Growth factor independence and indefinite growth ("immortalization") appear simultaneously after crisis in murine myelocytes expressing v-myc.

In murine myelocytes doubly infected with the v-myc virus and the v-Ha-ras virus, or the v-myc virus and the v-abl virus, the emergence of growth factor-independent cells is a rare event which coincides with crisis in the cultures. All growth factor-independent cells which emerge from crisis are also "immortalized", i.e., able to grow indefinitely. We wanted to determine whether the v-abl gene plays a role in the immortalization of the growth factor-independent cells. Therefore we infected murine myelocytes with v-myc virus and a v-abl mutant virus coding for a temperature-sensitive tyrosine kinase. Growth factor-independent cell clones were isolated and their properties at the nonpermissive temperature analyzed. We observed that 4 hr after the shift to the nonpermissive temperature the expression of both the genomic and subgenomic viral v-myc transcripts decreased significantly, followed by a loss of the viability of the cells. However, several variants emerged which were able to grow at the nonpermissive temperature and showed elevated expression of v-myc. The results suggest: 1) that v-abl plays a role in the immortalization of the cell clones by maintaining a critical level of v-myc expression; 2) that rare genetic changes leading to constitutive v-myc expression independent of v-abl tyrosine kinase activity can also lead to immortalization in this model system, and 3) that immortalization and growth factor independence occur in post-crisis cells and are associated with constitutive expression of v-myc.

Envelope gene and long terminal repeat determine the different biological properties of Rauscher, Friend, and Moloney mink cell focus-inducing viruses.

The nucleotide sequence of the envelope (env) gene and the long terminal repeat (LTR) of an infectious clone of Rauscher mink cell focus-inducing (R-MCF) virus has been determined and compared with the published env gene and LTR sequences of Friend (F)- and Moloney (M)-MCF viruses. The sequence shows that R-MCF virus, like other MCF viruses, is a recombinant virus. Its env gene contains sequences which were acquired from an env gene in the mouse genome and which confer on the MCF virus its dualtropic host range. Unlike F-MCF and M-MCF viruses, R-MCF virus will not replicate in NIH 3T3 cells. The deduced amino acid sequence for the gp70 of R-MCF differs from that of F- and M-MCF viruses by 15 amino acids between residues 49 and 138 of gp70. These differences in amino acid sequences may be responsible for the inability of R-MCF virus to replicate in NIH 3T3 cells. The host range of two hybrid viruses constructed in vitro is consistent with this hypothesis. R-MCF virus and Friend murine leukemia virus (F-MLV) show 98% identity in their env gene 3' from the acquired env sequences. This contrasts with 82% identity between the env gene of R-MCF virus and M-MLV. The LTR of R-MCF shows 98% identity with the LTR of F-MCF as compared to 88% identity with the LTR of M-MCF. This striking similarity between the sequences of R-MCF, F-MCF, and F-MLV is surprising since the Rauscher virus and the Friend virus are thought to have originated independently. The high degree of similarity suggests that Rauscher and Friend viruses have a common origin. In contrast to M-MLV, which induces predominantly a lymphoid disease, R- and F-MCF viruses induce an erythroproliferative disease in NIH Swiss mice. A hybrid R-MCF virus with a genome derived primarily from R-MCF virus and a 3' end including the U3 region derived from M-MLV induces a lymphoid disease instead of an erythroid disease. This result indicates that it is the U3 region which determines the tissue specificity of the MCF virus-induced disease. It is suggested that the putative viral enhancers in the U3 region play two roles in the process of leukemogenesis: in the Friend and Rauscher disease, the viral enhancers act by increasing the transcription of the MCF env gene; in the thymic lymphoma, the enhancers activate mainly the expression of cellular genes.

Specific sequences of the env gene determine the host range of two XC-negative viruses of the Rauscher virus complex.

Two viruses which do not give rise to XC plaques in the standard XC assay (XC-negative) have been isolated from the Rauscher virus (RV) complex. These viruses differ in their host range. One, R-MCF-1, is dualtropic and will therefore infect both murine and non-murine cells. However, unlike other mink cell focus-inducing (MCF) viruses, it cannot infect NIH 3T3 cells. The other, R-XC-, is ecotropic. It will infect murine cells, including NIH 3T3 cells, but does not infect mink lung cells. Analysis of hybrid viruses, in which homologous regions of the genomes of R-MCF-1 and R-XC- virus were exchanged, indicated that the NH2-terminal portion of the gp70 is responsible for the particular host ranges of these viruses. The nucleotide sequence of the env gene of R-XC- virus was therefore determined and compared with the known env sequences of ecotropic MLVs and dualtropic MCF viruses of the Rauscher and Friend virus complexes. R-XC- virus was found to be a recombinant virus. Its env gene contained sequences derived from an endogenous env gene which were closely related to those of the MCF viruses but differed from any previously described sequences. The particular properties of R-MCF-1 and R-XC- virus suggest that the two viruses arose by recombination between R-MLV and two endogenous env sequences which differ from those of the known MCF viruses. If so, this suggests that the mouse genome contains at least five env sequences which can give rise to MCF-like viruses. In addition, since the host range and interference properties of R-XC- virus are very similar to those of the previously described ecotropic recombinant viruses, it may be that the ecotropic recombinant viruses arose by recombination with the same endogenous env sequences as did R-XC- virus.

Characterization and cell cycle regulation of the related human telomeric proteins Pin2 and TRF1 suggest a role in mitosis.

Telomeres are essential for preserving chromosome integrity during the cell cycle and have been specifically implicated in mitotic progression, but little is known about the signaling molecule(s) involved. The human telomeric repeat binding factor protein (TRF1) is shown to be important in regulating telomere length. However, nothing is known about its function and regulation during the cell cycle. The sequence of PIN2, one of three human genes (PIN1-3) we previously cloned whose products interact with the Aspergillus NIMA cell cycle regulatory protein kinase, reveals that it encodes a protein that is identical in sequence to TRF1 apart from an internal deletion of 20 amino acids; Pin2 and TRF1 may be derived from the same gene, PIN2/TRF1. However, in the cell Pin2 was found to be the major expressed product and to form homo- and heterodimers with TRF1; both dimers were localized at telomeres. Pin2 directly bound the human telomeric repeat DNA in vitro, and was localized to all telomeres uniformly in telomerase-positive cells. In contrast, in several cell lines that contain barely detectable telomerase activity, Pin2 was highly concentrated at only a few telomeres. Interestingly, the protein level of Pin2 was highly regulated during the cell cycle, being strikingly increased in G2+M and decreased in G1 cells. Moreover, overexpression of Pin2 resulted in an accumulation of HeLa cells in G2+M. These results indicate that Pin2 is the major human telomeric protein and is highly regulated during the cell cycle, with a possible role in mitosis. The results also suggest that Pin2/TRF1 may connect mitotic control to the telomere regulatory machinery whose deregulation has been implicated in cancer and aging.

Independent induction of senescence by p16INK4a and p21CIP1 in spontaneously immortalized human fibroblasts.

In this work, we address the question of whether replicative senescence can be induced in immortal nontumorigenic human fibroblasts. The immortal fibroblasts used in this study were derived from two Li-Fraumeni (LF) patients who carry in their germ line one wild-type and one mutant p53 allele. Both immortal lines have lost the wtp53 allele and express no detectable p16INK4a protein, although they carry the p16INK4a gene. In contrast to immortal human fibroblasts, senescent human fibroblasts have a low content of 5-methyl-cytosine in their DNA. This observation suggested the possibility that a demethylating agent could revert the immortal phenotype and induce replicative senescence in the immortal cell lines. Cells of the two LF lines were exposed to the demethylating agent 5-aza-2'-deoxycytidine. Within 6 days, all cells were growth arrested and showed the enlarged and flat morphology characteristic of senescent cells, an accumulation of lipofuscin granules and senescence-associated beta-galactosidase activity at pH6, both biomarkers for senescence. Immunoblots of 5-aza-2'-deoxycytidine-treated cells showed a greatly increased expression of p16INK4a protein but no detectable change in the expression of p21CIP1, a gene known to be strongly expressed in senescent normal human fibroblasts. In two other experimental series, cells of the two LF lines were infected with retroviral constructs encoding either p16INK4a or p21CIP1. Each of the transduced genes induced senescence without affecting the expression of the other endogenous gene. The results show that induction of senescence in immortal LF fibroblasts can occur by different pathways: (a) by demethylation-dependent pathways that induce the expression of p16INK4a; and (b) by demethylation-independent pathways involving the expression of p21CIP1. The induction of senescence by p16INK4a and p21CIP1 occurred equally in the two human immortal fibroblast lines, which differed in the length of their telomeres and the activity of their telomerase.

The induction of growth factor-independence in murine myelocytes by oncogenes results in monoclonal cell lines and is correlated with cell crisis and karyotypic instability.

Infection of established (IL-3)-dependent hematopoietic cell lines with Abelson murine leukemia virus (A-MLV) abrogates their requirement for IL-3 and leads to non-autocrine growth factor-independent cells. We were interested to determine whether A-MLV can induce IL-3 independence also in non-established cells. To obtain long-term cultures of diploid myelocytes, splenic hematopoietic cells were first infected with MMCV, a murine retrovirus carrying the avian v-myc oncogene. These cultures were superinfected with A-MLV. In three independent experiments, the first growth factor-independent cells appeared between 18 and 43 days after superinfection with A-MLV and represented .02-1% of the population. Furthermore, the cultures that became growth factor-independent were monoclonal for integration of the v-abl gene. These results indicate that the acquisition of growth factor-independence after superinfection of v-myc-expressing cells with A-MLV is a rare event. The low frequency of growth factor-independent cells was not due to a low percentage of infected cells, since 15-25% of the cells were infected with A-MLV after 7 days. The first appearance of growth factor-independent cells coincided with crisis in the cultures, as indicated by a high incidence of cell death and a reduced overall growth rate of the cell populations. These growth factor-independent cells exhibited variable karyotypes, including many that were near-triploid to near-tetraploid. In summary, growth factor-independence induced by super-infection with A-MLV, like that induced by double-infection with v-myc- and v-H-ras-containing viruses, is associated with unstable karyotypes. The growth factor-independent cells show variable ploidy characteristic of cells which survived crisis.