Atsuko Shigenari

Comparative sequencing of human and chimpanzee MHC class I regions unveils insertions/deletions as the major path to genomic divergence

Despite their high degree of genomic similarity, reminiscent of their relatively recent separation from each other (≈6 million years ago), the molecular basis of traits unique to humans vs. their closest relative, the chimpanzee, is largely unknown. This report describes a large-scale single-contig comparison between human and chimpanzee genomes via the sequence analysis of almost one-half of the immunologically critical MHC. This 1,750,601-bp stretch of DNA, which encompasses the entire class I along with the telomeric part of the MHC class III regions, corresponds to an orthologous 1,870,955 bp of the human HLA region. Sequence analysis confirms the existence of a high degree of sequence similarity between the two species. However, and importantly, this 98.6% sequence identity drops to only 86.7% taking into account the multiple insertions/deletions (indels) dispersed throughout the region. This is functionally exemplified by a large deletion of 95 kb between the virtual locations of human MICA and MICB genes, which results in a single hybrid chimpanzee MIC gene, in a segment of the MHC genetically linked to species-specific handling of several viral infections (HIV/SIV, hepatitis B and C) as well as susceptibility to various autoimmune diseases. Finally, if generalized, these data suggest that evolution may have used the mechanistically more drastic indels instead of the more subtle single-nucleotide substitutions for shaping the recently emerged primate species.

Rapid assignment of the swine major histocompatibility complex (SLA) class I and II genotypes in Clawn miniature swine using PCR-SSP and PCR-RFLP methods

Abstract:  Background:  Inbred miniature swine with defined novel SLA haplotypes will be useful in allo‐ and xeno‐transplantation studies, which can be carried out representing variable combinations of SLA haplotypes.

Assignment of the SLA alleles and reproductive potential of selective breeding Duroc pig lines.

Abstract:  Background:  Pigs with defined swine leukocyte antigen (SLA) haplotypes and their detailed information are useful for transplantation and immunological studies. We developed two herds of SLA homozygous Duroc pigs with novel SLA haplotypes and characterized their reproductive potential.

Genomic Sequence Analysis of the MHC Class I G/F Segment in Common Marmoset (Callithrix jacchus)

The common marmoset (Callithrix jacchus) is a New World monkey that is used frequently as a model for various human diseases. However, detailed knowledge about the MHC is still lacking. In this study, we sequenced and annotated a total of 854 kb of the common marmoset MHC region that corresponds to the HLA-A/G/F segment (Caja-G/F) between the Caja-G1 and RNF39 genes. The sequenced region contains 19 MHC class I genes, of which 14 are of the MHC-G (Caja-G) type, and 5 are of the MHC-F (Caja-F) type. Six putatively functional Caja-G and Caja-F genes (Caja-G1, Caja-G3, Caja-G7, Caja-G12, Caja-G13, and Caja-F4), 13 pseudogenes related either to Caja-G or Caja-F, three non-MHC genes (ZNRD1, PPPIR11, and RNF39), two miscRNA genes (ZNRD1-AS1 and HCG8), and one non-MHC pseudogene (ETF1P1) were identified. Phylogenetic analysis suggests segmental duplications of units consisting of basically five (four Caja-G and one Caja-F) MHC class I genes, with subsequent expansion/deletion of genes. A similar genomic organization of the Caja-G/F segment has not been observed in catarrhine primates, indicating that this genomic segment was formed in New World monkeys after the split of New World and Old World monkeys.

Polymorphic major histocompatibility complex class II Alu insertions at five loci and their association with HLA-DRB1 and -DQB1 in Japanese and Caucasians.

We investigated polymorphic Alu insertion (POALIN) frequencies at five loci in the major histocompatibility complex (MHC) class II genomic region to determine their allele and haplotype frequencies and associations with the human leukocyte antigen (HLA)-DRB1 and -DQB1 genes for 100 Japanese, 174 Australian Caucasians and 67 HLA reference cell lines obtained from different ethnic groups. The POALINs varied in frequency between 11% and 57% with significant differences between the Japanese and Caucasians at three loci. One POALIN locus deviated significantly from Hardy-Weinberg equilibrium (HWE) and four POALIN loci were in significant linkage disequilibrium and had a high percentage association with a variety of HLA-DRB1 or -DQB1 two-digit alleles. Inferred haplotype analysis among two-locus, five-locus and seven-locus haplotype structures showed maximum differences between the Japanese and Caucasians with the seven-locus haplotypes. The most common multilocus haplotype in Caucasians was DRB1*1501/DQB1*0602/AluDQ1/AluDRB1/AluORF10/AluDPB2 (6.7%), whereas the second most common allele HLA-DRB1*15 (17.5%) in Japanese was associated with three or four Alu insertions. The HLA class II POALINs also differentiated within and between HLA-DRB1 super-haplotypes DR1, DR8, DR51, DR52 and DR53. This is the first comparative population study of multilocus POALINs in the HLA class II region, which shows that POALINs whether investigated alone or together with the HLA class II alleles are informative genetic markers for the identification of allele and haplotype lineages and variations within the same and/or different populations.

Human Endogenous Retrovirus (HERVK9) Structural Polymorphism With Haplotypic HLA-A Allelic Associations

The frequency and HLA-A allelic associations of a HERVK9 DNA structural polymorphism located in close proximity to the highly polymorphic HLA-A gene within the major histocompatibility complex (MHC) genomic region were determined in Japanese, African Americans, and Australian Caucasians to better understand its human population evolutionary history. The HERVK9 insertion or deletion was detected as a 3′ LTR or a solo LTR, respectively, by separate PCR assays. The average insertion frequency of the HERVK9.HG was significantly different (P < 1.083e−6) between the Japanese (0.59) and the African Americans (0.34) or Australian Caucasians (0.37). LD analysis predicted a highly significant (P < 1.0e−5) linkage between the HLA-A and HERVK9 alleles, probably as a result of hitchhiking (linkage). Evolutionary time estimates of the solo, 5′ and 3′ LTR nucleotide sequence divergences suggest that the HERVK9 was inserted 17.3 MYA with the first structural deletion occurring 15.1 MYA. The LTR/HLA-A haplotypes appear to have been formed mostly during the past 3.9 MY. The HERVK9 insertion and deletion, detected by a simple and economical PCR method, is an informative genetic and evolutionary marker for the study of HLA-A haplotype variations, human migration, the origins of contemporary populations, and the possibility of disease associations.

SLA-DRB1 and -DQB1 genotyping by the PCR-SSOP-Luminex method.

A simple and novel genotyping method was developed to detect alleles at the swine leukocyte antigen (SLA)-DRB1 and -DQB1 class II loci by using polymerase chain reaction (PCR)-fluorescently labeled sequence-specific oligonucleotide probes (SSOPs) and Luminex 100 xMAP detection. The PCR-SSOP-Luminex method exhibited accuracy of 95% for both SLA-DRB1 and -DQB1 in 6 homozygous and 16 heterozygous pig samples as confirmed by sequencing the PCR products of the same samples. In addition, 12 low-resolution SLA class II haplotypes consisting of 7 and 9 DRB1 and DQB1 alleles were identified, respectively, in one population of 283 Landrace pigs. This genotyping method facilitates the rapid and accurate identification of two- or four-digit alleles at the SLA-DRB1 and -DQB1 loci.

Genetic variation and hitchhiking between structurally polymorphic Alu insertions and HLA-A, -B, and -C alleles and other retroelements within the MHC class I region.

We investigated structurally polymorphic Alu insertions (POALINs) at five loci in the major histocompatibility complex (MHC) class I genomic region to determine their allele and haplotype frequencies and associations with the human leukocyte antigen (HLA)-A, -B, and -C genes in three populations, the Australian Caucasians, Japanese, and African Americans. The POALINs varied in allelic frequency between 0% and 42.3% with significant differences between populations at three of the five loci. The linkage disequilibrium (LD) between Alu insertions and the HLA-A, -B, or -C alleles and previously published polymorphic retroelements (four SVA and human endogenous retrovirus type 9 (HERVK9) loci) within the class I region of the MHC were calculated in pairwise analyses of haplotypes to show strong allelic associations and possible crossing-over events between some loci. Each POALIN was in significant LD with a variety of HLA-A, -B, or -C two-digit alleles probably as a result of hitchhiking. The POALINs helped to further stratify the HLA-A:B:C haplotypes into different POALIN:HLA-A:B:C haplotype frequencies. Of the multilocus haplotype analyses, the seven- and eight-locus haplotypes showed the largest number of differences between the populations, and fewer matched haplotypes between populations that ranged, for example, from 49% for HLA-B:HLA-A haplotypes to 7% for AluMICB:HLA-B:HLA-C:AluTF:AluHJ:HLA-A:AluHG:AluTF haplotypes in the Japanese. This comparative study of multilocus POALINs in the HLA class I region of three ethnic populations shows that POALINs alone or together with the HLA class I alleles and other retroelements are informative ancestral markers for assessing the interrelationship of HLA class I haplotype lineages, LD, and genetic diversity within the same and/or different populations.

Modified S/MAR episomal vectors for stably expressing fluorescent protein-tagged transgenes with small cell-to-cell fluctuations

We modified and tested scaffold/matrix attachment region (S/MAR) episomal vectors. The new vectors would be useful in obtaining cells stably expressing fluorescent protein-tagged transgenes with small, mostly within 10-fold cell-to-cell fluctuations. In the vectors, the same transcript directs episomal replication and expression of transgene/antibiotic marker, and only antibiotic selection without any other extra steps was sufficient to obtain desired stable cells, including those expressing two different proteins simultaneously. Furthermore, the two test cases (expression of human growth hormone in AtT20 and four protein kinase C isoforms in HEK293) would prove to be useful in visualizing and analyzing regulatory processes involving these proteins.

Polymorphic SVA retrotransposons at four loci and their association with classical HLA class I alleles in Japanese, Caucasians and African Americans

Polymorphic insertion frequencies of the retrotransposons known as the “SVA” elements were investigated at four loci in the MHC class I genomic region to determine their allele and haplotype frequencies and associations with the HLA-A, -B or -C genes for 100 Japanese, 100 African Americans, 174 Australian Caucasians and 66 reference cell lines obtained from different ethnic groups. The SVA insertions representing different subfamily members varied in frequency between none for SVA-HF in Japanese and 65% for SVA-HB in Caucasians or African Americans with significant differences in frequencies between the three populations at least at three loci. The SVA loci were in Hardy–Weinberg equilibrium except for the SVA-HA locus which deviated significantly in African Americans and Caucasians possibly because of a genomic deletion of this locus in individuals with the HLA-A*24 allele. Strong linkage disequilibria and high percentage associations between the human leucocyte antigen (HLA) class I gene alleles and some of the SVA insertions were detected in all three populations in spite of significant frequency differences for the SVA and HLA class I alleles between the three populations. The highest percentage associations (>86%) were between SVA-HB and HLA-B*08, -B*27, -B*37 to -B*41, -B*52 and -B*53; SVA-HC and HLA-B*07; SVA-HA and HLA-A*03, -A*11 and -A*30; and SVA-HF and HLA-A*03 and HLA-B*47. From pairwise associations in the three populations and the homozygous cell line results, it was possible to deduce the SVA and HLA class I allelic combinations (haplotypes), population differences and the identity by descent of several common HLA-A allelic lineages.