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HLA‐DRB1*13:99, a novel HLA‐DRB1*13 allele identified by sequence‐based typing
Ko, S.‐,Y.,Oh, H.‐,B.,Heo, Y.‐,S.,Jun, J. H.,Kwon, O.‐,J. Blackwell Publishing Ltd 2011 Tissue antigens Vol.77 No.4
<P>The new allele DRB1*13:99 showed one nucleotide difference with DRB1*13:02:01 at codon 51 (ACG/AAG).</P>
Identification of a novel <i>HLA‐B*40</i> null allele, <i>HLAB*40:155N</i>
Ko, S.‐,Y.,Oh, H.‐,B.,Cho, M.‐,C.,Park, N.,Kwon, O.‐,J. Blackwell Publishing Ltd 2011 Tissue antigens Vol.78 No.2
<P>The new allele B*40:155N showed five nucleotide insertion between nucleotide 594 and 595 (codon 174 and 175) compared to B*40:01:01.</P>
A novel HLA‐A*31 allele, A*31:34, identified by sequence‐based typing
Ko, S.‐,Y.,Oh, H.‐,B.,Heo, Y.‐,S.,Jun, J. H.,Kwon, O.‐,J. Blackwell Publishing Ltd 2011 Tissue antigens Vol.77 No.1
<P>New allele A*31:34 showed one nucleotide difference with A*31:01:02 at codon 166 (GAG/CAG).</P>
Sequencing of a new HLA‐A allele: <i>HLA‐A*11:01:54</i>
Ko, S.‐,Y.,Oh, H.‐,B.,Jun, J.‐,H.,Kwon, O.‐,J. Blackwell Publishing Ltd 2014 Tissue antigens Vol.83 No.5
<P><B>Abstract</B></P><P>The new allele <I>A*11:01:54</I> shows one nucleotide difference from <I>A*11:01:01</I> at codon 35 (CGG/AGG).</P>
B*39:60, a novel HLA‐B*39 allele identified by sequence‐based typing
Ko, S.‐,Y.,Oh, H.‐,B.,Heo, Y.‐,S.,Jun, J. H.,Kwon, O.‐,J. Blackwell Publishing Ltd 2011 Tissue antigens Vol.77 No.2
<P>The new allele B*39:60 showed one nucleotide difference with B*39:01:01 at codon 152 (GTG/GCG).</P>
A processed HLA‐A*24:02 pseudogene found in the peripheral blood of a father and his son
Ko, S.‐,Y.,Oh, H.‐,B.,Sohn, Y.‐,H.,Jun, J.,Kwon, O.‐,J. Blackwell Publishing Ltd 2011 Tissue antigens Vol.77 No.3
<P>We encountered a case that exhibited a discrepancy in human leukocyte antigen‐A (HLA‐A) type determined by sequence‐based typing (SBT) and sequence‐specific primer (SSP) molecular typing. The child of this case was identified as <I>A</I><SUP>*</SUP><I>02:01</I> homozygote and <I>A</I><SUP>*</SUP><I>02</I>, <I>A</I><SUP>*</SUP><I>24</I>, respectively. The HLA‐A type of his father was <I>A</I><SUP>*</SUP><I>02:01</I>, <I>26:01</I>, but low‐resolution SSP also showed unexpected amplification with <I>A</I><SUP>*</SUP><I>24</I> primers as with the child. Serologic typing of the child and the father was A2/blank and A2/A26, respectively. Sequencing analysis of the <I>A</I><SUP>*</SUP><I>24</I> variant in the child and the father showed a complete deletion of all introns of the <I>A</I><SUP>*</SUP><I>24:02</I> allele. Though rare, this type of processed pseudogene variant can be one of the causes of discrepancies between high‐ and low‐resolution HLA typing.</P>
OUT-OF-PILE MECHANICAL PERFORMANCE AND MICROSTRUCTURE OF RECRYSTALLIZED ZR-1.5 NB-O-S ALLOYS
Ko, S.,Lee, J.M.,Hong, S.I. Korean Nuclear Society 2011 Nuclear Engineering and Technology Vol.43 No.5
The out-of-pile mechanical performance and microstructure of recrystallized Zr-1.5 Nb-S alloy was investigated. The strength of the recrystallized Zr-1.5Nb-O-S alloys was observed to increase with the addition of sulfur over a wide temperature range, from room temperature up to $300^{\circ}C$. A yield drop and stress serrations due to dynamic strain were observed at room temperature and $300^{\circ}C$. Wavy and curved dislocations and loosely knit tangles were observed after strained to 0.07 at room temperature, suggesting that cross slip is easier. At $300^{\circ}C$, however, dislocations were observed to be straight and aligned along the slip plane, suggesting that cross slip is rather difficult. At $300^{\circ}C$, oxygen atoms are likely to exert a drag force on moving dislocations, intensifying the dynamic strain aging effect. Oxygen atoms segregated at partial dislocations of a screw dislocation with the edge component may hinder the cross slip, resulting in the rather straight dislocations distributed on the major slip planes. Recrystallized Zr-Nb-S alloys exhibited ductile fracture surfaces, supporting the beneficial effect of sulfur in zirconium alloys. Oxidation resistance in air was also found to be improved with the addition of sulfur in Zr-1.5 Nb-O alloys.