Study of markers of human erythroid differentiation in hybrid cells

Summary Somatic cell hybrids exhibiting co-expression of the globin genes of two species were generated by fusion of mouse erythroleukemia cells with Chinese hamster or human marrow erythroid cells. In contrast, extinction of the mouse globin genes occurred in hybrids formed between the erythroleukemia cells and human fibroblasts. Direct detection of the human globin genes in human X mouse fibroblast hybrids was achieved by annealing of DNA from these cells to human globin complementary DNA. This method was developed to permit the chromosomal assignment of the human globin genes. Presented in the formal symposium on Somatic Cell Genetics at the 27th Annual Meeting of the Tissue Culture Association, Philadelphia, Pennsylvania, June 7–10, 1976. Some of this work was conducted during the tenure of a National Research Fellowship 1 F32 AM05080-01 held by A.D.     

Extinction of globin gene expression in human fibroblast x mouse erythroleukemia cell hybrids.

We have chosen human fibroblast x mouse erythroleukemia hybrid cells as a model system to examine regulation of unique genes. The globin genes were studied as a marker of erythroid differentiation. Three separate hybrid cell lines were incubated in 2% dimethylsulfoxide, an agent which induces erythroid differentiation of the parental erythroleukemia cells. Neither human nor mouse globin mRNA sequences could be detected by a sensitive molecular hybridization assay which utilized globin complementary D N A. However, td n a from one of the cell lines was shown to contain both the mouse and humand globin genes. Thus, loss of the genes by chromosomal segregation did not account for their failure to be expressed. Cocultivation of the mouse erythroleukemia cells with excess human fibroblasts did not prevent erythroid differentiation of the erythroleukemia cells in the presence of dimethylsulfoxide. Similarly globin gene expression was preserved in tetraploid cells generated by fusion of two erythroleukemia lines. Thus, extinction of globin geneated by fusion of two erythroleukemia lines. Thus, extinction of blobin gene expression in the human fibroblast x erythroleukemia hybrids occurred at the level of mRNA production and appeared to be due to the presence of the fibroblast genome within the hybrial cell.     

Active expression of Gγ globin gene on chromosome 11 with Yunnanese (Ayγδβ)~0-thalasseinia deletion in MEL cells

A permanent lymphocyte cell line of a heterozygote with Yunnanese (Aγδβ)0-thalassemia deletion, associated with an increased production of Cry globin in adult, was founded using Epstein-Barr virus transformation. The hybrids of the lymphocyte cell and mouse erythroleukemia cell (MEL) were achieved and the hybrids containing human chromosome 11 were selected with the monoclonal antibody 53/6. The subclones containing only either the normal or the abnormal human chromosome 11 were separated and the expression of the human globin genes was studied. Expression of the β-globin gene, but not the Cγ and Aγ, was observed in the hybrids containing only the normal human chromosome 11, while active expression of the Cγ globin gene was observed in the hybrids containing only the abnormal human chromosome 11. These results have confirmed that the DNA deletion in the β-globin gene cluster is the cause of persistent active expression of the Cγ globin gene in the Yunnanese mutant.     

Human globin gene expression after gene transfer

Human globin genes can be transferred into mouse and human erythroid cells in culture, and can be appropriately expressed at the mRNA level in these cells. A plasmid containing a human beta globin gene is expressed in mouse erythroleukemia cells (MELC), and another containing a human epsilon or gamma gene is expressed in human erythroleukemia (K562) cells. A neomycin resistance (neoR) gene on the plasmids has been used to select for those cells containing the transferred globin genes; this selection may favor the expression of the globin genes by providing chromosomal positions requiring neoR expression. Analyzing clones resistant to G418, a neomycin analogue, demonstrated globin mRNA expression and induction. Retroviral vectors have also been used to transfer and appropriately express human beta genes in MELC. In addition, a plasmid containing a dihydrofolate reductase (DHFR) gene as well as neoR and beta globin genes has been used to amplify and express beta globin mRNA in MELC. These experiments suggest that high level appropriate expression of human beta globin genes is feasible and provides potentially useful approaches to the long-range goal of gene therapy for sickle cell anemia and beta thalassemia.     

Developmental regulation of fetal to adult globin gene switching in human fetal erythroid x mouse erythroleukemia cell hybrids

Human fetal erythroid x murine erythroleukemia cell hybrids undergo human fetal (gamma) to adult (beta) globin gene switching in vitro under the control of a mechanism located on human chromosome 11. We investigated whether this mechanism acts in cis or in trans by preparing hybrid cells containing marked fragments of the gamma and beta genes known to switch in transgenic mice. In these cells the chromosomally introduced human globin locus undergoes the fetal to adult globin gene switch. In contrast, the marked globin gene fragments were expressed at all stages of hybrid development. These results suggest that either the mechanism of switching acts in cis or that sequences present in the chromosomal globin locus but missing from the transfected globin gene fragments mediate its action.     

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.     

Serum factors can modulate the developmental clock of gamma- to beta-globin gene switching in somatic cell hybrids.

The fusion of human fetal erythroid (HFE) cells with mouse erythroleukemia (MEL) cells produces stable synkaryons (HFE x MEL) which can be monitored for extended periods of time in culture. Initially these hybrids express a human fetal globin program (gamma >> beta), but after weeks or months in culture, they switch to an adult pattern of globin expression (beta >> gamma). The rate at which hybrids switch to the adult phenotype is roughly dependent on the gestational age of the fetal erythroid cells used in the fusion, suggesting that the rate of switching in vitro may be determined by a developmental clock type of mechanism, possibly involving the cumulative number of divisions experienced by the human fetal cells. To investigate whether the number or rate of cell divisions postfusion can influence the rate of switching, we monitored the rate of switching in hybrids from independent fusions under growth-promoting (serum-replete) and growth-suppressing (serum-deprived) conditions. We found that hybrids grown under serum-deprived or serumless conditions switched more rapidly to adult globin expression than did their counterparts in serum-replete conditions. Neither the number of cumulative cell divisions nor time in culture per se predicted the rate of switching in vitro. Our data suggest that factors present in serum either retard switching of hybrids by their presence or promote switching by their absence, indicating that globin switching in vitro can be modulated by the environment; however, once switching in HFE x MEL hybrids is complete, serum factors cannot reverse this process.     

Butyrate induces expression of transfected human fetal and endogenous mouse embryonic globin genes in GM 979 erythroleukemia cells

We have analyzed the expression of endogenous murine genes and of transfected human fetal A gamma globin gene in GM 979, a mouse erythroleukemia line which produces adult as well as embryonic globins. Optimal induction of the endogenous murine adult globin genes was obtained with DMSO or HMBA while the epsilon y and beta h1 embryonic genes were preferentially induced by butyrate. Similarly, the transferred human A gamma-globin gene was preferentially induced by butyrate. These results as well as previous observations in vivo or in erythroid cell cultures suggest that butyrate preferentially induces the expression of fetal globin genes.     

Expression of globin genes in teratocarcinoma-Friend cell hybrids

We have used an isoelectric focusing technique to analyse the hemoglobins synthesized by cell hybrids isolated following the fusion of Friend erythroleukemia to embryonal carcinoma cells. Our results confirm that the embryonal carcinoma-derived alpha globin genes are expressed in cell hybrids. In addition, the extent to which the various alpha chains and beta chains are synthesized in these hybrids depends on both the genetic composition of the cell line and on the chemical nature of the agent used to induce hemoglobin synthesis.     

A negative cis-element regulates the level of enhancement by hypersensitive site 2 of the beta-globin locus control region

The core of DNase hypersensitive site (HS) 2 from the beta-globin locus control region is a potent enhancer of globin gene expression. Although it has been considered to contain only positive cis-regulatory sequences, our study of the enhancement conferred by segments of HS2 in erythroid cells reveals a novel negative element. Individual cis-regulatory elements from HS2 such as E boxes or Maf-response elements produced as great or greater enhancement than the intact core in mouse erythroleukemia (MEL) cells, indicating the presence of negative elements within HS2. A deletion series through HS2 revealed negative elements at the 5' and 3' ends of the core. Analysis of constructs with and without the 5' negative element showed that the effect is exerted on the promoters of globin genes expressed at embryonic, fetal, or adult stages. The negative effect was observed in bipotential human cells (K562 and human erythroleukemia (HEL) cells), proerythroblastic mouse (MEL) cells, and normal adult human erythroid cells. The novel negative element also functions after stable integration into MEL chromosomes. Smaller deletions at the 5' end of the HS2 core map the negative element within a 20-base pair region containing two conserved sequences.