The hemocytes of an lsopod Ligia exotica Roux

The morphological features of the hemocytes of the crustacean Ligia exotica are similar to hemocytes of insects and millipedes. Jones system of hemocyte classification is extended to crustacean hemocytes. As in insects, seven classes of hemocytes, identified as prohemocytes, plasmatocytes, granular hemocytes, cystocytes, oenocytoids, spherule cells and adipohemocytes, occur. The prohemocytes can be subdivided into five categories that probably represent the precursor of major cell types. The structural and chemical features of other major cell classes are distinct and support the concept of Jones ('62) that these types might have different lineages and might not be capable of transforming into one another. Some of the prohemocytes, plasmatocytes and granular hemocytes are amoeboid. Cystocytes do not bring about any visible plasma coagulation similar to their counterpart in millipedes. Oneocytoids and adipohemocytes are rare. Plasmatocytes, cystocytes and oenocytoids occur in conglomerates, the significance of which is discussed. The cell types are compared with those of the hemocytes of other crustaceans. It is suggested that the nomenclature based on morphological characters is more suited for crustacean hemocytes than a nomenclature based on behavioural and physiological characters.     

Morphology and differential counts of hemocytes of healthy and wound tumor virus-infected Agallia constricta

Six types of hemocytes were found in Agallia constricta leafhoppers: plasmatocytes, spherule cells, granular hemocytes, adipohemocytes, oenocytoids, and prohemocytes. Plasmatocytes, spherule cells, and granular hemocytes accounted for 90–95% of all hemocytes in numphs and adult leafhoppers. As the insect aged from second- and third-instar nymphs to 7- and 8-week-old adults, there was a significant decrease in plasmatocytes in healthy leafhoppers compared to wound tumor virus-infected insects. In contradistinction, there were more granular and spherule hemocytes in healthy leafhoppers than in virus-infected ones as the insects aged. In general, there were more prohemocytes in infected than in healthy leafhoppers. Plasmatocytes from 4- to 8-week-old, infected leafhoppers contained large irregularly shaped, cytoplasmic inclusions. Electron microscopy of these cells showed that the inclusions were either large accumulations of wound tumor virus particles or virus-free electron dense bodies.     

Aspects of classification of Hemiptera hemocytes from six triatomine species.

The objective of this work was to characterize, and compare different morphological types of hemocytes of Rhodnius prolixus, Rhodnius robustus, Rhodnius neglectus, Triatoma infestans, Panstrongylus megistus, and Dipetalogaster maximus. This information provides the basis for studying the cellular immune systems of these insects. Seven morphological hemocyte types were identified by phase-contrast microscopy: prohemocytes, plasmatocytes, granular cells, cystocytes, oenocytoids, adipohemocytes and giant cells. All seven types of hemocytes are not present in every species. For example, adipohemocytes and oenocytoids were not observed in P. megistus and P. infestans, and giant cells were rarely found in any of the species studied. The hemocytes of Rhodnius and Dipetalogaster are more similar to each other than those from Triatoma and Panstronglus which in turn closely resemble each other. Emphasis is placed on methodological problems arising in this work which are discussed in detail.     

Monoclonal antibodies bind distinct classes of hemocytes in the moth Pseudoplusia includens

Insect hemocytes have historically been identified on the basis of morphology, ultrastructure and hypothesized function. Among insects in the order Lepidoptera, five hemocyte classes are usually recognized: granular cells, plasmatocytes, spherule cells, oenocytoids and prohemocytes. We have generated a panel of monoclonal antibodies (mAbs) against hemocytes of the moth Pseudoplusia includens. In this study, hemocyte identification using 16 different mAbs was compared to identification methods using morphological characters. Three main categories of mAb binding activity were identified: (1) mAbs that specifically labeled only one morphological class of hemocytes, (2) mAbs that labeled granular cells and spherule cells, and (3) mAbs that labeled plasmatocytes and oenocytoids. With one exception, none of the antibodies bound to other tissues in P. includens. However, certain mAbs that specifically labeled granular cells and/or spherule cells in separated hemocyte populations also labeled plasmatocytes co-cultured with granular cells or cultured in granular cell conditioned medium. Overall, our results suggest that granular cells are antigenically related to spherule cells, and that plasmatocytes are antigenically related to oenocytoids. The use of mAbs as hemocyte markers are discussed.     

Hemocytes and hemocytopoiesis in Silkworms.

A brief review is presented of the current state of ultrastructure, cytochemistry, and physiology of the hemocytes and meso- and metathoracic peri-imaginal-wing organs in silkworms. According to the accepted morphological classification, five circulating types of hemocytes are recognized in Bombyx mori as well as in Antheraea pernyi. They are prophemocytes or stem cells, plasmatocytes or pre-differentiated cells and three specialized cells, granulocytes, spherule cells and oenocytoids. During post-embryonic development the last four types are the most common in the circulating hemolymph. Plasmatocytes are considered to be pluripotent cells from which granulocytes, spherule cells and oenocytoids are derived. Contrary to the situation in most insects the plasmatocytes are not phagocytic in Antheraea. The granulocytes are efficient phagocytes. Both plasmatocytes and granulocytes are involved in pinocytosis. Another possible function of the granulocytes is hemolymph coagulation. The function of the spherule cells which contain a paracrystalline material (muco- or glycoproteins) is by no means clear. The phenoloxidase activity found within the cytosol of oenocytoids appears effective against the natural monophenol and diphenol substrates. The involvement of oenocytoids in the complex metabolism of phenols and particularly in the production of plasma phenolases has been reported. The mitotic division of five circulating hemocyte types is well known and was long regarded as the only mechanism of postembryonic hemocyte production. We present for silkworms, experimental evidence of the hemocytopoietic function of the meso- and metathoracic organs surrounding the imaginal wing discs. Ablation experiments demonstrate that the mitotic activity of free hemocytes is unable to maintain the normal hemocytogram in the absence of the two paris of organs. These organs are typically divided into cell islets ensheathed by a connective tissue membrane. Two types of islets may be classified by the disposition of the cells : the compact islets or aggregations of stem cells and the reticulate islets which are mainly composed of hemocytes at different steps of differentiation. The relative number of prohemocytes in the total hemocyte population ranges from 84 to 97 p. cent in organs of Antheraea pernyi. This well-defined cell type appears to be the major hemocyte type in hemocytopoietic organs. In Antheraea, the mitotic index (the relative number of mitotic hemocytes in the total cell population) varies from 0.5 to about 3 p. cent. Finally, our data direct attention to cyclic functional changes such as mitotic divisions and hemocyte differentiation which run parallel to the molting cycle.     

Hemocyte differentiation in the hematopoietic organs of the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>: prohemocytes have the function of phagocytosis

Hemocytes isolated from the larval hematopoietic organs of the silkworm were classified following staining with acridine orange and propidium iodide. Among the hemocytes isolated from the hematopoietic organs of whole fifth larval and wandering stages, most were prohemocytes (60%–70%) and oenocytoids (30%–40%). Granulocytes comprised only about 0.5%–1% at the wandering stage and were even rarer at other stages; no spherulocytes or plasmatocytes were found. Therefore, hemocyte differentiation inside larval hematopoietic organs is not as extensive as previously thought. Following 10–30 min in vitro culture of hemocytes isolated from larval hematopoietic organs, many young granulocytes and plasmatocytes appeared. Furthermore, during phagocytosis assays, prohemocytes were seen to adopt the morphology of plasmatocytes, containing fragments of phagocytosed cells. Our results underline the similarities between Drosophila and Bombyx hematopoiesis.     

Characterization of the Hemocytes in Larvae of Protaetia brevitarsis seulensis: Involvement of Granulocyte-Mediated Phagocytosis

Hemocytes are key players in the immune response against pathogens in insects. However, the hemocyte types and their functions in the white-spotted flower chafers, Protaetia brevitarsis seulensis (Kolbe), are not known. In this study, we used various microscopes, molecular probes, and flow cytometric analyses to characterize the hemocytes in P. brevitarsis seulensis. The circulating hemocytes were classified based on their size, morphology, and dye-staining properties into six types, including granulocytes, plasmatocytes, oenocytoids, spherulocytes, prohemocytes, and adipohemocytes. The percentages of circulating hemocyte types were as follows: 13% granulocytes, 20% plasmatocytes, 1% oenocytoids, 5% spherulocytes, 17% prohemocytes, and 44% adipohemocytes. Next, we identified the professional phagocytes, granulocytes, which mediate encapsulation and phagocytosis of pathogens. The granulocytes were immunologically or morphologically activated and phagocytosed potentially hazardous substances in vivo. In addition, we showed that the phagocytosis by granulocytes is associated with autophagy, and that the activation of autophagy could be an efficient way to eliminate pathogens in this system. We also observed a high accumulation of autophagic vacuoles in activated granulocytes, which altered their shape and led to autophagic cell death. Finally, the granulocytes underwent mitotic division thus maintaining their number in vivo.     

Ultrastructure of the hemocytes of Cetonischema aeruginosa larvae (Coleoptera,Scarabaeidae): involvement of both granulocytes and oenocytoids in in vivo phagocytosis

In the context of comparative studies on immunity defence mechanisms of adults and larvae of the coleopteran Cetonischema aeruginosa (Drury, 1770) the ultrastructure of the circulating hemocytes of the third instar larval stage has been investigated by means of light and transmission electron microscopy (TEM). Six types of hemocytes were found in the hemolymph of C. aeruginosa and they were identified as prohemocytes, granulocytes, plasmatocytes, coagulocytes, oenocytoids and spherule cells. In order to identify the "professional" phagocyte cell, phagocytosis assays were performed in vivo by injection of 0.9 microm carboxylate-modified polystyrene latex beads. It was demonstrated that the granulocytes and the oenocytoids of C. aeruginosa were the only hemocyte types involved in this cellular response.     

黑翅痂蝗血细胞形态学的研究

【目的】蝗虫血细胞的研究以及不同血细胞类型间的演化关系,是蝗虫细胞免疫学的依据,也是防蝗治蝗的重要依据。【方法】本研究通过Wright-Giemsa对黑翅痂蝗Bryodema nigroptera Zheng血细胞进行了混合染色,并使用光学显微镜进行了观察。【结果】发现黑翅痂蝗血细胞包括原血胞、浆血胞、粒血胞、类绛色血细胞、囊血胞、脂血胞、蠕形细胞和巨核血细胞8种类型。【结论】在成虫体内,原血胞占细胞总数的1%,浆血胞占32.2%,粒血胞占57.3%,类绛色血细胞占1%,囊血胞占6%,脂血胞占1%,蠕形细胞占1%,巨核细胞占细胞总数的0.5%,粒血胞数量最多,巨核细胞最少。     

Correlation of light and electron microscopic hemocyte structue in the dictyoptera

As part of program of research into insect cellular immunity, an integrated light and electron microscopic study of the hemocytes of seven members of the Order Dictyoptera has been made. In fresh hemolymph, five cell types, the prohemocytes, plasmatocytes, granular cells, spherule cells and cystocytes, are easilv distinguished. However, in thick Araldite sections and in thin sections in the electron microscope it is sometimes difficult to identify the various cell types. The reasons for this difficulty are discussed. Granules with a microtubular substrcture are found in the plasmatocytes, spherule cells and cystocytes. In the plasmatocytes these granules have a different ultrastructure than those in the spherule cells and cystocytes. The in vitro fragility of these granules in both the spherule cells and cystocytes during coagulation partially explains the previous confusion in distinguishing these two cell types. Evidence is presented which indicates that the plasmatocytes, granular cells and spherule cells represent a developmental series originating from the prohemocytes. Where exactly the cystocytes are derived from is unknown.     

The hemocytes of Panstrongylus megistus (Hemiptera: Reduviidae)

Five hemocyte types were identified in the hemolymph of Panstrongylus megistus by phase contrast and common light microscopy using some histochemical methods. These are: Prohemocytes, small cells presenting a great nucleus/cytoplasm ratio; Plasmatocytes, the most numerous hemocytes, are polymorphic cells mainly characterized by a large amount of lysosomes; Granulocytes, hemocytes very similar to plasmatocytes which contain cytoplasmic granules and are especially rich in polysaccharides; Oenocytoids, cells presenting a small nucleus and a thick cytoplasm; they show many small round vacuoles when observed in Giemsa smears and many cytoplasmic granules under phase microscopy; Adipohemocytes, very large hemocytes, presenting many fat droplet inclusions which could correspond to free fat bodies which entered the hemolymph. Only prohemocytes and plasmatocytes can be clearly classified; all the other hemocyte types have a more ambiguous classification.     

Comparative study of hemocytes and associated cells of some medically important dipterans

The aim of this work is to study, characterize, and compare different morphological types of hemocytes of Glossina austeni, G. morsitans, Calliphora erythrocephala, Stomoxys calcitrans, Lucilia sericata, Aedes aegypti, and Culex quinquefasciatus. This information is intended to provide a basis for future studies of the cellular defense mechanisms of these dipterans. Seven morphological types of hemocytes were identified by phase-contrast optics: prohemocytes, plasmatocytes, thrombocytoids, granulocytes, adipohemocytes, oenocytoids, and spindle cells of various sizes. Adipohemocytes are difficult to distinguish from both fat body cells and granulocytes. All seven cell types are not present in every species. For example, thrombocytoids and spindle cells were not found in A. aegypti or C. quinquefasciatus, and oenocytoids were observed only in A. aegypti, C. quinquefasciatus, and in C. erythrocephala. In addition to the hemocytes, fat body cells and nephrocytes are also freely present in the hemolymph of some species but may have gained access to the blood during the bleeding process. With electron microscopy and with thick plastic sections of G. austeni hemolymph, only nephrocytes, plasmatocytes, granulocytes, and spindle cells were identified with any certainty, and the large spindle cells are morphologically very different from those found in the other dipterans. They are rigid cells supported by microtubules running throughout their entire length. These hemocytes are present in large numbers only in newly emerged flies, they are absent in larvae and young pupae, and are rare in old adults. Their disappearance from the hemolymph of newly emerged Glossina appears to be a result of phagocytosis by the plasmatocytes.     

The hemocytes of Heliothis armigera: Ultrastructure,functions, and evolution in the course of larval development

Five types of hemocytes, prohemocytes, typical plasmatocytes, coagulocytes, spherule cells, and oenocytoides, have been defined in the last larval instar of Heliothis armigera on the basis of ultrastructural microscopy, smears, and optical phase-contrast microscopy. Modifications in typical plasmatocytes and coagulocytes have been evidenced in the course of development in this instar, which suggests that these hemocytes are involved in physiological processes of development. Only coagulocytes exhibit endocytotic capacities. Phenoloxidase activity was observed in oenocytoides.     

A systematic study on hemocyte identification and plasma prophenoloxidase from Culex pipiens quinquefasciatus at different developmental stages

Culexpipiens quinquefasciatus (C. quinquefasciatus) is an important vector that can transmit human diseases such as West Nile virus, lymphatic filariasis, Japanese encephalitis and St. Louis encephalitis. However, very limited research concerning the humoral and cellular immune defenses of C. quinquefasciatus has been done. Here we present the research on hemocyte identification and plasma including hemocyte prophenoloxidase from C. quinquefasciatus at all developmental stages in order to obtain a complete picture of C. quinquefasciatus innate immunity. We identified hemocytes into four types: prohemocytes, oenocytoids, plasmatocytes and granulocytes. Prophenoloxidase (PPO) is an essential enzyme to induce melanization after encapsulation. PPO-positive hemocytes and plasma PPO were observed at all developmental stages. As for specific hemocyte types, prophenoloxidase was found in the plasmatocytes at larval stage alone and in the smallest prohemocytes during almost all developmental stages. Moreover, the granulocytes were PPO-positive from blood-fed female mosquitoes and oenocytoids were observed PPO-positive in pupae and in adult females after blood-feeding. As for plasma, there were different patterns of PPO in C. quinquefasciatus at different developmental stages. These results are forming a basis for further studies on the function of C. quinquefasciatus hemocytes and prophenoloxidase as well as their involvement in fighting against mosquito-borne pathogens.     

Hemocytes of the cochineal insect: ultrastructure

Using transmission electron microscopy, light microscopy (Giemsa May‐Grumwald), and the Periodic Acid‐Schif (PAS) and Sudan Black B staining techniques, hemocytes in the hemolymph of adult female Dactylopius coccus were characterized. The following, in order of abundance, were found: granulocytes, plasmatocytes, prohemocytes, and oenocytoids. Granulocytes varied in size with granulations in the cytoplasm, a large quantity of mitochondria, rugose endoplasmatic reticulum, ribosomes and vesicles, central or exocentric, spherical and occasionally lobulate nucleus. Plasmatocytes were polymorphic with irregularities in the plasma membrane; cytoplasm contained mitochondria, rugose endoplasmatic reticulum and vesicles, and exocentric, spherical, or irregular nucleus. In both types of hemocytes, scant polysaccharides and lipids were found. Prohemocytes were small and spherical with homogeneous cytoplasm and large exocentric nuclei. Oenocytoids were oval or irregular with dense homogeneous cytoplasm and elongated exocentric nuclei. The percentages of granulocytes on different days (d 1 and 10) during the life of the adult female were significantly different, as were those of plasmatocytes on d 30 and 50 and prohemocytes on d 1 and 50. © 2010 Wiley Periodicals, Inc.     

幼虫密度对草地螟血细胞数量和组成的影响

为了阐明幼虫密度对草地螟Loxostege sticticalis L.（鳞翅目： 螟蛾科）细胞免疫能力的影响, 本研究调查了在活体灰菜植株上1,5,10和20头/瓶（900 mL）4种密度条件下的其5龄幼虫血细胞种类、数量和组成。结果表明： 草地螟幼虫血淋巴中有原血细胞、浆血细胞、 颗粒血细胞、珠血细胞和类绛色血细胞等5种（类）血细胞。血细胞总数、 浆血细胞、颗粒血细胞数量随幼虫密度的增加而显著递增, 但原血细胞、珠血细胞和类绛色血细胞数量在幼虫密度间的差异不明显;各种血细胞所占血细胞总数的比例在4个密度中的排序相同, 但10和20头/瓶密度下的浆血细胞比例显著高于1头/瓶的,其余4种血细胞的比例在不同密度之间无显著差异。可见, 幼虫密度主要是通过影响草地螟幼虫浆血细胞和颗粒血细胞的数量及血细胞总数, 从而影响草地螟的细胞免疫能力。     

Immunolocalization of prophenoloxidase among hemocytes of the silkworm, Bombyx mori

Silkworm (Bombyx mori) hemocytes were fixed immediately after collection. Thin sections of the hemocytes were stained by an indirect immunogold staining method using rabbit anti-prophenoloxidase/IgG as a primary antibody and colloidal gold coated with goat anti-rabbit/IgG as a secondary antibody. Electron micrographs of the sections revealed that only plasmatocytes and oenocytoids have prophenoloxidase both in cytoplasm and nucleus whereas granulocytes, spherulocytes and prohemocytes do not have appreciable amounts of the proenzyme. Cytoplasmic inclusions of oenocytoids also contain the proenzyme. A wide variety of concentrations of prophenoloxidase was observed among oenocytoids. Plasmatocytes appeared to have less prophenoloxidase than any oenocytoids. Once materials in the granules of granulocyte were discharged into the plasma and formed coagula, they cross-reacted with antiprophenoloxidase/IgG, suggesting that prophenoloxidase was trapped in the coagula by unknown mechanisms. This observation is discussed in relation to the dispute concerning the presence of prophenoloxidase or phenoloxidase in the granulocyte.     

家蚕拟浆细胞具有吞噬功能

目的：通过观察家蚕Bombyx mori吞噬细胞的微细结构,来确定拟绛色细胞是否也具有吞噬功能。方法：用荧光小球微量注射家蚕pnd pS品系的幼虫,经荧光染色剂丫啶橙和碘化丙啶染色循环血细胞后,在荧光显微镜下观察并扫描拍摄。结果：观察发现除颗粒细胞和浆血细胞外,一些原血球细胞（血干细胞）和拟绛色细胞（多酚氧化酶）也能吞噬荧光小球。在拟绛色细胞里还发现许多和颗粒细胞一样的能被丫啶橙染色的颗粒。尽管在小球细胞中没有发现被吞噬的荧光小球,但该类血球有比较多的能被丫啶橙染色的大颗粒,这表明它们可能是已经被吞噬的凋亡小体。结论：除颗粒细胞和浆血细胞外,一些原血球细胞和拟绛色细胞也能吞噬荧光小球。说明拟绛色细胞也具有吞噬功能。     

亚洲玉米螟幼虫血细胞的包囊行为

根据光镜和电镜观察结果,将亚洲玉米螟(Ostrinia furnacalis)幼虫血细胞分为粒细胞、浆细胞、类绛色细胞、原血细胞和球形血细胞五类。调查了幼虫的血细胞总数(THC)和各类血细胞数量(DHC)的变化情况。从三龄末期到五龄第五天期间,幼虫的THC在蜕皮前后会下降,蜕皮后约12h降到最低点,然后又慢慢回升。在五龄幼虫前5d期间,浆细胞在前第三天呈增加趋势,之后开始下降,而粒细胞呈相反趋势。浆细胞和粒细胞具有附着延展性,它们可以附着在载玻片表面,但延展能力不同。血细胞可以迅速黏附在外源物如葡聚糖凝胶珠表面形成包囊,部分包囊会发生黑化现象。体外培养条件下,血细胞也可以形成包囊,其结构与体内形成的包囊差异不大。     

Reexamination of phenoloxidase in larval circulating hemocytes of the silkworm, Bombyx mori

We have developed a modified method to detect phenoloxidase activity on hemocytes by using freshly prepared l-DOPA (1 mg/ml in 35% ethanol) to fix and incubate larval hemocytes. This method is more sensitive than the common method, in which hemocytes were fixed in 4% formaldehyde and then incubated with 2 mg/ml l-DOPA in water separately. Phenoloxidase assayed using this modified method can be inhibited by phenyltiourea (phenoloxidase inhibitor). After incubation with l-DOPA solution in ethanol, most prohemocytes, all plasmatocytes and young granulocytes are stained brown due to oxidation of l-DOPA into pigments, indicating that they have phenoloxidase. Oenocytoids are dimly stained because many of their cell inclusions have been released during the treatment. Large propidium-iodide-negative prohemocytes have strong phenoloxidase activity and are easily misunderstood as propidium-iodide-positive oenocytoids if the fluorescent method is not used for identification. Thus, in addition to oenocytoids and plasmatocytes, some prohemocytes and granulocytes in the silkworm also have phenoloxidase.