Synthesis of donor type gamma-G-globulin following thymus transplantation in hypo-gamma-globulinaemia with severe lymphocytopenia

Sources of Human Hematopoietic Stem Cells for Transplantation–A Review

Transplantation of hematopoietic stem cells provides a means of replacing a defective hematopoietic system in patients with a wide range of malignant and nonmalignant disorders that affect the blood forming tissue. The same procedure has also allowed dose-escalation of standard chemotherapy and radiotherapy in the treatment of malignant disease of nonhematological origin. Until recently, bone marrow has been the sole source of hematopoietic stem cells, but limitations of conventional bone marrow transplantation have stimulated a search for alternative sources and uses of stem cells. Fetal tissues (especially liver) are a recognized source of transplantable stem cells and offer the great advantage of reduced immunogenicity, potentially removing the problems of tissue type matching. Umbilical cord blood is also a rich source of stem cells and, although it contains alloreactive cells, it is readily available without special ethical constraints. Both fetal tissue and cord blood suffer the disadvantages of limited numbers of stem cells per donation, and there is much interest in the development of technologies for the safe and reliable expansion and/or pooling of stem and progenitor cells. The observation that small numbers of stem cells are found in the peripheral blood of adults has led to the exploitation of the blood as a further source of stem cells. The ability to mobilize these cells from the medullary compartment into the periphery by the use of chemotherapy and/or recombinant hematopoietic growth factors has enabled the collection of sufficient numbers of cells for transplantation purposes. All of these advances are increasing the options and the range of choices available to clinicians and patients in the arena of hematopoietic stem cell transplantation.

Human fetal tissue research: practice, prospects, and policy

Tissue from human fetal cadavers has long been used for medical research, experimental therapies, and various other purposes. Research within the last two decades has led to substantial progress in many of these areas, particularly in the application of fetal tissue transplantation to the treatment of human disease. As a result, clinical trials have now been initiated at centers around the world to evaluate the use of human fetal tissue transplantation for the therapy of Parkinson's disease, insulin-dependent diabetes mellitus, and a number of blood, immunological and, metabolic disorders. Laboratory studies suggest a much wider range of disorders may in the future be treatable by transplantation of various types of human fetal tissue. A combination of characteristics renders fetal tissue uniquely valuable for such transplantation, as well as for basic research, the development of vaccines, and a range of other applications. Although substitutes for human fetal tissue are being actively sought, for many of these applications there are at present no satisfactory alternatives. Important issues remain unresolved concerning the procurement, distribution, and use of human fetal cadaver tissue as well as the effects of such use on abortion procedures and incidence. These issues can be addressed by the introduction of appropriate guidelines or legislation, and need not be an impediment to legitimate research and therapeutic use of fetal tissue.

Development of multiple monoclonal serum immunoglobulins (multiclonal gammopathy) following both HLA-identical unfractionated and T cell-depleted haploidentical bone marrow transplantation in severe combined immunodeficiency

We have identified five patients with severe combined immunodeficiency (SCID) who developed multiple monoclonal serum immunoglobulin components (multiclonal gammopathy) following bone marrow transplantation. Four patients received haploidentical bone marrow stem cells depleted of T cells and other mature marrow cells by soy lectin agglutination and/or sheep erythrocyte rosetting. One patient received unfractionated HLA-identical bone marrow. Twenty-one distinct paraproteins were detected: 14 IgG, 5 IgM, and 2 IgA, all containing either kappa or lambda light chains. In the haploidentical stem-cell recipients, these monoclonal immunoglobulins appeared immediately prior to, or concomitant with, a rise in T-cell numbers and function. Resolution or diminution of this multiclonal gammopathy occurred as T-cell function was established. Posttransplant karyotypic analyses revealed PHA-stimulated T cells to be of donor origin in all patients. Karyotyping of B-cell lines posttransplantation revealed them to be 100% donor in the patient receiving unfractionated HLA-identical marrow and 100% host (1/4), 100% donor (1/4), mixed (1/4), or not tested (1/4) in the patients receiving haploidentical marrow stem cells. There was no evidence of Epstein-Barr virus (EBV) infection in any of the patients. All patients are currently alive and well. Immunoglobulin synthesis is normal in the patient who received the HLA-identical marrow but remains below normal in the four patients who received T cell-depleted haploidentical stem cells. The posttransplantation development of monoclonal immunoglobulins in the absence of EBV infection did not adversely affect the outcome of either HLA-identical marrow or haploidentical stem-cell grafting.(ABSTRACT TRUNCATED AT 250 WORDS)

Monoclonal gammopathies in children

Over a 10-year period sera of 4000 pediatric patients were subjected to agar gel electrophoresis and immunoelectrophoresis. Retrospective examination of the electrophoresis patterns indicated that single or multiple homogeneous immunoglobulin components were present in sera of 155 children (3.9%). They were most frequently found in patients suffering from primary and secondary immunodeficiency diseases, hematological malignancies, autoimmune diseases, and severe aplastic anemia. Follow-up analysis revealed that most of these monoclonal gammopathies were transient. The monoclonal gammopathies in the serum of 79 patients were identified by immunoblotting for class and light-chain isotypes. A marked absence of IgA monoclonal gammopathies and a predominance of monoclonal gammopathies of the lambda light-chain isotype were found. Most of the B-cell mono- or oligoclonal proliferations in children can probably develop due to a disturbance in the regulatory T-cell function.

Appearance of multiple benign paraproteins during early engraftment of soy lectin T cell-depleted haploidentical bone marrow cells in severe combined immunodeficiency

Recent advances in the prevention of graft-versus-host disease through postthymic T-cell depletion have allowed the use of haploidentical bone marrow cells for immunologic reconstitution of severe combined immunodeficiency disease. We report a male infant with severe combined immunodeficiency (with normal adenosine deaminase) who developed two IgG kappa and one IgA lambda paraproteins 7 weeks following the administration of 1.4 X 10(9) maternal bone marrow cells depleted of postthymic T cells by soy lectin agglutination and sheep erythrocyte rosetting. Serum IgG rose from 128 to 820 mg/dl, and IgA from 0 to 2400 mg/dl, peaking at 10 weeks postgrafting. By 14 weeks posttransplantation T-cell numbers and function had risen to normal (all dividing T cells had the donor karyotype) and paraprotein concentrations began to decline. These observations strongly suggest that the later-appearing T cells regulated the B-cell clones from which the paraproteins were derived. Failure of such function to appear could account for the increased incidence of B-cell lymphomas in severe combined immunodeficiency.

Transient B cell immaturity with intractable diarrhoea: a possible new immunodeficiency syndrome

A male boy is described, who suffered from an intractable diarrhoea and several infections and who died in a severe marasmic state at the age of 8 months. Immunological studies revealed a block in the normal differentiation of B cells to Ig-producing plasma cells. After the age of 5 months, however, this block disappeared, leading to a dramatic increase in circulating Ig, most pronounced in the IgM class. In the intestine, plasma cells could only be detected after the age of 5 months, and then with a marked preponderance of IgM cells. Our results thus indicate a reversible block in the normal maturation of B cells in our patient. An older brother may have had a similar disease, suggesting a possible genetic basis for the disorder.

Serum monoclonal immunoglobulins in childhood

Of 18 children with monoclonal immunoglobulins in their sera, 13 had a primary or secondary immunodeficiency. The monoclonal immunoglobulin belonged to each of the three main Ig classes, and in 3 children multiple monoclonal components were detected. The level of the monoclonal component exceeded 0·5 g/100 ml in 7 cases. The monoclonal immunoglobulin disappeared spontaneously in 9 children. The significance of this homogeneous component and the importance of the underlying immunodeficiency are outlined.

Imbalances of gamma globulin subgroups and gene defects in patients with primary hypogammaglobulinemia

Analysis of immunoglobulin classes, gammaG subgroups, and Gm genetic markers from 59 patients with various types of immune deficiencies was undertaken to assess the function of the several cistrons concerned with synthesis of gamma globulins. 13 patients including two sibling pairs were found to have gammaG subgroup imbalances. All of these patients had non sex-linked disease. 11 of the 13 had preponderance of the gammaG3 subgroup. In most instances of gammaG3 preponderance it was the Gm(b) type of gammaG3 that was selectively retained; the Gm(g) type, controlled by the allelic gene was markedly depressed but not absent in the cases where it could be studied. Other imbalances, either seen concomitantly with gammaG3 preponderance or independently, included predominance of the gammaG2 subgroup and selective absence of single gammaG subgroups.One family was encountered with probable structural gene abnormalities in the autosomal Gm loci. Both parents had different abnormal gene complexes detectable by absence of specific Gm markers and the propositus received both types from the parents. Similar gene complexes have been seen previously in rare instances through population screening but only in the heterozygous state and were not associated with clinically evident hypogammaglobulinemia. Of several other families of patients with subgroup imbalance, two were informative in that structural gene defects could be excluded. Studies on 22 first degree relatives of patients with subgroup imbalances indicated that the most common abnormality detected was in gammaA which was absent in 3 and markedly decreased in 2 others; other abnormalities included decreased levels of specific genetic types of gammaG globulin. It is concluded that gammaG subgroup imbalances are frequently found in non sex-linked immunoglobulin deficiency disorders and in some instances may be associated with family abnormalities suggesting either regulator or structural gene defects.

Thymic alymphoplasia, monoclonal gammopathy, and Pneumocystis carinii pneumonia in an infant

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Adsorption of immunolgobulin A onto oral bacteria in vivo

Oral bacteria become coated with immunoglobulin A in human saliva in vivo. This may indicate that the salivary immunoglobulin A possesses antibacterial activity. Some of the immunoglobulin-coated cocci grow in extremely long chains and exhibit synchronous cell division. The long chain phenomenon may result from growth in the presence of salivary antibody specific to antigenic determinants of the bacterial cell walls.