Mani T. Valarmathi

Regulation of Osteogenic Differentiation of Rat Bone Marrow Stromal Cells on 2D Nanorod Substrates

Bone marrow stromal cells (BMSCs) possess multi-lineage differentiation potential and can be induced to undergo differentiation into various cell types with the correct combination of chemical and environmental factors. Although, they have shown great prospects in therapeutic and medical applications, less is known about their behavior on nanosurfaces mimicking the extra cellular matrix (ECM). In this report we have employed 2D substrates coated with tobacco mosaic virus (TMV) nanorods to study the differentiation process of BMSCs into osteoblast like cells. TMV is a rod-shaped plant virus with an average length of 300 nm and diameter of 18 nm. The osteogenic differentiation of BMSCs on TMV was studied over time points of 7, 14 and 21 days. We examined the temporal gene expression changes during these time points by real-time quantitative PCR (RT-qPCR) analysis. As expected, osteo-specific genes (osteocalcin, osteopontin and osteonectin) were upregulated and showed a maximum change in expression on TMV at 14 days which was 7 days earlier than on tissue culture plastic (TCP). Based on the genes expression profile generated by RT-qPCR experiments, we proposed that the early interaction of cells with TMV triggers on signaling pathways which regulate speedy expression of osteocalcin in turn, resulting in early mineralization of the cells. To further investigate these regulating factors we studied global changes in gene expression (DNA microarray analyses) during osteogenic differentiation on the nanosubstrate. Multitudes of genes were affected by culturing cells on nanorod substrate, which corroborated our initial PCR findings. Microarray analysis further revealed additional targets influenced by the presence of nanorods on the surface, of which, the expression of bone morphogenetic protein 2 (BMP2) was of particular interests. Further investigation into the temporal change of BMP2, revealed that it acts as a major promoter in signaling the early regulation of osteocalcin on TMV coated substrates.

A three-dimensional model of vasculogenesis

Postnatal bone marrow contains various subpopulations of resident and circulating stem cells (HSCs, BMSCs/MSCs) and progenitor cells (MAPCs, EPCs) that are capable of differentiating into one or more of the cellular components of the vascular bed in vitro as well as contribute to postnatal neo-vascularization in vivo. When rat BMSCs were seeded onto a three-dimensional (3-D) tubular scaffold engineered from topographically aligned type I collagen fibers and cultured either in vasculogenic or non-vasculogenic media for 7, 14, 21 or 28 days, the maturation and co-differentiation into endothelial and/or smooth muscle cell lineages were observed. Phenotypic induction of these substrate-grown cells was assayed at transcript level by real-time PCR and at protein level by confocal microscopy. In the present study, the observed upregulation of transcripts coding for vascular phenotypic markers is reminiscent of an in vivo expression pattern. Immunolocalization of vasculogenic lineage-associated markers revealed typical expression patterns of vascular endothelial and smooth muscle cells. These endothelial cells exhibited high metabolism of acetylated low-density lipoprotein. In addition to the induced monolayers of endothelial cells, the presence of numerous microvascular capillary-like structures was observed throughout the construct. At the level of scanning electron microscopy, smooth-walled cylindrical tube-like structures with smooth muscle cells and/or pericytes attached to its surface were elucidated. Our 3-D culture system not only induces the maturation and differentiation of BMSCs into vascular cell lineages but also supports microvessel morphogenesis. Thus, this unique in vitro model provides an excellent platform to study the temporal and spatial regulation of postnatal de novo vasculogenesis, as well as attack the lingering limit in developing engineered tissues, that is perfusion.

The promotion of osteoblastic differentiation of rat bone marrow stromal cells by a polyvalent plant mosaic virus

To investigate the role that the micro/nano-environment plays on the differentiation pathway of bone marrow stromal cells (BMSCs) into osteoblasts, we employed a 2D substrate coated with turnip yellow mosaic virus (TYMV) particles. TYMV is a non-enveloped icosahedral plant virus which has an average diameter 28 nm and the protein cage structure consists of 180 identical subunits. The temporal effect of TYMV coated substrate on the adhesion and differentiation capacity of the BMSCs was monitored for selected time periods of 7, 14 and 21 days. We examined the gene expression profile of BMSCs cultured in primary media (undifferentiated cells) and cells induced to osteoblast lineage by real time PCR analysis. To further corroborate our findings, we investigated the expression of osteogenic markers using immunohistochemistry and cytochemical staining. As expected, the genes involved in the process of osteogenic differentiation were activated more during the growth of cells under osteogenic media. In addition, we found that the BMSCs induced to undergo osteogenic differentiation on TYMV coated substrates formed fully mineralized nodules comprising of osteoblast-like cells around day 14. Comparing the gene expression pattern of BMSCs induced to osteogenic differentiation under standard culture conditions with the cells induced on TYMV substrates, we found significant differences in the temporal expression and level of expression of several key genes. Our findings indicate that TYMV, as a biogenic nanoparticle, can be employed as a model to modulate the nano-environment of the substrates in order to gain an insight into the role that the micro/nano-environment has in regulating adhesion, growth and differentiation of BMSCs towards osteogenic lineage, which will be vital for designing compatible biomaterials for tissue engineering purposes.

A three-dimensional tubular scaffold that modulates the osteogenic and vasculogenic differentiation of rat bone marrow stromal cells.

Bone marrow stromal cells (BMSCs) or mesenchymal stem cells (MSCs) are a heterogeneous population of cells that are multipotent. When rat BMSCs were seeded onto a 3-dimensional (3-D) tubular scaffold engineered from aligned type I collagen strands and cultured in osteogenic medium, they simultaneously matured and differentiated into osteoblastic and vascular cell lineages. In addition, these osteoblasts produced mineralized matricellular deposits. BMSCs were seeded at a density of 2 x 10(6) cells/15 mm tube and cultured in basal or osteogenic medium for 3, 6, and 9 days. These cells were subsequently processed for real-time reverse-transcriptase polymerase chain reaction (RT-qPCR), immunohistochemical, cytochemical, and biochemical analyses. Immunolocalization of lineage-specific proteins was visualized using confocal microscopy. In the present study, the expression pattern of key osteogenic markers significantly differed in response to basal and osteogenic media. Alkaline phosphatase activity and calcium content increased significantly over the observed period of time in osteogenic medium. The observed up-regulation of transcripts coding for osteoblastic phenotypic markers is reminiscent of in vivo expression patterns. Abundant sheets of Pecam (CD31) -, Flk-1 (vascular endothelial growth factor receptor-2) -, CD34-, tomato lectin-, and alpha-smooth muscle actin-positive cells were observed in these tube cultures. Moreover, nascent capillary-like vessels were also seen amid the osteoblasts in osteogenic cultures. Our 3-D culture system augmented the maturation and differentiation of BMSCs into osteoblasts. Thus, our in vitro model provides an excellent opportunity to study the concurrent temporal and spatial regulation of osteogenesis and vasculogenesis during bone development.

A 3-D cardiac muscle construct for exploring adult marrow stem cell based myocardial regeneration.

Adult bone marrow stromal cells (BMSCs) are capable of differentiating into cardiomyocyte-like cells in vitro and contribute to myocardial regeneration in vivo. Consequently, BMSCs may potentially play a vital role in cardiac repair and regeneration. However, this concept has been limited by inadequate and inconsistent differentiation of BMSCs into cardiomyocytes along with poor survival and integration of neo-cardiomyocytes after implantation into ischemic myocardium. In order to overcome these barriers and to explore adult stem cell based myocardial regeneration, we have developed an in vitro model of three-dimensional (3-D) cardiac muscle using rat ventricular embryonic cardiomyocytes (ECMs) and BMSCs. When ECMs and BMSCs were seeded sequentially onto a 3-D tubular scaffold engineered from topographically aligned type I collagen-fibers and cultured in basal medium for 7, 14, 21, or 28 days, the maturation and co-differentiation into a cardiomyocyte lineage was observed. Phenotypic induction was characterized at morphological, immunological, biochemical and molecular levels. The observed expression of transcripts coding for cardiomyocyte phenotypic markers and the immunolocalization of cardiomyogenic lineage-associated proteins revealed typical expression patterns of neo-cardiomyogenesis. At the biochemical level differentiating cells exhibited appropriate metabolic activity and at the ultrastructural level myofibrillar and sarcomeric organization were indicative of an immature phenotype. Our 3-D co-culture system sustains the ECMs in vitro continuum of differentiation process and simultaneously induces the maturation and differentiation of BMSCs into cardiomyocyte-like cells. Thus, this novel 3-D co-culture system provides a useful in vitro model to investigate the functional role and interplay of developing ECMs and BMSCs during cardiomyogenic differentiation.

The influence of proepicardial cells on the osteogenic potential of marrow stromal cells in a three-dimensional tubular scaffold

It is well established that the process of neovascularization or neoangiogenesis is coupled to the development and maturation of bone. Bone marrow stromal cells (BMSCs) or mesenchymal stem cells (MSCs) comprise a heterogeneous population of cells that can be differentiated in vitro into both mesenchymal and non-mesenchymal cell lineages. When both rat BMSCs and quail proepicardia (PEs) were seeded onto a three-dimensional (3-D) tubular scaffold engineered from aligned collagen type I strands and co-cultured in osteogenic media, the maturation and co-differentiation into osteoblastic and vascular cell lineages were observed. In addition, these cells produced abundant mineralized extracellular matrix materials and vessel-like structures. BMSCs were seeded at a density of 2 x 10(6)cells/15 mm tube and cultured in basal media for 3 days. Subsequently, on day 3, PEs were seeded onto the same tubes and the co-culture was continued for another 3, 6 or 9 days either in basal or in osteogenic media. Differentiated cells were subjected to immunohistochemical, cytochemical and biochemical analyses. Phenotypic induction was analyzed at mRNA level by reverse transcriptase quantitative polymerase chain reaction (RT-qPCR). Immunolocalization of key osteogenic and vasculogenic lineage specific markers were examined using confocal scanning laser microscopy. In osteogenic tube cultures, both early and late osteogenic markers were observed and were reminiscent of in vivo expression pattern. Alkaline phosphatase activity and calcium content significantly increased over the observed period of time in osteogenic medium. Abundant interlacing fascicles of QCPN, QH1, isolectin and alpha-smooth muscle actin (alpha-SMA) positive cells were observed in these tube cultures. These cells formed extensive arborizations of nascent capillary-like structures and were seen amidst the developing osteoblasts in osteogenic cultures. The 3-D culture system not only generated de novo vessel-like structures but also augmented the maturation and differentiation of BMSCs into osteoblasts. Thus, this novel co-culture system provides a useful in vitro model to investigate the functional role and effects of neovascularization in the proliferation, differentiation and maturation of BMSC derived osteoblasts.

The mechanical coupling of adult marrow stromal stem cells during cardiac regeneration assessed in a 2-D co-culture model

Postnatal cardiomyocytes undergo terminal differentiation and a restricted number of human cardiomyocytes retain the ability to divide and regenerate in response to ischemic injury. However, whether these neo-cardiomyocytes are derived from endogenous population of resident cardiac stem cells or from the exogenous double assurance population of resident bone marrow-derived stem cells that populate the damaged myocardium is unresolved and under intense investigation. The vital challenge is to ameliorate and/or regenerate the damaged myocardium. This can be achieved by stimulating proliferation of native quiescent cardiomyocytes and/or cardiac stem cell, or by recruiting exogenous autologous or allogeneic cells such as fetal or embryonic cardiomyocyte progenitors or bone marrow-derived stromal stem cells. The prerequisites are that these neo-cardiomyocytes must have the ability to integrate well within the native myocardium and must exhibit functional synchronization. Adult bone marrow stromal cells (BMSCs) have been shown to differentiate into cardiomyocyte-like cells both in vitro and in vivo. As a result, BMSCs may potentially play an essential role in cardiac repair and regeneration, but this concept requires further validation. In this report, we have provided compelling evidence that functioning cardiac tissue can be generated by the interaction of multipotent BMSCs with embryonic cardiac myocytes (ECMs) in two-dimensional (2-D) co-cultures. The differentiating BMSCs were induced to undergo cardiomyogenic differentiation pathway and were able to express unequivocal electromechanical coupling and functional synchronization with ECMs. Our 2-D co-culture system provides a useful in vitro model to elucidate various molecular mechanisms underpinning the integration and orderly maturation and differentiation of BMSCs into neo-cardiomyocytes during myocardial repair and regeneration.

A Novel Human Tissue-Engineered 3-D Functional Vascularized Cardiac Muscle Construct

Organ tissue engineering, including cardiovascular tissues, has been an area of intense investigation. The major challenge to these approaches has been the inability to vascularize and perfuse the in vitro engineered tissue constructs. Attempts to provide oxygen and nutrients to the cells contained in the biomaterial constructs have had varying degrees of success. The aim of this current study is to develop a three-dimensional (3-D) model of vascularized cardiac tissue to examine the concurrent temporal and spatial regulation of cardiomyogenesis in the context of postnatal de novo vasculogenesis during stem cell cardiac regeneration. In order to achieve the above aim, we have developed an in vitro 3-D functional vascularized cardiac muscle construct using human induced pluripotent stem cell-derived embryonic cardiac myocytes (hiPSC-ECMs) and human mesenchymal stem cells (hMSCs). First, to generate the prevascularized scaffold, human cardiac microvascular endothelial cells (hCMVECs) and hMSCs were co-cultured onto a 3-D collagen cell carrier (CCC) for 7 days under vasculogenic culture conditions. In this milieu, hCMVECs/hMSCs underwent maturation, differentiation, and morphogenesis characteristic of microvessels, and formed extensive plexuses of vascular networks. Next, the hiPSC-ECMs and hMSCs were co-cultured onto this generated prevascularized CCCs for further 7 or 14 days in myogenic culture conditions. Finally, the vascular and cardiac phenotypic inductions were analyzed at the morphological, immunological, biochemical, molecular, and functional levels. Expression and functional analyses of the differentiated cells revealed neo-angiogenesis and neo-cardiomyogenesis. Thus, our unique 3-D co-culture system provided us the apt in vitro functional vascularized 3-D cardiac patch that can be utilized for cellular cardiomyoplasty.

Nitric Oxide Modulates Postnatal Bone Marrow-Derived Mesenchymal Stem Cell Migration.

Nitric oxide (NO) is a small free-radical gas molecule, which is highly diffusible and can activate a wide range of downstream effectors, with rapid and widespread cellular effects. NO is a versatile signaling mediator with a plethora of cellular functions. For example, NO has been shown to regulate actin, the microfilament, dependent cellular functions, and also acts as a putative stem cell differentiation-inducing agent. In this study, using a wound-healing model of cellular migration, we have explored the effect of exogenous NO on the kinetics of movement and morphological changes in postnatal bone marrow-derived mesenchymal stem cells (MSCs). Cellular migration kinetics and morphological changes of the migrating MSCs were measured in the presence of an NO donor (S-Nitroso-N-Acetyl-D,L-Penicillamine, SNAP), especially, to track the dynamics of single-cell responses. Two experimental conditions were assessed, in which SNAP (200 μM) was applied to the MSCs. In the first experimental group (SN-1), SNAP was applied immediately following wound formation, and migration kinetics were determined for 24 h. In the second experimental group (SN-2), MSCs were pretreated for 7 days with SNAP prior to wound formation and the determination of migration kinetics. The generated displacement curves were further analyzed by non-linear regression analysis. The migration displacement of the controls and NO treated MSCs (SN-1 and SN-2) was best described by a two parameter exponential functions expressing difference constant coefficients. Additionally, changes in the fractal dimension (D) of migrating MSCs were correlated with their displacement kinetics for all the three groups. Overall, these data suggest that NO may evidently function as a stop migration signal by disordering the cytoskeletal elements required for cell movement and proliferation of MSCs.

Functional Tissue-Engineering: A Prevascularized Cardiac Muscle Construct for Validating hMSCs Engraftment Potential in Vitro

The influence of somatic stem cells in the stimulation of mammalian cardiac muscle regeneration is still in its early stages, and so far, it has been difficult to determine the efficacy of the procedures that have been employed. The outstanding question remains whether stem cells derived from the bone marrow or some other location within or outside of the heart can populate a region of myocardial damage and transform into tissue-specific differentiated progenies, and also exhibit functional synchronization. Consequently, this necessitates the development of an appropriate in vitro three-dimensional (3D) model of cardiomyogenesis and prompts the development of a 3D cardiac muscle construct for tissue engineering purposes, especially using the somatic stem cell, human mesenchymal stem cells (hMSCs). To this end, we have created an in vitro 3D functional prevascularized cardiac muscle construct using embryonic cardiac myocytes (eCMs) and hMSCs. First, to generate the prevascularized scaffold, human cardiac microvascular endothelial cells (hCMVECs) and hMSCs were cocultured onto a 3D collagen cell carrier (CCC) for 7 days under vasculogenic culture conditions; hCMVECs/hMSCs underwent maturation, differentiation, and morphogenesis characteristic of microvessels, and formed dense vascular networks. Next, the eCMs and hMSCs were cocultured onto this generated prevascularized CCCs for further 7 or 14 days in myogenic culture conditions. Finally, the vascular and cardiac phenotypic inductions were characterized at the morphological, immunological, biochemical, molecular, and functional levels. Expression and functional analyses of the differentiated progenies revealed neo-cardiomyogenesis and neo-vasculogenesis. In this milieu, for instance, not only were hMSCs able to couple electromechanically with developing eCMs but were also able to contribute to the developing vasculature as mural cells, respectively. Hence, our unique 3D coculture system provides us a reproducible and quintessential in vitro 3D model of cardiomyogenesis and a functioning prevascularized 3D cardiac graft that can be utilized for personalized medicine.