Distribution of the CD4 Alleles in Sus scrofa Demonstrates the Genetic Profiles of Western Breeds and Miniature Pigs.

Widely used antipig CD4 monoclonal antibodies (mAbs) fail to recognize CD4 alleles characteristic of miniature pig lines such as the National Institutes of Health (NIH) miniature pigs and microminipigs. We surveyed polymorphisms in the coding sequence of the porcine CD4 gene among Western and Oriental pig breeds and Japanese wild boars and investigated their distribution. Of the 13 alleles that we identified among the 47 animals, 2 in group I and 3 in group II were found exclusively in Western breed pigs. Group IV alleles, which included mAb-nonbinding alleles, were found frequently in Oriental breed pigs, suggesting that the mAb-nonbinding allele arose from the gene pool of Oriental pigs. Group IV alleles were also found in Duroc and Large White pigs, suggesting genetic inflow from Oriental pig breeds into Western breeds. Comparison of the CD4 sequences of species in Cetartiodactyla suggested that the group IV alleles in Sus scrofa occurred before the divergence of this species from the other artiodactyls. The different antibody specificities of the various CD4 alleles may facilitate the discrimination of T-cell populations in transplantation studies using miniature pigs. The significance of the preservation of CD4 polymorphisms to immune function in pigs warrants further investigation.

First Complete Genome Sequence of the Skin-Improving Lactobacillus curvatus Strain FBA2, Isolated from Fermented Vegetables, Determined by PacBio Single-Molecule Real-Time Technology.

The first complete genome sequence of Lactobacillus curvatus was determined by PacBio RS II. The single circular chromosome (1,848,756 bp, G+C content of 42.1%) of L. curvatus FBA2, isolated from fermented vegetables, contained low G+C regions (26.9% minimum) and 43 sets of >1,000-bp identical sequence pairs. No plasmids were detected.

Generation and characterization of RAG2 knockout pigs as animal model for severe combined immunodeficiency.

Pigs with severe combined immunodeficiency (SCID) are versatile animal models for human medical research because of their biological similarities to humans, suitable body size, and longevity for practical research. SCID pigs with defined mutation(s) can be an invaluable tool for research on porcine immunity. In this study, we produced RAG2-knockout pigs via somatic cell nuclear transfer and analyzed their phenotype. The V(D)J recombination processes were confirmed as being inactivated. They consistently lacked mature T and B cells but had substantial numbers of cells considered to be T- or B-cell progenitors as well as NK cells. They also lacked thymic medulla and lymphoid aggregations in the spleen, mesenteric lymph nodes, and ileal Peyer's patches. We showed more severe immunological defects in the RAG2 and IL2RG double-knockout pig through this study. Thus, SCID pigs could be promising animal models not only for translational medical research but also for immunological studies of pigs themselves.

Large-scale sequencing based on full-length-enriched cDNA libraries in pigs: contribution to annotation of the pig genome draft sequence.

BACKGROUND: Along with the draft sequencing of the pig genome, which has been completed by an international consortium, collection of the nucleotide sequences of genes expressed in various tissues and determination of entire cDNA sequences are necessary for investigations of gene function. The sequences of expressed genes are also useful for genome annotation, which is important for isolating the genes responsible for particular traits. RESULTS: We performed a large-scale expressed sequence tag (EST) analysis in pigs by using 32 full-length-enriched cDNA libraries derived from 28 kinds of tissues and cells, including seven tissues (brain, cerebellum, colon, hypothalamus, inguinal lymph node, ovary, and spleen) derived from pigs that were cloned from a sow subjected to genome sequencing. We obtained more than 330,000 EST reads from the 5'-ends of the cDNA clones. Comparison with human and bovine gene catalogs revealed that the ESTs corresponded to at least 15,000 genes. cDNA clones representing contigs and singlets generated by assembly of the EST reads were subjected to full-length determination of inserts. We have finished sequencing 31,079 cDNA clones corresponding to more than 12,000 genes. Mapping of the sequences of these cDNA clones on the draft sequence of the pig genome has indicated that the clones are derived from about 15,000 independent loci on the pig genome. CONCLUSIONS: ESTs and cDNA sequences derived from full-length-enriched libraries are valuable for annotation of the draft sequence of the pig genome. This information will also contribute to the exploration of promoter sequences on the genome and to molecular biology-based analyses in pigs.

Structure of the genomic sequence comprising the immunoglobulin heavy constant (IGHC) genes from Sus scrofa.

The number of immunoglobulin heavy chain (IGH) constant genes (IGHC) varies among mammals. To annotate the porcine IGHC genes, we sequenced the entire IGHC-containing genomic region from a single porcine haplotype. The resulting contiguous sequence included in 5' the IGH diversity (D) gene cluster and in 3' TMEM121, which flank the IGHC cluster in the human genome, suggesting that we had obtained the entire genomic region containing porcine IGHC. This region was about 190-kb long, in good agreement with those of other mammals. The porcine IGHC cluster contained 10 genes, IGHM, IGHD, six IGHG genes, IGHE and IGHA. The porcine IGHG genes formed a cluster between IGHD and IGHE, with IGHG3 considered as the most ancient IGHG gene, located at the beginning of the IGHG cluster. Furthermore, the porcine sequence contained two IGHG5 and two IGHG6 genes, but no IGHG genes for IgG2 and IgG4, suggesting flexibility within the IGHG cluster. We also recorded structural differences in the switch regions of the IGHC genes that may be important in their transcription. This haplotype can serve as a reference for future studies on other haplotypes and for functional analysis of porcine immunoglobulin (IG) isotypes.

A rapid and cost-effective method for sequencing pooled cDNA clones by using a combination of transposon insertion and Gateway technology.

Large-scale cDNA-sequencing projects require an efficient strategy for mass sequencing. Here we describe a method for sequencing pooled cDNA clones using a combination of transposon insertion and Gateway technology. Our method reduces the number of shotgun clones that are unsuitable for reconstruction of cDNA sequences, and has the advantage of reducing the total costs of the sequencing project.

Cloning, expression, and polymorphisms of natural killer cell receptor NCR1 in pigs.

NCR1 (NKp46) is expressed on the surfaces of natural killer cells and recognizes hemagglutinin on the influenza virus. We cloned the NCR1 gene in pigs and found that porcine NCR1 was minimally expressed in the thymus, suggesting that NCR1 could be a useful marker of natural killer cells in pigs. We observed three nonsynonymous single nucleotide polymorphisms and one deletion of three nucleotides in the coding sequence of porcine NCR1; these may affect the function of NCR1. The polymorphisms detected here may be useful markers for breeding for influenza resistance in pigs.

Antibody repertoire development in fetal and neonatal piglets. XI. The relationship of variable heavy chain gene usage and the genomic organization of the variable heavy chain locus.

In this study, we have mapped the 3' H chain V region (V(H)) genes and those in the H chain diversity, H chain joining, and 5' portion of the H chain constant locus. We show that swine possess only two functional H chain diversity segments and only one functional H chain joining segment. These data help to explain more 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, Cmu, and Cdelta while revealing that the ancestral IgG3 is the most 5' Cgamma gene. We also observed a recent duplication ( approximately 1.6 million years ago) in the V(H) locus that contains six of the seven V(H) genes that comprise 75% of the preimmune repertoire. Because there are no known transfers of immune regulators or Ags that cross the placenta as in mice and humans, fetal V(H) usage must be intrinsically regulated. Therefore, we quantified V(H) usage in fetal piglets and demonstrated that usage is independent of the position of V(H) genes in the genome; the most 3' functional V(H) gene (IGHV2) is rarely used, whereas certain upstream genes (IGHV14 and IGHV15) are predominately used early in fetal liver but seldom thereafter. Similar to previous studies, three V(H) genes account for 40% of the repertoire and six for approximately 70%. This limited combinatorial diversity of the porcine V(H) repertoire further emphasizes the dependence on CDR3 diversity for generating the preimmune Ab repertoire of this species.

Influence of polymorphisms in porcine NOD2 on ligand recognition.

Nucleotide oligomerization domain 2 (NOD2) is a cytosolic pattern recognition receptor (PRR) that responds to muramyldipeptide (MDP), a component of peptidoglycans of gram positive and negative bacteria. NOD2 is involved in the modulation of signaling pathways for other PRRs, such as Toll-like receptors. Polymorphisms in NOD2 may evoke bowel disorders, and human Crohn's disease is significantly correlated with mis-sense insertion of the NOD2 gene. Such polymorphisms affecting ligand recognition in the NOD2 gene may also influence bowel flora in livestock, which is compromised by bowel diseases such as diarrhea. We investigated the functional variance of mis-sense polymorphisms in ligand recognition by porcine NOD2. The 1949T>C polymorphism, located in the region encoding the hinge domain of the molecule, notably diminished the functional response of porcine NOD2 to MDP. By comparison, the 2197A>C polymorphism, localized in the region corresponding to leucine-rich repeats, significantly augmented the response of porcine NOD2 to the ligand. The 1949C allele was rare among pig breeds, suggesting that this mutation is a disadvantage to pigs in their immune response to microbes. The 2197C allele, in contrast, was widely distributed among Western breeds and is most likely to be derived from wild boars in Asia. This is the first report of a causal relationship between molecular function and polymorphisms in PRRs in non-primate, non-rodent mammals. These findings suggest that the 2197C allele might confer an immune response advantage in modern pig breeds and may be a useful marker for breeding aimed at disease resistance in pigs.

Genomic structure of the whole D-J-C clusters and the upstream region coding V segments of the TRB locus in pig.

In the vertebrate immune system, T cells play a central role in host defense against microbial or viral infection. Previous studies suggested that at least two sets of TRBD-J-C clusters are harbored in the porcine genome. In this study, we determined 212,193 bp of a continuous porcine genomic sequence covering the entire TRBC region. EPHB6, TRPV6, TRY, and ten TRBV genes were conserved in the vicinity of the TRBD-J-C clusters. Interestingly, three TRBD-J-C clusters were identified in this sequence; each TRBD-J-C cluster consisted of one TRBD and seven TRBJ segments, with one TRBC region composed of four exons. The distribution of repetitive sequences and phylogenetic analysis indicated that the TRBD-J-C cluster, located at the center of the three clusters identified, had a structure combined with the others. Most of the TRBJ segments were available in public databases, suggesting that all three TRBD-J-C clusters are functional in pigs.

Genomic sequence encoding diversity segments of the pig TCR delta chain gene demonstrates productivity of highly diversified repertoire.

To better understand the function and diversity of gammadelta T cells, we determined the genomic sequence encoding diversity (D) segments of the porcine TCR delta chain and its upstream regions, because pigs and other artiodactyls have relatively high proportions of gammadelta T cells. The revealed sequence contained 28 variable (V) alpha/delta segments, including 4 TRDV1 and at least 6 Ddelta segments, a much higher number than in humans and mice. All 6 of the Ddelta segments that had canonical recombination signal sequences were functionally utilized in expressed TCR delta chain genes. The multiplicity of Ddelta segments enabled the use of more than 3 Ddelta segments in a single functional TCR delta chain. The increased number of TCR delta segments was acquired by the duplication of the germline sequence, which occurred after the divergence of artiodactyls from primates and rodents. These data demonstrate that the pig is able to generate a highly diversified repertoire of TCR delta chain molecules.

PEDE (Pig EST Data Explorer) has been expanded into Pig Expression Data Explorer, including 10 147 porcine full-length cDNA sequences.

We formerly released the porcine expressed sequence tag (EST) database Pig EST Data Explorer (PEDE; http://pede.dna.affrc.go.jp/), which comprised 68,076 high-quality ESTs obtained by using full-length-enriched cDNA libraries derived from seven tissues. We have added eight tissues and cell types to the EST analysis and have integrated 94,555 additional high-quality ESTs into the database. We also fully sequenced the inserts of 10,147 of the cDNA clones that had undergone EST analysis; the sequences and annotation of the cDNA clones were stored in the database. Further, we constructed an interface that can be used to perform various searches in the database. The PEDE database is the primary resource of expressed pig genes that are supported by full-length cDNA sequences. This resource not only enables us to pick cDNA clones of interest for a particular analysis, but it also confirms and thus contributes to the sequencing integrity of the pig genome, which is now being compiled by an international consortium (http://www.piggenome.org/). PEDE has therefore evolved into what we now call 'Pig Expression Data Explorer'.

Analysis of the genomic structure of the porcine CD1 gene cluster.

CD1 is an MHC class I-like protein that presents lipid antigens to T cell receptors. We determined 470,187 bp of the genomic sequence encompassing the region encoding porcine CD1 genes. We identified 16 genes in this region and newly identified CD1A2, CD1B, CD1C, CD1D, and CD1E. Porcine CD1 genes were located in clusters between KIRREL and olfactory receptor (OR) genes, as observed in humans, although they were divided into two regions by a region encoding OR genes. Comparison of the genomic sequences of CD1 gene loci in pigs with other mammals showed that separation of the CD1 gene cluster by ORs was observed only in pigs. CD1A duplication in the porcine genome was estimated to have occurred after the divergence of the human and porcine. This analysis of the genomic sequence of the porcine CD1 family will contribute to our understanding of the evolution of mammalian CD1 genes.

Biased distribution of single nucleotide polymorphisms (SNPs) in porcine Toll-like receptor 1 (TLR1), TLR2, TLR4, TLR5, and TLR6 genes.

Toll-like receptors (TLRs) recognize various microbial components and induce immune responses. Polymorphisms in TLRs may influence their recognition of pathogen-derived molecules; swine TLRs are predicted to be associated with responses to infectious diseases such as pneumonia. In this study, we searched for single nucleotide polymorphisms (SNPs) in the coding sequences of porcine TLR1, TLR2, TLR4, TLR5, and TLR6 genes in 96 pigs from 11 breeds and elucidated 21, 11, 7, 13, and 11 SNPs, respectively, which caused amino acid substitutions in the respective TLRs. Distribution of these nonsynonymous SNPs was biased; many were located in the leucine-rich repeats, particularly in TLR1. These data demonstrated that the heterogeneity of TLR genes was preserved in various porcine breeds despite intensive breeding that was carried out for livestock improvement. It suggests that the heterogeneity in TLR genes is advantageous in increasing the possibility of survival in porcine populations.

Porcine Toll-like receptor 1, 6, and 10 genes: complete sequencing of genomic region and expression analysis.

Toll-like receptors (TLRs) recognize various microbial components and play key roles in activating the innate immune system. Hence, their function is important in swine infectious diseases. We completely determined 173,804 bp of nucleotide sequence of a genomic region including porcine TLR6 and the newly identified porcine TLR homologues TLR1 and TLR10. The porcine genomic structure of these genes was highly conserved in comparison with the corresponding region in humans. Analysis of their expression in porcine tissues showed differences in expression patterns between porcine TLR10 and TLR1 or TLR6. Moreover, phylogenetic analysis of the cytoplasmic regions of TLR genes suggested that the signal transduction pathway of TLR10 was different from those of TLR1 and TLR6. We also developed six polymorphic microsatellite markers within this genomic region; these markers will be valuable for association studies between TLR genes and resistance or susceptibility to infectious diseases in swine.

Genomic structure of eight porcine chemokine receptors and intergene sharing of an exon between CCR1 and XCR1.

We completely sequenced a 516,013-bp portion of the porcine genome that encompassed a cluster of genes for chemokine (C-C motif) receptors (CC chemokine receptors). We identified genes for six CC chemokine receptors (CCR1, CCR2, CCR3, CCR5, CCR9, and CCRL2) and two other chemokine receptors (CXCR6 and XCR1) in this region. Clarification of the entire structure of the region and the respective genes revealed their high conservation among human, mouse, and pig. Interestingly, much of the 5'UTR of porcine XCR1 shared an identical sequence with CCR1; this sharing does not occur in humans or mice. This finding suggests a mechanism for posttranscriptional switching of tandem-located genes in mammals that depends on alternative splicing. Furthermore, our findings contribute to analyses of lymphocyte trafficking and the functions of immune cells in pigs and other artiodactyls.