Auxiliary Wnt3A Signaling in Cell Fate Decisions of C3H10T1/2 Mesenchymal Stem Cells

Rossol-Allison, Jessica K.

January 2011

<p>Activation of Wnt signaling pathways is critical to a variety of developmental events across all animal taxa. These highly evolutionarily conserved pathways are also important in the adult organism for maintaining homeostasis of self-renewing tissues. Because of its role in such important physiological processes, deregulation of Wnt signaling can have severe consequences; indeed, inappropriate activation of this pathway has been implicated in multiple human diseases, including cancer.</p><p>Upon binding their cellular receptors, canonical Wnt ligands, like Wnt 3A, stimulate the stabilization, accumulation, and nuclear translocation of a multifunctional cellular protein &#946;catenin, the consequence of which is induction of &#946;catenin-dependent transcription. This work describes the identification and characterization of two Wnt3A-stimulated intracellular signaling pathways activated in parallel to &#946;catenin stabilization: the RhoA pathway and the ERK pathway. These two auxiliary pathways do not affect &#946;catenin stability, accumulation, or subcellular localization; rather, they modulate &#946;catenin -dependent transcriptional activity through other mechanisms. As a result of their influence on &#946;catenin-dependent transcription, these pathways instruct cell fate decisions in C3H10T1/2 mesenchymal stem cells, in particular inhibition of adipogenesis and promotion of osteoblastogenesis.</p><p>Expression microarray analysis and biochemical and pharmacological techniques were used to further characterize the two Wnt3A-stimulated auxiliary pathways in C3H10T1/2 cells. Remarkably, each pathway influences &#946;catenin function via a novel mechanism. In the Wnt3A/RhoA pathway, Wnt3A-stimulated trimeric G proteins activate a RhoA-ROCK-SRF cascade. Activated SRF can cooperate with &#946;catenin to enhance the induction of Wnt3A target genes, like Ctgf, that also contain SRF binding sites within regulatory elements. In the Wnt3A/ERK pathway, Wnt3A transactivates the EGFR in a concentration-dependent manner, leading ultimately to ERK activation, which interacts with and promotes &#946;catenin/Tcf4 interaction and enhances induction of &#946;catenin/Tcf4 target genes. </p><p>These data emphasize the complexity of Wnt signaling and have intriguing implications regarding cross-regulation of the pathway, especially in stem cells. Also, since not all cells are capable of responding to Wnt3A by activation of these auxiliary pathways, this work identifies novel mechanisms that could underlie cell type-specific responses to Wnts and provides mechanistic insight into cellular responses to Wnt concentration gradients. Moreover, this work identifies novel transcriptional mechanisms important for promoting osteogenic cell fate specification, which could ultimately provide new therapeutic targets in disease states with bone loss or ineffective bone formation.</p> / Dissertation

Biochemistry

Molecular Biology

Auxiliary Pathway

Erk

Mesenchymal Stem Cell

RhoGTPase

ßcatenin

Wnt

Untersuchungen zur therapeutischen Anwendung mesenchymaler Stammzellen bei chronischen Lebererkrankungen am Beispiel der Nicht-alkoholischen Steatohepatitis

Winkler, Sandra

13 January 2015

Die Nicht-alkoholische Steatohepatitis (NASH), gehörig zu der Gruppe der chronischen Lebererkrankungen als eine schwere Form der Nicht-alkoholischen Fettleber-erkrankungen (NAFLD), nimmt in ihrer Prävalenz ständig zu. Gründe dafür sind u.a. eine gesteigerte Nahrungsaufnahme sowie Veränderungen der Nahrungszusammen-setzung. Es kommt zur Ausbildung einer Steatose, die sich unter Mitwirkung verschie-dener Einflussfaktoren zur Steatohepatitis weiterentwickeln kann, wobei die Pathoge-nese noch nicht genau verstanden ist. Die Nicht-alkoholische Steatohepatitis geht oft einher mit Insulinresistenz und starkem Übergewicht. Die Folgen für die Leber sind Funktionseinschränkungen und –verlust, hervorgerufen durch eine massive Akkumula-tion von Triglyzeriden in den Hepatozyten, Entzündungsprozesse sowie einem fibro-tischen Umbau der Leber. Im fortgeschritten Stadium wird eine Lebertransplantation unausweichlich, die jedoch aufgrund des zunehmenden Mangels an Spenderorganen oft nicht möglich ist. Eine Alternative bietet die Transplantation mesenchymaler Stammzellen (MSC). MSC können in vitro in leberzellähnliche Zellen differenziert wer-den und weisen dabei essentielle hepatozytäre Eigenschaften auf, wodurch sie als möglicher Ersatz bzw. als Überbrückungstherapie bis zur Lebertransplantation in Frage kommen. Die vorliegende Arbeit beschäftigte sich mit dieser Fragestellung. Dazu wur-de ein Tiermodell der NASH mittels Methionin-Cholin-defizienter Diät (MCD-Diät) etab-liert und die Transplantation von hepatozytär differenzierten MSC durchgeführt. An-hand spezifischer zellulärer und biochemischer Marker der NASH konnte die Wirkung des Zelltransplantats auf die Empfängerleber analysiert werden. Es hat sich gezeigt, dass die MSC einen anti-inflammatorischen, anti-fibrotischen und pro-proliferativen Einfluss auf das Empfängerparenchym hatten und somit zur Verbesserung der Symptomatik der NASH beitrugen.

mesenchymale Stammzellen (MSC)

Non-alcoholic steatohepatitis

mesenchymal stem cells (MSC)

ddc:610

The role of nanostructural and electrical surface properties on the osteogenic potential of titanium implants

Gittens Ibacache, Rolando Arturo

03 August 2012

Dental and orthopaedic implants are currently the solutions of choice for teeth and joint replacements with success rates continually improving, but they still have undesirable failure rates in patients who are compromised by disease or age, and who in many cases are the ones most in need. The success of titanium (Ti) implants depends on their ability to osseointegrate with the surrounding bone and this, in turn, is greatly dependent on the surface characteristics of the device. Advancements in surface analysis and surface modification techniques have improved the biological performance of metallic implants by mimicking the hierarchical structure of bone associated with regular bone remodeling. In this process, damaged bone is resorbed by osteoclasts, which produce resorption lacunae containing high microroughness generated after mineral dissolution under the ruffled border, as well as superimposed nanoscale features created by the collagen fibers left at the surface. Indeed, increasing Ti surface roughness at the micro and sub-microscale level has been shown to increase osteoblast differentiation in vitro, increase bone-to-implant contact in vivo, and accelerate healing times clinically. Recently, the clinical application of surface nanomodification of implants has been evaluated. Still, most clinically-available devices remain smooth at the nanoscale and fundamental questions remain to be elucidated about the effect of nanoroughness on the initial response of osteoblast lineage cells. Another property that could be used to control osteoblast development and the process of osseointegration is the electrical surface charge of implants. The presence of endogenous electrical signals in bone has been implicated in the processes of bone remodeling and repair. The existence of these native signals has prompted the use of external electrical stimulation to enhance bone growth in cases of fractures with delayed union or nonunion, with several in vitro and in vivo reports confirming its beneficial effects on bone formation. However, the use of electrical stimulation on Ti implants to enhance osseointegration is less understood, in part because of the lack of in vitro models that truly represent the in vivo environment. In addition, an aspect that has not been thoroughly examined is the electrical implication of implant corrosion and its effect on the surrounding tissue. Implants are exposed to extreme conditions in the body such as high pH during inflammation, and cyclic loads. These circumstances may lead to corrosion events that generate large electrochemical currents and potentials, and may cause abnormal cell and tissue responses that could be partly responsible for complications such as aseptic loosening of implants. Consequently, Ti implants with tailored surface characteristics such as nanotopography and electrical polarization, could promote bone healing and osseointegration to ensure successful outcomes for patients by mimicking the biological environment of bone without the use of systemic drugs. The objective of this thesis is to understand how surface nanostructural and electrical characteristics of Ti and Ti alloy surfaces may affect osteoblast lineage cell response in vitro for normal tissue regeneration and repair. Our central hypothesis is that combined micro/nanostructured surfaces, as well as direct stimulation of Ti surfaces with fixed direct current (DC) potentials, can enhance osteoblast differentiation.

Electrical stimulation

Mesenchymal stem cells

Osteoblast differentiation

Surface nanomodification

Bone

Titanium implants

Snail controls TGFB responsiveness and diferentiation of MS cells

Batlle Gómez, Raquel

19 December 2011

The Snail1 transcriptional repressor is a key factor responsible in triggering epithelial to mesenchymal transition. Although Snail1 is widely expressed in early development, it is limited in adult animals to a subset of mesenchymal cells where it has a largely unknown function. In this project we have demonstrated that Snail1 is required to maintain mesenchymal stem cells (MSCs). This effect is associated to the responsiveness to TGF-[beta]1 which showed a strong Snail1 dependence. Snail1-depletion in conditional knock-out adult animals caused a significant decrease in the number of bone marrow-derived MSCs. In culture, Snail1-deficient MSCs prematurely differentiated to osteoblasts or adipocytes and, in contrast to controls, were resistant to the TGF-[beta]1-induced differentiation block. TGF-[beta]1 was unable to up-regulate most of its targets in Snail1 KO MSCs, an effect that was related, but not limited, to defective PTEN repression and Akt activation. Correspondingly, an analysis of human sarcomas also showed enhanced expression of Snail1 in undifferentiated tumors, which was strongly associated with high expression of TGF-[beta] and poor outcome. These results not only demonstrate a new role for Snail1 in TGF-[beta] response and MSC maintenance but also suggest the involvement of MSCs in sarcoma generation. / El repressor transcripcional Snail1 ha estat descrit principalment com el responsable de la inducció de la transició epiteli mesènquima. Encara que Snail1 s’expressa durant les etapes més primerenques del desenvolupament embrionari, la seva expressió en adults es veu limitada en un conjunt de cèl•lules mesenquimals sense saber-se la seva funció. En aquest projecte hem demostrat que Snail1 es requereix per mantenir el fenotip més indiferenciat de les cèl•lules mare del mesènquima. Aquesta funció la fa en part, per la capacitat de resposta de la citoquina TGF-[beta] la qual mostra una força dependència amb Snail1. Quan s’elimina Snail1 en ratolins adults provoca una clara disminució en el nombre de cèl•lules mare de la medul•la òssia. Aquestes cèl•lules en cultiu presenten una clara diferenciació prematura a osteoblasts i adipòcits. Pel contrari, tractaments amb TGF-[beta]1 aturen la diferenciació. El TGF-[beta]1 es incapaç de incrementar moltes dianes en cèl•lules mare del mesènquima aïllades del ratolí deficient per snail1, aquest efecte en part es degut a la repressió de PTEN i l’activació de AKT. L’anàlisi de sarcomes humans ens ha mostrat una alta expressió de Snail1, el qual també es troba associada amb una alta expressió de TGF-[beta] i baixa supervivència. Aquests resultats no només demostren una nova funció per Snail1 en resposta a TGF-[beta] i el manteniment de les MSC, sinó que també suggereix que Snail1 podria participar en la generació del sarcoma.

Snail1

MSC- mesenchymal stem cell

Sarcoma

TGF-[beta]- transforming growth factor

AKT

Activated fibroblast

57

Biological therapies for the restoration of degenerated intervertebral discs

Wei, Ai-Qun, Clinical School - St George Hospital, Faculty of Medicine, UNSW

January 2008

Low back pain is a common cause of disability and work inability, often associated with intervertebral disc degeneration. The current understanding of disc degeneration is limited and none of the available treatments is entirely effective. The work described herein investigates potential strategies for the biological herapeutic restoration of disc degeneration. Firstly, an in vitro study to investigate the effects of BMP-7 on human discal cellular viability was performed. Cultured cells were treated with TNF-a or H202 to induce apoptosis, resulting in the down regulation of extracellular matrix proteins, decreased cell viability, morphological changes and activation of caspase-3; however, addition of BMP-7 alone prevented the observed effects, demonstrating the ability of BMP-7 to prevent apoptosis of human disc cells in vitro. Secondly, the differentiation potential of stem cells towards disc-like cells was studied. Rodent mesenchymal stem cells (rMSCs) were cultured alone or co-cultured with rat disc tissue. Differentiation potential of rMSCs was evaluated by mRNA and protein expression, cellular function and morphological studies. The co-culture conditions led to the expression of chondrocytic markers in rMSCs, whereas rMSCs cultured alone did not express the chondrocytic markers. Cellular contact between the co-cultured rMSCs and the discal tissue were observed. This study demonstrated that rMSCs can differentiate into functional disc-like cells in a tissue influenced co-culture environment. Finally, the survival and differentiation of CD34+ or CD34?? bone marrow (hBM) cells, in an intra-discal xenogeneic transplantation rat model was investigated. Human CD34+ or CD34?? cells were isolated, fluorescent-labelled and injected into rat coccygeal discs. The survival of transplanted cells was confirmed by fluorescent positive cells as well as a human nuclear specific marker. Interestingly, CD34?? cells survived until day 42 in the injected discs, and differentiated into cells ex:pressing a chondrocytic phenotype. In contrast, CD34+ cells could not be detected by day 21. This data suggests that transplanted hBM CD34?? cells, in contrast to CD34+ cells, were able to survive and differentiate within the intervertebral disc. Together, the results of these studies can both encourage and contribute to the basis of potential biological therapies in the restoration of intervertebral disc degeneration.

Human bone marrow (hBM) cells.

Disc degeneration.

Rodent mesenchymal stem cells (rMSCs)

Neurogenesis of adult stem cells from the liver and bone marrow

Deng, Jie,

January 2005

Thesis (Ph.D.)--University of Florida, 2005. / Typescript. Title from title page of source document. Document formatted into pages; contains 143 pages. Includes Vita. Includes bibliographical references.

GDF5 mediated enhancement of chondrocyte phenotype and its modulation by heparin and heparan sulfates

Ayerst, Bethanie Imogen

January 2017

Articular cartilage plays a vital role in load-bearing joints, providing an almost frictionless surface to articulating bones. However, the avascular nature and low cell density of the tissue means that following injury, there is limited potential for regeneration and repair. With the ageing population, the prevalence and economic burden associated with osteoarthritis (OA) is increasing rapidly, but as of yet there are no fully effective ways to treat the condition. Research into novel therapies has therefore become a popular avenue of investigation, and human mesenchymal stem/stromal cells (hMSCs) have been highlighted as particularly promising targets. However, current, methods for inducing the chondrogenic differentiation of hMSCs, which typically employ the use of transforming growth factor beta 1 or 3 (TGFβ1/3), result in the production of hypertrophic rather than hyaline tissue, hampering translational progress. Growth differentiation factor 5 (GDF5) belongs to the TGFβ superfamily of proteins and is vital for skeletal formation, however its use in cartilage tissue engineering (TE) strategies has been somewhat neglected. Here we demonstrate that GDF5 significantly increases aggrecan gene expression (a marker of articular cartilage), without affecting collagen type X expression (a marker of chondrocyte hypertrophy), in chondrocyte pellet cultures derived from hMSCs, making it a promising target for the formation of permanent articular cartilage. The therapeutic application of growth factors is, at present, limited due to their expense, susceptibility to proteolytic degradation, and rapid clearance, leading to large quantities being required to get anywhere near the desired outcome. The highly sulfated glycosaminoglycan (GAG), heparin, is already extensively used in the clinic as an anticoagulant, and is also able to bind and potentiate the activity of a wide range of growth factors. As such, researchers are now using it to enhance stem cell expansion/ differentiation protocols, as well as to improve the delivery/ activity of growth factors in TE strategies. Here, we identify GDF5 as a novel heparin/heparan sulfate (HS)-binding protein, and show that endogenous HS proteoglycans (HSPGs) are vital for localizing GDF5 to the cell surface, but are not required for its signalling activity. Importantly, we report that clinically relevant doses of heparin (≥ 10 nM), but not equivalent concentrations of HS, inhibit GDF5’s biological activity, in both hMSC-derived chondrocyte pellet cultures, and in the skeletal cell line ATDC5. We demonstrate that these inhibitory effects are due to heparin (but not HS) inhibiting both GDF5 binding to endogenous HSPGs and GDF5-induced induction of Smad 1/5/8 signalling. This study may therefore explain the variable (and disappointing) results seen with heparin-loaded biomaterials for skeletal TE, and the adverse skeletal effects, such as osteoporosis, that have been reported in the clinic following long-term heparin treatment. Together, our results caution the use of heparin in the clinic and in TE applications, and prompt the transition to using more specific GAGs (e.g. HS derivatives or synthetics), with better-defined structures and fewer off-target effects, if optimal therapy is to be achieved. In the case of GDF5, we have used a variety of developed techniques to begin uncovering important structural and functional information regarding the HS-GDF5 interaction, which are hoped to ultimately pave the way towards achieving this aim. Although further analysis is necessary, our data indicate that relatively long HS sequences are required for binding, and that both ionic and non-ionic interactions play a role in the interaction. In addition we suggest that low- rather than high-affinity HS variants may be key to potentiating the activity of this growth factor.

615.7

Development and utility of magnetic nanoparticles production by mammalian cells

Lungaro, Lisa

January 2018

Magnetic hyperthermia (MH) is an anti-cancer treatment which exploits the heat produced by tumour-targeted magnetic nanoparticles (MNPs) subjected to an alternating magnetic field (AMF). A problem limiting the clinical use of MH, however, is the inability to adequately localise the MNPs at the tumour site. A cellular approach using mesenchymal stem cells (MSCs) as carriers has been proposed as these cells are believed to home to sites of tissue injury and tumour growth, however problems with MNPs uptake and toxicity retard progress and need to be overcome. The aim of this project was to find an alternative approach in MH treatment, creating engineered human MSCs able to biosynthesise MNPs. To achieve this goal, MSCs were transfected with either, or both, M. magneticum AMB-1 mms6 and mmsF genes. M. magneticum AMB-1 is a genus of magnetotactic bacteria, containing magnetosomes, which are lipidic organelles containing single crystals of magnetite. M. magneticum-AMB1 mms6 and mmsF genes are important for final crystal morphology and are known to play a role in crystal synthesis and growth respectively. The originality of this study was in using mms6 and mmsF genes, which were codon-optimized for mammalian expression, alone or in combination, for transfection of human MSCs, which have known tumour homing capacity. The transfected MNPs-bearing MSCs, able to migrate into the tumour tissue, were subjected to AMF in MH experiments in an attempt to induce cancer cell death. mms6 and mmsF gene expression, following transfection, was investigated in the human osteosarcoma cell line MG63 by reverse transcription polymerase chain reaction (RT-PCR). The cellular ultrastructure of transfected MG63 cells was investigated by transmission electron microscopy (TEM), revealing the presence of nanoparticles. The magnetism of transfected MG63 cells was proved by superconducting quantum interference device (SQUID) and supported by in vitro MH experiments. Then, human MSCs were transfected with mms6 and mmsF genes, alone or in combination. The effect of transfection experiments and MNPs synthesis on MSCs markers of stemness, cell proliferation and differentiation ability were investigated. The MTB genes expression in human MSCs was assessed by RT-PCR and cell magnetism was confirmed by SQUID, in vitro MH experiments and by magnetic force microscopy (MFM). Then, in vitro studies of MH were undertaken to establish whether mms6 transfected MSCs expressing MNPs supported a MH effect when exposed to an AMF. Cells were initially exposed to an AMF of 565.3 kHz frequency in monolayers and in 3D arrangements and cell death/viability was assessed. Subsequently, the effect of the same AMF on 3D models of mixed populations of mms6-expressing MSCs and cancer cells was assessed. The results indicate that viability of MNPs-expressing MSCs and adjacent cancer cells is reduced following AMF exposure. In vivo studies of MH were undertaken following intracardiac injection of mms6-expressing MSCs in tumour-bearing mice (epidermoid carcinoma). The expression of mms6-expressing MSCs inside mice organs was confirmed by RT-PCR, fluorescence microscopy and immunohistochemistry. The effect of the application of an AMF of 565.3 kHz on mice tumours was studied with different techniques (tumour size and volume measurement, multiphoton microscopy, haematoxylin and eosin staining, and activated Caspase 3 expression), to understand if MNPs created inside mms6- expressing MSCs, following AMF exposure, could lead to cancer cell death. Results indicate that mice tolerate the treatment well, however no appreciable tumour reduction or necrosis was evident. Overall the results suggest that mms6 transfection alone confers the highest magnetisation to MSCs compared to mmsF alone or mms6+mmsF co-transfected, and that mms6 expression in human MSCs does not have an adverse effect on important cell functions. mms6-expressing MSCs, when exposed to an AMF, show reduced viability and enhanced cell cytotoxicity in vitro. When co-cultured with cancer cells in 3D models in vitro, mms6-expressing MSCs are able to reduce viability of adjacent cancer cells confirming the potential applicability of mms6- expressing MSCs for MH treatment. In vivo proof of concept experiments show that mms6-expressing MSCs can locate to the tumour tissue, and mms6-expressing intracardiac injected MSCs mice exposed to AMF tolerate the treatment well. However, the number of mms6-expressing MSCs able to localize to the tumour tissue in this experiment was too low to give an appreciable tumour reduction, so more experiments are needed to enhance the experimental protocol. A number of improvements are required to progress this novel technique towards clinical application. Gene transfection and MNPs production need to be optimised, the best frequency for MH needs to be established and MSCs delivery to the tumour has to be significantly increased to allow concentration of MNPs. The study has helped to increase our knowledge on the creation of magnetic human MSCs to potentially use these cells in MH cancer treatment.

Design and development of anisotropic laminate scaffolds of electrospun polycaprolactone for annulus fibrosus tissue engineering applications

Fotticchia, Andrea

January 2016

In several cases, current therapies available to treat a large number of musculoskeletal system diseases are unsatisfactory as they provide only temporary or partial restoration of the damaged or degenerated site. In an attempt to maintain a high standard of life quality and minimise the economic losses due to the treatments of these frequently occurring ailments and subsequent lost working days, alternative therapies are being explored. Contrary to the current treatments, tissue engineering aims to regenerate the impaired tissue rather than repair and alleviate the symptoms; thus offering a definitive solution. The annulus fibrosus (AF) of the intervertebral disc (IVD) is a musculoskeletal system component frequently subjected to degeneration and rupture, characterised by predominance of anisotropically arranged collagen fibres. In the present thesis, electrospinning technology is used to fabricate polycaprolactone (PCL) scaffolds intended to replicate the anisotropic structure of the AF.

New culture systems for mesenchymal stem cells

Duffy, Cairnan Robert Emmett

January 2015

Mesenchymal stem cells are the stem cells that replace the bone, fat and cartilage tissues of the human body. In addition, these cells can form muscles, ligaments and neurons. This wide multipotency has made mesenchymal stem cells of particular interest in the fields of tissue engineering and regenerative medicine. Furthermore, mesenchymal stem cells can modulate the immune system by reducing factors that increase inflammation and immune recognition. This immune recognition suppression has resulted in their application as part of bone marrow transplantation in the prevention of 'graft versus host‘ disease. There are hundreds of on-going clinical trials using these cells for the treatment of autoimmune diseases such as type I diabetes, arthritis and multiple sclerosis. The increasing importance of these cells has brought in to focus the culture methods used to for their expansion and manipulation. Currently, animal derived components are used as surfaces for their growth and as components in the culture media. This exposes these cells to animal pathogens and antigens that can be passed to the recipients of these cells. In the first part of this thesis, polymer microarrays were employed to identify alternatives to the biological surfaces currently used for mesenchymal stem cell culture. This platform allowed hundreds of polyacrylates/acrylamides and polyurethanes to be simultaneously scrutinised to identify surfaces that could support their growth and maintain their stem cell characteristics. Identified polymer surfaces were monitored in long-term culture (10 passages) and were shown to retain the cell phenotype and capacity to differentiate, thus providing chemically defined substrates for long-term mesenchymal stem cell culture. In the second part of this thesis, a 'smart‘ polymer microarray of hydrophilic cross-linked polymers (hydrogels) were used to remove another key biological component of culture, trypsin. These 'smart‘ hydrogels modulated their properties depending on the temperature. Hydrogels that could trigger mesenchymal stem cell release after a reduction in temperature were identified. A unique passaging system using a modest temperature reduction for 1h was developed as a passaging method. Cells were maintained and monitored for 10 passages using this novel enzyme free passaging method. Analysis of the mesenchymal stem cell phenotype and differentiation capacity revealed this method superior than conventional culturing methods. In the final part of this thesis, a 'knowledge-based‘ small molecule library was designed, which could potentially yield small molecules to manipulate/enhance the mesenchymal stem cell state without the use of biological components. The key protein pathways that control the stem cell state were examine with the bioinformatics tool GeneGo was used to identify compounds that affected these pathways, resulting in selection of 200 small molecules. The effect of the small molecules on the mesenchymal phenotype was examined and 5 small molecules were identified that enhanced the phenotype of these cells. The anti-inflammatory properties associated with the hit compounds led to the investigation of their effects on key surface proteins associated with the immune-modulatory state of the cells. In this preliminary study, two of the small molecules, estriol and spermine, increased the expression of a key mesenchymal stem cell marker STRO-1 and down regulated ICAM-1, a critical component of the immune modulation capacity of this cell type.

616.02