Roy Riblet

The 3D Structure of the Immunoglobulin Heavy-Chain Locus: Implications for Long-Range Genomic Interactions

The immunoglobulin heavy-chain (Igh) locus is organized into distinct regions that contain multiple variable (V(H)), diversity (D(H)), joining (J(H)) and constant (C(H)) coding elements. How the Igh locus is structured in 3D space is unknown. To probe the topography of the Igh locus, spatial distance distributions were determined between 12 genomic markers that span the entire Igh locus. Comparison of the distance distributions to computer simulations of alternative chromatin arrangements predicted that the Igh locus is organized into compartments containing clusters of loops separated by linkers. Trilateration and triple-point angle measurements indicated the mean relative 3D positions of the V(H), D(H), J(H), and C(H) elements, showed compartmentalization and striking conformational changes involving V(H) and D(H)-J(H) elements during early B cell development. In pro-B cells, the entire repertoire of V(H) regions (2 Mbp) appeared to have merged and juxtaposed to the D(H) elements, mechanistically permitting long-range genomic interactions to occur with relatively high frequency.

CCCTC-binding factor (CTCF) and cohesin influence the genomic architecture of the Igh locus and antisense transcription in pro-B cells

Compaction and looping of the ~2.5-Mb Igh locus during V(D)J rearrangement is essential to allow all VH genes to be brought in proximity with DH-JH segments to create a diverse antibody repertoire, but the proteins directly responsible for this are unknown. Because CCCTC-binding factor (CTCF) has been demonstrated to be involved in long-range chromosomal interactions, we hypothesized that CTCF may promote the contraction of the Igh locus. ChIP sequencing was performed on pro-B cells, revealing colocalization of CTCF and Rad21 binding at ~60 sites throughout the VH region and 2 other sites within the Igh locus. These numerous CTCF/cohesin sites potentially form the bases of the multiloop rosette structures at the Igh locus that compact during Ig heavy chain rearrangement. To test whether CTCF was involved in locus compaction, we used 3D-FISH to measure compaction in pro-B cells transduced with CTCF shRNA retroviruses. Reduction of CTCF binding resulted in a decrease in Igh locus compaction. Long-range interactions within the Igh locus were measured with the chromosomal conformation capture assay, revealing direct interactions between CTCF sites 5′ of DFL16 and the 3′ regulatory region, and also the intronic enhancer (Eμ), creating a DH-JH-Eμ-CH domain. Knockdown of CTCF also resulted in the increase of antisense transcription throughout the DH region and parts of the VH locus, suggesting a widespread regulatory role for CTCF. Together, our findings demonstrate that CTCF plays an important role in the 3D structure of the Igh locus and in the regulation of antisense germline transcription and that it contributes to the compaction of the Igh locus.

A Three-Megabase Yeast Artificial Chromosome Contig Spanning the C57BL Mouse Igh Locus

The mouse Ig H chain (Igh) complex locus is composed of >100 gene segments encoding the variable, diversity, joining, and constant portions of the Ab H chain protein. To advance the characterization of this locus and to identify all the VH genes, we have isolated the entire region from C57BL/6 and C57BL/10 as a yeast artificial chromosome contig. The mouse Igh locus extends approximately three megabases and contains at least 134 VH genes classified in 15 partially interspersed families. Two non-Igh pseudogenes (Odc-rs8 and Rpl32-rs14) were localized in the distal part of the locus. This physical yeast artificial chromosome map will provide important structure and guidance for the sequencing of this large, complex, and highly repetitive locus.

The origin of a developmentally regulated Igh replicon is located near the border of regulatory domains for Igh replication and expression

The 3′ Ig heavy chain locus (Igh) regulatory region is the most downstream known element of the murine Igh gene cluster. We report here that the nearest non-Igh genes—Crip, Crp2, and Mta1—are located ≈70 kb further downstream and are beyond the end of the domain of Igh transcriptional regulation. We have localized an origin of replication in MEL cells to a 3-kb segment located between the 3′ Igh regulatory region and Crip. Sequences downstream of this origin are replicated by forks that move in both directions. Sequences upstream of this origin (Igh-C, -D, and -J) are replicated in a single direction through a 500-kb segment in which no active bidirectional origins can be detected. We propose that this origin may lie at or near the end of the Igh regulation domain.

Sites That Direct Nuclear Compartmentalization Are near the 5′ End of the Mouse Immunoglobulin Heavy-Chain Locus

ABSTRACT VDJ rearrangement in the mouse immunoglobulin heavy chain (Igh) locus involves a combination of events, including a large change in its nuclear compartmentalization. Prior to rearrangement, Igh moves from its default peripheral location near the nuclear envelope to an interior compartment, and after rearrangement it returns to the periphery. To identify any sites in Igh responsible for its association with the periphery, we systematically analyzed the nuclear positions of the Igh locus in mouse non-B- and B-cell lines and, importantly, in primary splenic lipopolysaccharide-stimulated B cells and plasmablasts. We found that a broad ∼1-Mb region in the 5′ half of the variable-gene region heavy-chain (Vh) locus regularly colocalizes with the nuclear lamina. The 3′ half of the Vh gene region is less frequently colocalized with the periphery, while sequences flanking the Vh gene region are infrequently so. Importantly, in plasmacytomas, VDJ rearrangements that delete most of the Vh locus, including part of the 5′ half of the Vh gene region, result in loss of peripheral compartmentalization, while deletion of only the proximal half of the Vh gene region does not. In addition, when Igh-Myc translocations move the Vh genes to a new chromosome, the distal Vh gene region is still associated with the nuclear periphery. Thus, the Igh region that interacts with the nuclear periphery is localized but is likely comprised of multiple sites that are distributed over ∼1 Mb in the 5′ half of the Vh gene region. This 5′ Vh gene region that produces peripheral compartmentalization is the same region that is distinguished by requirements for interleukin-7, Pax5, and Ezh2 for rearrangement of the Vh genes.

Sequence and Characterization of the Ig Heavy Chain Constant and Partial Variable Region of the Mouse Strain 129S1

Although the entire mouse genome has been sequenced, there remain challenges concerning the elucidation of particular complex and polymorphic genomic loci. In the murine Igh locus, different haplotypes exist in different inbred mouse strains. For example, the Ighb haplotype sequence of the Mouse Genome Project strain C57BL/6 differs considerably from the Igha haplotype of BALB/c, which has been widely used in the analyses of Ab responses. We have sequenced and annotated the 3′ half of the Igha locus of 129S1/SvImJ, covering the CH region and approximately half of the VH region. This sequence comprises 128 VH genes, of which 49 are judged to be functional. The comparison of the Igha sequence with the homologous Ighb region from C57BL/6 revealed two major expansions in the germline repertoire of Igha. In addition, we found smaller haplotype-specific differences like the duplication of five VH genes in the Igha locus. We generated a VH allele table by comparing the individual VH genes of both haplotypes. Surprisingly, the number and position of DH genes in the 129S1 strain differs not only from the sequence of C57BL/6 but also from the map published for BALB/c. Taken together, the contiguous genomic sequence of the 3′ part of the Igha locus allows a detailed view of the recent evolution of this highly dynamic locus in the mouse.

Identification of a candidate regulatory element within the 5' flanking region of the mouse Igh locus defined by pro-B cell-specific hypersensitivity associated with binding of PU.1, Pax5, and E2A.

The Igh locus is controlled by cis-acting elements, including Eμ and the 3′ IgH regulatory region which flank the C region genes within the well-studied 3′ part of the locus. Although the presence of additional control elements has been postulated to regulate rearrangements of the VH gene array that extends to the 5′ end of the locus, the 5′ border of Igh and its flanking region have not been characterized. To facilitate the analysis of this unexplored region and to identify potential novel control elements, we physically mapped the most D-distal VH segments and scanned 46 kb of the immediate 5′ flanking region for DNase I hypersensitive sites. Our studies revealed a cluster of hypersensitive sites 30 kb upstream of the most 5′ VH gene. Detection of one site, HS1, is restricted to pro-B cell lines and HS1 is accessible to restriction enzyme digestion exclusively in normal pro-B cells, the stage defined by actively rearranging Igh-V loci. Sequence motifs within HS1 for PU.1, Pax5, and E2A bind these proteins in vitro and these factors are recruited to HS1 sequence only in pro-B cells. Transient transfection assays indicate that the Pax5 binding site is required for the repression of transcriptional activity of HS1-containing constructs. Thus, our characterization of the region 5′ of the VH gene cluster demonstrated the presence of a single cluster of DNase I hypersensitive sites within the 5′ flanking region, and identified a candidate Igh regulatory region defined by pro-B cell-specific hypersensitivity and interaction with factors implicated in regulating V(D)J recombination.

Sequence-ready physical map of the mouse chromosome 16 region with conserved synteny to the human velocardiofacial syndrome region on 22q11.2.

Abstract. Proximal mouse Chromosome (Chr) 16 shows conserved synteny with human Chrs 16, 8, 22, and 3. The mouse Chr 16/human Chr 22 conserved synteny region includes the DiGeorge/Velocardiofacial syndrome region of human Chr 22q11.2. A physical map of the entire mouse Chr 16/human Chr 22 region of conserved synteny has been constructed to provide a substrate for gene discovery, genomic sequencing, and animal model development. A YAC contig was constructed that extends ca. 5.4 Mb from a region of conserved synteny with human Chr 8 at Prkdc through the region conserved with human Chr 3 at DVL3. Sixty-one markers including 37 genes are mapped with average marker spacing of 90 kb. Physical distance was determined across the 2.6-Mb region from D16Mit74 to Hira with YAC fragmentation. The central region from D16Jhu28 to Igl-C1 was converted into BAC and PAC clones, further refining the physical map and providing sequence-ready template. The gene content and borders of three blocks of conserved linkage between human Chr 22q11.2 mouse Chr 16 are refined.

Variation and evolution of Class I Mhc in sexual and parthenogenetic geckos

We present the first Mhc class I sequences in geckos. We compared Mhc variation in gekkonid species that reproduce sexually (Hemidactylus frenatus, Lepidodactylus aureolineatus, L. moestus, L. sp. Arno, L. sp. Takapoto) to others reproducing parthenogenetically (H. garnotii, L. lugubris). These comparisons include the known maternal (L. moestus) and paternal (L. sp. Arno) ancestors of the asexual L. lugubris. Sequences similar to other vertebrate species were obtained from both nuclear and cDNA templates indicating that these sequences are derived from expressed class I Mhc loci. Southern blot analysis using gecko class I probes, revealed that parthenogenetic clonal lineages of independent evolutionary origin have no within-clone band variation at class I loci and that no detectable recombination between restriction sites had taken place. Variability in the sexual species was similar to mammalian taxa, i. e. class I genes are highly variable in outbreeding sexual populations. Sequence analysis of the alpha-2 domain of class I genes identified point mutations in a clonal lineage of L. lugubris which led to amino acid substitutions. Potential transspecific allelic lineages were also observed. The persistence of asexual lineages with little or no class I diversification over thousands of generations seems to argue against strong selection for Mhc multi-allelism caused by pathogen-Mhc allele specificity. On the other hand, the high level of heterozygosity in the parthenogenetic species (a consequence of their hybrid origin) may provide clonal lineages with adequate antigen presenting diversity to survive and compete with sexual relatives.

Evolution of the immunoglobulin heavy chain variable region (Igh-V) locus in the genus Mus.

The evolution of the mouse immunoglobulin heavy chain variable region (Igh-V) locus was investigated by the comprehensive analysis of variable region (Vh) gene family content and restriction fragment polymorphism in the genusMus. The examination of naturalMus domesticus populations suggests an important role for recombination in the generation of the considerable restriction fragment polymorphism found at theIgh-V locus. Although the sizes of individualVh gene families vary widely both within and between differentMus species, evolutionary trends ofVh gene family copy number are revealed by the analysis of homologues of mouseVh gene families inRattus andPeromyscus. Processes of duplication, deletion, and sequence divergence all contribute to the evolution ofVh gene copy number. CertainVh gene families have expanded or contracted differently in the various muroid lineages examined. Collectively, these findings suggest that the evolution of individualVh family size is not driven by strong selective pressure but is relatively neutral, and that gene flow, rather than selection, serves to maintain the high level of restriction fragment polymorphism seen inM. domesticus.