Point mutation in essential genes with loss or mutation of the second allele: relevance to the retention of tumor-specific antigens.

Antigens that are tumor specific yet retained by tumor cells despite tumor progression offer stable and specific targets for immunologic and possibly other therapeutic interventions. Therefore, we have studied two CD4(+) T cell-recognized tumor-specific antigens that were retained during evolution of two ultraviolet-light-induced murine cancers to more aggressive growth. The antigens are ribosomal proteins altered by somatic tumor-specific point mutations, and the progressor (PRO) variants lack the corresponding normal alleles. In the first tumor, 6132A-PRO, the antigen is encoded by a point-mutated L9 ribosomal protein gene. The tumor lacks the normal L9 allele because of an interstitial deletion from chromosome 5. In the second tumor, 6139B-PRO, both alleles of the L26 gene have point mutations, and each encodes a different tumor-specific CD4(+) T cell-recognized antigen. Thus, for both L9 and L26 genes, we observe "two hit" kinetics commonly observed in genes suppressing tumor growth. Indeed, reintroduction of the lost wild-type L9 allele into the 6132A-PRO variant suppressed the growth of the tumor cells in vivo. Since both L9 and L26 encode proteins essential for ribosomal biogenesis, complete loss of the tumor-specific target antigens in the absence of a normal allele would abrogate tumor growth.

Enhanced growth of primary tumors in cancer-prone mice after immunization against the mutant region of an inherited oncoprotein.

One major objective of tumor immunologists is to prevent cancer development in individuals at high risk. (TG.AC x C57BL/6)F1 mice serve as a model for testing the feasibility of this objective. The mice carry in the germline a mutant ras oncogene that has an arginine at codon 12 instead of glycine present in the wild-type, and after physical (wounding) or chemical promotion, these mice have a high probability for developing papillomas that progress to cancer. Furthermore, F1 mice immunized with Arg(12) mutant ras peptide in complete Freund's adjuvant (CFA) develop T cells within 10 d that proliferate in vitro on stimulation with the Arg(12) mutant ras peptide. Within 14 d, these mice have delayed-type hypersensitivity to the peptide. Immunization with CFA alone or with a different Arg(12) mutant ras peptide in CFA induced neither response. To determine the effect of immunization on development of tumors, mice immunized 3 wk earlier were painted on the back with phorbol 12-myristate 13-acetate every 3 d for 8 wk. The time of appearance and the number of papillomas were about the same in immunized and control mice, but the tumors grew faster and became much larger in the mice immunized with the Arg(12) mutant ras peptide. Thus, the immunization failed to protect against growth of papillomas. The peptide-induced CD4(+) T cells preferentially recognized the peptide but not the native mutant ras protein. On the other hand, mice immunized with Arg(12) mutant ras peptide and bearing papillomas had serum antibodies that did bind native mutant ras protein. Together, these studies indicate that active immunization of cancer-prone individuals may result in immune responses that fail to eradicate mutant oncogene-expressing tumor cells, but rather induce a remarkable enhancement of tumor growth.

Transgenic human lambda 5 rescues the murine lambda 5 nullizygous phenotype.

The human lambda 5 (hu lambda 5) gene is the structural homologue of the murine lambda 5 (m lambda 5) gene and is transcriptionally active in pro-B and pre-B lymphocytes. The lambda 5 and VpreB polypeptides together with the Ig mu H chain and the signal-transducing subunits, Ig alpha and Ig beta, comprise the pre-B cell receptor. To further investigate the pro-B/pre-B-specific transcription regulation of hu lambda 5 in an in vivo model, we generated mouse lines that contain a 28-kb genomic fragment encompassing the entire hu lambda 5 gene. High levels of expression of the transgenic hu lambda 5 gene were detected in bone marrow pro-B and pre-B cells at the mRNA and protein levels, suggesting that the 28-kb transgene fragment contains all the transcriptional elements necessary for the stage-specific B progenitor expression of hu lambda 5. Flow cytometric and immunoprecipitation analyses of bone marrow cells and Abelson murine leukemia virus-transformed pre-B cell lines revealed the hu lambda 5 polypeptide on the cell surface and in association with mouse Ig mu and mouse VpreB. Finally, we found that the hu lambda 5 transgene is able to rescue the pre-B lymphocyte block when bred onto the m lambda 5-/- background. Therefore, we conclude that the hu lambda 5 polypeptide can biochemically and functionally substitute for m lambda 5 in vivo in pre-B lymphocyte differentiation and proliferation. These studies on the mouse and human pre-B cell receptor provide a model system to investigate some of the molecular requirements necessary for B cell development.

Pre-B cell receptor-mediated selection of pre-B cells synthesizing functional mu heavy chains.

Ig gene rearrangements could generate V(H)-D-J(H) joining sequences that interfere with the correct folding of a mu-chain, and thus, its capability to pair with IgL chains. Surrogate light (SL) chain might be the ideal molecule to test the capacity of a mu-chain to pair with a L chain early in development, in that only pre-B cells that assemble a membrane mu-SL complex would be permitted to expand and further differentiate. We have previously identified two SL chain nonpairing V(H)81X-mu-chains with distinct V(H)-D-J(H) joining regions. Here, we show that one of these V(H)81X-mu-chains does not rescue B cell development in J(H) knock-out mice, because flow cytometric analysis of bone marrow cells from V(H)81X-mu transgenic J(H) knock-out mice revealed normal numbers of pro-B cells, but essentially no pre-B and surface IgM+ B cells. Immunoprecipitation analysis of transfected pre-B and hybridoma lines revealed that the same mu-chain fails to pair not only with SL chain but also with four distinct kappa L chains. These findings demonstrate that early pre-B cells are selected for maturation on the basis of the structure of a mu-chain, in particular its V(H)-D-J(H) joining or CDR3 sequence, and that one mechanism for this selection is the capacity of a mu-chain to assemble with SL chain. Therefore, we propose a new function of SL chain in early B cell development: SL chain is part of a quality control mechanism that tests a mu-chain for its ability to pair with conventional L chains.

Surrogate light chain-dependent selection of Ig heavy chain V regions.

Bone marrow B cell precursors frequently rearrange the Ig heavy chain variable (VH) gene segment VH81X. It is puzzling, therefore, that mature B cells in adult mice rarely express mu-heavy chains bearing this VH gene segment. We show in this work in transformed pre-B cell lines that two VH81X/mu-chains that differ in their VH-D-JH joining sequences are not assembled covalently with the B cell precursor-specific surrogate light (SL) chain and are not expressed on the cell surface. From these findings, we propose that a B cell precursor clonally expands and proceeds to the next developmental stage only if it expresses a mu-chain with a VH domain that, together with the SL chain, directs the formation of a signal-transducing mu/SL chain membrane complex. Therefore, a checkpoint exists early in B cell development, at which SL chain not only screens B cell precursors for the presence of a full-length mu-chain, but also for a VH domain that promotes the assembly of a mu/SL chain complex.

Sequence of the rabbit glyceraldehyde-3-phosphate dehydrogenase-encoding cDNA.

Two full-length cDNA clones encoding rabbit glyceraldehyde-3-phosphate dehydrogenase (GAPDH) were isolated from a lambda gt10 rabbit spleen cDNA library and sequenced. As predicted from the open reading frame (ORF) in vitro translation of a sense orientation GAPDH cDNA clone yielded a protein product with a molecular mass of 37 kDa. Rabbit GAPDH exhibits a high degree of homology to the mouse, rat, hamster, chicken and human GAPDH on both the nucleotide (nt) and amino acid (aa) levels.

Roles of heavy and light chains in IgM polymerization.

IgM antibodies are secreted as multisubunit polymers that consist of as many as three discrete polypeptides: mu heavy chains, light (L) chains, and joining (J) chains. We wished to determine whether L chains that are required to confer secretory competence on immunoglobulin molecules must be present for IgM to polymerize--that is, for intersubunit disulfide bonds to form between mu chains. Using a L-chain-loss variant of an IgM-secreting hybridoma, we demonstrated that mu chains were efficiently polymerized independent of L chains, in a manner similar to that observed for conventional microL complexes, and that the mu polymers incorporated J chain. These mu polymers were not secreted but remained associated with the endoplasmic reticulum-resident chaperone BiP (GRP78). This finding is consistent with the endoplasmic reticulum being the subcellular site of IgM polymerization. We conclude that mu chain alone has the potential to direct the polymerization of secreted IgM, a process necessary but not sufficient for IgM to attain secretory competence.

Allelic inclusion in the pre-B-cell line 18-81.

In an Abelson-virus-transformed mouse lymphoid cell line with pre-B-cell characteristics, a few cells continuously produce heavy chains from both homologs. Each chain has a different variable region. These cells thereby exhibit allelic inclusion rather than allelic exclusion.

Immunoglobulin heavy-chain class switching in a pre-B cell line is accompanied by DNA rearrangement.

Switching of an Abelson virus-transformed mouse lymphoid cell line from immunoglobulin mu to gamma 2b heavy-chain synthesis in vitro is accompanied by loss of DNA sequences between the JH and C gamma 2b gene segments, and thus cannot be explained by differential RNA processing. The light-chain loci of both mu- and gamma 2b-producing cell clones are in the embryonic configuration, which indicates that class switching can occur in pre-B cells.