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of June 17, 2018.This information is current as Chain Locus
HeavyGenomic Organization of the Variable Variable Heavy Chain Gene Usage and theand Neonatal Piglets. XI. The Relationship of Antibody Repertoire Development in Fetal
Chardon, Gregory J. Tobin and John E. ButlerFrancois Puimi, Hirohide Uenishi, Kevin Wells, Patrick Tomoko Eguchi-Ogawa, Nancy Wertz, Xiu-Zhu Sun,
http://www.jimmunol.org/content/184/7/3734doi: 10.4049/jimmunol.0903616March 2010;
2010; 184:3734-3742; Prepublished online 5J Immunol
MaterialSupplementary
6.DC1http://www.jimmunol.org/content/suppl/2010/03/05/jimmunol.090361
Referenceshttp://www.jimmunol.org/content/184/7/3734.full#ref-list-1
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Print ISSN: 0022-1767 Online ISSN: 1550-6606. Immunologists, Inc. All rights reserved.Copyright © 2010 by The American Association of1451 Rockville Pike, Suite 650, Rockville, MD 20852The American Association of Immunologists, Inc.,
is published twice each month byThe Journal of Immunology
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The Journal of Immunology
Antibody Repertoire Development in Fetal and NeonatalPiglets. XI. The Relationship of Variable Heavy Chain GeneUsage and the Genomic Organization of the Variable HeavyChain Locus
Tomoko Eguchi-Ogawa,* Nancy Wertz,† Xiu-Zhu Sun,† Francois Puimi,‡
Hirohide Uenishi,* Kevin Wells,x Patrick Chardon,‡ Gregory J. Tobin,{ and
John E. Butler†
In this study, we havemapped the 39H chainV region (VH) genes and those in theH chain diversity, H chain joining, and 59 portion of
theHchain constant locus.We show that swinepossess only two functionalHchain diversity segments andonlyone functionalH chain
joining segment. These data help to explainmore than a decade of observations on the preimmune repertoire of this species and reveal
the vulnerability of swine to natural or designed mutational events. The results are consistent with earlier studies on the region
containing Enh, Cm, and Cd while revealing that the ancestral IgG3 is the most 59 Cg gene. We also observed a recent duplication
(∼1.6 million years ago) in the VH locus that contains six of the seven VH genes that comprise 75% of the preimmune repertoire.
Because there are no known transfers of immune regulators orAgs that cross the placenta as inmice and humans, fetal VHusagemust
be intrinsically regulated. Therefore, we quantified VH usage in fetal piglets and demonstrated that usage is independent of the
position of VH genes in the genome; themost 39 functional VH gene (IGHV2) is rarely used, whereas certain upstream genes (IGHV14
and IGHV15) arepredominately used early in fetal liver but seldom thereafter. Similar to previous studies, threeVHgenes account for
40% of the repertoire and six for ∼70%. This limited combinatorial diversity of the porcine VH repertoire further emphasizes the
dependence on CDR3 diversity for generating the preimmune Ab repertoire of this species. The Journal of Immunology, 2010, 184:
3734–3742.
The H chain Ig variable locus is organized similarly in allmammals that have been studied. As few as 12 to.1000 Hchain V region (VH) genes are thought to be arrayed 59 of
multiple H chain diversity (DH) segments that in turn are found 59 ofup to nine H chain joining (JH) segments (1, 2). VH genes charac-terized to date include many pseudogenes (3), such as those withnonconsensus signal sequences, stop codons, frameshift mutations,or the absence of functional leader sequences. In humans, for ex-ample, only 38–46 of the.100VH genes (haplotype dependent) are
functional,whereas 27DH segments canbe expressed, but only six ofthe nine JH segments are functional (2, 4). The VH genes of verte-brates belong to different families that have been grouped into threeclans based on sequence homologies (5). There are large differencesin the number of VH genes and VH gene families among species. Inswine,,30 genes have been described, all belonging to the ancestralVH3 family (6, 7) and have identical or nearly identical frameworkregions but differ in their CDR1 and CDR2 regions (8, 9). However,CDR regions are often shared among different porcine VH genes,suggesting they could be a consequence of gene duplication com-bined with a type of genomic gene conversion (10, 11).The distribution of VH gene segment usage in fetal and newborn
mice, humans, rabbits, and swine is nonrandom, and usage patternsvary during ontogeny. In the fetal liver of mice, members of the VH5and VH2 families (especially 7183 and Q52, respectively) arepreferentially used (12, 13), but after birth, splenic B cells use theVH1 family (J558) (14). TheVH2 andVH5 family genes are themost39 in the locus, whereas the J558 family is midway (more 59) in thelocus, suggesting that VH usage in the preimmune repertoire favors39 VH genes but that usage shifts upstream, presumably due to ex-posure to environmental Ag because this shift does not occur ingerm-free mice (14, 15). A preferential usage of the most JH prox-imal VH3 family genes has also been reported in humans (16, 17).Early VH usage in rabbits favors the most 39 VH gene (VH1) in 90%of VDJ rearrangements, but this preferential usage declines duringdevelopment and with exposure to environmental Ag (18). How-ever, developmental repertoire changes in rabbits are compoundedby somatic gene conversion, a phenomenon rarely seen inmice (19).The pattern of preferential usage of 39VH genes is not supported in
all studies. In humans,V3-23 andV3-30 are preferentially used in the
*National Institute of Agrobiological Sciences, Tsukuba, Ibaraki, Japan; †Departmentof Microbiology, University of Iowa, Iowa City, IA 52242; ‡National Institute for Agro-nomic Research, Institute of Molecular Biology, Jouy-en-Josas, France; xDivision ofAnimal Sciences, University of Missouri, Columbia, MO 65211; and {Biological Mim-etics, Frederick, MD 21702
Received for publication November 11, 2009. Accepted for publication February 1,2010.
This work was supported by National Science Foundation-Integrative OrganismalSystems Grant 15203800 and Grant 58-1265-5-053 from the National Pork Boardand subaward C080090-UI from Biological Mimetics.
The sequences presented in this article have been submitted to GenBank underaccession numbers AB513624 and AB513625.
Address correspondence and reprint requests to Dr. John E. Butler, InterdisciplinaryImmunology Program, Department of Microbiology, University of Iowa, 51 NewtonRoad, Iowa City, IA 52242. E-mail address: [email protected]
The online version of this article contains supplemental material.
Abbreviations used in this paper: BAC, bacterial artificial chromosome; CH, H chainconstant; DG, day of gestation; DH, H chain diversity; FR, framework region; IMGT,ImMunoGeneTics; IPP, ileal Peyer’s patches; JH, H chain joining; LINE, long in-terspersed nucleotide element; RSS, recombination signal sequence; VH, H chain Vregion.
Copyright� 2010 by TheAmericanAssociation of Immunologists, Inc. 0022-1767/10/$16.00
www.jimmunol.org/cgi/doi/10.4049/jimmunol.0903616
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preimmune repertoire, but these map to the middle of the locus (20).Alternatives to the locus position concept include: 1) negative se-lection for B cells utilizing VH genes that recognize certain self-Ags;2) positive selection for B cells by stromal ligands based on featuresof their BCR; and 3) the evolutionary conservation of BCRs bearingVH genes that encode binding sites that recognize bacteria thatthreaten the newborn.Thebasis for 2) and3) above could be the same.For example, human V3-23, mouse VH283 (a VH2 family gene), andshark VH genes share.80% sequence similarity at the protein level(7, 21) andencodeBCRs that are polyreactive and recognize bacterialpolysaccharides (22). In humans and mice, such Abs are often as-sociated with IgG3 (23, 24) and class switch that occurs in the ab-sence of environmental Ag (25, 26) and in CD40/CD40L-deficientmice (27). In swine, IgG3 expression accounts for.60% of the totalIgG expression in the ileal Peyer’s patches (IPP) of fetal piglets(28). The IPP of swine is the anatomical homolog of the IPP of sheep,in which Ab repertoire development is considered to be Ag-in-dependent (29). In both the human and mouse genome, IgG3 is themost Cd proximal functional Cg gene (reviewed in Refs. 30, 31).In contrast to rabbits, mice, and humans, fetal piglets present
a different patternof fetal/neonatal development that could affectVH
gene usages. In swine, there is no known protein transfer frommother to fetus including Igs (32–34). Because maternal Igs caninfluence fetal immune responses (35, 36) and presumably B cellselection and development, usage of certain VDJ rearrangements isindependent of this influence in fetal piglets. Although it is knownthat certain porcine viruses can cross the placenta, the mechanismremains unknown. In any case, our studies on VDJ usage in fetalpiglets were done in animals free of all detectable viral pathogens.Offspring of swine are precosial and routinely reared in isolatorsseparate from their mothers, allowing the experimenter to controlenvironmental factors that might influence the development ofadaptive immunity (37). In swine, VH, DH, and JH usage is highlyrestricted. In the expressed preimmune repertoire, four to seven VH
genes account for 75–95% of the repertoire (9, 38) (Table I). Al-though the mechanism is unknown, swine use only a single JH andtwo DH segments to generate their preimmune Ab repertoire (38–40). We believed these observations might be better understood bymapping the VH, DH, and JH loci of swine. We were especiallyinterested to know if the predominant use of a few VH genes in thepreimmune repertoire was confined to those at the 39 end of the VH
locus as reported in rabbit, mouse, and some human studies.We describe in this study the characterization of a 229-kb segment
of swine chromosome 7 containing the VH-DH-JH-Cm-Cd and 59 Cg
region of the H chain locus that includes 15 DH proximal VH genesand the 59 portion of the H chain constant (CH) genome. Our mapshows that swine possess only one functional JH gene segment, ap-parently two functional DH segments, and that preferential VH usagein primary B cell tissues of fetal animals cannot be explained asa stochastic process dependent on the location of VH genes in thelocus. In contrast, the dominant early expression of porcine IgG3 inlate-term fetuses in an organ believed to develop an Ag-independentrepertoire appears correlated with its position in the H chain C regionof the locus.
Materials and MethodsNomenclature
The porcine VH genes were originally named according to their order ofdiscovery and given vernacular names like VHA and VHB (Table I) (9).The intention was that once their location in the genome was known, thenomenclature would be changed to the familiar VH1, VH2, etc., system orthe ImMunoGeneTics (IMGT) system (IGHV1, IGHV2). In this report, wehave maintained the vernacular nomenclature in certain cases and used it inparenthesis in the text. Both the vernacular and IMGT system are used inTable II. Because the IMGT system contains an unfortunate redundancy(IGHD is used for both IgD and DH diversity segments), we have used theconventional Cm, Cd, and Cg for CH regions.
Screening of bacterial artificial chromosome clones andconstruction of bacterial artificial chromosome contigs
All bacterial artificial chromosome (BAC) clones were isolated froma genomic library constructed by using a Large White boar resulting fromintrafamilial matings at Institute Nationale Recherche Agronomique (Jouyen Josas, France) (42). BAC clones containing the porcine IGHV, IGHD,and IGHJ regions and 59 IGHC genes (Cm, Cd, Cg3, and Cg5) wereidentified by using a PCR-based screening system. Selected BAC cloneswere cultured overnight in Luria-Bertani broth containing 12.5 mMchloramphenicol. BAC clones 850A09 and 747A01 that hybridized withpolynucleotide probes specific for VH genes, JH, and Cm (Table I) wereselected for further study. DNA from relevant clones was extracted witha Qiagen Plasmid Midi Kit (Qiagen, Hilden, Germany).
Sequencing of BAC clones
BAC DNAs were extracted by using a Qiagen Large Construction Kit(Qiagen). TheDNAwere cleaved into 2- to 4-kb fragments by sonication andthen subcloned into the plasmid vector pUC118 (Takara, Otsu, Japan) at theHincII site to construct a shotgun library. The inserts obtained were se-quenced by an ABI 3730xl sequencer with a Big Dye Terminator version 3cycle sequencing kit (Applied Biosystems, Foster City, CA) using universalprimers annealing to vector sequences. Sequence data were processed withPhredbase caller and assembledwithPhrap (CodonCode,Dedham,MA) (43,44). Compiled sequences of the two BAC clones have been uploaded inGenBank (AB513624 and AB513625). Restriction enzyme digestion wasperformed to confirm the sequence assembly. BAC clones were digested
Table I. Probe sequences used to identify common porcine VH genes, JH, and Cm
VH Gene CDR1 CDR2
Probe Sequence for CDR1 Probe Sequence for CDR2
39 FR1 CDR1 59 F2 39 F2 CDR2
VHA A A CAGT AGTACCTACATTAAC T TGGCA GCTATTAGTACTAGTVHB B B GACAACGCTTTCAGC TGG GCCATTGCTAGTAGTGACVHG G E TTCAGT AGTTATAGCATGGAGC GGTATTGATAGTGGTAGTTAVHE E E TCAGT AGTTATGCAGTGAGC T GGTATTGATAGTGGTAGTTAVHF F F GT AGTTATGGCGTAGGC TGG TCTATTGGTAGTGGTAVHC C C GT AGTTATGAAATCAGC TG GGTATTTATAGTAGTGGTAGVHZ E C TCAGT AGTTATGCAGTGAGC T GGTATTTATAGTAGTGGTAGVHY C A GT AGTTATGAAATCAGC TG TGGCA GCTATTAGTACTAGTVHA* A A AGAGACAACTCCCAGAACACG FR3Pan CGCCAGGCTCCAGGGAAG FR2JH TGAGGACACGACGACTTCAA JHCm GCACATGCCGCTCGTGTA CH4
Columns labeled CDR1 and CDR2 list the vernacular designation used in the laboratory for the porcine VH genes (see also Table II). The upstream VHA (IGHV10) isdesignated as VHAp and requires a special probe that binds in the FR3 region for identification. Detection of VHN requires a combination of the probes described in Table I. Thismethod of recognition was confirmed by sequence analysis.
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with HindIII, PvuI, or FspI, and the fragment sizes were compared withthose predicted by a Genetyx sequence editor (Genetyx, Tokyo, Japan).
Thenumberof IGHVgenes contained in theBACcloneswas confirmedbyPCRmethodsusingeachBACcloneDNAasa template.EachIGHVgenewasamplified using a primer set annealing to sequences in 59 framework region(FR) 1 (59-GAGGAGAAGCTGGTGGAGT-39) and 39 FR3 (59-GCCGTG-TCTTCGGTTCTCA-39) that are common to all known porcine VH genesexcept VHB. To amplify the VHB, 59 FR1 (59-GAGGAGAAGCTGGTGG-AGT-39) and FR3R IGHVB (59-GCCGTGTCTTCGGTTCTGA-39) wereused. The products were cloned into the TOPO 2.1 vector (Invitrogen,Carlsbad, CA).More than 80 clones were selected at random from each PCRproduct for sequence analysis.
Analysis of mapping data
Sequence similarity was examined using the BLAST2 program (45) (www.ncbi.nlm.nih.gov/BLAST/bl2seq/wblast2.cgi), and interspersed repetitivesequences in the pig genomewere detected by using RepeatMasker (A. Smitand P. Green, unpublished observations; www.repeatmasker.org/) withRepbase (46) (www.girinst.org/repbase/index.html). Homologous regionsbetween genomic sequences were identified by using the PipMaker program(47). Sequence alignment and phylogenetic analysis were performed by theCLUSTALW (1.83) program (48). The detected IGHV genes were analyzedby the BLAST program with public nucleotide databases (DNA Data Bankof Japan, EMBL, and GenBank). Only sequences that showed .98%identity to previously identified porcine IGHV sequences were adopted.
Quantitation of VH gene usage in fetal liver and late-gestationbone marrow
DNA from fetal liver at 30 d of gestation (DG30) from four piglets eachfrom four unrelated gilts and RNA from the bone marrow of five fetuses atDG95 were used to recover VDJ rearrangement from DNA and cDNA,
respectively, as previously described (9, 39, 40). The VDJs recovered byPCR were cloned into pCRO4-TOPO (Invitrogen), and 632 clones fromfetal liver and 432 from bone marrow transcripts were then sequentiallyhybridized with polynucleotide probes specific for the CDR1 and CDR2regions of the most common porcine VH genes (9, 39) (Table I). Theseclones were also hybridized with a pan-specific FR2 probe to identify allclones with a plasmid containing a VDJ insert (Table I).
Statistical analysis
VH usage was complied in Excel spreadsheets (Microsoft, Redmond, WA)and displayed as proportional usage (mean and SD) in GraphPad Prism(GraphPad, San Diego, CA). Mean differences were compared by Student ttest routines embedded in the Prism program (GraphPad).
ResultsGenomic structure of the region containing porcine IGHD,IGHJ, and the 39 IGHV genes
WescreenedseveralBACclonescontainingIGHDandIGHJsegmentsbyPCRtoidentifyclones thatencompass the full locus.Clone851A09contained 118,088 bp with sequences from the IGHD3 segment toIGHV15. Clone747A01 overlapped 851A09 by ∼29.6 kbp and en-compassed IGHG2 through IGHV1P (Fig. 1). Together the twoclones represent 229,148 bp of genomic sequence. The two BACclones were subjected to shotgun sequencing as described in Mate-rials and Methods. The sequence overlap between 747A01 and851A09 was 100% homologous, indicating that they were derivedfrom the same allele. By analyzing open reading frames and usingBLASTagainstGenBank sequences,we identified15 IGHV,4 IGHD,
FIGURE 1. Genomic structure of the porcine Ig H chain region encompassing Cg5 to IGHV15. SP6 and T7 denote primer sites located in the vector that
flank the cloning site and assist in determining the orientation of the BAC clones. The putative coding sequence (CDS) and the switch region of IgM (Sm) are
indicated by black boxes and a gray oval, respectively. Genes in which exon 1 was collapsed or contained stop codon(s) in the V segment are regarded as
pseudogenes and are indicated by P. The enhancer region is indicated by awhite circle, the position of whichwas estimated in a previous study (49). Restriction
sites of HindIII, PvuI, and FspI are shown in the lower part of the figure. Numbers indicate the sizes of the BAC clone fragments generated by digestion with
each enzyme. Bars below the gene map indicate the region of gene duplication. Both the IMGT and vernacular nomenclatures for VH genes are given. The
familiar names of isotypes have been used because the IMGT does not distinguish between IGHD (IgD) and IGHD (diversity segment).
3736 VH USAGE AND GENOME ORGANIZATION
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and5 IGHJgene segments aswell as the constant regions of IgM(Cm)and IgD (Cd) and the two most 59 IgG genes (Cg3 and Cg5) (Fig. 1,Tables II–IV). The sequence of the switch region andC region of IgMhad been reported previously (49); this sequence had a high level ofidentity to the sequence determined in this study, showing that thesesequences were derived from the same region in the locus.Previous studies showed that functionally rearranged VDJs used
only two IGHD segments and a single IGHJ segment (38, 40).Although only transcripts carrying IGHD1, IGHD2, and IGHJ5 arein the public databases, we identified four IGHD segments and fiveIGHJ segments. The porcine genomic locus carrying the IGHD andIGHJ genes was much shorter than its human counterpart (9 IGHJand 27 IGHD are detected in the corresponding region of the human
genome: NT_026437.11, 86930000 to 87630000). In the case of JH,
only reading frame III of IGHJ5 translates to the sequence of the
only expressed JH region of swine (38); IGHJ1, IGHJ2, and IGHJ4
have noncanonical heptamer sequences (Table IV). A sequence
encoded by IGHJ3 has yet to be found in a rearranged or expressed
VDJ, although its recombination signal sequence (RSS) seems
functional, and no stop codons are present.Analysis of the DH shows that IGHD1 (DHA) and IGHD2 (DHB)
have canonical RSSs, whereas both the heptamer and nonamer of
IGHD3 are noncanonical (Table III). The RSS of IGHD4 should
be functional, but if expressed, the tiny segment it encodes (3 aas)
could be easily overlooked in a region where TdT-dependent
nucleotide additions are common and exonucleases are active.The 15 IGHV genes found in the sequence had very homologous
sequences. Because of this, reads could be misassembled following
shotgun sequencing. Thus, we cloned the PCR fragments generated
from clones 851A09 and 747A01 using the primer commonly used to
amplify the pig IGHV segments. The fragments obtained from ge-
nomic DNAwere identical to VH genes previously reported for this
species (9, 40). This, along with our restriction analysis (Fig. 1), in-
dicates that the assembly process had been performed correctly.
Among the VH segments detected, exon 1 and a part of exon 2 were
collapsed in 4 of the 15 IGHV genes (IGHV3, IGHV7, IGHV9, and
IGHV13), suggesting they are pseudogenes. The IGHV gene located
on the 39-most side (IGHV1) had a stop codon in exon 2, indicating
that it was also a pseudogene, confirming a previous observation (40).
VHA and VHB were highly expressed in newborn piglets andwere duplicated in the porcine genome sequence
We found a large degree of duplication in the porcine genomic se-quencecarryingIGHV9PtoIGHV14with thatcontainingIGHV3PtoIGHV8 (Supplemental Fig. 1). Repetitive sequences interspersedaround IGHV4 to IGHV6 were also highly conserved with thosearound IGHV10 to IGHV12 (Fig. 2). We analyzed the duplicationevent in the IGHV region by using repetitive sequences. As shown inFig. 2B, the repetitive units include long interspersed nucleotide el-ement (LINE) sequences such as L1_Art and L1_BT. We used theexcised sequences of the respective LINEs (commonly conservedamong the sequences) to demonstrate that L1_Art and L1_BT arehighly conserved between the two repetitive IGHV units in com-parison with the others (Fig. 2C). The excised L1_BT sequencesderived from the two repetitive units [L1_BT (a) and L1_BT (c)](135 bp) were completely identical, which implied that the two re-petitive units were established recently.We estimated the divergencetime of the repetitive units by using L1_Art because the length ofconserved regionswasmuch longer (.800 bp) than that of L1_BT. Itrevealed that L1_Art (b) and L1_Art (d) in Fig. 2B were diverged
Table II. IgH genes identified from the genome sequence determined in this study
IMGT Vernaculara No. of Exons Start End CDS Length (bp) Comment
IGHV15 VHN 2 3032 3473 353IGHV14 VHY 2 9306 9747 353IGHV13P 1 12,154 12,366 213 Exon 1 and part of exon 2 were collapsedIGHV12 VHB* 2 15,678 16,126 359IGHV11 VHF 2 27,618 28,065 359IGHV10 VHA* 2 34,235 34,676 353IGHV9P 1 37,094 37,306 213 Exon 1 and part of exon 2 were collapsedIGHV8 VHE 2 42,141 42,589 359IGHV7P 1 45,002 45,214 213 Exon 1 and part of exon 2 were collapsedIGHV6 VHB 2 48,526 48,974 359IGHV5 VHT 2 60,198 60,645 359IGHV4 VHA 2 66,808 67,249 353IGHV3P 1 69,661 69,873 213 Exon 1 and part of exon 2 were collapsedIGHV2 VHG 2 76,020 76,470 359IGHV1P Psg 2 2 90,845 91,288 352 Stop codon in exon 2IGHD1 DHA 1 108,609 108,646 38IGHD2 DHB 1 109,219 109,246 28IGHD3 1 113,937 113,973 37IGHD4 1 131,317 131,327 11IGHJ1 1 132,104 132,157 54IGHJ2 1 132,277 132,329 53IGHJ3 1 132,587 132,634 48IGHJ4 1 132,979 133,029 51IGHJ5 JH5 1 133,523 133,576 54Smb 135,726 139,170 3445IGHM IgM (Cm) 4 139,705 141,406 1216IGHD IgD (Cd) 5 147,270 152,588 1060IGHG1 IgG3c (Cg3) 4 188,628 190,144 1001IGHG2 IgG5bd (Cg5) 4 209,664 211,155 974
aVH gene names were classified according to CDR1 and CDR2 sequence specificities (9). The vernacular terminology is based on order of discovery,whereas the IMGT system is based on the position in the genome as shown in Fig. 1.
bSwitch region for IgMcIgG nomenclature based on recent studies of Butler et al. (41).dIgG5b is an allele of IgG5 (41).Psg, pseudogenes discovered in genomic DNA prior to mapping studies (see Ref. 9).
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from each other ∼1.6 million y ago. This calculation is based on theestimated mutation rate in pseudogenes: 4.63 1029 (50).Evidence for recent duplication of the IGHV region is further
supported by the observation of conserved HindIII and PvuI re-
striction fragments in Fig. 1. This duplication unit contained theduplicated VHA and VHB genes, which, along with VHC and VHE,
comprise .75% of the preimmune repertoire in piglets (39). Theexon-intron structures of the detected VHA and VHB genes were
also conserved, perhaps a clue that these genes are important in
generating the Ab repertoire.
VH gene usage in primary lymphoid tissues at DG30 and DG95
Fig. 3 summarizes VH usage in VDJ rearrangement in 632 clonesfrom DG30 fetal liver and 432 cloned transcripts from DG95 bonemarrow. VH genes are ordered on the x-axis according to theirposition in the locus, 39 to 59 (Fig. 1, Table II). The results confirmearlier findings that IGHV4, IGHV6, IGHV10, and IGHV12dominate the early repertoire (∼30%) but also show that IGHV14(VHY) and IGHV15 (VHN) play an equally dominant role atDG30. Noteworthy is that the first functional VH gene IGHV2(VHG) (Fig. 1) is seldom used. Thus, early usage in a primarylymphoid tissue cannot be ascribed to the position of the VH genesin the locus. In older fetuses (i.e., DG95), usage of IGHV14 andIGHV15 nearly disappears, whereas VHC and both IGHV4 (VHA)and IGHV10 (VHA*) are significantly increased. VH usage atDG95 DNA rearrangements or transcripts from bone marrow, IPP,and spleen does not significantly differ (J. E. Butler, X. Z. Sun, N.Wertz, K. M. Lager, and G. Tobin, unpublished observations).These data reject the notion that VH usage during developmentfollows a continuous progression of VH usage from 39 to 59. Inboth DG30 liver and DG95 bone marrow, usage of unidentified VH
genes (UNK) does not change. Previous studies (9) indicate thatmany VDJ clones identified as UNK in conventionally rearedyoung pigs use the same common genes that account for 70% ofthe preimmune repertoire (Fig. 3) but have mutated CDRs so theyno longer hybridize with gene-specific probes (Table I). This lowfrequency of somatic hypermutation occurs in utero in the com-plete absence of environmental Ag stimulation, although there isno accumulation of mutations in CDR regions as is the case in Ag-stimulated piglets (S. Bratsch, N. Wertz, T. Kunz, and J.E. Butler,unpublished observations).As indicated above, Enh, Cm, and Cd map to the same region as
previously described (40, 51). Among the six Cg subclasses andeleven allotypes (41), Cg3 and Cg5 are the most Cd proximal Cregion genes.
DiscussionWe present the first partial map of the porcine H chain locus thatcovers the 59 portion of the CH region, JH region, DH region, and thefirst 15 of the most 39VH genes. These results confirm previous dataon Cm and Cd (51) and Sm and Cm (49). Data presented in this studyalso explain.15 y of observations that swine express only two DH
segments, IGHD1, formally called DHA, and IGHD2, formallycalled DHB (40). Our mapping data also explain why swine onlyexpress a single JH sequence (38). Evidence that only IGHJ5 (JH5) isfunctional has recently been confirmed in studies in which thissegment was mutated, resulting in B cell knockout piglets (M.Mendicino, J. Ramsoondar, C. Phelps, T. Vaught, S. Ball, T. LeR-oith, J.Moonahan, S. Chen, A. Dandro, J. Boone, P. Jobst, A. Vance,N. Wertz, Z. Bergman, X-Z Sun, I. Polejaeva, J. Butler, Y. Dai, D.Ayares, and K. Wells, personal communication). Collectively, themap and sequence data we provide for DH, JH, Sm, Cm, and Cd areconsistent with earlier partial mapping studies (49, 51) and explainwhy swine express only two DH segments and a single JH (38, 40).T
able
III.
IGHD
genes
detectedin
thisstudy
Gene
9-m
er12-m
er7-m
erReadingFrame
Sequence
andDeducedAminoAcidSequence
7-m
er12-m
er9-m
er
IGHD1
GGTTTGAGA
ACGGGCCTGTGG
CACTGTG
GAATTGCTATAGCTATGGTGCTAGTTGCTATGATGACC
CACAGCA
TCACAGCGCCCT
ACAAAAACC
IELL*LW
C*LL**
IIN
CY
SY
GA
SCY
DD
III
IA
IA
MV
LVA
MM
TTGACTATAGCGGTTGCTATAGCGGTTAC
CACAGTG
ACAGACCCGGTG
GCAAAAACC
I*L*R
LL*RL
IID
YSG
CY
SG
YIII
TIAVA
IAV
IGHD2
GCTTTTTGC
CAAGGCCTTTCC
CACTGTG
CGGCTGAGCGCACAGCCCTGAGGCCCCAGCTGGCTGG
CACAGTG
ACAGACCCGGTG
GCAAAAACC
IR
LSAQ
P*G
PSW
LII
G*A
HSPEA
PA
GW
III
AERTA
LRPQ
LA
IGHD3
CGGCCGACC
TGAAGCCTCCGT
GCCTGTG
CTCACCGGGAC
CACAGCA
GGGCCTTGGAAC
TGCAGAAAC
ILTG
IISPG
III
HRD
IGHD4
GCTTGGGC
CGAGCCAGGAAC
CACAGTG
CTCACCGGGAC
CACAGTG
ACTGACCAAACT
CCCGGCCAG
ILTG
IISPG
III
HRD
Canonical
heptamersandnonam
ersareunderlined.
*Stopcodon.
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The partial map of the VH locus identified the same major VH
genes that our previous studies had identified (9, 39, 40) (Table II).When the location of particular genes in the locus (e.g., IGHV4,IGHV15, and IGHV2) is compared with their proportional usage,there is no positive correlation between position and usage (Fig. 3).This sharply differs from the situation in rabbits, in which the most39VHgene is used in∼90%of early rearrangements (18), or inmice,in which 7183 and Q52 dominate early VH usage (12, 13), andIGHV5 and IGHV6 are dominant in humans (17). In fact, IGHV2 isseldom used in swine at any time in development (Fig. 3) (J. E.Butler, X. Z. Sun, N.Wertz, L.M. Lager, andG. Tobin, unpublishedobservations). Our findings are more consistent with the studies bythe Milner group that selective usage is seen at all stages of de-velopment (20).The much higher level of control of factors that might influence
Ab repertoire development during fetal life in piglets argues thatthe pattern of VH usage that we observed is intrinsic and thereforemay differ from earlier studies in mouse and human fetuses. Themapping studies provided in this paper eliminate gene position asan explanation for VH, DH, and JH expression. Although it isa mistake to extrapolate data from one mammal to another, ourfindings and the controversy in the literature make us skeptical ofany arguments that VH usage in early development is exclusivelypositionally dependent. The studies of Pospisil et al. (33) usingthe Alicia rabbit would support our skepticism.Our study does offer several insights that may be related. First is
the evidence for recent duplication within the porcine VH locus.IGHV4 (VHA) and IGHV10 (VHA*) share identical CDR1 andCDR2 regions (Table I) and differ only in one nucleotide in FR3.The latter difference allowed us to prepare a probe that coulddistinguish the expression of these two genes by probe hybrid-ization (Fig. 3, Table I). Likewise, IGHV6 (VHB) and IGHV12(VHBp) differ by only one nucleotide in CDR1. For this reason,gene-specific probes for VHB do not distinguish between IGHV6and IGHV12 so that usage of both is included in VHB usage (Fig.3). Other similarities suggest that IGHV9P to IGHV14 andIGHV3P to IGHV8 (Fig. 1) may be recent duplicons. Similar du-plicons have been reported in the human VH genome (52). Thus,whatever factors control VH usage would be likely to affect all ofthe genes in each of these duplicon cassettes. Although overall VH
usage is not positional, proportional usage for VH genes withineach cassette may be the case (e.g., IGHV3P to IGHV8 in the firstcassette and IGHV9P to IGHV14 in the second cassette).Swine genetics, especially the fine genetics of lymphocyte
receptors, are still in infancy compared with mouse genetics. Mostof the nearly 30 VH genes described for swine were mostly re-covered from outbred farm pigs so that the number very likelycontains numerous alleles (9). The BAC library used in this studywas made from the Large White breed that was interbred at In-stitute Nationale Recherche Agronomique, whereas the data pre-sented in Fig. 3 were derived from United States animals, largelyLandrace, Yorkshires, and their crosses that are preferred overinbred animals for fecundity, health, and absence of viral disease,all of which are also important criteria for their use in fetal andneonatal isolator studies. We know from studies on Ig genetics thateven randomly inbred swine can be homozygous in the IGHC locus(53). This backgroundmight therefore explain one of two troublingobservations made in this study. The first concerns our failure tolocalize VHC within the region of the VH locus that was mapped,despite its prominent expression (Fig. 3) (9, 39, 40). IGHV14(VHY) (Fig. 1, Table II) shares CDR1 with VHC and CDR2 withIGHV4 (VHA) and IGHV10 (VHA*); all porcine VH genes haveessentially identical framework sequences. It is altogether possiblethat IGHV14 (VHY) and VHC are alleles and the BAC library cameT
able
IV.
IGHJgenes
detectedin
thisstudy
Gene
9-m
er23-m
er7-m
erIG
HJ(bp)
ReadingFrame
Sequence
andDeducedAminoAcidSequence
IGHJ1
GGTTCTGTG
TGCCAGGGCCTGGGTGGGCACAT
TGGTGTG
54
GCCATGGCTACTTAGATTCGTGGGGCCAGGGCATCCTGGTCACCGTCTCCTCAG
IA
MAT*IR
GA
RA
SW
SPSPQ
IIPW
LLR
FV
GPG
HPG
HR
LL
III
HG
YLD
SW
GQ
GILV
TV
SS
IGHJ2
GTGTATTTG
TCAAGGAGGGGCAACAGGGTGCA
GACTGTG
53
CCCCTGGAAACTTGACCACTGGGGCAGGGGCGTCCTGGTCACCGTCTCCTCAG
IPLET*PLG
QG
RPG
HR
LL
IIPW
KLD
HW
GR
GV
LV
TV
SS
III
PG
NLTTG
AG
ASW
SPSPQ
IGHJ3
GGTTTTTGGa
ACACCCCCTAATGGGGGCCACAG
CACTGTGa
48
ACCATCTTCACAGCTGGGGCCGAGGAGTCGAGGTCACCGTCTCCTCAG
ITIFTA
GA
EESR
SPSPQ
IIPSSQ
LG
PR
SR
GH
RLL
III
HLH
SW
GR
GV
EV
TV
SS
IGHJ4
CTTTCTTAAa
CTGGGATCCGGGCTTAGTTGTCG
CAATGTG
51
ACAACGGGCTCGAAAGCTGGGGCCAGGGGACCCTAGTCTACGACGCCTCGG
ITTG
SK
AG
AR
GP*STTPR
IIQ
RA
RK
LG
PG
DPSLRRL
III
NG
LESW
GQ
GTLV
YD
AS
IGHJ5
AGGTTTTTGa
TGGGGCGAGCCTGGAGATTGCAC
CACTGTGa
54
ATTACTATGCTATGGATCTCTGGGGCCCAGGCGTTGAAGTCGTCGTGTCCTCAG
IITM
LW
ISG
AQ
ALK
SSC
PQ
IILLCY
GSLG
PRR*SRRV
L
III
YYA
MD
LW
GPG
VEV
VV
SS
Boldface
textindicates
only
expressed
Jregion.
aCanonical
heptamersandnonam
ers.
pStopcodon.
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A
B
C
FIGURE 2. A, Phylogenetic tree of porcine IGHV genes detected in this study. Human b2-microglobulin (huB2M: NM_004048.2) was used as an
unrelated reference. Exon 2 sequences (or sequences corresponding to exon 2 of functional IGHV segments) were used for the alignment. Because all
porcine VH genes belong to the VH3 family of clan III, we designated the various subgroups as VH3-1, -2, and -3, respectively. Bootstrap values for 1000
replicates are indicated beside the branches. B, Genomic structure in the vicinity of the region coding IGHV. Repetitive sequences such as LINE/L1 and
PRE1 are indicated by black boxes. IGHV genes are indicated by white boxes. Areas surrounded by dashed lines are highly conserved regions. C,
Phylogenetic tree estimating the divergence of the two major duplicons within the mapped locus. Line, long interspersed nucleotide element; Pre, porcine
repeat element family belonging to short interspersed nucleotide elements.
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from a swine homozygous for IGHV14. The second observationconcerns IGHV5 (VHT) that is expressed in low frequency in out-bred North American swine (9). However, based on its position inthe first duplicon (Fig. 1), high expression might be expected.IGHV5 (VHT) shares CDR1 with IGHV8 (VHE) and CDR2 withIGHV11 (VHF), respectively. Because all three (IGHV5, IGHV8,and IGHV11) map to separate loci, IGHV5 cannot be an allele ofeither IGHV8 or IGHV11. Recent progress with the porcine ge-nome project might resolve these issues.Although the gene mapping studies we present can explain the
expression of only two DH segments and one JH, they fail to ex-plain the basis of selection for VH gene usage and expression.Clearly, it is not position in the locus. At DG30 in liver, there isvery little transcription and no BCR expression as determined byflow cytometry and immunohistochemistry (54). Because this isnot true at DG95, the changes in VH usage in fetal BCRs at DG95could be due to selection by intrinsic ligands for B cells that usecertain VH genes to form their BCRs.Theories to explain positive selection of B cells expressing
certain surface receptors date to the pre-B selection hypothesis ofMelchers (55) and the work of Pospisil et al. (56). The latterstudies used Alicia rabbits that carry a deficient VH1. These rab-bits show increased expression of a VH1-like gene that was gen-erated by gene conversion following gut colonization. Asindicated above, the authentic VH1 gene is normally used in.90% of rearrangements in newborn rabbits (18). These ob-servations by Melchers (55) and the Pospisil team (56) can beinterpreted to mean that B cells at certain stages of developmentdisplay BCRs that are recognized by stromal receptors that pro-mote their survival and proliferation.The dominant role of CDR3 in determining Ab specificity is well
acceptedandwasexperimentallyshowninstudiesbyPadlan(57)andXu and Davis (58). The latter group showed that mice with a singleVH gene could make Abs to nearly all of the same Ags as controllittermates with a full germline VH repertoire as long as the DH andJH region was intact. Because of limited VH, DH, and JH usage inswine, we estimated that .95% of the repertoire is determined byCDR3 (59). In the case of TCR,CDR1andCDR2 are purported to bemainly responsible for MHC recognition, whereas CDR3 is re-sponsible for peptide (Ag) recognition. Because TCR and BCR arestructural and genetic homologs, what is true for the goose may alsobe true for the gander. Perhaps VH usage by surviving B cells in
swine is a result of their recognition by certain stromal receptors thatrecognize epitopes expressed in FRs due to the conformation im-posed by theVHgenes theyuse. Perhaps this also explains the data ofPospisil et al. (56) in rabbits with a mutated VH1 gens.Finally, our data reveal that porcine IgG3, regarded as the an-
cestral IgG of swine (41) and which comprise 60% of all IgG ex-pression in the fetal IPP (25), is most 39 proximal to Cd. Becausespeciation preceded subclass diversification, IgG3 in swine, human,and mouse are not homologous genes (1, 41). Coincidentally, theCg gene called IgG3 in all three species is the most 59 Cg gene andappears to be involved in early natural Ab responses to bacteriasuch as those expressed by marginal zone B cells. In swine, thedominant expression of IgG3 in the fetal IPP of piglets would beconsistent with this concept because the IPP is considered the site ofAg-independent repertoire development (29).Our data argue that there is a practical reason to understand how
the IgH locus is organized and how the Ab repertoire is developed,and, in this case, to expose the Achilles’ heel of a species thatsupplies 60% of the world’s meat supply. Although a mutation ofVH1 in the Alicia still allows rabbits a second chance, probably bygene conversion, a mutation of JH5 in pigs destroys the entire Absystem of this species, as has been experimentally demonstrated(M. Mendicino et al., personal communication). Thus, JH5 of swinerepresents a deleterious genetic target of spontaneous or designedmutation.
DisclosuresThe authors have no financial conflicts of interest.
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FIGURE 3. Proportional usage of major porcine VH genes in VDJ re-
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Corrections
Eguchi-Ogawa, T., N. Wertz, X.-Z. Sun, F. Puimi, H. Uenishi, K. Wells, P. Chardon, G. J. Tobin, and J. E. Butler. 2010. Antibody repertoiredevelopment in fetal and neonatal piglets. XI. The relationship of variable heavy chain gene usage and the genomic organization of thevariable heavy chain locus. J. Immunol. 184: 3734–3742.
The fourth author’s name was published incorrectly. The correct spelling is Francois Piumi.
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