Engraftment of low numbers of pediatric acute lymphoid and myeloid leukemias into NOD/SCID/IL2Rcγnull mice reflects individual leukemogenecity and highly correlates with clinical outcome.

Although immortalized cell lines have been extensively used to optimize treatment strategies in cancer, the usefulness of such in vitro systems to recapitulate primary disease is limited. Therefore, the design of in vivo models ideally utilizing patient-derived material is of critical importance. In this regard, NOD.Cg-Prkdc(scid) IL2rg(tmWjl) /Sz (NSG) mice have been reported to provide superior engraftment rates. However, limited data exist on the validity of such a model to constitute a surrogate marker for clinical parameters. We studied primary and serial engraftment on more than 200 NSG mice with 54 primary pediatric B cell precursor acute lymphatic leukemia (B-ALL), myeloid leukemia (AML) and T cell leukemia (T-ALL) samples, characterized the leukemogenic profile and correlated engraftment kinetics with clinical outcome. Median time to engraftment was 7-10 weeks and 90% of the mice engrafted. Male recipients conferred significantly higher engraftment levels than female recipients (p ≤ 0.004). PCR-based minimal residual disease marker expression and fluorescence in situ hybridization confirmed the presence of patient-specific genetic aberrations in mice. Transcriptome cluster analysis of genes known to be important in the leukemogenesis of all three diseases revealed that well-known tumor-regulating genes were expressed to a comparable extent in mice and men. The extent of engraftment and overall survival of NSG mice highly correlated with the individual prognosis of B-ALL, AML and T-ALL patients. Thus, we propose an in vivo model that provides a valuable preclinical tool to explore the heterogeneity of leukemic disease and exploit patient-tailored leukemia-targeting strategies within multivariate analyses.

Monocytes derived from humanized neonatal NOD/SCID/IL2Rγ(null) mice are phenotypically immature and exhibit functional impairments.

Trials of immune-modulating drugs in septic patients have mostly failed to demonstrate clinical efficacy. Thus, we sought to generate a surrogate model of myelomonocytic lineage differentiation that would potentially allow sepsis induction and preclinical testing of anti-inflammatory drugs. Comparing transplantation of cord blood-derived stem cells in neonatal NOD/SCID/IL2Rγ(null) (neonatal huNSG) mice with transplantation of adult peripheral mobilized stem cells into adult NSG (adult huNSG) recipients, we demonstrate that myelomonocytic lineage differentiation in neonatal huNSG mice is retarded and monocytes are phenotypically immature with respect to HLA-DR expression and the emergence of CD80(+)CD86(+) monocytes. Functionally, neonatal huNSG mice were less sensitive toward interferon-γ-induced upregulation of CD86 and exhibited a reduced T-cell stimulating capacity when compared with adult huNSG mice, whereas the phagocytic activity and the ability for cytokine secretion were mature. However, comparison of these data with data obtained from human neonates indicate that absence of the CD80(+)CD86(+) population and the reduced T-cell stimulating capacity of neonatal huNSG monocytes resemble functional immaturities observed in human neonatal monocytes. Thus, these two mouse models might well serve as 2 independent surrogate models for studying the neonatal myelomonocytic lineage differentiation or for testing the efficacy of immunomodulatory drugs on functionally mature monocytes.

Long-term human CD34+ stem cell-engrafted nonobese diabetic/SCID/IL-2R gamma(null) mice show impaired CD8+ T cell maintenance and a functional arrest of immature NK cells.

Allogeneic hematopoietic stem cell transplantation represents the most effective form of immunotherapy for chemorefractory diseases. However, animal models have been missing that allow evaluation of donor-patient-specific graft-versus-leukemia effects. Thus, we sought to establish a patient-tailored humanized mouse model that would result in long-term engraftment of various lymphocytic lineages and would serve as a donor-specific surrogate. Following transfer of donor-derived peripheral blood stem cells into NOD/SCID/IL-2Rgamma(null) (NSG) mice with supplementation of human IL-7, we could demonstrate robust engraftment and multilineage differentiation comparable to earlier studies using cord blood stem cells. Phenotypical and functional analyses of lymphoid lineages revealed that >20 wk posthematopoietic stem cell transplantation, the majority of T lymphocytes consisted of memory-type CD4(+) T cells capable of inducing specific immune functions, whereas CD8(+) T cells were only present in low numbers. Analysis of NSG-derived NK cells revealed the expression of constitutively activated CD56(bright)CD16(-) killer Ig-like receptor(negative) NK cells that exhibited functional impairments. Thus, the data presented in this study demonstrate that humanized NSG mice can be successfully used to develop a xenotransplantation model that might allow patient-tailored treatment strategies in the future, but also highlight the need to improve this model, for example, by coadministration of differentiation-promoting cytokines and induction of human MHC molecules to complement existing deficiencies in NK and CD8(+) T cell development.

Combined action of celecoxib and ionizing radiation in prostate cancer cells is independent of pro-apoptotic Bax.

BACKGROUND AND PURPOSE: The cyclooxygenase-2-inhibitor celecoxib has been shown to inhibit cell growth and to reduce prostatic intraepithelial neoplasia in mice. The drug was suggested to increase efficacy of ionizing radiation. However, extent and mechanisms of the suggested benefit of celecoxib on the radiation response are still unclear. The aim of the present study was to analyze cytotoxic efficacy of celecoxib in combination with irradiation on human prostate cancer cell lines and to define the importance of pro-apoptotic Bax in this process. MATERIALS AND METHODS: Induction of apoptosis and global and clonogenic cell survival upon irradation- (2-10Gy), celecoxib- (10-75microM) or combined treatment were evaluated in prostate cancer cells by fluorescence microscopy, WST-1 assay and standard colony formation assays. RESULTS: Celecoxib <25microM caused morphological changes and growth inhibition without substantial apoptosis or radiosensitization in terms of decreased clonogenic cell survival. In contrast, celecoxib 25microM increased radiation-induced cell death and clonogenic kill. While radiation-induced clonogenic death was increased in the presence of Bax, effects of celecoxib or combined treatment were Bax independent. CONCLUSIONS: Our findings reveal Bax-independent beneficial effects of celecoxib on radiation-induced apoptosis and eradication of clonogenic prostate cancer cells in vitro providing a rationale for clinical evaluation of high-dose celecoxib in combination with irradiation in prostate cancer patients.

Array-based comparative gene expression analysis of tumor cells with increased apoptosis resistance after hypoxic selection.

Tumor hypoxia is an adverse prognostic factor. In a recent study, we could demonstrate that cyclic hypoxia selects for hypoxia-tolerant tumor cells, which are cross-resistant to other stimuli of mitochondrial death pathways. In contrast, sensitivity of the cells to death-receptor ligands was mainly not affected. The aim of the present study was to further elucidate cellular changes induced by cyclic hypoxia and to identify alterations in gene expression pattern upon hypoxic selection by means of DNA-microarray analysis. Our data reveal that cyclic hypoxia resulted in the selection of cells with resistance to doxorubicine and radiation. Furthermore, hypoxic selection was accompanied by constitutive changes of the gene expression pattern with downregulation of 156 and upregulation of 82 genes. Most of the differentially regulated genes were involved in cellular responses to hypoxia and reoxygenation. While many of the genes that were downregulated upon hypoxic selection represent genes that are usually upregulated by acute hypoxia, the genes that were upregulated represent genes that are involved in stress resistance and anti-apoptotic signalling. Most importantly, hypoxic selection was not associated with changes of single apoptosis relevant genes, but with alterations in gene expression levels of a wide variety of genes indicating a more complex adaptation process.

Cyclic exposure to hypoxia and reoxygenation selects for tumor cells with defects in mitochondrial apoptotic pathways.

The negative influence of hypoxia on the outcome of malignant tumors may be caused by direct oxygen effects, and potentially, the selection of resistant tumor cells under repetitive hypoxia. To evaluate whether cyclic hypoxia selects for resistant cells and to analyze the underlying mechanisms, the influence of cyclic hypoxia on intracellular death pathways was determined in tumor cells. It could be demonstrated that cyclic hypoxia selects for cells with increased resistance against hypoxia-induced apoptosis. These cells exhibited a cross-resistance against paradigmatic triggers of mitochondrial apoptotic pathways (ionizing radiation/etoposide). In contrast, TRAIL-receptor mediated apoptosis remained unaffected. Thus, cyclic hypoxia selects for cells with defects of the mitochondrial rather than receptor-mediated pathways. Selection of p53-defective cells has been described as a consequence of cyclic hypoxia; therefore, we evaluated the impact of hypoxic selection on activation of p21 and downstream mediators of p53-dependent apoptosis. p53 function and protein levels of key mediators of mitochondrial apoptosis remained unaffected by hypoxic selection. However, radiation-induced conformational changes of Bax were reduced after cyclic hypoxia. In summary, it could be demonstrated that hypoxic stress confers a selection pressure on mitochondrial apoptotic pathways and, consecutively, to an increased resistance toward mitochondrial death triggers.

Molecular ordering of hypoxia-induced apoptosis: critical involvement of the mitochondrial death pathway in a FADD/caspase-8 independent manner.

Dys-regulated growth and improper angiogenesis commonly lead to areas of hypoxia in human tumors. Hypoxia is known to be associated with a worse outcome since a lack of oxygen interferes with the efficacy of chemotherapy or radiotherapy. In parallel, hypoxia-induced apoptosis may also impose a selection pressure favoring growth of more resistant tumor cells. However, the mechanisms of hypoxia-induced apoptosis and the relative contribution of intrinsic and extrinsic apoptotic pathways are not understood. Therefore, Jurkat cell lines with defined defects in the extrinsic or intrinsic signaling cascades were used to evaluate the role of either pathway for induction of apoptosis under hypoxic conditions. Jurkat cells were incubated in hypoxia and the rate of apoptosis induction was determined by Western blotting, fluorescence microscopy and flow cytometry. Hypoxia-induced apoptosis was not affected by lack of caspase-8 or FADD, whereas overexpression of Bcl-2 or expression of dominant-negative caspase-9 mutant rendered the cells resistant to hypoxia-induced apoptosis. These results suggest that hypoxia-induced apoptosis mainly relies on intrinsic, mitochondrial pathways, whereas extrinsic pathways have no significant implications in this process. Thus, in human tumors, hypoxia will mainly lead to the selection of hypoxia-resistant cells with defects in mitochondrial apoptosis signaling pathways.

Influence of hypoxia on TRAIL-induced apoptosis in tumor cells.

PURPOSE: Tumor hypoxia reduces the efficacy of radiotherapy, many types of chemotherapy, and tumor necrosis factor-alpha (TNF-alpha). TRAIL (TNF-alpha-related apoptosis-inducing ligand) is a ligand for death receptors of the TNF superfamily shown to be selectively toxic for tumor cells and thereby a promising antineoplastic tool. The impact of hypoxia on TRAIL-induced apoptosis was examined in this study. METHODS AND MATERIALS: Apoptosis induction and growth rates of various tumor cell lines under hypoxia were evaluated in vitro. Biologically effective induction of hypoxia was verified by determination of hypoxia-inducible factor-1 (HIF-1) activation. The efficacy of TRAIL- and radiation-induced apoptosis under different oxygen conditions was quantified in vitro. The impact of Bcl-2 on TRAIL-induced apoptosis under hypoxia or normoxia was evaluated by comparing cells expressing Bcl-2 with a vector control. RESULTS: Moderate hypoxia caused no growth retardation or apoptosis, but led to activation of HIF-1 as a prerequisite of hypoxic gene induction. Cellular responses to TRAIL differed considerably among the cell lines tested. Hypoxia reduced radiation-induced, but not TRAIL-induced, apoptosis in the tested cell lines. Hypoxia did not induce Bcl-2 expression. Bcl-2 had a minor impact on the efficacy of TRAIL-induced apoptosis. CONCLUSION: Taken together, the data indicate that TRAIL is clearly effective under conditions of proven hypoxia.