DQB1*0323 is the result of a gene conversion event between a DQB1*06 and a DQB1*030303 allele

A novel human leukocyte antigen-DQB1 allele, DQB1*0323, was identified in a volunteer hematopoietic stem cell donor. DQB1*0323 differs from the closely related allele DQB1*030303 in five nucleotide positions.     

A novel DRB1*13 allele (DRB1*1327) on a DR17, DQ2 haplotype with a DRB1*0301 sequence motif in the 2nd hyperpolymorphic region

In a sample from a Netherlands Caucasian, we found a new DRB1*13 allele ( DRB1*1327 ). The nucleotide sequence of the second exon of the novel allele was identical to DRB1*1301 except for a single productive base substitution changing codon 26 from TTC to TAC, encoding phenylalanine and tyrosine, respectively. The new allele shares sequence with DRB1*03011 from codons 5 to 66. The haplotype carrying the new allele was, from known linkage disequilibria, deduced to be DRB1*1327, DRB3*0101, DQA1*05011, DQB1*0201 , i.e. similar to the DR17, DQ2 haplotype, which suggests that the DRB1*1327 allele has arisen by a double recombination event between a DR13 donor haplotype and a DR17, DQ2 recipient haplotype.     

Identification of a new HLA-DRB1 allele (DRB1*0318) in three members of a Caucasian Spanish family

This communication reports the identification of a new allele HLA-DRB1*03 in three members of a Caucasian Spanish family. The new allele has been officially named HLA-DRB1*0318 by the World Health Organization Nomenclature Committee. The exon 2 sequence of this new allele is identical to that of DRB1*03011 except for the first nucleotide of codon 45. The nucleotide change (C replacing G) leads to the amino acid substitution of glycine to arginine (GGG-->CGG) at position 45. This position of the beta1 domain shows very little polymorphism among DRB1* alleles (nucleotide changes at this position have only been reported for DRB1*1436 and DRB1*0105) and locates in the vicinity of the highly polymorphic position 47, which is a constituent of the groove's pocket interacting with the amino acid position 7 of the antigen peptide. The familial study showed that the new allele was maternally transmitted into the HLA-A*3002, -B*1801, -Cw*0501, -DRB1*0318, -DRB3*0202, -DQB1*0201 haplotype. Interestingly, the two siblings of the family, which were HLA identical and suffered of insulin-dependent diabetes mellitus (IDDM), were carriers of the two HLA haplotypes (DRB1*03/DQB1*0201 and DRB1*04/DQB1*0302) reported as susceptibility markers to IDDM in Caucasians.     

Characterization of a new HLA-DRB1*01 allele (HLA-DRB1*010203) in a Caucasian Italian family by using sequence-based typing

We report the identification of an HLA-DRB1*01 nucleotide sequence variant in three members of a Caucasian Italian family by using sequence-based typing. The nucleotide sequence of exon 2 observed in the new allele is identical to that of HLA-DRB1*010201 except in position 189 (codon 34) where the adenine of the consensus was replaced by a guanine and it was designated officially as HLA-DRB1*010203* by the WHO Nomenclature Committee.     

The roles of the RAG1 and RAG2 “non-core” regions in V(D)J recombination and lymphocyte development

The enormous repertoire of the vertebrate specific immune system relies on the rearrangement of discrete gene segments into intact antigen receptor genes during the early stages of B-and T-cell development. This V(D)J recombination is initiated by a lymphoid-specific recombinase comprising the RAG1 and RAG2 proteins, which introduces double-strand breaks in the DNA adjacent to the coding segments. Much of the biochemical research into V(D)J recombination has focused on truncated or “core” fragments of RAG1 and RAG2, which lack approximately one third of the amino acids from each. However, genetic analyses of SCID and Omenn syndrome patients indicate that residues outside the cores are essential to normal immune development. This is in agreement with the striking degree of conservation across all vertebrate classes in certain non-core domains. Work from multiple laboratories has shed light on activities resident within these domains, including ubiquitin ligase activity and KPNA1 binding by the RING finger domain of RAG1 and the recognition of specific chromatin modifications as well as phosphoinositide binding by the PHD module of RAG2. In addition, elements outside of the cores are necessary for regulated protein expression and turnover. Here the current state of knowledge is reviewed regarding the non-core regions of RAG1 and RAG2 and how these findings contribute to our broader understanding of recombination.     

Polymorphism of human HLA-DRB1 antigens generated by genetic exchange between DR2 (DRB1*15011) and DR6 (DRB1*1405) alleles: a novel DRB1 allele (DRB1*1437) identified in a Paiwan tribe member of Taiwan

We report herein the identification of a new DRB1 allele using sequence-based typing (SBT). This novel allele, HLA-DRB1*1437, was found in an aboriginal individual from the Paiwan tribe in the southern part of Taiwan. This individual was typed by SBT method as having an HLA genotype of HLA-A*02011/0203, HLA-B*15011/3901, HLA-DRB1*11011/1437, HLA-DRB3*0202/0202, and HLA-DPB1*0501/1301. This new allele differs from DRB1*1309 in the 5'-end nucleotide sequence of polymorphic exon 2 at codon 16 (CAT-->CAA; H16Q), codon 37 (AAC-->TTC; R37F), codon 47 (TTC-->TAC; F47Y), and codon 58 (GCC-->GCT; both specify alanine). By sequence comparison, it was found that this new allele has a 5'-end sequence (from amino acid residues 7 to 66) identical to that found in the DRB1*1405 allele and a 3'-end sequence (from amino acid residues 58 to 94) identical to that found in the DRB1*15011 allele. Both DRB1*1405 and DRB1*15011 alleles have been identified among the Paiwan members (Note).     

Non-homologous recombination between Alu and LINE-1 repeats caused a 430-kb deletion in the dystrophin gene: a novel source of genomic instability

Although large deletions in the dystrophin gene have been identified in more than two-thirds of Duchenne and Becker muscular dystrophy patients, the molecular mechanisms that lead to the generation of these deletions are largely unknown. Here, Alu and LINE-1 (L1) repetitive elements were shown to be present at one or other of the two ends, respectively, of a 430-kb deletion in the dystrophin gene. The breakpoint of the deletion, which stretches from exons 2 to 7, was defined more precisely by polymerase chain reaction (PCR) walking on introns 1 and 7. Finally, the region containing the breakpoint was amplified as a fragment of more than 10 kb. Sequencing of the deletion endpoint revealed the presence of an Alu sequence in intron 1, 25 kb downstream from the 3′ end of exon 1 that was joined directly to an L1 sequence in intron 7, 4.5 kb downstream from the 3′ end of exon 7. The deletion was calculated to be 430 kb. To our knowledge, this is a novel recombination event joining non-homologous Alu and L1 repeats, and is the largest known intrachromosomal deletion that is thought to involve repetitive genetic elements. Sequence characteristics around the breakpoint are discussed. Received: July 10, 2000 / Accepted: August 23, 2000     

An HLA-DR11/DQ3 haplotype with a DRB1*0301 sequence motif in the third hypervariable region of the HLA-DR beta-1 chain: molecular and serological analysis of its generation in a European Caucasian family

The formation of a new human leukocyte antigen (HLA)-DRB1 allele (DRB1*0340) has been detected during the routine testing of a European Caucasian blood and potential stem cell donor and his family. HLA typing of the donor with two polymerase chain reaction - sequence specific oligonucleotides (PCR-SSO) systems yielded inconclusive results. HLA typing of the family members including sequence-based typing of DRB1 in both directions after haplotype-specific amplification showed that the allele had most likely formed by a double crossover event in exon 2 of the DRB1 gene. The HLA haplotype containing the new allele was most probably derived from the father, who was typed as HLA-DRB1*0301,*1101 and DRB3*0101,*0202. The comparison of the sequences of the paternal DRB1 and DRB3 alleles with the exon 2 sequence of the DRB1*0340 showed that it had most likely formed through an uptake of at least the sequence part codons 58–77 of DRB1*0301 (donor) by DRB1*1101 (acceptor). We suppose that the recombination sites are located in the sequences from codons 38–57 and codons 78–88. At the protein level, more than 50% of the alpha-helical structure of the DRB1*1101 chain is replaced by a DRB1*0301-derived sequence with the exchange of several amino acids. Serological typing of the allele showed HLA-DR3. However, one monoclonal anti-DR11 of five DR11-reactive antibodies reacted positive, which might indicate residual immunogenic epitopes of DRB1*1101. HLA alleles that are most similar to HLA-DRB1*0340 are DRB1*030501, *0317, *0329 and *1107 with at least four amino acid differences in exon 2. In conclusion, HLA-DRB1*0340 is a new allele with unique properties compared with other known HLA-DRB alleles with regard to antigenicity, T-cell receptor-binding and peptide-binding possibilities.     

X-linked mental retardation exhibiting linkage to DXS255 and PGKP1: a new MRX family (MRX14) with localization in the pericentromeric region

Gene localization was determined by linkage analysis in a large French family with X-linked mental retardation (MRX). Seven living affected males were clinically studied and the clinical picture was characterized by moderate to severe mental handicap with poor secondary speech acquisition. Seizures, slight microcephaly, simian crease, anteverted pinnae, and macroorchidism were observed in some patients only. Linkage analysis revealed no recombination between the MRX gene and two loci: DXS255 at Xp11.22 (Zmax = 3.31 at θ= 0.00) and PGKP1 at Xq11.2-q12 (Zmax = 3.08 at 9 = 0.00). One recombination was observed between the gene and the two loci DXS164 at Xp21.2 and DXS441 at Xq13.3, respectively. These results suggested gene localization in the pericentromeric region of the X chromosome, and the LOD scores justified assignment of the symbol MRX14 to this family.     

Brain γ‐aminobutyric acid (GABA) detection in vivo with the J‐editing 1H MRS technique: a comprehensive methodological evaluation of sensitivity enhancement,macromolecule contamination and test–retest reliability

Abnormalities in brain γ‐aminobutyric acid (GABA) have been implicated in various neuropsychiatric and neurological disorders. However, in vivo GABA detection by ¹H MRS presents significant challenges arising from the low brain concentration, overlap by much stronger resonances and contamination by mobile macromolecule (MM) signals. This study addresses these impediments to reliable brain GABA detection with the J‐editing difference technique on a 3‐T MR system in healthy human subjects by: (i) assessing the sensitivity gains attainable with an eight‐channel phased‐array head coil; (ii) determining the magnitude and anatomic variation of the contamination of GABA by MM; and (iii) estimating the test–retest reliability of the measurement of GABA with this method. Sensitivity gains and test–retest reliability were examined in the dorsolateral prefrontal cortex (DLPFC), whereas MM levels were compared across three cortical regions: DLPFC, the medial prefrontal cortex (MPFC) and the occipital cortex (OCC). A three‐fold higher GABA detection sensitivity was attained with the eight‐channel head coil compared with the standard single‐channel head coil in DLPFC. Despite significant anatomical variation in GABA + MM and MM across the three brain regions (p < 0.05), the contribution of MM to GABA + MM was relatively stable across the three voxels, ranging from 41% to 49%, a non‐significant regional variation (p = 0.58). The test–retest reliability of GABA measurement, expressed as either the ratio to voxel tissue water (W) or to total creatine, was found to be very high for both the single‐channel coil and the eight‐channel phased‐array coil. For the eight‐channel coil, for example, Pearson's correlation coefficient of test vs. retest for GABA/W was 0.98 (R² = 0.96, p = 0.0007), the percentage coefficient of variation (CV) was 1.25% and the intraclass correlation coefficient (ICC) was 0.98. Similar reliability was also found for the co‐edited resonance of combined glutamate and glutamine (Glx) for both coils. Copyright © 2016 John Wiley & Sons, Ltd.