Recombination between kappa chain genetic markers in the mouse

In this study we report the first instance of recombination between kappa chain genetic markers in the mouse. The recombination frequency, 0.45% (95% limits, 0.12–1.61), is similar to that previously found for recombination between the kappa chain locus and the Lyt-2, 3 locus (0.3%, 95% limits, 0.05–1.6), but is relatively low in comparison with that found at the heavy chain locus (0.41–5.4%). Lyt-2, 3-typing of the recombinants permits a partial ordering of the kappa chain and Lyt-2, 3 loci as (Lyt-2, 3, Igk-Ef1) - Igk-Ef2. Light chains controlled by the two kappa markers include the V_k-(ser) subgroup (controlled by Igk-Ef1) and V_k–1 (controlled by Igk-Ef2). One of the recombinants has been recovered in a homozygous state (NAK) and should be suitable for V _k gene mapping studies.Abbreviations C complement - C_H constant region of the Ig heavy chain - CI cytotoxicity index - DNP dinitrophenyl - FMF flow microfluorimetry - IEF isoelectric focusing - IF immunofluorescence - Ig immunoglobulin - KLH keyhole limpet hemocyanin - V_H variable region of the Ig heavy chain - V_k variable region of the Ig kappa chain - V-region variable region     

Targeted disruption of the porcine immunoglobulin kappa light chain locus

Inactivation of the endogenous pig immunoglobulin (Ig) loci, and replacement with their human counterparts, would produce animals that could alleviate both the supply and specificity issues of therapeutic human polyclonal antibodies (PAbs). Platform genetics are being developed in pigs that have all endogenous Ig loci inactivated and replaced by human counterparts, in order to address this unmet clinical need. This report describes the deletion of the porcine kappa (??) light chain constant (C??) region in pig primary fetal fibroblasts (PPFFs) using gene targeting technology, and the generation of live animals from these cells via somatic cell nuclear transfer (SCNT) cloning. There are only two other targeted loci previously published in swine, and this is the first report of a targeted disruption of an Ig light chain locus in a livestock species. Pigs with one targeted C?? allele (heterozygous knockout or ±) were bred together to generate C?? homozygous knockout (?/?) animals. Peripheral blood mononuclear cells (PBMCs) and mesenteric lymph nodes (MLNs) from C?? ?/? pigs were devoid of ??-containing Igs. Furthermore, there was an increase in lambda (??) light chain expression when compared to that of wild-type littermates (C?? +/+). Targeted inactivation of the Ig heavy chain locus has also been achieved and work is underway to inactivate the pig lambda light chain locus.     

A yeast artificial chromosome contig spanning the mouse immunoglobulin kappa light chain locus

 A single contig spanning the entire mouse immunoglobulin kappa light chain (Igk) locus on chromosome 6 has been established using yeast and bacterial artificial chromosome clones. Detailed mapping of the Igk locus indicates that a member of the Igk-V2 gene family, located about 3.5 megabases upstream of the Igk-J-C complex, is the most distal functional Igk-V gene. Sequence analyses of Igk-V genes and anonymous DNA segments provide indications for internal duplications at the 5′ end of the Igk-V locus and identify the likely origin of Igk-V orphon gene clusters located elsewhere in the mouse genome. Received: 17 July 1996 / Revised: 2 September 1996     

Differential accessibility at the kappa chain locus plays a role in allelic exclusion

Gene rearrangement in the immune system is always preceded by DNA demethylation and increased chromatin accessibility. Using a model system in which rearrangement of the endogenous immunoglobulin kappa locus is prevented, we demonstrate that these epigenetic and chromatin changes actually occur on one allele with a higher probability than the other. It may be this process that, together with feedback inhibition, serves as the basis for allelic exclusion.     

Chromatin opening is tightly linked to enhancer activation at the kappa light chain locus

Enhancers play an important role in chromatin opening but the temporal relationship between enhancer activation and the generation of an accessible chromatin structure is poorly defined. Recombination enhancers are essential for chromatin opening and subsequent V(D)J recombination at immunoglobulin loci. In mice, the kappa light chain locus displays an open chromatin structure before the lambda locus yet the same proteins, PU.1/PIP, trigger full enhancer activation of both loci. Using primary B cells isolated from distinct developmental stages and an improved method to quantitatively determine hypersensitive site formation, we find the kappa and lambda recombination enhancers become fully hypersensitive soon after transition to large and small pre-B-II cells, respectively. This correlates strictly with the stages at which these loci are activated. Since these cells are short-lived, these data imply that there is a close temporal relationship between full enhancer hypersensitive site formation and locus chromatin opening.     

The frequency of multiple recombination events occurring at the human Ig kappa L chain locus

Products of Ig kappa L chain gene rearrangement in a variety of human B cell samples were investigated by sequential Southern blot hybridization analysis. By application of four region-specific probes (C kappa, J kappa, U' kappa and kappa de) a complete spectrum of kappa rearrangements, including both predicted and novel products, were detected. Nearly 30% of the products detected reflect multiple recombination of the kappa locus. The kappa-deleting element was responsible for 70% of the multiple rearrangements that were detected. Interestingly, eight kappa-expressing samples exhibited rearrangement of the kappa-deleting element. The remaining multiple recombination products were characteristic of double V kappa-J kappa rearrangement. This frequency reveals that secondary V-J rearrangement may significantly contribute to the expression of kappa L chains in humans.     

Sequence analysis of 0.4 megabases of the rabbit germline immunoglobulin kappa1 light chain locus

Two rabbit germline bacterial artificial chromosome (BAC) libraries from animals with the b5 and b4 allotype were screened with probes specific for the immunoglobulin kappa1 light chain locus. Two partially overlapping BAC clones containing Vkappa elements of b5 allotype were isolated from the b5 library and one BAC clone containing Jkappa1, Ckappa and Vkappa was isolated from the b4 library. These three BAC clones were sequenced. They span about 0.4 MB of the rabbit Ig kappa1 light chain locus including 36 Vkappa elements, five J elements and the coding region of Ckappa1. The organization of the locus and the potential function of newly identified functional and structural elements are discussed.     

Recombination between paralogues at the Rp1 rust resistance locus in maize

Rp1 is a complex rust resistance locus of maize. The HRp1-D haplotype is composed of Rp1-D and eight paralogues, seven of which also code for predicted nucleotide binding site-leucine rich repeat (NBS-LRR) proteins similar to the Rp1-D gene. The paralogues are polymorphic (DNA identities 91-97%), especially in the C-terminal LRR domain. The remaining family member encodes a truncated protein that has no LRR domain. Seven of the nine family members, including the truncated gene, are transcribed. Sequence comparisons between paralogues provide evidence for past recombination events between paralogues and diversifying selection, particularly in the C-terminal half of the LRR domain. Variants selected for complete or partial loss of Rp1-D resistance can be explained by unequal crossing over that occurred mostly within coding regions. The Rp1-D gene is altered or lost in all variants, the recombination breakpoints occur throughout the genes, and most recombinant events (9/14 examined) involved the same untranscribed paralogue with the Rp1-D gene. One recombinant with a complete LRR from Rp1-D, but the amino-terminal portion from another homologue, conferred the Rp1-D specificity but with a reduced level of resistance.     

Recombination networks as genetic markers in a human variation study of the Old World

We have analyzed human genetic diversity in 33 Old World populations including 23 populations obtained through Genographic Project studies. A set of 1,536 SNPs in five X chromosome regions were genotyped in 1,288 individuals (mostly males). We use a novel analysis employing subARG network construction with recombining chromosomal segments. Here, a subARG is constructed independently for each of five gene-free regions across the X chromosome, and the results are aggregated across them. For PCA, MDS and ancestry inference with STRUCTURE, the subARG is processed to obtain feature vectors of samples and pairwise distances between samples. The observed population structure, estimated from the five short X chromosomal segments, supports genome-wide frequency-based analyses: African populations show higher genetic diversity, and the general trend of shared variation is seen across the globe from Africa through Middle East, Europe, Central Asia, Southeast Asia, and East Asia in broad patterns. The recombinational analysis was also compared with established methods based on SNPs and haplotypes. For haplotypes, we also employed a fixed-length approach based on information-content optimization. Our recombinational analysis suggested a southern migration route out of Africa, and it also supports a single, rapid human expansion from Africa to East Asia through South Asia.     

Recombination between rhodopsin and locus D3S47 (C17) in rhodopsin retinitis pigmentosa families

Autosomal dominant retinitis pigmentosa (adRP) has shown linkage to the chromosome 3q marker C17 (D3S47) in two large adRP pedigrees known as TCDM1 and adRP3. On the basis of this evidence the rhodopsin gene, which also maps to 3q, was screened for mutations which segregated with the disease in adRP patients, and several have now been identified. However, we report that, as yet, no rhodopsin mutation has been found in the families first linked to C17. Since no highly informative marker system is available in the rhodopsin gene, it has not been possible to measure the genetic distance between rhodopsin and D3S47 accurately. We now present a linkage analysis between D3S47 and the rhodopsin locus (RHO) in five proven rhodopsin-retinitis pigmentosa (rhodopsin-RP) families, using the causative mutations as highly informative polymorphic markers. The distance, between RHO and D3S47, obtained by this analysis is theta = .12, with a lod score of 4.5. This contrast with peak lod scores between D3S47 and adRP of 6.1 at theta = .05 and 16.5 at theta = 0 in families adRP3 and TCDM1, respectively. These data would be consistent with the hypothesis that TCDM1 and ADRP3 represent a second adRP locus on chromosome 3q, closer to D3S47 than is the rhodopsin locus. This result shows that care must be taken when interpreting adRP exclusion data generated with probe C17 and that it is probably not a suitable marker for predictive genetic testing in all chromosome 3q-linked adRP families.     

Polymerase chain reaction-based genotyping for allotypic markers of immunoglobulin kappa shows allelic association of Km with kappa variable segment.

Allotypic markers of immunoglobulin kappa (Km) may be determined using a novel method of amplification of the constant segment (C kappa) (IGKC) by polymerase chain reaction (PCR) followed by restriction enzyme digestion. Restriction sites in the C kappa PCR product correlate with allotypic differences among Km(1), Km(1,2), and Km(3) alleles. An AccI site in the PCR product correlates with Km(3); and presence or absence of a MaeII site correlates with the Km(1) or Km(1,2) allele, respectively. Km allelic frequencies were determined in a Caucasian population and compared to genotypic frequencies of nearby polymorphic markers. Among unrelated individuals with rheumatoid arthritis (RA) and controls, there is no evidence of allelic association between CD8A and polymorphic markers of the immunoglobulin kappa region [a V kappa (IGKV) BglII polymorphism about 24 kb centromeric to C kappa, Km allotype, and a SacI polymorphism 3.5 kb telomeric to the C kappa segment]. Similarly, there is no allelic association of the SacI C kappa polymorphism with Km or with the BglII V kappa polymorphism. However, there is evidence of allelic association of V kappa B3 and Km, specifically between the V kappa BglII 2.2-kb allele and Km(3) and also between the V kappa 3.5-kb allele and Km(1,2). Therefore, Km typing by PCR-based methods suggests the presence of allelic association between polymorphisms within the coding region of the C kappa segment and the nearest V kappa segment.