Expression of human alpha-globin genes in hybrid mouse erythroleukaemia cells depends on differentiated state of human donor cell

A method improving the efficiency of the positive-negative selection used to isolate homologous recombinants

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Major chromatin changes accompany extinction of alpha-fetoprotein gene in hepatoma x fibroblast hybrids

The sensitivity of the alpha-fetoprotein (AFP) gene to digestion by the enzyme DNaseI, and the presence of hypersensitive sites in the 5' region of this gene, were examined in hepatoma x fibroblast hybrid cells that exhibit extinction of AFP gene expression. Major changes occur in the extinguished gene, i.e., loss of long-range sensitivity to DNase digestion and of the hypersensitive sites. In this respect, the extinguished gene resembles the corresponding silent gene present in fibroblasts, but differs from the silent gene present in normal adult hepatocytes. These observations suggest that extinguisher factors acting on the AFP gene alter its conformation.

Activation and repression of a beta-globin gene in cell hybrids is accompanied by a shift in its temporal replication

To investigate whether a switch in the transcriptional activity of a gene is associated with a change in the timing of replication during the S phase, we examined the replication timing of the beta-globin genes in two different types of somatic cell hybrids. In mouse hepatoma (Hepa 1a) x mouse erythroleukemia (MEL) hybrid cells, the beta-globin gene from the MEL parent is transcriptionally inactivated and is later replicating than in the parental MEL cell line. In human fibroblast (GM3552) x MEL hybrid cells, the human beta-globin gene is transcriptionally activated, and all of the sequences within the human beta-globin domain (200 kilobases) we have examined appear to be earlier replicating than those in the parental fibroblast cell line. The chromatin configuration of the activated human beta-globin domain in the hybrids is relatively more sensitive to nucleases than that in the fibroblasts. Furthermore, major nuclease-hypersensitive sites that were absent in the chromatin flanking the distal 5' region of the human beta-globin gene cluster in the parental fibroblast cell line are present in the transcriptionally activated domain in the hybrid cell line. These results suggest that timing of replication of globin genes has been altered in these hybrid cells and thus is not fixed during the process of differentiation.

Activation and repression of a beta-globin gene in cell hybrids is accompanied by a shift in its temporal replication

To investigate whether a switch in the transcriptional activity of a gene is associated with a change in the timing of replication during the S phase, we examined the replication timing of the beta-globin genes in two different types of somatic cell hybrids. In mouse hepatoma (Hepa 1a) x mouse erythroleukemia (MEL) hybrid cells, the beta-globin gene from the MEL parent is transcriptionally inactivated and is later replicating than in the parental MEL cell line. In human fibroblast (GM3552) x MEL hybrid cells, the human beta-globin gene is transcriptionally activated, and all of the sequences within the human beta-globin domain (200 kilobases) we have examined appear to be earlier replicating than those in the parental fibroblast cell line. The chromatin configuration of the activated human beta-globin domain in the hybrids is relatively more sensitive to nucleases than that in the fibroblasts. Furthermore, major nuclease-hypersensitive sites that were absent in the chromatin flanking the distal 5' region of the human beta-globin gene cluster in the parental fibroblast cell line are present in the transcriptionally activated domain in the hybrid cell line. These results suggest that timing of replication of globin genes has been altered in these hybrid cells and thus is not fixed during the process of differentiation.

Expression of transfected vimentin genes in differentiating murine erythroleukemia cells reveals divergent cis-acting regulation of avian and mammalian vimentin sequences

We studied the expression of transfected chicken and hamster vimentin genes in murine erythroleukemia (MEL) cells. MEL cells normally repress the levels of endogenous mouse vimentin mRNA during inducermediated differentiation, resulting in a subsequent loss of vimentin filaments. Expression of vimentin in differentiating MEL cells reflects the disappearance of vimentin filaments during mammalian erythropoiesis in vivo. In contrast, chicken erythroid cells express high levels of vimentin mRNA and vimentin filaments during terminal differentiation. We demonstrate here that chicken vimentin mRNA levels increase significantly in differentiating transfected MEL cells, whereas similarly transfected hamster vimentin genes are negatively regulated. In conjunction with in vitro nuclear run-on transcription experiments, these results suggest that the difference in vimentin expression in avian and mammalian erythropoiesis is due to a divergence of cis-linked vimentin sequences that are responsible for transcriptional and posttranscriptional regulation of vimentin gene expression. Transfected chicken vimentin genes produce functional vimentin protein and stable vimentin filaments during MEL cell differentiation, further demonstrating that the accumulation of vimentin filaments is determined by the abundance of newly synthesized vimentin.

Expression of transfected vimentin genes in differentiating murine erythroleukemia cells reveals divergent cis-acting regulation of avian and mammalian vimentin sequences

We studied the expression of transfected chicken and hamster vimentin genes in murine erythroleukemia (MEL) cells. MEL cells normally repress the levels of endogenous mouse vimentin mRNA during inducermediated differentiation, resulting in a subsequent loss of vimentin filaments. Expression of vimentin in differentiating MEL cells reflects the disappearance of vimentin filaments during mammalian erythropoiesis in vivo. In contrast, chicken erythroid cells express high levels of vimentin mRNA and vimentin filaments during terminal differentiation. We demonstrate here that chicken vimentin mRNA levels increase significantly in differentiating transfected MEL cells, whereas similarly transfected hamster vimentin genes are negatively regulated. In conjunction with in vitro nuclear run-on transcription experiments, these results suggest that the difference in vimentin expression in avian and mammalian erythropoiesis is due to a divergence of cis-linked vimentin sequences that are responsible for transcriptional and posttranscriptional regulation of vimentin gene expression. Transfected chicken vimentin genes produce functional vimentin protein and stable vimentin filaments during MEL cell differentiation, further demonstrating that the accumulation of vimentin filaments is determined by the abundance of newly synthesized vimentin.

Rapid reprogramming of globin gene expression in transient heterokaryons

Interspecific heterokaryons were formed by fusing adult mouse erythroleukemia (MEL) cells and human embryonic/fetal erythroid (K562) cells with each other, or with a variety of mouse and human nonerythroid cell types. Analysis of total cellular RNA isolated 24 hr after fusion revealed that normally inactive globin genes can be activated in these "transient" heterokaryons, in which the nuclei do not fuse. In general, the types of globin genes expressed in the donor erythroid cell are activated in the nucleus of the recipient cell. Therefore, erythroid cells contain transacting regulatory factors that are capable of activating the expression of globin genes in a stage- and tissue-specific manner. These observations also indicate that globin genes are not irreversibly repressed in differentiated cells and that their expression can be rapidly reprogrammed in the presence of the appropriate regulatory factors.

Analysis of human hemoglobin switching in MEL x human fetal erythroid cell hybrids

The switch from fetal to adult globin synthesis in man was studied using heterospecific cell hybrids between human fetal erythroblasts and mouse erythroleukemia cells. When erythroblasts from first trimester fetuses were used the hybrids expressed a fetal program of human globin expression. While in continuous culture, these hybrids switched from predominantly fetal to almost exclusively adult globin expression, providing direct evidence that switching can occur within a single cell lineage. Sequential studies of globin expression at a single cell level and subcloning experiments suggested that the switch reflects a progressive increase in the generation of beta + cells from gamma + cells. Hybrids formed with erythroblasts of second trimester fetuses switched faster than those produced with cells of first trimester fetuses. The findings suggest that the human gamma to beta switch is controlled by a developmental clock-like mechanism, which appears to be associated with chromosome 11.

Human alpha- and beta-globin gene transcription in mouse erythroleukaemia cells

Human beta-globin genes introduced into mouse erythroleukaemia (MEL) cells by DNA co-transformation are correctly regulated when erythroid cell differentiation is induced by dimethylsulphoxide (DMSO). In contrast, cloned human alpha-globin genes are efficiently transcribed in MEL cells before induction, and no increase in the level alpha-globin mRNA is observed when the cells differentiate. These observations suggest that the mechanisms by which alpha- and beta-globin genes are activated during erythroid cell differentiation are fundamentally different. Analysis of the transcription of hybrid human alpha-beta-globin genes in MEL cells revealed that the sequences responsible for differences in transcription of the intact alpha- and beta-globin genes are located on the 3' side of the mRNA capping site of the two genes, suggesting that cis-acting regulatory sequences are located within the structural genes.

Molecular analysis of erythropoiesis. A current appraisal

This article considers recent evidence concerning the molecular mechanisms involved in the coordinate regulation of gene expression during red blood cell (RBC) differentiation. Contrary to popular belief, recent evidence shows that only a few of the characteristic RBC proteins are restricted to the erythroid lineage: apart from the globins, an RBC lipoxygenase and (possibly) glycophorin are the only examples for which there is reasonably good evidence. In contrast, the proteins forming the RBC cytoskeleton (spectrin, ankyrin, band 4.1, actin and possibly the major anion exchange transmembrane protein by which the cytoskeleton is attached to the plasma membrane) have closely-related variants in other cell types. Yet two beta-spectrin variants are found exclusively in certain terminally differentiated cells, often only in certain specific regions of the cell membrane. Certain RBC isozymes (e.g. for pyruvate kinase and carbonic anhydrase) and an RBC 19 kD protein (ep19) are also expressed only in a subset of other cell types. This illustrates the importance of gene families which are differentially regulated in certain subsets of cell types during differentiation and development. The expression of the globin genes seems to be regulated mainly at the transcriptional level, although transport of these transcripts to the cytoplasm may be controlled by interactions with other RNAs: stabilisation of globin mRNAs by ribonucleoprotein complexes in the cytoplasm may also be important. In fact, the expression of the globin genes involves two distinct phases: first, structural changes occur in the chromatin surrounding the genes (as determined by sensitivity to digestion by nucleases) and these can be maintained independently of any subsequent transcription. In many cases, these nuclease-sensitive sites in the chromatin correspond to low-level transcription initiation sites and to DNA sequences with regulatory functions when the isolated genes are assayed for transcription in vivo after transfection into cells. How the unlinked alpha- and beta-globin genes are coordinately regulated is not yet understood. Indeed, the alpha- and beta-gene promoters have quite different properties as judged by their responses to DNA replication and to factors known to affect viral gene function (e.g. the cis-acting SV40 enhancer elements and the trans-acting adenovirus regulatory protein, Ela). Other evidence shows that a nuclear protein present only in erythroid cells is able to bind to the beta-globin gene precisely in the region that is hypersensitive to nuclease digestion in chromatin from erythroid cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Differences in human alpha- and beta-globin gene expression in mouse erythroleukemia cells: the role of intragenic sequences

Human beta-globin genes introduced into mouse erythroleukemia (MEL) cells by DNA cotransformation are correctly regulated when erythroid cell differentiation is induced by dimethylsulfoxide (DMSO). In contrast, cloned human alpha-globin genes are efficiently transcribed in MEL cells prior to induction, and no increase in the level of alpha-globin mRNA is observed when the cells differentiate. These observations suggest that the mechanisms by which alpha- and beta-globin genes are activated during erythroid cell differentiation are fundamentally different. Analysis of the transcription of hybrid human alpha/beta-globin genes in MEL cells revealed that the sequences responsible for differences in transcription of the intact alpha- and beta-globin genes are located on the 3' side of the mRNA capping site of the two genes, suggesting that cis-acting regulatory sequences are located within the structural genes.

Histone-H1-dependent chromatin superstructures and the suppression of gene activity

I have identified a chromatin particle containing DNA as large as 20-40 kb that migrates as a discrete entity on agarose gels. With increasing nuclease digestion, the particle becomes cleaved in the linker regions between nucleosomes, but remains intact, probably held together by the outer histones, H1 and H5. By hybridization analysis, inactive genes are found in these particles. Active genes (and their flanking sequences) are also found in particles containing H1 and H5, but in contrast to inactive supranucleosome particles, active polynucleosome particles are not held together after cleavage of linker DNA. This suggests that H1 cross-links adjacent nucleosomes in inactive regions and that H1 is bound differently in expressed regions. The results raise the possibility that the marked degree of suppression of repressed, tissue-specific genes may be determined, in part, by their assembly into these inactive supranucleosome structures.

Lack of retrovirus gene expression in somatic cell hybrids of friend cells and teratocarcinoma cells with a teratocarcinoma phenotype

Two types of hybrids between cells with erythroid phenotype (Friend cells) and teratocarcinoma cells can be distinguished: cell hybrids with an erythroid phenotype, which release or can be induced to release large amounts of Friend spleen focus-forming virus (F-SFFV) on exposure to bromodeoxyuridine and cell hybrids with a teratocarcinoma phenotype, which do not release Friend virus and are not inducible for F-SFFV release. In this paper, we attempted to relate these differences to the expression of F-SFFV and Friend murine leukemia virus (F-MuLV) functions. Teratocarcinoma phenotype hybrids retained F-SFFV-and F-MuLV-related provirus sequences. They did not express F-SFFV- or F-MuLV-related RNA or proteins. The hybrids differentiated to endoderm-like cells on exposure to retinoic acid or hexamethylene-bis -acetamide. These cells, in contrast to the teratocarcinoma phenotype (uninduced) cells expressing SSEA-1-like antigens, did not express SSEA-1-like antigens; they formed typical, prekeratin-staining cytoskeletal structures and could be induced to release mouse interferon. The differentiating cells, but not the uninduced teratocarcinoma hybrids, were infected productively with F-MuLV or the F-MuLV--F-SFFV complex. They, however, did not express endogenous F-SFFV. Endogenous F-SFFV functions could not be rescued by infection with F-MuLV. Induction of teratocarcinoma hybrids with retinoic acid did not activate endogenous F-MuLV or F-SFFV transcription or protein synthesis. These data demonstrated two control mechanisms of Friend virus repression: one which acted trans during formation of the cell hybrids and was maintained only in teratocarcinoma phenotype cells and the other which acted cis and was still operative during induction of endodermal differentiation.

Human globin gene expression in hybrid 2S MEL X human fibroblast cells

A somatic cell hybrid line, called M11-X, was developed in order to study the expression and regulation of the human beta-like globin genes in a mouse erythroid environment. M11-X cells were obtained by fusing the human fibroblast cell line GM3552 (which contains the translocation chromosome t(11;X) that carries the human beta-like globin genes) with hypoxanthine phosphoribosyltransferase (HPRT) -negative tetraploid (2S) mouse erythroleukemia (MEL) cells. After induction with 5 mM hexamethylene bisacetamide (HMBA), these cells contain approximately 300-600 copies per cell of correctly initiated, processed, and terminated human beta-globin mRNA; however, neither human epsilon- nor gamma-globin mRNAs were detected. Carboxymethylcellulose chromatography followed by SDS-polyacrylamide gel electrophoresis and Western blotting revealed that normal human beta-globin protein was also present. These results suggest that the human beta-globin gene, when present in mouse erythroid cells, can be transcribed and its mRNA translated into normal products, but at a much lower level than the mouse beta-globin genes. Analysis of the frequency of cytosine methylation near the human gamma-globin genes indicated that these genes are heavily methylated in M11-X cells. The inability to express the human gamma-globin genes of these cells might be accounted for, at least in part, by DNA methylation.

Lack of retrovirus gene expression in somatic cell hybrids of friend cells and teratocarcinoma cells with a teratocarcinoma phenotype

Two types of hybrids between cells with erythroid phenotype (Friend cells) and teratocarcinoma cells can be distinguished: cell hybrids with an erythroid phenotype, which release or can be induced to release large amounts of Friend spleen focus-forming virus (F-SFFV) on exposure to bromodeoxyuridine and cell hybrids with a teratocarcinoma phenotype, which do not release Friend virus and are not inducible for F-SFFV release. In this paper, we attempted to relate these differences to the expression of F-SFFV and Friend murine leukemia virus (F-MuLV) functions. Teratocarcinoma phenotype hybrids retained F-SFFV-and F-MuLV-related provirus sequences. They did not express F-SFFV- or F-MuLV-related RNA or proteins. The hybrids differentiated to endoderm-like cells on exposure to retinoic acid or hexamethylene-bis -acetamide. These cells, in contrast to the teratocarcinoma phenotype (uninduced) cells expressing SSEA-1-like antigens, did not express SSEA-1-like antigens; they formed typical, prekeratin-staining cytoskeletal structures and could be induced to release mouse interferon. The differentiating cells, but not the uninduced teratocarcinoma hybrids, were infected productively with F-MuLV or the F-MuLV--F-SFFV complex. They, however, did not express endogenous F-SFFV. Endogenous F-SFFV functions could not be rescued by infection with F-MuLV. Induction of teratocarcinoma hybrids with retinoic acid did not activate endogenous F-MuLV or F-SFFV transcription or protein synthesis. These data demonstrated two control mechanisms of Friend virus repression: one which acted trans during formation of the cell hybrids and was maintained only in teratocarcinoma phenotype cells and the other which acted cis and was still operative during induction of endodermal differentiation.

Regulation of Thy-1 and Pgp-1 glycoproteins in hybrids between T-cell lymphomas and Abelson-leukemia-virus-induced lymphomas

Most cells in the normal adult mouse thymus express Thy-1 glycoprotein but do not express Pgp-1 glycoprotein. In contrast, cells of the mouse B-cell lineage are Thy-1 negative and Pgp-1 positive. Somatic cell hybrids between pseudodiploid Thy-1+, Pgp-1- T-cell lymphomas and pseudotetraploid Thy-1-, Pgp-1+ Abelson-leukemia-virus-induced cell lines do not express detectable cell-surface Thy-1 but show activation of the T-cell Pgp-1 glycoprotein. Hybrids between pseudodiploid lines, in contrast, show extinction of Pgp-1. Thy-1+ or Pgp-1+ revertants were isolated by cell sorting from hybrids in which extinction occurred, demonstrating that all genes required for expression of these cell-surface antigens were present in antigen-negative hybrids. Thy-1- hybrids did not contain detectable cytoplasmic Thy-1 messenger RNA, while Thy-1 message could be detected in parental lines and Thy-1+ revertants. No obvious rearrangements of the Thy-1 structural genes could be demonstrated in Thy-1- hybrids and their Thy-1+ revertants, nor could rearrangements be demonstrated when parental cells and Thy-1- hybrids were compared. These results are consistent with the idea that diffusible gene products regulate both Thy-1 and Pgp-1 expression in these hybrids. These products act in a gene dosage-dependent manner in somatic cell hybrids. Regulation of Thy-1 is at the level of either messenger RNA transcription or processing.

Coexistence of expressed and non-expressed alpha-fetoprotein genes in somatic cell hybrids

Hybrids have been generated between mouse hepatoma cells, which actively synthesize alpha-fetoprotein (AFP), and adult hepatocytes, where AFP production is shut off. These hybrids maintain an active synthesis of mouse AFP. Using a specific radioimmunoassay, we found that rat AFP production is not activated. Southern blot analysis showed that mouse and rat AFP DNA sequences can be distinguished and that hybrid clones possessing something close to the complete chromosome sets of both parents have retained both parental AFP DNA sequences. Thus expressed and non-expressed AFP genes coexist in these hybrid cells as if their expression were dependent on a cis-acting event.

The regulated expression of beta-globin genes introduced into mouse erythroleukemia cells

We have introduced a hybrid mouse-human beta-globin gene as well as the intact human beta-globin gene into murine erythroleukemia (MEL) cells and have demonstrated that these genes are appropriately regulated during differentiation of the MEL cell in culture. The addition of chemical inducers to cotransformed cells results in a 5 to 50 fold increase in the level of mRNA transcribed from the exogenous globin gene. S1 nuclease and primer extension analyses demonstrate that these mRNAs initiate and terminate correctly. Nuclear transcription experiments indicate that induction of hybrid mRNA results at least in part from the increase in the rate of globin gene transcription. Furthermore, the induction appears to be specific for globin genes within an erythroid cell. These results permit the study of expression of the globin gene during erythroid differentiation and suggest that the specific induction of the globin gene is an inherent property of DNA sequences within or flanking the beta-globin genes. Moreover, the fact that the human and hybrid globin genes are both inducible in MEL cells suggests that these regulatory sequences are conserved between mouse and human cells.

Regulation of human globin gene expression in mouse erythroleukemia x human fibroblast hybrid cells

A somatic cell hybrid, XX-8, was obtained from a fusion of tetraploid mouse erythroleukemia cells with human Lesch-Nyhan skin fibroblasts. This hybrid cell was previously shown (1) to produce human beta- but no human gamma-globin mRNA sequences after induction with dimethylsulfoxide. In this study we show that: (a) human beta- and gamma-globin genes are present in XX-8 cells in approximately equal numbers; (b) no human gamma-globin mRNA sequences can be detected in either the cytoplasmic or nuclear RNA fractions even with several different inducers; (c) after induction the human beta-globin gene is converted from a DNase I insensitive or closed structure to a DNase I open configuration, while the human gamma-globin gene remains closed; and (d) no human beta-globin polypeptide can be detected in the intact induced cells, indicating that fibroblast globin genes, even when induced to make mRNA in an erythroid environment, do not synthesize an RNA that is translated efficiently.