Strand breaks without DNA rearrangement in V (D)J recombination

V(D)J recombination of chromosomally integrated, wild-type deletional and inversional substrates occur at similar frequencies with no preference for orientation

Efficient and correct recombination of V(D)J substrates results in the generation of antibodies. The RSS substrates are oriented in two directions with respect to each other: deletional and inversional. Deletional recombination results in the formation of the coding joint and excision of the intervening sequences. Inversional recombination retains all the genomic sequences and forms both a coding joint and a signal joint. A bias for deletional recombination has been characterized with specific loci in vivo and recapitulated in experiments using extrachromosomal substrates. We constructed retroviral substrates of RSS in the deletional and inversional orientation. We introduced the substrates into wild-type and scid pre-B cells and measured the frequency of functional recombination in addition to open/shut recombination. We also mutated the RSSs to determine whether mutated sequences influenced orientation bias. We show that pre-B cells recombine the wild-type substrates at a 1.6 ratio of deletion:inversion. Nonamer mutated substrates recombined with a deletional bias whereas heptamer mutated substrates recombined with an inversional bias. A spacer length mutation and drastic mutations in the RSS abolish all recombination. These results suggest that there is no orientation bias with wild-type RSSs but that orientation bias occurs when RSSs are mutated.

Clonal evolution as judged by immunoglobulin heavy chain gene rearrangements in relapsing precursor-B acute lymphoblastic leukemia

Oligoclonality and ongoing clonal evolution are common features in patients with precursor-B (pre-B) acute lymphoblastic leukemia (ALL), as judged by immunoglobulin heavy chain (IgH) gene rearrangement analysis. These features are considered to be results of secondary rearrangements after malignant transformation or emergence of new tumor clones. In the present study we analyzed the IgH gene rearrangement status in 18 cases with relapsing pre-B ALL using variable heavy chain (V(H)) gene family specific polymerase chain reaction (PCR) amplification and single stranded conformation polymorphism (SSCP) analysis. Clonal IgH rearrangements were displayed in all leukemias but one, and altered rearrangement patterns occurred in five cases (29%), which were selected for detailed nucleotide sequence analysis. In one case, multiple subclones at diagnosis were suggested to be derived from a progenitor clone through joining of different V(H) germline gene segments to a pre-existing D-J(H) complex (V(H) to D-J(H) joining). Evidence for V(H) gene replacement with identical N-sequences at the V(H)-D junction and a common D-J(H) region was observed in one case. Diversification at the V(H)-D junction consisting of heterogeneous N-sequences were observed in one case. This molecular modification of the V(H)-D region could fit a hypothesized "open-and-shut" mechanism. Nevertheless, despite these ongoing events at least one IgH rearrangement remained unchanged throughout the disease in most patients, indicating that the immunoglobulin heavy chain locus can be a suitable marker for detection of minimal residual disease (MRD).

Ku86-deficient mice exhibit severe combined immunodeficiency and defective processing of V(D)J recombination intermediates

Ku is a heterodimeric DNA end binding complex composed of 70 and 86 kDa subunits. Here, we show that Ku86 is essential for normal V(D)J recombination in vivo, as Ku86-deficient mice are severely defective for formation of coding joints. Unlike severe combined immunodeficient (scid) mice, Ku86-deficient mice are also defective for signal joint formation. Both hairpin coding ends and blunt full-length signal ends accumulate. Contrary to expectation, Ku86 is evidently not required for protection of either type of V(D)J recombination intermediate. Instead, V(D)J recombination appears to be arrested after the cleavage step in Ku86-deficient mice. We suggest that Ku86 may be required to remodel or disassemble DNA-protein complexes containing broken ends, making them available for further processing and joining.

Isolation of mammalian cell mutants that are X-ray sensitive, impaired in DNA double-strand break repair and defective for V(D)J recombination

The Chinese hamster lung V79-4 cell line was infected with a Moloney murine leukemia retrovirus and the infected cells were subsequently screened for mutants that were sensitive to X-rays using a toothpicking/96-well replica plating technique. Four independent mutants that were sensitive to X-irradiation (sxi-1 to sxi-4) were isolated from 9000 retrovirally infected colonies. A pulse-field gel electrophoresis (PFGE) assay demonstrated that all of the sxi mutants were impaired in DNA double-strand break (DSB) repair, thus providing a molecular explanation for the observed X-ray sensitivity. Interestingly, additional PFGE experiments demonstrated that for any given X-ray dose all of the mutants incurred more DNA DSBs than the parental V79-4 cell line indicating there may be some inherent fragility to sxi chromosomes. Cross-sensitivity to other DNA-damaging agents including bleomycin, mitomycin C and methyl methanesulfonate indicated that sxi-2, sxi-3 and sxi-4 appear to be specifically hypersensitive to genotoxic agents that cause DNA DSBs, whereas sxi-1 appeared to be hypersensitive to multiple types of DNA lesions. Lastly, in preliminary experiments all of the sxi mutants demonstrated an inability to carry out V(D)J recombination, a somatic DNA rearrangement process required for the assembly of lymphoid antigen receptor genes. Thus, the sxi cell lines have interesting phenotypes which should make them valuable tools for unraveling the mechanism(s) of DNA DSB repair and recombination in mammalian cells.

Complementation of V(D)J recombination defect and X-ray sensitivity of scid mouse cells by human chromosome 8

Cells derived from mice homozygous for the severe combined immune deficiency (scid) mutation exhibit hypersensitivity to ionizing radiation, and defects in DNA double-strand break repair and V(D)J recombination. Using the technique of microcell-mediated chromosome transfer, we have introduced a number of dominantly marked human chromosomes into scid cells to localize the human homolog of the murine scid gene. Analysis of human-scid hybrid clones revealed that the presence of human chromosome 8 partially restored accurate V(D)J recombination and radioresistance to scid cells. Subsequent loss of the human chromosome 8 from human-scid hybrid clones rendered these cells sensitive to gamma-radiation and impaired their ability to catalyse V(D)J recombination. Introduction of chromosomes 2, 14, 16 and 19 that encode other repair genes did not result in the correction of these two scid defects. These observations demonstrate that the human homolog of the mouse scid gene resides on human chromosome 8.

The SCID mouse: relevance as an animal model system for studying human disease

The simultaneous description some 5 years ago of two methods for the partial reconstitution of a human immune system in severe combined immune-deficient (SCID) mice (collectively, human:SCID mice) was met with great enthusiasm. At the time, it was hoped that human:SCID mice would provide experimental animal model systems for studying human disease and the human immune system. Many of these hopes have been borne out. Importantly, the experimental results obtained from these chimeric human/animal studies appear to be relevant to human disease and immune function. In spite of these glowing achievements, the SCID mouse may not represent the optimal experimental system with which to address these questions. The incomplete penetrance ("leakiness") of the scid mutation and the recent discovery that the mutation is not lymphoid specific, but rather affects a general DNA repair pathway, will only serve to complicate the interpretation of already complex biological interactions. Recently other immune-deficient mice have been described that appear to overcome one or both of these problems and thus these mice could represent improved hosts for the adaptive transfer of a human immune system. The current status of the SCID mouse in light of these new findings is discussed.

Mutations in the DNA ligase I gene of an individual with immunodeficiencies and cellular hypersensitivity to DNA-damaging agents

Two missense mutations occurring in different alleles of the DNA ligase I gene, encoding the major DNA ligase in proliferating mammalian cells, were detected in a human fibroblast strain (46BR). These cells exhibit retarded joining of Okazaki fragments during DNA replication and hypersensitivity to a variety of DNA-damaging agents. 46BR was derived from a patient who displayed symptoms of immunodeficiency, stunted growth, and sun sensitivity. A strongly reduced ability of DNA ligase I to form a labeled enzyme-adenylate intermediate correlated with the genetic defect in 46BR cells. The data indicate that human DNA ligase I is required for joining of Okazaki fragments during lagging-strand DNA synthesis and the completion of DNA excision repair.

V(D)J recombination in mouse thymocytes: double-strand breaks near T cell receptor delta rearrangement signals

In the murine T cell receptor delta locus, V(D)J recombination events frequently involve the D2 and J1 elements. Here we report the presence of double-strand breaks at recombination signals flanking D2 in approximately 2% of thymus DNA. An excised linear species containing the sequences between D2 and J1 and a circular product of the joining of D2 and J1 recombination signals were also found. Although broken molecules with signal ends were detected, no species with coding ends could be identified. Observation of these broken molecules in thymus, but not in liver or spleen, provides the first direct evidence for an association between specific cleavage of chromosomal DNA and recombination in mammalian cells, and supports a breakage-reunion model of V(D)J recombination.