Generation of tumor-specific transplantation antigens by UV radiation can occur independently of neoplastic transformation

The purpose of this study was to determine whether the UV-associated antigens present on tumors induced in mice by chronic UV irradiation could be induced by in vitro irradiation of cells that were already tumorigenic, or whether their occurrence was associated with the primary neoplastic transformation event. Cells of a nonantigenic, spontaneous fibrosarcoma cell line were exposed to UV radiation in vitro, were cloned, and were tested for antigenic properties. A large number of the clones obtained after UV irradiation of the fibrosarcoma cells were highly antigenic (20 of 39), whereas clones derived from unirradiated cultures were not (0 of 10). The antigenic variants did not induce cross-protection among themselves, but induced only variant-specific immunity in vivo. Several antigenic variants were tested for susceptibility to the action of UV-induced suppressor cells, which seem to recognize a common determinant shared among UV-induced tumors. The variants tested were indeed subject to the activity of the UV-induced suppressor lymphocytes. These results demonstrate that the unique antigenic properties exhibited by UV-induced murine skin cancers are also exhibited by cells exposed to UV radiation in vitro. In addition, they imply that the UV-associated antigens arise as a consequence of exposing cells to UV radiation and that they can occur independently of an initial neoplastic transformation event.     

Limited lifespan in somatic cell hybrids and cybrids

The transformed phenotype is believed to be dominant in fusions between limited lifespan cells and transformed cells, based on heterokaryon experiments and on the isolation of transformed hybrids from mass cultures of fused cells. A series of fusions has been performed between limited lifespan Lesch-Nyhan fibroblast cells and a permanent HeLa cell line with a complementary genetic marker. The growth of independently isolated hybrid clones was followed in parallel with Lesch-Nyhan cells. In fusions involving Lesch-Nyhan cells which had completed about 50% of their lifespan, all hybrids initially show fibroblastic properties. Thirty-five hybrids had a limited lifespan slightly longer than Lesch-Nyhan controls. Three other hybrid clones, and all mass cultures of hybrids, showed the appearance of transformed colonies at a rate of approx. one transformant in 2 × 10₅ hybrid cells. These transformed cells showed anchorage independence, low serum requirement, chromosome loss, and have been maintained in culture for 50–100 population doublings with no signs of senescence. Fusions involving enucleated HeLa cells did not show transformation. Fusions with senescent Lesch-Nyhan cells yielded hybrids which grew beyond the normal Lesch-Nyhan cell lifespan, but which again showed limited lifespan and low frequency transformation. It is concluded that limited lifespan is expressed in a dominant manner in these fusions, and that transformation or “escape from senescence” is a low frequency event requiring the presence of the HeLa nucleus.     

Genetic instability at the adenine phosphoribosyltransferase locus in mouse L cells.

Resistance to adenine analogs such as 2,6-diaminopurine occurs at a rate of approximately 10(-3) per cell per generation in mouse L cells. This resistance is associated with a loss of detectable adenine phosphoribosyltransferase activity. Other genetic loci in L cells have the expected mutation frequency (approximately 10(-6)). Transformation of L cell mutants with Chinese hamster ovary cell DNA results in transformants with adenine phosphoribosyltransferase activity characteristic of Chinese hamster ovary cells. No activation of the mouse gene occurs on hybridization with human fibroblasts. That this high frequency event is the result of mutation rather than an epigenetic event is supported by antigenic and reversion studies of the 2,6-diaminopurine-resistant clones. These results are consistent with either a mutational hot-spot, a locus specific mutator gene, or a site of integration of an insertion sequence.     

An effect-specific track-length model for radiations of intermediate to high LET

A model for the induction of transformation, mutation, and cell killing by radiations of intermediate to high linear energy transfer (LET) is presented. The mathematical formulation presupposes a constant probability per unit path length for damaging multiple subcellular targets by radiation of a fixed LET. The coupling between effects is accounted for through an explicit calculation of the probability that any specific combination of effects occurs in a given cell. This feature avoids the false assumption that cell killing and mutation (or transformation) are independent events. The resulting model then is applied to data on the in vitro survival, mutation, and transformation of cells by radiations of varying LET. A summary of estimated parameter values is provided and calculations of the effect of cellular flattening on transformation are presented.     

Persistent expression of morphological abnormalities in the distant progeny of irradiated cells

The phenomenon of delayed heritable lethal damage (often referred to as ``lethal mutations') in the progeny of cells which survive irradiation is now well established, but little is known of the mechanism by which this cell death occurs. Current theories suggest a generalised genomic instability affecting all cells which leads to the production of some mutations which are lethal, or alternatively that a lethal mutation gene is activated, mutated or induced by radiation and leads to persistent and random cell death at high levels in the progeny. The aim of this study was to look at the morphology of progeny of irradiated cells at various times after irradiation to establish how widespread morphological abnormalities were in the population and whether there was any evidence that such abnormalities were clonal. Using two different cell lines, the results showed that morphological evidence possibly suggestive of apoptosis occurred in the cultures after all doses of radiation and up to 45 cell doublings after exposure. There was no evidence of a decrease in the numbers of damaged or dead cells in colonies with number of divisions after irradiation, or with decreasing original radiation dose. There was a significant dose-dependent increase in the number of cells with microvilli for both cell lines. The dose-dependency of this effect did not change with number of divisions after irradiation. It is clear that morphological evidence of cellular damage persists for several generations after the initial exposure. The effects are widespread in the cell population, and their constancy over time argues strongly for a general instability and against a clonal mechanism, since clonal descendants should die out and leave undamaged survivors. The lack of evidence for necrosis or senescence together with many morphological changes in the cultures suggestive of apoptosis could indicate an active mechanism of cell death. It is concluded that survivor populations of irradiated cells from two widely different mammalian cell lines demonstrate an altered phenotype including gross morphological changes. These result in a higher probability that cell division will fail to yield two healthy progeny. Received: 22 January 1996 / Accepted in revised form: 24 September 1996     

The death-inducing effect and genomic instability

Exposure to ionizing radiation can induce a heritable change in the unirradiated progeny of irradiated cells. This non-targeted effect of ionizing radiation manifests as genomic instability, and although there is some debate as to the role of genomic instability in the carcinogenic process, it is thought by some to be an early step in radiation carcinogenesis. Although the mechanism of induction of genomic instability is not clearly understood, evidence suggests that secreted factors from irradiated cells may be involved. We have previously identified another non-targeted effect of ionizing radiation, the death-inducing effect. Exposure of unirradiated GM10115 cells to medium from chromosomally unstable clones was generally found to be cytotoxic. However, occasionally cells will survive in medium from unstable clones and can be clonally expanded. The absolute yield of survivors is independent of the initial number of cells plated when cell densities reached 5,000 or more cells/dish. After cytogenetic analysis of the surviving colonies, we found chromosomal instability in three of 40 clones analyzed, while some clones exhibited increased micronucleus frequency and HPRT mutation frequency. These data suggest that our chromosomally unstable GM10115 cells secrete factors that are cytotoxic to the majority of stable, parental cells but are also capable of inducing a heritable change in some of the survivors that can manifest as delayed genomic instability. These results suggest a mechanism whereby instability can be perpetuated through the influences of potentially cytotoxic factors produced by genomically unstable clones.     

The neoplastic transformation of SCID cells by radiation.

Severe combined immunodeficiency (SCID) cells are hypersensitive to killing by ionizing radiation because of deregulation of DNA-dependent protein kinase (DNA-PK) and a concomitant deficiency in the repair of DNA double-strand breaks. The effect of this condition on the neoplastic transformation of SCID fibroblasts, designated SCID 3T1, has been investigated. The spontaneous transformation rate was approximately 2 x 10(-5) at early passages and increased up to approximately 7 x l0(-3) at later passages. The radiation survival curves of transformed cells had thresholds and therefore appeared to be qualitatively similar to the survival curves of C3H 10T(1/2) mouse fibroblast cells, but the initial slopes were steeper. In contrast, per unit dose, SCID cells were more sensitive to transformation than 10T(1/2) cells. Eight transformed clones were tested for tumorigenicity, and all produced fibrosarcomas in athymic nude mice. Properties associated with the tumor suppressor Trp53 (formerly known as p53) were examined in three of the clones. In these clones, although Trp53 protein was overexpressed, a lower expression of Cdkn1a (formerly known as p21, Cip1) protein was observed compared to parental cells. The expression of Trp53 and Cdkn1a and the G(1)-phase arrest (one set of data on G(1)-phase delay is included as an example) was not induced by ionizing radiation in these transformed clones; each clone carried a point mutation in Trp53. This suggests that the deficiency in the repair of DNA double-strand breaks increased the tumorigenicity and the genomic instability of transformed SCID cells.     

Delayed chromosomal instability induced by DNA damage.

DNA damage induced by ionizing radiation can result in gene mutation, gene amplification, chromosome rearrangements, cellular transformation, and cell death. Although many of these changes may be induced directly by the radiation, there is accumulating evidence for delayed genomic instability following X-ray exposure. We have investigated this phenomenon by studying delayed chromosomal instability in a hamster-human hybrid cell line by means of fluorescence in situ hybridization. We examined populations of metaphase cells several generations after expanding single-cell colonies that had survived 5 or 10 Gy of X rays. Delayed chromosomal instability, manifested as multiple rearrangements of human chromosome 4 in a background of hamster chromosomes, was observed in 29% of colonies surviving 5 Gy and in 62% of colonies surviving 10 Gy. A correlation of delayed chromosomal instability with delayed reproductive cell death, manifested as reduced plating efficiency in surviving clones, suggests a role for chromosome rearrangements in cytotoxicity. There were small differences in chromosome destabilization and plating efficiencies between cells irradiated with 5 or 10 Gy of X rays after a previous exposure to 10 Gy and cells irradiated only once. Cell clones showing delayed chromosomal instability had normal frequencies of sister chromatid exchange formation, indicating that at this cytogenetic endpoint the chromosomal instability was not apparent. The types of chromosomal rearrangements observed suggest that chromosome fusion, followed by bridge breakage and refusion, contributes to the observed delayed chromosomal instability.     

Purified HLA class II peptide complexes can induce adherence and activation of peptide-specific human T cell clones.

An initial event in T cell activation is the specific adherence of T cells via their T cell receptor to the MHC peptide complex. We have studied this adherence by incubating T cells with preformed HLA DR4Dw4 peptide complexes attached to a solid support. Adherence of sodium 51Cr-labeled T cell clones specific for the influenza hemagglutinin peptide, HA 307-319, was maximal after 15 min and was specific for the HLA DR4Dw4-HA 307-319 complex. The binding was temperature dependent and could be blocked with azide or protein kinase C inhibitors, indicating that for adherence the T cells need to be metabolically active and have a functioning protein kinase C pathway. The adherence could be blocked with CD4- or CD3-reactive murine mAb, suggesting that the TCR and CD4 molecules work in concert to induce strong adherence to the HLA DR4Dw4-HA 307-319 complex. A subsequent event in T cell activation is proliferation, which is thought to need additional proteins such as IL-1 or other adhesion molecules. MHC peptide complexes coated on microtiter plates also induced proliferation in the human T cell clones. Removal of any monocytes by treatment of human T cell clones with anti-CD14 in conjunction with C, followed by purification over a nylon wool column, did not abrogate proliferation. After prolonged culture of the T cell clones in plates coated with peptide-pulsed HLA DR4Dw4 in the presence of IL-2, the T cell clones continued to proliferate in response to peptide. These results suggest that human T cell clones do not require a second signal from a monocyte or other APC to proliferate.     

Book Reviews

Because the cancerous change in cells appears to be a permanent alteration, handed on to daughter cells through innumerable divisions, it seems probable that it reflects an abnormality in the transfer of information from cell to daughter cells. Transfer of information in cells is believed to depend on their genetic apparatus, and transfer of abnormal information implies that the genetic apparatus is not functioning normally. Abnormalities in genetic material, whether induced by ionizing radiation, chemical compounds or viruses, would, if reproduced at cell division, reappear in daughter cells. If such abnormalities lead to cancerous change in cells, any one of these primary incitants might be effective. Under such circumstances, the nature of the primary incitant may not be the most important question, and definition of the nature of the abnormality in the genetic material may become the central problem. It may ultimately be feasible to explain the cancerous change in cells in chemical terms and to find that it represents a molecular disease which takes its origin from the emergence of abnormal nucleotide sequences in the genetic material. In biological terms this would correspond with an induced mutation which is heritable at the level of the somatic cell.     

Mutation induced clonal markers from polymorphic loci: application to stem cell organisation in the mouse intestine

Marked clones of cells can be induced somatically in intestinal epithelium. The markers are induced by mutation affecting single alleles of polymorphic genetic loci such as Dlb-1 or G6PD whose product can be detected histochemically. Analysis of mutated clones allows the organisation of intestinal stem cells to be investigated. In both small and large bowel the crypts, which contain the intestinal stem cell population, are populated with the progeny of a single cell several times during the life of the mouse. This process could occur by stochastic or hierarchical renewal of cells within the stem cell population.     

Frequency of CD59 mutations induced in human-hamster hybrid A(L) cells by low-dose X-irradiation

Determination of the genotoxic effects of ionizing radiation, especially at low-doses, is of great importance for risk assessment, e.g. in radiological diagnostics. The human-hamster hybrid A(L) cell line has been shown previously to be a well-suited in vitro model for the study of mutations induced by various mutagens. The A(L) cells contain a standard set of hamster chromosomes and a single human chromosome 11, which confers the expression of the human cell surface protein CD59. Using CD59 specific antibodies, cells mutated in the CD59 gene can be detected and quantified by the loss of the cell surface marker. In contrast to previous studies, prior to irradiation we removed spontaneous mutants by magnetic cell separation (MACS) which allows analysis of radiation-induced mutation events only. We exposed A(L) cells to 100kV X-rays at 0.1 to 5Gy. The proportions of X-irradiation-induced CD59(-) mutants were quantified by flow cytometry after immunofluorescence labeling. Between 0.2 and 5Gy the yield of CD59 mutants was a linear function of dose. The molecular analysis of individual CD59-negative clones induced after exposure of 1, 3 and 5Gy of X-ray revealed a dose-dependent linear increase of large deletions (>6Mbp), whereas, point mutations could be seen only in spontaneous CD59 mutants or after low-dose exposure (< or =1Gy). We conclude that the modified A(L) assay presented here is appropriate for detection and quantification of non-lethal DNA lesions induced by low-dose ionizing radiation.     

Human cell transformation in the study of sunlight-induced cancers in the skin of man

Human cell transformation provides a powerful approach to understanding--at the cellular and molecular levels--induction of cancers in the skin of man. A principal approach to this problem is the direct transformation of human skin cells by exposure to ultraviolet and/or near-UV radiation. The frequency of human cells transformed to anchorage independence increases with radiation exposure; the relative transforming efficiencies of different wavelengths implies that direct absorption by nucleic acids is a primary initial event. Partial reversal of potential transforming lesions by photoreactivation suggests that pyrimidine dimers, as well as other lesions, are important in UV transformation of human cells. Human cells can also be transformed by transfection with cloned oncogenes, or with DNAs from tumors or tumor cell lines. Cells treated by the transfection procedure (but without DNA) or cells transfected with DNAs from normal mammalian cells or tissues show only background levels of transformation. Human cells can be transformed to anchorage-independent growth by DNAs ineffective in transformation of NIH 3T3 cells (including most human skin cancers), permitting the analysis of oncogenic molecular changes even in tumor DNAs difficult or impossible to analyze in rodent cell systems.     

Cellular transformation by radiation: Induction,promotion, and inhibition

Mammalian cell cultures offer powerful tools for evaluating qualitatively and quantitatively the oncogenic potential of radiation over a wide range of doses with particular importance at the low dose range that is relevant to human exposure and risk. Our studies have shown that early events in the process of radiation induced transformation in both rodent and human cells requires initial replication for fixation of transformation as a hereditary property of the cells and further clonal expansion for full expression. Early events (fixation) are inhibited by cell–cell contact and high cell density but can be modified at low temperature where repair processes are slowed. Cell–cell contact and communication in tissue organization may be in part responsible for our findings that radiation oncogenesis induced in utero in hamsters is expressed at a lower frequency than that induced in vitro. Quantitative studies carried out on hamster embryo cells indicate that neutrons are more effective in their carcinogenic potential than x-rays but also more toxic, that splitting the dose of x-rays at low doses leads to enhanced transformation, but that at high doses protracted radiation has a sparing effect. At all dose ranges survival was increased by protracting the radiation dose, thus suggesting that different repair processes must be involved for survival and transformation. Similar observations were seen when the protease inhibitor Antipain was found to enhance transformation in rodent and human cells when present at the time of radiation, but was protective when added after radiation. Survival was not modified under any of those conditions, and Antipain did not affect DNA replication and repair. In our qualitative studies, once cells are transformed by radiation, they exhibit a wide range of structural and functional phenotypic changes, some of which are membrane-associated and are expressed within days after induction. Our current studies on nutritional and hormonal influences on radiation transformation indicate the following: Pyrolysate products from broiled protein foods act in synergism with radiation to produce transformation, whereas vitamin A analogs are powerful, preventive agents. Retinoids inhibit both x-ray-induced transformation and its promotion by TPA: these modifications (enhancement by TPA, inhibition by retinoids) are not reflected in sister chromatid exchanges, but are reflected in the level of membrane associated enzymes Na/K ATPase. Whereas retinoids modify late events (expression, promotion), we find that thyroid hormone plays a crucial role in the early phases of radiation and chemically induced transformation. Under hypothyroid conditions no transformation is observed. The addition of triiodothyronine at physiological levels results in a transformation rate that is dose-related. Our recent success in transforming human skin fibroblasts will enable quantitative and qualitative studies of radiation carcinogenesis in a system relevant to man.     

Immortal phenotype of the HeLa variant D98 is recessive in hybrids formed with normal human fibroblasts

Normal human cells such as human diploid fibroblasts (HDF) have a finite proliferative lifespan in culture. Previous studies have shown that the limited lifespan phenotype is dominant in cell hybrids formed by fusion of HDF to at least 23 different kinds of immortal human cells. However, two independent studies reported that hybrid clones formed by the fusion of HDF to the HeLa variant D98 had unlimited division potential. Those results were potentially very important because they implied that a) there is a dominant mechanism for immortalization of human cells in addition to the well-documented recessive mechanism, and b) a dominant mechanism would lend itself to identification of the immortalizing gene. Consequently, we carried out more detailed studies of the behavior of D98 cells in hybrids. Our results indicate that the majority of D98 x HDF hybrid clones exhibit a clear-cut finite proliferative lifespan phenotype. In addition, these hybrid cell populations often give rise to an immortal focus of cells that can be seen to take over the population of mortal cells at the end of their lifespan. This phenomenon reconciles our data with the previous reports of immortal D98 x HDF hybrid clones and leads us to conclude that D98 cells do not express a dominant immortalizing gene.     

A temperature sensitive mutation that reduces mitotic rate inDrosophila melanogaster

Summary A temperature-sensitive cell autonomous mutation ofDrosophila, l(1)ts-1126 (1–16±2), that affects the rate of cell division is described. When mutant animals are exposed to the restrictive temperature of 29°C during the first and second larval stages, the growth rate of the larvae is retarded. A delay in pupariation occurs during which larvae reach their full size, and the resulting flies are normal. When mutant animals are exposed to restrictive temperature during the third larval stage, growth is also retarded but no delay in pupariation occurs, and the resulting flies are reduced in size. Their small size is due in part to a decreased number of cells and in part to a smaller size of the cells.X-ray induced, marked, homozygousl(1)ts-1126 clones in an otherwise normal animal, are smaller in animals exposed to pulses of restrictive temperature when compared to clones in animals kept at permissive temperature of 22°C. Clone size decreases as pulse length increases. Clones on the wing blade induced 24 h after oviposition are smaller than clones induced at 48 h in animals grown at restrictive temperature. This result is interpreted as an inability of the slower dividingl(1)ts-1126 cells to survive when in competition with wildtype cells. The distribution of survivingl(1)ts-1126 clones in gynandromorphs grown at restrictive temperature supports this conclusion.     

Evolutionary dynamics of two related malignant plasma cell lines

Cancer is the consequence of sequential acquisition of mutations within somatic cells. Mutations alter the relative reproductive fitness of cells, enabling the population to evolve in time as a consequence of selection. Cancer therapy itself can select for or against specific subclones. Given the large population of tumor cells, subclones inevitably emerge and their fate will depend on the evolutionary dynamics that define the interactions between such clones. Using a combination of in vitro studies and mathematical modeling, we describe the dynamic behavior of two cell lines isolated from the same patient at different time points of disease progression and show how the two clones relate to one another. We provide evidence that the two clones coexisted at the time of initial presentation. The dominant clone presented with biopsy proven cardiac AL amyloidosis. Initial therapy selected for the second clone that expanded leading to a change in the diagnosis to multiple myeloma. The evolutionary dynamics relating the two cell lines are discussed and a hypothesis is generated in regard to the mechanism of one of the phenotypic characteristics that is shared by these two cell lines.     

Unlimited division potential of precancerous mouse mammary cells after spontaneous or carcinogen-induced transformation.

Serial transplantation of normal mouse mammary gland in young, isogenic hosts results in progressive loss of division potential, and the transplant line is eventually lost. This is interpreted as an expression of senescence at the cell and tissue level, and it inevitably occurs even though experimental conditions for growth are judged to be optimal. An indefinite extension of mammary growth span can be accomplished by transformation of these normal cells into precancerous cell types, which grow as a benign tissue but which may, however, occasionally undergo a second transformation into a malignant carcinoma. All precancerous tissues tested displayed unlimited growth potential, regardless of whether they occurred spontaneously, or were induced by oncogenic viruses or by administration of chemical carcinogens. Precancerous tissues of both ductal and lobuloalveolar morphology grew continuously. These results indicate that release from cell aging, as measured by the acquisition of unlimited growth potential, is associated with the precancerous state per se, and occurs as an early event in the transition from normal to malignant mammary cells.