Unexpected rearrangement and expression of the immunoglobulin lambda1 locus in scid mice.

In severe combined immunodeficient (scid) mice, V(D)J recombination is severely impaired due to a recessive mutation (scid). Thus, we were surprised to find in this study that Vlambda1-Jlambda1 rearrangement is routinely detectable in scid fetal liver, adult bone marrow, and spleen in the apparent absence of completed VH-DJH and Vkappa-Jkappa rearrangements. Particularly surprising, we found the level of Vlambda1-Jlambda1 rearrangement in scid fetal liver to be comparable to that in fetal liver of wild-type mice. The majority of scid Vlambda1-Jlambda1 rearrangements contained abnormal deletions at the VJ junction, consistent with the known effect of scid. However, approximately 15% of Vlambda1-Jlambda1 rearrangements lacked abnormal deletions. Productive lambda1 transcripts resulting from in-frame rearrangements were readily detectable in scid adult bone marrow and spleen, consistent with our ability to detect lambda1-expressing cells by flow cytometry in the spleens of bcl-2-transgenic scid mice. Strikingly, lambda1 transcripts from individual scid mice often showed VJ junctional sequences with the same recurring palindromic (P) additions of three, four, or five nucleotides. To account for these findings, we suggest that (a) nonhomologous end joining of Vlambda1 and Jlambda1 coding ends in fetal B lineage cells may not be (severely) impaired by scid; (b) recurring P additions in scid lambda1 transcripts may reflect certain molecular constraints imposed by scid on the resolution of Vlambda1 and Jlambda1 hairpin coding ends; and (c), scid lymphocytes with productively rearranged Vlambda1 and Jlambda1 elements may differentiate into recombinase-inactive cells and emigrate from bone marrow to spleen.

Signals transduced by CD3epsilon, but not by surface pre-TCR complexes, are able to induce maturation of an early thymic lymphoma in vitro.

Development of immature CD4-CD8- (double-negative) thymocytes to the CD4+CD8+ (double-positive) stage is linked to productive rearrangement of the TCRbeta locus by signals transduced through the pre-TCR. However, the mechanism whereby pre-TCR signaling is initiated remains unclear, in part due to the lack of an in vitro model system amenable to both biochemical and genetic analysis. In this study, we establish the thymic lymphoma Scid.adh as such a model system. Scid.adh responds to Ab engagement of surface IL-2Ra (TAC):CD3epsilon molecules (a signaling chimera that mimics pre-TCR signaling in vivo) by undergoing changes in gene expression observed following pre-TCR activation in normal thymocytes. These changes include down-regulation of CD25, recombinase-activating gene (RAG)-1, RAG-2, and pTalpha; and the up-regulation of TCRalpha germline transcripts. We term this complete set of changes in gene expression, in vitro maturation. Interestingly, Scid.adh undergoes only a subset of these changes in gene expression following Ab engagement of the pre-TCR. Our findings make two important points. First, because TAC:CD3epsilon stimulation of Scid.adh induces physiologically relevant changes in gene expression, Scid.adh is an excellent cellular system for investigating the molecular requirements for pre-TCR signaling. Second, Ab engagement of CD3epsilon signaling domains in isolation (TAC:CD3epsilon) promotes in vitro maturation of Scid.adh, whereas engagement of CD3epsilon molecules contained within the complete pre-TCR fails to do so. Our current working hypothesis is that CD3epsilon fails to promote in vitro maturation when in the context of an Ab-engaged pre-TCR because another pre-TCR subunit(s), possibly TCRzeta, qualitatively alters the CD3epsilon signal.

V(D)J recombination in peritoneal B cells of leaky scid mice.

Developing lymphocytes in immune-deficient severe combined immunodeficient (scid) mice express a defective recombinase activity and rarely succeed in making an antigen receptor; those cells that do succeed account for the known B and T cell leakiness in this mutant mouse strain. To gain more insight into the nature of the scid defect, we assessed the status of heavy (H) and light (L)k, chain genes in immunoglobulin (Ig)Mk-secreting B cells from the peritoneal cavity of old leaky scid mice, the only lymphoid site where scid B cells have been routinely detected. We found these cells to be unusual in that their nonexpressed H chain alleles were either abnormally rearranged or in germline configuration (wild-type B cells generally show normal rearrangements at both H chain alleles). The VDJH junctions of the expressed alleles showed little or no nontemplated (N) addition, similar to neonatal B cells from wild-type mice. About half of the V(D)J junctions lacking N additions contained nucleotides that could have been encoded by either of the participating coding elements (VDH, DJH, or VJk), indicating that the recombination occurred between short stretches of homology. Unusually long templated (P) additions were seen in both VDJH and VJK junctions, and many recombinations appeared to involve P-based homologies. These findings suggest that: (a) B cell leakiness results from a low frequency of coding joint formation in cells expressing the defective scid recombinase activity; (b) joining of scid coding ends is facilitated when the ends contain short stretches of sequence homology, where in many cases, one of the homologous sequences results from a P addition; and (c) scid peritoneal B cells may arise early in ontogeny.

Scid mouse Pre-B cells with intracellular mu chains: analysis of recombinase activity and IgH gene rearrangements.

Four Pre-B cell clones with intracellular mu chains were recovered from individual leaky scid mice by transformation of bone marrow or peritoneal cells with Abelson murine leukemia virus. Three clones were derived from independent bone marrow cell cultures. These express the defective scid recombinase activity and contain truncated mu chains resulting from abnormal and/or incomplete (D to J only) gene rearrangements. A fourth clone was obtained from a peritoneal cell culture and may represent a revertant. It expresses a recombinase activity indistinguishable from that of wild-type cells; one of its rearranged IgH alleles (VDJ+) encodes a normal size mu chain, the other is non-productively rearranged (VDJ-).

Coding joint formation of endogenous T cell receptor genes in lymphoid cells from scid mice: unusual P-nucleotide additions in VJ-coding joints.

The mouse mutation scid adversely affects the process of VDJ recombination. Attempts to form coding joints, that is, to joint V or D to J gene segments generally fail in developing scid lymphocytes. It has been proposed that the scid mutation results a defective VDJ recombinase system. Here we describe five scid T cell lymphomas containing one or two TcR gamma coding joints each, even though the majority of the multiple TcR gamma chain gene rearrangements and all TcR beta rearrangements in these cells were abnormal with the deletions typically found in scid lymphoid cells. One of the five T cell lymphomas was shown to have an active VDJ recombinase system; however, this activity was defective indicating that the scid phenotype has been retained. We conclude that the scid VDJ recombinase system has not completely lost the ability to form coding joints. P-nucleotide additions of unusual length or composition were found at the junctional border in five of the eight TcR gamma coding joints. This might reflect a defect in the activity of a component of the VDJ recombinase system involved in the generation of P-nucleotide additions. In one of the observed rearrangements, a V gamma 5-J gamma 3 coding joint was formed. This establishes the transcriptional orientation of J gamma 3-C gamma 3 and confirms a previously proposed organization of the TcR gamma genes.