ACQUISITION OF CHICK CYTOSOL THYMIDINE KINASE ACTIVITY BY THYMIDINE KINASE-DEFICIENT MOUSE FIBROBLAST CELLS AFTER FUSION WITH CHICK ERYTHROCYTES

Chick-mouse heterokaryons were obtained by UV-Sendai virus-induced fusion of chick erythrocytes with thymidine (dT) kinase-deficient mouse fibroblast [LM(TK^-)] cells. Autoradiographic studies demonstrated that 1 day after fusion, [³H]dT was incorporated into both red blood cell and LM(TK^-) nuclei of 23% of the heterokaryons. Self-fused LM(TK^-) cells failed to incorporate [³H]dT into nuclear DNA. 15 clonal lines of chick-mouse somatic cell hybrids [LM(TK^-)/CRB] were isolated from the heterokaryons by cultivating them in selective hypoxanthine-aminopterin-thymidine-glycine medium. LM(TK^-) and chick erythrocytes exhibited little, if any, cytosol dT kinase activity. In contrast, all 15 LM(TK^-)/CRB lines contained levels of cytosol dT kinase activity comparable to that found in chick embryo cells. Disk polyacrylamide gel electrophoresis and isoelectric focusing analyses demonstrated that the LM(TK^-)/CRB cells contained chick cytosol, but not mouse cytosol dT kinase. The LM(TK^-)/CRB cells also contained mouse mitochondrial, but not chick mitochondrial dT kinase. Hence, the clonal lines were somatic cell hybrids and not LM(TK^-) cell revertants. The experiments demonstrate that chick erythrocyte cytosol dT kinase can be activated in heterokaryons and in hybrid cells, most likely as a result of functions supplied by mouse fibroblast cells.     

Reconstitution of cells by fusion of cell fragments : I. Myogenic expression after fusion of minicells from rat myoblasts (L6) with mouse fibroblast (A9) cytoplasm

Rat L6 myoblasts and mouse A9 fibroblasts (HGPRT-) were enucleated by centrifugation of monolayers in the presence of cytochalasin B. Intact cells were reconstituted by Sendai virus mediated fusion of nuclei (minicells) from enucleated rat myoblasts and cytoplasms from enucleated mouse fibroblasts. Colonies arising from proliferating reconstituted cells were distinguished from intact parental cell types on the basis of nuclear and cytoplasmic markers. In five replicate experiments, approx. 70% of all colonies found after fusion were derived from reconstituted cells, 30% arose from intact rat myoblasts contaminating the minicell preparations, and two colonies were identified as hybrids between the parental cell types. Clones derived from reconstituted cells formed myotubes which produced myosin and developed the cross-striated pattern typical of skeletal muscle. The myogenic program of the rat myoblast thus can persist through the enucleation and reconstitution procedures, and is not obviously altered by a period of exposure to mouse fibroblast cytoplasm.     

Expression of the neuron-specific protein, 14-3-2, and steroid sulfatase in neuroblastoma cell hybrids

Three series of neuroblastoma X fibroblast hybrid clones were isolated from crosses between mouse or human fibroblasts and mouse or human neuroblastoma cell lines by virus-mediated cell fusion. The expression of 14-3-2 protein (an acidic protein specific to neurons) and steroid sulfatase activity was studied in parental and hybrid cell lines. Steroid sulfatase was extinguished in hybrids when only one parent expressed the enzyme, but was expressed in one hybrid combination in which both parents expressed the enzyme. The neuron-specific 14-3-2 protein, on the other hand, continued to be expressed in all three series of neuroblastoma x fibroblast hybrids. In most cases where these pheno-types were expressed, they also exhibited temporal modulation; that is, specific activity is low during logarithmic growth and increases markedly during stationary phase. The glial-specific protein S-100 is absent from all parents and hybrids. The results are discussed in terms of mechanisms of regulation of differentiated phenotypes in mammalian cells.     

Interaction of vinblastine with the secretagogue action of db-cAMP in the rat exocrine pancreas,.

Developmentally pluripotent embryonal carcinoma cells isolated from mouse teratocarcinomas were fused to whole cells, to cytoplasts, and to karyoplasts of 3T3 fibroblasts. The cybrids (cell X cytoplast fusion product) retained the developmental potency of the embryonal carcinoma cell parent. On the other hand, the karyobrids (cell X karyoplast fusion product) and the hybrids resembled the fibroblast parent cell and were incapable of differentiation. These experiments, therefore, failed to reveal the presence of cytoplasmic regulators of nuclear gene expression.     

Induction of DNA polymerase in mouse L cells

Two molecular species of DNA polymerase are found in mouse L cells. This study is concerned with the variation of these two species of enzyme with the rate of cell growth and DNA synthesis. The 3.4 S DNA polymerase, found in both nuclear and cytoplasmic fractions of mouse L cells, remains relatively constant during different stages of the growth curve. The heterogeneous 6 to 8 S DNA polymerase, found only in the cytoplasmic fractions, varies about 5 to 12-fold in correlation with DNA synthesis, as measured by [³H]thymidine incorporation.     

Mitochondrial genomes in intraspecies mammalian cell hybrids display codominant or dominant/recessive behavior

A unique type of nonstochastic mitochondrial DNA (mtDNA) segregation was found in mammalian cells. In human cell hybrids isolated from the fusion of HeLa cells with 23, GM639, A549, or 293 cells, HeLa mtDNA was always lost from the hybrids, whereas both parental mtDNAs were maintained in hybrids of HeLa X 143BTK-. Similar phenomena were observed in mouse cell hybrids isolated by the fusion of cells with different mtDNA types. Types 1, 2, and 3, can be distinguished from each other by restriction fragment-length polymorphisms. The mouse cell hybrids between cells with type 1 and type 2 mtDNA always lost type 2 mtDNA, whereas the hybrids between cells with type 2 and type 3 mtDNA retained both types stably. These observations suggest that either a codominant or a dominant/recessive relationship may be present in intraspecies mitochondrial genomes of human and mouse cells. When the mitochondrial genomes in cell hybrids are codominant, stochastic segregation occurs while nonstochastic segregation occurs when they are in the dominant/recessive relationship. These concepts may help elucidate organelle heredity in animals.     

Interspecies mitochondrial fusion between mouse and human mitochondria is rapid and efficient

A detailed molecular understanding of mitochondrial fusion and fission in mammalian cells is rapidly emerging. In this report, we demonstrate for the first time cross-species mitochondrial fusion between distantly related species using green and red fluorescent proteins targeted to the mitochondrial matrix. We found that mouse mitochondria were able to efficiently fuse to unmodified mitochondria of human cells and that the contents of the mitochondrial matrix were completely mixed in less than 4h. We also observed that mitochondria from the mtDNA-less (rho(0)) mouse cells can homogeneously fuse to the mitochondria of human cells. We were, however, unable to maintain human mitochondrial DNA in the mouse cells. These results indicate that mitochondrial fusion proteins in mouse and human cells have enough functional homology to mediate efficient cross-species mitochondrial fusion, but mouse nuclear and human mitochondrial genomes have not retained functional compatibility with one another.     

Generation of ρ0 cells utilizing a mitochondrially targeted restriction endonuclease and comparative analyses

Eukaryotic cells devoid of mitochondrial DNA (ρ⁰ cells) were originally generated under artificial growth conditions utilizing ethidium bromide. The chemical is known to intercalate preferentially with the mitochondrial double-stranded DNA thereby interfering with enzymes of the replication machinery. ρ⁰ cell lines are highly valuable tools to study human mitochondrial disorders because they can be utilized in cytoplasmic transfer experiments. However, mutagenic effects of ethidium bromide onto the nuclear DNA cannot be excluded. To foreclose this mutagenic character during the development of ρ⁰ cell lines, we developed an extremely mild, reliable and timesaving method to generate ρ⁰ cell lines within 3–5 days based on an enzymatic approach. Utilizing the genes for the restriction endonuclease EcoRI and the fluorescent protein EGFP that were fused to a mitochondrial targeting sequence, we developed a CMV-driven expression vector that allowed the temporal expression of the resulting fusion enzyme in eukaryotic cells. Applied on the human cell line 143B.TK⁻ the active protein localized to mitochondria and induced the complete destruction of endogenous mtDNA. Mouse and rat ρ⁰ cell lines were also successfully created with this approach. Furthermore, the newly established 143B.TK⁻ ρ⁰ cell line was characterized in great detail thereby releasing interesting insights into the morphology and ultra structure of human ρ⁰ mitochondria.     

Microinjection of arginase into enzyme-deficient cells with the isolated glycoproteins of Sendai virus as fusogen

A method of introducing enzymes into the cytoplasm of fibroblasts in culture is described. Erythrocytes obtained from normal and arginase-deficient individuals were loaded with arginase in vitro and fused to arginase-deficient mouse and human fibroblasts. Erythrocyte ghost-fibroblast fusion was quantified by a 14C-radioactive assay for arginase in solubilized fibroblasts. Fusion was successfully induced by Sendai virus and also by the isolated glycoproteins of Sendai virus. After fusion the arginase activity associated with the Fibroblasts was 700--1500 U of arginase/mg of cell protein; this enzyme activity was 5- to 10-times higher than that normally found in the fibroblasts. The enrichment in arginase activity indicated that between four and ten ghosts had fused per fibroblast. The use of isolated viral proteins to mediate the transfer of enzymes into cells in vivo might alleviate clinical complications inherent in the use of whole virions. The enzyme replacement technique described in this report for a hyperargininemic model cell system should be applicable to the group of inborn errors of metabolism characterized by deficiency of an enzyme normally localized in the cytoplasmic compartment of cells.     

Inherent resistance of HeLa cell derivatives to paromomycin

Summary The human tumor-derived cell line HeLa S3 and nuclear and mitochondrial gene mutants derived from it are resistant to the aminoglycoside antibiotic, paromomycin (PAR). Other carcinoma-derived cells, SV40-transformed cells, and four human diploid fibroblast cell lines are all sensitive to PAR. Sensitivity is dependent on cell density, and at cell numbers greater than 400/cm² sensitive cells will proliferate in PAR. The resistance to PAR is inherited in a dominant manner in cell-to-cell fusion hybrids, but is not transferred in cytoplast-to-cell fusions. PAR resistance is therefore encoded by a nuclear gene(s). Resistance to PAR is not caused by changes in the response to mitochondrial or cytoplasmic protein synthesis to PAR in vitro. The uptake of PAR is similar in resistant and sensitive cells, and dimethyl sulfoxide does not render resistant cells more sensitive. Thus, HeLa cell PAR resistance is unlike previously reported ribosomal mutations and may derive from differences in the intracellular metabolism of PAR. This work was supported by National Institutes of Health grant number AG 02664, University of South Carolina Biomedical Research Support grant number S07 RR7160, and by a grant from the Elsa U. Pardee Foundation, all to C. L. B.     

Growth Dynamics of Mitochondria in Synchronized Chinese Hamster Cells

The increase in cell volume (from electronic cell sizing) and the apportionment of this volume amongst the nuclear, cytoplasmic, and mitochondrial subcellular compartments (from electron microscopy) were studied throughout the cell division cycle in partially synchronized cultures of Chinese hamster V79-S171 cells. Average whole cell volume was found to increase smoothly, consistent with the doubling in one generation of individual cell volume. Nuclear size increased in like fashion. Mean total mitochondrial volume and number of mitochondria per cell both showed a different kind of variation, most notably a significant decrease in G₁ and G₂ as compared with mid S. These results are therefore counter to a model of simple doubling of mitochondria either synchronously with the cell division cycle or asynchronously. Absolute mean values per cell for log phase Chinese hamster cells were also determined, as follows: whole cell volume, 710 μ³; nuclear volume, 190 μ³; total mitochondrial volume, 37.5 μ³; number of mitochondria per cell, 90.     

Phosphorylated BRCA1 is predominantly located in the nucleus and mitochondria

Multiple copies of the mitochondrial genome in eukaryotic cells are organized into protein-DNA complexes called nucleoids. Mitochondrial genome repair mechanisms have been reported, but they are less well characterized than their nuclear counterparts. To expand our knowledge of mitochondrial genome maintenance, we have studied the localization of the BRCA1 protein, known to be involved in nuclear repair pathways. Our confocal and immunoelectron microscopy results show that BRCA1 is present in mitochondria of several human cancer cell lines and in primary breast and nasal epithelial cells. BRCA1 localization in mitochondria frequently overlapped that of nucleoids. Small interfering RNA-mediated knockdown of BRCA1 in human cancer cells (confirmed by Western blot) results in decreased nuclear, cytoplasmic, and mitochondrial staining after immunofluorescence microscopy, establishing the specificity of the BRCA1 immunolabeling. Furthermore, using cell fractionation, dephosphorylation, and enzyme protection experiments, we show that a 220-kDa phosphorylated isoform of BRCA1 is enriched in mitochondrial and nuclear fractions but reduced in cytoplasmic subcellular fractions. Submitochondrial fractionation confirmed the presence of BRCA1 protein in isolated mitoplasts. Because phosphorylation of BRCA1 and subsequent changes in subcellular localization are known to follow DNA damage, our data support a universal role for BRCA1 in the maintenance of genome integrity in both mitochondria and nucleus.     

DNA polymerases in midgestation mouse embryo, trophoblast, and decidua

The DNA polymerases of midgestation mouse embryo, trophoblast, and decidua have been examined. A low molecular weight, nuclear. DNA-dependent polymerase (D-DNA polymerase) and a higher molecular weight cytoplasmic enzyme were found in all three cell types. A DNA polymerase which utilized the poly(A) strand of oligo(dT) · poly(A) as template (R-DNA polymerase) was also found in the three cell types. This enzyme was present both in the nucleus and the cytoplasm. All enzyme levels were highest in the rapidly dividing embryonic cells, substantially lower in the DNA replicating but nondividing trophoblast cells, and lowest in the nonreplicating, nondividing decidual cells. Our observations are consistent with the idea that the nuclear and cytoplasmic D-DNA polymerases are under coordinate control. The relationship of these enzymes to DNA synthesis in vivo is discussed.     

Cytoduction as a new tool in studying the cytoplasmic heredity in yeast

Summary When crossing the haploid cells of genetically marked yeast strains we observed the appearance of both normal diploid zygotes and haploid nuclear cytoplasmic hybrids. The latter had the nuclear markers of one and the cytoplasmic marker (rho⁺) of the other parent. The autonomous cytoplasmic factor transfer was termed as cytoduction. Cytoduction is supposed to be the abortive form of yeast cell mating. Only about 1% of cytoductants is usually observed.Cytoduction can be used as a simple test on cytoplasmic determination of some characters. We observed the transfer into cytoductant cells of not only rho⁺ marker but of resistance factors to antibiotics (erythromycin, neomycin) and killer factor as well. Cytoduction can be applied towards constructing strains having the identical nucleus genotype with mitochondria and other cytoplasmic factors of different origin.In crossing strains with doubly marked mitochondria recombination of mitochondrial markers in cytoductant haploid cells was observed, the pattern of which was similar to that of mitochondrial recombination in normal zygotes.     

Physical properties of cytoplasmic membrane-associated DNA

Some of the physical properties of a cytoplasmic membrane-associated DNA isolated from a diploid human lymphocyte cell line have been examined. Cytoplasmic membrane-associated DNA extracted from lymphocytes labeled with either [³H]or [¹⁴C]thymidine had a specific activity lower than nuclear DNA extracted from the same cells. Analysis of cytoplasmic membrane-associated DNA in the electron microscope shows that the molecules are linear and have a mean length of 1·75 μm; the average sedimentation coefficient of this DNA is 16·6 S, which corresponds to a molecular weight of 4·2×10⁶. Cytoplasmic membrane-associated and nuclear DNA band at identical positions in both neutral and alkaline CsCl gradients with buoyant densities of 1·699 g/ml and 1·752 g/ml, respectively. Native cytoplasmic membrane-associated DNA is double-stranded and has a mole fraction of guanine plus cytosine of 40± l %. Sheared, denatured cytoplasmic membrane-associated DNA reassociates as two distinct fractions whose rates of reassociation differ by about four decades: the complexity of the reassociation of this DNA tends to rule out the possibility that it arises from either mycoplasmal or viral contamination of our cell cultures. The slowly reassociating fraction of cytoplasmic membrane-associated DNA reassociates about ten times faster than the unique sequences of nuclear DNA. This could represent potential genetic information for about 100,000 diverse genes of 1000 nucleotide pairs each. At present the function of cytoplasmic membrane-associated DNA in these cells is unknown.     

Stability of parental mitochondrial DNA species and expression of nuclear ribosomal RNA genes in mouse-rat hybrid cells

Mouse-rat hybrid somatic cells were isolated by fusion of chloramphenicol-sensitive (CAP^s) mouse fibroblast cells with hypoxanthine-guanine-phosphoribosyltransferase-deficient (HGPRT⁻) and CAP-resistant (CAP^r) rat myoblast cells and selected with hypoxanthine-aminopterin-thymidine (HAT) and CAP. Restriction endonuclease cleavage patterns showed that both mouse and rat mitochondrial DNAs (mtDNAs) were present in the hybrid cells and that the amount of rat mtDNA was one-quarter that of mouse mtDNA, even after cultivation for 3 months in the presence of CAP. Nuclear ribosomal RNA (rRNA) genes of mouse and rat were shown to be expressed stably in the hybrid cells by homochromatography fingerprinting of RNase T1 digests. The genetic compatibility between mouse and rat chromosomes in the mouse-rat hybrid cells assures retention of both parental chromosomes, and this may be responsible for the expression of both parental rRNA genes, and for the retention of both parental mtDNAs in the hybrid cells.     

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.     

Identification and expression of a cDNA clone encoding aspartate aminotransferase in carrot

A full-length cDNA clone encoding aspartate aminotransferase (AAT) has been identified from a carrot root cDNA library. Degenerate oligo primers were synthesized from the known amino acid sequence of AAT form I from carrot (Daucus carota L. cv Danvers). These primers were utilized in a polymerase chain reaction to amplify a portion of a carrot AAT gene from first strand cDNA synthesized from poly(A)⁺ RNA isolated from 5-d-old cell suspension cultures. The resulting 750-bp fragment was cloned, mapped, and sequenced. The cloned fragment, mpAAT1, was used as a probe to identify a full-length cDNA clone in a library constructed from poly(A)⁺ RNA isolated from carrot roots. A 1.52-kb full-length clone, AAT7, was isolated and sequenced. AAT7 has 54% nucleotide identity with both the mouse cytoplasmic and mitochondrial AAT genes. The deduced amino acid sequence has 52 and 53% identity with the deduced amino acid sequences of mouse cytoplasmic and mitochondrial AAT genes, respectively. Further analysis of the sequence data suggests that AAT7 encodes a cytoplasmic form of carrot AAT; the evidence includes the (a) absence of a transit or signal sequence, (b) lack of “m-residues,” or invariant mitochondrial residues, in the carrot AAT sequence, and (c) high degree of sequence similarity with the amino acid sequence previously obtained for form I of carrot, a cytoplasmic isoenzyme. High- and low-stringency hybridizations to Southern blots of carrot nuclear DNA with AAT7 show that AAT is part of a small multigene family. Northern blot analysis of AAT7 suggests that AAT is expressed throughout cell culture up to 7 d and is highly expressed in roots but not in leaves.     

Nuclear location of mammalian DNA polymerase activities.

Nuclei were isolated from monolayer cultures of mouse and human cells using a nonaqueous procedure of cell fractionation in which lyophilized cells were homogenized and centrifuged in 100% glycerol. In previous work we have shown that the nuclear pellet and cytoplasmic supernatant fraction contained 10% or less of the nucleic acids characteristic of the other cell fraction. Aqueous extracts made from fresh cultures and from nonaqueous material at each step of the fractionation procedure were assayed fro DNA polymerase activity. Activities were normalized to DNA contents of extracted material. Specific activity was preserved quantitatively through freezing and drying the cells, but was found to be unstable in glycerol suspensions with approximate half-lives and 1 h at 23 degrees and 4 h at 0-4 degrees. Activities were relatively stable at -25 degrees, however, so that by homogenizing only 15 min at 4 degrees and centrifuging at -25 degrees we preserved approximately 85% of the specific activity of fresh cultures in the nonaqueous nuclear fraction. Sedimentation analyses showed that the nuclear fraction contained both DNA polymerase-alpha and-beta in approximately the proportions expected if all polymerase activities were confined to the nucleus in living cells. DNA polymerase-alpha was found to be more unstable in glycerol suspensions than DNA polymerase-beta. Nuclear location of both activities was found in exponential cultures and in 3T3 mouse cultures synchronized in the G1 and S phases of the cell division cycle. We found no evidence for cytoplasmic factors affecting nuclear polymerase activities. We have concluded that the two major DNA polymerases are nuclear although one, DNA polymerase-alpha, frequently is present as a weakly bound nuclear protein.