Leukemic stromal hematopoietic microenvironment negatively regulates the normal hematopoiesis in mouse model of leukemia.

BACKGROUND AND OBJECTIVE: Leukemic microenvironment has a major role in the progression of leukemia. Leukemic cells can induce reversible changes in microenvironmental components, especially the stromal function which results in improved growth conditions for maintaining the malignant leukemic cells. This study aimed to investigate the survival advantage of leukemic cells over normal hematopoietic cells in stromal microenvironment in long term. METHODS: The mice were injected intraperitoneally with N-N' ethylnitrosourea (ENU) to induce leukemia; the mice received injection of normal saline were used as control. At 180 days after ENU induction, the mice were killed and the bone marrows were cultured for 19 days. Colony-forming assays were used to analyze the formation of various cell colonies. The expression of Sca-1, CD146, VEGFR2, CD95, pStat3, pStat5, and Bcl-xL in marrow cells were detected by flow cytometry. RESULTS: Long-term leukemic bone marrow culture showed abnormal elongated stromal fibroblasts with almost absence of normal hematopoietic cells. Adherent cell colonies were increased, but CFU-F and other hematopoietic cell colonies were significantly decreased in leukemia group (P<0.001). Primitive progenitor-specific Sca-1 receptor expression was decreased with subsequent increased expression of CD146 and VEGFR-2 in leukemic bone marrow cells. Decreased Fas antigen expression with increased intracellular pStat3, pStat5 and Bcl-xL proteins were observed in leukemic bone marrow cells. CONCLUSIONS: Stromal microenvironment shows altered morphology and decreased maturation in leukemia. Effective progenitor cells are decreased in leukemia with increased leukemia-specific cell population. Leukemic microenvironment plays a role in promoting and maintaining the leukemic cell proliferation and survivability in long term.

Primitive Sca-1 Positive Bone Marrow HSC in Mouse Model of Aplastic Anemia: A Comparative Study through Flowcytometric Analysis and Scanning Electron Microscopy.

Self-renewing Hematopoietic Stem Cells (HSCs) are responsible for reconstitution of all blood cell lineages. Sca-1 is the "stem cell antigen" marker used to identify the primitive murine HSC population, the expression of which decreases upon differentiation to other mature cell types. Sca-1(+) HSCs maintain the bone marrow stem cell pool throughout the life. Aplastic anemia is a disease considered to involve primary stem cell deficiency and is characterized by severe pancytopenia and a decline in healthy blood cell generation system. Studies conducted in our laboratory revealed that the primitive Sca-1(+) BM-HSCs (bone marrow hematopoietic stem cell) are significantly affected in experimental Aplastic animals pretreated with chemotherapeutic drugs (Busulfan and Cyclophosphamide) and there is increased Caspase-3 activity with consecutive high Annexin-V positivity leading to premature apoptosis in the bone marrow hematopoietic stem cell population in Aplastic condition. The Sca-1(bright), that is, "more primitive" BM-HSC population was more affected than the "less primitive" BM-HSC Sca-1(dim ) population. The decreased cell population and the receptor expression were directly associated with an empty and deranged marrow microenvironment, which is evident from scanning electron microscopy (SEM). The above experimental evidences hint toward the manipulation of receptor expression for the benefit of cytotherapy by primitive stem cell population in Aplastic anemia cases.

Alteration in marrow stromal microenvironment and apoptosis mechanisms involved in aplastic anemia: an animal model to study the possible disease pathology.

Aplastic anemia (AA) is a heterogeneous disorder of bone marrow failure syndrome. Suggested mechanisms include a primary stem cell deficiency or defect, a secondary stem cell defect due to abnormal regulation between cell death and differentiation, or a deficient microenvironment. In this study, we have tried to investigate the alterations in hematopoietic microenvironment and underlying mechanisms involved in such alterations in an animal model of drug induced AA. We presented the results of studying long term marrow culture, marrow ultra-structure, marrow adherent and hematopoietic progenitor cell colony formation, flowcytometric analysis of marrow stem and stromal progenitor populations and apoptosis mechanism involved in aplastic anemia. The AA marrow showed impairment in cellular proliferation and maturation and failed to generate a functional stromal microenvironment even after 19 days of culture. Ultra-structural analysis showed a degenerated and deformed marrow cellular association in AA. Colony forming units (CFUs) were also severely reduced in AA. Significantly decreased marrow stem and stromal progenitor population with subsequently increased expression levels of both the extracellular and intracellular apoptosis inducer markers in the AA marrow cells essentially pointed towards the defective hematopoiesis; moreover, a deficient and apoptotic microenvironment and the microenvironmental components might have played the important role in the possible pathogenesis of AA.

Phenotypic alteration of bone marrow HSC and microenvironmental association in experimentally induced leukemia.

Leukemia is a heterogeneous disorder of bone marrow (BM) failure syndrome where normal hematopoiesis gets altered due to transformation of either the normal hematopoietic cell or the hematopoietic microenvironment or both. Scientists have tried for decades to understand leukemia development in the context of therapeutic strategies. The existence of "leukemic stem cells" and their possible role in leukemogenesis have only recently been identified and it has changed the perspective with regard to new approaches for treating the disease. However the relationship between leukemic stem cells (LSCs) and leukemogenesis requires further investigation. In this present study, we have experimentally induced leukemia in mice by means of N-N' Ethylnitrosourea (ENU) to investigate the alterations in normal bone marrow cellular phenotype and associated changes in the stromal hematopoietic microenvironment under the event of leukemic disease progression. We have identified a significant decrease in the normal HSC phenotype in terms of Sca1 and c-kit receptor expression and subsequent sharp increase in certain leukemic cell specific receptor expression like CD123, CXCR4 and CD44 in the leukemic bone marrow. The decreased HSC receptor (Sca1 and c-kit) expression profile with concurrent increase in the expression of leukemic cell specific receptors (CD123, CXCR4, CD44) by the bone marrow cells of leukemic mice may account for the possible transformation of the normal hematopoietic cells that is necessary for the disease initiation and progression. Some of these receptors like CXCR4 and CD44 are also known to play an important role in maintaining leukemic cells and their complex crosstalk with the surrounding stromal microenvironment. Thus up-regulation in CXCR4 and CD44 receptor expression essentially pointed towards the stroma dependent surveillance of the leukemic bone marrow cells in leukemia. Leukemic bone marrow cells documented a rapid generation of stromal feeder layer in culture. The rapid stroma generation further supported the fact that leukemic stromal microenvironment gets altered in possible ways to support leukemic cell generation and fueling leukemogenesis. The study presented here, has tried to hint at exploring new therapeutic strategies by not only identifying the expression profile of cell surface receptors unique to cells involved in leukemic progression but also targeting the specific components of the stromal microenvironment that would facilitate therapeutic management of the disease.

The bone marrow stem stromal imbalance--a key feature of disease progression in case of myelodysplastic mouse model.

Myelodysplastic syndromes (MDSs) represent a spectrum of disorders that are generally thought to arise from a defective hematopoietic stem cell leading to clonal, dysregulated hematopoiesis. Although it is generally agreed that the marrow microenvironment plays a role in the biology of MDS, it is unclear whether this represents an intrinsically abnormal stromal compartment derived from the MDS clone. Hematopoiesis requires cooperation between progenitors and a variety of functionally and phenotypically different cell types that form the bone marrow stroma. Stromal abnormalities suspected to contribute to the pathology of bone marrow disorder with impaired hematopoiesis. Several studies on human MDS bone marrow microenvironment revealed functional alteration and increased cellular apoptosis thus contribute to the pathology of the disease progression. In this present study, we have investigated alterations in the hematopoietic microenvironment and underlying mechanisms involved in the disease progression of MDS animal model. We presented the results of bone marrow single cell culture study, Long-term bone marrow adherent culture study (LTBMC) and their functional efficacy, flowcytometric characterization of stem (Scal+c-kit+) and stromal (Scal+CD44+) progenitor cell population and expression level of extracellular apoptosis marker (Annexin v) in the bone marrow cells of MDS animal model. Bone marrow single cell culture study of MDS animal showed impairment in the normal cellular generation, proliferation and presence of apoptic cells. Long-term liquid Bone marrow stromal cell colony formation assay from MDS bone marrow cells showed significant difference in the colony formation and their maintenance than the control groups of animals. Immune functional capacity of the bone marrow stromal cells through cell mediated immune (CMI) parameter study denoted defects in the stromal microenvironment. Decreased expression of bone marrow long-term primitive hematopoietic population and stromal progenitor population depicted bone marrow abnormality in case of MDS animal model, which bears significant correlation with high expression level of apoptosis marker in the bone marrow cells. From the above experimental study we tried to highlight the abnormal bone marrow microenvironment and alteration in the bone marrow cell surface marker expression, which could be the probable mechanism of evolution and disease progression in case of MDS animal model.

An animal model of chronic aplastic bone marrow failure following pesticide exposure in mice.

The wide use of pesticides for agriculture, domestic and industrial purposes and evaluation of their subsequent effect is of major concern for public health. Human exposure to these contaminants especially bone marrow with its rapidly renewing cell population is one of the most sensitive tissues to these toxic agents represents a risk for the immune system leading to the onset of different pathologies. In this experimental protocol we have developed a mouse model of pesticide(s) induced hypoplastic/aplastic marrow failure to study quantitative changes in the bone marrow hematopoietic stem cell (BMHSC) population through flowcytometric analysis, defects in the stromal microenvironment through short term adherent cell colony (STACC) forming assay and immune functional capacity of the bone marrow derived cells through cell mediated immune (CMI) parameter study. A time course dependent analysis for consecutive 90 days were performed to monitor the associated changes in the marrow's physiology after 30(th), 60(th) and 90(th) days of chronic pesticide exposure. The peripheral blood showed maximum lowering of the blood cell count after 90 days which actually reflected the bone marrow scenario. Severe depression of BMHSC population, immune profile of the bone marrow derived cells and reduction of adherent cell colonies pointed towards an essentially empty and hypoplastic marrow condition that resembled the disease aplastic anemia. The changes were accompanied by splenomegaly and splenic erythroid hyperplasia. In conclusion, this animal model allowed us a better understanding of clinico-biological findings of the disease aplastic anemia following toxic exposure to the pesticide(s) used for agricultural and industrial purposes.

Kinetic impairment of haemopoietic stem cells in experimentally induced leukemia and aplastic anemia: an inverse correlation.

The production of blood cells from bone marrow (BM) hematopoietic stem cells (HSC) is regulated by a number of cytokines and growth factors that influence cell survival; differentiation, proliferation and apoptosis in health and supposedly, such mechanisms are deregulated in diseased conditions. As far as cellular kinetics is concerned HSCs are relatively quiescent in adults, have the ability to replicate symmetrically and asymmetrically and predictably exhibit multi-lineage hematopoietic reconstitution potential. HSC drive hematopoiesis and homeostasis by contracting and expanding the pool of hematopoietic cells in the bone marrow. In mouse they can be identified immunophenotypically as Sca1+ c-kit cells. In aplastic anemia a drastic decline in the marrow efficacy to produce mature blood cells leads to bone marrow failure. In contrast, in leukemia hyper stimulated marrow leads to deregulated differentiation of immature hematopoietic stem cells with increased self-proliferation potential. In our experimental set up, we induced aplastic anemia by injecting busulfan and cyclophosphamide and leukemia by N-N' ethylnitrosourea intraperitoneally in inbred swiss albino mice. Indeed, HSCs and haematopoietic progenitor cells (HPCs) are vulnerable target for such disease oriented dysregulation which bears close correlation with the bone marrow microenvironmental damage. The present study aims at evaluating the possible mechanism(s) of deregulation in the bone marrow physiology with special reference to HSC surface receptor expression, cellular granularity, cell cycle status and overall marrow architecture. The investigations made so far revealed an interesting correlation between disease initiation and specific cytokinetic involvement of HSC in the BM microenvironment with particular reference to leukemia and aplastic anemia.

Sca-1 / c-Kit receptor expression and apoptosis pattern in ENU induced MDS mice.

The bone marrow is the major site of haemopoiesis in adult human. It contains cells that represent the stages in the development of different types of blood cells e.g. myelocytes, metamyelocytes, erythroblasts, reticulocytes, and other lymphoid progenies etc. Bone marrow failure is primarily the result of a specific failure of bone marrow precursor cells to produce mature cells. N-ethyl N-nitroso urea (ENU) is one of the most potent mutagens that can create an abnormal bone marrow microenvironment by causing defect in haematopoietic stem cell maturation cascade. ENU is easy to administer in mouse, and some probable mutations can be helpful to create models of human diseased conditions like Myelodysplastic syndrome (MDS). MDS is considered as an intravascular bone marrow disorder, a combined structural-functional abnormality wherein the differentiation procedure of the bone marrow stem cell is either incomplete or defective. We assumed that Myelodysplastic syndrome stands in between an inhibitory cellular pattern and a positive overshoot of abnormal differentiations representing an unknown juncture where the mystery of aplasia and leukemia hide back. Instead of using a transgenic mouse model, we attempted to develop an experimentally induced murine model of preleukemia or human MDS like disease model. In doing so ENU has been administered i.p and the animals were examined on thirtieth day and peripheral blood haemogram was documented. Upon registering the appearance of abnormal peripheral blood scenario, the changes in the intravascular bone marrow (BM) architecture, cell surface receptor expression, e.g. Sca-1, c-Kit and the early and late phase apoptic patterns were noted. The results represented an interesting correlation in between bone marrow architecture, early stem cell receptor and apoptic marker expression resembling human MDS.