Synovial Extracellular Matrix and Synovial Mesenchymal Stem Cells are Chondrogenic In Vitro and In Vivo

Reisbig, Nathalie A.

January 2018

No description available.

Veterinary Services

Animal Sciences

Regenerative Medicine

Involvement of Aryl Hydrocarbon Receptor in Adipocyte Differentiation and Circadian Clock Regulation

Khazaal, Ali

01 December 2018

Type 2 diabetes is a metabolic disorder characterized by increased glucose concentrations in the blood due to decreased insulin sensitivity. The worldwide incidence of diabetes has increased remarkably over the last two decades. Obesity, due to increased consumption of calorie dense diets, and sedentary life styles, is commonly cited as a primary cause. However, many epidemiological studies have established a relationship between insulin resistance and exposure to environmental chemicals such as persistent organic pollutants (POPs). The mechanisms by which POPs alter metabolism remain poorly understood, although their lipophilic nature suggests a role in adipose tissue function. The Tischkau lab has established a relationship between Aryl hydrocarbon Receptor (AhR) activation by different types of POPs and increased risk of insulin resistance. This dissertation, therefore, explored the effects of AhR activation by POPs on adipose tissue function. Adipose tissue regulates systemic glucose and lipid metabolism through production of hormones and cytokines that regulate appetite and energy homeostasis. It is well-known that impaired adipose function promotes systemic insulin resistance. The first specific aim examined the hypothesis that activation of AhR suppresses adipogenesis by lowering the rate of pre-adipocyte differentiation. Adipogenesis is a process by which mesenchymal stem cells (MSCs) and pre-adipocytes differentiate into mature adipocytes. Limitations in adipogenesis and accumulation of ectopic lipid have significant roles in decreasing insulin sensitivity. Thus, I hypothesized that POPs contribute to systemic insulin resistance by lowering the rate of MSCs and preadipocyte differentiation; the resulting large, poorly-functioning adipocytes increase serum lipids and promote lipid deposition in other tissues. MSCs derived from mouse bone marrow and pre-adipocytes were treated with different concentrations of AhR agonist, β-Naphthoflavone (BNF), and levels of transcripts associated with adipocyte differentiation were determined by using quantitative PCR. Oil red O staining and lipid content were observed to examine differentiation into mature adipocytes. Genes that promote adipogenesis, including peroxisome proliferator-activated receptor gamma (PPARγ), CCAAT/enhancer-binding protein alpha (CEBPα), fatty acid binding protein 4 (FABP4), and adiponectin were downregulated in MSCs treated with BNF. Moreover, accumulation of triglycerides was decreased after BNF treatment. Recombinant lentivirus vector-mediated AhR knockdown blocked the effects of BNF on adipogenesis. Therefore, activation of AhR by exogenous ligands inhibits adipogenesis leading to impaired fat storage. Limitations in adipogenesis promotes accumulation of the excess lipid in non-fat tissue such as liver, muscle, and heart leading to decrease the insulin sensitivity and disrupt energy homeostasis. The second specific aim examined effects of AhR activation on circadian clock regulation in adipose tissue. A circadian clock essentially regulates systematic energy homeostasis; the central clock in the suprachiasmatic nucleus (SCN) works with the local clocks in peripheral tissues such as liver, muscle, and adipose tissue to regulate whole-body metabolism. The Tischkau lab has previously shown that AhR interacts with the core machinery of the circadian clock. Activation of AhR by environmental toxicants leads to a dampening of the rhythm expression of core clock genes or an alteration in the timing of their peak expression, which subsequently promotes metabolic disorders such as glucose insensitivity and hyperlipidemia. Given the importance of appropriately timed adipose tissue function to regulation of energy homeostasis, this study focused on mechanisms by which AhR may influence clock-controlled mature adipose tissue activity. Lipolysis is a clock-regulated process in adipose tissue that provides the necessary energy during periods of fasting and exercise. Thus, I hypothesized that AhR activation in adipose tissue would impair lipolysis by altering molecular circadian clock function. AhR activation was proposed to dampen adipose rhythms, leading to a decreased lipolysis rate during the absence of food, and subsequently, increased glucose concentrations in the blood. C57BL/6 mice were injected with vehicle or 50 mg/kg body weight of the AhR agonist, BNF, 48 hours after release into constant darkness. Mice were sacrificed, and epididymal adipose tissue was collected every 6 hours over a 24 hour period. Real-Time RT-qPCR was used to measure mRNA expression of genes responsible for lipolysis. To examine effects of AhR activation in vitro; mouse pre-adipocytes, 3T3-L1 cells, were differentiated into mature adipocytes for 12 days. Cells were then starved for 24 hours with DMEM media containing 1% FBS to induce lipolysis in the presence of 100, 200, 300 µM of BNF. RNA was then extracted and mRNA expression for genes responsible for circadian clock and lipolysis were determined by RT-qPCR. Alterations were observed in rhythms of core clock genes in wild type mice injected with BNF compared to wild type mice injected with vehicle. Rhythms of key enzymes controlling lipolysis including hormone sensitive lipase (HSL) and adipose triglycerides lipolysis (ATGL) was changed in wild type mice injected with BNF compared to wild type mice injected with vehicle. These effects were blocked in AhR deficient mice, suggesting that these effects were AhR dependent. Liver glycogen was decreased in mice injected with BNF compared to wild type mice injected with vehicle after 12 hour of food restriction but not in AhR null mice. Activation of AhR led to decreased expression of lipolysis genes in adipose tissue at CT6 (middle of the rest phase) as well as in 3T3-L1 cells. Recombinant lentivirus vector-mediated AhR knockdown blocked the effects of BNF on lipolysis in 3T3-L1 cell line. These data establish a link between environmental toxicants and impaired lipolysis, specifically by altering rhythms of clock genes in adipose tissue. In response to the decreased available energy from impaired lipolysis, the body increases glycogenolysis, thereby degrading more glycogen to provide the necessary energy. This process may lead to increased glucose level in the blood and development of type 2 diabetes. The data from this study suggest that activation of AhR by BNF increases the risk of insulin resistance and type 2 diabetes by impairing adipogenesis. Reduced adipogenesis likely decreases adipocyte capacity to capture triglycerides from the blood. These effects may disturb energy homeostasis and contribute to the development of metabolic syndrome. This study also establishes a link between environmental toxicants and impaired lipolysis, specifically by altering rhythms of clock genes in adipose tissue. In response to the decreased available energy from impaired lipolysis, the body increases glycogenolysis, thereby degrading more glycogen to provide the necessary energy. This process may lead to increased glucose level in the blood and development of type 2 diabetes. All together, these data suggest that environmental pollutants result in adipose tissue dysfunction by reducing adipogenesis and lipolysis. Therefore, activation of AHR by its exogenous ligands may increase the risk of insulin resistance and type 2 diabetes by impairing adipose tissue function. In particular, activation of AHR by exogenous ligands leads to impairment of free fatty acids storage during feeding and release during fasting to disturb energy homeostasis.

Adipogenesis

Adipose Tissue

Aryl hydrocarbon Receptor

Circadian Clock

Lipolysis

Mesenchymal Stem Cells

Polymer Prodrug Conjugation to Tumor Homing Mesenchymal Stem Cells

Panzarino, Nick

01 January 2012

Toxicity resulting from systemic administration continues to limit the effectiveness of modern chemotherapeutics. Administered drugs and biologics damage vital organs via off target effects while in circulation, decreasing the maximum tolerated dose and preventing the use of more effective drug concentrations. Many therapeutic agents are additionally constrained by a narrow therapeutic index, requiring delicate balance between toxicity and loss of efficacy. With dose remaining a critical determinant of efficacy, the inability to utilize increased drug concentrations due to toxicity prevents the full exploitation of the drug’s therapeutic effect. While exploitation of the enhanced permeability and retention effect has been somewhat successful in targeting nanoparticles to tumors via passive accumulation, elevated tumor pressure and poor drug penetrance prevent a significant improvement in therapeutic effect. Here we describe the conjugation of polymer prodrugs to tumor homing mesenchymal stem cells as a novel approach to chemotherapeutic drug delivery. The utilization of an actively homing cellular vehicle for effective drug delivery against the pressure gradient has the potential to improve drug penetration of the tumor while reducing systemic toxicity and improving drug efficacy.

Polymer

Nanotechnology

Drug Delivery

Mesenchymal Stem Cells

Cancer

Biochemistry

Medical Sciences

Molecular Biology

Polymer Chemistry

Layer 3 pyramidal neurons of rhesus monkeys in aging and after ischemic injury

Chang, Wayne Wei-En

23 January 2023

Layer 3 (L3) pyramidal neurons are involved in intrinsic and extrinsic corticocortical communications that are integral to area specific cortical functions. The functional and morphological properties of these neurons are altered in the lateral prefrontal cortex (LPFC) of aged rhesus monkeys, changes which parallel the decline of working memory (WM) function. What is not yet understood is the time course of these neuronal alternations during the aging process, or the impact of neuronal changes on the function of local networks that underlie WM. By comparing the properties of L3 pyramidal neurons from the LPFC of behaviorally characterized rhesus monkeys over the adult lifespan using whole cell patch clamp recordings and neuronal reconstructions, the present dissertation demonstrates that WM impairment, neuronal hyperexcitabilty and spine loss begin in middle age. We use bump attractor models to predict how empirically observed changes affect performance on the Delayed Response Task and Delayed Recognition Span Task (spatial). The performance of both models is affected much more by neuronal hyperexcitability than by synapse loss. In a separate study, we examine pathological changes of L3 pyramidal neurons in the perilesional ventral premotor cortex following acute ischemic injury to the primary motor cortex. Neurons from lesioned monkeys exhibit hyperexcitability and changes the excitatory:inhibitory synaptic balance in favor of inhibition. As oxidative stress and inflammation are known to exacerbate both age-related and injury-induced neuronal pathology, we characterize neuronal properties in both conditions after administering therapeutic interventions which target inflammatory pathways and which have previously been shown to ameliorate behavioral deficits. Chronic dietary curcumin treatment dampens neuronal hyperexcitability in middle-aged subjects, but the neuronal changes are not correlated with WM improvements. Treatment with mesenchymal-derived extracellular vesicles lowers firing rates and restores excitatory:inhibitory synaptic balance, and importantly, these changes correlate significantly with motor function.

Neurosciences

Aging

Extracellular vesicles

Ischemic injury

Mesenchymal stem cells

Pyramidal neurons

Rhesus onkeys

Inflammatory-Based Therapies Driven by Intervertebral Disc Injury Responses

Kenawy, Hagar Mohamed

January 2024

Intervertebral disc (IVD) degeneration is a major cause of low back pain (LBP) worldwide which is expected to affect 80% of the world’s population. IVD degeneration (IDD) is a key player in the degenerative cascade associated with LBP. Pro-inflammatory cytokines and mediators, such as nitric oxide, have been shown to be triggers and mediators of IDD. Due to the avascular nature of the adult IVD, the disc is unable to heal or regenerate when damaged. The multi-components of the IVD, namely glycosaminoglycan (GAG)-rich nucleus pulposus (NP), a concentric collagen dense annulus fibrosis (AF), and cartilage endplates (CEPs), further complicate possible regenerative solutions. Cell therapies show promise. This is supported by studies that demonstrate the use of mesenchymal stem cells (MSCs) in animal models showing potential in mitigating inflammatory signaling as well as recovering proteoglycan content. Despite these promising findings, several gaps in knowledge remain. While the biochemical and mechanical properties of an injured disc (via physical or chemical stimulation) have been characterized, the resulting inflammatory signaling cascades remain undefined. A growing body of evidence suggests that TLR4 is involved in the pathogenesis of the IVD. However, it is unknown how TLR4 mediates injury responses of the IVD. Second, it is unknown how mechanical loading of IVDs can influence the transcriptome or secretome of the IVD. The IVD is normally exposed to multimodal loading (e.g., compression, tension, shear, hydrostatic pressure, and osmotic pressure). Both frequency and magnitude regulate whether loading is beneficial or detrimental to disc integrity, which will be explored. Furthermore, the secretome of the IVD, especially during loading, may be essential to creating therapies targeted for regeneration of the IVD. There may be key, distinct paracrine factors that are released in IVD conditioned loading media which can influence the regenerative and anti-inflammatory capabilities of cell-based therapies. To address these gaps, this thesis describes a series of experiments employing novel ex vivo organ culture model to study the response of the IVD to various injury modalities (inflammatory stimulation, puncture injury, compressive loading), and resulting changes in inflammatory, biomechanical, and biochemical responses. Through methods such as RNA sequencing and proteomics, we now have expanded the characterization to beyond candidate genes or proteins, and are more informed on (1) the IVD response to injury, (2) the role of TLR4 signaling in this ex vivo organ culture model, in addition to (3) the downstream effects of loading and how paracrine factors can be used to improve and develop potential cell and molecular therapies. Sex-based differences, in male and female rat caudal IVDs, were also identified and are analyzed in the context of response to injury.

Biomedical engineering

Biomechanics

Intervertebral disk--Diseases

Backache--Treatment

Inflammation

Nitric oxide--Physiological effect

Mesenchymal stem cells

3D Scaffolds from Self Assembling Ultrashort Peptide for Tissue Engineering and Disease Modeling

Alshehri, Salwa

06 June 2022

Tissue engineering is a promising approach that combines the interactions of biomaterials, cells, and growth factors to stimulate tissue growth and regeneration. As such, selecting a suitable biomaterial is vital to the success of the procedure. Ideally, the material should show similarity to the extracellular matrix in the structure and relative stiffness, and biofunctionality beside others to provide a comfortable environment for the cells. Additionally, the biomaterial properties should allow for the effective diffusion of relevant growth factors and nutrients throughout the material to enable cell growth. Because peptides are composed of amino acids found naturally within the human body, they are considered non-toxic and biocompatible. Ultrashort peptides are peptides with three to seven amino acids that can be self-assembled into helical fibers forming scaffolds of supramolecular structures. These peptide hydrogels formed a highly porous network of nanofibers which can quickly solidify into nanofibrous hydrogels that resemble the extracellular matrix (ECM) and provide a 3D environment for cells with suitable mechanical properties. Furthermore, we can easily tune the stiffness of these peptide hydrogels by just increasing peptide concentration, thus providing a wide range of peptide hydrogels with different stiffness for 3D cell culture applications. Herein we describe the use of ultrashort peptide hydrogels for the maintenance and the differentiation of human mesenchymal stem cells into the osteogenic lineage. Furthermore, we develop a three dimensional (3D) biomimicry acute myeloid leukemia (AML) disease model using biomaterial from a tetramer ultrashort self-assembling peptide. In addition, we evaluate the potential application of peptide hydrogels as a hemostatic agent. The results presented in this study suggest that our biomimetic ultrashort tetrapeptide hydrogels are an excellent candidate for tissue engineering and biomedical applications.

Peptide hydrogel

Mesenchymal stem cells

Osteogenic differentiation

Acute myeloid leukemia

3D culture

Biomedical Imaging of Stem Cells Using Reporter Genes

Wang, Fangjing

17 May 2010

No description available.

Biomedical Research

Engineering

Scientific Imaging

Imaging

BLI

PET

GVHD

mesenchymal stem cells

reporter gene

non-invasive

repeated

Guiding Chondrogenesis through Controlled Growth Factor Presentation with Polymer Microspheres in High Density Cell Systems

Solorio, Loran Denise

26 June 2012

No description available.

Biomedical Engineering

cartilage tissue engineering

microspheres

mesenchymal stem cells

growth factor delivery

Elastogenic characterization of rat BM-MSC-derived SMCS towards use in soft Tissue Engineering

Wintrich, Sahithya

07 November 2012

No description available.

Biomedical Engineering

elastin

bone marrow

mesenchymal stem cells

differentiation

rat

MSC

BM-MSC

Characterization and Clinical Implications of Microsatellite Instability in Human Adult Mesenchymal and Hematopoietic Stem Cells

Thomas, Emily A.

January 2008

No description available.

Biology, Molecular

microsatellite instability

DNA mismatch repair

mesenchymal stem cells

hematopoietic stem cells