Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential
Cardiovascular disease is the leading cause of death in the United States, and coronary artery disease (CAD) kills over 370,000 people annually. There are available therapies that offer a temporary solution; however, only a heart transplant can fully resolve heart failure, and donor organ shortages...
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Virginia Tech
2019
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Keratin/Keratose Biomaterials Human c-kit+ cardiac stem cells Differentiation Vascular smooth muscle cells Hind limb ischemic mouse model Laser Doppler Imaging Blood flow Cardiovascular diseases |
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Keratin/Keratose Biomaterials Human c-kit+ cardiac stem cells Differentiation Vascular smooth muscle cells Hind limb ischemic mouse model Laser Doppler Imaging Blood flow Cardiovascular diseases Ledford, Benjamin Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential |
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Cardiovascular disease is the leading cause of death in the United States, and coronary artery disease (CAD) kills over 370,000 people annually. There are available therapies that offer a temporary solution; however, only a heart transplant can fully resolve heart failure, and donor organ shortages severely limit this therapy. C-kit+ human cardiac stem cells (hCSCs) offers a viable alternative therapy to treat cardiovascular disease by replacing damaged cardiac tissue; however, low cell viability, low retention/engraftment, and uncontrollable in vivo differentiation after transplantation has limited the efficacy of stem cell therapy. Tissue engineering solutions offer potential tools to overcome current limitations of stem cell therapy. Materials derived from natural sources such as keratin from human hair offers innate cellular compatibility, bioactivity, and low immunogenicity. Keratin proteins extracted using oxidative chemistry known as keratose (KOS) have shown therapeutic potential in a wide range of applications including cardiac regeneration. My studies utilize KOS hydrogels to modulate c-kit+ hCSC differentiation, and explore the capability of differentiated cells to regenerate vascular tissue.
In the first Chapter, we reviewed literature relevant to keratin-based biomaterials and their biomedical applications, the use of stem cells in cardiovascular research, and the differentiation of vascular smooth muscle cells (VSMCs). The section on biomedical applications of keratin biomaterials focuses on the oxidized form of keratin known as keratose (KOS), because this was the material used for our research. Since we planned to use this material in conjunction with c-kit+ hCSCs, we also briefly explored the use of stem cells in cardiovascular research. Additionally, we examined some key signaling pathways, developmental origins, and the cell phenotype of VSMCs for reasons that will become clear after observing results from chapters 2 and 3. Based upon our review of the literature, KOS biomaterials and c-kit+ hCSCs were determined to be promising as a combined therapeutic for the regeneration of cardiac tissue.
Research in Chapter 2 focused on characterizing the effects of KOS hydrogel on c-kit+ hCSC cell viability, proliferation, morphology, and differentiation. Results demonstrated that KOS hydrogels could maintain hCSC viability without any observable toxic effects, but it modulated cell size, proliferation, and differentiation compared to standard tissue culture polystyrene cell culture (TCPS). KOS hydrogel produced gene and protein expression consistent with a VSMC phenotype. Further, we also observed novel "endothelial cell tube-like" microstructures formed by differentiated VSMCs only on KOS hydrogel, suggesting a potential capability of the hCSC-derived VSMCs for in vitro angiogenesis. Results from this study lead us to question what signaling pathways might be responsible for the apparent VSMC differentiation pattern we observed on KOS hydrogels.
Research in Chapter 3 explored the time course of VSMC differentiation, cell contractility, inhibition of VSMC differentiation, and measured protein expression of transforming growth factor beta 1 (TGF-β1) and its associated peptides for hCSCs cultured on KOS hydrogels, tissue culture polystyrene, and collagen hydrogels. A review of VSMC differentiation signaling pathways informed our decision to investigate the role of TGF-β1 in VSMC differentiation. Results demonstrated that KOS hydrogel differentiated hCSCs significantly increased expression for all three vascular smooth muscle (VSM) markers compared to TCPS differentiated cells. Additionally, KOS differentiated hCSCs were significantly more contractile than cells differentiated on TCPS. Recombinant human (rh) TGF-β1 was able to induce VSM differentiation on TCPS. VSM differentiation was successfully inhibited using TGF-β NABs and A83-01. Enzyme-Linked Immunosorbent Assay (ELISA) analysis revealed that both TCPS and KOS hydrogel differentiated cells produced TGF-β1, with higher levels being measured at early time points on TCPS and later time points on KOS hydrogels. Results from supplementing rhTGF-β1 to TCPS and KOS hydrogels revealed that KOS seems to interact with TGF-β to a greater extent than TCPS. Western blot results revealed that latency TGFβ binding protein (LTBP-1) and latency associated peptide (LAP) had elevated levels early during differentiation. Further, the levels of LTBP-1 and LAP were higher on KOS differentiated hCSCs than TCPS hCSCs. This study reaffirms previous results of a VSM phenotype observed on KOS hydrogels, and provides convincing evidence for TGF-β1 inducing VSM differentiation on KOS hydrogels. Additionally, results from ELISA and western blot provide evidence that KOS plays a direct role in this pathway via interactions with TGF-β]1 and its associated proteins LTBP-1 and LAP. Results from chapter 2 and 3 offered significant evidence that our cells exhibited a VSMC phenotype, and that TGF-β1 signaling was a key contributor for the observed phenotype, but we still needed an animal model to explore the therapeutic potential of our putative VSMCs.
Research in Chapter 4 investigated a disease model to test the ability of KOS hydrogel differentiated cells to regenerate vascular tissue. To measure vascular regenerative capability, we selected a murine model of critical limb ischemia (CLI). CLI was induced in 3 groups (n=15/group) of adult mixed gender NSG mice by excising the femoral artery and vein, and then treated the mice with either PBS (termed as PBS-treated), Cells differentiated on TCPS (termed as Cells from TCPS), or KOS hydrogel-derived VSMCs (termed as Cells from KOS). Blood perfusion of the hind limbs was measured immediately before and after surgery, then 14, and 28 days after surgery using Laser Doppler analysis. Tissue vascularization, cell engraftment, and skeletal muscle regeneration were measured using immunohistochemistry, 1,1'-Dioctadecyl3,3,3',3'-Tetramethylindocarbocyanine Perchlorate (DiL) vessel painting, and hematoxylin and eosin (HandE) pathohistological staining. During the 4-week period, both cell treatment groups showed significant increases in blood perfusion compared to the PBS-treated control, and at day 28 the Cells from KOS group had significantly better blood flow than the Cells from TCPS group. Additionally, the Cells from KOS group demonstrated a significant increase in the ratio of DiL positive vessels, capillary density, and a greater density of small diameter arterioles compared to the PBS-treated group. Further, both cell-treated groups had similar levels of engraftment into the host tissue. We conclude that Cells from KOS therapy increases blood perfusion in an NSG model of CLI, but does not lead to increased cell engraftment compared to other cell based therapies.
Overall, the results from this dissertation demonstrated that KOS hydrogels produce VSMC differentiation from c-kit+ hCSCs mediated by TGF-β1 signaling, and that the differentiated cells are able to increase blood perfusion in a CLI model by increasing capillary density, suggesting enhanced angiogenesis. Future studies should explore potential protein-protein interactions between KOS, TGF-β1 and its associated proteins. Additionally, we should plan animal studies that examine the efficacy of our cells to regenerate cardiac tissue following an acute myocardial infarction (AMI). === PHD |
author2 |
Biomedical and Veterinary Sciences |
author_facet |
Biomedical and Veterinary Sciences Ledford, Benjamin |
author |
Ledford, Benjamin |
author_sort |
Ledford, Benjamin |
title |
Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential |
title_short |
Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential |
title_full |
Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential |
title_fullStr |
Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential |
title_full_unstemmed |
Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential |
title_sort |
keratose hydrogels promote vascular smooth muscle differentiation from c-kit+ human cardiac stem cells: underlying mechanism and therapeutic potential |
publisher |
Virginia Tech |
publishDate |
2019 |
url |
http://hdl.handle.net/10919/93593 |
work_keys_str_mv |
AT ledfordbenjamin keratosehydrogelspromotevascularsmoothmuscledifferentiationfromckithumancardiacstemcellsunderlyingmechanismandtherapeuticpotential |
_version_ |
1719461361552982016 |
spelling |
ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-935932021-08-21T05:30:43Z Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential Ledford, Benjamin Biomedical and Veterinary Sciences He, Jia-Qiang Van Dyke, Mark Huckle, William R. Gourdie, Robert G. Keratin/Keratose Biomaterials Human c-kit+ cardiac stem cells Differentiation Vascular smooth muscle cells Hind limb ischemic mouse model Laser Doppler Imaging Blood flow Cardiovascular diseases Cardiovascular disease is the leading cause of death in the United States, and coronary artery disease (CAD) kills over 370,000 people annually. There are available therapies that offer a temporary solution; however, only a heart transplant can fully resolve heart failure, and donor organ shortages severely limit this therapy. C-kit+ human cardiac stem cells (hCSCs) offers a viable alternative therapy to treat cardiovascular disease by replacing damaged cardiac tissue; however, low cell viability, low retention/engraftment, and uncontrollable in vivo differentiation after transplantation has limited the efficacy of stem cell therapy. Tissue engineering solutions offer potential tools to overcome current limitations of stem cell therapy. Materials derived from natural sources such as keratin from human hair offers innate cellular compatibility, bioactivity, and low immunogenicity. Keratin proteins extracted using oxidative chemistry known as keratose (KOS) have shown therapeutic potential in a wide range of applications including cardiac regeneration. My studies utilize KOS hydrogels to modulate c-kit+ hCSC differentiation, and explore the capability of differentiated cells to regenerate vascular tissue. In the first Chapter, we reviewed literature relevant to keratin-based biomaterials and their biomedical applications, the use of stem cells in cardiovascular research, and the differentiation of vascular smooth muscle cells (VSMCs). The section on biomedical applications of keratin biomaterials focuses on the oxidized form of keratin known as keratose (KOS), because this was the material used for our research. Since we planned to use this material in conjunction with c-kit+ hCSCs, we also briefly explored the use of stem cells in cardiovascular research. Additionally, we examined some key signaling pathways, developmental origins, and the cell phenotype of VSMCs for reasons that will become clear after observing results from chapters 2 and 3. Based upon our review of the literature, KOS biomaterials and c-kit+ hCSCs were determined to be promising as a combined therapeutic for the regeneration of cardiac tissue. Research in Chapter 2 focused on characterizing the effects of KOS hydrogel on c-kit+ hCSC cell viability, proliferation, morphology, and differentiation. Results demonstrated that KOS hydrogels could maintain hCSC viability without any observable toxic effects, but it modulated cell size, proliferation, and differentiation compared to standard tissue culture polystyrene cell culture (TCPS). KOS hydrogel produced gene and protein expression consistent with a VSMC phenotype. Further, we also observed novel "endothelial cell tube-like" microstructures formed by differentiated VSMCs only on KOS hydrogel, suggesting a potential capability of the hCSC-derived VSMCs for in vitro angiogenesis. Results from this study lead us to question what signaling pathways might be responsible for the apparent VSMC differentiation pattern we observed on KOS hydrogels. Research in Chapter 3 explored the time course of VSMC differentiation, cell contractility, inhibition of VSMC differentiation, and measured protein expression of transforming growth factor beta 1 (TGF-β1) and its associated peptides for hCSCs cultured on KOS hydrogels, tissue culture polystyrene, and collagen hydrogels. A review of VSMC differentiation signaling pathways informed our decision to investigate the role of TGF-β1 in VSMC differentiation. Results demonstrated that KOS hydrogel differentiated hCSCs significantly increased expression for all three vascular smooth muscle (VSM) markers compared to TCPS differentiated cells. Additionally, KOS differentiated hCSCs were significantly more contractile than cells differentiated on TCPS. Recombinant human (rh) TGF-β1 was able to induce VSM differentiation on TCPS. VSM differentiation was successfully inhibited using TGF-β NABs and A83-01. Enzyme-Linked Immunosorbent Assay (ELISA) analysis revealed that both TCPS and KOS hydrogel differentiated cells produced TGF-β1, with higher levels being measured at early time points on TCPS and later time points on KOS hydrogels. Results from supplementing rhTGF-β1 to TCPS and KOS hydrogels revealed that KOS seems to interact with TGF-β to a greater extent than TCPS. Western blot results revealed that latency TGFβ binding protein (LTBP-1) and latency associated peptide (LAP) had elevated levels early during differentiation. Further, the levels of LTBP-1 and LAP were higher on KOS differentiated hCSCs than TCPS hCSCs. This study reaffirms previous results of a VSM phenotype observed on KOS hydrogels, and provides convincing evidence for TGF-β1 inducing VSM differentiation on KOS hydrogels. Additionally, results from ELISA and western blot provide evidence that KOS plays a direct role in this pathway via interactions with TGF-β]1 and its associated proteins LTBP-1 and LAP. Results from chapter 2 and 3 offered significant evidence that our cells exhibited a VSMC phenotype, and that TGF-β1 signaling was a key contributor for the observed phenotype, but we still needed an animal model to explore the therapeutic potential of our putative VSMCs. Research in Chapter 4 investigated a disease model to test the ability of KOS hydrogel differentiated cells to regenerate vascular tissue. To measure vascular regenerative capability, we selected a murine model of critical limb ischemia (CLI). CLI was induced in 3 groups (n=15/group) of adult mixed gender NSG mice by excising the femoral artery and vein, and then treated the mice with either PBS (termed as PBS-treated), Cells differentiated on TCPS (termed as Cells from TCPS), or KOS hydrogel-derived VSMCs (termed as Cells from KOS). Blood perfusion of the hind limbs was measured immediately before and after surgery, then 14, and 28 days after surgery using Laser Doppler analysis. Tissue vascularization, cell engraftment, and skeletal muscle regeneration were measured using immunohistochemistry, 1,1'-Dioctadecyl3,3,3',3'-Tetramethylindocarbocyanine Perchlorate (DiL) vessel painting, and hematoxylin and eosin (HandE) pathohistological staining. During the 4-week period, both cell treatment groups showed significant increases in blood perfusion compared to the PBS-treated control, and at day 28 the Cells from KOS group had significantly better blood flow than the Cells from TCPS group. Additionally, the Cells from KOS group demonstrated a significant increase in the ratio of DiL positive vessels, capillary density, and a greater density of small diameter arterioles compared to the PBS-treated group. Further, both cell-treated groups had similar levels of engraftment into the host tissue. We conclude that Cells from KOS therapy increases blood perfusion in an NSG model of CLI, but does not lead to increased cell engraftment compared to other cell based therapies. Overall, the results from this dissertation demonstrated that KOS hydrogels produce VSMC differentiation from c-kit+ hCSCs mediated by TGF-β1 signaling, and that the differentiated cells are able to increase blood perfusion in a CLI model by increasing capillary density, suggesting enhanced angiogenesis. Future studies should explore potential protein-protein interactions between KOS, TGF-β1 and its associated proteins. Additionally, we should plan animal studies that examine the efficacy of our cells to regenerate cardiac tissue following an acute myocardial infarction (AMI). PHD 2019-09-15T06:00:36Z 2019-09-15T06:00:36Z 2018-03-23 Dissertation vt_gsexam:14364 http://hdl.handle.net/10919/93593 In Copyright http://rightsstatements.org/vocab/InC/1.0/ ETD application/pdf application/pdf Virginia Tech |