长吻鮠血细胞发生的研究

用Wright-Giemsa和PAS染色对长吻鮠头肾、肾脏、脾脏、肝脏等器官组织的涂片、印片染色观察发现,头肾、肾脏和脾脏是其主要造血器官。红细胞、粒细胞和淋巴细胞主要在肾脏和头肾中发生,其次是脾脏。单核细胞则主要在肾脏和脾脏中发生,头肾中也有少量单核细胞产生。肝脏中无原始型血细胞,可能不是其造血器官。红细胞的发育经历四个阶段,其胞体体积经历了由大到小,由小到大再变小的"两大两小"发育过程;粒细胞的发育经历五个阶段,其胞体体积均由大变小,双叶或多叶核的粒细胞可能是衰老的粒细胞亦即核的分叶是粒细胞衰老的标志;淋巴细胞和单核细胞的发育各经历了三个阶段,两者发育成熟过程中胞体体积均由大变小。巨噬细胞由单核细胞发育而来。原血细胞和部分早期幼稚血细胞可以进行有丝分裂,部分成熟红细胞和血栓细胞可以进行直接分裂。红细胞在整个发育过程中,PAS反应均呈阴性,各类白细胞的发育过程中,PAS反应由阴性到阳性并逐渐增强,这显示随着白细胞的逐渐发育成熟,细胞内糖原物质含量逐渐增多。     

Morphogenesis of blood cell lineages in channel catfish

The morphogenesis of blood cell lineages in channel catfish Ictalurus punctatus , from head and trunk kidney and spleen imprints as well as from blood smears of bled and control fish, showed that early maturation stages resembled those in higher vertebrates. The erythroid lineage consisted of the proerythroblast, erythroblasts (basophilic, polychromatic, orthochromic), young erythrocyte and erythrocyte. The rare bilobed erythrocyte seemed to be a cell in apoptosis while old erythrocytes and erythroplastids represented remnants of this process. Maturation stages of neutrophils and basophils encompassed the granuloblast, young progranulocyte, progranulocyte and metagranulocyte. The basophilic lineage was regularly present in kidneys, rare in spleen and absent from blood. It contained large Sudan Black and PAS-negative, water soluble granules and small PAS-positive ones. Lymphocytes with azurophilic granulation occured regularly in kidneys and spleen. Monoblasts and promonocytes in kidneys preceded monocytes. A phagocytic lineage devouring apoptotic blood cell remnants was present in kidneys and spleen. Its youngest identified stage (promacrophage) resembled more a granuloid cell without granules than a monocytoid one. The larger, young macrophages contained a few to several ingestions and the very large mature macrophages were loaded with them. The latter two stages corresponded to cells in melano-macrophage centres (macrophage aggregates). Precursor stages of the thrombocyte were not identified.     

植物血凝素对兴国红鲤头肾和脾脏的比较组织学研究

PHA注射前后兴国红鲤头肾和脾脏结构基本相同。红鲤头肾有被膜,为淋巴样组织,由许多血管,血窦和淋巴索组成,脾脏是实质性器官,淋巴细胞聚集成团,有弥散的胰腺组织渗入,注射PHA后头肾和脾脏内的大淋巴细胞,小淋巴细胞,巨噬细胞以及原始型细胞显著增加,而粒细胞数量变化不明显。     

Differential proliferation of erythroid and granuloid spleen colonies following sublethal irradiation of the bone marrow donor

Spleen colonies produced by sublethally irradiated mouse bone marrow cells were compared to those produced by unirradiated marrow cells in lethally irradiated mice. Sublethally irradiated marrow cells gave rise to many fewer spleen colonies. At seven days of colony age, the ratio of erythroid colonies to granuloid colonies was lower (< 1) than for colonies formed by unirradiated marrow (2 to 3 or more). Delay of harvest of colonies to day 10 or 12 resulted in 6 to 11 fold increase in the ratio of erythroid to granuloid colonies due largely to the belated appearance of erythroid colonies.     

Vascularization and related distribution of leucocytes in carp, Cyprinus carpio L., head kidney

The distribution of lymphoid cells in the carp head kidney was investigated in relation to the vascular system. Blood vessels in the head kidney were histologically identified into arteries, sinusoids and two types of veins: renal veins and portal, which were distinguished by India ink injection into the caudal vein. By histological and histoplanimetrical observations it was found that the head kidney contained a number of lymphoid cells, which mainly aggregate around the connections between the portal veins and sinusoids, and that the cellular density of the aggregations was higher than in the thymus.
Pigment-containing cell clusters were also observed around these connections. This arrangement of the blood vessels suggests that it is one of the structures able to trap foreign materials, and the occurrence of the lymphoid clusters around the portal veins is a phylogenetic sign of the morphological division between granulopoietic and lymphatic tissues in the carp head kidney.     

The effect of haemorrhage on the cell populations of the thymus and bone marrow in wild starlings (Sturnus vulgaris)

Summary Following the withdrawal of blood from the brachial vein of adult wild starlings (Sturnus vulgaris) changes in the cell populations within the bone marrow and thymus were observed over an eight day period. The packed cell volume, haemoglobin content and reticulocyte count of the peripheral blood was determined before and after haemorrhage.The maximum effect of the haemorrhage was observed in the bone marrow after four days when the population of small lymphocytes, and basophilic erythroid precursors were reduced to less than 1%. At the same time the percentage of another line of erythroid cells increased to 68%. This second erythroid lineage was the major erythroid line in the thymus, and again maximum representation occurred at 4 days post haemorrhage. After this the thymus became predominantly lymphoid and started to increase in size.The two erythroid lines are described and their status with regard to avian thrombocytes is also discussed.The peripheral blood had not attained the pre-haemorrhagic values for reticulocyte counts by eight days although the packed cell volumes and haemoglobin contents were similar.I would like to thank Dr. Peter Ward of the Institute of Terrestrial Ecology for help in obtaining the starlings. Thanks are also due to the staff of the Anatomy Department of St. Thomas's Hospital Medical School, and in particular Mr. Watson. This and other work on the thymus is possible due to the support of the Research (Endowments) Committee of St. Thomas's Hospital     

Detection of mitogen induced stimulation of leukocytes from the rainbow trout (Oncorhynchus mykiss) by flow cytometric analysis of intracellular calcium

Flow cytometric analysis of the forward/side light scatter (FSC/SSC) of density gradient-separated head kidney cells of the rainbow trout revealed three distinctly separated populations, which we defined as population 1, 2 and 3. In spleen cells, populations 1 and 2 were also found, whereas population 3 was not detected. Further characterization regarding the surface Ig (sIg) revealed that population 2 of the head kidney and spleen contained 37.4 and 34.4% sIg⁺-cells, respectively. Incubation of the head kidney and spleen cells with different concentrations of concanavalin A (ConA), phytohemagglutinin (PHA) and [PWM] induced a pronounced intracellular calcium increase only in cells of population 2. This reaction was concentration dependent and caused by a release of intracellular Ca²⁺-stores. FMLP, a chemotactic peptide, had no effect on intracellular calcium response in all three populations. Similarly, the stimulation with PMA had no effect. This indicates that population 2 of the head kidney as well as the spleen is characterized by a high forward and low side light scatter and contains both subpopulation of lymphocytes, B- and T-cells. We demonstrated that the analysis of intracellular calcium increase due to mitogens is a suitable approach to identify lymphocytes in fish and enables further functional studies in these cells.     

The fate of intraperitoneally injected carbon particles in cyprinid fish

Summary The lymphoid organs of rosy barb (Barbus conchonius) and carp (Cyprinus carpio) were investigated for their phagocytic uptake of carbon, after its intraperitoneal injection. Carbon handling was similar in both species. It was first detected in the lymphoid organs at 30 min after injection. During the first day, carbon was phagocytized by macrophages situated in the spleen within the ellipsoids and in the red pulp. In head and trunk kidney, carbon was found in macrophages scattered throughout the haemopoietic parenchyma, and in cells lining the blood sinuses. In the spleen, macrophages replete with carbon left the ellipsoidal structures and formed aggregates with pigment-containing macrophages from day 6 onwards. In all lymphoid organs, almost all carbon was ultimately concentrated in the melano-macrophage centres.     

The development of the lymphoid organs of flounder, Paralichthys olivaceus, from hatching to 13 months

The growth of the lymphoid organs, such as head kidney, spleen and thymus were studied in flounder, Paralichthys olivaceus Temminck & Schlegel, from hatching to 13 months of age. Except for the thymus, all organs grew as the fish grew. By 2 months of age the lymphoid organs attained their maximum relative weight. The organ weight showed a closer correlation to body weight than they did to age. The total number of leucocytes in the lymphoid organs increased with age, but the number per milligram of lymphoid organ remained constant. A micro and ultrastructural study of the lymphoid organs showed that the full development of the lymphoid organs was not achieved until the juvenile stage. The spleen and head kidney had mixed populations of "red" and "white" cells. The head kidney was more lymphoid than the spleen. The thymus involuted quickly during the first 6 months. The blood components had no obvious relationship with age or season during the period studied.     

AN EARLY RESPONSE OF THE MORPHOLOGICALLY RECOGNIZABLE ERYTHROID PRECURSORS TO BLEEDING

⁵⁵Fe autoradiography of the peripheral red blood cells has been used to study the proliferation of the recognizable erythroid precursors in bled animals. The transit time of the recognizable erythroid precursors present in the bone marrow and labelled with ⁵⁵Fe 6 hr before bleeding, remains unchanged, but the number of red cells produced by these precursors is significantly greater than normal. It is deduced that the increased red cell production is brought about by an increase in the number of divisions that the cells undergo during maturation and that a shortening in the red cell cycle time is implied. The possibility that the transit time of the progeny of cells differentiating into pro-erythroblasts after bleeding may be shorter than the transit time of the precursors already differentiated before bleeding, is briefly discussed.     

Plasma membrane lipid order of leukemic and normal immature avian erythroid cells

Mammalian erythroblasts and their leukemic counterparts contain characteristic disordered regions of plasma membrane identified as putative membrane protein collection sites. In order to determine whether erythroid cells which do not enucleate contain homologous membrane domains, immature avian erythroid precursor cells and avian erythroleukemic cells were examined using merocyanine 540 (MC540), a fluorescent dye whose binding is sensitive to the packing of membrane lipids. Results were found to contrast with previous studies of the murine equivalents of these cells. In birds, normal erythroid precursors, including basophilic erythroblasts from the bone marrow and spleen of anemic animals, contained no detectable (less than 0.1%) cells which were stained by the dye. But cells from chicks infected with avian erythroblastosis virus (AEV) did stain. Considering the pattern of staining observed on AEV-erythroblasts relative to other leukemic and normal phenotypes, however, we conclude that neither normal nor leukemic avian erythroid cells contain a functional equivalent to the membrane protein collection sites found on their mammalian counterparts.     

cDNA sequence and tissue expression of an antimicrobial peptide, dicentracin; a new component of the moronecidin family isolated from head kidney leukocytes of sea bass, Dicentrarchus labrax

A 483-bp cDNA was isolated from sea bass (Dicentrarchus labrax) head kidney leukocytes, dicentracin, using PCR primers designed from conserved moronecidin domains. Gene bank analysis revealed that dicentracin cDNA belongs to the moronecidin family. As deduced from alignment with Morone chrysops moronecidin, the precursor of 79 aa appeared to be composed of a signal peptide of 22 aa, followed by the mature AMP (antimicrobial peptide) of 22 aa named dicentracin, and a C-terminal extension of 35 aa. Dicentracin precursor displayed 3 aa substitutions with other moronecidin sequence but none in the mature peptide sequence. Using in situ hybridization assay, dicentracin gene expression was observed in 68–71% of peripheral blood leukocytes, kidney leukocytes or peritoneal cavity leukocytes without significant statistical differences. Dicentracin mRNA was observed in most of the granulocytes, as well as in monocytes from both peripheral blood and head kidney, and in macrophages from peritoneal cavity. No expression was observed in thrombocytes or in lymphocytes.     

Forced differentiation of CFU-S by Iron-55 erythrocytocide

Cascades of Auger electrons are emitted in the decay of 55Fe and absorbed in tissue within a 1 micrometer radius. Cytocidal amounts of 55Fe can therefore eliminate erythroid precursors with minimal damage to adjacent cells. A single intravenous injection leads to continued erythrocytocide in mice because the isotope is reutilized and has a 2.7 year half-life. The cytocide evokes an early compensatory response from morphologically unrecognizable precursors which differentiate into pronormoblasts. These early events leave the granuloid series undisturbed but they are accompanied by a precipitous fall in pluripotent stem cell (CFU-S) numbers in bone marrow, spleen, and blood. The pretreatment levels of CFU-S are not restored. Gradual decline of CFU-S is associated with intermittently increased turnover rates and reduced settings of cell production, yet the capacity for quick restoration of blood loss is unimpaired. The precipitous initial stem cell decrease is not caused by irradiation damage, as shown in a separate experimental series that used the frozen-storage cytocide technique. Only over several weeks could 55Fe radiation accumulate to lethal levels in nondividing stem cells. This irradiation is attributed to incorporation of small amounts of 55Fe into CFU-S, from where it is slowly cleared. The stem cell loss immediately following 55Fe injection is in our interpretation caused by rapid differentiation along the erythroid pathway in a response that involves all progenitor populations. Data are consistent with the hypothesis of limited cell renewal capacity which thereby gains further support.     

Synchrony of bone marrow proliferation and maturation as the origin of cyclic haemopoiesis

Abstract. Cyclic haemopoiesis in Grey Collie dogs is characterized by stable oscillations in all haemopoietic lineages. It is proposed that in these animals, in contrast to normal animals, the maturation process of haemopoietic (in particular granuloid) cells from the primitive progenitors to the functional cells is characterized by an abnormally strong synchrony. It is conjectured that the marrow maturation time has a very small variance compared with non-cyclic normal dogs. With a mathematical model of haemopoiesis it is shown that small fluctuations are amplified via regular feedback processes such that stable granuloid oscillations are established. Erythroid oscillations are induced indirectly by granuloid feedback to the stem cell pool. The model calculations further show that the synchrony hypothesis of bone marrow maturation can quantitatively explain the following experimental results: (1) the maintenance of stable cycles of granuloid and erythroid bone marrow and blood cells with a period of approximately 14 d; (2) the disappearance of granuloid and erythroid cycles during the administration of the colony stimulating factor rhG-CSF; (3) the reappearance of oscillations when the administration of CSF is discontinued; (4) the cessation of cycles during endotoxin application; and (5) the persistence of cycles during erythroid manipulations (bleeding anaemia, hypoxia, hypertransfusion). We therefore conclude that cyclic haemopoiesis is not caused by a defect in the regulatory control system but by an unusual maturation process.     

Ca2+, Mg2+-dependent endonuclease activity in different subpopulations of spleen cells from normal and erythroleukemic mice

We have detected Ca2+, Mg2+-dependent endonuclease activity in spleen cells of normal, Friend erythroleukemic, and phenylhydrazine-treated mice. When nuclei were isolated and incubated in the presence of Ca2+ and Mg2+ ions, the activity resulted in the production of 3'-OH termini in the cellular DNA and the release of chromatin due to internucleosomal DNA fragmentation. This enzyme activity was chromatin-bound and could be extracted from chromatin in an active form in 0.35 M KCl. The majority of endonuclease activity from erythroleukemic spleens was present in nuclei of precursor erythroid cells of low buoyant density (1.025-1.05 g/ml). Uninfected normal splenic tissue contained an endonuclease activity which was almost entirely confined to a B-lymphocyte population of high buoyant density (greater than 1.07 g/ml). Erythroid cell-enriched spleens from phenylhydrazine-treated mice exhibited a distribution of endonuclease activity in cells at low and high densities reflecting a mixture of erythroid and lymphoid cells. Cloned erythroleukemic cell lines propagated in vitro lacked cells of low density and showed no detectable endonuclease activity. However, nuclei from these cell lines were susceptible to exogenously added endonuclease extracted from erythroleukemic spleen cells. These same cell lines propagated as subcutaneous tumors contained endonuclease activity and a morphologically-similar low-density cell population which accounted for the endonuclease activity in these tumors. Nuclei from cloned lymphoid cell lines, representing different B-lymphocyte phenotypes, showed differences in the presence of endonuclease activity. Among the cell lines tested, only those expressing late B-cell markers showed detectable endonuclease activity.     

Synchrony of bone marrow proliferation and maturation as the origin of cyclic haemopoiesis.

Cyclic haemopoiesis in Grey Collie dogs is characterized by stable oscillations in all haemopoietic lineages. It is proposed that in these animals, in contrast to normal animals, the maturation process of haemopoietic (in particular granuloid) cells from the primitive progenitors to the functional cells is characterized by an abnormally strong synchrony. It is conjectured that the marrow maturation time has a very small variance compared with non-cyclic normal dogs. With a mathematical model of haemopoiesis it is shown that small fluctuations are amplified via regular feedback processes such that stable granuloid oscillations are established. Erythroid oscillations are induced indirectly by granuloid feedback to the stem cell pool. The model calculations further show that the synchrony hypothesis of bone marrow maturation can quantitatively explain the following experimental results: (1) the maintenance of stable cycles of granuloid and erythroid bone marrow and blood cells with a period of approximately 14 d; (2) the disappearance of granuloid and erythroid cycles during the administration of the colony stimulating factor rhG-CSF; (3) the reappearance of oscillations when the administration of CSF is discontinued; (4) the cessation of cycles during endotoxin application; and (5) the persistence of cycles during erythroid manipulations (bleeding anaemia, hypoxia, hypertransfusion). We therefore conclude that cyclic haemopoiesis is not caused by a defect in the regulatory control system but by an unusual maturation process.     

Blood flow distribution and tissue allometry in channel catfish

Blood flow (as percentage of cardiac output) in fasted channel catfish acclimated to 21°C was directed primarily to white muscle (72%) followed by head kidney (5·7%), red muscle (5·5%), trunk kidney (3·1%), liver (2·2%), swim bladder (1·4%) and skin (1·1%). The stomach, intestines, pyloric caeca, gonads, brain, abdominal fat and spleen contained <0·5% of blood flow. There was considerable interfish variation among blood flow distribution to visceral organs with substantial spatial heterogeneity of blood flow to white muscle. The spatial heterogeneity of flow to muscle prevented accurate estimation of total flow to this tissue based on the microsphere deposition of a few sub-samples. Instead, a novel approach, based on the whole animal counting of the eviscerated carcass was used to measure blood flow to white muscle. The scaling relationships for tissue mass in catfish (63–1873 g) followed the allometric equation (aW^b) and tended to exhibit negative allometry, with organ weight decreasing in proportion to body weight. The b values for most tissues ranged between 0·83 and 1·0. The relative mass of the brain showed the greatest decline and with a b value of 0·32. The results, together with previous data on cardiac output, permitted calculation of organ blood flow rates in channel catfish. © 1999 The Fisheries Society of the British Isles     

Colony formation in agar by adult bone marrow multipotential hemopoietic cells

Erythroid colony formation in agar cultures of CBA bone marrow cells was stimulated by the addition of pokeweed mitogen-stimulated spleen conditioned medium (SCM). Optimal colony numbers were obtained when cultures contained 20% fetal calf serum and concentrated spleen conditioned medium. By 7 days of incubation, large burst or unicentric erythroid colonies occurred at a maximum frequency of 40–50 per 10⁵ bone marrow cells. In CBA mice the cells forming erythroid colonies were also present in the spleen, peripheral blood, and within individual spleen colonies. A marked strain variation was noted with CBA mice having the highest levels of erythroid colony-forming cells. In CBA mice erythroid colony-forming cells were mainly non-cycling (12.5% reduction in colony numbers after incubation with hydroxyurea or 3H-thymidine). Erythroid colony-forming cells sedimented with a peak of 4.5 mm/hr, compared with CFU-S, which sedimented at 4.25 mm/hr. The addition of erythropoietin (up to 4 units) to cultures containing SCM did not alter the number or degree of hemoglobinisation of erythroid colonies. Analysis of the total number of erythroid colony-forming cells and CFU-S in 90 individual spleen colonies gave a correlation coefficient of r = 0.93 for these two cell types. In addition to benzidine-positive erythroid cells, up to 40% of the colonies contained, in addition, varying proportions of neutrophils, macrophages, eosinophils, and megakaryocytes. Taken together with the close correlation between the numbers of CFU-S in different adult hemopoietic tissues, including individual spleen colonies, the data indicate that the erythroid colony-forming cells expressing multiple hemopoietic differentiation are members of the hemopoietic multipotential stem cell compartment.