Separation of primitive and definitive erythroid cells of the chick embryo

The primitive and definitive erythroid cells of the chick embryo are separated preparatively by means of velocity sedimentation at unit gravity in BSA gradients. Analyses of the hemoglobins contained by the fractionated cells show a segregation of different hemoglobins between the primitive and definitive cells. Studies of the incorporation of [³H]leucine show that the fractionated cells are normal with respect to their protein synthetic activities and that their relative rates of incorporation are markedly different.     

Reduced binding of epidermal growth factor by avian sarcoma virus-transformed rat cells

Rat cells transformed by Rous sarcoma virus and Fujinami sarcoma virus bound 5-10% of the amount of epidermal growth factor (EGF) bound by normal cells. Scatchard plot analysis indicated that the reduction in binding by transformed cells was due to a decreased number of receptors rather than to altered binding affinity. In experiments with temperature sensitive mutants of Rous sarcoma virus and Fujinami sarcoma virus significant loss of EGF binding occurred within one hour of shift from non-permissive to permissive temperature. Conditioned media from various normal and transformed cell lines were examined for the ability to inhibit EGF binding to normal cells or to cause "down regulation" of EGF receptors. No activity of either type was found. EGF-dependent phosphorylation in isolated membrane preparations was also examined. Membranes from normal cells displayed EGF-dependent phosphorylation of a Mr 180,000 protein presumed to be the EGF receptor. This activity was absent in membranes from transformed cells. The data suggest a close correlation between activation of avian sarcoma virus transforming gene products and modulation of the EGF growth regulatory system.     

Early appearance in neural crest and crest-derived cells of an antigenic determinant present in avian neurons

A monoclonal antibody (“$\text{E}\text{C8}$”) against chicken dorsal root ganglion cells has been produced. The epitope (antigenic determinant) to which this antibody binds appears in neuronal cells—of both the peripheral and central nervous systems—and in a limited number of nonneuronal cell types in avian embryos. The epitope is intracellular and is probably part of a protein as judged by its susceptibility to proteases. This epitope appears very early in neuronal development. It may be detected in brain, spinal cord, and ventral root nerve fibers of Hamburger-Hamilton stage 16 chicken embryos (51–56 hr of incubation). At this same age, $\text{E}\text{C8}\text{-}\text{immunoreactive}$ cells can be found in the neural crest migratory space between the neural tube and the somite about a day before dorsal root ganglia begin to coalesce. Since some cultured neural crest cells (but not somitic mesenchymal cells) also express this epitope, we propose that the $\text{E}\text{C8}$ monoclonal antibody identifies an early differentiating subpopulation of neural crest cells which express this putative neuronal trait soon after the time of cessation of migration in vivo.     

Hemoglobin switching in sheep: commitment of erythroid stem cells to expression of the betaC-globin gene and accumulation of betaC-globin mRNA

The switch from HbA (α₂β₂^A) to HbC (α₂β₂^C) synthesis was induced by injection of erythropoietin into a lamb homozygous for HbA. Serial samples of bone marrow were analyzed to detect the initial commitment of erythroid stem cells (CFU-E) to form colonies which made HbC in vitro, and to detect the initial accumulation of β^C-globin mRNA and the onset of HbC synthesis in erythroblasts in vivo. CFU-E-derived erythroid colonies were formed in plasma clot culture at a low erythropoietin concentration, and the relative amounts of β^A- and β^C-globin synthesized were determined after a 24 hr pulse of ³H-leucine, added after 84 hr in culture. RNA was extracted from nuclei and cytoplasm of “early” and “late” populations of bone marrow erythroblasts which had been fractionated by Ficoll-Hypaque density centrifugation. The concentration of β^A- and β^C-globin mRNA was determined by annealing to purified synthetic DNAs (cDNAs) complementary to β^A and β^C mRNA. No β^C-globin was synthesized in erythroblasts or in CFU-E-derived erythroid colonies prior to the injection of erythropoietin. An increase in the concentration of CFU-E in the bone marrow and the appearance of β^C-globin synthesis in CFU-E-derived colonies were detected 12 hr after the erythropoietin injection. In contrast, β^C mRNA was not detected in either “early” or “late” erythroid cells until 36 hr later. The first measurable β^C-globin mRNA was accompanied by the appearance of β^C-globin synthesis in bone marrow erythroblasts. Our results suggest that the accumulation of β^C-globin mRNA is a relatively late event following induction of HbA to HbC switching by erythropoietin. The expansion of the compartment of erythroid stem cells and the commitment of CFU-E to β^C-globin synthesis appear to precede the detectable accumulation of β^C mRNA by 24–36 hr.     

Immunofluorescent and autoradiographic analysis of the relationship between the presence of histone H5 and DNA synthesis in developing chick erythroid cells

Simultaneous detection of histone H5 by indirect immunofluorescence and of [³H]thymidine incorporation by autoradiography on the same preparations of developing erythroid cells have been used to precisely define the extent of correlation between the loss of nuclear activity and the presence of histone H5. It was found that from day 3–12 of embryonic life there are two successive waves of double-labelled cells. At some stages, as many as 30% of the cells which incorporate [³H]thymidine also contain histone H5. Thus, the simple presence of H5 cannot be sufficient to cause nuclear inactivation. A kinetic analysis of the appearance and disappearance of [³H]thymidine-labelled cells, containing histone H5, and cells which are positive for both markers is presented. The result is consistent with the interpretation that the appearance of H5 in the first wave of double labelled cells occurs just before the erythroid cells become metabolically inactive. These observations modify the concept that histone H5 functions uniquely or solely as a template repressor.     

On the mechanism of erythroid cell sensitivity to chloramphenicol: Studies on mitochondria isolated from erythroid and myeloid tumors

Erythroleukemia mitochondria (E. Mito) and chloroma mitochondria (C. Mito) were isolated from tumors grown in their hosts, DBA/2J mice and Long-Evans rats, respectively. Oxypolarographic tests showed respiratory control and ADP/O ratios typical for well-coupled mitochondria. Therapeutic concentration of chloramphenicol (CAP) had no effect on the energy transfer of those mitochondria. l-[¹⁴C]leucine incorporation into protein was comparable in both types of mitochondria. Although the incorporation at 15 min appeared higher in C. Mito, at 60 min it became similar to that in E. Mito. When CAP was used at the therapeutic concentration of 20 μg/ml about 80% inhibition was observed in both mitochondria. The exogenous amino acid mixture added to the medium was an important determinant in both the rate of leucine incorporation as well as the sensitivity to CAP. Thus, if no amino acids were added the incorporation was reduced to 18–25%. Under these conditions, however E. Mito were significantly more sensitive to the same concentration of CAP than C. Mito. The results suggest that mitochondrial amino acid pool may be involved in the greater sensitivity of erythroid precursors to CAP.     

The cellular oncogenes c-myc, c-myb and c-erb are transcribed in defined types of avian hematopoietic cells

The possible role of normal chicken cellular sequences c-erb, c-myb and c-myc, together referred to as c-onc genes and related to the oncogenes of defective avian acute leukemia retroviruses (DLVs), was investigated by determining the accumulation of c-onc RNA in different avian cells an cell lines. Levels of c-myc and in some instances c-myb RNA are elevated in immature hematopoietic cells or cell lines from various lineages but more mature hematopoietic cells, as well as non-hematopoietic cells, contain only low levels. In contrast, the level of c-erb RNA is generally low, but high in a small number of normal bone marrow cells. The results indicate that the cellular homologues of the viral oncogenes are differentially expressed during hematopoiesis. They also indicate that the hypothesis that DLV target cells express their homologous c-onc genes might hold for c-erb, but is not valid in its simple form for c-myc and c-myb.     

Size and sequence homology of masked maternal and embryonic histone messenger RNAs.

The messenger RNAs for five classes of histone proteins are shown by competitive RNA-DNA hybridization to be stored in the unfertilized egg of the sea urchin, Lytechinus pictus. The masked mRNAs for f2b, f2a2, f3 and f2al histones migrate in polyacrylamide slab gels with the same mobility as the histone mRNAs that are synthesized after fertilization and are found engaged in protein synthesis on polysomes. The masked maternal and embryonic mRNAs for histone f2a1 are identical in mobility when analyzed in a gel system capable of resolving differences estimated as small as 4–5 nucleotides in length. We conclude that these histone mRNAs synthesized during oogenesis and inactive prior to fertilization are not activated during embryogeny by alteration in their molecular size.     

Human lymphocyte subpopulations identified by bacterial adherence are functionally different.

Previously, two B (B₁ and B₂)- and four T (T₁, T₂, T₃, T₄)-lymphocyte subpopulations have been identified in human blood smears by bacterial adherence. Here, to study the functional differences between these subpopulations the T₁T₂ cells were separated from T₃T₄ cells by selective adherence to Escherichia coli-2⁴ monolayers. The adherent cells (T₁T₂ cells) responded well to concanavalin A in 3-day cultures and in mixed lymphocyte culture (MLC) in 6-day cultures and developed into cells specifically cytotoxic for allogeneic lymphocytes. The nonadherent cells (T₃T₄ cells) cultured for the same length of time were poorly responsive to concanavalin A, variably responsive in MLC, and poorly active in specific cytotoxicity. The T₃T₄ cells were naturally cytotoxic for allogeneic lymphocytes and for a normal lymphoblastoid cell line. We concluded that the T cells that bind E. coli-2 (T₁T₂ cells) are functionally different from those that do not bind (T₃T₄ cells).     

Increase in DNA synthesis in Werner''s syndrome cells by hybridization with normal human diploid and HeLa cells

The dominance or recessiveness of the senescent phenotype in cells from patients with Werner's syndrome (WS cells) was investigated using cell fusion. The [³H]thymidine labeling index of normal human diploid fibroblast cell X WS cell heterodikaryons was considerably lower than that of normal homodikaryons, but was significantly higher than that of WS homodikaryons. The labeling index of WS cell X HeLa cell heterodikaryons was the same as that of HeLa homodikaryons. The labeling indices of heterodikaryons obtained by fusion between various strains of premature aging cells were as low as those of parental homodikaryons. These results indicate: (1) the senescent phenotype of WS cells appears to be partially recessive to the phenotype of normal cells and completely recessive to that of HeLa cells; (2) the marked inhibition of DNA synthesis in normal nuclei in heterodikaryons with WS cells could be due to ‘senescent factor(s)’ in WS cells; and (3) no complementation phenomenon was observed among genetically different premature aging cells, probably due to ‘senescent factor(s)’.     

The biosynthesis of ubiquinone in isolated rat heart cells

Beating heart cells were isolated from the adult rat and the biosynthesis of ubiquinone was studied. These cells were able to incorporate p-hydroxy[U-¹⁴C]benzoate into ubiquinone and some unidentified compounds, presumably intermediates in the biosynthesis of ubiquinone. The unidentified compounds were labile to alkali and were also labeled by [5-³H]-mevalonate and [methyl-³H]methionine, but not by p-hydroxy[carboxy-¹⁴C]benzoate. They appear to be chromatographically different from 5-demethoxy ubiquinone and 5-desmethyl ubiquinone. Addition of unlabeled mevalonate stimulated the incorporation of p-hydroxy [U-¹⁴C]benzoate into ubiquinone and the other compounds. The addition of dimethylsulfoxide to the isolated cells or the isolation medium caused inhibition of ubiquinone biosynthesis. Adriamycin was not inhibitory to the biosynthesis of ubiquinone in the cells. The advantages of these cells are the rapidity and ease in studying the biosynthesis of ubiquinone from various precursors and its regulation.     

Differentiation of lens and pigment cells in cultures of neural retinal cells of early chick embryos

Dissociated cells of neural retinas of 3.5-day-old chick embryos (stages 20–21) were cultured as a monolayer in order to examine their differentiation in vitro. These cells started to grow actively soon after inoculation and formed a confluent sheet within which neuroblast-like cells with long cytoplasmic processes were differentiated by 8 days. At about 16 days the differentiation of both lentoid bodies and foci of pigment cells was observed, while neuronal structure disappeared. The numbers of lentoid bodies and foci of pigmented cells continued to increase up to 30 days, when primary cultures were terminated. The increase in δ-crystallin content, as measured by quantitative immunoelectrophoresis assay using rabbit antiserum against δ-crystallin, was consistent with the increase in the number of lentoid bodies in cultures. The amount of α-crystallin per culture, estimated by the same technique as above, reached a maximum at 16 days and decreased slightly during further culture. The differentiation of both lentoid bodies and pigment cells was observed also in cultures of the second generation. The results demonstrate that cells of the undifferentiated neuroepithelium of 3.5-day-old embryonic retinas can achieve at least three differentiations, neuronal, lens, and pigment cells, in vitro. We discuss several differences between the present results and the previous ones from in vitro cultures of 8- to 9-day-old embryonic neural retinas.     

Serum suppresses the expression of hormonally induced functions in cultured granulosa cells

Growth and function of primary cultures of granulosa cells obtained from immature, hypophysectomized, estrogen-treated rats were compared in serum-containing and serum-free media. In serum-free medium (1:1 mixture of DMEM:F-12) supplemented with insulin, hydrocortisone, transferrin and fibronectin (4F medium), the cells remained healthy and steroidogenically responsive for at least 60 days in culture. The growth profile of the granulosa cells in 4F medium was similar to that obtained in serum-containing medium. In both media cell proliferation did not exceed more than one cell doubling. DMEM:F-12 alone did not support the cell viability. Upon FSH stimulation, the cells produced 25 fold more progestin and estrogen per cell in 4F medium than in medium supplemented with 5% serum. This effect was not directly related to serum proteins which mediate cell adhesion since cells cultured in dishes precoated with serum remained steroidogenically responsive to FSH. Cholera toxin and Bt₂-cAMP readily stimulated progestin production in the presence of serum. The inhibitory effect of serum was not reversed by adding the four factors to serum-containing medium. The factors were essential for the FSH-induced steroidogenesis in serum-free medium. After four days of incubation in 4F medium, the cells showed a transient loss of their ability to produce progestin in response to FSH. In both 4F medium as well as in serum-containing medium, the cells regained their hormonal responsiveness after 35 days in culture. Since the loss of hormonal responsiveness occurred at the same time as growth was initiated in the cultures, it is suggested that the FSH-induced steroidogenesis is negatively controlled by growth-related processes.     

X-chromosome activity in heterokaryons and hybrids between mouse fibroblasts and teratocarcinoma stem cells

To determine whether 2X-active cells contain factors capable of reactivating the inactive mammalian X chromosome, fibroblast lines, having a cytologically or genetically marked inactive X, were fused with 2X-active mouse embryos or ovarian teratocarcinoma stem cells. Fusions with 2–16 cell embryos were uninformative because no mitosis occurred in heterokaryons. Fusions with 2X-active teratocarcinoma cells, and screening for re-expression of alleles on the inactive X showed that reactivation did not occur with detectable frequency in heterokaryon. Hybridization of HPRT^?M. musculus × M. caroli cells with XO HPRT^? teratocarcinoma cells yielded hybrids with a frequency of >10^?6; these hybrids all expressed the Hpt allele on the inactive M. caroli X, but not the M. caroliGpd or Pgk. Late replication-banding studies of hybrids and 6-thioguanine-resistant revertants showed that the reactivated Hp⁺ allele was still located on the late replicating X. Similar results were obtained with hybridization of this line to 1X-active (male-derived) fibroblast lines, indicating that hybridization per se, rather than a specific factor contributed by the teratocarcinoma cell partner, was reponsible for the frequent localized derepression of the Hpt⁺ allele on the inactive X.     

Biosynthesis of transcobalamin II by adult rat liver parenchymal cells in culture.

The biosynthesis of transcobalamin II was investigated in primary cultures of adult rat liver parenchymal cells maintained in serum-free media. The data indicate that these hepatocytes secrete a vitamin B₁₂-binding substance into the culture medium which is identical to rat serum transcobalamin II as judged by the following criteria: (i) gel filtration on columns of Sephadex G-200; (ii) ion-exchange chromatography on columns of diethyl aminoethyl cellulose and carboxymethyl cellulose; (iii) polyacrylamide-gel electrophoresis at pH 9.5; and (iv) the ability to facilitate cellular vitamin B₁₂ uptake by HeLa cells and mouse L-929 fibroblasts in culture. The secretion of transcobalamin II by the liver parenchymal cells was blocked by cycloheximide, puromycin, and p-fluorophenylalanine. The inhibition by cycloheximide, but not that of the other inhibitors, was partially reversed upon removal of the drug. The liver parenchymal cells incorporated radioactive amino acids into transcobalamin II which was absorbed from the growth medium using affinity chromatography on Sepharose containing covalently linked B₁₂. Collectively, these data indicate that rat liver parenchymal cells, in culture, are capable of the biosynthesis de novo of transcobalamin II and the subsequent secretion of this protein into the culture media.     

Proteases are mitogenic to mesenchyme in vivo : A study using the chick embryo chorioallantoic membrane

The chorioallantoic membrane (CAM) of the 9 and 10 day chick embryo has been used as a system to investigate the control of growth of mesenchymal tissue in vivo. The mesenchyme (but not the chorionic epithelium or allantoic epithelium) responded to the mitogenic stimuli of trypsin, activated macrophages and the secreted products of activated macrophages. The response to trypsin mimics the response of chick embryo fibroblasts in vitro. Under the conditions used, the increased labeling index was observed in CAM mesenchyme by 6 h (the shortest time assayed) and remained at this level for at least 24 h. This system could be used to evaluate the mitogenicity in vivo of other substances known to be mitogenic to fibroblasts in vitro.