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.     

Two Transitions of Haemoglobin Expression in Xenopus: from Embryonic to Larval and from Larval to Adult

Abstract. Electrophoretic analyses of haemoglobin and globin phenotypes in families of Xenopus borealis and Xenopus l. laevis revealed two developmental haemoglobin transitions during ontogeny. The first transition occurs at the developmental stage when tadpoles begin to feed. It is characterized by the decline of embryonic-specific globins in favour of novel, tadpole-specific globins ( X. borealis ) correlated to changes in the haemoglobin pattern. We suppose that this switch results from the replacement of a primitive, ventral blood island-dependent erythrocyte population by tadpole erythrocytes from other erythropoietic sites. Several other globin chains and haemoglobins are present in both young tadpoles and throughout larval life. The second, well-known transition occurs during metamorphosis, where all tadpole haemoglobins are replaced by adult haemoglobins composed of entirely different globin chains.     

Two transitions of haemoglobin expression in Xenopus: from embryonic to larval and from larval to adult

Electrophoretic analyses of haemoglobin and globin phenotypes in families of Xenopus borealis and Xenopus l. laevis revealed two developmental haemoglobin transitions during ontogeny. The first transition occurs at the developmental stage when tadpoles begin to feed. It is characterized by the decline of embryonic-specific globins in favour of novel, tadpole-specific globins (X. borealis) correlated to changes in the haemoglobin pattern. We suppose that this switch results from the replacement of a primitive, ventral blood island-dependent erythrocyte population by tadpole erythrocytes from other erythropoietic sites. Several other globin chains and haemoglobins are present in both young tadpoles and throughout larval life. The second, well-known transition occurs during metamorphosis, where all tadpole haemoglobins are replaced by adult haemoglobins composed of entirely different globin chains.     

Erythropoiesis and unexpected expression pattern of globin genes in the salamander Hynobius retardatus

Transition of hemoglobin (Hb) from larval to adult types during the metamorphosis in a salamander Hynobius retardatus has been reported to occur almost independently of thyroid activity, in contrast to the case with many amphibians. In order to obtain further information on the mechanism of the transition in H. retardatus, larval and adult globin cDNAs were cloned, and the globin gene expression was analyzed in normally developing and metamorphosis-arrested animals. Northern hybridization and RT-PCR revealed that larval globin genes were initially expressed 5 days before hatching, and unexpectedly remained expressed even in juveniles 2 years old. The adult globin gene was expressed 19 days after hatching, much earlier than the initiation of morphological metamorphosis. Furthermore, the pattern of globin gene expression in metamorphosis-arrested larvae was almost identical to that in normal controls, suggesting that the transition occurs independently of thyroid hormones. In larvae recovering from anemia, precocious Hb transition, which occurs in Xenopus laevis and Rana catesbeiana, did not occur in H. retardatus. In situ hybridization convincingly demonstrated that the erythropoietic sites are the ventral blood island and the dorsolateral plate at the prehatching stage. During the ontogeny they changed to the liver, kidney, and spleen and were finally restricted to the spleen. Single erythroid cells expressed concurrently larval and adult globin genes, as demonstrated by double in situ hybridization. Thus the transition occurred within a single erythroid cell population, a unique characteristic of H. retardatus. Received: 5 August 1999 / Accepted: 14 October 1999     

The metamorphic switch in hemoglobin phenotype ofXenopus laevis involves erythroid cell replacement

Summary To elucidate the cellular basis of hemoglobin transition inXenopus laevis the distribution of larval and adult hemoglobins was analyzed by indirect immunofluorescence in the circulating erythrocytes during metamorphosis. In addition, the morphological characteristics as well as the capacity for synthesis of DNA and hemoglobin in the erythrocytes were followed during the same developmental period. Our quantitative analysis on the distribution of larval and adult hemoglobins suggests that they are localized in different cells. Hemoglobin transition, therefore, most likely reflects replacement of the larval erythrocyte population by new cells which are committed to adult globin synthesis. Since hemoglobin transition is not accompanied by an increase in the abundance of immature erythroid cells with active DNA synthesis, we assume that the presumptive adult erythroid cells are released into circulation at a relatively advanced stage of maturation. The decline in the synthesis of DNA and larval hemoglobin further indicates that cessation of cell renewal in the larval erythrocyte population may represent a decisive step in hemoglobin transition.     

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.     

Sequential methylation of globin mRNA in nucleated erythroid cells and reticulocytes of mice

The order of methylation of the 5'-terminus of globin mRNA of mice was studied by incubation of staged nucleated erythroid cells and peripheral reticulocytes with [methyl-3H] methionine. Methylation of the 5'-termini of alpha and beta- globin mRNAs in enucleated reticulocytes was demonstrated as follows: (a) [methyl-3H] incorporation into poly(A)+ RNA of reticulocytes co-migrated with the alpha- and beta- globin mRNAs on gel electrophoresis, and (b) following digestion of this RNA, radioactivity was localized to the four methyl sites at the 5'-capped structure of mouse globin mRNAs. However, this methylation is only 5 to 8% as efficient as in nucleated erythroid precursor cells, suggesting that most globin mRNA molecules are fully methylated prior to the reticulocyte stage. Incubations of early and late nucleated erythroid precursor cells and pulse-chase experiments with reticulocytes demonstrate that addition of the four 5'-terminal methyl groups follows an orderly sequence. In addition, the pulse-chase experiments suggest the turnover of the N7-methyl group on the 5'-terminal guanosine, but not of the other methyl groups in the 5'-terminus of globin mRNA. Thus, 5'-terminal methylation of globin mRNA is a nonrandom, dynamic process.     

Ontogenetic changes of circulating erythroid cells and haemoglobin components in Esox lucius

Using light microscopy the morphology, the mitotic index and levels of erythroid cell types were detected from 48 h pike Esox lucius embryos before hatching to adult specimens. At the same developmental stages, the haemoglobins and globin chains expressed were electrophoretically characterized. The erythroid cells of the primitive generation were the most abundant from 48 h before hatching until 15–20 days after hatching, then their number decreased and only rare cells remained in the 3 month‐old juvenile specimens. These cells divided and differentiated in the blood and were substituted by the definitive erythrocyte series. As in other vertebrates, the immature cells of the two generations differed in morphological properties and in the synthetized haemoglobin. The circulating erythroid cells of the definitive population cell lineage were, at all differentiation stages, smaller than those of the primitive generation. The definitive erythrocytes appeared in blood smears of 7 days post‐hatching larvae, they increased rapidly and at 20 days they represented the predominant red blood cell population in the circulation of young pike. Electrophoretic analysis of haemolysates obtained from different developmental stages indicated the presence of distinct embryonic, larval and adult haemoglobins. The embryonic haemoglobins differed from those of the older larva and juvenile specimens and were detectable within the first week of post‐hatching development when only primitive erythrocytes were present in the blood.     

Immunohistochemical analysis of the distribution of histone H5 and hemoglobin during chicken development

We used immunohistochemical procedures to investigate embryonic erythropoiesis in serial sections of chicken embryos after 2-13 days of incubation. Antibodies specific for the erythrocyte-specific histone H5, for embryonic hemoglobin, and for adult hemoglobin were used as markers for general, primitive, and definitive erythropoiesis, respectively. Histone H5 was present in erythrocytes at all of the stages studied, i.e., in both the primitive and definitive cells. Cell of the definitive lineage were first detected, at about 5-6 days of incubation, in erythroid foci in the mesenchyme around the vitelline stalk. At 7-9 days of incubation, a massive mesenchymal conglomeration of erythropoietic cells developed, extending from the cervical to the abdominal region and ventrally to the vertebral body, with its largest extensions being around the arteries in the mediastinum. Immunostaining revealed that these erythroid cells belonged to the definitive erythropoietic lineage. These cells had disappeared completely after 12 days of incubation, i.e., before erythropoiesis is visible in the bone marrow. These observations are consistent with the notion that the yolk sac is essential for the formation of the definitive erythroid lineage.     

Developmental changes in erythropoietin receptor expression of fetal mouse liver.

Erythropoietin (EPO) stimulates proliferation and differentiation of late erythroid precursor cells (CFU-E) and thereby determines the rate of erythropoiesis. Liver is the major erythropoietic site in a fetus. We dealt with developmental changes in CFU-E and EPO receptor (EPO-R) of fetal mouse liver. The affinity of the EPO-R to EPO was unchanged during fetal development. The population size of CFU-E, the number of EPO-R per liver cell, and EPO-R mRNA decreased as gestation proceeded, in a pattern indicating that the expression of EPO-R on erythroid precursor cells in fetal mouse liver is governed mostly by the process of mRNA production.     

Different globin messenger RNAs are present before and after the metamorphosis in Lampetra zanandreai

Lampreys are very primitive vertebrates belonging to the Agnata group. Although higher vertebrates have polymeric hemoglobin molecules which are encoded by several differentially expressed genes, lampreys have monomeric hemoglobins. However, it is unclear whether one or more globin genes are present. In this paper we show that four different species of globin can be separated by electrophoresis in acetic acid-urea-Triton gels. Two of the four species are present only before metamorphosis, while the other two are present only during adult life. In order to discover whether these differences are due to post-translational modifications of a unique amino acid sequence, we extracted globin mRNAs from both larval and adult stages and translated them in vitro. We found that both larval and adult globin mRNAs produce single globin bands; however, larval and adult bands are different from each other. Our data are consistent with the idea that two different globin genes are present in lampreys and that they are differentially expressed during development.     

Coexpression of embryonic, fetal, and adult globins in erythroid cells of human embryos: relevance to the cell-lineage models of globin switching

The cellular control of the switch from embryonic to fetal globin formation in man was investigated with studies of globin expression in erythroid cells of 35- to 56-day-old embryos. Analyses of globins synthesized in vivo and in cultures of erythroid progenitors (burst-forming units, BFUe) showed that cells of the yolk sac (primitive) erythropoiesis, in addition to embryonic chains, produced fetal and adult globins and that cells of the definitive (liver) erythropoiesis, in addition to fetal and adult globins, produce embryonic globins. That embryonic, fetal, and adult globins were coexpressed by cells of the same lineage was documented by analysis of globin chains in single BFUe colonies: all 67 yolk sac-origin BFUe colonies and 42 of 43 liver-origin BFUe colonies synthesized epsilon-, gamma-, and beta-chains. These data showed that during the switch from embryonic to adult globin formation, embryonic and definitive globin chains are coexpressed in the primitive, as well as in the definitive, erythroid cells. Such results are compatible with the postulate that the switch from embryonic to fetal globin synthesis represents a time-dependent change in programs of progenitor cells rather than a change in hemopoietic cell lineages.     

Inhibition of heme biosynthesis in erythroid precursors (BFU-e) isolated from human peripheral blood: effects on globin synthesis

We studied the relationship between heme accumulation and globin synthesis in human erythroid precursors which were stimulated by 2 I.U. of erythropoietin in semi-solid cultures (1% methyl-cellulose, 20% fetal calf serum) and treated with 6-9 micrograms/ml of desferrioxamina (DF), a potent inhibitor of heme synthesis (6). Heme accumulation was detected by specific reaction with benzidine (4), globin synthesis by CM-cellulose column chromatography. Our results demonstrate that globin gene expression occurs in DF-treated erythroid cells which do not accumulate heme molecules. As heme does affect translation and stability of globin mRNA (10) our system might be suitable for studies focused on pathological alterations of erythropoiesis associated with the presence of unstable globin mRNAs and/or unstable globins.