Immunoglobulin gene expression and DNA methylation in murine pre-B cell lines

DNA modification accompanying immunoglobulin gene expression was examined in various Abelson murine leukemia virus (A-MuLV)-transformed cell lines, which were able to differentiate from the mu- to mu+ stage or to undergo an isotype switch during in vitro culture. The C mu genes were relatively demethylated in the A-MuLV-transformed cell lines examined irrespective of whether or not the C mu genes were expressed. Normal IgM-bearing B cells, as well as a T cell line, also showed a similar DNA methylation pattern and the C mu genes were relatively demethylated. In one of the mu+ clones, however, the expressed C mu gene was heavily methylated. The DNA methylation pattern did not change and remained hypermethylated before and after gamma 2b expression in the two cell lines which underwent class switch to gamma 2b during in vitro culture, suggesting that expression of the gamma 2b gene was not accompanied by demethylation of the C gamma 2b gene. Taken together, these results indicate that DNA demethylation within and around the CH gene may not be necessary for its expression.     

Molecular basis of heavy-chain class switching and switch region deletion in an Abelson virus-transformed cell line.

We demonstrated that a subclone of an Abelson murine leukemia virus-transformed B-lymphoid cell line switched from mu to gamma 2b expression in vitro, by the classical recombination-deletion mechanism. In this line, the expressed VHDJH region and the C gamma 2b constant region gene were juxtaposed by a recombination event which linked the highly repetitive portions of the S mu and S gama 2b regions and resulted in the loss of the C mu gene from the intervening region. An additional recombination event in this subclone involved an internal deletion in the S mu region of the expressed (switched) allele. One end of this deletion occurred very close to the switch recombination point. Despite the recombination-deletion mechanism of switching, the gamma 2b-producing line retained two copies of the C mu gene and two copies of the sequence just 5' to the S gamma 2b recombination point. The possible significance of the retention of these sequences to the mechanism of class switching is discussed.     

Secondary genomic rearrangement events in pre-B cells: VHDJH replacement by a LINE-1 sequence and directed class switching.

We describe rearrangement events which alter expression from a productive VHDJH rearrangement in an Abelson murine leukemia virus-transformed pre-B cell line. One such rearrangement results in replacement of the initially expressed variable region gene by a site-specific join between the open reading frame of a LINE-1 repetitive element and a remaining JH segment. We discuss this event in the context of the 'accessibility' model of recombinase control, and with respect to similar rearrangements involved in oncogene activation. In another subclone of the same pre-B cell line, altered heavy chain expression resulted from a mu to gamma 2b class switch recombination which occurred by a recombination-deletion mechanism but involved a complex inversion. We provide evidence that the germline gamma 2b region is specifically expressed in pre-B cell lines and early in normal development. We propose that the predisposition of pre-B cell lines to switch to gamma 2b production may reflect a normal physiological phenomenon in which the switch event is directed by an increased 'accessibility' of the germline gamma 2b locus to switch-recombination enzymatic machinery. Our findings support the hypothesis that the apparently distinct recombination systems involved in variable region gene assembly and heavy chain class switching are both directed by the accessibility of their substrate gene segments.     

In vitro transformation of murine pre-B lymphoid cells by Snyder-Theilen feline sarcoma virus

Snyder-Theilen feline sarcoma virus (ST-FeSV) codes for a protein kinase with specificity for tyrosine residues (Barbacid et al., Proc. Natl. Acad. Sci. U.S.A. 77:5158-5163, 1980), properties analogous to those of the transforming gene product of Abelson murine leukemia virus (Witte et al., Nature (London) 283:826-831, 1980). In the present report, ST-FeSV was demonstrated to transform murine hematopoietic cells under in vitro assay conditions which detect lymphoid cell transformation by Abelson murine leukemia virus. Bone marrow colony formation was shown to require ST-FeSV, follow single-hit kinetics, and require the presence of mercaptoethanol in the agar medium. ST-FeSV-induced colonies could be established in culture as continuous cell lines that demonstrated unrestricted self-renewal capacity and leukemogenicity in vivo. The hematopoietic blast cells transformed by ST-FeSV in culture appeared to be at an early stage of B cell differentiation. They possessed Lyb 2 surface antigens, were dependent on mercaptoethanol for growth, and contained only low levels of terminal deoxynucleotidyl transferase. Moreover, a large fraction of the lines synthesized immunoglobulin mu chain in the absence of light chains. Thus, the phenotype of ST-FeSV hematopoietic transformants was indistinguishable from that of the pre-B lymphoblast transformants induced by Abelson murine leukemia virus. These findings indicate that the in vitro functional similarities in the onc gene products of ST-FeSV and Abelson murine leukemia virus may reflect a common pathway by which they exert their oncogenic potential.     

Thymocyte subsets transformed by Abelson murine leukemia virus.

The infectious complex of Abelson murine leukemia virus was altered by replacing its usual helper virus, Moloney leukemia virus, with radiation leukemia virus (RadLV). After intrathymic injection of the Abelson-RadLV complex, thymomas arose rapidly, as described previously for injection of the Abelson-Moloney complex. Cell lines were derived from thymomas induced by each Abelson virus complex and were classified according to normal thymus cell phenotypes. Each virus complex induced some cell lines which were like a 0.7% subpopulation of murine thymocytes in that they failed to express the Thy-1 cell-surface antigen. These lines are thus far indistinguishable from some Abelson-derived bone marrow transformants classified as pre-B cells. However, the Abelson-Moloney complex induced some cell lines which expressed low levels of Thy-1 and which shared most markers with immature blast cells of the thymic medulla, whereas the Abelson-RadLV complex induced some lines which were clearly like thymic cortex blast cells. Thus, Abelson virus can induce thymoma cell lines of at least two, and possibly three, distinct phenotypes corresponding to normal thymocyte blast subsets, the determination of which can be influenced by helper virus sequences.     

Class-switching from mu to gamma 3 or gamma 2b production at pre-B cell stage

An Abelson virus-transformed murine pre-B cell line class-switched from mu to gamma 3 or gamma 2b at the pre-B stage during culture. A class-switch was mediated by the deletion mechanism of the intervening CH genes on the active chromosome. This study showed for the first time that class-switching at the pre-B cell stage was not always confined to gamma 2b production.     

Immature B cells can pass through a VHDJH/germ line state in the Ig H chain gene rearrangements

SPL2-1-2, an Ig- murine immature B cell line, was established by the infection of immature B cells with tsOS-59, a temperature-sensitive mutant of Abelson murine leukemia virus. Southern blot and DNA cloning and sequencing analysis showed that SPL2-1-2 had a nonproductive VHQ52.DSP2.JH3 and a germ line (G) allele (VHDJH-/G), and that D to JH joinings followed by VH to DJH joinings progressed on the G allele during culture. These results indicated the existence of novel pathway of IgH gene rearrangements: G/G----DJH/G----VHDJH/G----VHDJH/DJH----VHDJH /VHDJH. This also implied that whether DJH/G state progressed to DJH/DJH or VHDJH/G state was stochastically determined, but not strictly controlled in an ordered fashion, although DJH/G state progressed more preferentially to DJH/DJH state than to VHDJH/G state.     

Abnormal recombination of Igh D and J gene segments in transformed pre-B cells of scid mice

Studies of Ig and TCR genes in transformed lymphocytes of scid mice have revealed aberrant DNA rearrangements. Here we present a more detailed analysis of the Igh gene recombination in nine scid pre-B cell lines transformed by Abelson murine leukemia virus. We found 85% of the rearranged Igh alleles to contain abnormal Dh-Jh deletions of varying size. All of these deletions encompassed Jh elements and extended into the Igh enhancer region, occasionally involving the switch (S) region of the C mu gene. Some of these rearrangements removed most of the Dh elements, but none appeared to extend to the Vh genes. DNA sequence analysis of the two abnormally rearranged Igh alleles in one pre-B cell line showed that no Dh or Jh coding sequences were retained at the recombination sites though heptamer-like (CACTGTG) recognition signal sequences were present in the absence of nonamer (GGTTTTTGT) recognition signal sequences. These results imply that a deregulated recombinase activity may be responsible for the abnormal Dh-Jh deletions and the absence of Vh-Dh joining in established lines of Abelson murine leukemia virus-transformed scid pre-B cells.     

Identification of a common helper provirus integration site in Abelson murine leukemia virus-induced lymphoma DNA.

Abelson murine leukemia virus induces oligoclonal pre-B lymphoma in mice. The expression of the v-abl oncogene in target cells does not appear to be sufficient for tumor induction in several mouse strains, and additional genetic events are thought to be required. We postulated that the helper Moloney murine leukemia virus might induce these events, and its potential role as an insertional mutagen was assessed by the search of a common helper provirus integration site in Abelson murine leukemia virus lymphomas. Molecular cloning of cellular sequences adjacent to Moloney proviruses enabled us to identify a cellular region, designated Ahi-1, which was found occupied by the helper proviruses in 16% of Abelson pre-B-cell lymphomas. All proviruses for which the precise integration site within Ahi-1 could be mapped were found to be in the same orientation. Ahi-1 has been mapped to mouse chromosome 10 and represents a new common proviral integration site. These data suggest that the helper virus contributes to the induction of secondary genetic events which may be important for the development of Abelson murine leukemia virus-induced pre-B-cell lymphoma.     

p53 Mediates Apoptotic Crisis in Primary Abelson Virus-Transformed Pre-B Cells

Transformation of pre-B cells by Abelson murine leukemia virus (Ab-MLV) involves a balance between positive, growth-stimulatory signals from the v-Abl oncoprotein and negative regulatory cues from cellular genes. This phenomenon is reflected by the clonal selection that occurs during Ab-MLV-mediated transformation in vivo and in vitro. About 50% of all Ab-MLV-transformed pre-B cells express mutant forms of p53 as they emerge from this process, suggesting that this protein may play an important role in the transformation process. Consistent with this idea, expression of p19(Arf), a protein whose function depends on the presence of a functional p53, is required for the apoptotic crisis that characterizes primary Ab-MLV transformants. To test the role of p53 in pre-B-cell transformation directly, we examined the response of Trp53(-/-) mice to Ab-MLV. The absence of p53 shortens the latency of Abelson disease induction but does not affect the frequency of cells susceptible to Ab-MLV-induced transformation. However, primary transformants derived from the null animals bypass the apoptotic crisis that characterizes the transition from primary transformant to fully malignant cell line. These effects do not require p21(Cip-1), a major downstream target of p53; however, consistent with a role of p19(Arf), transformants expressing mutant p53 and abundant p19 retain wild-type p19 sequences.     

Conservation of function of Drosophila melanogaster abl and murine v-abl proteins in transformation of mammalian cells.

The Drosophila melanogaster abl and the murine v-abl genes encode tyrosine protein kinases (TPKs) whose amino acid sequences are highly conserved. To assess functional conservation between the two gene products, we constructed Drosophila abl/v-abl-chimeric Abelson murine leukemia viruses. In these chimeric Abelson murine leukemia viruses, the TPK and carboxy-terminal regions of v-abl were replaced with the corresponding regions of D. melanogaster abl. The chimeric Abelson murine leukemia viruses were able to mediate morphological and oncogenic transformation of NIH 3T3 cells and were able to abrogate the interleukin-3 dependence of a lymphoid cell line. We also found that a virus that contained both TPK and carboxy-terminal Drosophila abl regions had no in vitro transforming activity for primary bone marrow cells and lacked the ability to induce tumors in susceptible mice. A virus that replaced only a portion of the v-abl TPK region with that of Drosophila abl had low activity in in vitro bone marrow transformation and tumorigenesis assays. These results indicate that the transforming functions of abl TPKs are only partially conserved through evolution. These results also imply that the TPK region of v-abl is a major determinant of its efficient lymphoid cell-transforming activity.     

Functional macrophage cell lines transformed by Abelson leukemia virus.

Three cloned cell lines have been established from murine tumors induced with Abelson leukemia virus which express properties of macrophages. Two of the three original tumors in addition yielded lymphocyte cell lines, one typical of the Abelson virus disease and the other a thymic lymphoma. Two of the macrophage lines are tumorigenic when placed in syngeneic mice. All of the macrophage lines pinocytose neutral red, phagocytose zymosan and latex beads, mediate antibody-dependent killing and phagocytosis of sheep erythrocyte targets, and secrete high levels of lysozyme. None of these properties was exhibited by the lymphocyte lines. Of the two macrophage cell lines tested, neither was capable of replacing the adherent cell population required for the induction of in vitro immune responses. An agent that activates normal macrophages, bacterial lipopolysaccharide, specifically inhibits the growth of the transformed macrophages in culture. Secretion of infectious Abelson leukemia virus by two of the macrophage lines, RAW 309Cr and WR 19M, provides conclusive evidence that the Abelson virus is capable of productively infecting the macrophage cell type. The other macrophage line, RAW 264, fails to secrete detectable virus particles and is negative in the XC plaque formation assay, as well as the fibroblast transformation assay for Abelson virus, but becomes positive for Abelson virus production after rescue by Moloney leukemia virus.     

Abelson virus transformation of an interleukin 2-dependent antigen-specific T-cell line.

Abelson murine leukemia virus (A-MuLV) carries the gene v-abl, one of a group of oncogenes with structural and functional (tyrosine kinase) homology to three growth factor receptors. Work in this and other laboratories has shown that A-MuLV infection can render myeloid and lymphoid cells independent of the growth factors interleukin 3 and granulocyte-macrophage colony-stimulating factor. We have now shown that v-abl can also relieve interleukin 2 (IL-2) dependence in T cells. We infected a cloned IL-2-dependent antigen-specific cell line. Transformed cells were generated which were factor independent and tumorigenic. The transformants each bore unique v-abl DNA inserts and expressed v-abl mRNA. No elevation of expression of either IL-2 or its receptor could be detected in these cells. Thus, A-MuLV can short-circuit the dependence of hematopoietic cells on IL-2, IL-3, and possibly granulocyte-macrophage colony-stimulating factor, none of whose receptors are known to be of the tyrosine kinase type.     

Different genes control the susceptibility of mice to Moloney or Abelson murine leukemia viruses.

The susceptibility of mice to lymphoma induction by Moloney or Abelson murine leukemia virus has been compared in BALB/c, C57BL/6, and BALB/cXC57BL/6 recombinant inbred strains. BALB/c mice were found to be susceptible to lymphoma induction by either virus, and C57BL/6 mice were found to be relatively resistant to lymphoma induction by either virus. The genes that control these patterns of susceptibility to each virus are not the same because susceptibility to each virus segregated independently in CXB recombinant inbred strains. We also found, as reported by Cook (W. Cook, Proc. Natl. Acad. Sci. U.S.A. 79:2917-2921, 1982), when injected intrathymically that Abelson murine leukemia virus rapidly induced thymomas in weanling B6 mice. Examination of the cellular phenotypes of the tumors induced by Abelson murine leukemia virus or by Moloney murine leukemia virus indicated that different lymphocyte subpopulations were the targets for tumor induction by each virus.     

Abelson murine leukemia virus mutants deficient in kinase activity and lymphoid cell transformation.

Abelson murine leukemia virus transforms both lymphoid cells and fibroblasts in vitro and induces a unique type of thymus-dependent lymphoma in vivo. Four fibroblast-transforming strains of Abelson murine leukemia virus were identified, based on the sizes of the Abelson murine leukemia virus-specific phosphoproteins produced by these isolates. Two of these strains, the standard P120- and the P160-producing viruses, transformed lymphoid cells efficiently in vitro and induced Abelson disease in vivo. Two other strains, which synthesized small Abelson murine leukemia virus-specific proteins with molecular weights of 90,000 (P90) and 100,000 (P100), transformed lymphoid cells very poorly both in vitro and in vivo. The reduced oncogenic potentials of these isolates were correlated with a high level of synthesis of fairly unstable P90 and P100. In addition, neither P90 nor P100 functional efficiently in protein kinase assays. The correlation of abnormal metabolism and deficient protein kinase activity with the reduced oncogenic potentials of these virus strains supported a direct role for these proteins and the kinase activity in transformation. Furthermore, these results suggested that the requirements for lymphoid cell transformation and fibroblast transformation are different.     

Activation of the c-abl oncogene by viral transduction or chromosomal translocation generates altered c-abl proteins with similar in vitro kinase properties.

The v-abl protein of Abelson murine leukemia virus is a tyrosine-specific kinase. Its normal cellular homolog, murine c-abl, does not possess detectable tyrosine kinase activity in vitro. Previously, we have detected tyrosine kinase activity in vitro for an altered c-abl gene product (c-abl P210) in the K562 human chronic myelogenous leukemia cell line. The expression of this variant c-abl gene product correlates with chromosomal translocation and amplification of the c-abl gene in K562 cells. Like v-abl, c-abl P210 is a fusion protein containing non-abl sequences near the amino terminus of c-abl. We compared the in vitro tyrosine kinase activity of c-abl P210 with that of wild-type murine v-abl. The remarkable similarities of these two proteins with respect to cis-acting autophosphorylation, trans-acting phosphorylation of exogenous substrates, and kinase inhibition, using site-directed abl-specific antisera, suggested that c-abl P210 could function similarly to v-abl in vivo. In addition, c-abl P210 possessed an associated serine kinase activity in immunoprecipitates. The serine kinase activity was not inhibited by site-directed, abl-specific antisera that inhibit the tyrosine kinase activity, suggesting that the serine kinase activity is not an intrinsic property of c-abl P210. Thus, the activation of the c-abl gene in a human leukemia cell line may have functional consequences analogous to activation of the c-abl gene in Abelson murine leukemia virus.     

Novel recombinations of the IG kappa-locus that result in allelic exclusion

Allelic exclusion of Ig H and L chain gene loci serves to ensure that a B cell expresses a single specificity antibody. The analysis of Abelson murine leukemia virus transformed cells that rearrange the kappa-locus during growth in cell culture has provided the opportunity to characterize intermediate steps in Ig gene rearrangement. By sequential cloning of an Abelson murine leukemia virus transformed cell line we have observed a novel two-step pathway that results in a rearrangement of a V kappa gene segment into the J-C kappa intron. This type of rearrangement effectively excludes functional kappa expression from that allele. A truncated mRNA product resulting from the V kappa signal exon splicing to the C kappa exon is diagnostic of these unique rearrangements. In addition to demonstrating a novel mechanism for allelic exclusion, the two-step pathway described serves to explain how V-intron recombination products were generated in previously described cell lines.