A tissue engineered approach to progenitor cell delivery and myocardial repair

Simpson, David Lemar

21 August 2009

Heart failure accounts for more deaths in the United States than any other pathology. Unfortunately, repairing the heart after pathological injury has become an overwhelming task for physicians and researchers to overcome. Fortunately, cellular cardiomyoplasty has emerged as a promising solution for sufferers of heart failure. Such a therapy is limited in efficacy due to poor engraftment efficiencies, however. To address this issue, we have developed a tissue engineered vehicle for cell delivery. Use of a "cardiac patch" resulted in localized and efficient delivery of human mesenchymal stem cells (hMSC) to infarcted myocardium. Application of a cardiac patch also attenuated adverse remodeling. Additionally, the culture of stem/progenitor cells within three dimensional collagen constructs led to modulations in cell function, which did not promote enhanced angiogenesis in vitro or in vivo. Despite enhanced neovessel formation, hMSC patches were more beneficial at augmenting myocardial repair compared to directly injected hMSC. Lastly, although hMSC represent an effective cell source option for enhancing cardiac repair they require additional purification and expansion steps which inherently delay the turnover before treatment. Therefore, suitable cell alternative are being sought. Human embryonic stem cell derived mesenchymal (B4) cells display several phenotypic similarities to hMSC. B4 progenitor cells responded similarly to hMSC in 3D culture. In addition B4 progenitor cell patch application to infarcted myocardium resulted in similar indices of repair compared to hMSC. Thus, a tissue engineering approach represents an effective cell delivery strategy and induces modulations in cell function which may demonstrate pathological significance.

Stem cell

Tissue engineering

Myocardial infarction

Cell delivery

Paracrine

Progenitor cells

Coronary heart disease

Microenvironmental stimulation of cardiac progenitor cells

French, Kristin Marie

21 September 2015

Heart failure, predominately caused by myocardial infarction (MI), is the leading cause of death in the United States. Currently the only treatment for heart failure is cardiac transplantation, but studies show that progenitor cell, biomaterial, or combined therapies have improved cardiac function post-MI. The endogenous environment of CPCs is drastically different from commonly used culture conditions. Further the endogenous environment changes with age and disease state. We evaluated the behavior of CPCs cultured on a naturally-derived, cardiac extracellular matrix (cECM) as compared to the standard culture coating collagen I, that also mimics fibrotic tissue. In this study, CPCs cultured on cECM had improved cell numbers and cardiomyogenic maturation. However, the microenvironmental cues responsible for stimulating CPC activation are largely unknown. During development, aging and disease the myocardium changes in matrix composition and stiffness exposing endogenous cells to a wide variety of stimuli. In a combinatorial study, we evaluated the effect of cyclic strain and extracellular matrix composition on CPC behavior. The response of CPCs to signals from the microenvironment is complex, with more matrix-dependency observed at lower strains. Alignment, cell division and paracrine signaling are extracellular matrix and strain dependent. Extracellular matrix conditions affect CPC maturation and calcium signaling. Mechanotransduction pathways, including focal adhesion kinase and extracellular signal-regulated kinase, are activated through adhesion and maintained under cyclic strain. Insights from this work will advance pragmatic cell therapy attempts to regenerate healthy myocardium post-MI.

Cardiac progenitor cells

Decellularized extracellular matrix

Microenvironment

Myocardial infarction

Cyclic strain

Evidence for the physical interaction of endosomes with mitochondria in erythroid cells

Kahawita, Tanya.

January 2008

Utilization of iron by hemoglobin-producing cells is highly efficient. The acquisition of iron from plasma requires the binding of diferric transferrin (Tf) to its cognate receptor (Tf-R) on the erythroid cell membrane, followed by internalization of the Tf - Tf-R complexes via receptor-mediated endocytosis. Through a poorly understood mechanism, iron is targeted to mitochondria, the site of heme biosynthesis. We believe that a direct interaction between iron-containing endosomes and mitochondria is essential for iron transfer to mitochondria and its efficient incorporation into heme. / In order to illustrate the interaction between endosomes and mitochondria, we have employed flow cytometry. Flow cytometry analysis of reticulocytes (erythrocyte precursors which still synthesize hemoglobin) stained with fluorescent dyes specific to mitochondria and endosomes revealed three distinct populations: mitochondria, endosomes and a population labeled with both dyes. This double-labeled population suggests a population composed of endosomes associated with mitochondria. Using non-fluorescent diferric-Tf, we were able to remove the double population, leaving only the endosomal and the mitochondrial population. This finding has confirmed that the double population is the result of the interaction between the two organelles. / Additionally, we established a cell-free assay consisting of fluorescent mitochondria and endosomes isolated from erythroid cells. Using confocal microscopy, we demonstrated a colocalization between the two organelles. We repeated the assay using fluorescent mitochondria and endosomes isolated from HeLa spinner cells. Using the mitochondrial uncoupler CCCP, we were able to significantly reduce the colocalization between the two organelles, indicating that the interaction between the organelles is specific and that the mitochondrial potential is a requirement for organellar interaction. / Based on our results from flow cytometry and confocal microscopy, we conclude that a specific and direct interaction exists between the two organelles.

Heme -- biosynthesis.

Iron -- metabolism.

Reticulocytes -- metabolism.

Endosomes -- metabolism.

Mitochondria -- metabolism.

MECHANISMS OF HEME-OXYGENASE-1 CYTOPROTECTION FOR GENE AND CELL BASED THERAPIES AGAINST CARDIOVASCULAR DISEASE

Brunt, KEITH

23 April 2009

Establishing the cellular and molecular basis for cardiovascular disease and the application of tools to manipulate the cardiovascular system genetically provide potential for new forms of treatment against cardiovascular disease, including: atherosclerosis, myocardial ischemia, cardiac hypertrophy and heart failure. Heme oxygenase-1 (HO-1) is an enzyme that has potential for the treatment of cardiovascular diseases (CVD). Atherosclerotic plaques express high levels of HO-1. Advanced plaques are stabilized in part through the separation of plaque constituents from the blood by the fibrous cap made up of smooth muscle cells. Protection of smooth muscle cells from apoptosis in the fibrous cap may be a means of promoting plaque stability in patients. Here we show that expression of HO-1 in human vascular smooth muscle cells renders them resistant to apoptosis mediated by oxidative stress. The cytoprotective mechanism mediated by HO-1 is mediated in part through protein kinase B (Akt). Plaque rupture may lead to myocardial infarction. Tissue recovery after mycocardial infarction requires neovascularization for improved tissue perfusion. A novel cell type recently discovered in the circulation has been characterized as an endothelial progenitor cell (EPC) and appears capable of promoting neovascularization of post-infarct tissue, thereby enhancing tissue recovery and perfusion. Most EPCs transplanted into the infarct environment do not survive or are not retained to function in neovascularization. Here we show that expression of HO-1 and its cytoprotective partner Akt protect EPCs in an infarct environment and promote EPC function in an infarct environment. Oxidative stress can result in maladaptive cardiomyocyte hypertrophy. In a model of oxidative stress-induced myocyte hyperterophy we demonstrate the expression of HO-1 prevents cellular hypertrophy through antioxidant mechanisms and regulation of the transcription nuclear factor kappa B (NF-κB). Atherosclerotic plaque vulnerability is determined by the composition of the lesion. We demonstrate that HO-1 deficient mice have more calcified and fibrotic lesions. This may have implications in the management of late stage atherosclerosis. Collectively, this work demonstrates new insights into the molecular mechanisms of cardiovascular cells under stress that may have implications for strategies aimed at treating CVD using HO-1. / Thesis (Ph.D, Physiology) -- Queen's University, 2009-04-21 15:31:14.05

HEME-OXYEGANSE-1

CARDIOVASCULAR DISEASE

PROTEIN KINASE B

ATHEROSCLEROSIS

ENDOTHELIAL PROGENITOR CELLS

PLAQUE STABILITY

Existence of endothelial progenitor cells with self-renewal and clonogenic potential in normal human placenta and preeclampsia

Garbacea, Ioana

Unknown Date

No description available.

preeclampsia

micro vasculature

macro vasculature

endothelial progenitor cells

human placenta

endothelial colony forming cells

The Effect of Ketamine and Glutamate on Proliferation, Differentiation and Migration of Neural Progenitor Cells Derived from the Subventricular Zone and Spinal Cord

Shanmugalingam, Ushananthini

07 May 2013

During spinal cord injury (SCI), glutamate excitotoxicity and astrocytic scar formation can impede repair. In a preliminary study we found that ketamine, a N-methyl-D-aspartate (NMDA) receptor non-competitive antagonist, can contribute to functional recovery post SCI. Therefore, we investigated the cellular basis for this recovery with respect to neural progenitor cells using an in vitro cell culture model. We examined whether ketamine and glutamate influenced the proliferation, differentiation, and migration of differentiating endogenous neural progenitor cells (NPCs) found in the subventricular zone and spinal cord. Our study illustrates that the post functional recovery may have been due to ketamine’s influence on delaying spinal cord NPCs derived astrocyte maturation and migration while increasing radial glial cell migration. These results are promising since ketamine administration may help alleviate some of the adverse affects glutamate has on the NPCs found in the spinal cord following SCI.

Ketamine

Spinal cord

Subventricular zone

Neural progenitor cells

Glutamate

Proliferation

Differentiation

Migration

Differentiation of Human Atrial Myocytes from Endothelial Progenitor Cell-Derived Induced Pluripotent Stem Cells

Jambi, Majed

30 May 2014

Recent advances in cellular reprogramming have enabled the generation of embryoniclike cells from virtually any cell of the body. These inducible pluripotent stem cells (iPSCs) are capable of indefinite self-renewal while maintaining the ability to differentiate into all cell types. Nowhere will this technology have a greater impact than in the ability to generate disease and patient-specific cell lines. Here we explore the capacity of human iPSCs reprogrammed from peripheral blood endothelial progenitor cells lines to differentiate into atrial myocytes for the study of patient specific atrial physiology. Methods and Results: Late outgrowth endothelial progenitor cells (EPCs) cultured from clinical blood samples provided a robust cell source for genetic reprogramming. Transcriptome analysis hinted that EPCs would be comparatively more amenable to pluripotent reprogramming than the traditional dermal fibroblast. After 6 passages, EPCs were transduced with a doxycycline inducible lentivirus system encoding human transcription factors OCT4, SOX2, KLF4 and Nanog to permit differentiation after removal of doxycycline. The high endogenous expression of key pluripotency transcripts enhanced the ease of iPSC generation as demonstrated by the rapid emergence of typical iPSC colonies. Following removal of doxycycline, genetically reprogrammed EPC-iPSC colonies displayed phenotypic characteristics identical to human embryonic stem cells and expressed high levels of the pluripotent markers SSEA-4, TRA1-60 and TRA1-81. After exposure to conditions known to favor atrial identity, EPC- iPSC differentiating into sheets of beating cardiomyocytes that expressed high levels of several atrial-specific expressed genes (CACNA1H, KCNA5, and MYL4). Conclusions: EPCs provide a stable platform for genetic reprogramming into a pluripotent state using a doxycycline conditional expression system that avoids reexpression of oncogenic/pluripotent factors. Human EPC-derived iPSC can be differentiated into functional cardiomyocytes that express characteristic markers of atrial identity.

inducible pluripotent stem cells

Atrial Cardiomyocytes

Decellularised extracellular matrices as instructive microenvironments for bone marrow derived stem cells

Prewitz, Marina

07 May 2012

The regenerative potential of adult stem cell populations within the human body bears great promises for their use in regenerative medicine. The bone marrow (BM) harbours two different types of adult stem cells, haematopoietic stem and progneitor cells (HSPCs) and multipotent mesenchymal stromal cells (MSCs), which are tightly regulated in their distinct anatomically defined niches by multiple cues such as cytokines, cell-cell contacts, the extracellular matrix (ECM) and the physical microenvironment. The ex vivo expansion of these cells for applications in regenerative therapies is of great interest and several biomaterial approaches attempt to mimic the natural BM niche and its components to control stem cell maintenance and differentiation. However, as of now the complexity of such stem cell niches is hard to recapitulate. Towards this goal, this work was focussing on the ECM environment of BM stem cells and was set out to engineer improved in vitro culture systems. MSC themselves are one of the most important cell types within the BM that secrete and construct ECM-networks and thereby shape the microenvironment of the residing cells. The potential of primary human BM-MSC to secrete ECM in vitro has been exploited to generate niche-like ECM surrogates in a robust and versatile format. Application of decellularisation regimes allowed the fabrication of complex matrices which demonstrated suprastructural, compositional and physicochemical properties compareable to those of the native BM-ECM environment. Reliable stability and reproduciblity was achieved by a dedicated procedure of maleic anhydride co-polymer-mediated covalent binding of fibronectin and subsequent anchorage of cell-secreted ECM molecules. As a result of the high reproducibility, a complete proteomic register of ECM molecules was obtained in combination with determining the complex fibrillar and soft gel-like characteristics of MSC-derived matrices. Based on the established BM niche-like substrate, the impact of extracellular matrices on MSC and HSPC ex vivo behavior has been explored. Both cell types demonstrated strong adhesion to ECM substrates and depicted a changed cellular morphology upon contact with native ECM structures compared to standard culture substrates or simple ECM protein coatings, indicating an intense interplay between the cell and the microenvironment. MSC that re-grew into their own matrices have shown advantageous proliferation and cytokine secretion levels as well as enhanced differentiation intensity (upon differentiation induction) compared to MSC that were cultured on less complex substrates. Similarly, HSPC were also instructed for enhanced expansion on MSC-derived matrices without exhaustion of stem cell-marker expressing progenitor cells. The efficiency of these matrices was related to their ability to mimic the native composite suprastructure, ligand nano-topography, molecular composition and physical properties of natural BM ECM environments. The data obtained within this thesis set the ground for a more rational design of artificial stem cell niches with defined and distinct properties, offering exciting options for the in-depth analysis and understanding of stem cell regulation by exogenous cues.

Knochenmark

Stammzellen

Extracellular matrix

Mesenchymal stem cells

Haematopoietic stem and progenitor cells

ddc:570

rvk:WG 2100

Vascular Endothelial Growth Factor Functionalized Agarose Can Efficiently Guide Pluripotent Stem Cell Aggregates Toward Blood Progenitor Cells

Rahman, Muhammad Nafeesur

27 July 2010

Embryonic stem cells (ESCs) are derived from the inner cell mass (ICM) of the embryo that have great potential for regenerative therapies because of their ability to self-renew and differentiate into almost all cell types. However, this developmental potential is influenced by the local cellular microenvironment, including cell surface bound ligands. In this study, we synthesized an artificial stem cell niche wherein vascular endothelial growth factor A (VEGFA) was functionally immobilized in an agarose hydrogel. Immobilized VEGFA treatments were able to upregulate mesodermal markers, brachyury and VEGF receptor 2, by day 4 and were CD34+CD41+ by day seven. Subsequently, VEGFA immobilized treatments were able to generate colony forming cells by day fourteen. This work demonstrates our ability to use functionalized hydrogels to guide ESCs toward blood progenitor cells and serves as a useful tool to replicate aspects of the embryonic microenvironment.

Agarose

Hydrogel

Embryoid Bodies

VEGFA

Blood Progenitor Cells

3D

Differentiation

Serum-Free

0541

0542

Vascular Endothelial Growth Factor Functionalized Agarose Can Efficiently Guide Pluripotent Stem Cell Aggregates Toward Blood Progenitor Cells

Rahman, Muhammad Nafeesur

27 July 2010

Embryonic stem cells (ESCs) are derived from the inner cell mass (ICM) of the embryo that have great potential for regenerative therapies because of their ability to self-renew and differentiate into almost all cell types. However, this developmental potential is influenced by the local cellular microenvironment, including cell surface bound ligands. In this study, we synthesized an artificial stem cell niche wherein vascular endothelial growth factor A (VEGFA) was functionally immobilized in an agarose hydrogel. Immobilized VEGFA treatments were able to upregulate mesodermal markers, brachyury and VEGF receptor 2, by day 4 and were CD34+CD41+ by day seven. Subsequently, VEGFA immobilized treatments were able to generate colony forming cells by day fourteen. This work demonstrates our ability to use functionalized hydrogels to guide ESCs toward blood progenitor cells and serves as a useful tool to replicate aspects of the embryonic microenvironment.

Agarose

Hydrogel

Embryoid Bodies

VEGFA

Blood Progenitor Cells

3D

Differentiation

Serum-Free

0541

0542