Localization of hematopoietic cells in the bullfrog (<Emphasis Type="Italic">Lithobates catesbeianus</Emphasis>)

Amphibians represent the first phylogenetic group to possess hematopoietic bone marrow. However, adult amphibian hematopoiesis has only been described in a few species and with conflicting data. Bone marrow, kidney, spleen, liver, gut, stomach, lung, tegument, and heart were therefore collected from adult Lithobates catesbeianus and investigated by light microscopy and immunohistochemical methods under confocal laser microscopy. Our study demonstrated active hematopoiesis in the bone marrow of vertebrae, femur, and fingers and in the kidney, but no hematopoietic activity inside other organs including the spleen and liver. Blood cells were identified as a heterogeneous cell population constituted by heterophils, basophils, eosinophils, monocytes, erythrocytic cells, lymphocytes, and their precursors. Cellular islets of the thrombocytic lineage occurred near sinusoids of the bone marrow. Antibodies against CD34, CD117, stem cell antigen, erythropoietin receptor, and the receptor for granulocyte colony-stimulating factor identified some cell populations, and some circulating immature cells were seen in the bloodstream. Thus, on the basis of these phylogenetic features, we propose that L. catesbeianus can be used as an important model for hematopoietic studies, since this anuran exhibits hematopoiesis characteristics both of lower vertebrates (renal hematopoiesis) and of higher vertebrates (bone marrow hematopoiesis).     

Haematopoiesis in snakes (Ophidia) in early postnatal development

The occurrence of haematopoiesis has been studied in various parts of the spine and in the ribs in four species of snakes (Boa constrictor L., Elaphe guttata L., Lamprophis fulaginosus Boie., Bothrops jararaca Wied.) from hatching until 150 days of postnatal development. Marrow spaces are formed by chondrolysis with various time frames depending on the studied species. Marrow cells egress to the general circulation in two ways: via migration through the endothelial cells lining the venous sinuses or by the rupture of protrusions. Erythroblasts are present in the lumen of marrow sinuses suggesting their final maturation there. Various relationships of the spleen to the pancreas have been found. No myelopoietic foci occur in the spleen, liver or kidney of any of the studied species. However, erythropoiesis (sparse islets) has been observed in Bothrops jararaca spleen. This study was supported by Polish KBN grant 3P04C 022 24 and Brazilian FAPESP and CNPq grants.     

Targeting the Spleen as an Alternative Site for Hematopoiesis

Bone marrow is the main site for hematopoiesis in adults. It acts as a niche for hematopoietic stem cells (HSCs) and contains non‐hematopoietic cells that contribute to stem cell dormancy, quiescence, self‐renewal, and differentiation. HSC also exist in resting spleen of several species, although their contribution to hematopoiesis under steady‐state conditions is unknown. The spleen can however undergo extramedullary hematopoiesis (EMH) triggered by physiological stress or disease. With the loss of bone marrow niches in aging and disease, the spleen as an alternative tissue site for hematopoiesis is an important consideration for future therapy, particularly during HSC transplantation. In terms of harnessing the spleen as a site for hematopoiesis, here the remarkable regenerative capacity of the spleen is considered with a view to forming additional or ectopic spleen tissue through cell engraftment. Studies in mice indicate the potential for such grafts to support the influx of hematopoietic cells leading to the development of normal spleen architecture. An important goal will be the formation of functional ectopic spleen tissue as an aid to hematopoietic recovery following clinical treatments that impact bone marrow. For example, expansion or replacement of niches could be considered where myeloablation ahead of HSC transplantation compromises treatment outcomes.     

Experimental analysis of hematopoietic cell development in the liver of larval Rana pipiens.

Hematopoietic cell development in the liver of Rana pipiens throughout the larval period was examined. Differential counts of Wright/Giemsa-stained cell suspensions demonstrated that hepatic hematopoiesis includes lymphoid, myeloid, and erythroid cell lineages. Hematopoietic activity appeared to be initiated near the end of embryonic development (Shumway stages 24–25) and reached a substantial level by 30 days of development (Taylor and Kollros stage IV). Although lymphopoiesis became highly variable during later larval stages, granulopoiesis remained stable and erythropoiesis increased throughout the larval period. Erythropoiesis is the predominant hematopoietic activity in the larval liver. Histological examination of plastic embedded tissue demonstrated that hematopoietic activity is localized in discrete foci within the endothelial-lined sinusoids. These hematopoietic foci are found in both the subcapsular region and deeper portions of the organ. Microdensitometric analysis of experimental embryos which received chromosomally labeled presumptive ventral blood island transplants at Shumway stage 15 indicated that the derivatives of this embryonic region are limited to the circulating erythrocyte population of the early larvae. The hematopoietic cell populations of the liver appear to be derived from an extrinsic stem cell source which may be located in the dorsal region of the early embryo.     

Of birds and mice: hematopoietic stem cell development

For many years it has been assumed that the ontogeny of the mammalian hematopoietic system involves sequential transfers of hematopoietic stem cells (HSCs) generated in the yolk sac blood islands, to successive hematopoietic organs as these become active in the embryo (fetal liver, thymus, spleen and eventually bone marrow). Very little was known about early events related to hematopoiesis that could take place during the 4.5 day gap separating the appearance of the yolk sac blood islands and the stage of a fully active fetal liver. Experiments performed in birds documented that the yolk sac only produce erythro-myeloid precursors that become extinct after the emergence of a second wave of intra-embryonic HSCs from the region neighbouring the dorsal aorta. The experimental approaches undertaken over the last ten years in the murine model, which are reviewed here, led to the conclusion that the rules governing avian hematopoietic development basically apply to higher vertebrates.     

Localisation of Ig heavy chain mRNA positive cells in Atlantic cod (Gadus morhuaL.) tissues; identified byin situhybridisation

Localisation of immunoglobulin heavy chain (IgH) producing cells was determined in sections from head kidney, spleen, thymus, gills, gut, skin, heart and liver from the Atlantic cod. In general, IgH mRNA positive cells were detected in all organs examined and were mainly located to the connective tissue surrounding the vascular system in these organs. In the head kidney and spleen, IgH mRNA positive cells appeared as single distributed cells or as dense clusters, whereas in the thymus only single distributed positive cells were observed. The percentage of Ig heavy chain mRNA positive (plasma) cells in the head kidney, spleen and thymus was estimated at about 1% of the total cell mass. The number of IgH mRNA positive cells was lower than this in all the other organs examined.     

Monoclonal antibodies as probes for differentiation and tumor-associated antigens: a Forssman specificity on teratocarcinoma stem cells

A set of monoclonal antibodies derived by fusing P3-NS1/1-Ag4-1 myeloma cells with spleen cells from a rat immunized with mouse spleen were screened for activity against a tumor cell panel. One of these antibodies was found to react only with mouse embryonal carcinoma cells and no other tumor cell type tested, including differentiated derivatives of teratocarcinomas. In the adult mouse, this antigen is expressed by subpopulations of cells in the spleen, bone marrow, lymph node, brain, kidney and testes, although not in liver and thymus. This antigen has a species and tissue distribution consistent with that of Forssman antigen. The molecules which carry this specificity on the embryonal carcinoma cells appear to be glycolipids.     

造血干细胞特异性表达Cre重组酶转基因小鼠的建立

EDAG是在胚胎发育阶段造血干细胞特异性表达的基因.为了在早期造血组织细胞中实现相关基因的条件敲除,构建了含有早期造血组织特异性表达的EDAG启动子和Cre重组酶基因的转基因EDAG-Cre表达载体质粒.通过显微注射的方法将线性化的5.6kb的EDAG-Cre转基因片段导入小鼠受精卵细胞核,获得的新生小鼠经过PCR鉴定,常规方法培育传代.结果发现,共获得了6只阳性转基因首建鼠,其中4只已经建系并稳定传代.RT-PCR分析表明Cre重组酶基因在阳性转基因小鼠的骨髓、脾脏、胸腺、外周血以及胎肝等组织中均有表达,重组酶活性也在脾和骨髓中获得确认.EDAG-Cre重组酶转基因小鼠的建立,为研究早期造血组织以及造血干细胞特异性基因条件敲除小鼠模型的建立奠定了基础.     

Spatial differences in hematopoiesis but not in stem cells indicate a lack of regional patterning in definitive hematopoietic stem cells

Most tissues are patterned so that progenitors in different locations are programmed to have different properties. Stem cells from different regions of the nervous system acquire intrinsic differences in their properties as they migrate through distinct environments. Hematopoietic stem cells (HSCs) also migrate through diverse environments throughout life, raising the question of whether HSCs also acquire at least transient changes in their properties as they are exposed to diverse environments. Although we observed significant differences in hematopoiesis between the fetal liver and fetal spleen, we were not able to detect phenotypic, functional, or gene expression differences between the HSCs in these organs. Regional differences in definitive hematopoiesis are therefore not determined by regional differences between HSCs. We were also not able to detect phenotypic, functional, or gene expression differences between HSCs in different adult bone marrow compartments. Our failure to detect differences among stem cells from different regions of the hematopoietic system at the same time during development suggests that the hematopoietic system has evolved mechanisms to prevent the spatial reprogramming of HSC properties as they migrate between distinct environments.     

Protein tyrosine phosphorylation in normal rat tissues

• 1.1. Exogenous and endogenous tyrosine protein phosphorylation activities were examined in soluble and partieulate fractions from various normal tissues by using poly-[Glu-⁸⁰Na, Tyr²⁰] and a monoclonal antibody specific for phosphotyrosine.
• 2.2. Phosphorylation of the exogenous substrate by the partieulate forms of TPKs was 2- to 10-fold higher than by soluble forms. The activities of partieulate and soluble enzymes decreased in the following order: spleen > (thymus = kidney) > testes ⩾ (pancreas = liver = brain) > heart.
• 3.3. The level of endogenous phosphorylation in the tissues decreased respectively in the following order: thymus > brain ⩾ (pancreas = liver) > spleen > testes > kidney > heart for the partieulate fractions, and spleen > thymus > brain > pancreas ⩾ liver > testes > kidney > heart for the soluble fractions.
• 4.4. A large number of phosphotyrosine-containing proteins were detected. In addition, several phosphotyrosine-containing proteins of similar molecular weight were found in different tissues and fractions.

     

Ontogeny of the mouse hematopoietic system

In vertebrates the extraembryonic mesoderm of the yolk sac (YS) is the first site during embryogenesis where morphologically discernible hematopoiesis may be found. Later hematopoiesis shifts into the embryo proper, first to the liver, the major fetal hematopoietic site, then to definitive hematopoietic territories, the spleen and bone marrow. It is widely accepted that in the mouse this picture reflects the migration of pluripotent hematopoietic stem cells (HSC) from the YS accompanied by subsequent colonization of the hematopoietic tissues during embryogenesis. However, there is no conclusive evidence showing unequivocally the initiating role of the YS in murine adult hematopoiesis. Recently, we have demonstrated the important role of embryo body tissues in the development of CFU-S before the establishment of definitive hematopoiesis in the fetal liver. This finding suggests that the early development of the hematopoietic system in the mouse is more complex than has been previously proposed and we consider here the early hematopoietic events in the developing mouse embryo.     

Effect of graft-versus-host disease (GVHD) on host hematopoietic progenitor cells is mediated by Fas-Fas ligand interactions but this does not explain the effect of GVHD on donor cells.

The acute graft-versus-host disease (GVHD) generated in BDF1 mice by the injection of spleen cells from the C57BL/6 parental strain induces a direct cell-mediated attack on host lymphohematopoietic populations, resulting in the reconstitution of the host with donor hematopoietic stem cells. We examined the effect of GVHD on the donor and host hematopoiesis in parental-induced acute GVHD. The bone marrow was hypoplastic and the number of hematopoietic progenitor cells significantly decreased at 4 weeks after GVHD induction. However, extramedullary splenic hematopoiesis was present and the number of hematopoietic progenitor cells in the spleen significantly increased at this time. Fas expression on the host spleen cells and bone marrow cells significantly increased during weeks 2 to 8 of GVHD. Host cell incubation with anti-Fas Ab induced apoptosis, and the number of hematopoietic progenitor cells decreased during these weeks. A significant correlation between the augmented Fas expression on host bone marrow cells and the decreased number of host bone marrow cells by acute GVHD was observed. Furthermore, the injection of Fas ligand (FasL)-deficient B6/gld spleen cells failed to affect host bone marrow cells. Although Fas expression on repopulating donor cells also increased, Fas-induced apoptosis by the repopulating donor cells was not remarkable until 12 weeks, when more than 90% of the cells were donor cells. The number of hematopoietic progenitor cells in the bone marrow and the spleen by the repopulating donor cells, however, decreased over an extended time during acute GVHD. This suggests that Fas-FasL interactions may regulate suppression of host hematopoietic cells but not of donor hematopoietic cells. Hematopoietic dysfunctions caused by the reconstituted donor cells are independent to Fas-FasL interactions and persisted for a long time during parental-induced acute GVHD.     

Direct detection of exogenous mouse mammary tumor virus sequences in lymphoid cells of BALB/cfC3H female mice.

The presence of exogenous mouse mammary tumor virus (MMTV) (C3H) DNA sequences in lymphoid tissue (spleen, bone marrow, and thymus) and nonlymphoid tissue (liver and kidney) of BALB/cfC3H female mice was directly assessed by DNA hybridization methods. Lymphoid tissues were found positive for integrated MMTV(C3H) sequences in females as young as 4 weeks. In most samples, the level of splenic MMTV(C3H) infection was low (2 to 5%). Infection remained throughout the life of the animal. The percentage of spleen samples found positive for exogenous viral infection was significantly higher in females bearing mammary tumors, whether virgin or multiparous. Liver and kidney DNAs were negative for exogenous MMTV sequences, suggesting tissue type selectivity in MMTV infection.     

Tissue distribution of the lipocalin alpha-1 microglobulin in the developing human fetus.

Alpha-1 microglobulin (alpha(1)m), a lipocalin, is an evolutionarily conserved immunomodulatory plasma protein. In all species studied, alpha(1)m is synthesized by hepatocytes and catabolized in the renal proximal tubular cells. alpha(1)m deficiency has not been reported in any species, suggesting that its absence is lethal and indicating an important physiological role for this protein To clarify its functional role, tissue distribution studies are crucial. Such studies in humans have been restricted largely to adult fresh/frozen tissue. Formalin-fixed, paraffin-embedded multi-organ block tissue from aborted fetuses (gestational age range 7-22 weeks) was immunohistochemically examined for alpha(1)m reactivity. Moderate to strong reactivity was seen at all ages in hepatocytes, renal proximal tubule cells, and a subset of pancreatic islet cells. Muscle (cardiac, skeletal, or smooth), adrenal cortex, a scattered subset of intestinal mucosal cells, tips of small intestinal villi, and Leydig cells showed weaker and/or variable levels of reactivity. Connective tissue stained with variable location and intensity. The following cells/sites were consistently negative: thymus, spleen, hematopoietic cells, lung parenchyma, glomeruli, exocrine pancreas, epidermis, cartilage/bone, ovary, seminiferous tubules, epididymis, thyroid, and parathyroid. The results underscore the dominant role of liver and kidney in fetal alpha(1)m metabolism and provide a framework for understanding the functional role of this immunoregulatory protein.     

Kupffer cells support extramedullary erythropoiesis induced by nitrogen-containing bisphosphonate in splenectomized mice

Our previous study indicated that injecting nitrogen-containing bisphosphonate (NBP) induced the site of erythropoiesis to shift from the bone marrow (BM) to the spleen. This was due to the depletion of BM-resident macrophages, which support erythropoiesis. In this study, we examined NBP treatment-induced extramedullary hematopoiesis in splenectomized mice, focusing on hepatic hematopoiesis. NBP-treated mice did not display anemia or significant change in erythropoietin production, while megakaryopoiesis and erythropoiesis were constantly observed in the liver. Erythroblastic islands were detected in the sinusoidal lumen. Kupffer cells expressed VCAM-1 following NBP treatment, which is an important factor for erythroblast differentiation. Cl₂MBP-liposome treatment depleted the erythroblastic islands, and decreased the number of hematopoietic cells in the liver, as determined by colony forming assays. Together, these results indicate that Kupffer cells support erythropoiesis, acting as stromal cells in the liver, and that they might act as a niche for hematopoietic precursor cells in an emergency.     

Studies on the nuclear binding of steroid hormone-receptor complex; binding of liver and thymus dexamethasone-receptor complex and prostate dihydrotestosterone-receptor complex to nuclei from various tissues.

To examine the binding specificity of steroid hormone-cytoplasmic receptor complexes to nuclei, binding of 3H-dexamethasone (Dex)-liver, 3H-Dex-thymus and 3H-dihydrotestosterone (DHT)-prostate receptor complexes to nuclei from liver, prostate, thymus, spleen and kidney was studied. It was observed that a significant amount of steroid-receptor complexes was bound to any nuclei used in the present study and the extent of the binding of receptor complexes to nuclei from homologous tissues was not always greater than that to nuclei from heterogenous tissues. However, a significant portion of the 3H-Dex-liver and 3H-DHT-prostate receptor complexes was not absorbed by nuclei from kidney, spleem, and thymus, and the unabsorbed complexes were efficiently bound to liver and prostate nuclei. The results obtained indicate that two types of receptor complex with regard to nuclear binding were present in cytosols of liver and prostate; one binds to nuclei from kidney, spleen, thymus, liver and prostate and the other does not bind to nuclei from kidney, spleen and thymus but does bind to nuclei of liver and prostate. The latter type of receptor complex was not observed in the cytosol from the thymus.     

STUDIES OF HEMATOPOIESIS IN MURINE SPLEENS: SIGNIFICANCE OF HEMATOPOIETIC COLONIES FORMED ON THE SURFACE OF SPLEENS

Conies of hematopoietic tissue are formed in spleens of lethally irradiated mice by the injection of small numbers of hematopoietic cells. Some of these colonies appear as surface colonies, others can be identified only in serial sections of the spleen. The present studies have related the number and cellular composition of total hematopoietic colonies in the murine spleen to their visual recognition on the splenic surface. These studies demonstrate that only 50% of the total colonies in a spleen are recognized as surface colonies and that of those colonies on the surface, approximately 80% contain erythroid elements. At least four factors play important roles in the recognition of hematopoietic colonies as splenic surface colonies: (1) dose of repopulating cells or hematopoietic stem cells injected into the irradiated animal; (2) location of colonies within the spleen; (3) size of colonies; and (4) cellular content of the colonies. These studies demonstrate that surface colony formation reflects primarily erythropoiesis and not total hematopoiesis.