Simultaneous immunomagnetic CD34+ cell selection and B-cell depletion in peripheral blood progenitor cell samples of patients suffering from B-cell non-Hodgkin's lymphoma.

The reduction of residual tumor cells is one of the main targets of leukapheresis product (LP) processing. Immunomagnetic enrichment/selection of CD34+ progenitor cells (Baxter Isolex 300i) can achieve a reduction of contaminating B-cells of approximately 2-3 logs in B-cell non-Hodgkin's lymphoma patients. Specific release of the enriched CD34+ cells (stem cell releasing agent PR34+; Baxter) and the use of antibody-coated immunobeads targeted against B-cell markers (CD10, CD19, CD20, CD22, CD23, and CD37) during this procedure allows the GMP-like simultaneous capture of residual B cells within a closed system. This combination of two purging techniques enhances the B-cell depletion capacity up to 4.5 logs. By performing 10 clinical-scale purging procedures, we could show that the simultaneous immunomagnetic purging method is easy to perform and highly efficient. We evaluated B-cell log depletion by flow cytometry for cases with marker-positive cells detectable before and after the purging procedure. The mean reduction of B-cells in these cases was 3.5 logs; the mean CD34+ cell yield and purity were 47 and 92%. Using three LPs, we tested the procedure on a modified Baxter Isolex 300i device with software adaptations for this procedure (software version 2.0) in direct comparison with CD34+ cell selection only, using the former version (version 1.12). The CD34+ cell yield was 49% (40-54%) for the CD34+ cell selection and 51% (19-72%) for simultaneous double selection. The mean purity was 96% for CD34+ cell selection and 98% for simultaneous double selection. B-cell depletion was 1.9 logs for CD34+ cell selection, and after simultaneous double selection, the B-cell content was decreased by 3.7 log steps (P = 0.0495). Clinical application of double-purged cells has not prolonged the hematopoietic recovery times after high-dose therapy as compared with nonpurged peripheral blood progenitor cell autotransplants. In conclusion, we could show that the simultaneous double selection protocol developed leads to a highly increased B-cell purging efficacy when compared with CD34+ cell selection without any negative effects regarding CD34+ cell yield and engraftment times after high-dose therapy.

Structural definition of the A*74 group: implications for matching in bone marrow transplantation with alternative donors.

We have identified two new A*74 alleles (A*7402 and 7403) in two unrelated individuals. A*7402 differs from A*7401 by a single amino acid substitution in the signal peptide and may be the result of a gene conversion event at the 3' end of exon 1. A*7403 differs from A*7401 by a single amino acid exchange in the alpha 1 domain and is most likely due to a point mutation in exon 2, since no HLA class I donor allele has been found. Since A*7402 appears to be the ancestor of the other two A*74 alleles, it is possible that A*7401 and 7403 have been created by successive point mutations. The sequences of the expressed proteins of A*7401 and 7402 are identical. The heavy chain sequence of A*7403 differs from these alleles at the crucial residue 79 which is located in the sequence stretch of the alpha 1 alpha-Helix where the Bw4/Bw6 determinants have been identified and which probably affects TCR interaction. This variation can therefore be expected to stimulate alloreactive T cells, graft rejection and graft versus host disease emphasizing the relevance for matching in bone marrow transplantation with alternative donors.