Cytochemical reaction for cationic proteins as a marker of primary granules during development in chick heterophilis.

The ammoniacal silver reaction (ASR) for cationic proteins was used as a cytochemical marker for the primary or A granules in the cytoplasm of developing heterophils of chick bone marrow. The presence of the electron-dense particulate reaction product of silver, which is localized in the fully formed rod-shaped A granules, provides a marker by which the A granules could be distinguished from the B granules of similar size and by which the formation and maturation of both granule types could be followed through the developmental stages. Progressive developmental stages were ascertained on the basis of decreasing cell size, increasing condensation and margination of the chromatin, and the number and morphology of the granules; the stages were divided into promyelocyte, myelocyte, metamyelocyte and heterophil. During the promyelocyte stage, the first appearance of the electron-dense, membrane-bound, spherical granules (0.3--1.0 micrometer in diameter) is observed in the vicinity of an extensive Golgi complex. They occur in a cytoplasm containing rough-surfaced endoplasmic reticulum, ribosomal clusters, centrioles, mitochondria, microtubules, as well as the membranes, saccules, vesicles and vacuoles of the Golgi complex. These granules are considered as primary but their presence as the only granule type appears very brief. The ASR reaction product is first detected on the surface of these primary granules in late promyelocytes or myelocytes. The secondary or B granule, devoid of reaction for cationic protein at all stages, appears as a condensing vacuole in promyelocytes, but after some A granules are already present. The vacuole contents condense to form the B granules which are 0.1--0.6 micrometer in diameter, often oval-shaped, and contain a loose filamentous material surrounded by a membrane. Tertiary C granules or lysosomes appear during the myelocyte stage as dense core vesicles (0.1--0.2 micrometer in diameter) negative for cationic protein.     

The human neutrophilic promyelocyte

Summary The developmental changes in the neutrophilic promyelocytes from normal human bone marrow have been analyzed by means of phase contrast and electron microscopy. This developmental phase is characterized by the elaboration of primary (azurophillysosomal) granules and the entire intracellular machinery is directed principally toward this goal. The promyelocyte stage has been subdivided into three arbitrary stages based upon morphological, histochemical and functional characteristics which relate to the onset, active production and cessation of primary granulogenesis.Supported by Grant No. AM-HE-12084-12 from the National Institutes of Health, Bethesda, Maryland.Appreciation is expressed to Dr. Arthur Sagone who performed the bone marrow aspirations and to Marjorie Griffith, Anita Topson and Barbara Jordan for their technical assistance.     

Development ot the granule population in heterophil granulocytes from rat bone marrow

Summary The development of the heterophil granulocyte in the bone marrow of the rat is described, and an electron-microscopical analysis of the changes in the cytoplasm as well as in the granule population in several stages of maturation is reported. Three types of granule originate in consecutive stages of heterophil maturation. Granules with an internal fine structure (nucleated granules) are the first to be formed, i.e., in early promyelocytes; azurophil granules are formed in late promyelocytes; and specific granules appear in myelocytes. Quantitative analysis showed that the granule population in mature cells, i.e., about 160 granules per electron micrograph, is composed of roughly 14% nucleated granules, 10% azurophil granules, and 76% specific granules. Three cell stages were observed in mitosis: the early promyelocyte, the late promyelocyte, and the myelocyte. Granule counts in non-dividing cells confirmed the occurrence of mitosis in the late promyelocyte and myelocyte.     

The ultrastructure of guinea pig heterophil granulocytes and the heterogeneity of the granules

Summary The development of the heterophil granulocytes in the bone marrow of the guinea pig is described. During the maturation of these cells, three types of granule are formed, not only the azurophil and specific granules already described in other mammals but also a third type of granule referred to here as the nucleated granule. During the process of maturation of the cells, these three types of granule are formed successively. On this basis, two steps can be distinguished in the promyelocyte phase in which primary (nucleated and azurophil) granules are formed, i.e. an early and a late stage, nucleated granules being formed in early and azurophil granules in late promyelocytes. Secondary (specific) granules occur first in myelocytes. In mature heterophils of the guinea pig the granule population is composed of about 85% secondary granules, about 10% azurophil granules, and about 5% nucleated granules. The changes in the granule population during the maturation process were quantified. The observations and calculations point to the occurrence of three mitoses: one in the early and one in the late promyelocyte and the third in the myelocyte.     

Immunocytochemical localization of lactoferrin in human neutrophils

Summary The subcellular localization of lactoferrin in human neutrophils was studied by an electron-microscopic immunoperoxidase method. This molecule was detected in small granules of blood polymorphonuclear leukocytes. A morphometrical analysis showed that there was no significant difference in the mean size between lactoferrin-positive and myeloperoxidase-negative granules. In contrast, the mean size of myeloperoxidase-positive granules was significantly larger than that of lactoferrin-positive granules. This indicates that lactoferrin is contained in the myeloperoxidase-negative, secondary, granules of human neutrophils. In immature bone marrow mononuclear neutrophils, lactoferrin was present in cytoplasmic granules of somewhat larger size than lactoferrin-positive granules of polymorphonuclear leucocytes. A morphometrical study showed that the mean size of lactoferrin-positive granules was significantly greater in immature bone marrow cells than in polymorphonuclear leucocytes. This indicates that lactoferrin-positive granules decrease in size as the cells mature. Besides cytoplasmic granules, lactoferrin was demonstrated in the Golgi complex and a part of the rough endoplasmic reticulum of immature bone marrow neutrophils, probably myelocytes and early metamyelocytes. These results show that lactoferrin is synthesized and packed into secondary granules in immature bone marrow neutrophils and therefore that the secondary granules are a type of secretory granule.     

A new type of primary granule in guinea pig heterophil granulocytes

Guinea pig heterophil granulocytes were found to have three types of granules which are formed sequentially during the development of the cells in the bone marrow and differ in shape and electron density: nucleated, azurophil and specific granules. Early promyelocytes proved to synthesize nucleated granules of medium electron density prior to the formation of azurophil granules which are highly electron dense, by late promyelocytes. Since the formation of nucleated granules and azurophil granules is restricted to promyelocytes, both can be considered to be primary granules. The moderately dense specific granules (secondary granules) appear later during granulopoiesis and are firstly present in the myelocyte.     

ORIGIN OF GRANULES IN POLYMORPHONUCLEAR LEUKOCYTES : Two Types Derived from Opposite Faces of the Golgi Complex in Developing Granulocytes

The origin, nature, and distribution of polymorphonuclear leukocyte (PMN) granules were investigated by examining developing granulocytes from normal rabbit bone marrow which had been fixed in glutaraldehyde and postfixed in OsO₄. Two distinct types of granules, azurophil and specific, were distinguished on the basis of their differences in size, density, and time and mode of origin. Both types are produced by the Golgi complex, but they are formed at different stages of maturation and originate from different faces of the Golgi complex. Azurophil granules are larger (~800 mµ) and more dense. They are formed only during the progranulocyte stage and arise from the proximal or concave face of the Golgi complex by budding and subsequent aggregation of vacuoles with a dense core. Smaller (~500 mµ), less dense specific granules are formed during the myelocyte stage; they arise from the distal or convex face of the Golgi complex by pinching-off and confluence of vesicles which have a finely granular content. Only azurophil granules are found in progranulocytes, but in mature PMN relatively few (10 to 20%) azurophils are seen and most (80 to 90%) of the granules present are of the specific type. The results indicate that inversion of the azurophil/specific granule ratio occurs during the myelocyte stage and is due to: (a) reduction of azurophil granules by multiple mitoses; (b) lack of new azurophil granule formation after the progranulocyte stage; and (c) continuing specific granule production. The findings demonstrate the existence of two distinct granule types in normal rabbit PMN and their separate origins from the Golgi complex. The implications of the observations are discussed in relationship to previous morphological and cytochemical studies on PMN granules and to such questions as the source of primary lysosomes and the concept of polarity within the Golgi complex.     

A light and electron microscopic study of myelopoietic cells in the perihepatic subcapsular region of the liver in the adult aquatic newt,Notophthalmus viridescens

Summary The liver of the newt, Notophthalmus viridescens, consists of several incompletely separated lobes of parenchymal tissue each of which is covered by a perihepatic subcapsular region (PSR) of myeloid tissue. This tissue contains neutrophils and eosinophils in various stages of differentiation. As neutrophils develop from myeloblasts to late neutrophilic myelocytes, two types of granules appear. The primary granules (type of granules formed first) are more electron dense and smaller than the secondary granules (type of granules formed later). The primary granules first appear at the stage designated early neutrophilic myelocyte, and the secondary granules appear at the stage of the maturing neutrophilic myelocyte. The eosinophils present are characterized by much larger granules than those observed in neutrophils. Cells in the PSR which superficially resemble small lymphocytes are primitive stem cells that give rise to neutrophils and eosinophils. The liver PSR is invested by a visceral peritoneum of simple squamous mesothelial cells some of which are ciliated.Supported by ACS IN-105.     

Morphometry of feline neutrophil granule genesis

During neutrophil granule genesis, the formation of primary granules is generally thought to be limited to the promyelocyte stage; whereas synthesis of secondary granules is thought to occur only at the myelocyte stage. This hypothesis was tested morphometrically in feline neutrophils that are known to contain both granule types. Marrow specimens obtained from six cats were stained with peroxidase for identification of neutrophil primary granules and counterstained with periodic acid-thiocarbohydrazide-silver proteinate (PA-TCH-SP) for identification of secondary granules. By regression analysis using arithmetic models, numbers of cytoplasmic granules in 311 cells were correlated with the degree of nuclear chromatin condensation, which was shown to be an adequate parameter for cell maturation. Promyelocytes and myelocytes had similar mean numbers of peroxidase-positive granules per unit area. A significant increase (p less than or equal to 0.0001) in the numbers of peroxidase-positive granules was noted between the metamyelocyte and the mature neutrophil stage, despite the lack of peroxidase activity in endoplasmic reticulum and Golgi lamellae. By contrast, a significant increase of peroxidase-negative granules between the metamyelocyte and the mature neutrophil stage was not clearly established with these methods. The increase in peroxidase-positive granules may indicate continued production of peroxidase-containing granules and/or redistribution of peroxidase among lysosomal organelles in late feline neutrophils.     

Ultrastructural features of the developing eosinophils in bone marrow and spleen of the musk shrew, Suncus murinus

Eosinophilopoiesis in the musk shrew, Suncus murinus, a representative of the order Insectivora, was studied by light and electron microscopy. To examine biochemical features of cytoplasmic granules, extraction with proteolytic enzymes was carried out on ultrathin sections of bone marrow. In this species, eosinophils are produced in the same manner in both spleen and bone marrow. Developing eosinophils were distinguished as belonging to four stages, recognized by ultrastructural changes in cytoplasmic organelles as well as the eosinophilic granules during maturation. Granulogenesis began by budding of vacuoles containing flocculent material from the concave face of the Golgi apparatus, in the promyelocyte to myelocyte stage. The matrix of developing granules transformed into a finely granular structure, and the large spherical granules of mature eosinophils were homogeneous without crystalline cores. It was shown by proteolytic enzyme extraction that the proteinaceous cores of mature granules were uniformly removed; there was no evidence that they contained crystalloid inclusions. These results indicate that shrew eosinophils can be regarded as cells that retain a prototype of eosinophil granules, probably like those of ancestral mammals rather than those of higher living Mammalia.     

Ultrastructural localization of peroxidase activity in developing neutrophil granulocytes from human bone marrow

Developing neutrophil granulocytes of normal human bone marrow were investigated with the diaminobenzidine technique to determine the ultrastructural localization of peroxidase activity. Neutrophil granulocytes have three types of granule: nucleated, azurophil, and specific granules. These granules are produced consecutively during the eomyelocyte stage, the promyelocyte stage, and the myelocyte stage, respectively. The organelles involved in the production of granules, i.e., the nuclear envelope, rough endoplasmic reticulum, and Golgi apparatus, are peroxidase positive during the eomyelocyte and promyelocyte stages and peroxidase negative thereafter. This pattern differs for the granules themselves: nucleated granules are negative in the eomyelocyte and become positive in the promyelocyte. Azurophil granules become positive in the promyelocyte. Specific granules are negative. Our observations highly suggest that small Golgi-derived peroxidase-positive vesicles are involved in the maturation of both nucleated granules and azurophil granules.     

Cytochemical studies of normal feline blood and bone marrow cells

Blood and bone marrow cells of ten clinically healthy cats were stained for alkaline phosphatase (ALP), peroxidase (PO), chloroacetate esterase (CAE), alpha-naphthyl butyrate esterase (NBE), sudanophilia, and periodic acid-Schiff (PAS) reaction. Mature neutrophils in blood and bone marrow were devoid of ALP and NBE, but exhibited modest to strong PO, CAE, sudanophilia, and PAS reaction. In bone marrow, sudanophilia, PO, and CAE were prominent at the promyelocyte stage and diminished with cellular differentiation and maturation, while PAS reactivity increased with cell maturation usually from the myelocyte stage onwards. Myeloblasts were negative for all cytochemical reactions, but some large unidentifiable cells reacted strongly for ALP. Eosinophils were slightly reactive for ALP, CAE, and PAS, but not for PO, sudanophilia, and NBE. Basophil granules stained strongly for CAE, revealed PAS positivity, and stained negatively for PO, NBE, ALP, and sudanophilia. Slight ALP activity was detected in the intergranular cytoplasm of basophils. Lymphocytes and monocytes, with few exceptions, stained negatively. An occasional lymphocyte revealed slight globular NBE activity (NaF-resistant) and diffuse PAS reaction, while an occasional monocyte contained a few PO-positive and sudanophilic granules. Monocytes reacted modestly, whereas bone marrow macrophages reacted strongly for NBE (NaF-sensitive). Cells of the erythroid series stained negatively for all cytochemical reactions, megakaryocytes were PAS-positive, and platelets gave positive reactions for PAS and CAE.     

Ultrastructural localization of peroxidase activity in developing neutrophil granulocytes from human bone marrow

Summary Developing neutrophil granulocytes of normal human bone marrow were investigated with the diaminobenzidine technique to determine the ultrastructural localization of peroxidase activity. Neutrophil granulocytes have three types of granule: nucleated, azurophil, and specific granules. These granules are produced consecutively during the eomyelocyte stage, the promyelocyte stage, and the myelocyte stage, respectively.The organelles involved in the production of granules, i.e., the nuclear envelope, rough endoplasmic reticulum, and Golgi apparatus, are peroxidase positive during the eomyolocyte and promyelocyte stages and peroxidase negative thereafter. This pattern differs for the granules themselves: nucleated granules are negative in the eomyelocyte and become positive in the promyelocyte. Azurophil granules become positive in the promyelocyte. Specific granules are negative.Our observations highly suggest that small golgi-derived peroxidase-positive vesicles are involved in the maturation of both nucleated granules and azurophil granules.In honour of Prof. P. van Duijn     

Ultrastructural localization of peroxidase activity in normal human bone marrow cells

Summary The ultrastructural localization of peroxidase activity has been studied in the cells of normal human bone marrow using the diaminobenzidine peroxidase technique. Peroxidase activity has been localized within the primary (azurophil) granules of the neutrophilic series as well as in the cytoplasmic granules of eosinophils, basophils and monocytes. Peroxidase activity appears within the cisternal system (nuclear envelope, Golgi complex and rough endoplasmic reticulum) of these cells during the period of peroxidase-containing lysosome production. With the cessation of granulogenesis, peroxidase activity disappears from the cisternal system and does not reappear in subsequent developmental stages. In cells incubated in peroxide-free media, staining of granular components, but not of cisternae, is reduced. The inclusion of catalase in peroxide-free media eliminates all staining. This indicates that an endogenous peroxide is present within the cisternae and granules of these cell types.Supported by Grant No. AM-HE-12084-12 from the National Institutes of Health, Bethesda, Maryland.Appreciation is expressed to Anita Topson and Barbara Jordan for their technical assistance and to Dr. Arthur Sagone who performed the marrow aspirations.     

Effect of Zhen Qi Fu Zheng granules on the bone marrow depression model induced by Zidorf

Zidorf is a commonly used drug for the treatment of AIDS, the most common side effects of AZT was bone marrow depression. Therefore, we investigated the effects of Zhen Qi Fu Zheng (AQFZ) granules on the model of bone marrow depression induced by AZT. We showed that the high, medium and low doses of AQFZ granules could increase the number of WBC in the mice model induced by AZT, and the difference was significant (P < 0.01) compared with the model group. Each dose of AQFZ granules can increase the thymus cortex thickness, the number of thymus lymphocytes, spleen nodule size, the number of lymphocytes in the spleen (P < 0.01). The medium dose of AQFZ granules can also significantly improve the number of BMC in the bone marrow depression model (P < 0.01). As well as, the low dose of AQFZ granules can clearly increase the number of nucleated cells in a bone marrow (P < 0.05) and IL-2blood serum. So, AQFZ granules can improve and regulate the hemogram, bone marrow and immune level of bone marrow depression model induced by AZT.     

A comparative study of primary and secondary granules in monocytopoiesis and myelopoiesis of mouse bone marrow

Summary The differentiation and maturation of monocytes and neutrophil granulocytes were studied in bone marrow of normal mice by electron microscopy and cytochemical assessment of peroxidatic activity. The granule populations of the mature cells of bone marrow were identified and investigated to obtain a basis for the analysis of the earlier stages of maturation. Mature monocytes and neutrophils showed primary and secondary granules, and mature neutrophils had more of both kinds. The size, shape, and number of primary granules proved to offer the most reliable criteria for distinguishing promonocytes and promyelocytes. The primary granules of monocytes were smaller than those of mature neutrophils and were either spherical (smallest diameter 50–200 nm) or elongate (100×400 nm). Both granules had a homogeneous matrix. The granules of the granulocytes were either spherical (smallest diameter 200–300 nm) or elongate (150–200×300–500 nm), and some of them had a crystalline inclusion.     

The action of dipyridamole on megakaryocytopoiesis in regenerating and stationary bone marrow cell populations]

The effect of dipyridamole on megakaryocytopoiesis in regenerating and stationary populations of mouse bone marrow cells has been studied by heterotopic transplantation of the bone marrow using histological, electron microscopic and biochemical techniques. It is shown that drug administration induced destruction of megakaryocytes. In megakaryocytic cytoplasm giant lipid granules were found whose growth and number increase resulted in megakaryocytes kill. Gas-liquid chromatography was used to evaluate the effect of dipyridamole on distribution of lipid fatty acids of the stationary and regenerating populations of the bone marrow cells. A marked increase of the percentage of docosahexaenoic acid was found in lipids of the stationary population. Chronic dipyridamole administration caused an increase of percentage of myristic, palmitic oleic acids, and decrease of percentage of arachidonic and eicosapentaenoic acids in lipids of regenerating bone marrow cells population.     

Granule formation in rat myeloid cells

Summary Rat bone marrow was fixed in glutaraldehyde, postfixed in osmium tetroxide, and processed for electron microscopy. The myeloid cells were arranged in order of maturation according to their successive compartments.On the basis of their differences in form, substructure, volume, and density five morphologically distinct types of developing granules are to be observed in neutrophil, two in eosinophil, and four in basophil, cells. Primordial granules appear in the interphase of the myeloblast, respectively in the early promyelocytes. The first granules in the neutrophils are pale, of homogeneous structure. These granules grow gradually denser with increasing condensation. In the myelocyte stage polymorphism is more pronounced. In the granulocytes, vacuoles and dense-cored vacuoles indicate the sites of granules. In the eosinophil line, the basophilic bodies decrease in number during differentiation. The eosinophil granules show fewer variations in the course of maturation than the neutrophils. The immature forms of the basophil granules are relatively large, pale, and of globular structure; they undergo condensation and show gradually higher density.Sites of granulogenesis in the rat are first of all the Golgi apparatus and, possibly, the cisternae in the endoplasmic reticulum. On occasion, bodies in a transitional stage between a mitochondrium and a granule can be observed, but whether they may have a bearing on the problem of granulogenesis is an open question.     

SELF-RENEWAL OF COLONY FORMING UNITS (CFU) IN SERIAL BONE MARROW TRANSPLANTATION EXPERIMENTS

The capacity of stem cells (CFU) for self-renewal was tested by transplanting normal bone marrow (primary transplantation) and bone marrow which had been subjected to one or two earlier transplantations (secondary and tertiary transplantation) into lethally irradiated syngeneic recipients. It was found that the capacity for self-renewal is diminished within the first weeks after one or more previous transplantations. This ability of stem cells recovered after a longer interval after the previous transplantation. The time required for this recovery depended upon the number of previous transplantations and amounted to more than 1 or 2 months after one or two transplantations respectively. Shortly after transplantation the CFU/nucleated cell ratio in bone marrow was below normal and its decrease was more pronounced when the bone marrow had been transplanted more often. An increase of the ratio towards normal values was observed in the course of one month after the last transplantation. Measurements of the spleen colony size after transplantation of normal and re-transplanted bone marrow indicated that CFUs from re-transplanted marrow gave slightly smaller spleen colonies than those of normal marrow.
It is concluded that the decreased self-renewal of stem cells shortly after previous transplantations is probably not due to a limitation in the number of normal mitoses they can perform, but to a loss of stem cells by transfer to the compartment of differentiating cells.     

Selective abnormalities of azurophil and specific granules of human neutrophilic leukocytes

Human neutrophilic granulocytes (PMN) contain two chemically distinct granule types, which appear at different stages of maturation. The azurophilic granule (or primary granule) is formed during the promyelocyte stage and is known to contain myeloperoxidase in addition to numerous lysosomal enzymes, neutral proteases, glycoaminoglycans, cationic bactericidal proteins, and lysozyme. The specific granule (or secondary granule) is formed during the myelocyte stage. It is defined by the absence of peroxidase and has been shown to contain lysozyme, lactoferrin, and B12-binding proteins. The mature PMN contains both types of granules: 33% azurophilic and 67% specific granules. There are now a few well-documented examples of pathological PMN granulations that can be classified as a selective abnormality of one granule type or the other.