Epstein-Barr virus in somatic cell hybrids between mouse cells and human nasopharyngeal carcinoma cells.

Somatic cell hybrids between mouse cells and cells derived directly from NPC biopsies were produced in order to study the association of the Epstein-Barr virus (EBV) genome and the expression of Epstein-Barr nuclear antigen (EBNA) with the human chromosome(s). All attempts to correlate the presence of EBV-DNA and the expression of EBNA with the presence of a particular human chromosome(s) showed that the segregation of EBV-DNA or of EBNA and human chromosomes was dysconcordant. The data, therefore, suggest that in the hybrids studied the presence of EBA-DNA is not determined by the presence of a specific human chromosome.     

Differential tumorigenicity between Epstein-Barr virus genome-positive and genome-negative cell lines with t(11;14)(q13;q32) derived from mantle cell lymphoma.

Epstein-Barr virus (EBV) genome has been detected in several human lymphoproliferative diseases, but the oncogenic function of EBV is not fully understood. We previously established EBV-positive (SP-50B) and EBV-negative (SP-53) cell lines with the t(11;14)(q13;q32) chromosome abnormality from a single patient with mantle cell lymphoma. Monoclonal EBV DNA in a circular episomal form was demonstrated in the SP-50B cells by Southern blot hybridization with the EBV-terminal fragment probe. SP-50B cells were positive for not only EBV-encoded nuclear antigen-1 (EBNA1) but also latent membrane protein-1 and EBNA2. None of the EBV-encoded proteins was expressed in SP-53 cells. The isogenic EBV-infected and EBV-free cell lines of neoplastic clones made it possible to examine a tumorigenic role of EBV. Only EBV-positive SP-50B cells possessed malignant phenotypes, such as growth ability in low serum, colony formation in soft agarose, and tumorigenicity in nude mice. On the other hand, a lymphoblastoid B-cell line established by infecting the patient's normal B lymphocytes in vitro with exogenous EBV had no tumorigenicity. These results suggested that EBV infection, if it occurred in neoplastic lymphoma cells, could play a role in acquisition of malignant phenotypes.     

Levels of fos, ets2, and myb proto-oncogene RNAs correlate with segregation of chromosome 11 of normal cells and with suppression of tumorigenicity in human cell hybrids.

The tumorigenicity in nude mice of human carcinoma-derived D98AH2 (D98) cells is suppressed when cell hybrids are made by fusing these cells with normal human diploid cells. Selection for hybrids that have segregated chromosomes results in the recovery of tumorigenic segregants. These segregants have all lost at least one copy of chromosome 11 of the diploid cell parent. Earlier we found that the parental D98 cells had detectable levels of mRNA specific for 13 of 21 proto-oncogenes examined. To determine if transregulation of proto-oncogenes by genes of the normal cell occurs in such hybrids, the steady-state levels of mRNA specific to 22 proto-oncogenes in the parental cells were compared with those of nontumorigenic D98 X human diploid hybrids as well as with those of their tumorigenic segregants and with the cells of the resulting tumors. The only chromosome consistently segregated in the latter was chromosome 11 of the diploid cell. fos and ets2 RNA levels and the amount of fos protein were consistently elevated in the segregants compared with amounts in the original hybrids. An unexpected finding was the inverse relationship for myb RNA that was barely detected in the parental D98 cells but was at least 10-fold elevated in hybrids that did not have segregated chromosomes compared with those that did. These patterns were evident in RNAs prepared from both subconfluent and confluent cell cultures. The findings suggest that genes of the normal cell parent can affect proto-oncogene expression. Whether the genes affecting fos, ets2, and myb RNA levels are on chromosome 11 and whether these alterations are causally related to the tumorigenic phenotype of the hybrid remain to be determined.     

Identification of a human chromosome 11 gene which is differentially regulated in tumorigenic and nontumorigenic somatic cell hybrids of HeLa cells.

The tumorigenicity of HeLa cells in nude mice can be suppressed by the addition of a normal human chromosome 11 in somatic cell hybrids. We have attempted to identify specific genes involved in this phenomenon by transfecting a complementary DNA expression library into a tumorigenic HeLa-fibroblast hybrid. A cell line designated F2 was isolated which displayed morphological features of the nontumorigenic hybrids, demonstrated reduced tumorigenicity in nude mice, and showed an 85% reduction in alkaline phosphatase, a consistent marker of the tumorigenic phenotype in these cells. F2 contained a single exogenous complementary DNA, which was recovered by polymerase chain reaction and designated HTS1 because of its potential association with "HeLa tumor suppression." Northern blot studies suggested differential regulation of the HTS1 gene dependent on the tumorigenicity of the cell. In nontumorigenic hybrids, RNA species of 2.8, 3.1, and 4.6 kilobases were identified. In two tumorigenic hybrid lines, the 2.8-kilobase species was markedly reduced or absent. Similarly, three nontumorigenic human keratinocyte lines expressed all three RNA species, whereas several tumorigenic cervical carcinoma cell lines lacked the 2.8-kilobase species. Chromosome localization studies mapped the HTS1 gene to chromosome 11p15, a region of chromosome 11 that is believed to contain a tumor suppressor gene. These findings indicate that HTS1 represents a novel chromosome 11 gene which may be a target of the tumor suppressor gene active in this system.     

Genetic control of tumorigenicity in interspecific mammalian cell hybrids.

The nature of genetic control of cellular malignancy was investigated by examining the tumorigenicity of a series of interspecific mouse-human cell hybrids in the athymic nude mouse. Two highly malignant but genetically distinct mouse cell lines, A9 and PG19, were hybridized with three normal human diploid fibroblast strains, and 19 independently arising hybrid clones were isolated. Each of these clones was capable of forming progressive lethal tumors in the nude mouse, and thus resembled the malignant parental mouse cells rather than the nonmalignant parental human cells. We failed to obtain any evidence for complete suppression of tumorigenicity in these cell hybrids. The absence of suppression was observed regardless of the extent and composition of the human chromosome complements retained in the hybrid clones; the results of detailed cytological and isoenzyme analyses would make it highly improbable that the observed lack of suppression was due to cellular selection in vivo for a more tumorigenic subpopulation in the injected hybrid cells. These data demonstrate that at least for the parental cell combinations used in this study, no human chromosome, when present singly in the mouse-human cell hybrids, can suppress the tumorigenic phenotype of the mouse cells. Our results are consistent with the view that the suppression of cellular malignancy previously demonstrated in intraspecific (mouse × mouse) somatic cell hybrids does not occur in interspecific (mouse-human) cell hybrids, or alternatively, genetic determinants located on two or more human chromosomes are required simultaneously to suppress the malignancy of the mouse cells in cell hybrids derived from malignant mouse cell and nonmalignant human cells.     

Lack of tumor suppression but induced loss of copies of indigenous chromosome 10 in vitro following microcell-mediated transfer of a deleted human der(9)t(X;9) chromosome to Syrian hamster BHK-191-5C cells

We have previously shown that microcell-mediated transfer of a der(9)t(X;9) chromosome, containing an almost complete human chromosome (HSA) 9 derived from the human fibroblast strain GM0705, into the Syrian hamster (Mesocricetus auratus) cell line BHK-191-5C suppressed the anchorage independence and tumorigenicity of the hybrids. Transfer of a normal HSA X did not have any effect on these phenotypes. Although the recipient cell line contained a 1:1 ratio of near-diploid and near-tetraploid cells, all hybrids retaining the der(9) chromosome were near-tetraploid, in contrast to hybrids retaining a normal X chromosome. In the present study, we have generated microcell hybrids by transferring another der(9)t(X;9) chromosome derived from the human fibroblast strain GM01429. This derivative chromosome contained a deletion on the short arm of HSA 9 and was also missing the distal part of the long arm of HSA 9 due to the involvement in a reciprocal (constitutive) translocation of this chromosome with HSA X. Cytogenetic analysis showed that all hybrid clones were near-tetraploid, confirming our previous finding. We also observed that the introduction of the deleted der(9) chromosome forced the hybrids to lose Syrian hamster chromosome 10. A soft agar test and nude mice assay indicated that none of the hybrids was suppressed for either anchorage independent growth or tumor formation. These data suggest that there is an antagonistic relationship between growth-promoting genes and antiproliferative genes. The observed dosage effects of both growth-promoting and growth-suppressing genes indicate that cellular growth may be a quantitative trait.     

Evidence for suppression of cellular growth in vitro and selection against the indigenous mouse X chromosome in A9 cell hybrids after microcell-mediated transfer of an X from other mammalian species

Introduction of a human or Syrian hamster X chromosome (derived from BHK-191-5C cell hybrids) into tumorigenic mouse A9 cells via microcell fusion induced changes in cellular morphology and a retardation of cellular growth. The suppression of growth of the hybrids could be abolished, however, by daily changes of medium containing 20% serum. G-banding analysis showed the absence of a single, cytogenetically identifiable, indigenous X chromosome (marker Z) in two of four hybrid clones after an X chromosome was transferred from either hamster or human cells. All hybrids were tumorigenic when tested in nude mice. Together, these data suggest that the loss of the mouse X chromosome took place probably because of growth inhibitory effects imposed on hybrid cells due to the increase in X chromosome dosage. In addition, our results show a lack of association between the phenotype of cellular growth suppression in vitro and the phenotype of suppression of tumorigenicity in vivo.     

Genetic analysis of tumorigenesis. VIII. Suppression of SV40 transformation in cell hybrids and cytoplasmic transferants

Intraspecies somatic cell hybrids of BALB/c mouse 3T3 and SV40-transformed embryonic fibroblast (SVT2) cells were analyzed for transformation-associated properties and their tumorigenic potential in nude mice. In confirmation of our earlier findings, hybrids expressing the viral T-antigen were not suppressed for the ability to clone in medium with 1% serum. In contrast, division rate in medium with 1% or 10% serum, anchorage independence, cytochalasin-sensitive growth control, and tumorigenicity were suppressed noncoordinately, and the extent of suppression varied from one hybrid to another. Suppression was not simply determined by the increased chromosome content of the hybrid cells, nor was suppression correlated with rearrangements of the integrated viral sequence (SAGER et al., 1981a, b). Similar results were found in cytoplasmic transferants expressing T-antigen. Four independent transferants and subclones derived from them varied in the extent of suppression of anchorage independence and tumorigenicity. In both hybrids and transferants, a low serum requirement for clonal growth apparently was determined solely by expression of SV40 T-antigen, but other transformation properties, as well as tumorigenicity, appeared to require multiple changes in the cellular genome for their expression. These changes must occur during or after viral integration, since they are not expressed in uninfected 3T3 cells.     

Association of human chromosome 14 with a ts defect in G1 of Chinese hamster K12 cells.

Somatic cell hybrids between human lymphoblastoid cells (Raji) and temperature-sensitive Chinese hamster cells (K12) were selected from monolayer cultures in MEM at 40 degrees C. A total of 21 hybrid clones were isolated and karyotyped. All clones contained a near complete set of Chinese hamster chromosomes and 1 to 5 human chromosomes. Human chromosome 14 present in the hybrid cells of all clones; and was the only human chromosome retained in 10 clones. The presence of human chromosome 14 in hybrids was further confirmed by the demonstration of human nucleoside phosphorylase activity in the hybrid cells. Only one hybrid clone was positive for EBNA, the Epstein-Barr virus antigen present in Raji cells. These findings indicate that human chromosome 14 contains the necessary information for the K12 cells to overcome their G1 defect in the cell cycle and grow at non-permissive temperature. The present study lends strong support to the possibility that different steps in the G1 phase of the cell cycle are controlled by genes located on different chromosomes.     

Complete suppression of tumor formation by high levels of basement membrane collagen

Suppression of tumorigenicity was first shown in hybrids produced by the fusion of a range of different highly malignant tumor cells with diploid fibroblasts. Cytogenetic analysis of these hybrids revealed that suppression involved a genetic region located in one specific chromosome donated to the hybrid cell by the fibroblast parent. The identity of the gene responsible for this dramatic effect has remained obscure. We now present strong evidence that the primary determinant is the gene specifying collagen XV, a proteoglycan closely associated with the basement membrane. We transfected a line of highly tumorigenic human cervical carcinoma cells with an expression vector carrying the full-length cDNA of the human collagen XV gene. We selected clones making various amounts of collagen XV, examined their growth in vitro, and tested their tumorigenicity in nude mice. High levels of collagen XV altered the growth properties of the cells in three-dimensional cultures. Moreover, we found that, in a dose-dependent manner, the production of collagen XV completely suppressed tumorigenicity in clones that synthesized this molecule at high levels. Immunohistologic studies suggest that suppression is associated with extracellular deposition of the proteoglycan at the cell periphery.     

Suppressor genes for malignant and anchorage-independent phenotypes located on human chromosome 9 have no dosage effects

We have previously shown that microcell-mediated transfer of a der(9)t(X;9) human chromosome (HSA), derived from human fibroblast strain GM0705, into the Syrian hamster cell line BHK-191-5C produced only near-tetraploid hybrids, although the recipient cell line contained a 1:1 ratio of near-diploid and near-tetraploid cells. However, the tumorigenicity and the anchorage independence could be suppressed in the near-tetraploid hybrids with one copy of the der(9)t(X;9) chromosome. The introduction of an HSA X chromosome did not suppress either of these phenotypes. We concluded that in addition to two suppressor genes, one for tumorigenicity and another for anchorage independence, HSA 9 might carry a third gene capable of inhibiting cellular growth in vitro, which had dosage effects. In the present study, keeping one copy of the der(9)t(X;9) chromosome, we have increased the hamster background chromosome number beyond hexaploid level by fusing two microcell-generated hybrid cell lines, where both malignant and anchorage-independent phenotypes were suppressed, with the parental malignant BHK-191-5C cell line. Tests with nude mice showed that hybrids containing one copy of the der(9)t(X;9) chromosome against the increased background of chromosomes of malignant parental origin were still suppressed for both phenotypes. These results suggest that the suppressor genes for malignancy and for anchorage independence have no dosage effects, in contrast to the suppressor gene(s) for cellular growth.     

恶性横纹肌样瘤（MRT）的起源研究——高变异率HeLa细胞致裸鼠产生MRT的实验研究

HeLa细胞KB株、X株、NM20／X株、H株的染色体众数依次为60±3（超二倍体）、62±3（超二倍体）、68±3（超二倍体和亚四倍体）和78±2（亚四倍体）,所占比率分别为72%～76%,69%,52%和40%。在纯化3代的肿瘤阴性对照二倍体猫肾（染色体众数38所占比率80%）和犬肾原代细胞皮下接种裸鼠的致癌／致瘤率分别为0%（0／22）和0%（0／10）,X株HeLa细胞冻融裂解物皮下接种裸鼠产生进行性缩小肿瘤的比率为20%（1／5）的前提下,HeLa细胞KB株、X株、NM20／X株皮下接种裸鼠产生进行性生长恶性肿瘤的比率分别为100%（10／ 10）,100%（25／25）和100%（5／5）,H株细胞皮下接种裸鼠产生恶性肿瘤的比率为50%（5／10）。其中,只有HeLa细胞KB株10～11代（染色体结构畸变率高达20%,出现18%双着丝点和2%断片）以超高数量接种的1组4只裸鼠（0.17ml12.75×10     

Suppression of tumorigenicity in somatic cell hybrids. IV. Chromosomes of normal human cells associated with suppression of tumorigenicity in hybrids with D98AH2 carcinoma cells

An analysis for cosegregation of chromosomes and tumorigenicity in 52 hybrids of human diploid X D98AH2 human carcinoma-derived cells reveals the consistent presence of four copies of chromosome 11 in all nontumorigenic hybrids (two from each of the parental cells) and a consistent loss of one or two copies of the 11 in all tumor cells derived from tumorigenic hybrids that grow in nude mice. In our earlier study, assays with restriction fragment length polymorphic (RFLP) markers for the cell parent origin of the chromosomes 11 in the hybrids indicated that at least one of the Nos. 11 lost in the tumor cells is from the diploid. Thus both Nos. 11 of the diploid seem to be required for complete and stable suppression of the tumorigenic phenotype. The results of the present study suggest that chromosome 2 may also carry suppressor information, but this causes only partial suppression of the tumorigenic phenotype in the absence of both Nos. 11. On the other hand, when the hybrids contain full complements of the 2 and the 11, suppression is very stable. All other chromosomes except for Nos. 1, 16, 17, 19, and 21 are clearly discordant with suppression. The latter chromosomes are not discordant often enough to allow their exclusion as possible carriers of suppressor information, particularly in the absence of RFLP evaluations. It is clear, however, that if they do carry such information it is not adequate for maintaining a stably suppressed phenotype in the absence of both Nos. 11 of the diploid.     

Multi-step neoplastic transformation of normal human fibroblasts by Co-60 gamma rays and Ha-ras oncogenes

As reported previously (Namba et al., 1985; Namba, 1985), normal human fibroblasts were transformed into immortal cells with abnormal karyotypes by Co-60 gamma-ray irradiation. These immortally transformed cells (KMST-6) showed no clonability in soft agar and were not tumorigenic. However, by treatment with Ha-ras oncogenes derived from a human lung carcinoma or Harvey murine sarcoma virus, the KMST-6 cells acquired elevated clonability in soft agar and transplantability in nude mice. All the tumors produced grew progressively without showing regression and killed the mice. The tumors were also serially transplantable into other mice. The Ha-ras oncogene alone did not convert normal human fibroblasts into either immortal or tumorigenic cells. Our current data suggest that gamma rays worked as an initiator of carcinogenesis in normal human cells, giving rise to chromosome aberrations and immortality, and the Ha-ras oncogene played a role in the progression of the immortally transformed cell population to a neoplastic one showing enhanced colony formation in soft agar and tumorigenicity in nude mice.     

Cellular and Epstein-Barr virus specific DNA polymerases in virus-producing Burkitt's lymphoma cell lines.

We have determined the levels of cellular DNA polymerases and Epstein-Barr virus specific DNA polymerase in three Burkitt's lymphoma cell lines producing varying amounts of EBV, one of which was induced by 12-0-tetra-decanoylphorbol-13-acetate (TPA). There was a proportional increase in the level of EBV-DNA polymerase with an increase in the percent of virus-producing cells. However, there was a reciprocal relationship between the levels of EBV-DNA polymerase and DNA polymerase alpha i.e., in cell line containing the highest level of EBV-DNA polymerase, activity of DNA polymerase alpha, but not of DNA polymerase beta, was reduced to an insignificantly low level. TPA does not have any direct effect on activities of either EBV-DNA polymerase or DNA polymerase alpha. EBV-DNA polymerases isolated from cells grown with or without TPA are indistinguishable in their properties such as elution position on phosphocellulose column, molecular weight, mono and divalent cation requirements, pH optimum, and other requirements for optimum activity. Addition of crude extracts of cells grown in presence of TPA to the purified DNA polymerase alpha did not inhibit its activity indicating that the observed loss was not due to any specific inhibitor present in TPA treated cells. Raji, a nonproducer cell line, did not contain EBV-DNA polymerase. There was no induction of EBV-DNA polymerase when Raji cells were grown in presence of TPA. The phenomenon of reduction in the levels of DNA polymerase alpha in cells induced to produce EBV may represent a mechanism by which the host DNA replication is shut off following virus infection.     

人胎脑源性神经前体细胞致瘤性评价

目的:研究体外培养的人胎脑源性神经前体细胞的致瘤性。方法:将人胎脑源神经前体细胞体外培养至第1、25、40、60代,且每代细胞分别制备成神经球及单个细胞混悬液两种制剂,并取293T细胞作为阳性对照,共9组,每组5只,分别皮下接种于4~8周龄的BALB/C裸鼠,接种后饲养6个月,定期观察裸鼠精神状态、饮食、排便、以及接种局部有无出现结节或肿块,接种6个月后处死裸鼠,对接种局部及内脏进行组织病理切片及HE染色。结果:将人胎脑源性神经前体细胞接种于裸鼠皮下6个月未见肿瘤形成,且未见其他异常组织形成;而阳性对照组293T细胞接种于裸鼠皮下1个月后可见明显肿瘤形成。结论:人胎脑源神经前体细胞对裸鼠不具有体内致瘤性。     

Use of adenovirus vectors expressing Epstein-Barr virus (EBV) immediate-early protein BZLF1 or BRLF1 to treat EBV-positive tumors

The Epstein-Barr virus (EBV) genome is present in a variety of tumor types, including virtually all undifferentiated nasopharyngeal carcinomas (NPC) and a portion of gastric carcinomas. The uniform presence of the EBV genome in certain tumors (versus only a very small number of normal B cells) suggests that novel therapies which specifically target EBV-positive cells for destruction might be effective for treating such tumors. Although the great majority of EBV-positive tumor cells are infected with one of the latent forms of EBV infection, expression of either viral immediate-early protein (BZLF1 or BRLF1) is sufficient to convert the virus to the lytic form of infection. Induction of the lytic form of EBV infection could potentially result in death of the tumor cell. Here we have examined the efficacy of adenovirus vectors expressing the BZLF1 or BRLF1 proteins for treatment of EBV-positive epithelial tumors. The BZLF1 and BRLF1 vectors induced preferential killing of EBV-positive, versus EBV-negative, gastric carcinoma cells in vitro. Infection of C18 NPC tumors (grown in nude mice) with either the BZLF1 or BRLF1 vector, but not a control adenovirus vector, induced expression of early lytic EBV genes in tumor cells. Injection of C18 tumors with the BZLF1 or BRLF1 adenovirus vector, but not the control vector, also significantly inhibited growth of the tumors in nude mice. The addition of ganciclovir did not significantly affect the antitumor effect of the BZLF1 and BRLF1 adenovirus vectors. These results suggest a potential cancer therapy against EBV-related tumors.     

Isolation of Epstein-Barr virus (EBV)-negative cell clones from the EBV-positive Burkitt's lymphoma (BL) line Akata: malignant phenotypes of BL cells are dependent on EBV.

During cultivation of the Epstein-Barr virus (EBV)-positive Burkitt's lymphoma (BL) line Akata, it was noted that EBV DNA is lost from some of the cells. Isolation of EBV-positive and EBV-negative clones with the same origin made it possible to examine the effects of EBV in BL cells. The results indicate that malignant phenotypes of BL, such as growth in low serum, anchorage-independent growth in soft agar, and tumorigenicity in nude mice, are dependent on the presence of EBV genomes and underline the oncogenic function of EBV in human cancer.