Intraerythrocytic organic phosphates of fetal and adult seaperch (Embiotoca lateralis): Their role in maternal-fetal oxygen transport

Summary The viviparous seaperch,Embiotoca lateralis, has unique fetal and adult hemoglobins. Stripped fetal hemoglobin has a higher oxygen affinity than stripped adult hemoglobin at pH 6.5–7.1. The oxygen affinities of both adult and fetal hemoglobins are lowered allosterically by ATP at pH 7.1. Both fetal and adult seaperch erythrocytes include approximately 82% ATP and 18% GTP of the total nucleotide triphosphates (NTP) with a trace of AMP. No 2,3-diphosphoglycerate or inositol polyphosphate was detected. Mid- and late-gestation erythrocytes contain less NTP/mole hemoglobin tetramer than do adult cells. The effective NTP concentration in adult cells is higher than that of the fetal erythrocytes even when the intracellular concentration of Mg²⁺, which complexes with NTP, is accounted for. The difference in adult and fetal intraerythrocytic NTP concentration should enhance transfer of oxygen from maternal to fetal blood. Thus, the teleostEmbiotoca lateralis may employ a dual mechanism in maternal-fetal oxygen transfer. A difference in fetal and maternal hemoglobin structure and oxygen affinities is enhanced by a difference in their respective intraerythrocytic organic phosphate concentrations.     

A kinetic study of the genetic control of hemopoietic progenitor cells assayed in culture and in vivo

The kinetics of growth of bone marrow cells from normal or genetically anemic mice (Sl/Sl^d and W/W^v) were studied in irradiated normal and genetically anemic hosts. The parameters followed included total cellularity, the number of peroxidase positive cells, and the number of cells capable of forming colonies in vivo (CFU-S) or in culture (CFU-C). The results of these experiments demonstrate that W and Sl defects alter the growth of CFU-C and peroxidase-positive cells to a modest degree; that the defects are more obvious when studied in spleen rather than in bone marrow; and that there is no additivity of W and Sl defects. Nineteen irradiated recipients of marrow from W/W^v mice were studied after three to six months. Of these, 18 showed host-type erythrocytes, while in one mouse the erythrocytes had the size distribution of W/W^v cells. This finding indicated that occasionally genetically defective stem cells may repopulate irradiated hosts.     

T lymphocyte development from fetal hematopoietic stem cells

Hematopoietic stem cells (HSCs) are isolated from bone marrow and fetal liver as Thy-1^lo Lin^- Sca-1⁺ cells. Both adult and fetal HSCs have similar stem cell activities. However, fetal HSCs differentiate more efficiently than adult HSCs into Vγ3 and Vγ4 cells without N nucleotide insertion in the fetal thymic microenvironment. Thus HSC themselves may lose some of their developmental potential during ontogeny. It is possible that only fetal, but not adult, HSCs can differentiate into the fetal types of hematopoietic cells, including Vγ3, Vγ4 T cells, CD5 B cells, and fetal type erythrocytes.     

Marrow allograft success inW/W v anemic mice: Relation to skin graft survival times

Genetically anemicW/W ^v mice were cured by marrow allografts from donors of 13 out of 18 tested strains that differed at non-H-2 histocompatibility alleles defined by skin or tumor grafting. They were also cured by donors from all four tested congenic lines whose antigenic differences had been defined by induction of serum antibodies. They were not cured acrossH-2 differences. Tail skin graft survival times on uncuredW/W ^v recipients were determined for all congenic lines used as marrow donors. The longest and shortest skin graft survival times predicted correctly marrow graft success or failure. NoW/W ^v mice were cured by marrow grafts from donors of the three congenic lines whose skin grafts were rejected in fewer than three weeks. Almost everyW/W ^v mouse grafted was cured by marrow grafts from donors of the 13 congenic lines whose skin grafts survived longest, from 11 to more than 25 weeks. Intermediate skin graft survival times failed to predict whether marrow grafts would succeed.W/W ^v mice were cured by marrow from four congenic lines with mean skin graft survival times of 4.2, 4.4, 8, and 9 weeks, while marrow grafts failed from other congenic lines with mean skin graft survival times of 3.3, 3.4, 4.8, and 8.7 weeks. The simplest explanation for these results is that the antigens specified by theH-2, H-3, H-4, H-25, andH-28 loci are strongly immunogenic on both marrow precursor cells and skin,H-17 andH-24 are strongly immunogenic on skin but not on marrow, andH-12 is strongly immunogenic on marrow precursor cells but less strongly on skin.     

Survival of marrow allografts inW/W v anemic mice: Effect of disparity at theEa-2 locus

Erythrocyte producing tissues of genetically anemicW/W ^v mice were completely populated and the anemic mice were permanently cured by marrow cell grafts from donors that differed at theEa-2 locus. Circulating erythrocytes contained ≧ 80% donor Ea-2 antigen and ≧ 90% donor hemoglobin. Population occurred without immunosuppressive treatment. No sign of graft-versus-host reaction was observed, although donors were congenic with one parent strain of the F₁ hybrid recipients. When partially congenic donors carrying the T6 chromosome marker were used, the immune systems of curedW-anemic mice were populated to an appreciable extent by donor cells. The dependence of cure upon route of injection and the persistence of functioning donor type cells across the strong immunological barrier of the Ea-2 system are discussed.     

Fetal erythropoiesis in steel mutant mice : I. A morphological study of erythroid cell development in fetal liver

A method of definitive identification of mutant (S1/S1^d) and wild-type (+/+) mouse embryos in segregating litters is described, based on the total number of circulating erythrocytes in a unit volume of embryonic blood and the relative proportion of nonnucleated vs. nucleated red blood cells. Evidence is presented that from days 13–17 of gestation, S1/S1^d embryos have many fewer fetal liver derived nonnucleated erythrocytes whereas the number of yolk sac-derived nucleated red blood cells is similar between S1/S1^d and +/+. Erythroid precursor cells at various stages of maturation in mutant fetal livers are studied by light and electron microscopy, and their fine structure is found to be identical to those present in normal embryos. The number of hemoglobin-containing mature erythroblasts in mutant fetal livers is far fewer than that of the normal, whereas the number of immature erythroid precursors present in a unit area of fetal liver is not significantly different between S1/S1^d and +/+. It is suggested that the mutant S1 gene product(s) interferes with or fails to support the differentiation of immature erythroid precursors into hemoglobin synthesizing cells.     

Human oral epithelial cell culture II. Keratin expression in fetal and adult gingival cells

Summary Epithelial cells from human fetal and adult gingiva were cultured in keratinocyte growth medium (KGM), a serum-free medium. The expression of keratin proteins in these cells was evaluated using immunohistochemistry and SDS-PAGE-immunoblot analysis and compared with expression in the tissue. Keratins 5, 6, 14, 16, and 19 were identified in cells cultured from both fetal and adult tissues. K19 was localized in basal cells of fetal oral tissue but was not seen in adult gingiva (except for scattered Merkel cells). K1 and K10 were expressed in tissue, but not in cultured cells. The keratin profiles of cultured epithelial cells from several adult donors were similar and were identical in cultures from primary through Passage 5. K13, a differentiation-specific keratin, was expressed in all suprabasal cells of fetal oral epithelium, but shows only spotty expression in adult gingival tissue. K13 was expressed in cultures of fetal cells, but very weakly or not at all in cultures of adult cells. K13 expression was greater in cultures grown with physiologic calcium concentrations (1.2 mM) than in those grown at 0.15 mM or less. Our findings are consistent with basal-like characters of these cells in 0.15 mM calcium growth conditions. Differentiation of fetal oral cells in culture to the suprabasal basal cell stage in 1.2 mM Ca²⁺ is shown by the expressionof K13. This work was supported by Biomedical Research grant RR05346, National Institutes of Health grant DE04660, University of Washington Graduate Fund and Hack Foundation Fund, Department of Periodontology, University of Washington.     

Outward-rectifying chloride channels in cultured adult and fetal human nasal epithelial cells

Summary The patch-clamp technique was used to characterize ion channels in the apical membranes of cultured human nasal epithelial cells, dissociated from fetal nasal mucosa and from adult nasal polyps. Outward-rectifying chloride channels were found in 4.3% of the cell-attached patches from fetal cells (n=258) and in 3.1% of the patches from adult cells (n=320). After exeision the number of patches containing active chloride channels increased threefold to 13% of the patches from the fetal cells and 10% from adult cells. The single-channel conductance at 0 mV in symmetrical 150mm NaCl solutions was 24.3 ±0.9 pS (n=28) and 26.0 ± 1.2 pS (n=30), respectively, in adult and fetal cells and showed outward rectification in the potential range from –80 to +80 mV. In fetal cells as well as in adult cells the channels were anion selective, and were almost impermeable for larger anions and monovalent cations. In cell-free patches the channels were Ca²⁺ independent. In most of the channels the open probability was voltage independent and high (±0.86); in 20% of the channels, however, the open probability increased with depolarization. In conclusion, fetal nasal epithelial cells contain chloride channels in their apical membranes with singlechannel properties and regulatory mechanisms similar to those found in cells from adults.     

Genetic and developmental variation of hemoglobin in the deermouse,Peromyscus maniculatus

A genetic investigation of electrophoretic hemoglobin variants of the deermouse, Peromyscus maniculatus, shows three alleles, HbI ^f, HbI^r, and HbI ^o, at a duplicated site controlling the six adult phenotypes. The HbI ^fallele has not been described previously. The hemoglobin locus is not closely linked to the albino locus. Fetal hemoglobin is distinct from any of the adult components and has a slower electrophoretic mobility. The fetal phenotype changes to the adult type between the days 15 and 18 of prenatal life.     

Fetal and adult multipotent mesenchymal stromal cells are killed by different pathways

Background aimsMultipotent mesenchymal stromal cells, also known as mesenchymal stem cells (MSC), can be isolated from adult and fetal tissues. Recently, there has been considerable interest in MSC because they have features favorable for transplantation, namely their multipotency and non-immunogenic properties.MethodsWe analyzed how human MSC derived from first-trimester fetal liver and adult bone marrow interact with naive and activated innate natural killer (NK) cells. NK cell function was studied by measuring killing of MSC, as well as degranulation (CD107a) induced by MSC. To assess the importance of NK cell killing, expression of surface epitopes was analyzed by flow cytometry on MSC before and after stimulation with interferon (IFN)γ.ResultsFetal and adult MSC express several ligands to activating NK cell receptors as well as low levels of HLA class I, with large inter-individual variation. Naive peripheral blood NK cells did not lyse fetal or adult MSC, whereas interleukin (IL)2 activated allogeneic as well as autologous NK cells did. Pre-incubation of MSC with IFN-γ increased their levels of HLA class I, protecting them from NK cell recognition. Fetal and adult MSC were preferably killed via the tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) and Fas ligand (FasL) pathways, respectively. Blocking NKG2D reduced NK cell degranulation in both fetal and adult MSC.ConclusionsFetal and adult MSC differ in their interactions with NK cells. Both fetal and adult MSC are susceptible to lysis by activated NK cells, which may have implications for the use of MSC in cell therapy.     

IL‐23 drives differentiation of peripheral γδ17 T cells from adult bone marrow‐derived precursors

Pro‐inflammatory interleukin (IL)‐17‐producing γδ (γδ17) T cells are thought to develop exclusively in the thymus during fetal/perinatal life, as adult bone marrow precursors fail to generate γδ17 T cells under homeostatic conditions. Here, we employ a model of experimental autoimmune encephalomyelitis (EAE) in which hematopoiesis is reset by bone marrow transplantation and demonstrate unequivocally that Vγ4⁺ γδ17 T cells can develop de novo in draining lymph nodes in response to innate stimuli. In vitro, γδ T cells from IL‐17 fate‐mapping reporter mice that had never activated the Il17 locus acquire IL‐17 expression upon stimulation with IL‐1β and IL‐23. Furthermore, IL‐23R (but not IL‐1R1) deficiency severely compromises the induction of γδ17 T cells in EAE, demonstrating the key role of IL‐23 in the process. Finally, we show, in a composite model involving transfers of both adult bone marrow and neonatal thymocytes, that induced γδ17 T cells make up a substantial fraction of the total IL‐17‐producing Vγ4⁺ T‐cell pool upon inflammation, which attests the relevance of this novel pathway of peripheral γδ17 T‐cell differentiation.     

Hemopoietic progenitor cells of W anemic mice studied in vivo and in vitro

The proliferation and differentiation of hemopoietic cells from genetically anemic W^v/W^x,W/W^v, and W^v/W^v mice, and from nonanemic carrier W/+, W^b/+, and W^v/+ mice have been evaluated in vivo by transplantation techniques and in vitro by the agar gel culture method. Marrow from anemic and carrier mice contained progenitor cells which were decreased in number and formed small, often rudimentary, colonies in the spleens of irradiated recipient mice. Proliferation and differentiation of both erythropoietic and leukopoietic progenitor cells were delayed and reduced, but erythropoiesis was more severely affected than leukopoiesis. The severity of the hemopoietic impairment was gene-dose dependent. The W gene effect on leukopoietic progenitor cells was not secondary to anemia or to abnormal erythropoiesis. The marrow cells of anemic and carrier mice which form colonies of granulocytic and mononuclear cells in vitro were neither decreased in number nor impaired in proliferation and differentiation. Hypertransfusion of red blood cells increased the frequency of in vitro colony-forming cells, but not that of in vivo progenitor cells. The data demonstrate that colony-forming cells which proliferate in the agar gel cultures in vitro are distinct from the in vivo colony-forming cells and suggest that the former are primitive members of the granulocytic cell line. Perhaps in vitro CFU are in an intermediate stage of differentiation between in vivo CFU and myeloblasts, analogous to that which has been suggested for the erythropoietin-sensitive cell in the red cell series. W mutant alleles appear to act, therefore, at or very near the beginning of hemopoietic differentiation.     

Usage of TCRAV and TCRBV gene families in human fetal and adult TCR rearrangements

We have investigated fetal and adult T-cell receptor (TCR) A and B V-gene repertoires both by fluorescence-activated cell sorter (FACS) analysis with the avialable TCR V region-specific mAbs and by the polymerase chain reaction (PRC) with TRC V gene family-specific oligonucleotides. Among the low number of CD3+ T cells, most of the TRC V region tested for could be detected by FACS analysis in liver, bone marrow, and spleen derived from a 14-week-old fetus and two 15-weeks-old fetuses. Similarly, the PCR analysis showed that the majority of the TCRAV and TCRBV families were expressed in the peripheral organs of the 13-week-old fetus, although an apparent absence of particular TCR V families was found in liver and bone marrow. This was most probably the consequence of the low number of CD3⁺ T cells in these organs. In 17-week-old week-old fetal thymi the level of expression of some TCRAV and TCRBV gene families, in particular those that contain single member, was lower compared to post-partum thymi and adult peripheral blood mononuclear cells. The combined data of FACS and PCR analysis demonstrate that TCR genes belonging to the majority of TCR V gene families can be used in TCR and chain rearrngements during early human fetal life. Our data also suggest that the expression levels of some of the single member TCR V gene families may be influenced by the development stage.     

Prostaglandin E2 mediated effects on the synthesis of fetal and adult hemoglobin in blood erythroid bursts

The effects of prostaglandin E₂ (PGE₂) in association with erythropoietin on the synthesis of fetal and adult hemoglobin in peripheral blood-derived erythroid burst colonies from normal adults and from patients with sickle cell anemia were investigated. The synthesized hemoglobin at the end of 8, 14 or 18 days in culture was separated by DEAE-cellulose chromatography of ³⁵S-methione labelled hemoglobin. Quantitative estimation of the synthesized hemoglobin phenotypes, for the three indicated culture periods, showed preferential synthesis of Hb F in addition to an overall increase in hemoglobin synthesis in PGE₂ treated colonies. Furthermore, the reactivation of fetal hemoglobin production by PGE₂ was more pronounced when the adherent cells were included in the culture dishes. These results indicate that the addition of PGE₂ to culture dishes presumably constitutes an environmental change to promote the functional seen in the blood erythroid bursts in terms of Hb synthesis and switching.     

On the kinetics of erythroid cell differentiation in fetal mice. I. Microspectrophotometric determination of the hemoglobin content in erythroid cells during gestation

In a microspectrophotometric study, photographic emulsions and a computer are used for measuring the hemoglobin content of a large number (about 50,000) of erythroid cells in fetal mice. Histograms of the hemoglobin content in erythroid cells illustrate the kinetics of erythropoiesis in yolk sac derived nucleated cells in the fetal peripheral blood, in fetal liver, and in fetal spleen. After the occasional extrusion of their nucleus, yolk sac derived erythrocytes remain as “macrocytes” in fetal circulation two or three days longer than the nucleated yolk sac derived erythrocytes do. Erythrocytes in fetal liver have a constant hemoglobin content of 28 pg ² until day 17 of gestation. During further erythropoiesis in liver and then in the spleen, this amount is gradually adapted to the normal hemoglobin content in red blood cells of 16 pg.     

Skin graft rejection in mice repopulated with marrow of the skin donor type: A SKn gene in a congenic line

Genetically anemic W/W ^c mice and lethally irradiated wild-type mice were cured and populated by grafted marrow cells from donor mice of three congenic lines that differed at non-H-2 histocompatibility loci. Tail skin from mice of the same congenic lines was grafted 3–4 weeks later. In two cases, the recipients behaved as expected, no longer rejecting skin syngeneic with the marrow graft that had repopulated them. However, B6-H-24 ^c skin was rejected by WBB6F₁-W/W mice that were cured with B6-H-24 ^c marrow showing a mean survival time of 9.9 weeks. It was rejected somewhat faster, with a mean survival time of 5.9 weeks, by W/W mice cured with marrow from other types of donors. Results were more variable in lethally irradiated WBB6F₁-+/+ recipients of B6-H-24 ^c marrow, but they also rejected B6-H-24 ^c skin. Both types of recipients remained chimeras after the skin was rejected, showing more than 90% of the B6-H-24 ^c hemoglobin type. This is the first report of a Skn gene in a congenic line.     

On the kinetics of erythroid cell differentiation in fetal mice. II. DNA and hemoglobin measurements of individual erythroblasts during gestation

Microspectrophotometric absorption measurements were used to determine the hemoglobin content of erythroid cells derived from the yolk sac during gestation of fetal C3H mice, from day 9 to day 15. Using the DNA content as a marker for the mitotic state between 2C and 4C phase, five successive cell generations and their mean hemoglobin contents were distinguished: 12 pg (pg, picogram = 10^?12 gm). 22.2 pg, 37 pg, 50 pg and 56 pg. In the final state, nucleated erythrocytes contained 98 ± 22 pg hemoglobin. Erythroid cells derived from the liver were measured on day 15 of fetal gestation. The hemoglobin content of proerythroblasts was below 0.3 pg. The two cell generations in the basophilic state had 0.6 pg and 1.7 pg respectively. Polychromatic erythroblasts yielded a hemoglobin content of 5.1 pg in the first cell generation and 7.5 pg in the second one. Orthochromatic erythroblasts contained 8 pg, reticulocytes 12 pg and mature erythrocytes 28 ± 7 pg hemoglobin. Calculations based on these data suggest that the rate of total hemoglobin synthesis is similar in both yolk sac and liver erythropoiesis. The difference between the final hemoglobin content in nucleated erythrocytes of yolk sac origin and that in hepatic erythrocytes can be explained by the different cell generation times.     

Decreased neutrophils and megakaryocytes in anemic mice of genotype W/W

The concentration of neutrophils and megakaryocytes was determined in the marrow of anemic mice of genotype W/W^v and their normal (+/+) litter mates. In all groups studied, the humerus of W/W^v mice contained significantly less neutrophils and megakaryocytes than did normal animals. Blood neutrophil concentration was less in all groups of W/W^v mice but in only one group which was the youngest group studied, did this value differ significantly from normal. The blood and marrow neutrophil response to endotoxin was similar in W/W^v and “+/+” animals. This suggests that the neutrophilic system of W/W^v mice responds to this stimulus in a relatively normal manner, much as their erythroid system responds to hypoxia, and androgens.     

Differential monooxygenase-like activity of fetal and adult erythrocytes

The monooxygenase-like activity of human erythrocytes was measured by monitoring the rate of para-hydroxylation of aniline. Erythrocytes from umbilical cord blood samples were found to be 3–5 times more active than erythrocytes from adult peripheral venous blood samples. This result may be attributed to an intrinsic difference in the reactivity of the particular form of hemoglobin which predominates in each of these erythrocyte types. Thus, the fetal hemoglobin isolated and purified from the cord blood displayed 2–6 times more activity than purified adult hemoglobin when each was tested in reconstituted aniline hydroxylation systems containing NADPH.     

Precursor of mast cells fixed in the skin of mice

The presence and origin of mast-cell precursors fixed in the skin tissue of mice were investigated. Giant granules of beige (C57BL/6-bg^j/bg^j, Chediak-Higashi syndrome) mice were used to distinguish different populations of mast cells. Pieces of the skin were grafted from the intact WBB6F¹ (WB × C57BL/6)F¹?+/+ mice onto the back of the WBB6F¹?+/+ mice which had been irradiated and injected with bone marrow cells of C57BL/6-bg^j/bj^j mice (bg^j/bg^j ?+/+ chimeras). Although the number of mast cells in the skin grafts decreased after the transplantation, the mast-cell precursors circulating in the bloodstream of bg^j/bg^j ?+/+ chimeras (bg^j/bg^j type) did not seem to enter into the skin grafts, because most of mast cells were of +/+ type after the recovery of mast-cell number to pregrafting levels. As a considerable proportion of +/+-type mast cells was labeled with ³H-thymidine, the recovery of mast-cell number in the grafts was attributed to the proliferation and differentiation of +/+-type precursor cells fixed in the skin tissue of the donor. On the other hand, the skin of WBB6F¹-W/W^v mice seemed to be depleted of fixed precursors, because most of mast cells were of bg^j/bg^j type in skin grafted from WBB6F¹-W/W^v mice to bg^j/bg^j?+/+ chimeras. Since the fixed precursor cells which proliferate and differentiate into mast cells after skin grafting may be transferred to WBB6F¹-W/W^v mice by bone marrow transplantation, such precursor cells seem to have been derived from the bone marrow.