Infusion of autologous retrodifferentiated stem cells into patients with beta-thalassemia.

Beta-thalassemia is a genetic, red blood cell disorder affecting the beta-globin chain of the adult hemoglobin gene. This results in excess accumulation of unpaired alpha-chain gene products leading to reduced red blood cell life span and the development of severe anemia. Current treatment of this disease involves regular blood transfusion and adjunct chelation therapy to lower blood transfusion-induced iron overload. Fetal hemoglobin switching agents have been proposed to treat genetic blood disorders, such as sickle cell anemia and beta-thalassemia, in an effort to compensate for the dysfunctional form of the beta-globin chain in adult hemoglobin. The rationale behind this approach is to pair the excess normal alpha-globin chain with the alternative fetal gamma-chain to promote red blood cell survival and ameliorate the anemia. Reprogramming of differentiation in intact, mature, adult white blood cells in response to inclusion of monoclonal antibody CR3/43 has been described. This form of retrograde development has been termed "retrodifferentiation", with the ability to re-express a variety of stem cell markers in a heterogeneous population of white blood cells. This form of reprogramming, or reontogeny, to a more pluripotent stem cell state ought to recapitulate early hematopoiesis and facilitate expression of a fetal and/or adult program of hemoglobin synthesis or regeneration on infusion and subsequent redifferentiation. Herein, the outcome of infusion of autologous retrodifferentiated stem cells (RSC) into 21 patients with beta-thalassemia is described. Over 6 months, Infusion of 3-h autologous RSC subjected to hematopoietic-conducive conditions into patients with beta-thalassemia reduced mean blood transfusion requirement, increased mean fetal hemoglobin synthesis, and significantly lowered mean serum ferritin. This was always accompanied by an increase in mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH), and mean corpuscular hemoglobin concentration (MCHC) in such patients. No adverse side effects in response to the infusion of autologous RSC were noted. This novel clinical procedure may profoundly modify the devastating course of many genetic disorders in an autologous setting, thus paving the way to harnessing pluripotency from differentiated cells to regenerate transiently an otherwise genetically degenerate tissue such as thalassemic blood.

SCID repopulating cells derived from unmobilised adult human peripheral blood.

Severe combined immunodeficient (SCID)-repopulating cells (termed SRC) with lymphohaematopoietic differentiation potential reside at an extremely low frequency in unmobilised adult human peripheral blood. Recently, an ex vivo method of increasing the relative numbers of at least four distinct human stem cell classes, that include CD34+ haematopoietic progenitor cells, in mononuclear cells (MNC) obtained from unmobilised adult human peripheral blood has been described. This process is triggered by a monoclonal antibody (mAb) against the human monomorphic region of the beta chain of HLA-DP, DQ and DR (clone CR3/43). Herein, we assess the ability of human male donor-derived MNC, following ex vivo culturing for 3 hr in haematopoietic-conducive conditions (HCC) (3-hr MNC/HCC), to form SRC in female non-obese diabetic/severe combined immunodeficient (NOD/SCID) mice. All 3-hr MNC/HCC-recipient animals exhibited significant levels (> 0.5%) of human cell engraftment in the bone marrow, thymus and spleen when compared to animals receiving MNC cultured in the absence of CR3/43. Phenotypic characterisation of the bone marrow cell populations of engrafted mice demonstrated significant levels of human lymphohaematopoietic cell lineages, comprised of T lymphocytes, monocytes, erythrocytes and megakaryocytes, including platelets. In addition, significant levels of clonogenic human CD34+ cells were also detected by in vitro surrogate assay. The thymi of engrafted animals contained maturating human thymocytes, while the spleen consisted mainly of T lymphocytes. Fluorescence in situ hybridisation (FISH) further identified the presence of human male X and Y chromosomes at engrafted sites, whilst the human origin of the cells was confirmed by a specific PCR assay for the human Cart-1 gene. In conclusion, the conversion of MNC to SRC in response to treatment with CR3/43 for 3 hr could have far-reaching clinical implications especially where time and donor-histocompatibility are limiting factors.