N. J. Oudeman-Gruber scite author profile

Gerritsen

Lange

et al. 1996

Pediatric recipients (n = 25) of an allogeneic bone marrow (BM) graft were selected on the basis of informative IgG allotype (Gm) differences between the BM donor and the recipient. To investigate the kinetics of the appearance of IgG of donor origin and the disappearance of IgG of recipient origin, G1m and G2m allotype levels were quantified in sera obtained at regular intervals between 3 months and 5 years after BM transplantation (BMT). For this quantification, a dot immunobinding assay (DIBA) has been developed. In 19 of 22 informative recipients, the Gm allotype distribution had reached the range of values expected on the basis of the Gm phenotype of the donor within 6 months after BMT. Remarkably, IgG of recipient origin persisted in 15 of 18 informative recipients until last follow up, ie, for several years after BMT. In addition to the origin of total IgG production, the origin of homogeneous IgG components (H-IgG) appearing after BMT was investigated. H-IgG of donor origin could be detected as early as 3 weeks after BMT, but also H-IgG of recipient origin were present in 8 of 13 informative recipients for a period of up to 1 year after BMT. We conclude that host-type IgG-producing cells were not eradicated by the (myeloablative) conditioning regimen and persisted in a high number of graft recipients. It is our hypothesis that lack of graft-versus-host disease (GVHD) in the majority of these recipients results in the persistence of IgG-producing cells of host origin. These observations may be relevant for the evaluation of patients who received allogeneic BMT for the treatment of multiple myeloma.

Immunoglobulin levels and monoclonal gammopathies in children after bone marrow transplantation

Gerritsen

Lankester

et al. 1993

Bone marrow graft recipients suffer profound immunodeficiency during at least 3 months after transplantation. B-cell reconstitution following allogeneic bone marrow transplantation (BMT) in children was studied longitudinally by quantification of Ig (sub)class levels in serum and by investigation of numbers and characteristics of homogeneous Ig components (H-Ig); ie, monoclonal gammopathies (MG). For the latter purpose, a sensitive immunoblotting technique capable of detecting H-Ig of a concentration as low as 0.5 microgram/mL was used. Sera of 40 children grafted for a variety of diseases were investigated and followed up for 5 years. It was found that Ig (sub)classes reached normal levels from 3 months after BMT onward. The sequential increase of the different Ig isotypes was in accordance with that seen in normal ontogeny. This was especially clear following BMT for severe congenital immunodeficiency. H-Ig appeared from as early as 6 weeks after BMT in increasing numbers, beginning within IgM, IgG3, and IgG1, and afterward within other isotypes. After an initial increase of serum Ig levels, “overshooting” occurred accompanied by high frequency of H-Ig. H-Ig were still present at 5 years after BMT, when Ig levels normalized. Our data indicate that B-cell reconstitution after allogeneic BMT recapitulates normal ontogeny but in a clonally dysregulated fashion; that is, with overexpression of some clones and underexpression of others.

Relationship between patterns of engraftment in peripheral blood and immune reconstitution after allogeneic bone marrow transplantation for (severe) combined immunodeficiency

Leeuwen

Joosten

et al. 1994

We report the outcome of allogeneic bone marrow transplantation (BMT) as treatment for severe combined immunodeficiency disease (SCID) in 31 patients grafted from 1968 until 1992. The patients received a graft from an HLA-identical related (n = 10), an HLA-haplo-identical related (n = 19), or a closely HLA-matched unrelated (n = 2) donor that resulted in the long-term survival of 6 of 10, 9 of 19, and 0 of 2 children, respectively. Major complications included failure of engraftment and early death caused by respiratory failure. The chimerism pattern and immunologic reconstitution were evaluated in 15 children who survived more than 1 year with sustained engraftment. The pattern of engraftment was investigated within flow-sorted peripheral blood (PB) T- and B-lymphoid, natural killer (NK), and myelomonocytic cell populations using the amplification of variable number of tandem repeats by the polymerase chain reaction. The immunologic reconstitution was assessed by various in vitro and in vivo parameters. Although the number of PB T cells and the in vitro T-cell proliferative response was in the lower region of normal in the majority of cases and even subnormal in some, in all cases donor T-cell engraftment and reconstitution of T-cell immunity was observed. Residual host-type T cells (1% to 5%) were detected in eight cases at multiple occasions. All children showed normal serum IgM and IgG subclass levels and produced specific IgG antibodies after vaccination, irrespective of donor B-cell engraftment. However, three HLA haplo-identical graft recipients with host-type B lymphoid and myeloid cells have a persistent selective IgA deficiency. NK cells were either of donor, host, or mixed origin. Donor NK cell engraftment restored defective in vitro NK cell function of the recipient. We conclude that determination of lineage-specific engraftment patterns provides valuable information for the understanding of the immunologic reconstitution after allogeneic BMT for SCID.

Immunoglobulin levels and monoclonal gammopathies in children after bone marrow transplantation

Gerritsen

Lankester

et al. 1993

Validation of a serum‐free growth factor‐replenished in vitro culture system for hematopoietic progenitor cells in healthy donors and recipients of an allogeneic bone marrow graft

Berg

European J of Haematology

Oudeman-Gruber

et al. 1992

The in vitro colony formation of hematopoietic progenitor cells of bone marrow samples, taken before and early after allogeneic bone marrow transplantation (BMT), was investigated prospectively. In order to circumvent culture‐related and sample‐related variations, a serum‐free recombinant growth factor‐replenished culture system was developed using T cell‐ and monocyte‐depleted bone marrow samples. Samples of healthy bone marrow donors were used to validate the technique. The standardized culturing technique gave reproducible results, with numbers of colonies above those in conventional conditioned‐medium technique. Colony formation in vitro of myelomonocytic precursor cells was found decreased in graft recipients, also after addition of growth factors, in comparison with healthy donors. The growth‐promoting effect of the combination of IL‐3 + GM‐CSF was superior to that of either growth factor alone or conditioned medium. No effect was observed of T lymphocytes and monocytes on in vitro colony formation after bone marrow transplantation, probably as a result of functional impairment of these cells at that period after transplantation.