The Chondrogenesis of PDLs by Dynamic Unconfined Compression Is Dependent on p42/44 and Not p38 or JNK

Fritz, Jason Ronald

01 January 2009

Articular cartilage lines the surfaces of load bearing joints and has limited capabilities for self-repair due to its alymphatic and avascular structure. Attempts at making repairs to this tissue has resulted in substandard materials and/or causing further injury to the patient making this tissue a prime candidate for tissue engineering studies incorporating adult stem cells. These studies have given rise to some answers and many more questions including a search for alternative stem cell sources and what biochemical changes the cells undergo during the differentiation of these stem cells into chondrocytes, the cells which make up articular cartilage. Recently, periodontal dental ligament stem cells (PDLs) have come to the forefront as a practical alternative to other adult stem cells as well as the involvement of the mitogen-activated protein kinases (MAPKs) in stem cell differentiation via mechanical stimulation. During dynamic unconfined compression, levels of p42/44 MAPK increased by 50% (p<0.05). Additionally, the expression of the chondrogenic differentiation factor SRY (sex determining region Y)-box 9 (SOX-9) increased by 3-fold (p<0.05) as well as the chondrocyte marker aggrecan by over 2-fold after 4h of dynamic unconfined compression. Addition of the p42/44 phosphorylation inhibitor PD98059, along with compression, yielded no change in SOX-9 or aggrecan expression levels from basal levels in uncompressed controls. Inhibition of p38 MAPK or JNK phosphorylation during unconfined compression had no effect on the elevated expression of SOX-9 and aggrecan as compared to compressed cells without the addition of an inhibitor. It is therefore the overall findings of this study that PDLs possess the ability to differentiate into chondrocytes by mechanical compression and this differentiation is mediated by the p42/44 MAPK cascade.

Étude des propriétés hémato-supportives in vitro des cellules souches mésenchymateuses

Briquet, Alexandra

18 December 2009

Bone marrow (BM) mesenchymal stem cells (MSC) support proliferation and differentiation of hematopoietic progenitor cells (HPC) in vitro. Since they represent a rare subset of BM cells, MSC preparations for clinical purposes involves a preparative step of ex vivo multiplication. The aim of our study was to analyze the influence of culture duration on MSC supportive activity. MSC were expanded for up to 10 passages. MSC and CD34+ cells were seeded in cytokinefree co-cultures after which the phenotype, clonogenic capacity and in vivo repopulating activity of harvested hematopoietic cells were assessed. Early passage MSC supported HPC expansion and differentiation toward both B lymphoid and myeloid lineages. Late passage MSC did not support HPC and myeloid cell outgrowth but maintained B cell supportive ability. In vitro maintenance of NOD/SCID mouse repopulating cells cultured for one week in contact with MSC was effective until the fourth MSC passage and declined afterwards. CD34+ cells achieved higher levels of engraftment in NOD/SCID mice when co-injected with early passage MSC; however MSC expanded beyond 9 passages were ineffective in promoting CD34+ cell engraftment. Non-contact cultures indicated that MSC supportive activity involved diffusible factors. Among these, interleukin (IL)-6 and IL-8 contributed to the supportive activity of early passage MSC but not of late passage MSC. MSC phenotype as well as fat, bone and cartilage differentiation capacity did not change during MSC culture. Extended MSC culture alters their supportive ability toward HPC without concomitant changes in phenotype and differentiation capacity.

progenitor cells of B lymphoid

NOD/SCID-repopulating cells

human bone marrow mesenchymal stem cells

Development of biosynthetic conduits for peripheral nerve repair

McGrath, Aleksandra

January 2012

Peripheral nerve injuries are often associated with significant loss of nervous tissue leading to poor restoration of function following repair of injured nerves. Although the injury gap could be bridged by autologous nerve graft, the limited access to donor material and additional morbidity such as loss of sensation and scarring have prompted a search for biosynthetic nerve transplants. The present thesis investigates the effects of a synthetic matrix BD™ PuraMatrix™ peptide (BD)hydrogel, alginate/fibronectin gel and fibrin glue combined with cultured rat Schwann cells or human bone marrow derived mesenchymal stem cells (MSC) on neuronal regeneration and muscle recovery after peripheral nerve injury in adult rats. In a sciatic nerve injury model, after 3 weeks postoperatively, the regenerating axons grew significantly longer distances within the conduits filled with BD hydrogel if compared with the alginate/fibronectin gel. The addition of rat Schwann cells to the BD hydrogel drastically increased regeneration distance with axons crossing the injury gap and entering into the distal nerve stump. However, at 16 weeks the number of regenerating spinal motoneurons was decreased to 49% and 31% in the BD hydrogel and alginate/fibronectin groups respectively. The recovery of the gastrocnemius muscle was also inferior in both experimental groups if compared with the nerve graft. The addition of the cultured Schwann cells did not further improve the regeneration of motoneurons and muscle recovery. The growth-promoting effects of the tubular conduits prepared from fibrin glue were also studied following repair of short and long peripheral nerve gaps. Retrograde neuronal labeling demonstrated that fibrin glue conduit promoted regeneration of 60% of injured sensory neurons and 52% of motoneurons when compared with the autologous nerve graft. The total number of myelinated axons in the distal nerve stump in the fibrin conduit group reached 86% of the nerve graft control and the weight of gastrocnemius and soleus muscles recovered to 82% and 89%, respectively. When a fibrin conduit was used to bridge a 20 mm sciatic nerve gap, the weight of gastrocnemius muscle reached only 43% of the nerve graft control. The morphology of the muscle showed a more atrophic appearance and the mean area and diameter of fast type fibres were significantly worse than those of the corresponding 10 mm gap group. In contrast, both gap sizes treated with nerve graft showed similar fiber size. The combination of fibrin conduit with human MSC and daily injections of cyclosporine A enhanced the distance of regeneration by four fold and the area occupied by regenerating axons by three fold at 3 weeks after nerve injury and repair. In addition, the treatment also significantly reduced the ED1 macrophage reaction. At 12 weeks after nerve injury the treatment with cyclosporine A alone or cyclosporine A combined with hMSC induced recovery of the muscle weight and the size of fast type fibres to the control levels of the nerve graft group. In summary, these results show that a BD hydrogel supplemented with rat Schwann cells can support the initial phase of neuronal regeneration across the conduit. The data also demonstrate an advantage of tubular fibrin conduits combined with human MSC to promote axonal regeneration and muscle recovery after peripheral nerve injury.

Biosynthetic conduit

Mesenchymal stem cells

Nerve graft

Nerve tissue engineering

Peripheral nerve injury

Schwann cells

Formation of Composite Islet Grafts : A novel strategy to promote islet survival and revascularization

Johansson, Ulrika

January 2009

The islets of Langerhans are small and delicate spheroid organs scattered in the pancreas responsible for insulin production. Transplantation of isolated islets is a beneficial therapy for patients with a severe form of type 1 diabetes. The islets, which normally are richly vascularized in the pancreas, are completely disconnected from the vascular support by the enzymatic digestion during the isolation procedure. Islet viability is affected throughout all steps in this process, from donor death and isolation of islets to culturing and the transplantation process itself. In this thesis a novel strategy to promote islet survival and to re-establish islet vasculature is presented. We show endogenous expression of 51 different genes related to inflammation in cultured islets. Among these genes high expression of MCP-1, MIF, VEGF, thymosin b-10 and IL-8, IL-1β, IL-5R-a, IFN-γ antagonist were found in all donors during the 5- and the 2-day cultures, respectively. Protein expression of these genes can stimulate inflammatory immune responses but also promote tissue repair by attracting curative cells such as endothelial cells (EC) leading to re-establishment of the vasculature. We have established a novel technique by formation of composite islets using EC and mesenchymal stem cells (MSC). EC adhered on the surface of the islets and created a potential blood tolerant surface. The EC-islets showed a degree of protection from the detrimental effects of instant blood-mediated inflammatory reaction (IBMIR) with the major components of IBMIR being decreased in in vitro assays. We combined MSC to the EC-islets with success. The MSC were found to have proliferative effect on EC and the combination of these two cell types on the islets further increased the EC covered surface compared to EC-islets. The EC-MSC-islets in co-culture formed vessel-like structures both into the islets and out to the surrounding matrix. The MSC enhanced the exogenous EC to form vessel-like network in the EC-MSC-islets indicating vascular support by the MSC. The novel strategy and conditions presented herein could alleviate problems related to survival of the islets by promoting revascularization. This would open up a new era in islet transplantation and allow more patients to benefit from this therapy. / Clinical immunology, islet group

Islet of Langerhans

endothelial cells

mesenchymal stromal cells

transplantation

revascularization

Clinical immunology

Klinisk immunologi

The Role of miR-126/126* in Microenvironmental Regulation of Cancer Metastasis

Zhang, Yun

January 2013

<p>Cancer metastasis is the cause of about 90% of cancer patients' deaths. Despite significant improvements in the past three decades in understanding the molecular bases of oncogenic transformation of cancer cells, little is known about the molecular mechanisms underlying tumour cells' alteration of their microenvironment, entrance into the circulation, and colonization of distant organs. In recent years, accumulating evidence has indicated that tumour microenvironment, which consists of a variety of cell types and extracellular matrix components&#65292;plays an important role in regulating the metastatic abilities of carcinoma cells. Co-opted by cancer cells, those stromal cells promote tumour progression via multiple mechanisms, including enhancement of tumour invasiveness, elevation of angiogenesis, and suppression of immune surveillance activity. </p><p>Using a series of human breast cancer cell lines with different metastatic potentials <italic>in vivo</italic>, we performed an unbiased screen examining expression of miRNAs, and found that miR-126 and miR-126*, whose expression are regulated by methylation of the promoter of their host gene Egfl7 inside tumour cells, were significantly negatively correlated with metastatic potential. Using both mouse xenograft models and <italic>in vitro</italic> assays, we showed that this pair of miRNAs suppressed breast cancer metastasis through shaping the tumour microenvironment without changing tumour cell autonomous properties. Specifically, miR-126 and miR-126* act independently to suppress the sequential recruitment of mesenchymal stem cells (MSCs) and inflammatory monocytes into the primary tumour stroma, consequently inhibiting lung metastasis by breast tumour cells. Mechanistically, these miRNAs directly inhibit the production of stromal cell-derived factor-1 alpha (Sdf-1&alpha;, also known as Cxcl12), and indirectly suppress the expression of chemokine (C-C motif) ligand 2 (Ccl2) by the cancer cells within the tumour mass in an Sdf-1&alpha;-dependent manner. In addition, in contrast with the majority of reports which have shown incorporation of only the guiding strand of the miRNA duplex into the mRNA-targeting RNA induced silencing complex (RISC), both strands of the miR-126 RNA duplex are maintained at a similar level and suppress Sdf-1&alpha; expression independently. </p><p>Collectively, we have determined a dynamic process by which the composition of the primary tumour microenvironment could be altered via a change in the expression of two tumour-suppressive miRNAs derived from a single miRNA precursor to favor metastasis by breast cancer cells. Importantly, this work provides a prominent mechanism to explain the clinical correlation between reduced expression of miR-126/126* and poor metastasis-free survival of breast cancer patients.</p> / Dissertation

Oncology

Biology

Medicine

Inflammatory Monocytes

Mesenchymal Stem Cells

Metastasis

microRNA

Sdf-1/Cxcl12

Tumour Microenvironment

Cellular and Molecular Mechanism Underlying the Effect of Low-magnitude, High-frequency Vibration on Bone

Lau, Esther Yee Tak

27 July 2010

An emerging non-pharmacological treatment for bone degenerative diseases is whole body vibration (WBV), a mechanical signal composed of low-magnitude, high-frequency (LMHF) vibrations that when applied to bone, have osteogenic and anti-resorptive effects. Currently, the cellular and molecular mechanism underlying the effect of WBV on bone is unclear. In this study, we investigated the response of osteocytes, the putative mechanosensor in bone, under LMHF vibration. As bone cells differentiate from mesenchymal stromal cells (MSCs), we also studied the osteogenic differentiation of rat MSCs in the presence of vibration loading. We found that vibrated osteocytes show gene and protein expression changes suggestive of an anti-osteoclastogenic response, and secrete soluble factors that inhibit osteoclast formation and activity. In contrast, rat MSCs showed moderate to no response to LMHF vibration during osteogenic differentiation. Our data suggest that in vivo effects of LMHF vibration are mediated through mechanosensing and biochemical responses by osteocytes.

bone

mechanotransduction

osteocyte

osteoclast

mesenchymal stromal cell

whole body vibration

low-magnitude, high-frequency vibration

0541

Cellular and Molecular Mechanism Underlying the Effect of Low-magnitude, High-frequency Vibration on Bone

Lau, Esther Yee Tak

27 July 2010

An emerging non-pharmacological treatment for bone degenerative diseases is whole body vibration (WBV), a mechanical signal composed of low-magnitude, high-frequency (LMHF) vibrations that when applied to bone, have osteogenic and anti-resorptive effects. Currently, the cellular and molecular mechanism underlying the effect of WBV on bone is unclear. In this study, we investigated the response of osteocytes, the putative mechanosensor in bone, under LMHF vibration. As bone cells differentiate from mesenchymal stromal cells (MSCs), we also studied the osteogenic differentiation of rat MSCs in the presence of vibration loading. We found that vibrated osteocytes show gene and protein expression changes suggestive of an anti-osteoclastogenic response, and secrete soluble factors that inhibit osteoclast formation and activity. In contrast, rat MSCs showed moderate to no response to LMHF vibration during osteogenic differentiation. Our data suggest that in vivo effects of LMHF vibration are mediated through mechanosensing and biochemical responses by osteocytes.

bone

mechanotransduction

osteocyte

osteoclast

mesenchymal stromal cell

whole body vibration

low-magnitude, high-frequency vibration

0541

Delivering Electrical and Mechanical Stimuli through Bioactive Fibers for Stem Cell Tissue Engineering

Carnell, Lisa Ann Scott

January 2009

<p>Regenerative medicine holds the promise of providing relief for people suffering from diseases where treatment has been unattainable. The research is advancing rapidly; however, there are still many hurdles to overcome before the therapeutic potential of regenerative medicine and cell therapy can be realized. Low in frequency in all tissues, stem cell number is often a limiting factor. Approaches that can control the proliferation and direct the differentiation of stem cells would significantly impact the field. Developing an adequate environment that mimics in vivo conditions is an intensively studied topic for this purpose. Collaboratively, researchers have come close to incorporating nearly all biological cues representative of the human body. Arguably the most overlooked aspect is the influence of electrical stimulation. In this dissertation, we examined polyvinylidene fluoride (PVDF) as a new biomaterial and developed a 3D scaffold capable of providing mechanical and electrical stimuli to cells in vitro. </p><p>The fabrication of a 3D scaffold was performed using electrospinning. To obtain highly aligned fibers and scaffolds with controlled porosity, the set-up was modified by incorporating an auxiliary electrode to focus the electric field. Highly aligned fibers with diameters ranging from 500 nm to 15 µm were fabricated from colorless polyimide (CP2) and polyglycolic acid (PGA) and used to construct multilayer scaffolds. This experimental set-up was used to electrospin &#945;-phase PVDF into the polar &#946;-phase. We demonstrated the transition to the &#946;-phase by examining the crystalline structure using x-ray diffraction (XRD), differential scanning calorimetry (DSC), fourier transform infrared spectroscopy (FTIR) and polarized light optical microscopy (PLOM). We confirmed these results by observing a polarization peak at 80°C using the thermally stimulated current (TSC) method. Our results proved the electrospinning process used in our investigation poled the PVDF polymer in situ. </p><p>TThe influence of architecture and topographical cues was examined on 3D scaffolds and films of CP2 polyimide and PVDF. Culture of human mesenchymal stem cells (hMSCs) for 7 and 14 days demonstrated a significant difference in gene expression. The fibers upregulated the neuronal marker microtubule associated protein (MAP2), while downregulation of this protein was observed on films. Gap junction formation was observed by the expression of connexin-43 after 7 days on PVDF films attributed to its inherent pyroelectric properties. Connexin-43 expression on fibers showed cell-cell contact across the fibers indicating good communication in our 3D scaffold. </p><p>A scaffold platform was designed using PVDF fibers that allowed us to apply electrical stimulation to the cells through the fibers. The electrically stimulated PVDF fibers resulted in enhanced proliferation compared to TCPS as evidenced by a 10% increase in the uptake of EdU. Protein expression revealed upregulation of neuronal marker MAP2. Our findings indicate this new platform capable of delivering mechanical, electrical, topographical and biochemical stimuli during in vitro culture holds promise for the advancement of stem cell differentiation and tissue engineering.</p> / Dissertation

Engineering, Biomedical

Engineering, Materials Science

electroactive

mesenchymal

PVDF

scaffold

stimulation

topography

Oscillatory Compressive Loading Effects On Mesenchymal Progenitor Cells Undergoing Chondrogenic Differentiation In Hydrogel Suspension

Case, Natasha D.

15 April 2005

Articular cartilage functions to maintain joint mobility. The loss of healthy, functional articular cartilage due to osteoarthritis or injury can severely compromise quality of life. To address this issue, cartilage tissue engineering approaches are currently in development. Bone marrow-derived mesenchymal progenitor cells (MPCs) hold much promise as an alternative cell source for cartilage tissue engineering. While previous studies have established that MPCs from humans and multiple other species undergo in vitro chondrogenic differentiation, additional research is needed to define conditions that will enhance MPC differentiation, increase matrix production by differentiating cultures, and support development of functional tissue-engineered cartilage constructs. Mechanical loading may be an important factor regulating chondrogenic differentiation of MPCs and cartilage matrix formation by chondrogenic MPCs. This thesis work evaluated the influence of oscillatory unconfined compressive mechanical loading on in vitro MPC chondrogenic activity and biosynthesis within hydrogel suspension. Loading was conducted using MPCs cultured in media supplements supporting chondrogenic differentiation. Possible interactions between the number of days in chondrogenic media preceding loading initiation and the ability of the MPC culture to respond to mechanical stimulation were explored in two different loading studies. The first loading study investigated the effects of 3 hour periods of daily oscillatory mechanical stimulation on subsequent chondrogenic activity, where chondrogenic activity represented an assessment of cartilage matrix production by differentiating MPCs. This study found that oscillatory compression of MPCs initiated during the first seven days of culture did not enhance chondrogenic activity above the level supported by media supplements alone. The second loading study evaluated changes in biosynthesis during a single 20 hour period of oscillatory mechanical stimulation to assess mechanoresponsiveness of the MPC cultures. This study found that MPCs modulated proteoglycan and protein synthesis in a culture time-dependent and frequency-dependent manner upon application of oscillatory compression. Together the two loading studies provide an assessment of dynamic compressive mechanical loading influences on MPC cultures undergoing chondrogenic differentiation. The information gained through in vitro studies of differentiating MPC cultures will increase basic knowledge about progenitor cells and may also prove valuable in guiding the future development of cartilage tissue engineering approaches.

Compressive loading

Mechanical stimulation

Chondrogenic differentiation

Mesenchymal progenitor cell

Alginate

TGF-beta 1

The effect of age and sex on the number and osteogenic differentiation potential of adipose-derived mesenchymal stem cells

Lazin, Jamie Jonas

23 June 2010

It has been shown that stem cells exist within adult adipose tissue. These stem cells are named adipose-derived mesenchymal stem cells (ASCs), are derived from the mesoderm, and can differentiate into a number of cells including osteoblasts, chondrocytes, and adipocytes. However, before these cells can be used clinically it is important that we understand how factors like age, sex, and ethnicity affect ASC number and potential. Additionally, since men and women vary in their distribution of adipose tissue, it will be important to see if the ideal source of ASCs is different for each sex. The goal of this study was to assess how age and sex affects ASCs. We used flow cytometry to investigate how age and sex affected the number of ASCs in adipose tissue. Additionally, we plated these cells in culture and treated them with an osteogenic media (OM) with the intention of pushing them towards osteoblast differentiation. The purpose of this was to see if age or sex affected the potential of the ASCs to undergo osteogenesis in culture. For this study we used real-time PCR and biochemical assays to look at markers of early and late osteogenic differentiation. Finally, we used immunohistochemistry to demonstrate where in adipose tissue the CD73 and CD271 positive cell population exists. It is our hope that this work will shed light on how age and sex affect ASCs so that clinicians can optimize their ASC harvest depending on the patient's physiology.

Adipose stem cells

Osteogenesis

Tissue engineering

Regenerative medicine

Stem cells

Mesenchymal stem cells

Bones Growth