Tissue selectivity of murine leukemia virus infection is determined by long terminal repeat sequences.

Polyomavirus mutants were isolated from PCC4 embryonal carcinoma cells infected with a variant strain of polyomavirus (ev 1001h) and were found to contain a tandem duplication overlapping the enhancers and the origin of replication. These mutants were able to infect several lines of embryonal carcinoma cells, including PCC4, F9, and LT1. The sequence and structure of one of these mutants are presented and compared with those of other PyEC PCC4 mutants previously described.     

Sodium butyrate induces histone hyperacetylation and differentiation of murine embryonal carcinoma cells

Cells from embryonal carcinoma (EC) lines 6050AJ and PCC4.aza 1R differentiate in response to treatment with sodium butyrate as well as retinoic acid (RA) or hexamethylenebisacetamide (HMBA). Murine 6050AJ EC cells exposed to sodium butyrate possess hyperacetylated forms of histones H4 and altered forms of histones H2a and H2b, whereas histones from cells treated with other inducers appear to be unaffected. These results might indicate that the mechanism by which sodium butyrate promotes differentiation of EC cells is different from the ways in which RA and HMBA act. Differentiation-defective PCC4(RA)-1 EC cells fail to respond to RA, presumably because they possess minimal amounts of active binding protein for RA (cRABP). Sodium butyrate treatment of these cells results in only a modest level of differentiation. On the other hand, exposure to sodium butyrate plus RA leads to extensive differentiation. As is the case with 6050AJ cells, PCC4(RA)-1 cells treated with sodium butyrate also contain hyperacetylated histones. Furthermore, these cells now possess high levels of cRABP. The latter observations suggest that sodium butyrate has the ability to reactivate a silent cRABP gene in PCC4(RA)-1 cells and thereby lead to extensive differentiation via the retinoid pathway when RA is added.     

Genetic complementation of propionyl-CoA carboxylase deficiency in cultured human fibroblasts.

Propionyl-CoA carboxylase (PCC) deficiency is an inherited metabolic disorder showing considerable variability of expression. We have investigated the possibility that there is a genetic basis for the clinical heterogeneity in this disorder by examining complementation in Sendai virus mediated heterokaryons of mutant fibroblast strains. Restoration of PCC activity was monitored in individual multinucleate cells in situ using a radioautographic procedure which detects the incorporation of 14C-propionate into trichloracetic acid precipitable material. Each mutant strain incorporated negligible amounts of radioactivity compared to control strains. Activity was not restored when different mutants were mixed without virus or when homokaryons were produced by self-fusion. Seven mutant strains were fused in all pairwise combinations and examined for increased 14C-propionate incorporation in heterokaryons. Two main complementation groups were revealed. One group was composed of three mutants. The other was a complex group composed of four mutants in which intragroup complementation was demonstrated. Two mutants showing excellent complementation by radioautography were examined for complementation by the direct assay of PCC ACTIVITY. The enzyme activity of virus-treated preparations with 23% multinucleate cells was 183 U (pmol/min/mg protein) compared to 16 U for the untreated mixture (normal range 450-850 u). We conclude that PCC deficiency resulted from mutations of heterogeneous origin, although the classification of mutants into complementation groups did not correlate with patterns of clinical heterogeneity.     

Two distinct sequence elements mediate retroviral gene expression in embryonal carcinoma cells.

Moloney murine leukemia virus (M-MuLV) and M-MuLV-derived retroviral vectors are not expressed in early mouse embryos or in embryonal carcinoma cells. M-MuLV-derived mutants or M-MuLV-related variants which transduce the neomycin phosphotransferase gene can, however, induce drug resistance in embryonal carcinoma cells with high efficiency. In this study we investigated the sequences critical for retroviral gene expression in two different embryonal carcinoma cell lines, F9 and PCC4. We show that two synergistically acting sequence elements mediate expression in embryonal carcinoma cells. One of these is located within the U3 region of the viral long terminal repeat, and the second one is in the 5' untranslated region of the retrovirus. The latter element, characterized by a single point mutation, affects the level of stable RNA in infected cells, suggesting a regulatory mechanism similar to that of human immunodeficiency virus in human T cells.     

Effect of 5-azacytidine treatment on mouse embryonal carcinoma cells

Several properties of embryonal carcinoma (EC) cell lines, such as multipotent PCC4-aza-1 cells and nullipotent F9 cells originating from murine teratocarcinoma cells, were examined after treatment with 5-azacytidine, which produces undermethylated DNA. Drug-treated PCC4-aza-1 cells exhibited morphological changes and differentiated, whereas azacytidine-treated F9 cells displayed no detectable morphological change. After treatment with 5 azacytidine, PCC4-aza-1 cells, whether or not they differentiated, as well as F9 cells, became permissive for polyoma even though both cell types are usually resistant to polyoma. In contrast, only the differentiated azacytidine-treated PCC4-aza-1 cells became sensitive to SV40 infection, i.e., synthesized T antigen, despite the resistance normally shown by such cells to this viral infection. In some PCC4-aza-1 and F9 cells, drug treatment induced expression of H2 antigen but did not derepress plasminogen activator synthesis. These results suggest that undermethylation of certain cellular genes in PCC4-aza-1 and F9 cells is correlated with the establishment of Py permissivity, SV40 sensitivity, H2 antigen expression, and the triggering of a differentiation process. The relationship between the expression of these characters and differentiation is discussed.     

Retinoic acid effect on cyclic AMP-dependent protein kinases in embryonal carcinoma cells: studies with differentiation-defective sublines

Retinoic acid induces the differentiation of PCC4.aza 1R and Nulli-SCC1 embryonal carcinoma (EC) cells. In response to retinoic acid treatment, the levels of cyclic AMP (cAMP)-dependent protein kinases are enhanced in the plasma membrane within 17 hours and in the cytosol fractions of these cells within 2 to 3 days, as determined by phosphotransferase activity and by 8-azido-cyclic [32P]AMP binding to the RI and RII regulatory subunits. PCC4 (RA)-1 and Nulli (RA)-1 are mutant EC lines that fail to differentiate in response to retinoic acid. The former line, but not the latter, lacks cellular retinoic acid-binding protein (cRABP). Basal levels of cAMP-dependent protein kinase activities are elevated in PCC4 (RA)-1 cells. When these cells are treated with retinoic acid, neither cAMP-dependent protein kinase activities nor cAMP binding activities are enhanced; rather, there is a decrease in cytosolic kinase activity and RI subunit. On the other hand, Nulli (RA)-1 cells exhibit increases both in cAMP-dependent protein kinase activities and cAMP binding in response to retinoic acid. These results raise the possibility that cRABP mediates the enhancement of regulatory and catalytic subunits of cAMP-dependent protein kinases in both the membrane and the cytosolic fractions of the teratocarcinoma cells. There also might be some effects of retinoic acid on the cAMP-dependent protein kinase that are unrelated to differentiation and to the presence of cRABP.     

Analyses of the interactions between retinoid-binding proteins and embryonal carcinoma cells

[3H]Retinoic acid (RA) and [3H]retinol bind in an unsaturable manner to isolated nuclei from Nulli-SCC1 and PCC4.aza1R embryonal carcinoma (EC) cells. When nuclei are challenged with the same labeled retinoids on their respective binding proteins (CRABP and CRBP), much less binding is observed and the binding is saturable. RA-CRABP does not compete with [3H]retinol-CRBP for binding to specific Nulli-SCC1 nuclear sites, whereas retinol-CRBP (but not apo-CRBP) actually potentiates the binding of [3H]RA-CRABP to these nuclei. The binding of [3H]RA-CRABP and [3H]retinol-CRBP is not dramatically affected by prior removal of the outer nuclear membrane with Triton X-100. However, treatment with the detergent after the binding reaction is complete removes about half of the bound [3H]RA-CRABP and almost all of the bound [3H]retinol-CRBP. We measured specific retinoid-binding activities in nucleoplasmic extracts of Nulli-SCC1 and PCC4.aza1R cells. The only readily detectable specific binding activity in nucleoplasmic extracts from untreated cells was for [3H]retinol in PCC4.aza1R preparations. Nucleoplasmic extracts from Nulli-SCC1 and PCC4.aza1R cells pretreated with RA had considerable levels of specific [3H]RA-binding activity with little or no increase in [3H]retinol binding. By contrast, similar extracts from Nulli-SCC1 cells treated with retinol bound large amounts of both [3H]retinol and [3H]RA. Under the same conditions, PCC4.aza1R extracts also contained [3H]RA-binding activity with no increase in [3H]retinol binding above the high endogenous levels. Although these results might reflect translocation of binding proteins from cytoplasm to nucleus, other interpretations must be considered since we often observed an increase, rather than the expected reduction, in cytoplasmic retinoid-binding protein levels.     

New class of polyomavirus mutant that can persist as free copies in F9 embryonal carcinoma cells.

A small circular DNA was found extrachromosomally in a clone of F9 embryonal carcinoma (EC) cells at high copy numbers per cell. The DNA was cloned in plasmid pUC19. Restriction endonuclease analyses of the DNA indicated that the DNA (fPyF9) was a mutant of polyomavirus (Py) DNA and had a mutation in a noncoding regulatory region. There have been many reports on the isolation of Py mutants capable of replication in undifferentiated cells. However, fPyF9 was different from other Py mutants in the following aspects: it was harbored stably as a free copy at 1 X 10(4) to 5 X 10(4) copies per cell in EC cells; it replicated in undifferentiated cells better than in differentiated cells; it was extremely rearranged in the sequences of the enhancer B domain; and it carried in the enhancer B domain three copies of an exogenous sequence which does not exist in Py strain A2. From these observations, we propose a new class of Py EC mutant which has an autonomous state similar to that of plasmid and small circular DNA in host cells.     

Cell-specific modulation of papovavirus replication by tumor suppressor protein p53

Small DNA tumor viruses like human papillomaviruses, simian virus 40, and adenoviruses modulate the activity of cellular tumor suppressor proteins p53 and/or pRB. These viruses replicate as nuclear multicopy extrachromosomal elements during the S phase of the cell cycle, and it has been suggested that inactivation of p53 and pRb is necessary for directing the cells to the S phase. Mouse polyomavirus (Py), however, modulates only the pRB protein activity without any obvious interference with the action of p53. We show here that Py replication was not suppressed by the p53 protein indeed in all tested different mouse cell lines. In addition, E1- and E2-dependent papillomavirus origin replication was insensitive to the action of p53 in mouse cells. We show that in hamster (Chinese hamster ovary) or human (osteosarcoma 143) cell lines the replication of both Py and papillomavirus origins was efficiently blocked by p53. The block of Py replication in human and hamster cells is not caused by the downregulation of large T-antigen expression. The deletion analysis of the p53 protein shows that the RPA binding, proline-rich regulatory, DNA-binding, and oligomerization domains are necessary for p53 action in both replication systems. These results indicate that in mouse cells the p53 protein could be inactive for the suppression of papovavirus replication.     

Isolation and characterization of polyoma virus mutants which grow in murine embryonal carcinoma and trophoblast cells.

Mouse trophoblast cell lines established from cultured midterm placenta and a cell line obtained from cultured blastocyst resemble trophectoderm cells. These cells are resistant to infection by wild-type polyoma virus. We have isolated six polyoma virus mutants capable of growing in trophoblast cell lines. Restriction enzyme analyses and marker rescue experiments revealed that the genetic changes necessary for the growth of these mutants ( PyTr mutants) in trophoblast cells were located in a regulatory region of the genome between the origin of viral DNA replication and the region encoding the viral structural proteins. PyTr mutants are, therefore, similar to PyEC mutants, described by others, which are able to grow in embryonal carcinoma cell lines such as F9 or PCC4. The nucleotide sequence of two independently obtained PyTr mutants has an identical 26-bp deletion from nucleotide 5131 to 5156. This deleted region is replaced by either the sequence GGGA or by viral DNA sequences that flank this deletion. PyECF9 mutants grow well in trophoblast and trophectoderm cells, but PyTr mutants do not grow in F9 or PCC4 cells.     

Requirement for prolonged action in the cytosol for optimal protein synthesis inhibition by diphtheria toxin

Diphtheria toxin A-fragment enters the cytosol of target cells, where it inhibits protein synthesis by catalyzing ADP-ribosylation of elongation factor 2 (EF-2). We have here analyzed toxin-induced protein synthesis inhibition in single cells by autoradiography and compared it with inhibition of protein synthesis in the whole cell culture. The data show that half-maximal protein synthesis inhibition in the whole cell population after a short incubation time is achieved by partially inhibiting protein synthesis in basically all the cells, while half-maximal protein synthesis inhibition after a long incubation time is due to a complete protein synthesis block in about half the cells in the population. We have also compared stable and unstable A-fragment mutants with respect to the kinetics of cell intoxication. While the toxicity of the stable mutants increased with time, the unstable mutants showed a similar toxicity at early and late time points. When studying the kinetics of cell intoxication by toxins with short cytosolic half-life, we could not detect any recovery of protein synthesis at late time points when all the mutant A-fragments should be degraded. This indicates that the ADP-ribosylation of EF-2 cannot be reversed by an endogenous activity in the cells. The data indicate that entry of toxin into a cell is not associated with an immediate block in protein synthesis, and that prolonged action of single A-fragment molecules in the cytosol is sufficient to obtain complete protein synthesis inhibition at low toxin concentrations.     

The c-Ha-ras oncogene and a tumor promoter activate the polyoma virus enhancer

A c-Ha-ras oncogene, to a lesser extent the c-Ha-ras proto-oncogene, and the tumor promoter 12-O-tetradecanoylphorbol-13-acetate activate the inactive polyoma virus (Py) enhancer in a myeloma cell line and the partially active Py enhancer in NIH 3T3 fibroblasts, but have no effect on the active Py enhancer in LMTK- fibroblasts. In addition, c-Ha-ras can stimulate the inactive Py enhancer in embryonal carcinoma F9 cells. c-Ha-ras activation in embryonal carcinoma cells does not appear to involve reversal of "E1A-like" inhibition of the enhancer. We suggest that modulation of cellular enhancer activity could play a key role in tumorigenesis by oncogenes.     

Alpha4beta1 integrin acts as a cell receptor for murine polyomavirus at the postattachment level

The initial interaction of murine polyomavirus (Py) with host cells occurs through direct binding of the major capsid protein VP1 with cell membrane molecules containing terminal sialic acids; however, these Py receptor molecules have not yet been identified. Analysis of the capsid protein primary sequences of all murine strains revealed the presence of integrin ligand motifs in the DE and EF loops of VP1 (LDV and DLXXL, respectively) and at the N terminus of VP2 (DGE). We show that infectivity of the Py A2 strain in mouse Swiss 3T3 fibroblasts is significantly reduced only in the presence of natural integrin ligands carrying an LDV motif or antibodies directed against the alpha4 and beta1 integrin subunits. Furthermore, we demonstrate that expression of the alpha4 subunit in the alpha4-deficient BALB/c 3T3 cells increases viral infectivity. Addition of alpha4 function-blocking antibodies, prior to or after virus adsorption, blocks this increased infectivity without affecting virus binding to cells. Taken together, these data indicate that expression of alpha4 integrin enhances permissivity to Py, probably by acting as one of the postattachment receptors.