Comparative heat sensitivity of murine and human hemopoietic progenitors and clonogenic leukemia cells

Heat shock proteins and Bcl-2 expression and function in relation to the differential hyperthermic sensitivity between leukemic and normal hematopoietic cells

A major problem in autologous stem cell transplantation is the occurrence of relapse by residual neoplastic cells from the graft. The selective toxicity of hyperthermia toward malignant hematopoietic progenitors compared with normal bone marrow cells has been utilized in purging protocols. The underlying mechanism for this selective toxicity has remained unclear. By using normal and leukemic cell line models, we searched for molecular mechanisms underlying this selective toxicity. We found that the differential heat sensitivity could not be explained by differences in the expression or inducibility of Hsp and also not by the overall chaperone capacity of the cells. Despite an apparent similarity in initial heat-induced damage, the leukemic cells underwent heat-induced apoptosis more readily than normal hematopoietic cells. The differences in apoptosis initiation were found at or upstream of cytochrome c release from the mitochondria. Sensitivity to staurosporine-induced apoptosis was similar in all cell lines tested, indicating that the apoptotic pathways were equally functional. The higher sensitivity to heat-induced apoptosis correlated with the level of Bcl-2 protein expression. Moreover, stable overexpression of Bcl-2 protected the most heat sensitive leukemic cells against heat-induced apoptosis. Our data indicate that leukemic cells have a specifically lower threshold for heat damage to initiate and execute apoptosis, which is due to an imbalance in the expression of the Bcl-2 family proteins in favor of the proapoptotic family members.

Increased megakaryopoiesis in cultures of CD34-enriched cord blood cells maintained at 39 degrees C

Based on previous evidence suggesting positive effects of fever on in vivo hematopoiesis, we tested the effect of hyperthermia on megakaryopoiesis (MK) in ex vivo cultures of CD34-enriched cord blood (CB) cells. The cells were cultured at 37 degrees C or 39 degrees C for 14 days in cytokine conditions optimized for megakaryocyte development and analyzed periodically. Compared to 37 degrees C, the cultures maintained at 39 degrees C produced significantly more (up to 10-fold) total cells, myeloid and MK progenitors, and total MKs, and showed accelerated and enhanced MK maturation with increased yields of proplatelets and platelets. This observation could facilitate clinical applications requiring ex vivo expansion of hematopoietic cells.

AC133 expression on acute myeloid leukemia blasts: correlation to FAB and to CD34 expression and possible implications for peripheral blood progenitor cell purging in AML

AC133 is an antigen expressed on CD34+ hematopoietic progenitor cells. In acute myeloid leukemia (AML) it is expressed on leukemic blasts of most FAB subtypes. However, few data are available regarding coexpression of other surface antigens. We measured AC133 expression on AML blasts from 28 consecutive patients at initial diagnosis (n=26) or at diagnosis of first relapse (n=2) and on 26 leukapheresis products from 14 patients. In AML AC133 correlated with CD34 expression (Spearman r=0.4711, P=0.0114) and even stronger with combined CD34/CD33 expression (Spearman r=0.5083, P=0.0068). In leukapheresis products AC133 expression correlated with CD34 expression (Spearman r=0.7495, P=0.002) and the yield of the obtained amount of CD34+ cells (Spearman r=0.6484, P=0.0121). In conclusion AC133 expression is closely related to CD34 expression in AML. In leukapheresis products AC133 provides an additional marker for selection of PBPC autografts in AC133- AML.

Behaviour of heat-treated bone marrow cells in long-term bone marrow cultures

The effect of prior heat treatment on the ability of bone marrow cells to form long-term bone marrow culture has been studied. Bone marrow cells were heated for various times in the temperature range of 39-43 degrees C and then cultured in the modified Dexter type suspension culture. At weekly intervals, the behaviour of the cultures in terms of stroma formation and confluency, cellular viability, and myelopoiesis were evaluated. The results show that there was a dose-dependent decrease in the number of viable cells in the non-adherent fraction of the cultures. Cytological analysis of these cells showed a strong shift towards macrophage population in the successive weeks of the cultures and also as a function of heat dose delivered to these cultures. The stroma formation was delayed or inhibited as a function of the heat dose. The number of granulocyte-macrophage colony forming cells (CFU-GM) in both adherent and non-adherent fraction of the cultures were decreased substantially after hyperthermia treatment. At 41 degrees C and higher temperatures, the CFU-GM were severely diminished in both fractions. The dose response experiments showed that the decrease in the number of CFU-GM was dependent on the heat dose. The results suggest that CFU-GM is an extremely sensitive target in the hyperthermia treatment of bone marrow cells and heat-treated bone marrow cells lose their ability to maintain long-term cultures.