Hemocyte classification and differential counts in the dungeness crab, Cancer magister

The primary purposes of this research were to describe and classify the circulating hemocytes of Cancer magister and devise a method for making differential hemocyte counts for crustaceans. C. magister hemocytes were classified using two simple criteria: the presence or absence of cytoplasmic granules and staining characteristics of the granules, if present. Hyalinocytes (HC) were devoid of granules, intermediate granulocytes (IG) contained basophilic granules or a mixture of basophilic and acidophilic granules, and eosinophilic granulocytes (EG) contained large, acidophilic granules. Hemocyte renewal and a hypothetical maturation sequence of C. magister hemocytes are described and discussed. Differential counts revealed that granulocytes were more abundant than hyalinocytes. For 22 crabs, the mean percentage (and range) of each hemocyte class was: IG, 65.97 (57.50–73.80); EG, 17.76 (4.70–26.47); and HC, 16.25 (3.40–34.67). After additional data are collected and analyzed, the routine use of differential counts may prove to be a valuable method for monitoring the status and health of C. magister and perhaps other crustaceans as well.     

Characterization of subpopulations and immune-related parameters of hemocytes in the green-lipped mussel Perna viridis

The green-lipped mussel Perna viridis is distributed widely in the estuarine and coastal areas of the Indo-Pacific region and extensively cultured as an inexpensive protein source. Morphology and immunological activities of hemocytes of P. viridis were investigated using flow cytometry and light and electron microscopy. Three major types of hemocytes were identified in the hemolymph, including dense-granulocyte, semi-granulocyte (small and large size) and hyalinocyte. Other hemocytes, which occurred in low numbers, included granulocytes with different electron-dense/lucent granules and hemoblast-like cells. Based on flow cytometry, two subpopulations were identified. Granulocytes were larger cells, and the more abundant, containing numerous granules in the cytoplasm, and hyalinocytes were the smaller and less abundant with the fewest granules. Flow cytometry revealed that the granulocytes were more active in cell phagocytosis, contained the higher lysosomal content, and showed higher esterase activity and reactive oxygen species (ROS) generation compared with hyalinocytes. Immune functions assessed by the flow cytometry indicated that the granulocytes were the main hemocytes involved in the cellular defence in P. viridis.     

Flow cytometric and light microscopic identification of hemocyte subpopulations in <Emphasis Type="Italic">Modiolus kurilensis</Emphasis> (Bernard, 1983) (Bivalvia: Mytilidae)

Flow cytometry using forward and side light scattering identified three cell subpopulations in the hemolymph of Modiolus kurilensis (Mytilidae). Light microscopic data indicated that they correspond to three hemocyte morphotypes: R1, hemoblasts and agranulocytes (hyalinocytes); R2, semigranulocytes; and R3, granulocytes. The hemoblasts, agranulocytes, and semigranulocytes had a basophilic endoplasm, while the granulocytes were mainly eosinophilic. The proportion of the different cell morphotypes and the level of subpopulation distinction substantially varied among individuals. This seems to be connected with the different functional activities of the hemocytes, depending on the immunological status of the bivalves.     

The cytology and cytochemistry of the hemocytes of Mytilus edulis and their responses to experimentally injected carbon particles

Hemocytes of Mytilus edulis were examined cytologically and cytochemically. On the basis of structure, staining reactions, and phagocytic behavior, they were divided into two main groups: basophilic hemocytes and eosinophilic granular hemocytes (granulocytes). The basophilic cells were further divided into small lymphocytes and larger phagocytic macrophages reactive for lysosomal hydrolases. Mitosis was observed in granulocytes and in small lymphoid cells, believed to be the stem cells for the basophilic cell line. A few cells appeared to be intermediate between lymphocytes and small granulocytes. Macrophages were the main cell type involved in the clearance of injected carbon particles. However, granulocytes did show some phagocytic activity. Brown cells displaying apparent amoebocytic behavior were found to contain Fe³⁺ and Pb²⁺ in cytoplasmic inclusions, some of which were also reactive for β-glucuronidase and glucosaminidase. These cells appear to have a separate origin from the hemocytes.     

Categorization of hemocytes of three gastropod species Trachea vittata (Muller), Pila globosa (Swainson) and Indoplanorbis exustus (Dehays)

Light microscopic observations were made on the hemocytes of three gastropod species namely Trachea vittata, Indoplanorbis exustus and Pila globosa. It revealed two basic types of hemocytes. They are agranulocytes and granulocytes. Agranulocytes are hyalinocytes which are round, unspread hemocytes and have a large nucleo-cytoplasmic ratio. Granulocytes are spreading hemocytes, forming numerous pseudopodia. For the purpose of differential counting, we present a categorization of the granulocytes into three sub-categories based on cell dimensions, nucleo-cytoplasmic ratio, distribution of granules in the cytoplasm and position of the nucleus. The smaller granulocytes are younger cells, and are termed Granulocytes I (Progranulocytes). The larger ones are fully developed cells that have been differentiated into Granulocyte II (basophilic) and Granulocyte III (eosinophilic).     

Immune Defenses of the Invasive Apple Snail Pomacea canaliculata (Caenogastropoda,Ampullariidae): Phagocytic Hemocytes in the Circulation and the Kidney

Hemocytes in the circulation and kidney islets, as well as their phagocytic responses to microorganisms and fluorescent beads, have been studied in Pomacea canaliculata, using flow cytometry, light microscopy (including confocal laser scanning microscopy) and transmission electron microscopy (TEM). Three circulating hemocyte types (hyalinocytes, agranulocytes and granulocytes) were distinguished by phase contrast microscopy of living cells and after light and electron microscopy of fixed material. Also, three different populations of circulating hemocytes were separated by flow cytometry, which corresponded to the three hemocyte types. Hyalinocytes showed a low nucleus/cytoplasm ratio, and no apparent granules in stained material, but showed granules of moderate electron density under TEM (L granules) and at least some L granules appear acidic when labeled with LysoTracker Red. Both phagocytic and non-phagocytic hyalinocytes lose most (if not all) L granules when exposed to microorganisms in vitro. The phagosomes formed differed whether hyalinocytes were exposed to yeasts or to Gram positive or Gram negative bacteria. Agranulocytes showed a large nucleus/cytoplasm ratio and few or no granules. Granulocytes showed a low nucleus/cytoplasm ratio and numerous eosinophilic granules after staining. These granules are electron dense and rod-shaped under TEM (R granules). Granulocytes may show merging of R granules into gigantic ones, particularly when exposed to microorganisms. Fluorescent bead exposure of sorted hemocytes showed phagocytic activity in hyalinocytes, agranulocytes and granulocytes, but the phagocytic index was significantly higher in hyalinocytes.Extensive hemocyte aggregates (''islets'') occupy most renal hemocoelic spaces and hyalinocyte-like cells are the most frequent component in them. Presumptive glycogen deposits were observed in most hyalinocytes in renal islets (they also occur in the circulation but less frequently) and may mean that hyalinocytes participate in the storage and circulation of this compound. Injection of microorganisms in the foot results in phagocytosis by hemocytes in the islets, and the different phagosomes formed are similar to those in circulating hyalinocytes. Dispersed hemocytes were obtained after kidney collagenase digestion and cell sorting, and they were able to phagocytize fluorescent beads. A role for the kidney as an immune barrier is proposed for this snail.     

Cell types and hydrolytic enzymes of soft shell clam (Mya arenaria) hemocytes

Hemocytes of the soft shell clam, Mya arenaria, based on appearance after Romanowsky-type staining, can be shown to be either granulocytes or agranulocytes comprising 76.5 and 23.5% of the total cell population, respectively. Cytoplasmic granules are basophilic, eosinophilic, or refractile. Cytochemical studies indicate that these cells are markedly heterogeneous with respect to certain hydrolytic lysosomal enzymes and in cytoplasmic glycogen and lipofuscin. The overall activities of these enzymes in clam hemocytes, as estimated by the number of reactive sites, were unrelated to one another. Using consecutive double-staining techniques, individual cells were also found to vary in their enzyme content. These findings emphasize the biochemical individuality of circulating hemocytes and the variations noted probably reflect differences in number and composition of lysosomes.     

Hemocytes of Bulinus truncatus rohlfsi (Mollusca: Gastropoda)

Two basic cell types occur in the hemolymph of Bulinus truncatus rohlfsi: granulocytes and hyalinocytes. Granulocytes are divided into three subtypes: (1) Granulocytes I, which account for 19% of the hemocytes, are small, young amoebocytes with 1–20 filopodia and small numbers of cytoplasmic granules, including some lysosomes; (2) granulocytes II, which account for 78% of the cells, are large, fully developed amoebocytes that possess 1–20 filopodia and many granules, both acidophilic and basophilic, including numerous lysosomes, phagosomes, and mitochondria; and (3) spent granulocytes, which are rare, have few filopodia, large accumulations of glycogen granules and prominent vacuoles in addition to lysosomes in the cytoplasm. These three subtypes of granulocytes probably represent ontogenetic stages within a single cell line. In addition, granulocytes with 40 or more filopodia and little ectoplasm, found in only 1 of 45 snails examined, probably reflect a pathologic condition. Hyalinocytes, which account for 3% of all hemocytes, are similar in size to mature granulocytes, but have few or no cytoplasmic granules and lack filopodia and glycogen granules. Total hemocyte concentration in hemolymph is 328,000 ± 188,000 cells/ml.     

Haemocyte morphology and function in the Akoya Pearl Oyster, Pinctada imbricata

The morphology and cytochemistry of Pinctada imbricata haemocytes were studied in vitro. Three distinct blood cell types were identified; hyalinocytes, granulocytes, and serous cells. Haemocytes were classified based on the presence/absence of granules, and nucleus to cytoplasm ratio. Granulocytes were the most common cell type (62 ± 2.81%), followed by hyalinocytes (36 ± 2.35%), and serous cells (2 ± 0.90%). Granulocytes, and hyalinocytes were found to be immunologically active, with the ability to phagocytose Congo red stained yeast. Of the cells involved in phagocytosis, granulocytes were the most active with 88.8 ± 3.9% of these haemocytes engulfing yeast. Cytochemical stains (phenoloxidase, peroxidase, superoxide, melanin, neutral red) showed that enzymes associated with phagocytic activity were localised in granules within granulocytes. Based on their affinities for Giemsa/May-Grünwald stain, haemocytes were also defined as either acidic, basic or neutral. Hyalinocytes and serous cells were found to be eosinophilic, whilst granulocytes were either basophilic (large granulocytes), eosinophilic (small granulocytes) or a combination of the two (combination granulocytes). Light, differential interference contrast and epi-fluorescence microscopy identified three sub-populations of granulocytes based on size and granularity; small (4.00-5.00 μm in diameter, with small granules (0.05-0.5 μm in diameter), large (5.00-9.00 μm in diameter, with large granules (0.50-2.50 μm in diameter) and combination (5.00-9.00 μm in diameter, with both large and small granules). These observations demonstrate that P. imbricata have a variety of morphologically and functionally specialized haemocytes, many of which maybe associated with immunological functions.     

Morula-like cells in photo-symbiotic clams harboring zooxanthellae

Symbiosis is observed between zooxanthellae, symbiotic dinoflagellates, and giant clams and related clams which belong to the families Tridacnidae and Cardiidae. We have previously shown that a photo-symbiotic clam Tridacna crocea has three types of hemocytes, the eosinophilic granular hemocyte with phagocytic activity, the agranular cell with electron lucent granules, and the morula-like cell with large (ca. 2 mum in diameter) colorless granules. The function of the morula-like cell is not clear, but it has not been reported in any other bivalves except photo-symbiotic clams T. crocea and Tridacna maxima. In order to clarify whether it is specific to photo-symbiotic clams or not, we studied hemocytes in the photo-symbiotic clams Tridacna derasa (Tridacnidae), Hippopus hippopus (Tridacnidae) and Corculum cardissa (Cardiidae), and a closely related non-symbiotic clam Fulvia mutica (Cardiidae). The eosinophilic granular hemocytes and the agranular cells were found in all of the clams examined. However, the morula-like cells which were packed with many large electron dense granules (ca. 2 mum in diameter), were observed only in the photo-symbiotic clams. In F. mutica, a closely related non-symbiotic clam, this type of hemocyte was not found. Instead a hemocyte with vacuoles and a few large granules containing peroxidase activity was observed. The large granules of F. mutica varied in size from ca. 1-9 mum in diameter. Present data suggests that the presence of morula-like cells is restricted to photo-symbiotic clams and that the hemocytes associated with the morula-like cells may have some functional relationship to symbiosis with zooxanthellae.     

圆背角无齿蚌血细胞培养

用新设计的培养基培养了圆背角无齿蚌的血细胞,在倒置相差镜下进行了活体观察及扫描电镜摄影,发现培养的血细胞无颗粒细胞、颗粒细胞、透明细胞和类淋巴细胞,前三者均能伸出长的伪足和突起,与瓶壁紧密贴附,呈体外培养的成纤维细胞型;后者呈圆形,不与瓶壁贴附;四者的比例约为4：2：3：1。在活体内注射或在培养基上加入PHA和ConA,培养2－7d中,每天取部分供加入秋水仙素,用空气干燥法制片,作染色体观察,但未观察到转化细胞和有丝分裂相。研究结果表明,圆背角无齿蚌的颗粒细胞、无细胞和透明细胞在体外贴附玻璃表面的特征与高等动物的巨噬细胞类似,而不贴瓶的圆形细胞与高等动物的淋巴细胞类似,但在体外培养均不能繁殖,它们可能是高度分化的细胞。     

贝类血细胞硫代黄素T荧光染色方法

硫代黄素T( thioflavin T,TFT)是一种用于组织学的苯并噻唑荧光染料,因其对淀粉样蛋白有高亲和性而主要被用于淀粉样病变的荧光显微检测.本研究分别以软体动物门双壳纲的栉孔扇贝(Chlamys farreri)和中国蛤蜊(Mactra chinensis)、腹足纲的拟紫口玉螺(Natica janthosto...     

Hemocytes of the palaemonids Macrobrachium rosenbergiiand M. acanthurus,and of the Penaeid Penaeus paulensis

The hemocytes of two palaemonids and one penaeid were characterized using light and transmission electron microscopy (TEM). The blood cells in all three species were classified as hyaline hemocytes (HH), small granule hemocytes (SGH), and large granule hemocytes (LGH). The HH are unstable hemocytes with a characteristic high nucleo-cytoplasmic ratio. Their cytoplasm appears particularly dense and has from few to numerous granules that often exhibit a typical striated substructure. In both palaemonids, the great majority of the HH contain numerous granules, whereas in Penaeus paulensis, a small number of these cells have few or no granules. The cytoplasm of some HH of the penaeid exhibits typical electron-dense deposits. The granulocytes, LGH and SGH, contain abundant electron-dense granules that are usually smaller in the SGH. In both hemocyte types, the cytosol, but not the granules, is rich in carbohydrates (PAS positive) and numerous vesicles contain acid phosphatase (Gomori reactive). In all studied shrimps, the SGH and LGH were actively phagocytic when examined on blood cell monolayers incubated with the yeast Saccharomyces cerevisiae. A few mitotic figures (less than 1%) were observed in the granulocytes of P. paulensis, but not in the palaemonids. SGH is the main circulating blood cell type in both palaemonids, whereas HH is predominant in the penaeid. Based on morphological and functional features, it appears that the hyaline and the granular hemocytes of the three shrimp species represent different cell lineages. J. Morphol. 236:209–221, 1998. © 1998 Wiley-Liss, Inc.     

Unaltered hematocrit values and differential hemocyte counts in acanthocephalan-infected Armadillidium vulgare

Three cell types were present in Armadillidium vulgare hemolymph. Hyaline cells, 8.2 to 12.0 μm in size with a few fine granules in the cytoplasm, comprised 42% of the cells. Twelve percent of the cells were nonexplosive granulocytes, 8.8 to 15.0 μm, with many cytoplasmic granules of medium size. A third cell type, an explosive 7.2- to 12.0-μm granulocyte with coarse cytoplasmic granules, comprised 46% of the cells. Within 48 hr after adult specimens of A. vulgare were fed eggs of the acanthocephalan, Plagiorhynchus cylindraceus, isopod hemocytes aggregated in the intestinal epithelium surrounding penetrating acanthors. Encapsulation and death of the parasite routinely followed. No significant difference in hematocrit values or in differential hemocyte counts occurred between infected and uninfected control isopods.     

Sydney rock oyster (Saccostrea glomerata) hemocytes: morphology and function

In this study, three major hemocyte types were identified in the Sydney rock oyster. They were characterized primarily by light and electron microscopy based on the presence or absence of granules and nucleus to cytoplasm ratios. Hemoblast-like cells were the smallest cell type 4.0+/-0.4microm and comprised 15+/-3% of the hemocyte population. They had large nuclei and scanty basic cytoplasm. This cell type also had some endoplasmic reticuli and mitochondria. The second major type were hyalinocytes. Hyalinocytes represented 46+/-6% of all hemocytes. They were large cells (7.1+/-1.0microm) that had low nucleus:cytoplasm ratios and agranular basic or acidic cytoplasm. Hyalinocytes had the ability to phagocytose yeast cells and formed the core of hemocyte aggregates associated with agglutination. Four discrete sub-populations of hyalinocytes were identified. The third major cell type were the granulocytes, comprising 38+/-1% of the hemocyte population. These cells were large (9.3+/-0.3microm) and were characterized by cytoplasm containing many acidic or basic granules. Granulocytes were more phagocytic than hyalinocytes and they formed the inner layer of hemocytes during the encapsulation of fungal hyphae. Five discrete sub-populations of granulocytes were identified based on the types of granules in their cytoplasm. Flow cytometry showed that the hemocytes of rock oysters could be divided into between two and four major cell types based on their light scattering properties. The most common of the cell types identified by flow cytometry corresponded to hyalinocytes and granulocytes. Cytochemical assays showed that most enzymes associated with immunological activity were localized in granulocytes. Their granules contained acid phosphatase, peroxidase, phenoloxidase, superoxide and melanin. Hyalinocytes were positive only for acid phosphatase. All of these observations suggest that Sydney rock oysters have a broad variety of functionally specialized hemocytes, many of which are involved in host defense.     

Soluble and surface-bound aminopeptidase in eosinophilic blood cells from Mytilus edulis

This study focused on soluble and surface-bound aminopeptidase (AP) in hemocytes from Mytilus edulis and on the identification of the enzyme-producing blood cells. The cell extract hydrolyzed alanine p-nitroanilide (Ala-pNA) with an optimum between pH 6.4 and 7.0. Following native gradient PAGE of extract, alanyl methoxy-naphthylamide (AMNA) was converted by one band with an estimated molecular weight of 375 kDa; it included at least ten putative AP-isozymes with isoelectric points between pH 4.5 and 5.8. In addition to this soluble form, electron microscopy revealed simultaneous conversion of AMNA on the surface of blood cells. Individual mussels expressed AP-molecules in 23-39% of their hemocytes. These cells were shown to represent eosinophilic granulocytes.     

First characterisation of the populations and immune-related activities of hemocytes from two edible gastropod species,the disk abalone,Haliotis discus discus and the spiny top shell,Turbo cornutus

The disk abalone Haliotis discus discus and the spiny top shell Turbo cornutus are edible gastropod species of high economic value, mainly in Asia. Mortality outbreaks and variations in worldwide stock abundance have been reported and suggested to be associated, at least in part, with pathogenic infections. Ecology, biology and immunology of both species are currently not well documented. The characterisation of the immune systems of these species is necessary to further assess the responses of H. discus discus and T. cornutus to environmental, chemical and disease stresses. In the present study, we investigated the morphology and immune-related activities of hemocytes in both species using light microscopy and flow cytometry. Two types of hemocytes were identified in the disk abalone hemolymph, blast-like cells and hyalinocytes; whereas four main hemocyte types were distinguished in the spiny top shell, blast-like cells, type I and II hyalinocytes, and granulocytes. Flow cytometric analysis also revealed differences between cell types in immune-related activities. Three subsets of hemocytes, defined by differing lysosomal characteristics, were observed in the hemolymph of the spiny top shell, and only one in the disk abalone. Phagocytic activity was higher in H. discus discus hemocytes than in T. cornutus hemocytes, and the kinetics of PMA-stimulated oxidative activity was different between hemocytes of the disk abalone and the spiny top shell. Finally our results suggest for the first time a predominant mitochondrial origin of oxidative activity in gastropod hemocytes.     

A comparative analyses of morphological variations,phagocytosis and generation of cytotoxic agents in flow cytometrically isolated hemocytes of Indian molluscs

A comparative analyses of hemocytes of molluscs, Pila globosa (Gastropoda: Prosobranchia), Bellamya bengalensis (Gastropoda: Prosobranchia) and Lamellidens marginalis (Bivalvia: Eulamellibranchiata) were carried out for morphotype and subpopulation identification, analyses of phagocytosis and generation of cytotoxic agents. Flow cytometry and microscopic analyses of hemocytes revealed the existence of agranulocytes (blast like cells, round hyalinocytes and spindle hyalinocytes), semigranulocytes (semigranular asterocytes and round semigranulocytes) and granulocytes (round granulocytes, spindle granulocytes and granular asterocytes) as three morphotypes. In P. globosa, granulocytes and semigranulocytes and in B. bengalensis granulocytes and agranulocytes are the chief phagocytes and major producers of superoxide anion and nitric oxide. In L. marginalis, granulocytes were identified as principal phagocytes with prominent activity of superoxide anion and nitric oxide. Highest activity of phenoloxidase was recorded in the agranulocytes of P. globosa with moderate activities among other morphotypes of all three species. Differential result may be due to species specific response, non-identical habitat preference and related adaptation of the species to their different ecological niches.     

Ultrastructures and classification of circulating hemocytes in 9 botryllid ascidians (chordata: ascidiacea)

Ultrastructures of circulating hemocytes were studied in 9 botryllid ascidians. The hemocytes are classified into five types: hemoblasts, phagocytes, granulocytes, morula cells, and pigment cells. These five types are always found in the 9 species. They should represent the major hemocyte types of the circulating cells in the blood. Hemoblasts are small hemocytes having a high nucleus/cytoplasm ratio. There are few granular or vacuolar inclusions in the cytoplasm. Phagocytes have phagocytic activity and their shape is variable depending on the amount of engulfed materials. In granulocytes, shape and size of granules are different among the species. Morula cells are characterized by several vacuoles filled with electron dense materials. In pigment cells, the bulk of the cytoplasm is occupied by one or a few vacuoles containing pigment granules. We also described some other hemocyte types found in particular species. Furthermore, we encountered free oocytes circulating in the blood in two species, Botryllus primigenus and Botrylloides lentus.