Bone marrow CD34+/B220+ progenitors target the inflamed brain and display in vitro differentiation potential toward microglia.

Recent evidence indicates that microglial cells may not derive from blood circulating mature monocytes as they express features of myeloid progenitors. Here, we observed that a subpopulation of microglial cells expressed CD34 and B220 antigens during brain development. We thus hypothesized that microglia, or a subset of microglial cells, originate from blood circulating CD34+/B220+ myeloid progenitors, which could target the brain under developmental or neuroinflammatory conditions. Using experimental allergic encephalomyelitis (EAE) as a model of chronic neuroinflammation, we found that a discrete population of CD34+/B220+ cells expands in both blood and brain of diseased animals. In EAE mice, intravenous transfer experiments showed that macrophage-colony stimulating factor (M-CSF) -expanded CD34+ myeloid progenitors target the inflamed central nervous system (CNS) while keeping their immature phenotype. Based on these results, we then assessed whether CD34+/B220+ cells display in vitro differentiation potential toward microglia. For this purpose, CD34+/B220+ cells were sorted from M-CSF-stimulated bone marrow (BM) cultures and exposed to a glial cell conditioned medium. Under these experimental conditions, CD34+/B220+ cells were able to differentiate into microglial-like cells showing the morphological and phenotypic features of native microglia. Overall, our data suggest that under developmental or neuroinflammatory conditions, a subpopulation of microglial cells derive from CNS-invading CD34+/B220+ myeloid progenitors.

The various domains of v-myb and v-ets oncogenes of E26 retrovirus contribute differently, but cooperatively, in transformation of hematopoietic lineages.

The genome of the avian leukemia virus E26 is a unique example of association between two transcription factors which appear as a fused composite nuclear oncoprotein, P135gag-myb-ets. Previous studies with E26 have shown that v-myb and v-ets must cooperate to fully transform both erythrocytic and myelomonocytic precursor cells in vivo and in vitro. To analyse further the contribution of the individual domains involved in the transformation of various hematopoietic lineages, we have constructed several mutant viruses expressing a fusion protein with deletions in either v-myb or v-ets. We show here that integrity of the v-ets oncogene is necessary for transformation of the erythrocytic cells but that neither the DNA-binding domain nor the trans-activating domain of v-myb is required for this transformation. The DNA-binding domain of v-ets is necessary to transform myelomonocytic cells. Furthermore, we show that E26 onco-protein also transforms granulocytic cells. The v-ets DNA-binding domain is not necessary to transform them, whereas deleting the v-myb DNA-binding domain strongly reduces transformation of these cells. These data show that the v-myb and v-ets DNA-binding domains provide quite different contributions to the transformation of various hematopoietic lineages by E26.

Contact inhibition within hemoglobin S polymer by thiol reagents.

N-Ethylmaleimide, a thiol reagent, increases the solubility of deoxyhemoglobin S. We investigated which of the two reacted beta 93 cysteine residues of the Hb tetramer was responsible for the inhibition of Hb S polymerization. Accordingly we compared the solubility of equal mixtures of HbA + HbS, HbA NEM + HbS and HbA + HbS NEM. Upon deoxygenation these mixtures contain about 50% a stable and asymmetrical hybrid alpha 2A beta A beta S, alpha 2A beta A,NEM beta S or alpha 2A beta A beta S,NEM respectively and 25% parental molecules as confirmed by ion-exchange HPLC performed in anaerobic conditions. Within the hybrid molecule, beta A or beta A,NEM chain has to be present in the alpha beta dimer located in trans to the dimer which contains the only beta 6 valine residue participating in intermolecular contacts (dimer in cis), while beta S or beta S,NEM must be in cis position in the hybrid molecule. The solubility of mixtures increases 4% for HbA NEM + HbS and 20% for HbA + HbS NEM mixtures compared to HbA + HbS mixture, indicating that the inhibitory effect of N-ethylmaleimide is more effective in cis than in trans position. The absence of a major role played by N-ethylmaleimide located in trans was supported by the solubility study of a mixture of HbS + Hb Créteil beta 89 Ser----Asn. The beta 89 residue in trans next to the cysteine beta 93 modified the T structure similarly to N-ethylmaleimide, and did not affect intermolecular contacts. Crystallographic studies of molecular contacts within deoxyHbS crystals suggest that the cis inhibitory effect of N-ethylmaleimide can be explained by direct inhibition of 'external' contacts between double strands involving the CD corner of the alpha chains.

Kinetics of polymerization of hemoglobin S modified by thiol reagents and by oxidation.

The effects of four thiol reagents on the kinetics of polymerization of hemoglobin S have been studied in high phosphate buffer (1.8 M), in the presence (3 mM) or absence of sodium dithionite, depending on the reduction of mixed disulfides of Hb in the presence of this reducing agent. The effect of oxidized forms (methemoglobin) of HbS on the kinetics of aggregation of deoxyHbS was also studied because of the presence of 33% metHbS when HbS was modified by 4-aminophenyl disulfide. In the presence of sodium dithionite, the delay times prior to polymerization of deoxyHbS modified by N-ethylmaleimide, iodoacetamide and 4-aminophenyl disulfide were, respectively, 1.5-, 1.35- and 1.15-times longer than that of native deoxyHbS. The results indicate that the radicals bound to the cysteine beta 93 residue inhibit the contacts in the polymer formation to various extents but do not modify the size of the nuclei.

Changes of polymerization and conformation of hemoglobin S induced by thiol reagents.

Thiol reagents, covalently bound to cysteine beta 93, either inhibit or facilitate the polymerization process of hemoglobin S. The progelling effect of parahydroxymercurybenzoate or 2,2'-dithiodipyridine contrasted with the increased oxygen affinity and the destabilization of the T state of Hb shown by functional and NMR studies. Thiol reagents increased the oxygen affinity of Hb from 30 to 1000%. Such variability was also observed in the reduction (up to 50%) of the alkaline Bohr effect. We show that the antigelling or progelling activity of thiol reagents does not depend solely on the concentration of molecules present in the deoxy T state but that specific effects of the reagent affects molecular interactions of the hemoglobin S polymerization process.

Mouse alpha chains inhibit polymerization of hemoglobin induced by human beta S or beta S Antilles chains.

A murine model of sickle cell disease was tested by studying the polymerization of hybrid hemoglobin tetramers between alpha mouse and human beta S or beta S Antilles chains were prepared from Hb S Antilles, which was a new sickling hemoglobin inducing a sickle cell syndrome more severe than Hb S. The hybrid molecules did not polymerize in solution, indicating that the mouse alpha chains inhibited fiber formation. Consequently, a mouse model for sickle cell disease requires the transfer and expression of both alpha and beta S or beta S Antilles genes.

Antagonistic role of vitamin D3 and retinoic acid on the differentiation of chicken hematopoietic macrophages into osteoclast precursor cells.

An in vitro culture model of osteoclast differentiation is described which is derived from homogeneous populations of chick yolk sac and peripheral blood macrophages. In primary cultures, both types of macrophages undergo a proliferative phase, become quiescent after reaching high cell densities, then aggregate and eventually form large multinucleated giant cells (MNGCs), presumably by fusion. These MNGCs can be characterized as premature osteoclasts on the basis of several morphological and biochemical criteria, although they do not undergo the final differentiation step rendering them competent to resorb bone in vitro. Clonal analysis of single cell-derived colonies indicates that all macrophages have the potential to differentiate into these osteoclast-like cells under these culture conditions. Both retinoic acid and 1,25-dihydroxyvitamin D3 [1,25-(OH)2D3] modulate macrophage growth, but in an antagonistic manner. Although retinoic acid strongly promotes macrophage proliferation and impedes MNGC formation, 1,25-(OH)2D3 inhibits proliferation and changes the kinetics of MNGC formation. Combination experiments reveal that the proliferative signals induced by retinoic acid can override the signal to differentiate induced by 1,25-(OH)2D3. Our results indicate that even though retinoic acid and vitamin D3 act through homologous receptors, they have dramatically opposing effects on macrophage differentiation toward osteoclast progenitors.

Filterability of sickle cells as a function of pO2: role of physico-chemical factors.

A rigidity index (RI) related to red blood cell deformability was measured by using the hemorheometre. The RI for 13 patients homozygous for sickle cell disease was 109 +/- 44 at 37 degrees C and at atmospheric pO2. The filtration time curve as a function of pO2 is biphasic for sickle cell suspensions. The pO2 at which filtration time is maximum, pO2max., correlated with the rigidity index measured at atmospheric pO2. This pO2max. value was very sensitive to small changes in physico-chemical parameters such as osmolality, pH, temperature, hematocrit, and cell density. Conditions which reduced the Hb S polymerization induced a leftward shift of pO2max.. The experimental curves are in agreement with theoretical models based on the presence of two abnormal cell types: filtrable "slow cells" and infiltrable "sickled cells".

Identification of avian sarcoplasmic reticulum Ca(2+)-ATPase (SERCA3) as a novel 1,25(OH)(2)D(3) target gene in the monocytic lineage.

Osteoclasts are postmitotic, multinucleated giant cells generated by the fusion of hematopoietic mononuclear precursors from the monocyte-macrophage lineage. In culture, adherent macrophages from blood-derived monocytes grow, gather, and fuse together to form multinucleated osteoclast-like cells. These events are controlled by 1,25(OH)(2)D(3). To sort out new 1,25(OH)(2)D(3) target genes involved in osteoclast differentiation, we have performed an RT-PCR differential display using mRNA from macrophages induced for 10 h by 1,25(OH)(2)D(3) compared to nontreated cells. We have identified a new target gene, a chick ATP-dependent Ca(2+) pump, ChkSERCA3. Although the level of the corresponding transcript increases during the differentiation process from macrophages to osteoclast-like cells, its steady-state level is downregulated by hormone treatment. The action of 1,25(OH)(2)D(3) on the Ca(2+)-ATPase gene expression is independent of de novo protein synthesis and is hormone dose dependent. This expression in adult chick was restricted to the hematopoietic cell lineage, spleen, lung, intestine, and brain, whereas no expression was detected in embryos. The function of the protein can be predicted from its high homology with the other members of the SR ATP-dependent Ca(2+) pump family, i.e., storage and control of cytosolic Ca(2+) directly regulated by 1, 25(OH)(2)D(3), further supporting the critical role for intracellular calcium in highly specialized cells such as osteoclasts.

Multinucleated cells can continuously generate mononucleated cells in the absence of mitosis: a study of cells of the avian osteoclast lineage.

The multinucleated bone-resorbing osteoclast has a hematopoietic origin. We have demonstrated previously that osteoclasts are derived from the monocytic lineage by fusion of mononuclear macrophage precursors. Using an in vitro-osteoclast differentiation model derived from pure populations of chick macrophage cultures, osteoclast-like multinucleated giant cells (MNGCs) can be formed by fusion following an active proliferation phase. However, after reaching a peak with 70% of the culture being MNGCs, a new round of expansion of the mononuclear cells is observed. The following experiments suggest that these mononuclear cells were derived directly from the MNGCs by a budding process, selectively from the central zone of the apical surface. After microinjection of the membrane-impermeable probe, Lucifer Yellow, into single MNGCs, initially only diffuse fluorescence, limited to the whole MNGC injected, was observed. However, after 24-48 hours fluorescent mononuclear cells were observed adjacent but distinct from the injected MNGC. To confirm that these mononuclear cells were indeed derived from a parent MNGC, single MNGCs were cloned into single wells. Within a week, the MNGC was surrounded by mononuclear cells, which eventually populated the entire well. These mononuclear cells could then give rise to a second generation of MNGCs following a three-week period of culture. To determine whether this process required mitosis, MNGCs were cultured for three days in the presence of the mitotic inhibitor, Ara-C, prior to microinjection with Lucifer Yellow. Fluorescent mononuclear cells were still seen to arise from a single injected MNGC under these conditions.(ABSTRACT TRUNCATED AT 250 WORDS)

Covalent binding of glutathione to hemoglobin. I. Inhibition of hemoglobin S polymerization.

Thiol reagents react with cysteine beta 93 of hemoglobin and as a result increase the oxygen affinity of hemoglobin. In the present studies we have used a thiol-disulfide exchange between mixed disulfides of hemoglobin and reduced glutathione to attach intracellular glutathione to hemoglobin and to study its antisickling properties. The rates of production of glutathionyl hemoglobin (G-Hb) depend on the structure of the thiol reagent linked to cysteine beta 93. Up to 25% G-Hb can be produced in normal and sickle red cells because of the high intracellular concentration of reduced glutathione. This high level of G-Hb in normal cells increases the oxygen affinity by about 35% and reduces heme-heme interactions. In sickle cells the increased oxygen affinity is associated with an inhibition of sickling of about 70% at 21 mm Hg. Inhibition of polymerization of deoxy HbS is also due to a direct inhibition of intermolecular contacts in the fibers as demonstrated by the increased solubility and the increased delay time of G-HbS compared to deoxy HbS.

Mouse beta thalassemia, a model for the membrane defects of erythrocytes in the human disease.

The present study describes the pathophysiology, at the cellular level, of the mouse beta thalassemia and shows the pertinence of this model for the human disease. The homozygous state of mouse beta thalassemia is characterized by a clinical syndrome similar to the human beta thalassemia intermedia, but it cannot be explained by the small deficiency in beta chain synthesis. The small pool of unpaired and soluble alpha chains present in mouse reticulocytes contrasts with the large amount of insoluble alpha chains in erythrocytes which is induced by the high instability of mouse alpha chains and the absence of significant proteolysis. The amount of insoluble alpha chains associated with red cell ghosts is similar in human and mouse disease of similar severity. The study of membrane protein defects showed a decreased amount of spectrin (alpha and beta chains) and dramatic changes in the distribution of the most reactive thiol groups of membrane proteins. These results were similar to that previously described in the human disease (Rouyer-Fessard, P., Garel, M. C., Domenget, C., Guetarni, D., Bachir, D., Colonna, P., and Beuzard, Y. (1989) J. Biol. Chem. 264, 19092-19098). Abnormal density distribution curves of erythrocytes and oxidant-induced lysis of red blood cells used as functional tests were similar in the human and mouse beta thalessemia. We conclude from the present study that 1) mouse beta thalassemia is an excellent model for the membrane defects occurring in the human disease; 2) disease expression is not the reflection of the globin chain unbalance only nor of the soluble pool of alpha hemoglobin chain but mainly is a reflection of insoluble alpha chains; and 3) the rate of proteolysis and instability of alpha chains are important factors which must be taken into consideration in the pathophysiology and the clinical heterogeneity of the disease.

Inhibition of erythrocyte sickling by thiol reagents.

The antisickling effects of eight thiol reagents that cross the red cell membrane and then react with the cysteine beta 93, the only accessible thiol group of hemoglobin, have been investigated at various pO2 values. In spite of completely reacted hemoglobins, the potent antisickling effect varied from one compound to the other and was partially related to the extent of the increased oxygen affinity of intact sickle cells induced by these compounds. The formation of methemoglobin upon the incubation of red blood cells with some disulfides had only a small effect on the sickling process.

Binding of 21 thiol reagents to human hemoglobin in solution and in intact cells.

The reactivity of the cysteine-beta 93 residue of human hemoglobin was investigated in order to define the optimal structure of potential antisickling agents. The properties of 21 thiol reagents were compared with regard to (a) their binding rate to hemoglobin in solution and within intact cells; (b) the modification of the oxygen dissociation curve of intact cells and (c) the effect on methemoglobin formation in solution or within intact cells. The results show the very different behaviors of these reagents.

A study of membrane protein defects and alpha hemoglobin chains of red blood cells in human beta thalassemia.

The soluble pool of alpha hemoglobin chains present in blood or bone marrow cells was measured with a new affinity method using a specific probe, beta A hemoglobin chain labeled with [3H]N-ethylmaleimide. This pool of soluble alpha chains was 0.067 +/- 0.017% of hemoglobin in blood of normal adult, 0.11 +/- 0.03% in heterozygous beta thalassemia and ranged from 0.26 to 1.30% in homozygous beta thalassemia intermedia. This elevated pool of soluble alpha chains observed in human beta thalassemia intermedia decreased 33-fold from a value of 10% of total hemoglobin in bone marrow cells to 0.3% in the most dense red blood cells. The amount of insoluble alpha chains was measured by using the polyacrylamide gel electrophoresis in urea and Triton X-100. In beta thalassemia intermedia the amount of insoluble alpha chains was correlated with the decreased spectrin content of red cell membrane and was associated with a decrease in ankyrin and with other abnormalities of the electrophoretic pattern of membrane proteins. The loss and topology of the reactive thiol groups of membrane proteins was determined by using [3H]N-ethylmaleimide added to membrane ghosts prior to urea and Triton X-100 electrophoresis. Spectrin and ankyrin were the major proteins with the most important decrease of thiol groups.

v-myb and v-ets cooperate for the mitogenic stimulation of primary fibroblasts by avian E26 retrovirus.

By using a series of deletion mutants, we have shown that the stimulation of fibroblast growth by E26 requires the cooperation of the two oncogenes, v-myb and v-ets, fused in the nuclear viral product. Of the two DNA-binding domains, only one must be present to promote anchorage-independent growth, whereas that of v-myb is required to allow growth in low serum medium. Furthermore, the v-ets oncogene comprises multifunctional domains.

[Use of a new rheometer for the study of the filtrability of a suspension of sickled red cells as a function of PO2]. / Utilisation d'un nouveau rhéomètre pour étudier la filtrabilité d'une suspension de globules rouges drepanocytaires en fonction de la PO2.

The filtration time of a small volume (0.1 ml) of red cell suspension from normal (AA), heterozygous (AS) and homozygous (SS) subjects for sickle cell disease was investigated as a function of PO2 The curve of filtration time of AS and SS red cell suspensions was biphasic. At high values of PO2, the progressive reduction of filtrability of sickle cell suspensions with decreasing PO2 occurred without new change in morphology of most of the cells. In contrast, at lower PO2 the apparent filtrability was improved and the cells were sickled." However the red blood cells were retained by the filter and the "solvent" filtrability was improved because rigid and highly deformed sickled cells did not clogged completely the pores of the filter. This study allowed to distinguish a new concept of apparent filtrability for red blood cells in sickle cell disease.