Chicken IgL gene rearrangement involves deletion of a circular episome and addition of single nonrandom nucleotides to both coding segments

Chicken immunoglobulin light chain (IgL) gene rearrangement has been characterized. Rearrangement of the single variable (VL) segment with the single joining (JL) segment within the chicken IgL locus results in the deletion of the DNA between VL and JL from the genome. This deletion is accomplished by a molecular mechanism in which a precise joining of the IgL recombination signal sequences leads to the formation of a circular episomal element. The circular episome is an unstable genetic element that fails to be propagated during B cell development. Evidence was obtained that the formation of the circular episome is accompanied by the addition of a single nonrandom base to both the VL and JL coding segments. The subsequent joining of the VL and JL segments appears to occur at random, as we observed at least 25 unique V-J junction sequences, 11 of which are out-of-frame. A novel recombination mechanism that accounts for the observed features of chicken IgL gene rearrangement is discussed.     

The Maize Transposable Element Ac Induces Recombination between the Donor Site and an Homologous Ectopic Sequence

The prominent repair mechanism of DNA double-strand breaks formed upon excision of the maize Ac transposable element is via nonhomologous end joining. In this work we have studied the role of homologous recombination as an additional repair pathway. To this end, we developed an assay whereby β-Glucuronidase (GUS) activity is restored upon recombination between two homologous ectopic (nonallelic) sequences in transgenic tobacco plants. One of the recombination partners carried a deletion at the 5' end of GUS and an Ac or a Ds element inserted at the deletion site. The other partner carried an intact 5' end of the GUS open reading frame and had a deletion at the 3' end of the gene. Based on GUS reactivation data, we found that the excision of Ac induced recombination between ectopic sequences by at least two orders of magnitude. Recombination events, visualized by blue staining, were detected in seedlings, in pollen and in protoplasts. DNA fragments corresponding to recombination events were recovered exclusively in crosses with Ac-carrying plants, providing physical evidence for Ac-induced ectopic recombination. The occurrence of ectopic recombination following double-strand breaks is a potentially important factor in plant genome evolution.     

Recombination events near the immunoglobulin Cmu gene join variable and constant region genes, switch heavy-chain expression, or inactivate the locus

Immunoglobulin heavy-chain expression is initiated by recombination between a variable region (VH) gene and one of several joining region (JH) genes located near the mu constant region (Cmu) gene, and the active VH gene can subsequently switch to another CH gene. That the general mechanism for CH switching involves recombination between sites within the JH-Cmu intervening sequence and the 5' flanking region of another CH gene is supported here by Southern blot hybridization analysis of eight IgG- and IgA-secreting plasmacytomas. An alternative model requiring successive VH linkage to similar JH clusters near each CH gene is shown to be very unlikely since the mouse genome appears to contain only one complement of the JH locus and no JH gene was detectable within large cloned sequences flanking germline C gamma 3 and C gamma 1 genes. Thus, VH-JH joining and CH switching are mediated by separate regions of "the joining-switch" or J-S element. In each plasmacytoma examined, the J-S element had undergone recombination within both the JH locus and the switch region and was shown to be linked to the functional CH gene in an IgG3, and IgG1, and three IgA secretors. Both JH joining and CH switching occurred by deletion of DNA. Switch recombination occurred at more than one site within the J-S element in different lines, even for recombination with the same CH gene. Significantly, although heavy-chain expression is restricted to one allele ("allelic exclusion"), all rearranged in each plasmacytoma. Some rearrangements were aberrant, involving, for example, deletion of all JH genes from the allele. Hence, an error-prone recombination machinery may account for allelic exclusion in many plasmacytomas.     

A LINE element is present at the site of a 300-kb deletion starting in intron 10 of the PAX6 gene in a case of familial aniridia

We have identified a 300-kb germline deletion in 11p13 in a family with aniridia but no Wilms’ tumor. Cloning and sequencing of the breakpoint revealed that the deletion starts in intron 10 of the PAX6 gene and removes the C-terminal part of the proline-serine-threonine rich domain, leaving both DNA-binding domains intact. The PAX6 gene is joined head-to-head to a LINE-1 (L1) element. The L1 is truncated at the 3′ end, removing part of ORF2. Sequencing of the L1 element shows that it does not encode a functional transposase and is therefore probably not an active element. These data suggest that the L1 element is normally present at the site of the distal deletion endpoint in 11p13. No extensive sequence homologies are detected at the deletion junction points; however, the PAX6 gene as well as the L1 element have runs of T nucleotides at this position, indicating that the deletion occurred by nonhomologous recombination. Several consensus recognition sequences for topoisomerase I flank the deletion site in both sequences, suggesting an involvement of this enzyme during the deletion-recombination process. Received: 22 November 1995 / Revised: 25 March 1996     

V(D)J recombination coding junction formation without DNA homology: processing of coding termini.

Coding junction formation in V(D)J recombination generates diversity in the antigen recognition structures of immunoglobulin and T-cell receptor molecules by combining processes of deletion of terminal coding sequences and addition of nucleotides prior to joining. We have examined the role of coding end DNA composition in junction formation with plasmid substrates containing defined homopolymers flanking the recombination signal sequence elements. We found that coding junctions formed efficiently with or without terminal DNA homology. The extent of junctional deletion was conserved independent of coding ends with increased, partial, or no DNA homology. Interestingly, G/C homopolymer coding ends showed reduced deletion regardless of DNA homology. Therefore, DNA homology cannot be the primary determinant that stabilizes coding end structures for processing and joining.     

Molecular basis of the Cd36 chromosomal deletion underlying SHR defects in insulin action and fatty acid metabolism

The human insulin resistance syndromes—type 2 diabetes, obesity, combined hyperlipidemia, and essential hypertension—are genetically complex disorders whose molecular basis is largely unknown. The spontaneously hypertensive rate (SHR) is a model of these human syndromes. In the SHR/NCrlBR strain, a chromosomal deletion event that occurred at the Cd36 locus during the evolution of this SHR strain has been proposed as a cause of defective insulin action and fatty acid metabolism. In this study, three copies of the Cd36 gene, one transcribed copy and two pseudogenes, were identified in normal rat strains, but only a single gene in SHR/NCrlBR. Analysis of SHR genomic sequence localized the chromosomal deletion event between intron 4 of the normally transcribed copy of the gene and intron 4 of the second pseudogene. The deletion led to the creation of a single chimeric Cd36 gene in SHR/NCrlBR. The boundaries of the recombination/deletion junction identified within intron 4 were surrounded by long interspersed nuclear elements (LINEs) and DNA topoisomerase I recognition sequences. An 8-bp deletion at the intron 14/exon 15 boundary of the second pseudogene abolishes the putative splice acceptor site and is the cause of an aberrant 3′ UTR previously observed in SHR/NCrlBR. We conclude that in SHR/NCrlBR, the complex trait of insulin resistance and defective fatty acid metabolism is caused by Cd36 deficiency, resulting from a chromosomal deletion caused by unequal recombination. This demonstrates that chromosomal deletions caused by unequal recombination can be a cause of quantitative or complex mammalian phenotypes. Received: 7 September 2001 / Accepted: 3 October 2001     

Homing of a group II intron from Lactococcus lactis subsp. lactis ML3.

Ll.ltrB is a functional group II intron located within a gene (ltrB) encoding a conjugative relaxase essential for transfer of the lactococcal element pRSO1. In this work, the Ll.ltrB intron was shown to be an independent mobile element capable of inserting into an intronless allele of the ltrB gene. Ll.ltrB was not observed to insert into a deletion derivative of the ltrB gene in which the intron splice site was removed. In contrast, a second vector containing a 271-nucleotide segment of ltrB spanning the Ll.ltrB splice site was shown to be a proficient recipient of intron insertion. Efficient homing was observed in the absence of a functional host homologous recombination system. This work demonstrates that the Ll.ltrB intron is a novel site-specific mobile element in lactococci and that group II intron self-transfer is a mechanism for intron dissemination among bacteria.     

T cell receptor beta gene sequences in the circular DNA of thymocyte nuclei: direct evidence for intramolecular DNA deletion in V-D-J joining

We have identified circular DNA containing T cell receptor (TCR) beta gene sequences in mouse thymocytes, thereby providing direct evidence for the intramolecular DNA deletion model of V-D-J joining in TCR beta genes. Two types of excision products of V-D-J joining have been identified. Type I, a circular reciprocal recombinant of normal V-D or D-J joining, contains a 7mer-7mer head-to-head structure expected from an excised product of normal V-D or D-J joining. Type II contains a D beta 2-J beta 1 structure on the circular DNA; the recombination event producing this molecule occurs between an upstream J and a downstream D segment, probably leaving the reciprocal 7mer-7mer structure on the chromosome. Some type I molecules seem to represent excision products of secondary joining after formation of the first D-J or V-D-J structure. The recombination mechanism that generates the circular DNA is discussed.     

Mechanisms of nonhomologous recombination in mammalian cells.

The primary mechanism of nonhomologous recombination in transfected DNA involves breakage followed by end joining. To probe the joining step in more detail, linear simian virus 40 genomes with mismatched ends were transfected into cultured monkey cells, and individual viable recombinants were analyzed. The transfected genomes carried mismatched ends as a result of cleavage with two restriction enzymes, the recognition sites of which are located in the intron of the gene encoding the T antigen. Because the T antigen gene was split by this cleavage, the transfected genomes were inert until activated by cell-mediated end joining. Clonal descendants of the original recombinants were isolated from 122 plaques and were grouped into four classes based on the electrophoretic mobility of the junction fragment. The structures of representative junctions were determined by nucleotide sequencing. The spectrum of nonhomologous junctions analyzed here along with a large number of previously reported junctions suggest that there are two mechanisms for the linkage of DNA molecules: (i) direct ligation of ends and (ii) repair synthesis primed by terminal homologies of a few nucleotides. A paired-priming model of nonhomologous recombination is discussed.     

A DNA replication mechanism for generating nonrecurrent rearrangements associated with genomic disorders

The prevailing mechanism for recurrent and some nonrecurrent rearrangements causing genomic disorders is nonallelic homologous recombination (NAHR) between region-specific low-copy repeats (LCRs). For other nonrecurrent rearrangements, nonhomologous end joining (NHEJ) is implicated. Pelizaeus-Merzbacher disease (PMD) is an X-linked dysmyelinating disorder caused most frequently (60%-70%) by nonrecurrent duplication of the dosage-sensitive proteolipid protein 1 (PLP1) gene but also by nonrecurrent deletion or point mutations. Many PLP1 duplication junctions are refractory to breakpoint sequence analysis, an observation inconsistent with a simple recombination mechanism. Our current analysis of junction sequences in PMD patients confirms the occurrence of simple tandem PLP1 duplications but also uncovers evidence for sequence complexity at some junctions. These data are consistent with a replication-based mechanism that we term FoSTeS, for replication Fork Stalling and Template Switching. We propose that complex duplication and deletion rearrangements associated with PMD, and potentially other nonrecurrent rearrangements, may be explained by this replication-based mechanism.     

Structure of extrachromosomal circular DNAs excised from T-cell antigen receptor alpha and delta-chain loci

Small polydisperse circular (spc) DNA was isolated from mouse thymocytes, fragmented by HindIII digestion and cloned into the vector. Sixty DNA clones were randomly selected from the 10,400 phage library. The average size of insert was one-fifth of the original circular molecule. Twenty spc-DNA clones were homologous to DNA probes derived from T-cell antigen receptor (TCR) alpha-chain loci. We have characterized nine clones by DNA sequencing; they contain new germline sequences of the TCR alpha-chain variable (V alpha) and joining (J alpha) gene segments and the products out of the recombination of a V alpha with a J alpha gene segment. An additional four spc-DNA clones carried a new rearranging gene of the TCR delta-chain that is located between V alpha and J alpha genes. At least nine of 60 DNA clones carried the recombination junction of a heptamer-heptamer head-to-head structure expected from an excised product of V-J joining. This shows that most extrachromosomal circular DNAs in the thymus are formed by a sequence-dependent recombination mechanism. We suggest that a functional T-cell receptor V alpha gene can be constructed by somatic random rearrangements through successive looping-out, excision and deletion.     

Is gene deletion in eukaryotes sequence-dependent? A study of nine deletion junctions and nineteen other deletion breakpoints in intron 7 of the human dystrophin gene

Although large deletions comprise 65% of the mutations that underlie most cases of Duchenne and Becker muscular dystrophies, the DNA sequence characteristics of the deletions and the molecular processes leading to their formation are largely unknown. Intron 7 of the human dystrophin gene is unusually large (110 kb) and a substantial number of deletions have been identified with endpoints within this intron. The distribution of 28 deletion endpoints was mapped to local sequence elements by PCR. The break points were distributed among unique sequence, LINE-1, Alu, MIR, MER and microsatellite sequences with frequencies expected from the frequency of those sequences in the intron. Thus, deletions in this intron are not associated primarily with any one of those sequences in the intron. Nine deletion junctions were amplified and sequenced. Eight were deletions between DNA sequences with minimal homology (0–4 bp) and are therefore unlikely to be products of homologous recombination. In the ninth case, a complex rearrangement was found to be consistent with unequal recombinational exchange between two Alu sequences coupled with a duplication. We have hypothesized that a paucity of matrix attachment regions in this very large intron expanded by the insertion of many mobile elements might provoke a chromatin structure that stimulates deletions (McNaughton et al., 1997, Genomics 40, 294–304). The data presented here are consistent with that idea and demonstrate that the deletion sequences are not usually produced by homologous DNA misalignments.     

The 185/333 gene family is a rapidly diversifying host-defense gene cluster in the purple sea urchin Strongylocentrotus purpuratus

The genome of the purple sea urchin contains numerous large gene families with putative immunological functions. One gene family, known as 185/333, is characterized by extraordinary molecular diversity resulting from single nucleotide polymorphisms and the presence or the absence of 27 large blocks of sequences known as elements. The mosaic composition of elements, known as element patterns, that is present within the members of this gene family is encoded entirely in the second of two exons. Many of the elements correspond to one of six types of repeats that are present throughout the genes. The sequence diversity and variation in element patterns led us to investigate the evolution of the 185/333 gene family. The work presented here suggests that the element patterns are the result of both recombination and duplication and/or deletion of intragenic repeats. Each element is composed of a limited number of similar but distinct sequences, and their distribution among the 185/333 genes suggests frequent recombination within this gene family. Phylogenetic analyses of five 185/333 elements and two regions of the intron were performed using two tests: incongruence length difference and incongruence permutation. Results indicated that each pair of sequence segments was incongruent, suggesting that recombination occurs frequently along the length of the genes, including both the intron and the second exon, and that recombination is not restricted to intact elements. Paradoxically, the high level of similarity among the elements indicated that the 185/333 genes appear to be the result of a recent diversification. These results add to the growing body of evidence suggesting that invertebrate immune systems are not simple and static, but are dynamic and highly complex, and may employ group-specific mechanisms for diversification.     

Characterization of immunoglobulin enhancer deletions in murine plasmacytomas.

We have analyzed enhancer deletions found in murine plasmacytomas by DNA cloning. This analysis revealed that the deletions occurred between the JH region and the switch region, removing the Ig heavy chain enhancer. The loss of the enhancer did not significantly affect the level of heavy chain expression as determined by RNA blots. Nucleotide sequence analysis revealed that there are no characteristic or homologous sequences around the recombination site. Extra nucleotides were found at the recombination sites, in a manner analogous to Ig and T-cell receptor V-D-J joining. The germline JH and switch sequences involved in the deletion were analyzed by the in vitro DNA cleavage system with an endonucleolytic activity purified from mouse fetal liver nuclear extracts. It was found that the germline JH DNA was strongly cleaved at the deletion recombination site.     

A deletion/insertion leading to the generation of a direct repeat as a result of slipped mispairing and intragenic recombination in the factor VIII gene

A deletion/insertion in the human factor VIII gene was found in a patient with severe hemophilia A; 316 bp were removed, viz., those enclosing part of intron 15 and the first 7 bp of exon 16. In addition to the deletion, 6 bp were added to the deletion breakpoints; this resulted in the duplication of an existing 13-bp unit. Thus, an overlapping 13-bp direct repeat was generated at the deletion junction. Moreover, the deleted fragment itself was flanked by two homologous 6-bp sequences, one unit being lost by the deletion. A combination of slipped mispairing during replication and an intragenic recombination is discussed to describe this deletion/insertion process. Received: 4 January 1999 / Accepted: 22 March 1999     

Group II intron-anchored gene deletion in Clostridium

Clostridium plays an important role in commercial and medical use, for which targeted gene deletion is difficult. We proposed an intron-anchored gene deletion approach for Clostridium, which combines the advantage of the group II intron "ClosTron" system and homologous recombination. In this approach, an intron carrying a fragment homologous to upstream or downstream of the target site was first inserted into the genome by retrotransposition, followed by homologous recombination, resulting in gene deletion. A functional unknown operon CAC1493-1494 located in the chromosome, and an operon ctfAB located in the megaplasmid of C. acetobutylicum DSM1731 were successfully deleted by using this approach, without leaving antibiotic marker in the genome. We therefore propose this approach can be used for targeted gene deletion in Clostridium. This approach might also be applicable for gene deletion in other bacterial species if group II intron retrotransposition system is established.     

Deletions extending from a single Ty1 element in Saccharomyces cerevisiae.

Chromosomal rearrangements associated with one Ty1 element in the iso-1-cytochrome c (CYC1) region of Saccharomyces cerevisiae yeast cells were examined. Most of the rearrangements were deletions of the three linked genes, CYC1, OSM1, and RAD7, and resulted from recombination involving the single Ty1 element and a solo delta in the same orientation. These deletions differed by the number of Ty1 elements (zero, one, or two) remaining after deletion and by restriction site heterogeneities associated with these elements. A single Ty1 element remained at the deletion junction point much more frequently than no Ty1. Apparently the Ty1-associated delta element nearer to the solo delta was involved more often in recombination than the more distal Ty1-associated delta element. The restriction site data implicate gene conversion and suggest that site-specific recombination within the deltas, if occurring, is not the only mechanism of delta-delta recombination. Three other rearrangements bore deletions which began at the end of the Ty1 element and extended into regions not bearing Ty1 or delta sequences. Two of these deletions eliminated 7 kilobases of DNA, although they differed by an associated reciprocal translocation. The third involved a deletion of 14.7 kilobases of DNA associated with an overlapping inversion.