Defining the mechanism of prostaglandin E₂-enhanced hematopoietic stem and progenitor cell homing

Speth, Jennifer M.

02 April 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Hematopoietic stem cell (HSC) transplantation is a lifesaving therapy for a number of hematological disorders. However, to be effective, transplanted HSCs must efficiently “home” to supportive niches within the bone marrow. Limited HSC number and poor function are complications of transplant in some circumstances, and can lead to delayed engraftment and immune reconstitution, or in some cases, bone marrow failure. Enhancing HSC homing is a strategy to improve stem cell transplantation efficiency. We have previously shown that ex vivo treatment of mouse or human HSCs with 16-16 dimethyl PGE2 (dmPGE2) increases their bone marrow homing efficiency and engraftment, resulting in part from upregulation of surface CXCR4 expression. We now show that pulse-treatment of mouse or human HSPCs with dmPGE2 stabilizes HIF1α in HSPCs, and that similar treatment with the hypoxia mimetic DMOG produces analogous effects to dmPGE2 on HSPC CXCR4 expression and homing. This suggests that HIF1α is responsible for PGE2’s enhancing effects on HSPCs. Pharmacological inhibition of HIF1α stabilization in vitro with Sodium Nitroprusside (SNP), confirms the requirement of HIF1α for dmPGE2-enhanced migration and CXCR4 upregulation. Additionally, we confirm the requirement for HIF1α in dmPGE2-enhanced in vivo homing using a conditional knockout mouse model of HIF1α gene deletion. Finally, we validate that the hypoxia response element located 1.3kb from the transcriptional start site within the CXCR4 promoter is required for enhanced CXCR4 expression after PGE2 treatment. Interestingly, we also observe an increase in the small GTPase Rac1 after dmPGE2 treatment, as well as a defect in PGE2-enhanced migration and CXCR4 expression in Rac1 knockout HSPCs. Using state-of-the-art imaging technology we, confirm an increase in Rac1 and CXCR4 colocalization after dmPGE2 treatment that likely explains enhanced sensitivity of PGE2-treated HSPCs to SDF-1. Taken together, these results define a precise mechanism through which ex vivo pulse treatment of HSPC with dmPGE2 enhances HSPC function through alterations in cell motility and homing, and describe a role for hypoxia and HIF1α in enhancement of hematopoietic transplantation.

Regeneration (Biology)

Bone marrow -- Transplantation

Immune response -- Regulation

Hematology -- Research

Gene expression

Sodium nitroferricyanide

Imaging systems in medicine

Cells -- Motility

Cell migration -- Research

Cellular signal transduction

Small molecule compounds targeting DNA binding domain of STAT3 for inhibition of tumor growth and metastasis

Huang, Wei

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Signal transducer and activator of transcription 3 (STAT3) is constitutively activated in malignant tumors, and its activation is associated with high histological grade and advanced cancer stage. STAT3 has been shown to play important roles in multiple aspects of cancer aggressiveness including proliferation, survival, self-renewal, migration, invasion, angiogenesis and immune response by regulating the expression of diverse downstream target genes. Thus, inhibiting STAT3 promises to be an attractive strategy for treatment of advanced tumors with metastatic potential. We firstly identified a STAT3 inhibitor, inS3-54, by targeting the DNA-binding site of STAT3 using an in-silico screening approach; however, inS3-54 was finally found not to be appropriate for further studies because of low specificity on STAT3 and poor absorption in mice. To develop an effective and specific STAT3 inhibitor, we identified 89 analogues for the structure-activity relationship analysis. By using hematopoietic progenitor cells isolated from wild-type and STAT3 conditional knockout mice, further studies showed that three analogues (A18, A26 and A69) only inhibited STAT3-dependent colony formation of hematopoietic progenitor cells, indicating a higher selectivity for STAT3 than their parental compound, inS3-54. These compounds were found to (1) inhibit STAT3-specific DNA binding activity; (2) bind to STAT3 protein; (3) suppress proliferation of cancer cells harboring aberrant STAT3 signaling; (4) inhibit migration and invasion of cancer cells and (5) inhibit STAT3-dependent expression of downstream targets by blocking the binding of STAT3 to the promoter regions of responsive genes in cells. In addition, A18 can reduce tumor growth in a mouse xenograft model of lung cancer with little effect on body weight. Taken together, we conclude that it is feasible to inhibit STAT3 by targeting its DNA-binding domain for discovery of anticancer therapeutics.

STAT3

DNA binding domain

Inhibitor

Structure-based drug discovery

Signaling pathway

Cancer

Chemoprevention -- Research

Cancer -- Chemotherapy

Pathology, Molecular

Genetic transcription -- Regulation

Mobile genetic elements

Drug development

Carcinogenesis

Enzyme inhibitors -- Therapeutic use

Impact of ALCAM (CD166) on homing of hematopoietic stem and progenitor cells

Aleksandrova, Mariya Aleksandrova

18 December 2012

Indiana University-Purdue University Indianapolis (IUPUI) / The potential of hematopoietic stem cells (HSC) to home and to anchor within the bone marrow (BM) microenvironment controls the ability of transplanted HSCs to establish normal hematopoiesis. Activated Leukocyte Cell Adhesion Molecule (ALCAM; also identified as CD166), which participates in homophilic interactions, is expressed on a group of osteoblasts in the hematopoietic niche capable of sustaining functional HSC in vitro. Since we could also detect ALCAM expression on HSC, we suspect that ALCAM may play a role in anchoring primitive hematopoietic cells to ALCAM expressing components of the hematopoietic niche via dimerization. We investigated the role of ALCAM on the homing abilities of hematopoietic stem and progenitor cells (HSPC) by calculating recovery frequency of Sca-1+ALCAM+ cells in an in vivo murine bone marrow transplantation model. Our data supports the notion that ALCAM promotes improved homing potential of hematopoietic Sca-1+ cells. Recovery of BM-homed Sca-1+ cells from the endosteal region was 1.8-fold higher than that of total donor cells. However, a 3.0-fold higher number of Sca-1+ALCAM+ cells homed to the endosteal region compared to total donor cells. Similarly, homed Sca-1+ALCAM+ cells were recovered from the vascular region at 2.1-fold greater frequency than total homed donor cells from that region, compared to only a 1.3-fold increase in the recovery frequency of Sca-1+ cells. In vitro quantitation of clonogenic BM-homed hematopoietic progenitors corroborate the results from the homing assay. The frequency of in vitro clonogenic progenitors was significantly higher among endosteal-homed Sca-1+ALCAM+ cells compared to other fractions of donor cells. Collectively, these data demonstrate that engrafting HSC expressing ALCAM home more efficiently to the BM and within the BM microenvironment, these cells preferentially seed the endosteal niche.

Hematopoietic Stem Cells

ALCAM (CD166)

Sca-1

Homing

Endosteal bone marrow

Vascular bone marrow

Flow cytometry

Bone marrow -- Transplantation

Human immunogenetics

Genetic regulation

Stem cells -- Research

Catenins

Cell adhesion molecules

Bone marrow cells

Regeneration (Biology)

Cell migration

Flow cytometry

Cloning

Mesenchymal stem cells

CD4+ T cell mediated tumor immunity following transplantation of TRP-1 TCR gene modified hematopoietic stem cells

Ha, Sung Pil

10 December 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Immunotherapy for cancer has held much promise as a potent modality of cancer treatment. The ability to selectively destroy diseased cells and leave healthy cells unharmed has been the goal of cancer immunotherapy for the past thirty years. However, the full capabilities of cancer immunotherapies have been elusive. Cancer immunotherapies have been consistently hampered by limited immune reactivity, a diminishing immune response over time, and a failure to overcome self-tolerance. Many of these deficiencies have been borne-out by immunotherapies that have focused on the adoptive transfer of activated or genetically modified mature CD8+ T cells. The limitations inherent in therapies involving terminally differentiated mature lymphocytes include limited duration, lack of involvement of other components of the immune system, and limited clinical efficacy. We sought to overcome these limitations by altering and enhancing long-term host immunity by genetically modifying then transplanting HSCs. To study these questions and test the efficiency of gene transfer, we cloned a tumor reactive HLA-DR4-restricted CD4+ TCR specific for the melanocyte differentiation antigen TRP-1, then constructed both a high expression lentiviral delivery system and a TCR Tg expressing the same TCR genes. We demonstrate with both mouse and human HSCs durable, high-efficiency TCR gene transfer, following long-term transplantation. We demonstrate the induction of spontaneous autoimmune vitiligo and a TCR-specific TH1 polarized memory effector CD4+ T cell population. Most importantly, we demonstrate the destruction of subcutaneous melanoma without the aid of vaccination, immune modulation, or cytokine administration. Overall, these results demonstrate the creation of a novel translational model of durable lentiviral gene transfer, the induction of spontaneous CD4+ T cell immunity, the breaking of self-tolerance, and the induction of anti-tumor immunity.

Melanoma

Lentivirus

Hematopoietic Stem Cells

Immunology

Tumor Immunology

CD4 T Cells

Gene Therapy

Tumor Antigens

T Cell Receptor

Bone Marrow Transplantation

Tumor Immunity

Tyrosine Relate Protein

Melanocyte Differentiation Antigen

Lentiviral Vectors

Melanoma -- Research

Lentiviruses

Cancer -- Immunology -- Genetic aspects

Tumors -- Immunological aspects

T cells -- Receptors

Cancer -- Gene therapy

Tumor antigens

Bone marrow -- Transplantation

Tyrosine

MSH (Hormone)

Genetic vectors -- Research

Differentiation and characterization of cell types associated with retinal degenerative diseases using human induced pluripotent stem cells

Gupta, Manav

31 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Human induced pluripotent stem (iPS) cells have the unique ability to differentiate into 200 or so somatic cell types that make up the adult human being. The use of human iPS cells to study development and disease is a highly exciting and interdependent field that holds great promise in understanding and elucidating mechanisms behind cellular differentiation with future applications in drug screening and cell replacement studies for complex and currently incurable cellular degenerative disorders. The recent advent of iPS cell technology allows for the generation of patient-specific cell lines that enable us to model the progression of a disease phenotype in a human in vitro model. Differentiation of iPS cells toward the affected cell type provides an unlimited source of diseased cells for examination, and to further study the developmental progression of the disease in vitro, also called the “disease-in-a-dish” model. In this study, efforts were undertaken to recapitulate the differentiation of distinct retinal cell affected in two highly prevalent retinal diseases, Usher syndrome and glaucoma. Using a line of Type III Usher Syndrome patient derived iPS cells efforts were undertaken to develop such an approach as an effective in vitro model for studies of Usher Syndrome, the most commonly inherited disorder affecting both vision and hearing. Using existing lines of iPS cells, studies were also aimed at differentiation and characterization of the more complex retinal cell types, retinal ganglion cells (RGCs) and astrocytes, the cell types affected in glaucoma, a severe neurodegenerative disease of the retina leading to eventual irreversible blindness. Using a previously described protocol, the iPS cells were directed to differentiate toward a retinal fate through a step-wise process that proceeds through all of the major stages of neuroretinal development. The differentiation process was monitored for a period of 70 days for the differentiation of retinal cell types and 150 days for astrocyte development. The different stages of differentiation and the individually derived somatic cell types were characterized by the expression of developmentally associated transcription factors specific to each cell type. Further approaches were undertaken to characterize the morphological differences between RGCs and other neuroretinal cell types derived in the process. The results of this study successfully demonstrated that Usher syndrome patient derived iPS cells differentiated to the affected photoreceptors of Usher syndrome along with other mature retinal cell types, chronologically analogous to the development of the cell types in a mature human retina. This study also established a robust method for the in vitro derivation of RGCs and astrocytes from human iPS cells and provided novel methodologies and evidence to characterize these individual somatic cell types. Overall, this study provides a unique insight into the application of human pluripotent stem cell biology by establishing a novel platform for future studies of in vitro disease modeling of the retinal degenerative diseases: Usher syndrome and glaucoma. In downstream applications of this study, the disease relevant cell types derived from human iPS cells can be used as tools to further study disease progression, drug screening and cell replacement strategies.

Degeneration

Differentiation

Disease Modeling

Glaucoma

Induced Pluripotent Stem Cell

Retina

Usher's syndrome -- Pathophysiology

Glaucoma -- Alternative treatment

Retinitis pigmentosa -- Pathophysiology

Genetic disorders -- Diagnosis

Embryonic stem cells -- Research

Human cell culture -- Research

Cell differentiation -- Analysis

Stem cells -- Transplantation -- Methods

Cellular therapy

Retinal ganglion cells -- Research

Retinal degeneration

Cells -- Morphology

Regenerative medicine -- Research

Transcription factors

Astrocytes -- Morphology

Genetic engineering

Drug testing