Multistage carcinogenesis in murine thymocytes: involvement of oncogenes, chromosomal imbalances and T cell growth factor receptor

An animal model of carcinogenesis has been exploited to analyze the various events involved in carcinogen-induced T cell lymphomagenesis. Two carcinogenic agents, the alkylating agent N-methylnitrosourea (NMU) and ionizing gamma-radiation, induce tumors in C57BL/6J mice that are phenotypically and histologically identical. Are the genetic events similar or different in the T cell tumors produced by these two carcinogenic agents? NMU treatment produced a different spectrum of activated oncogenes from gamma-irradiation. The K-ras oncogene was preferentially activated in all of the NMU-induced tumors, most frequently by a GGT to GAT transition in codon 12. Ionizing gamma-radiation produced two different transforming activities. Approximately half of the radiation-induced tumors contained activated N-ras genes and half contained a novel non-ras transforming activity. Analysis of NMU- and gamma-irradiated treated animals for chromosomal abnormalities showed anomalies early in the disease. Although both agents produce tumors containing trisomy of chromosome 15, the timing of this event appears to be different occurring early in NMU-induced tumors and later in gamma-radiation induced tumors. In addition, a unique marker chromosome consisting of a translocation between chromosomes one and five appears to be involved in the early stages of radiation-induced disease and may be associated with the novel transforming activity detected in these same tumors. Expression of receptors for the T cell growth factor (IL-2R) is similar in both NMU- and gamma-irradiation induced tumors. Changes in the expression of IL-2R on different T cell populations with disease progression may account for thymus dependent and thymus independent phases of malignant T cell growth.     

Activation of K-ras by codon 13 mutations in C57BL/6 X C3H F1 mouse tumors induced by exposure to 1,3-butadiene

1,3-Butadiene has been detected in urban air, gasoline vapors, and cigarette smoke. It has been estimated that 65,000 workers are exposed to this chemical in occupational settings in the United States. Lymphomas, lung, and liver tumors were induced in female and male C57BL/6 X C3H F1 (hereafter called B6C3F1) mice by inhalation of 6.25 to 625 ppm 1,3-butadiene for 1 to 2 years. The objective of this study was to examine these tumors for the presence of activated protooncogenes by the NIH 3T3 transfection and nude mouse tumorigenicity assays. Transfection of DNA isolated from 7 of 9 lung tumors and 7 of 12 liver tumors induced morphological transformation of NIH 3T3 cells. Southern blot analysis indicated that the transformation induced by 6 lung and 3 liver tumor DNA samples was due to transfer of a K-ras oncogene. Four of the 7 liver tumors that were positive upon transfection contained an activated H-ras gene. The identity of the transforming gene in one of the lung tumors has not been determined but was not a member of the ras family or a met or raf gene. Eleven 1,3-butadiene-induced lymphomas were examined for transforming genes using the nude mouse tumorigenicity assay. Activated K-ras genes were detected in 2 of the 11 lymphomas assayed. DNA sequencing of polymerase chain reaction-amplified ras gene exons revealed that 9 of 11 of the activating K-ras mutations were G to C transversions in codon 13. One liver tumor contained an activated K-ras gene with mutations in both codons 60 and 61. The activating mutation in one of the K-ras genes from a lymphoma was not identified but DNA sequence analysis of amplified regions in proximity to codons 12, 13, and 61 demonstrated that the mutation was not located in or near these codons. Activation of K-ras genes by codon 13 mutations has not been found in any lung or liver tumors or lymphomas from untreated B6C3F1 mice. Thus, the K-ras activation found in 1,3-butadiene-induced B6C3F1 mouse tumors probably occurred as a result of genotoxic effects of this chemical. The oncogenes most frequently detected in human pulmonary adenocarcinomas are K-ras genes. Activated K-ras genes have also been found in some human lymphomas. This suggest that activation of K-ras may be important in the induction of human pulmonary adenocarcinomas and lymphomas.(ABSTRACT TRUNCATED AT 400 WORDS)     

Activation of protooncogenes in spontaneously occurring non-liver tumors from C57BL/6 x C3H F1 mice

The C57BL/6 x C3H F1 (hereafter called B6C3F1) mouse is an important animal model for long-term carcinogenesis studies. Maintained under normal laboratory conditions, these mice develop various types of spontaneous tumors during their lifetime. Activated Ha-ras genes have been detected in 66% of spontaneous hepatocellular tumors in the B6C3F1 mouse [Reynolds et al., Science (Washington DC), 237:1309, 1988]. In this study 49 spontaneous non-liver tumors were investigated for oncogene activation by DNA transfection techniques. Of the 49 tumor DNAs analyzed, only 5 yielded multiple foci in the NIH 3T3 focus assay: 2 of 10 pulmonary adenocarcinomas; 0 of 25 lymphomas; 2 of 2 Harderian gland adenomas; 0 of 1 adenocarcinoma of the small intestine; 1 of 6 malignant skin tumors; 0 of 4 hemangiosarcomas; and 0 of 1 lung metastasis of a hepatocellular carcinoma. DNA from six lymphomas which were negative in the NIH 3T3 focus assay were further analyzed for transforming genes by the nude mouse tumorigenicity assay. One of the five lymphomas tested positive with this assay. Southern blot analysis identified five activated ras genes: H-ras in two Harderian gland adenomas; K-ras in one pulmonary adenocarcinoma and in one s.c. adenocarcinoma; and N-ras in one lymphoma. The mutations involved were CG to AT and AT to TA in codon 61 of the Ha-ras genes, GC to AT or TA in codon 12 of the K-ras genes, and a GC to AT mutation in codon 12 of the N-ras gene. Transformant DNA from a pulmonary adenocarcinoma which yielded multiple foci in the transfection assay did not hybridize to DNA probes specific for the K-, H-, and N-ras, raf, neu, and met genes. Thirteen additional tumor DNAs yielded a single focus in the NIH 3T3 transfection assay. The transformant DNAs retransmitted in a second cycle transfection assay. Rearranged and/or amplified raf genes were detected in six of the transformant DNAs. At present we do not know whether these activated raf genes were present in the original tumor DNA. The other seven transformant DNAs did not hybridize with any of the above mentioned specific DNA probes utilized in Southern blot analysis. Unlike liver tumors, the activation of ras protooncogenes is not a frequent event in the development of spontaneous non-liver tumors of the B6C3F1 mouse. The results from this study should aid in understanding the neoplastic development associated with exposure to chemical carcinogens in the B6C3F1 mouse.     

Activation of the K-ras protooncogene in lung tumors from rats and mice chronically exposed to tetranitromethane

Dominant transforming genes were detected in lung tumors from Fischer 344 rats and C57BL/6 X C3H F1 mice chronically exposed by inhalation to tetranitromethane, a highly volatile compound used in several industrial processes. The rat lung neoplasms were classified as adenocarcinomas, squamous cell carcinomas (epidermoid carcinomas), or adenosquamous carcinomas. The mouse lung tumors were classified as papillary adenocarcinomas or adenomas. In both species, the tumors were morphologically similar to lung tumors in humans. The transfection assay using NIH/3T3 mouse fibroblasts detected transforming genes in 74% (14 of 19) of the rat lung tumors and in 100% (4 of 4) of the mouse lung tumors. Southern blot analysis indicated that transforming gene was an activated K-ras protooncogene in both species. The first exon of the K-ras gene in normal DNA and in DNA from two cell lines transformed by tumor DNA was compared by cloning and sequencing the gene. Experiments showed that there was a GC----AT transition in the second base of the 12th codon of the K-ras oncogene in the two transfectant DNAs. Oligonucleotide hybridization indicated that all of the rat and mouse transfectants had this activating lesion. Additional tumor DNA was then tested for the presence of a mutated allele with the GC----AT transition. All of the rat tumors tested and all of the mouse tumors tested had this mutation present. Hybridization using the normal oligonucleotide sequence around the 12th codon indicated that the normal allele was also present in the majority of the tumors, suggesting that the loss of normal allele is not necessary for the development of neoplasia. One rat lung tumor had no normal allele present, possibly suggesting that this tumor could have been in a more advanced stage than the other tumors. This is the first study to detect activated protooncogenes in rodent tumors induced under conditions which mimic human exposure to a chemical in the workplace. Tetranitromethane may exert its carcinogenic action by both activation of the K-ras oncogene and stimulation of cell proliferation by its irritant properties.     

Proto-oncogene activation in liver tumors of hepatocarcinogenesis-resistant strains of mice.

Activation of the ras family of oncogenes occurs frequently in liver tumors of the B6C3F1 mouse, a strain which is highly sensitive to hepatocarcinogenesis. Many other mouse strains are much more resistant to hepatocarcinogenesis; the aim of this study was to determine the frequency and pattern of oncogene activation in spontaneous and chemically induced liver tumors of three such strains, the C57BL/6J, the C57BL/6 x DBA/2 F1 hybrid (B6D2F1) and the C57BL/6 x Balb/c F1 hybrid (B6BCF1). The C57BL/6, DBA/2 and Balb/c strains are all relatively resistant to spontaneous hepatocarcinogenesis (1.5-3.6% of animals develop liver tumors in 2 years); with regard to chemically induced hepatocarcinogenesis the Balb/c is highly resistant, the C57BL/6 has low susceptibility and the DBA/2 has low to moderate susceptibility. The nude mouse tumorigenicity assay was used to search for activated oncogenes in 15 C57BL/6J liver tumors induced by a single neonatal dose of vinyl carbamate (VC, 0.15 mumol/g body weight). Three tumors contained H-ras genes activated by point mutations at codon 61 and one contained a non-ras oncogene. The polymerase chain reaction and allele-specific oligonucleotide hybridization were used to study H-ras mutations in spontaneous and VC-induced tumors from all three strains of mice. The frequency of H-ras codon 61 mutations in tumors induced by 0.15 mumol/g body weight VC in the C57BL/6J mouse (5/37) was similar to that in spontaneous tumors (2/9); surprisingly, tumors induced by a lower dose of VC (0.03 mumol/g body weight) had a higher frequency of H-ras mutations (12/28). The frequencies of H-ras activation detected in VC (0.03 mumol/g body weight)-induced tumors from the two F1 hybrids studied differed markedly. Only one VC-induced B6BCF1 tumor contained a mutated H-ras gene (1/10), whereas the majority of B6D2F1 tumors contained such mutations (23/33). Several spontaneous B6D2F1 liver tumors contained H-ras codon 61 mutations (6/15). Thus, H-ras activation frequency does not determine susceptibility to hepatocarcinogenesis in inbred mice and their F1 hybrids, since a relatively high frequency of H-ras mutations was observed in two resistant strains and a low frequency was found in the other strain.     

Detection of transforming oncogenes in rat colon tumors induced by direct perfusion with N-methyl-N-nitrosourea.

We assayed rat colon tumors induced by N-methyl-N-nitrosourea (MNU) for transforming oncogenes by the NIH 3T3 transfection and nude mouse tumorigenicity assays. Transfection of DNA from 3 of 3 adenomas and 3 of 5 carcinomas induced transformed foci on NIH 3T3 cells. DNA from 2 of 3 primary foci also possessed focus-forming activity, and rat-specific sequences were observed in secondary focus DNAs. Furthermore, NIH 3T3 cells transfected with DNA from a carcinoma and from a primary focus derived from it, both positive in the focus-forming assay, induced tumors in nude mice. We found no evidence for rat H-ras, K-ras, or N-ras sequences in the DNA of any of 16 primary foci derived from 6 rat tumors; thus, in contrast to other animal tumor models induced by MNU, activation of the ras genes does not appear to predominantly occur in MNU-induced rat colon tumors. We also did not observe, in any of these foci, sequences corresponding to the rat neu, raf, fms, met, or hst genes, thus indicating that none of these is the transforming oncogene in our model. These results suggest that an as yet unidentified transforming oncogene may be activated in rat colon tumors induced by MNU.     

Myeloid,B and T lymphoid and mixed lineage thymic lymphomas in the irradiated mouse

Thymic lymphoma is a very common spontaneous and/or induced malignancy in both inbred mice and in transgenic mouse models of human cancer. Although a thymic lymphoma is defined as thymus-dependent T-cell malignancy, diagnostic criteria vary between studies and considerable heterogeneity has been reported. To define and classify the thymic lymphomas that arose in our study of X-irradiated (CBA/HxC57BL/6)F1, F1 backcross and F1 intercross mice, 66 thymic lymphomas were immunogenotyped for immunoglobulin heavy chain (IgH) and T-cell receptor beta (TCRbeta) gene rearrangements, and/or analysed for expression of lineage-specific markers and allelic loss on chromosome 4. The data indicate that 33% of the thymic lymphomas are very similar to mouse radiation-induced acute myeloid (AML) and mixed lineage (IgH(R), TCRbeta(G)) pre-B lympho-myeloid (L-MLs) leukaemias, 33% are mixed lineage (IgH(R), TCRbeta(R)) B/T lymphoid and <33% can be described as single lineage (IgH(G), TCRbeta(R)) T-cell malignancies. As the myeloid and L-ML leukaemias are not thymus-dependent this suggests that a malignant myeloid or pre-B lympho-myeloid cell can colonize the spleen to give an AML or L-ML leukaemia, or can colonize the thymus where TCRbeta gene rearrangement(s) may be induced to give the mixed lineage thymic lymphomas. Thus, assuming the single lineage T-cell thymic lymphomas fulfil the criteria of a thymus-dependent T-cell malignancy, thymic lymphomas are comprised of at least three distinct malignancies.     

Transforming genes from familial adenomatous polyposis patient cells detected by a tumorigenicity assay

We tried to detect oncogenes associated with familial adenomatous polyposis by a tumorigenicity assay in nude mice. One polyp and two peripheral blood lymphocyte DNAs out of 12 samples from patients induced Alu-positive tumors. Lymphocyte DNAs from one of 5 healthy people also showed tumorigenic activity. The transforming genes of polyps from a patient and lymphocytes from a normal person were found to be the human N-ras gene. Since these N-ras genes were amplified in nude mouse tumors and did not show any alterations in the nucleotide sequences around codons 12 and 61, it is likely that the tumors were induced by the amplified normal N-ras genes. The transforming sequences from two patients' lymphocytes did not hybridize with 12 known oncogene probes, suggesting that these two genes are novel oncogenes or genes for which we have not yet examined the homology. One oncogene derived from a patient's lymphocytes was partially cloned and shown to be located on human chromosome 7. This gene did not hybridize with the met and erbB1 genes, which are potential oncogenes located on chromosome 7. These data indicate that this gene is a new oncogene.     

Detection of novel non-ras oncogenes in rat nasal squamous cell carcinomas

Rat nasal squamous cell carcinomas induced by inhalation of three direct-acting alkylating agents yielded DNA containing activated oncogenes with no homology to any member of the ras family. The novel NIH 3T3 transforming oncogenes from tumors induced by beta-propiolactone and methylmethane sulfonate are distinct from each other based on restriction analysis. The gene isolated from beta-propiolactone-induced tumors is between 6 and 9 kb in size. None of the tumors induced by dimethylcarbamyl chloride contained positive DNA in the NIH 3T3 focus assay or in the nude mouse cotransfection assay. The rat nasal tumor model is apparently ideally suited for analysis of the roles of carcinogen and tissue specificity in oncogene activation, especially related to novel (non-ras) transforming oncogenes.     

N-methylnitrosourea—lnduced Ki-ras codon 12 mutations: Early events in mouse thymic lymphomas

N-Methylnitrosourea (NMU)—induced codon 12 Ki-ras mutations were analyzed in premalignant thymic lymphomas from C57BL/6J mice by using a selective polymerase chain reaction amplification strategy. The frequency of codon 12 Ki-ras mutations was 67% (16 of 24) in NMU-treated animals with premalignant stage I disease. Previously, animals with different stages of disease had been analyzed for cytogenetic changes and for mutations in the p53 tumor suppressor gene. The genetic changes observed were early-activating codon 12 G³⁵→A transition mutations of the Ki-ras gene, followed closely by trisomy 15 and infrequent mutation of the p53 gene late in tumor development. The consistent and early detection of Ki-ras mutations in NMU-treated animals but not in untreated controls suggests that the mutations result from direct carcinogen exposure. Alternate pathways of NMU-induced thymic lymphomagenesis were implicated. One pathway involved putative NMU-induced mutations in other, non-ras oncogenes that cooperate with trisomy 15 to produce similar T-cell tumors. The frequency of p53 gene mutations in human and murine T-cell tumors is similar but low. © 1995 Wiley-Liss, Inc.     

Lymphomagenesis in E mu-myc transgenic mice can involve ras mutations

Transgenic mice bearing c-myc driven by the immunoglobulin heavy chain enhancer (E mu) initially exhibit a preneoplastic lymphoproliferative syndrome from which clonal pre-B or B lymphomas develop at random. To investigate whether this transition involves the activation of oncogenes capable of transforming fibroblasts, we transfected DNA from 14 E mu-myc lymphomas into NIH3T3 cells and tested the tumorigenicity of the transfectants in nude mice. By this assay and subsequent direct analysis of the lymphoma mRNA by cDNA cloning or the polymerase chain reaction, two independent E mu-myc lymphomas were shown to contain an N-ras or a K-ras oncogene mutated at codon 61. When incorporated into a recombinant retrovirus, the mutant N-ras allele could collaborate with myc to transform preneoplastic E mu-myc bone marrow pre-B cells. These results indicate that spontaneous mutation of ras genes is one pathway to lymphomagenesis in E mu-myc mice but that many of the lymphomas arise in response to changes that do not register in fibroblasts.     

A new locus for resistance to gamma-radiation-induced thymic lymphoma identified using inter-specific consomic and inter-specific recombinant congenic strains of mice

Mice of the C57BL/6J inbred strain develop thymic lymphomas at very high frequency after acute gamma-irradiation, while mice of several inbred strains derived from the wild progenitor of the Mus spretus species and their F1 hybrids with C57BL/6J appear extremely resistant. Analysis of the genetic determinism of the gamma-radiation-induced thymic lymphoma (RITL) resistance with the help of inter-specific consomic strains (ICS), which carry a single introgressed Mus spretus chromosome on a C57BL/6J genetic background, provide significant evidence for the existence of a thymic lymphoma resistance (Tlyr1) locus on chromosome 19. The subsequent analysis of the backcross progeny resulting from a cross between consomic mice heterozygous for the Mus spretus chromosome 19 and C57BL/6J mice, together with the study of inter-specific recombinant congenic strains (IRCS), suggest that this Tlyr1 locus maps within the D19Mit60-D19Mit40 chromosome interval. In addition to the discovery of a new locus controlling RITL development, our study emphasizes the value of ICS and IRCS for the genetic analysis of cancer predisposition.     

RNA oncovirus expression in N-methyl-N-nitrosourea-induced lymphomas in mice

RNA oncovirus expression was investigated in thymic lymphomas induced by N-methyl-N-nitrosourea (MNU) in (C57BL/6 × DBA/2)F₁(BDF₁) mice. Out of 15 newborn mice injected with 20 mg/kg MNU, five developed thymic tumours of T-cell origin. Virus production of thymic cells from tumorous and normal animals was studied by an infectious center assay. All five tumours released ecotropic (mouse tropic) virus. No xenotropic or dualtropic mink cell focus-inducing virus was found. No virus was obtained from thymus cells taken from six normal mice killed between 83 and 124 days; however, an ecotropic virus was cultured from the thymus of a 134-dayold normal mouse. According to these results, the MNU-induced thymic lymphoma development in BDF₁, mice is accompanied by activation of endogenous ecotropic virus, whereas spontaneous activation also occurs in older mice.     

Defective expression of Notch1 and Notch2 in connection to alterations of c-Myc and Ikaros in gamma-radiation-induced mouse thymic lymphomas

Gamma-radiation-induced thymic lymphomas constitute a heterogeneous group of T-cell lymphomas. Some tumour suppressor genes and oncogenes have been shown to be defective in a fraction of such lymphomas, yet a considerable number of these remain elusive in terms of gene alterations. In the present work we present evidence that gamma-radiation-induced thymic lymphomas in (C57BL/6 J x BALB/c) F1 hybrid mice often exhibit increased levels of Notch1 expression, but, contrary to what was expected, they also exhibit a clearly reduced Notch2 mRNA expression, suggesting a cooperative antagonism of these genes. These results represent the first reported instance for the involvement of Notch2 inactivation in the development of thymic primary tumours while confirming the role of Notch1 as an activated oncogene. Additional analyses revealed that c-Myc over-expression and partial inactivation of Znfn1a1/Ikaros appear to be relevant events some how coupled to alterations in Notch genes inducing these kinds of tumours.     

Detection of infectious centers in C57BL/Ka lymphoid cell populations infected in vitro by the radiation leukemia virus

The cocultivation of nonproducer lymphoma cells derived from a radiation-induced lymphoma of the C57BL/Ka mouse with cultures of lymphoid cell populations from the thymus, spleen, and marrow of the same strain 48 hr after their infection by the C57BL/Ka leukemia viruses permits the detection of infectious centers in these cultures. A quantitative assay is described which allows the estimation in lymphoid cell subpopulations of the numbers of target cells susceptible to productive infection by the thymotropic and leukemogenic viruses of C57BL/Ka mice in vitro. This assay should greatly facilitate the identification and characterization of such target cells.     

Hipk2 cooperates with p53 to suppress γ-ray radiation-induced mouse thymic lymphoma

A genome-wide screen for genetic alterations in radiation-induced thymic lymphomas generated from p53+/- and p53-/- mice showed frequent loss of heterozygosity (LOH) on chromosome 6. Fine mapping of these LOH regions revealed three non-overlapping regions, one of which was refined to a 0.2 Mb interval that contained only the gene encoding homeobox-interacting protein kinase 2 (Hipk2). More than 30% of radiation-induced tumors from both p53+/- and p53-/- mice showed heterozygous loss of one Hipk2 allele. Mice carrying a single inactive allele of Hipk2 in the germline were susceptible to induction of tumors by γ-radiation, but most tumors retained and expressed the wild-type allele, suggesting that Hipk2 is a haploinsufficient tumor suppressor gene for mouse lymphoma development. Heterozygous loss of both Hipk2 and p53 confers strong sensitization to radiation-induced lymphoma. We conclude that Hipk2 is a haploinsufficient lymphoma suppressor gene.     

Analyses of transplanted murine tumors for HSV DNA sequences

Meignier et al. (1986) report the results of exposure of C57BL/6NCr mice to vaginal plugs containing live or inactivated herpes simplex virus 1 or 2 (HSV-1 or HSV-2) or recombinant viruses 5 times a week for up to 114 weeks. Genital organs showing abnormalities were transplanted into nude mice. Of 33 transplants, 13 produced subcutaneous tumors in nude mice and 12 were subsequently transplanted into C57BL/6NCr mice. We report that the DNA extracted from coded tumor tissues of nude mice and from normal viscera of the same rodents did not hybridize with HSV-1 and HSV-2 DNA probes representing the viral genomic regions shown previously to be capable of morphologically transforming cells in culture. The sensitivity of the assays was such that we could detect 0.5 copies of the HSV sequences of complexity equal to or greater than 1 Kbp per cell DNA equivalent. To control for the sensitivity of the assays in the actual hybridizations, the tumor-cell DNA was also hybridized with a beta-globin mouse DNA probe. A striking feature of these control hybridizations was the detection of beta-globin polymorphism in some nude mouse tumors. The beta-globin polymorphism allowed us to conclude that the analyzed tissues contained significant amounts of the tumor cells occurring in the C57BL/6NCr mice.     

Tumor necrosis factor and interferon gamma inhibit the development of radiation-induced thymic lymphomas in C57BL/Ka mice

Recombinant tumor necrosis factor and/or gamma-interferon were injected into C57BL/Ka mice after completion of a whole body split dose irradiation, which usually induces thymic lymphomas in more than 90% of the animals. The survival and the incidence of thymic lymphomas were significantly reduced in the cytokine-injected irradiated mice. The protective effect was similar to that obtained by grafting normal bone marrow cells after irradiation. The mechanisms of lymphoma inhibition by TNF or IFN-gamma are discussed.     

Leukemogenic activity of B-ecotropic C-type retroviruses isolated from tumors induced by radiation leukemia virus (RadLV-RS) in C57BL/6 mice

In addition to the endogenous N-tropic and xenotropic retroviruses in C57BL/6 mice, B-tropic viruses which result from recombination between the endogenous parental viruses have frequently been isolated from old or leukemic animals. A thymotropic B-tropic virus was also isolated after many serial in vivo passages from tumors induced by RadLV initially obtained by Kaplan from radiation-induced thymic lymphosarcomas. Although this agent was shown to be responsible for the capacity of Kaplan RadLV to induce thymic lymphosarcomas (TLS), the oncogenic role of C57BL/6 B-tropic viruses has never been demonstrated. Three B-tropic viruses (T1223/B, T128/B and T98/B) were isolated from Duplan (RadLV-Rs) extract which, like Kaplan isolate, originates from radiation-induced TLS. Whereas thymotropism was retained by Kaplan extract, extra-thymic lymphosarcomas were preferentially induced by RadLV-Rs. Although the B-tropic isolates emerged from recombinational events between the two endogenous parental viruses, their recombination pattern and their biological in vitro properties indicated that each of them was unique. The present experiments demonstrate, firstly, that in no case was an early disease ressembling that induced by RadLV-Rs observed; secondly, that the three viruses induced a high percentage of extra-thymic lymphomas whose latencies always exceeded 400 days; thirdly, that irrespective of the cloned virus a similar pattern of leukemogenesis was observed; fourthly, that B lymphomas predominated over thymic and extra-thymic T or null lymphoma and erythromyeloid leukemias. The injected viruses shortened the latencies and increased the frequency of the spontaneous disease observed in old animals, which suggests that in both cases leukemogenesis may result from closely related mechanisms. Our observation that the leukemic process developed after a shorter latent period in animals injected at 400 days of age than in those injected at birth or at 30 days of age strongly suggests that the injected viruses need to undergo a second recombination with the endogenous viruses expressed in old mice before they are capable of inducing lymphomas. This hypothesis is supported by the result of the transplantation assay. It does not exclude the possibility of an impairment of the immune responsiveness contributed to the accelerated leukemogenesis in old animals. Thymic and extra-thymic T lymphomas occurred preferentially in mice injected at birth, indicating that T-populations present at this age might be necessary for the newly generated T-tropic recombinants to emerge, replicate or find their target cells.     

Evaluation of role of natural killer cells in radiation-induced leukemogenesis in mice

The relationship of the leukemogenic and natural killer (NK)-suppressive effects of fractionated doses of gamma-radiation in mice was studied. A/J mice were relatively resistant; CBA/J, BALB/c, and C57BL/6 were susceptible to both the NK-suppressive and leukemogenic effects, and young (1 mo old) C57BL/6 mice were more susceptible than were 2- and 3-month-old C57BL/6 mice to both effects. Age-dependent susceptibility to radiation-induced leukemogenesis also was observed in C57BL/6 (bg/bg) (beige) mice. No differences in incidence and latent period of lymphoma development were found between C57BL/6 (+/+) and beige mice. Bone marrow cells (BMC) from normal C57BL/6 donors reconstituted the NK reactivity of irradiated C57BL/6 (+/+) or beige recipients and inhibited leukemogenesis. Although BMC of beige donors did not reconstitute the NK reactivity of irradiated C57BL/6 (+/+) or beige recipients, these cells were as efficient for antileukemic protection as were BMC from C57BL/6 (+/+) mice. The bone marrow of irradiated mice contained preleukemia cells that produced leukemias when transplanted iv into recipients preirradiated with 400 R. Inoculation (iv) of spleen cells (SpC) from syngeneic nude mice plus preleukemia bone marrow cells (PBMC) were able to inhibit leukemia formation in the 400 R-irradiated recipients. SpC from beige mice, normal C57BL/6 (+/+) mice, or C57BL/6 (+/+) mice treated with anti-asialo GM1 serum had no influence on the development of leukemia after their transplantation with PBMC.