a maximum of approximately 80% by day 28. Maturing eosinophils exhibited positive immunostaining for CD69 after 14, 21 and 28 days of culture. Compared with PBE, CE had lower expression of pan-CD45 and CD45 isoforms, CD95 and CD11b. In contrast, the specific mean fluorescence for CD69, CD18, IL-5Ralpha, and IL-9Ralpha was significantly elevated for CE compared with PBE. CCR3 expression by CE and PBE was similar with no expression of CXCR4 detected by either CE or PBE. No significant difference in expression of CCR1 was found between CE and PBE.

CONCLUSION

These data suggest that CE and PBE share many phenotypic properties and both MBP and ECP appear early in eosinophil development in vitro. However, there are quantitative differences that may be a consequence of their immaturity and/or the influence of the cytokines used in their culture.

Piecemeal degranulation of peripheral blood eosinophils: a study of allergic subjects during and out of the pollen season

The variability of serum and plasma levels of eosinophil granule proteins in different clinical conditions, interpreted as the result of different patterns of cytokine priming, suggests a selective mobilization of granule proteins. Inasmuch as piecemeal degranulation (PM) is the mechanism proposed for the differential release of eosinophil granule proteins, we decided to investigate whether blood eosinophils from allergic subjects show characteristics of PM during natural allergen challenge. Eosinophils from three birch-sensitive subjects were studied before and during the pollen season. Electron microscopy analysis showed that during the season, eosinophils presented morphologic features of PM. By immunogold labeling, eosinophil cationic protein (ECP) was detected not only in normal specific granules but also in the cytoplasm, in the vicinity of partially lucent specific granules. These results were confirmed by subcellular fractionation, where the amount of ECP associated with compartments containing small vesicles increased 2-fold during the pollen season. A study of the distribution of ECP, eosinophil peroxidase, and hexosaminidase in eosinophils of different densities showed that the profile of each of these proteins differed depending on cell density. All of these proteins decreased in the specific granule of hypodense cells and increased in other cell compartments. We conclude that allergen exposure causes PM of the peripheral blood eosinophils of allergic subjects, and that the density of these cells reflects the degree of degranulation. Our results provide novel information for the understanding of the selective mobilization of granule proteins into the circulation.

Immunofluorescence analysis of cytokine and granule protein expression during eosinophil maturation from cord blood-derived CD34 progenitors

BACKGROUND

In allergic inflammation and asthma, eosinophils are major effector cells. They have been shown to synthesize at least 23 cytokines, some of which are stored intracellularly in their unique crystalloid granules together with cationic granule protein. Little is known about the synthesis and storage of cytokines relative to cationic granule proteins in maturing eosinophils during eosinophilopoiesis.

OBJECTIVE

Our purpose was to analyze the expression of eosinophil-derived mediators, major basic protein (MBP), eosinophil cationic protein (ECP), IL-6, and RANTES, during early stages of eosinophil maturation in CD34(+) cell-derived colonies.

METHODS

Purified human cord blood CD34(+) cells were grown in methylcellulose cultures in the presence of recombinant human IL-3 and IL-5. By confocal laser scanning microscopy, the coexpression of eosinophil granular proteins MBP and ECP was determined concurrently with IL-6 and RANTES during eosinophil maturation on days 16, 19, 23, and 28 of culture.

RESULTS

Immunoreactivity against MBP, ECP, IL-6, and RANTES was not detectable in freshly purified CD34(+) cells. Maturing eosinophils (>95%) exhibited positive immunostaining for all these proteins between days 16 and 28 of culture. At early stages of culture, discrete immunostaining was observed around the periphery but not in the center of granular structures. By day 28 cultured eosinophil-like cells showed evidence of the acquisition of crystalloid granule-like structures, analogous to those observed in mature peripheral blood eosinophils.

CONCLUSIONS

Eosinophils express and store cytokines simultaneously with cationic granule proteins during the process of maturation. We propose that the storage of cytokines during the development of eosinophils is an early event and it may be integral to inflammatory responses involving these cells. The results of this study suggest a potential immunoregulatory function for maturing eosinophils.

Exocytotic Competence and Intergranular Fusion in Cord Blood-Derived Eosinophils During Differentiation

We studied degranulation of single cord blood-derived mononuclear cells differentiating to eosinophils in cultures containing recombinant human interleukin-5 (rhIL-5) and rhIL-3 by whole-cell patch-clamp capacitance measurements. As in mature cells, degranulation can be stimulated by intracellular application of guanosine-5′-O-(3-thiotriphosphate) (GTP) γS after 10 days in culture, simultaneously with the first morphological appearance of granules. These results demonstrate that the fusion machineries for exocytotic fusion are present and functional as soon as the granules are formed, presumably at the myeloblast stage. In the third week, the total amount of granules exocytosed upon stimulation is similar to that in mature eosinophils from peripheral blood. The capacitance step size distributions in promyelocytes and myelocytes confirm that mature large specific granules are formed by homotypic fusion of unit granules with similar size. Homotypic fusion is facilitated during early stages of differentiation associated with granulogenesis. Between day 10 and day 35 in culture the plasma membrane area of resting cells decreases from ≈700 μm2 to ≈400 μm2, approaching the value of mature cells from peripheral blood. The most prominent decrease occurs between day 25 and day 35 and is accompanied by the appearance of an exocytotic component due to small vesicles. This suggests that a class of small secretory vesicles is formed by endocytosis during a late phase in maturation.

Vesicular transport of peroxidase in human eosinophilic myelocytes

We performed ultrastructural cytochemistry to detect peroxidase in developmentally arrested human eosinophilic myelocytes. Human umbilical cord blood mononuclear cells were cultured for 21 days in the presence of murine-derived conditioned media, resulting in the development of eosinophilic myelocytes. Unlike normally developing eosinophilic myelocytes, which contain peroxidase in synthetic organelles (i.e. cisterns surrounding the nucleus and bounded by the rough endoplasmic reticulum and Golgi structures) and in immature and mature granules, the developmentally arrested cells showed ultrastructural evidence of decreased synthesis and secretory transport of peroxidase. Thus, peroxidase was generally absent in the perinuclear and rough endoplasmic cisterns, in Golgi structures, in immature granules and in the matrix compartment of most mature granules. Rather, biocompartmental specific granules displayed empty, peroxidase-negative matrix and central, peroxidase-negative core material. Peroxidase was present in perigranular vesicles, some of which were attached to granules. Such peroxidase-loaded transport vesicles are similar to those that effect piecemeal degranulation of mature human eosinophils cultured in rhIL-5-containing media [1]. These findings establish vesicle-mediated piecemeal degranulation in the secretory repertoire of immature human eosinophils and suggest the possibility that eosinophilic myelocytes may participate in vivo in important physiological and/or pathological events that require selective secretion from the specific granule matrix compartment.

Electron-microscopic characterization of mixed granulated (hybridoid) leucocytes of chronic myeloid leukaemia

In chronic granulocytic leukaemia, hybridoid leucocytes can regularly be found. Light microscopically they contain a mixture of eosinophilic, basophilic and naphthol AS-D chloroacetate esterase-positive granules. The present study was done to clarify the ultrastructural composition of these cells. It could be clearly shown that in some leukaemic granulocytes primary and secondary eosinophilic as well as basophilic granules occur side by side. There were also basophils with additional tissue mast cell granules. Since normal mast cell granules as well as granules of normal eosinophilic promyelocytes are naphthol AS-D chloroacetate esterase-positive, it would appear possible that mastocytoid as well as primary eosinophilic granules within the leukaemic basophils are responsible for the atypical, granular naphthol AS-D chloroacetate esterase-positivity of these cells. The existence in chronic myeloid leukaemia both of mixed basophilic and eosinophilic granulated leucocytes and of mixed basophilic and mastocytoid granulated leucocytes may suggest a common myeloid precursor of eosinophils, basophils and tissue mast cells. In addition, the hybridoid granulocytes may be considered an expression of a neoplasia-related lineage infidelity.

Ultrastructural visualization of complex carbohydrates in eosinophilic leukocytes

Complex carbohydrates in eosinophils from human, rabbit, and rat marrow were identified and localized by cytochemical and radioautographic methods. The high iron diamine-thiocarbohydrazide-silver proteinate (HID-TCH-SP), low iron diamine (LID)-TCH-SP, and periodate (PA)-TCH-SP methods were used for the localization of sulfate, sulfate and carboxyl, and vicinal glycol- containing complex carbohydrates, respectively. Golgi vesicles and small precursor granules (0.2-0.4 micrometer in diameter) demonstrated strong HID-TCH-SP staining and labeled intensely after a 10-minute pulse with 35SO4(2). Crystalloid-free or immature specific granules (0.5-0.9 micrometers in diameter) labeled heavily after a 60-minute incubation and 60-minute chase with 35SO4(2). Immature granules were graded according to their HID-TCH-SP staining. Type I granules demonstrated strong rim staining and similar or somewhat less central staining, whereas type 2 granules only demonstrated rim staining, and type 3 granules lacked staining. Fully mature crystalloid-containing granules lacked staining. LID-TCH-SP similarly stained the HID-positive sulfated material in cytoplasmic granules. PA-TCH-SP stained some Golgi vesicles and diffusely stained all precursor granules and type 1 granules. Weaker staining was observed in type 2 granules and staining was very weak or absent in type 3 and crystalloid-containing granules. In early eosinophils, tubulovesicular structures (TVS) were observed rosetting and contacting precursor and type 1 granules. These TVS contained material with strong PA-TCH-SP staining but lacked HID-TCH-SP or LID-TCH-SP-reactive acidic glycoconjugates. Flattened Golgi saccules or early eosinophils stained weakly or not at all with the PA-TCH-SP method. Small granules and TVS in late (bilobed) eosinophils displayed PA-TCH-SP reactivity and lacked HID-TCH-SP staining but differed from TVS in early eosinophils in that they were not associated as rosettes with specific granules. These results indicate that sulfated and vicinal glycol-containing complex carbohydrates are differently disturbed in immature specific granules of eosinophils and presumably become masked to staining as the granule matures.

Genesis, ultrastructure and cytochemical study of the cat eosinophil

Eosinophils from cat bone marrow and peripheral blood were studied by electron microscopy and cytochemical procedures. The maturation of eosinophils and formation of typical granules were described. Contrary to the accepted opinion that the core of animal's eosinophilic specific granules have a crytal-like structure, our observations revealed that the core has a myelin-like cylindrical appearance, whose layered formation proceeds from the inside outwards. Electron microscopic observations revealed that localization of reaction product to potassium pyroantimonate and phosphotungstic acid and to acid phosphatase activity was similar to that of eosinophils of man and other animals. Antimonate deposits and acid phosphatase activity were detected between the layers of the myelin-like structure of the core. Eosinophil granules failed to yield a positive reaction for peroxidase activity. The secretory activity of the eosinophil is discussed.

Acute eosinophilic leukemia. An ultrastructural study

Observations on a 32 year old male are described. Hematological examination demonstrated leukocytosis with circulating blastosis and dystrophic hypereosinophilia of the blood and bone marrow, with cells at various stages of maturation. Cytotoxic chemotherapy led to complete remission for 5 months followed by a terminal relapse. No features in favor of an "eosinophilic collagenosis" were revealed at autopsy. Repetitive ultrastructural studies performed during evolution of the illness demonstrated considerable anomalies of the eosinophil line. The present observation thus shows the clinical, evolutional, cytological and autopsy criteria of an acute eosinophilic leukemia.

High resolution autoradiographic studies of RNA, protein and DNA synthesis during human eosinophil granulocytopoiesis: evidence for the presence of RNA on or within eosinophil granules

Human bone marrow cells which had been incubated with [3H]uridine or [3H]leucine for I h were studied using the technique of electron microscope-autoradiography. The autoradiographs revealed the presence of newly-synthesized RNA and protein molecules within or on a proportion of (I) the primary and secondary granules in all classes of eosinophil precursors and (2) the secondary granules in eosinophil granulocytes. It is suggested that the granule-associated RNA molecules may be concerned with the synthesis of at least some of the new protein molecules which were incorporated into the limiting membrane or substance of eosinophil granules long after the immature primary granule stage. Studies of eosinophil precursors which had been incubated with [3H]thymidine for I h showed that the eosinophil granules do not label with this DNA precursor.

Ultrastructural characteristics of developing eosinophil leukocytes in human bone marrow during acute leukemia: evidence for extracellular granule release from human eosinophils

Developing eosinophils from the bone marrow of a patient with acute "eosinophilic" leukemia were characterized by electron microscopy. It was suggested that the first sequential step in granule formation occurred at the level of the endoplasmic reticulum without actual participation of the Golgi complex. Progressive densification of the former profiles, presumably mediated by Golgi vesicles, resulted in the formation of dense immature granules. Ultrastructural observations of the "leukemic" eosinophils which were generally arrested at an intermediate stage of maturation revealed also large vacuoles containing sequestered immature granules, without any indication of phagocytic activity. Morphological evidence that has been accumulated indicates that the membrane of these vacuoles fused with the cell membrane, thus being in contact with the extracellular space. These profiles strongly suggested that granules and/or granule-associated material were secreted by developing bone marrow eosinophils.

[3 cases of eosinophilic leukemia with atypical granulation in the eosinophils and neutrophils]

Three patients with eosinophilic leukemia and atypical granulation in the eosinophils are described. A remarkable light and electron microscopic finding was the appearance of enormous granules in the neurtophils and eosinophils. In addition the usual anomalies seen in acute leukemia, for example asynchronisation in cell maturation, fibrillar bundles, shrinkage of nucleolus and cell organelles, signs of degeneration and also the auer-rods characteristic of AML are observed.

Acute leukaemia with eosinophilia or acute eosinophilic leukaemia: a dilemma

A young male patient is described with acute leukaemia whose bone marrow and peripheral blood contained abundant cells of the eosinophilic series in all stages of maturation. These cells, proven histochemically to be true eosinophils, were abnormal in both maturation and proliferation. Upon electron microscopic study of bone marrow and peripheral blood, abnormalities in the eosinophilic series were identified as early as the promyelocytic stage as well as in the most mature eosinophil seen. The clinical and morphologic picture of this patient's disease raises the possibility of this being an acute eosinophilic leukaemia.

[On the ultrastructure and cytochemistry of eosinophil-myelomonocytic leukemias]

In the bone marrow of two patients with acute leukemia 46% and 55% of atypical eosinophilic cells were found, respectively. Blood eosinophilia was absent. The N-AS-D-Cl-Esterase reaction of the granules was positive in the first case in 58%, and in the second case in 3% of the eosinophils, as well as the PAS-reaction in all cells of this series. The ultrastructure of the eosinophils reveals nuclear maturation up to hypersegmentation. The maturation of the granules, in part of abnormal size, is arrested at the primary stage. Typical secondary granules with cristalloid cores are lacking. Only in the first case a few, small, semicircular or circular profiles of lamellar substructure are seen in the granules. The cytoplasm of hypersegmentated eosinophils shows an abnormally high glycogen content. Besides the eosinophils, monocytic cells and their precursors proliferate in the bone marrow of the first patient. In the second patient myeloblasts, promyelocytes with Auer rods, and monocytic cells characterize further neoplastic cell population. The elements of the monocytic series can be identified by their ultrastructural features, such as irregular configuration of the nuclei, bundles of cytoplasmatic microfilaments, and numerous small electron-dense lysosomal granules. In both cases the Alpha-Naphthyl-Acetase-Esterase reaction is weakly positive. The findings presented are summarized under the terms "eosinophil-monocytic leukemia" and "eosinophil-myelomonocytic leukemia" (collective term).