Deleterious effects of irradiation and bone marrow transplantation therapy in the genetically anemic an/an mouse

The efficacy and outcome of bone marrow transplantation therapy following lethal irradiation were examined in syngeneic mice that had a hereditary macrocytic anemia (an/an) or were genotypically normal (+/+). Successful RBC and WBC replacement, based on blood cell parameters and donor genetic markers, were observed in all combinations of transplant therapy. Nevertheless, the an/an mice died prematurely several months after treatment, whether they received +/+ or an/an marrow cells. In contrast, the +/+ recipients of either +/+ or an/an marrow cells survived for at least 1 year after transplantation. Premature death of the an/an mice was associated with lymphopenia, anemia, kidney lesions, and severe pathogen-free pneumonitis. On the basis of our results, we hypothesize that the premature deaths of an/an mice are caused by a kind of chronic irradiation damage to which an/an mice are especially susceptible.     

The hematopoietic stem cells of alpha-thalassemic mice

The alpha-thalassemic mouse has a hereditary microcytic anemia, almost certainly has a shortened RBC life span, and is a potential candidate for cell replacement therapy. In a routine study of bone marrow repopulating capacity using hemoglobin as a cell marker, normal donor marrow cells, but not alpha-thalassemic donor marrow cells, completely replaced the host cells. Further analysis showed that at least 30 times more alpha-thalassemic cells were required to outcompete normal donor cells injected simultaneously. The results were more extreme then expected and suggested a defect in a stem cell population as well as in the RBCs. Evidence that the multipotent and erythroid-committed stem cells in alpha-thalassemic mice are not decreased was shown by CFU-S and CFU-E assays. The combined results indicate that the deletion expresses itself most conspicuously in the RBC population. Tests were also performed to analyze repopulation kinetics in the Hbath-J/+ mice. In unirradiated alpha-thalassemic hosts, the hemoglobin from a normal donor persisted but did not replace the host hemoglobin. Sublethally irradiated alpha-thalassemic hosts, on the other hand, were easily repopulated with normal cells. We conclude that the alpha-thalassemic mouse is a good model for cell replacement therapy.     

Marrow transplantation in the treatment of a murine heritable hemolytic anemia

Mice with hemolytic anemia, sphha/sphha, have extremely fragile RBCs with a lifespan of approximately one day. Neither splenectomy nor simple transplantation of normal marrow after lethal irradiation cures the anemia but instead causes rapid deterioration and death of the mutant unless additional prophylactic procedures are used. In this report, we show that normal marrow transplantation preceded by sublethal irradiation increases but does not normalize RBC count. The mutant RBCs but not all the WBCs are replaced by donor cells. Splenectomy of the improved recipient causes a dramatic decrease in RBC count, indicating that the mutant spleen is a site of donor-origin erythropoiesis as well as of RBC destruction. Injections of iron dextran did not improve RBC counts. Transplantation of primary recipient marrow cells into a secondary host with a heritable stem cell deficiency (W/Wv) corrects the defect caused by residence of the normal cells in the sphha/sphha host. The original +/+ donor cells replace the RBCs of the secondary host, and the RBC count is normalized. Results indicate that the environment in the sphha/sphha host is detrimental to normal (as well as mutant) erythroid cells but the restriction is not transmitted.     

Iron homeostasis in beta-thalassemic mice

To explore the pathogenesis of nontransfusional iron overload in iron- loading anemia, we examined features of external iron exchange, internal iron kinetics, and tissue iron burden in adult mice with inherited gene-deletion beta-thalassemia. Mice homozygous for beta- thalassemia display moderate anemia, reticulocytosis, and shortened red cell survival, whereas heterozygous carriers appear hematologically normal. Quantitative iron determination revealed that iron content and concentration in liver, spleen, and kidney, but not heart, were far higher (P less than .01) in 15-to 35-week old homozygous thalassemic mice than in age-matched normal and heterozygous controls; of these tissues, iron content increased with age only in kidneys (P = .01) of homozygous affected mice. Although plasma iron levels were only minimally elevated in homozygotes, plasma iron turnover was threefold greater (P less than .001) than that seen in heterozygote controls. Nevertheless hyperabsorption of enteric radioiron, discernible among homozygous thalassemic mice as late as 6 to 8 weeks after birth, was not observed in older mice, additionally, thalassemic and control mice at 18 to 34 weeks showed comparable iron excretion after intravenous radioiron. We conclude that adult mice with beta-thalassemia regain balanced external iron exchange, despite substantial tissue iron excess and accelerated internal iron transit.     

Defective assembly of membrane proteins in erythroid precursors of beta- thalassemic mice

beta-Thalassemic mice provide a useful model for studying the pathophysiology of human beta-thalassemia in that one can perform experiments that are difficult to perform in humans. The ease of access to beta-thalassemic mouse marrow provided the opportunity to explore the cause of the ineffective erythropoiesis that characterizes severe beta-thalassemia in mouse and man. We hypothesized that the accumulation of excess alpha-globin might interfere with the normal assembly of red blood cell (RBC) membrane proteins, thus contributing to the severe intramedullary lysis. Femoral marrow was obtained from normal and beta-thalassemic mice, and RBC precursors were purified (> 90%) by panning and harvesting CD45- cells. The assembly of RBC membrane proteins was assessed by observing immunofluorescence patterns obtained on fixed permeabilized precursors using rabbit polyclonal antibodies directed against human spectrin, and band 4.1, and murine band 3. The distribution of the proteins was shown with a fluorescein- tagged goat antirabbit antibody. In contrast to normal mice, about 30% of intermediate and late stage erythroblasts in beta-thalassemic mice appear abnormal. Neither spectrin nor band 4.1 formed crisp rim fluorescence in these erythroid precursors of thalassemic mice, whereas assembly of band 3 appeared normal. Therefore, the assembly of membrane skeletal proteins is abnormal in murine beta-thalassemic erythroid precursors perhaps because of the deposition of unmatched alpha-globin chains.     

Erythroid marrow function in anemic patients

Erythropoietic activity is known to be closely associated with marrow iron uptake. A modification of the standard measure of plasma iron turnover has been developed in which erythron transferrin uptake (ETU) rather than iron uptake has been calculated. The ETU has the advantage of providing a parameter of erythroid marrow activity independent of change produced by plasma iron and transferrin saturation. Measurements in 80 patients with anemia were compared to the normal value of 60 +/- 12 mumol/L whole blood/d. The mean ETU for ten patients with severe aplastic anemia and for six patients with pure red-cell aplasia were 12 +/- 8 and 12 +/- 11 mumol/L whole blood/d, respectively. In ten transfusion-dependent patients with renal failure under dialysis therapy, the mean value was 35 +/- 11, while ten other dialyzed patients who were transfusion independent had a mean ETU of 73 +/- 21 mumol/L whole blood/d. Sixteen patients with hemolytic anemia had an average ETU of 400 +/- 130, while 28 patients with ineffective erythropoiesis had a mean value of 474 +/- 147 mumol/L whole blood/d. While patients with hypoproliferative anemia showed no relation between the severity of anemia and ETU, those with hyperproliferative erythroid marrow showed increasing values as the anemia became more severe. Sequential measurements in patients with aplastic anemia under treatment and in thalassemic patients under transfusion therapy showed the value of this measurement in monitoring the effects of treatment on erythroid marrow activity. It is concluded that the measurement of ETU provides a more direct ferrokinetic evaluation of erythroid activity in anemic states.     

Circulating mononuclear cells from pure red cell aplasia of chronic lymphocytic leukemia suppress in vitro erythropoiesis

In vitro studies were performed in a patient with B-cell chronic lymphocytic leukemia who developed pure red cell aplasia (CLL-PRCA). The patient's irradiated circulating mononuclear blood cells and supernatant markedly inhibited normal marrow erythroid (but not granulocyte-monocyte) progenitor colony proliferation. In contrast, irradiated peripheral blood mononuclear cells and supernatant obtained from a B-CLL patient (Rai stage III) and from a hematologically normal donor, did not affect hematopoietic progenitor colony growth. These findings suggest that the anemia of CLL-PRCA evolves different mechanisms of those causing anemia in CLL, and is mediated through cellular and secretory mechanisms.     

Selective erythroid replacement in murine beta-thalassemia using fetal hematopoietic stem cells.

We have explored the application of fetal hematopoietic stem cell (HSC) transplants for cellular replacement in a murine model of beta-thalassemia. Liver-derived HSCs from nonthalassemic syngeneic murine fetal donors were transplanted into nonirradiated neonatal beta-thalassemic recipients. Significant erythrocyte chimerism (9-27%) was demonstrated in the majority of recipients at 1 month and remained stable or increased (up to 55%) during long-term follow-up in almost all cases. Chimeras had improved phenotypes, as evidenced by decreased reticulocyte counts, increased mean erythrocyte deformability, and decreased iron deposits in comparison to controls. To investigate whether the high degree of peripheral blood chimerism was predominantly a feature of erythroid elements or was a general feature of all hematopoietic elements, chimeras were created using donor HSCs "tagged" with a DNA transgene. Whereas donor hemoglobin comprised > 30% of total hemoglobin, nucleated tagged nonerythroid donor cells comprised < 1% of peripheral blood elements. Explanations for the observed selective increase in erythroid chimerism include longer survival of normal donor red cells compared to that of thalassemic red cells and the effective maturation of the donor erythroid elements in the bone marrow in chimeric animals. The latter explanation bears consideration because it is consistent with the process of ineffective erythropoiesis, well documented to occur in thalassemia, in which the majority of thalassemic erythroid cells are destroyed during erythropoiesis prior to release from the bone marrow. Overall, these data demonstrate the potential for significant erythroid chimerism and suggest that fetal HSC transplantation may play a significant role in future treatment.     

Enhanced macrophagic attack on beta-thalassemia major erythroid precursors

BACKGROUND AND OBJECTIVES: In beta-thalassemia major (Cooley's anemia), ferrokinetic studies show that 60-80% of erythroid precursors die in the marrow or extramedullary sites. However, study of marrow aspirates does not reveal huge numbers of dead and dying erythroid precursors. We explored this apparent discrepancy with the hypothesis that enhanced phagocytosis of thalassemic erythroid precursors was a likely explanation. Prior studies had reported on an increase in thalassemic marrow macrophages and their enhanced state of activation. Therefore this study explored the characteristics of thalassemic erythroid precursors which might lead to enhanced susceptibility to phagocytosis. We have shown that enhanced erythroid apoptosis parallels the extent of ineffective erythropoeisis in thalassemic patients, and apoptotic cells are rapidly phagocytosed. Thus, increased apoptosis and perhaps other features of thalassemic erythroid precursors might be the cause of their enhanced phagocytic removal. DESIGN AND METHODS: Erythroid precursors were isolated from normal and beta-thalassemia major marrow, and incubated with uniform cultures of murine macrophages. The extent of phagocytosis was measured and then specific inhibitors were added to identify some of the messages effete erythroid precursors use to signal their condition to macrophages. RESULTS: Beta-thalassemia major erythroid precursors are phagocytosed twice as effectively as normal erythroid precursors. INTERPRETATION AND CONCLUSIONS: Experiments using inhibitors of phagocytosis showed that enhanced apoptosis is certainly responsible for part of the increased phagocytosis of thalassemic erythroid precursors. Interestingly, normal erythroid precursors are also subject to phagocytosis by qualitatively similar mechanisms.     

Erythropoiesis following bone marrow transplantation from donors heterozygous for β-thalassaemia

This study shows a marked and protracted activation of HbF synthesis in homozygous beta.-thalassaemia patients transplanted from HLA identical siblings heterozygous for beta-thalassaemia, as compared to patients transplanted from normal donors. HbF synthesis in recipients was much higher in relation to the corresponding bone marrow donor values either normal or heterozygous for beta thalassaemia. gamma-chain synthesis and G gamma/A gamma ratio were also studied in peripheral blood BFU-E from recipients and their donors. BFU-E from donors heterozygous for beta-thalassaemia showed higher gamma chain synthesis as compared to normal donors. Peripheral blood BFU-E gamma/beta + gamma ratios and G gamma percentage were higher in recipients than in their corresponding donors both normal or heterozygotes. The marked and protracted reactivation of HbF synthesis in recipients of heterozygous beta-thalassaemia bone marrow most likely results from an increased erythropoietic stress on erythroid progenitors. In order to obtain adequate Hb levels heterozygous beta-thalassaemia bone marrow should produce more red blood cells to compensate for the low MCH. The magnitude of activation of HbF synthesis was very variable. This variability may result from inherited differences in the capacity of reactivation of HbF synthesis of red cell progenitors from heterozygous beta-thalassaemia under stressed erythropoiesis.     

Adult bone marrow-derived pluripotent hematopoietic stem cells are engraftable when transferred in utero into moderately anemic fetal recipients

We have used W41/W41 (C57BL/6-Ly 5.1, Gpi-1b) anemic mice and a newly developed double congenic donor strain (C57BL/6-Ly 5.2, Gpi-1a) to determine if adult bone marrow (BM) injected in utero could provide stem cell engraftment. Of 38 fetuses injected intraperitoneally on day 13/14 of gestation with donor BM cells, 17 (47%) were live-born. On day 6, 12% had erythroid engraftment. On day 59, in 50% (8/16) of mice, 50% to 75% of erythroid cells, 42% of T cells, 5% of B cells, and 26% of granulocytes in the peripheral blood (PB) were derived from the in utero-injected donor BM. At 141 days, thymic, splenic, lymph node, BM, and PB chimerism studies showed that 57% to 80% of T cells, 10% to 15% of B cells, and 27% to 43% of granulocytes were of donor origin. At this time, BM was injected into irradiated secondary recipients. On day 104 posttransfer, a mean 23% of T cells, 8% of B cells, and 40% of granulocytes were derived from the in utero donor BM. These data indicate that adult BM has hierarchical engraftment capabilities in W41/W41 mice and prove that stem cells are engraftable in utero.     

Fetal compensation of the hemolytic anemia in mice homozygous for the normoblastosis (nb) mutation.

The mouse autosomal recessive mutation nb causes a deficiency of erythroid ankyrin and generates a life-threatening hemolytic anemia in adult mice; however, at birth, nb/nb mice appear to be robust and show no pallor. In our study, the time of disease onset was sought by comparison of nb/nb and +/? mice both in utero and postnatally. Erythroid ankyrin messenger RNA (mRNA) is expressed in fetal erythroid progenitors from normal mice, but is reduced to 10% of normal levels in mutant fetuses. Despite the deficiency of erythroid ankyrin mRNA, 16 and 18 day nb/nb fetuses have normal levels of red blood cells (RBCs) and the RBCs are morphologically normal by scanning electron microscopy. The earliest signs of any clinical anomaly are an increase in the number of circulating reticulocytes and the deposition of minor amounts of iron just before birth in the 18 day fetal nb/nb liver, suggesting that RBCs are being destroyed. Within 24 hours after birth, nb/nb neonates have a slight but significant decrease of their RBC counts. During the next 5 days, the nb/nb RBC counts decrease markedly, the reticulocyte counts assume the mutant adult levels of 60%, the erythrocytes become microcytic and fragmented, and iron deposits accumulate in the liver. The rapid onset of clinical disease postnatally, coupled with our findings that the erythroid ankyrin gene is transcribed in fetal erythroid cell precursors from normal mice, suggest that mechanisms exist in the nb/nb fetus to compensate for the erythroid ankyrin deficiency.     

The importance of erythroid expansion in determining the extent of apoptosis in erythroid precursors in patients with beta-thalassemia major

Beta-thalassemia major is characterized by ineffective erythropoiesis leading to severe anemia and extensive erythroid expansion. The ineffective erythropoiesis is in part due to accelerated apoptosis of the thalassemic erythroid precursors; however, the extent of apoptosis is surprisingly variable. To understand this variability as well as the fact that some patients undergoing allogeneic marrow transplantation are resistant to the myeloablative program, we attempted more quantitative analyses. Two groups of patients totaling 44 were studied, along with 25 healthy controls, and 7 patients with hemolysis and/or ineffective erythropoeisis. By 2 flow cytometric methods, thalassemic erythroid precursors underwent apoptosis at a rate that was 3 to 4 times normal. Because thalassemic marrow has between 5- to 6-fold more erythroid precursors than healthy marrow, this translated into an absolute increase in erythroid precursor apoptosis of about 15-fold above our healthy controls. In searching for the causes of the variability in thalassemic erythroid precursor apoptosis, we discovered tight direct correlations between the relative and absolute extent of apoptosis and the extent of erythroid expansion as measured either by the absolute number of marrow erythroid precursors or by serum soluble transferrin receptor levels. These results could mean that the most extreme rates of erythroid proliferation lend themselves to cellular errors that turn on apoptotic programs. Alternatively, extreme rates of erythroid hyperplasia and apoptosis might be characteristic of more severely affected patients. Lastly, extreme erythroid hyperplasia could generate such numbers of apoptotic erythroid precursors that marrow macrophages are overwhelmed, leaving more apoptotic cells in the sample.     

Latent deficiency of the hematopoietic microenvironment of aged mice as revealed in W/Wv mice given +/+ cells

The macrocytic anemia of W/Wv mice can be cured by injection of +/+ bone marrow cells (BMC) from WBB6F1 mice. However, it has been observed that some W/Wv recipients appear to "lose" their cure with time, an effect that does not appear to be related to the age of the BMC donor. The present study was undertaken to determine the effect of recipient age on W/Wv responses to BMC injection. The effect of aging on erythroid parameters was similar in untreated W/Wv mice and +/+ controls. In both genotypes, hematocrit (HCT) and red blood cell count (RBC) decreased, and the modal red blood cell size (peak) increased between 13 and 150 weeks of age. As anticipated, mean HCT and RBC values were lower and peak values higher in W/Wv mice compared to +/+ controls at every age. However, the rate of decrease in HCT and RBC with age was the same for both genotypes, suggesting that the age effect and W gene effect were independent. Peak values increased slightly more with age for W/Wv than for +/+ controls. When female W/Wv mice in three age groups (23.5, 70, and 91.5 weeks old) were injected with 5 x 10(5) BMC from 20-week-old +/+ female donors and HCT, RBC, and peak were determined monthly, improvement was seen in most W/Wv recipients. However, in the older mice this improvement was slower and often was not sustained; 100% of the youngest recipients, 80% of the middle-aged, and only 30% of the older groups were cured after 3 months. Taken together, these data suggest a latent deficiency of the aging hematopoietic microenvironment that is revealed in W/Wv mice by the stress of continuing erythroid demand on the limited number of normal donor BMC.     

Multiple high cell dose injections of normal marrow into newborn jaundiced mice dramatically prolong life despite transient repopulation.

Jaundiced (ja/ja) mice have a severe hemolytic anemia caused by deficiency of the erythroid cytoskeletal protein beta-spectrin. Unless they are transfused, 99% of the mutant mice die after birth. Here, we test a new therapy involving multiple, high cell dose marrow injections into newborn non-ablated recipients. The ja/ja and normal newborn mice were injected intravenously with a total of 8.7 x 10(6) genetically marked +/+ marrow cells/g body weight. Donor and host red blood cells were quantified and the status of the recipients monitored. The jaundiced but not the normal recipients had up to 57% replacement with donor red cells by 9 weeks. The treatment significantly increased red cell counts and extended the average lifespan to 5 months beyond that previously reported for ja/ja mice transfused at birth. Replacement was limited to red cells. The donor cells disappeared in three of five mutant mice alive beyond 27 weeks. Marrow from a 48-month-old ja/ja recipient no longer positive for donor cells was injected into a secondary host. The recipient acquired the blood phenotype of the primary ja/ja host. The possibility that the marker was not well tolerated following multiple cell injections was investigated in normal adult mice injected with a total of 5.3 x 10(6) marrow cells/g body weight. Recipients became chimeric (>38% donor red and white cells) long-term (>12 months). The results indicate donor stem cells (a) prolong life in the jaundiced mice, but (b) do not survive long-term when injected into newborn mice. We conclude that destructive mechanisms may not be limited to ja/ja red cells.     

Treatment of hypoplastic anemia in mice with placental transplants

A genetic mutation in mice (W/Wv) causes an autosomal recessive disease characterized by hypoplastic anemia which lasts throughout life. Double- dominant W/Wv anemic mice were sublethally irradiated to facilitate repopulation of marrow with transplanted cells and were injected intravenously with suspensions of 5-10 million placental cells of 15 days gestation derived from normal, isogeneic donors. Red cell counts fell promptly after irradiation and then rose progressively over a period of weeks, reaching normal levels of the nonmutant. Mean corpuscular volume and hemoglobin electrophoresis patterns of red cells in recipient W/Wv mice resembled those of normal donor animals. The therapeutic effect lasted for the duration of the observation period, in some instances over 9 mo. W/Wv mice that were administered Hanks' solution or fetal blood, instead of placental transplants, remained anemic. Late gestation placentas (18 days) were also ineffective.     

Abnormal assembly of membrane proteins in erythroid progenitors of patients with beta-thalassemia major

The life threatening anemia in beta-thalassemia major (Cooley's anemia) is characterized by profound intramedullary lysis, the cause of which is incompletely understood. Using marrow obtained from beta thalassemia major patients undergoing allogeneic bone marrow transplantation in Pesaro Italy, it became possible to directly study the mechanism of the intramedullary hemolysis. Based on our previous studies, we hypothesized that the unmatched alpha globin chains would interfere with normal assembly of erythroid precursor membrane proteins. Patient and control erythroid precursors were reacted with monospecific polyclonal rabbit antibodies directed against spectrin, band 3, and band 4.1 and with a monoclonal anti-alpha globin chain antibody. Using laser confocal fluorescence microscopy, normal erythroid precursors show no alpha globin chain accumulation and exhibited uniformly smooth rim fluorescence of the three membrane proteins. In some thalassemic precursors, spectrin appeared to interact with large alpha globin accumulations, and in many of these cells the spectin appeared clumped and discontinuous. Band 4.1 interacted strongly with accumulations of alpha globin in thalassemic precursors to produce bizarrely clumped zones of abnormal band 4.1 distribution. Band 3 was incorporated smoothly into thalassemic erythroblast membranes. However, the proerythroblasts and basophilic erythroblasts were significantly deficient in band 3. Thus, accumulations of alpha globin in beta- thalassemia major colocalized with and disrupt band 4.1 and spectrin assembly into the membrane. The cause of deficient band 3 incorporation into thalassemic proerythroblast membranes remains unknown. These profound membrane alterations would likely contribute to the intramedullary lysis seen in Cooley's anemia.     

The effect of syngeneic marrow injection upon recovery in sub- and near-lethally irradiated mice

Mice were given sub-lethal (200-600 cGy) or near-lethal (800 cGy) whole body irradiation and the effect of injecting syngeneic marrow on subsequent hematopoietic recovery was studied. Marrow cell injection enhanced erythropoietic recovery after sub-lethal irradiation as reflected in hematocrit values and rate of appearance of 59Fe-labeled red cells in blood. However, this enhanced erythropoiesis was only seen in the spleen, and 59Fe uptake in marrow was reduced. When the irradiation dose was kept constant and the marrow dose increased from 10(5) to 10(6) to 10(7) cells, there was a somewhat erratic increase in spleen 59Fe and a decrease in marrow 59Fe uptake. When marrow cell number was kept constant and the dose of irradiation was increased from 200 to 400 to 600 to 800 cGy, there was an exponential increase in spleen 59Fe uptake but the marrow 59Fe uptake changed from depressed after lower doses to increased after 800 cGy. Cell injection after sub-lethal irradiation did not increase or decrease granulocytopoiesis. Injection of irradiated marrow cells also reduced marrow erythropoiesis and this was evident after both sub- and near-lethal irradiation. However, injection of irradiated cells did not increase splenic erythropoiesis. Following splenectomy, the depressed marrow erythropoiesis attending injection of viable cells was virtually eliminated but no increase was seen. These data suggest that the injection of autologous or syngeneic marrow may not be effective as a means of accelerating hematopoietic recovery after irradiation unless near-lethal or lethal dose have been received.     

Chimerism and cure: hematologic and pathologic correction of murine sickle cell disease

Bone marrow transplantation (BMT) is the only curative therapy for sickle cell disease (SCD). However, the morbidity and mortality related to pretransplantation myeloablative chemotherapy often outweighs the morbidity of SCD itself, thus severely limiting the number of patients eligible for transplantation. Although nonmyeloablative transplantation is expected to reduce the risk of BMT, it will likely result in mixed-chimerism rather than complete replacement with donor stem cells. Clinical application of nonmyeloablative transplantation thus requires knowledge of the effect of mixed chimerism on SCD pathophysiology. We have, therefore, created a panel of transplanted SCD mice that received transplants displaying an array of red blood cell (RBC) and white blood cell (WBC) chimerism. A significant enrichment of RBC over WBC chimerism occurred in these mice, because of the dramatic survival advantage of donor over sickle RBCs in the peripheral blood. Increasing levels of RBC chimerism provided progressive correction of hematologic and pathologic abnormalities. However, sickle bone marrow and splenic hematopoiesis was not corrected until peripheral blood sickle RBCs were fully replaced with donor RBCs. These results have important and unexpected implications for nonmyeloablative BMT for SCD. As the critical hematopoietic organs were not corrected without full RBC replacement, 100% peripheral blood RBC chimerism becomes the most important benchmark for cure after nonmyeloablative BMT.