Pretransplant Single Antigen Bead-Detected HLA Antibodies in Kidney Transplant Long-term Outcome: A Single-Center Cohort Experience.

Single-antigen bead (SAB) platform permits the identification of antibodies not detectable by complement-dependent lymphocytotoxicity test, but their clinical significance is not completely understood. The aim of this study was to evaluate whether the presence of pretransplant SAB-detected antibodies is associated with the development of allograft failure. This is a single-center cohort study with 10-year follow-up in which 573 kidney recipients with negative pretransplant complement-dependent lymphocytotoxicity crossmatch who received transplants at the Kidney Transplant Center of Policlinico, Milan, from deceased donors between 1996 and 2005 were evaluated. Pretransplant plasma samples were retrospectively analyzed by SAB assay. Survival analyses were performed to assess the risk of allograft failures by SAB-detected antibodies. Pretransplant antibodies were found in 160 (28.0%) recipients, of whom 42 subsequently developed an allograft failure for a survival rate of 70.9% (95% confidence interval [CI), 63.5-78.4). Among those without antibodies, 58 (14.0%) returned to dialysis with a survival rate of 84.7% (95% CI, 81.0-88.4). In Cox regression analyses, patients with SAB-positivity had 2-fold higher risk of allograft failure than those who were SAB-negative (hazard ratio, 2.07; 95% CI, 1.39-2.79). Results did not change after adjustment for putative confounders. In conclusion, in this single-center cohort, 10-year allograft survival rate was significantly influenced by the presence of SAB-detected antibodies.

The distribution of KIR-HLA functional blocks is different from north to south of Italy.

The killer cell immunoglobulin-like receptor (KIR)-human leukocyte antigen (HLA) interaction represents an example of genetic epistasis, where the concomitant presence of specific genes or alleles encoding receptor-ligand units is necessary for the activity of natural killer (NK) cells. Although KIR and HLA genes segregate independently, they co-evolved under environmental pressures to maintain particular KIR-HLA functional blocks for species survival. We investigated, in 270 Italian healthy individuals, the distribution of KIR and HLA polymorphisms in three climatic areas (from cold north to warm south), to verify their possible geographical stratification. We analyzed the presence of 13 KIR genes and genotyped KIR ligands belonging to HLA class I: HLA-C, HLA-B and HLA-A. We did not observe any genetic stratification for KIR genes and HLA-C ligands in Italy. By contrast, in a north-to-south direction, we found a decreasing trend for the HLA-A3 and HLA-A11 ligands (P = 0.012) and an increasing trend for the HLA-B ligands carrying the Bw4 epitope (P = 0.0003) and the Bw4 Ile80 epitope (P = 0.0005). The HLA-A and HLA-B KIR ligands were in negative linkage disequilibrium (correlation coefficient -0.1211), possibly as a consequence of their similar function in inhibiting NK cells. The distribution of the KIR-HLA functional blocks was different along Italy, as we observed a north-to-south ascending trend for KIR3DL1, when coupled with HLA-B Bw4 ligands (P = 0.0067) and with HLA-B Bw4 Ile80 (P = 0.0027), and a descending trend for KIR3DL2 when coupled with HLA-A3 and HLA-A11 ligands (P = 0.0044). Overall, people from South Italy preferentially use the KIR3DL1-HLA-B Bw4 functional unit, while those from the North Italy equally use both the KIR3DL2-HLA-A3/A11 and the KIR3DL1-HLA-B Bw4 functional units to fight infections. Thus, only KIR3DL receptors, which exert the unique role of microbial sensors through the specific D0 domain, and their cognate HLA-A and HLA-B ligands are selectively pressured in Italy according to geographical north-to-south distribution.

Description of two new HLA-C alleles: C*08:63 and C*14:44.

Here, we present two new HLA allelic variants at C locus: HLA-C*08:63 and HLA-C*14:44 detected by sequence-based typing. In both cases, a single-nucleotide mutation in exon 3 is responsible for a change in aminoacid translation. The extremely high polymorphism of human leucocyte antigen (HLA) system in human genome is responsible for the capability to recognize different antigens, including non-self-MHC (Major Histocompatibility Complex) molecules. This very high polymorphism and the improving accuracy of genomic HLA typing methods lead to an exponential increasing of known HLA alleles. Here, we describe the characterization of two new HLA-C alleles identified by sequence-based typing (SBT): HLA-C*08:63 and HLA-C*14:44.

Identification of two new HLA-DRB1 alleles, DRB1*040405 and DRB1*1190.

We describe here two novel DRB1 alleles, officially named *040405 and *1190. DRB1*040405 differs from DRB1*0404 for one point mutation at codon 72 with no coding changes. DRB1*1190 is identical to DRB1*110101 except for a nucleotide substitution at codon 24 which causes an aminoacidic mutation from valine to methionine. Over time we have been witnessing the identification of a great number of new HLA alleles. DRB1 allelic variability is mostly present in the second exon and more that 760 alleles have been so far identified. Here, we report the description of two novel DRB1 alleles, named *040405 and *1190, and identified in two Caucasoid subjects.

Identification of two new HLA-B alleles, HLA-B*0732 and HLA-B*5809, by sequence-based typing.

Here, we have described the characterization of two novel human leukocyte antigen-B (HLA-B) alleles. The new alleles, HLA-B*0732 and HLA-B*5809, were identified in Italian Caucasian individuals. B*0732 differs from HLA-B*0708 by one nucleotidic change at position 412 (from G to A) in exon 3, leading to an amino acidic substitution from Asp (GAC) to Asn (AAC) at codon 114. The sequence of B*5809 is identical to that of HLA-B*5801, except for a point mutation at position 583 in exon 3, where a T is substituted by a C. This change leads to an amino acidic substitution from Tyr (TAC) to His (CAC) at codon 171.

Characterization of a new HLA-DRB3 allele, DRB3*0217, by direct sequencing.

We report the identification of a novel DRB3*02 using sequence-based typing (SBT). This new allele, officially named DRB3*0217, was detected while performing HLA high resolution typing of a bone marrow recipient and his siblings. DNA sequencing demonstrated the presence of a nucleotide substitution in exon 2 at position 199 where a C was substituted by a T. This point mutation at codon 67 (CTC-->TTC) has resulted in an amino acid substitution from Leucine to Phenylalanine.