Differential participation of ventral and dorsolateral mesoderms in the hemopoiesis of Xenopus, as revealed in diploid-triploid or interspecific chimeras

The thymocytes in the early larvae of Xenopus laevis have been shown to be derived from precursor cells immigrating interstitially through the mesenchyme into the organ rudiments at 3-4 days of age (Nieuwkoop and Faber stages 42-45). Orthotopic grafting of diploid tissues onto triploid stage 22 embryos followed by ploidy analyses of their hemopoietic cells revealed that both thymocytes and erythrocytes in early larvae are derived from the ventral blood islands (VBI), whereas those in late larvae and adults come mainly from the dorsolateral plate (DLP). To study how the VBI cells of embryos at stage 22 participate in hemopoiesis, a number of interspecific chimeras were produced in X. laevis and X. borealis embryos. Sections of the chimeras at various developmental stages were examined by employing the unique stainability of X. borealis nuclei to quinacrine as a marker; the results show that the VBI-derived cells enter into the circulation around stage 35/36, and that some of them leave the blood vessels to migrate interstitially through the mesenchyme toward the thymic rudiment during stages 43-45. A minor population of the VBI-derived cells was also found extravascularly in the mesonephric primordia. In contrast to the VBI, the DLP-derived cells contributed to the hemopoietic cell population not in early larvae, but in late ones as a major constituent in the mesonephros, thymus, liver, and peripheral blood.     

The Localization of Precursor Cells for Larval and Adult Hemopoietic Cells of Xenopus Laevis in two Regions of Embryos

For determination of the localization of lymphoid and erythroid precursor cells in embryos of Xenopus laevis , diploid-triploid chimeras were produced either by joining embryos antero-posteriorly or by orthotopic grafting of various tissues into N ieuwkoop -F aber st. 22–23 tailbud embryos. The sources of the hemopoietic cells were determined in the chimeric animals at various stages by microspectrophotometry of F eulgen -stained cells. Analyses of chimeras produced by joining embryos antero-posteriorly at different levels showed that the precursor cells that contribute to the hemopoietic cells are localized in the posterior half to three quarters. Orthotopic grafting of ventral or dorsal tissues revealed that the precursor cells that contribute to hemopoietic cells in early larvae are mostly localized in the ventral blood island (VBI) mesoderm, whereas those for late larvae and adults are localized both in the dorso-lateral plate (DLP) mesoderm comprising the prospective mesonephros and in the VBI mesoderm. Reciprocal heterotopic grafting of VBI- and DLP mesoderms showed that the two compartments differ in their capacities to differentiate into hemopoietic cells. It is proposed that the VBI-derived cells migrating towards the primary lymphoid organs constitute the transient hemopoietic population of early larvae, and the importance of the mesonephric region for definitive hemopoiesis is pointed out.     

Contribution of ventral blood island mesoderm to hematopoiesis in postmetamorphic and metamorphosis-inhibited Xenopus laevis

In an effort to label very early erythrocyte and lymphocyte populations and to follow their fate in normally developing postmetamorphic frogs and goitrogen-treated permanent larvae, diploid (2N) and triploid (3N) ventral blood island (VBI) mesoderm was exchanged between neurula stage embryos (about 16-22 hr old). Beginning at 15 days of age, half of the 2N or 3N hosts were treated with sodium perchlorate to prevent thyroxine-induced developmental changes. At larval stages 55-59 (41-48 days) and at 1-2 months postmetamorphosis (110-120 days), the untreated control chimeras and age-matched perchlorate-treated chimeras were killed for analysis of the VBI contribution to blood, spleen, and thymus populations by flow cytometry. The data suggest that grafting of ventral blood island mesoderm is an effective way to label an early larval erythrocyte population that declines after metamorphosis. In perchlorate-blocked permanent larvae this early VBI-derived erythrocyte population persists. In contrast, grafting of VBI mesoderm was less useful as a method to label a larvally distinct lymphocyte population in the thymus and spleen. At the late larval stages that we examined, the proportion of VBI-derived cells in thymus and spleen was not different from that observed after metamorphosis. Inhibition of metamorphosis interfered with the thymocyte expansion that normally occurs after metamorphosis, but the proportion of VBI-derived cells in thymus and spleen was not affected. This suggests that lymphopoiesis occurring in late larval life and after metamorphosis uses a stable persisting population of VBI-derived stem cells as well as dorsally derived stem cells.     

Location of hemopoietic stem cells influences frequency of lymphoid engraftment in Xenopus embryos

The first hemopoietic stem cells to differentiate in Xenopus embryos arise from ventral blood island (VBI) mesoderm. Progeny of these stem cells contribute to larval E, macrophage, thymocyte, and B lymphocyte populations. When small pieces of mesoderm are transplanted to a central location within the VBI, the contribution of this mesoderm is predominantly to erythropoiesis and engraftment of lymphoid populations is minimal. The present experiments examined the influence of position within the VBI on the contribution of single stem cells to lymphoid populations. Pieces of diploid VBI mesoderm, containing an average of one hemopoietic stem cell, were transplanted to either a central or a peripheral location within the defined boundaries of the VBI of triploid, stage matched embryos. The number of animals with donor-derived cells in lymphoid populations was markedly increased when stem cells were grafted to a peripheral position. In three cases, stem cells contributed to lymphoid populations at the exclusion of erythroid populations. These data were consistent with the notion of either a lymphoid stem cell or restricted B and T lymphocyte precursors. These data also suggested that during embryogenesis, stochastic differentiation of hemopoietic stem cells was influenced by regional differences in the VBI microenvironment.     

Accumulation and Spatial Distribution of Poly(A)+RNA in Oocytes and Early Embryos of Drosophila melanogaster

We describe the accumulation and distribution of poly (A)⁺RNA during oogenesis and early embryogenesis as revealed by in situ hybridization with a radio-labeled poly (U) probe. The amount of poly (A)⁺RNA in nurse cell cytoplasm continuously increased untill mid-vitellogenic stage (st. 10), then decreased with the rapid increase of poly (A)⁺RNA in the oocyte (st. 11). The localization of poly (A)⁺RNA at stage 10 was in the anterior region of the oocyte, where it is connected by cytoplasmic bridge to the nurse cells. These observations indicate that most of the poly (A)⁺RNA synthesized in the nurse cells is transferred to the oocyte through the cytoplasmic bridges at stage 10–11. During the remainder of oogenesis (st. 11–14) and during preblastodermal embryogenesis, poly (A)⁺RNA was evenly distributed over the cytoplasm of oocytes and embryos. At blastoderm stage, poly(A)⁺RNA became concentrated in the peripheral region of embryos. Though the somatic nuclei of the blastoderm contained a detectable amount of poly (A)⁺ RNA, the pole cell nuclei did not. The cytoplasmic RNA visualised by acridine orange staining and the poly (A)⁺RNA detected by hybridization with [³H]poly (U) exhibited identical distributions during oogenesis and early embryogenesis. These observations provide a basis to assess the unique distributions of specific RNA sequences involved in early development.     

Ontogeny and tissue distribution of leukocyte-common antigen bearing cells during early development of Xenopus laevis

To analyze the ontogenic emergence of leukocytes during early development, a mouse monoclonal antibody (IgG1), designated as XL-1, was produced against the peritoneal macrophages of adult Xenopus laevis. The XL-1 determinant was expressed on all types of leukocytes, including lymphocytes, granulocytes, thrombocytes and macrophages, but not on erythrocytes of either larvae or adults. Immunohistochemical observations of the hemopoietic organs revealed that the XL-1+ cells with granulocyte and/or macrophage morphology appeared at st.36-37 in the liver, at st.44-45 in the mesonephric and the thymus rudiments, and at st.47 in the spleen. The XL-1 determinant was expressed on the precursor cells of T lymphocytes in the thymus rudiments at st.46-47, on the pre-B cells in the liver rudiments at st.47, and on lymphocytes in the spleen at st.48-49. A few XL-1+ cells were present in the ventral blood island of the st.35/36 embryos, where differentiating erythrocytes had predominated since st.28. XL-1+ cells with a macrophage-like morphology were found in several locations of the mesenchyme in the st.32 embryos, before the establishment of vascularization at st.33/34 and far earlier than the emergence of lymphocytes.     

Positive and Negative Regulation of the Differentiation of Ventral Mesoderm for Erythrocytes in Xenopus laevis

To elucidate the mechanism of determination and regulation of hemopoiesis in the early Xenopus embryo, explants of dorsal and ventral mesoderm from various stage embryos were cultured alone or combined with various tissues derived from the same stage embryo. Western blot analysis of larvae-specific globin expression using monoclonal antibody L5.41 revealed that extensive erythropoiesis occurred in the explants of ventral mesoderm from st. 22 tailbud embryo, but not in those of dorsal mesoderm. Experiments using combined explants at this stage demonstrated that the in vitro differentiation of erythrocytes in the ventral mesoderm could be completely inhibited by the dorsal tissue, including neural tube, notochord, and somite mesoderm, but not by other mesoderms, gut endoderm, or forebrain. Subsequent explant studies showed that the notochord alone is sufficient for this inhibition. Furthermore, the ventral mesoderm explant from the st. 10⁺ early gastrula embryo was not able to differentiate into erythroid cells. However, small amounts of globin were expressed if ventral mesoderm of this stage was combined with animal pole cells which were mainly differentiated to epidermis. This stimulation was enhanced when both tissues were excised together without separation, while none of the other parts of st. 10⁺ embryo had this stimulatory effect. These observations found in the combined explants suggest that in vivo interactions between the ventral mesoderm and adjacent tissues are important for normal development of erythroid precursor cells.     

Distribution of Synechococcus spp. determined by immunofluorescent assay

By using two polyclonal antisera against WH 7803 strain (Synechococcus sp.) and WH 5701 strain (Synechococcus bacillaris) it is possible to detect and to enumerate cells of the two cyanobacterial serogroups. The immunofluorescence technique was used to study the distribution of the two serogroups in the estuarine, coastal and upwelling waters of the Mediterranean Sea surrounding Messina. In the estuarine waters of the Alcantara River (Ionian Sea), the WH 7803 serogroup was present at a concentration in the order of 10² cells ml⁻¹ and the WH 5701 serogroup at a concentration of 5·5 × 10² cellsml⁻¹. In the coastal waters of Messina, where urban and industrial wastes are usuallydumped, the concentration of total phycoerythrin- Synechococcus ranged from 1·3 × 10² to 4·1 × 10³ cells ml⁻¹; the WH 7803 serogroup accounted for 50–94% of the totalpopulation in Ionian stations, whereas the WH 5701 serogroup ranged from1·4 × 10¹ to6·7 × 102cells ml⁻¹. In the upwelling area (Straits of Messina) bothserogroups were found. Vertical distribution of two Synechococcus strains had anopposite trend and their concentrations were of the order of 10¹–10²cells ml⁻¹. Theuse of the Scan laser system allows both autofluorescent and labelled organismsto be distinguished in a preparation for optical microscopy. It also allows false-positivecells to be distinguished.     

阿霉素通过Wnt/β-catenin信号通路抑制口腔鳞癌干细胞迁移和侵袭

目的:探讨阿霉素对口腔鳞癌干细胞迁移、侵袭、凋亡的影响及其可能的机制.方法:体外培养人口腔鳞癌细胞系SCC25,通过流式细胞术分选CD44-和CD44+细胞,RT-PCR检测CD44-和CD44+细胞的Oct4、CD133、CD44和GAPDH的mRNA表达;检测和比较CD44-和CD44+细胞的克隆形成能力.CD44...     

In vitro stimulation of human peripheral blood lymphocytes by Neisseria meningitidis

Abstract Heat-killed Neisseria meningitidis was found to be mitogenic for human peripheral blood lymphocytes (PBL). Separation of lymphocytes by rosetting with sheep erythrocytes indicated that both rosette-forming cells (E⁺, T-enriched) and nonrosetting cells (E⁻, B-enriched) were induced to proliferate by the bacteria. Following meningococcal stimulation, E⁻ cells and PBL displayed proliferative responses of similar magnitude and followed essentially the same kinetics with peak responses occurring after 3–4 days of culture. By comparison, E⁺ lymphocytes gave significantly higher responses and required a longer incubation period (5–7 days) to reach maximum levels of proliferative activity.     

Differential stem cell contributions to thymocyte succession during development of Xenopus laevis.

The contribution of two embryonic stem cell compartments to the developing thymus in the amphibian Xenopus was examined throughout the larval, postmetamorphic, and adult periods. Hematopoietic chimeras were produced by transplanting either the ventral blood islands (VBI) or the dorsal stem cell compartment (DSC) from diploid donors onto triploid hosts. The DNA content of isolated nuclei harvested from the thymus and circulating E populations was analyzed using propidium iodide staining and flow cytometry. The DNA content of mitotic figures derived from PHA reactive splenocytes was analyzed using the Feulgen reaction and microdensitometry. These data suggested that both the VBI and DSC contribute to the thymocyte populations from the earliest developmental stages examined. Moreover, the contribution of both stem cell compartments was cyclic. However, the periods of these cycles were different. Both VBI- and DSC-derived cells entered the thymus 4 days postfertilization. VBI-derived thymocytes were at a minimum at 28 days postfertilization, reached a maximum at 35 days postfertilization and a second minimum at 42 days postfertilization. However, DSC-derived cells reached a maximum at 28 days, a minimum at 35 days, and a second maximum at 42 days. The PHA-reactive splenocyte population followed a similar temporal pattern. In contrast, the VBI-derived E population was at a maximum during early development and steadily declined throughout the larval period. DSC-derived E were undetectable during early development but steadily increased throughout the larval period. Both VBI- and DSC-derived hematopoietic cells persisted after metamorphosis and contributed to all populations examined in adult frogs. Because of temporal differences in the VBI and DSC contributions to the developing thymus, these data suggest heterogeneity within the thymocyte population associated with the embryonic origin of the colonizing stem cells.     

Phenylhydrazine stimulates lymphopoiesis and accelerates Abelson murine leukemia virus-induced pre-B cell lymphomas

Infection of bone marrow or fetal liver cells with Abelson murine leukemia virus (A-MuLV) results in the transformation of pre-B cells and the development of erythroid colonies, indicating that the abl oncogene can affect the growth characteristics of immature cells in both the B cell and erythroid lineages. By comparison, infection of mice with A-MuLV results primarily in the development of pre-B cell lymphomas. To determine whether A-MuLV could induce erythroid disease in vivo, NFS/N mice were pretreated with phenylhydrazine (PHZ) to stimulate erythropoiesis and increase the frequency of potential target cells for A-MuLV. No erythroleukemias developed in mice treated with PHZ. Instead, the latency for pre-B cell lymphomas was reduced by half. This acceleration of disease could be attributed to a marked increase in pre-B cells as targets for transformation by A-MuLV in the bone marrows but not the spleens of treated mice. Increases in the frequencies of T cells in bone marrow and spleen also followed treatment with PHZ. These results show that although PHZ-induced anemia stimulates the production of T and B cells as well as erythroid progenitors, PHZ-treated mice do not develop erythroleukemia or T cell lymphomas. It was also found that the genetically determined resistance of adult C57BL/6 mice to lymphoma induction by A-MuLV could not be overcome by pretreatment with PHZ even though the frequency of pre-B cells in bone marrow was greatly increased by this treatment.     

AN ANALYSIS OF BONE MARROW ERYTHROPOIESIS IN THE MOUSE

Following the model of the erythropoietic system developed in the rat by Tarbutt and Blackett, the authors have carried out a kinetic analysis of bone marrow erythropoiesis in the mouse.
Using ⁵⁹Fe labelling techniques the size of the recognizable precursor cells and of the functional cell compartments have been estimated, while the flow-rate from the unrecognized precursor cells to the recognizable cells and from the latter compartment to the circulating erythrocytes have been evaluated by ⁵⁵Fe autoradiography.
Differences in the kinetic parameters of the erythropoietic mouse bone marrow compared with the rat bone marrow are reported, whose interpretation has required a more detailed analysis of the original model.     

Contribution of ventral and dorsal mesoderm to primitive and definitive erythropoiesis in the salamander Hynobius retardatus

Previously, we found that the conversion of hemoglobins (Hbs) from the larval to the adult type occurred within a single erythroid cell population in a salamander, Hynobius retardatus ("Hb switching" model), whereas the transition involves replacement of red-blood-cell (RBC) populations ("RBC replacement" model) in many amphibians (M. Yamaguchi, H. Takahashi, and M. Wakahara, 2000, Dev. Gene Evol. 210, 180-189). To further characterize the Hb transition, developmental changes in the erythropoietic sites have been intensively analyzed using larval- and adult-specific globin antibodies and globin and GATA-3 RNA probes. Cells of the ventral blood island (VBI) and the dorsolateral plate (DLP) in embryos differentiate in situ to erythroid cells that contain larval globin mRNA, suggesting that both the VBI and the DLP contribute to "primitive" erythropoiesis. In contrast, the expression pattern of the GATA-3 gene suggests that cells of the DLP may contribute to "definitive" hematopoiesis. In order to determine whether it is possible to define a definitive erythropoiesis in H. retardatus or not, further experiments were done: (1) when metamorphosing larvae were treated with phenylhydrazine to induce anemia and then bled at the postmetamorphic stage after recovery from the anemia, a precocious Hb transition was observed in these animals; (2) an RBC population expressing only adult Hb was confirmed by subtracting the number of RBCs expressing larval Hb from the total number of RBCs during metamorphosis. All these results support the existence of a definitive erythroid cell population that contributes only adult RBCs in this species.     

Physical characterization of the pore forming cytolysine from Gardnerella vaginalis

Abstract The cytolytic toxin (CTox) produced by Gardnerella vaginalis is able to form voltage-dependent cationic channels when incorporated in lipid membranes (Moran et al, 1991) FEBS Lett. 283, 317–320). Osmotic protection experiments show that toxin incorporated in human erythrocytes forms pores between 18 Å and 28 Å in diameter. A hypothesis of pore formation as a primary event to produce cytolysis is proposed. The CTox activity increases when cells are depolarized by increasing the extracellular K⁺ concentration, probably reflecting the voltage dependent character of CTox formed channels. The cytolytic effect of the toxin was prevented by low temperatures and was a function of the extracellular Ca²⁺ concentration, suggesting a Ca²⁺ influx as part of the lytic mechanism. Binding of CTox to erythrocytes was dependent on external Ca²⁺ and was less temperature-dependent. Dose-response analysis suggests cooperativity of the toxin for the lytic activity, although no direct evidence of oligomerization has been found.     

Depolarization and Activation of Dihydropyridine-Sensitive Ca2+ Channels Stimulate Inositol Phosphate Accumulation in Photoreceptor-Enriched Chick Retinal Cell Cultures

Abstract: Elevated concentrations of extracellular K⁺ increased inositol phosphate accumulation in primary cultures of chick retinal photoreceptors and multipolar neurons. K⁺-evoked stimulation of inositol phosphate accumulation was greater in photoreceptor-enriched cell cultures than in cultures where multipolar neurons were the predominant cell type. Destroying multipolar neurons, but not photoreceptors, with kainic acid and N -methyl- d -aspartate did not reduce the K⁺-evoked stimulation of inositol phosphate accumulation. Both of these observations indicate that the observed effects occur in photoreceptor cells. The K⁺-evoked stimulation of inositol phosphate accumulation was blocked by omitting Ca²⁺ from the incubation medium or by adding the dihydropyridine-sensitive Ca²⁺-channel antagonists, nitrendipine and nifedipine. Bay K 8644, a dihydropyridine agonist, stimulated inositol phosphate accumulation and enhanced the effect of K⁺. ω-Conotoxin GVIA, an inhibitor of N-type Ca²⁺ channels, had no significant effect on K⁺-stimulated inositol phosphate accumulation. Pretreatment with pertussis toxin neither blocked K⁺-evoked inositol phosphate accumulation nor altered the inhibitory effect of nifedipine. K⁺-evoked inositol phosphate accumulation appears to reflect activation of phosphatidylinositol-specific phospholipase C, as it is inhibited by U-73122. These results indicate that Ca²⁺ influx through voltage-gated, dihydropyridine-sensitive channels activates phospholipase C in photoreceptor inner segments and/or synaptic terminals.     

Occurrence of nonlymphoid leukocytes that are not derived from blood islands in Xenopus laevis larvae

Previous immunohistochemical observations using the monoclonal antibody (XL-1) which recognizes all types of leukocytes in Xenopus laevis revealed the occurrence of XL-1+ cells in the mesenchyme throughout the early larval body, before the appearance of any lymphocytes. The present experiments were performed to determine whether these leukocytes originate, like lymphocytes and red blood cells (RBCs), in the ventral blood islands (VBI) or the dorsolateral plate (DLP). For tracing the derivation of cells, a specific staining by quinacrine to nuclei of X. laevis and Xenopus borealis hybrid (LB) cells was used to distinguish them from X. laevis (LL) cells. Orthotopic graftings of VBI tissue from st.22-23 LB embryos to the stage-matched LL embryos and examinations at st.44-45 before differentiation of the lymphocytes showed that the proportion of XL-1+ LB cells was always significantly lower than that of RBCs with the same marker in all experimental larvae. The head (LB)-body (LL) chimeras from st.22-23 embryos and culture of the head-portions as VBI- and DLP-free explants from st.14-23 embryos both demonstrated that a significant number of XL-1+ cells which had originated in the head portions had begun to differentiate by st.42-43. These results indicate that there is a significant population of larval nonlymphoid leukocytes (mostly macrophages) that do not originate from either the VBI or DLP region, and are distributed in the mesenchyme throughout the body.     

In vitro carbon dioxide excretion from erythrocytes of two species of Antarctic fishes and its inhibition by catecholamines

This study was designed to investigate whether the blood of Pagothenia borchgrevinki , exhibits a Haldane effect, and whether activation of a Na⁺/H⁺ antiporter increases transport of intracellular protons and Bohr protons out of the erythrocytes resulting in inhibition of CO₂ excretion in both P. borchgrevinki , and Dissostichus mawsoni. When carbon dioxide dissociation curves were determined from blood samples pooled from three fish under oxygenated and deoxygenated conditions a Haldane effect was observed. Using an in vitro , CO₂ excretion assay, the rate of HCO₃⁻ dehydration was determined on blood and plasma equilibrated under an N₂atmosphere then rapidly oxygenated with air in the presence of 10⁻⁵ M noradrenaline or acetazolamide (10⁰⁴M). Whole blood and plasma from P. borchgrevinki , and D. mawsoni , were equilibrated with 0·5% CO₂ in air and assayed in the presence of 10⁻⁵ M noradrenaline. Erythrocyte CO₂ excretion rates were depressed significantly by noradrenaline in both species. The whole blood HCO₃⁻ dehydration rate was depressed significantly following rapid oxygenation in the presence of acetazolamide indicating that the pathway of CO₂ excretion included activation of intracellular carbonic anhydrase and an adrenergic receptor.     

Adrenergic responses and the Root effect in erythrocytes of freshwater fish

The effects of adrenergic-stimulation upon the oxygen-binding capacity of fish erythrocytes have been investigated. The oxygen capacity of rainbow trout, Oncorhynchus mykiss (Walbaum), erythrocytes was lowered by 44% on extracellular acidification (the so-called 'Root effect'). Addition of isoproterenol at 20° Ccaused an acid shift of the curve relating oxygen capacity to pH₀ by approximately 0.2 pH units, a value which was similar to the change in intracellular pH caused by adrenergic stimulation (Cossins & Kilbey Journal of Experimental Biology , 148 , 303–312, 1990). Moreover, when plotted as a function of pH_i, the curves for control and adrenalinstimulated erythrocytes were superimposable suggesting that the adrenergic shift in the Root curve was a result of the change in pH_i caused by activation of the adrenergic Na⁺/H⁺ exchanger.
A similarly large adrenergic shift in the Root curve was observed for pike, Esox lucius L., erythrocytes, though not for erythrocytes of carp, Cyprinus carpio L., and tench, Tinea tinea (L.). The pH for the mid-point of the Root effect in pike erythrocytes was distinctly more acid than for trout, but in both cases corresponded closely with the optimal pH for the adrenergic Na⁺/H⁺ exchange mechanism. This suggests a link between the functional characteristics of the exchanger and the oxygen-binding properties of haemoglobin.