We have constructed the physical map of the 0.8 megabase DNA fragment which contains the 3' 64 variable region (V) gene segments of the human immunoglobulin heavy chain (H) locus. The organization of the VH locus showed several features that indicate dynamic reshuffling of this locus. The sequenced 64 VH segments include 31 pseudogenes, of which 24 are highly conserved except for a few point mutations. Comparison of the 64 germline VH sequences shows that each VH family has conserved sequences, suggesting that there might be some genetic or selection mechanisms involved in maintenance of each family. The total number of the human VH segments was estimated to be about 120, including at least 7 orphons.
DNA-dependent protein kinase (DNA-PK) is utilized in both DNA double-strand break repair (DSBR) and V(D)J recombination, but the mechanism by which this multiprotein complex participates in these processes is unknown. To evaluate the importance of DNA-PK-mediated protein phosphorylation in DSBR and V(D)J recombination, we assessed the effects of the phosphatidyl inositol 3-kinase inhibitor wortmannin on the repair of ionizing radiation-induced DNA double-strand breaks and V(D)J recombination in the V(D)J recombinase inducible B cell line HDR37. Wortmannin radiosensitized HDR37, but had no affect on V(D)J recombination despite a marked reduction in DNA-PK activity. On the other hand, studies with mammalian expression vectors for wild-type human DNA-PK catalytic subunit (DNA-PKcs) and a kinase domain mutant demonstrated that only the kinase active form of DNA-PKcs can reconstitute DSBR and V(D)J recombination in a DNA-PKcs-deficient cell line (Sf19), implying that DNA-PKcs kinase activity is essential for both DSBR and V(D)J recombination. These apparently contradictory results were reconciled by analyses of cell lines varying in their expression of recombinant wild-type human DNA-PKcs. These studies establish that minimal DNA-PKcs protein levels are sufficient to support V(D)J recombination, but insufficient to confer resistance to ionizing radiation.
We have constructed the physical map of the 3′ region of the human immunoglobulin heavy chain variable region (VH) genes. DNA segments extending to 200 kb upstream of the JH segment were isolated in two YAC clones. Five VH segments were identified in this region in the 5′ to 3′ order, V(II‐5), V(IV‐4), V(I‐3), V(I‐2), and V(VI‐1) segments which were all structurally normal and orientated in the same direction as the JH segments. From DNA of a different cell line we have isolated a cosmid contig containing the same DNA region which has extraordinary polymorphism. The YAC and cosmid DNAs were called haplotypes A and B, respectively. Haplotype B contained an additional VH‐I segment (V(I‐4.1b)) between the V(II‐5) and V(IV‐4) segments. V(I‐4.1b) segment is almost identical to a previously published VH sequence encoding a rheumatoid factor. Another VH segment in the B haplotype (V(I‐3b)) corresponding to the V(I‐3) segment also showed 99.7% nucleotide sequence homology with an anti‐DNA autoantibody VH sequence. However, none of the VH sequences in haplotype A showed such strong homology with autoantibody VH sequences. The results suggest that VH haplotypes may have linkage with autoantibody production.
Two major DNA double-strand break repair pathways exist in all eukaryotes, nonhomologous DNA end joining (NHEJ) and homologous recombination (HR). Although both pathways can function throughout the cell cycle, NHEJ predominates in G0͞G1 (when a replicated sister chromatid is unavailable), whereas HR makes a more substantial contribution in S and G2. How a cell chooses between these two important DNA repair pathways is largely unknown. DNA-dependent protein kinase (DNA-PK) is critical for NHEJ. Here, we describe two conserved splice variants of a catalytic subunit of DNA-PK (DNA-PKcs) that are expressed predominately in nondividing cells. Although both encode stable products, neither reverses the NHEJ defects in DNA-PKcs-deficient cells. In fact, cells expressing one of the DNA-PKcs variants are slightly more radiosensitive than cells completely deficient in DNA-PKcs. We investigated whether cells expressing the DNA-PKcs variants had any other DNA repair deficits and found that these cells are considerably more sensitive to both etoposide and mitomycin C than cells that express no DNA-PKcs at all. Because repair of DNA damage induced by these two agents requires intact HR, we tested whether the NHEJ-defective variants of DNAPKcs inhibit double-strand break-induced HR in an integrated substrate. In cells expressing the NHEJ-defective variants, HR was markedly reduced. Because the splice variants are expressed highly only in nondividing cells, quiescent cells would be afforded a mechanism to inhibit repair by means of HR when sister chromatids are not available as templates for accurate repair with low risk of genome rearrangement, thereby enhancing genome stability.DNA repair ͉ DNA-dependent protein kinase ͉ nonhomologous DNA end joining pathway
We have studied the organization of variable region (V) genes of the human immunoglobulin heavy chain (H) by cosmid cloning. We isolated two independent immunoglobulin D5 clusters (D5‐a and D5‐b) from cosmid libraries of the human genome. Restriction maps of these two regions showed that downstream 15 kb portions of the 55 kb overlap were different although upstream 40 kb portions were almost identical. Four more D segments, (DM, DXP, DA and DK) were found around the D5 segment in the conserved region of each cluster. Nucleotide sequences of the corresponding D segments from each cluster were almost identical and they encoded potentially functional D regions. Analysis using human‐rodent somatic cell hybrids demonstrated that both clusters were located in the immunoglobulin heavy chain (H) locus on chromosome 14, suggesting that the D5‐a and D5‐b regions evolved by internal duplication within this locus. We also isolated a 60 kb DNA region carrying four VH segments, designated as VH‐F region, which was located on chromosome 16. Nucleotide sequences of the four VH segments were determined. Two of them encoded potentially functional VH segments, and the other two were pseudogenes. Some more VH segments were found to be located outside chromosome 14, by Southern blot hybridization of human‐rodent hybrid cell DNAs. These results provide further evidence that the human VH locus has undergone recent reorganization.
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