Enhanced phagocytic capacity endows chondrogenic progenitor cells with a novel scavenger function within injured cartilage

Zhou, Cheng

01 December 2016

Articular cartilage underwent serious joint injuries seldom repair spontaneously and might progress to post-traumatic osteoarthritis. This is majorly because articular cartilage’s unique properties that lack blood and nerve supply intrinsically. This peculiar structure, in addition, generates an unfavorable environment for certain phagocytes (macrophages, monocytes, neutrophils, etc) to infiltrate to cartilage to scavenge debris from cartilage matrix and cell caused from joint injuries. Therefore, physiological and functional regeneration of damaged cartilage is urgently needed and several clinical techniques have been developed, including microfracture, autograft transplantation, autologous chondrocytes implantation. We previously identified highly migratory cells emerged and repopulated in cartilage damaged surface after ~10 days of artificial cartilage injury. These cells were later named chondrogenic progenitor cells (CPCs) due to their enhanced potential of chondrogenic differentiation. However, this important finding contrasts the conventional theory that cartilage harbors only one cell type, chondrocytes. Here we hypothesize that CPCs are a distinct cell type in cartilage, and more importantly, one of CPCs’ crucial natures is to phagocytose debris more effectively than chondrocytes. To test these, we first harvested CPCs from cartilage surfaces, chondrocytes, synovial cells (synoviocytes and synovial fluid cells) for microarray assay to evaluate the closeness among these joint cells on whole gene expression level. Quantitative PCR were then conducted to verify gene expression of certain functional interests. Moreover, debris from cell and extracellular matrix were generated and incubated with CPCs and chondrocytes to compare their phagocytic capacity via multiple experimental assessments. In confocal microscopy examination, the emergence of CPCs could be clearly observed after cartilage injury. Aside from their distinguishable morphology compared to chondrocyte, CPCs possess several vital properties including highly migratory, chemotactic, clonogenic. Microarray data revealed that CPCs, from gene expression profile, are distinctively isolated from chondrocytes and are more akin to synovial cells. Additionally, the series of phagocytosis related experiments showed that CPCs are dramatically superior to chondrocytes in engulfing debris, along with enhanced lysosomal activities indicating the following debris degradation. Taken all these data together, CPCs, activated by cartilage injury, emerged and migrated to damaged sites. They are a distinct cell type residing in cartilage apart from chondrocytes. Their enhanced capacity to sustainably phagocytose and clear debris provides a novel insight for cartilage regeneration and prevention of osteoarthritis.

cartilage regeneration

chondrocytes

chondrogenic progenitor cells

osteoarthritis

phagocytosis

Discriminating Chondrogenic Progenitor Cells (CPCs) as a Distinct Cell Type, Apart from Normal Chondrocytes

Zhou, Cheng

01 July 2013

Articular cartilage is an avascular, aneural, and alymphatic tissue with a structure consisting of a superficial, a middle and a deep zone, overlie a calcified zone at the cartilage border between. Each zone has biological and mechanical properties. Self-repair of damaged cartilage seldom if ever occurs, and joint injuries that harm cartilage surfaces often result in osteoarthritis. This has prompted researchers to explore diverse approaches to cartilage regeneration. The superficial zone shows the highest cellularity and the lowest matrix density. Cartilage cells (chondrocytes) residing in the superficial zone had been thought to be a subpopulation of chondrocytes. However, our laboratory identified a second population of cells that were distinguishable from chondrocytes based on their clonogenicity, multipotency, migratory activity, higher proliferate rate and substantial morphological differences. These cells later proved to be chondrogenic progenitor cells (CPCs). Our continuing studies have shown that CPCs are less chondrogenic than normal chondrocytes and their function is to protect the cartilage surface rather than to regenerate cartilage matrix as previously supposed. In addition, we found evidence to suggest that CPCs act as pro-inflammatory cells in the context of cartilage injury. For these reasons, we undertook a more comprehensive comparison of the phenotypic differences between CPCs and normal chondrocytes and between CPCs and joint cells (tissue synoviocytes from the joint capsule and cells present in synovial fluid) which have been shown to be play roles in joint inflammation. Gene expression microarray analysis of >25,000 genes revealed that the overall pattern of gene expression in CPCs was distinct from normal chondrocytes, but closely related to synoviocytes and synovial fluid cells. Analysis of specific genes by quantitative PCR (qPCR) showed profound differences between CPCs and normal chondrocytes in terms of cartilage matrix gene expression (Collagen Type ІІ, Aggrecan, Link Protein and COMP) and pro-inflammatory gene expression (IL6, IL8, CCL2 and CXCL12). In contrast, the pattern of CPC gene expression closely resembled. Sulfated glycosaminoglycan assays revealed that cartilage matrix deposition by CPCs, as well as synoviocytes and synovial fluid cells, was significantly inferior to normal chondrocytes. However, chondrogenic and osteogenic differentiation assays, showed no significant differences among the four cell types. In addition to establishing that CPCs are distinct from chondrocytes, this work suggests significant revisions to our understanding of CPC function in cartilage. The weak chondrogenic ability and higher expression of inflammatory cytokines, suggests these cells don't play a regenerative role as previously thought. On the other, we found evidence that CPCs may form a protective layer on the top of the injured cartilage surfaces, preventing further cartilage injury. In vivo studies are needed to fully elucidate the significance of these roles in cartilage health and disease.

cartilage

chondrogenic progenitor cells

microarray

normal chondrocytes

synovial fluid cells

synoviocytes

Characterizing the role of primary cilia in neural progenitor cell development and neonatal hydrocephalus

Carter, Calvin Stanley

01 May 2014

Neonatal hydrocephalus is a common neurological disorder leading to expansion of the cerebral ventricles. This disease is associated with significant morbidity and mortality and is often fatal if left untreated. Hydrocephalus was first described over 2500 years ago by Hippocrates, the father of medicine, and remains poorly understood today. Current therapies still rely on invasive procedures developed over 60 years ago that are associated with high failure and complication rates. Thus, the identification of molecular mechanisms and the development of non-invasive medical treatments for neonatal hydrocephalus are high priorities for the medical and scientific communities. The prevailing doctrine in the field is that hydrocephalus is strictly a "plumbing problem" caused by impaired cerebrospinal fluid (CSF) flow. Recently, animal models with impaired cilia have provided insight into the mechanisms involved in communicating (non-obstructive) hydrocephalus. However, as a result of a poor understanding of hydrocephalus, no animal studies to date have identified an effective non-invasive treatment. The goal of this thesis project is to investigate the molecular mechanisms underlying this disease and to identify a non-invasive, highly effective treatment strategy. In Chapter 2, we utilize a novel animal model with idiopathic hydrocephalus, mimicking the human ciliopathy Bardet-Biedl Syndrome (BBS), to examine the role of cilia in hydrocephalus. We find that these mice develop communicating hydrocephalus prior to the development of ependymal "motile" cilia, suggesting that this phenotype develops as a result of dysfunctional "primary" cilia. Primary cilia are non-motile and play a role in cellular signaling. These results challenge the current dogma that dysfunctional motile cilia underlies neonatal hydrocephalus and implicate a novel role for primary cilia and cellular signaling in this disease. Chapter 3 focuses on identifying the link between primary cilia and neonatal hydrocephalus. In this chapter, we report that disrupting the molecular machinery within primary cilia leads to faulty PDGFRα signaling and the loss of a particular class of neural progenitor cells called oligodendrocyte precursor cells (OPCs). We find that the loss of OPCs leads to neonatal hydrocephalus. Importantly, we identify the molecular mechanism underlying both the loss of OPCs and the pathogenesis of neonatal hydrocephalus. Chapter 4 explores the therapeutic potential of targeting the defective cellular signaling pathways to treat neonatal hydrocephalus. By targeting the faulty signaling, we restore normal development of oligodendrocyte precursor cells, and curtail the development of hydrocephalus. This work challenges the predominant view of hydrocephalus being strictly a "plumbing problem" treatable solely by surgical diversion of CSF. Here, we propose that hydrocephalus is a neurodevelopmental disorder that can be ameliorated by non-invasive means. Importantly, we introduce novel molecular targets and a non-invasive treatment strategy for this devastating disorder. To our knowledge, we are the first to successfully treat neonatal hydrocephalus in any model organism by targeting neural progenitor cells.

bardet-biedl syndrome

cilia

Hydrocephalus

lithium

neural progenitor cells

Oligodendrocyte precursor cells

Neuroscience and Neurobiology

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

Neural Stem and Progenitor Cells as a Tool for Tissue Regeneration

Wallenquist, Ulrika

January 2009

Neural stem and progenitor cells (NSPC) can differentiate to neurons and glial cells. NSPC are easily propagated in vitro and are therefore an attractive tool for tissue regeneration. Traumatic brain injury (TBI) is a common cause for death and disabilities. A fundamental problem following TBI is tissue loss. Animal studies aiming at cell replacement have encountered difficulties in achieving sufficient graft survival and differentiation. To improve outcome of grafted cells after experimental TBI (controlled cortical impact, CCI) in mice, we compared two transplantation settings. NSPC were transplanted either directly upon CCI to the injured parenchyma, or one week after injury to the contralateral ventricle. Enhanced survival of transplanted cells and differentiation were seen when cells were deposited in the ventricle. To further enhance cell survival, efforts were made to reduce the inflammatory response to TBI by administration of ibuprofen to mice that had been subjected to CCI. Inflammation was reduced, as monitored by a decrease in inflammatory markers. Cell survival as well as differentiation to early neuroblasts seemed to be improved. To device a 3D system for future transplantation studies, NSPC from different ages were cultured in a hydrogel consisting of hyaluronan and collagen. Cells survived and proliferated in this culturing condition and the greatest neuronal differentiating ability was seen in cells from the newborn mouse brain. NSPC were also used in a model of peripheral nervous system injury, and xeno-transplanted to rats where the dorsal root ganglion had been removed. Cells survived and differentiated to neurons and glia, furthermore demonstrating their usefulness as a tool for tissue regeneration.

traumatic brain injury

neural stem cells

transplantation

CNS

PNS

progenitor cells

inflammation

CCI

Biochemistry

Biokemi

Use of Human Blood-Derived Endothelial Progenitor Cells to Improve the Performance of Vascular Grafts

Stroncek, John

January 2011

<p>Synthetic small diameter vascular grafts fail clinically due to thrombosis and intimal hyperplasia. The attachment of endothelial cells (ECs) onto the inner lumen of synthetic small diameter vascular grafts can improve graft patency; however, significant challenges remain that prevent wide clinical adoption. These issues include difficulties in the autologous sourcing of ECs, the lack of attachment, growth and retention of the layer of ECs to the graft lumen, and the maintenance of an anti-thrombotic and anti-inflammatory profile by the layer of ECs. </p><p>This dissertation describes the isolation, characterization, and use of endothelial progenitor cells (EPCs) to improve the performance of small diameter vascular grafts. First, EPC isolation efficiency and expression of critical EC markers was compared between young healthy volunteers and patients with documented coronary artery disease (CAD). EPCs were isolated and expanded from patients with CAD and had a similar phenotype to EPCs isolated from healthy donors, and a control population of human aortic ECs. Second, we assessed the ability to enhance the anti-thrombotic activity of patient derived EPCs through the over expression of thrombomodulin (TM). In vitro testing showed TM-transfected EPCs had significantly increased production of key anti-thrombotic molecules, reduced platelet adhesion, and extended clotting times over untransfected EPCs. Finally, native and TM-transfected EPCs were seeded onto small diameter vascular grafts and tested for their ability to improve graft performance. EPCs sodded onto the lumen of small diameter ePTFE vascular grafts had strong adhesion and remained adherent during graft clamping and exposure to flow. TM-transfected EPCs improved graft anti-thrombotic performance significantly over bare grafts and grafts seeded with native EPCs. Based on these promising in vitro results, grafts were implanted bilaterally into the femoral arteries of athymic rats. Bare grafts and grafts with air removed clotted and had only 25% patency at 7 days. In contrast, graft sodded with native EPCs or TM-transfected EPCs had 87% and 89% respective patency rates. High patency rates continued with 28 day implant testing with EPC sodded grafts (88% Native; 75% TM). There were no significant differences in patency rates at 7 or 28 days between native and TM-transfected grafts. These in vivo data suggest patient blood-derived EPCs can be used to improve the performance of small diameter vascular grafts.</p> / Dissertation

Biomedical Engineering

Biology

Engineering

Endothelial cells

Endothelial progenitor cells

Gene therapy

Thrombomodulin

Thrombosis

Vascular graft

Circulating Progenitor Cell Therapeutic Potential Impaired by Endothelial Dysfunction and Rescued by a Collagen Matrix

Marier, Jenelle

26 July 2012

Angiogenic cell therapy is currently being developed as a treatment for coronary artery disease (CAD); however, endothelial dysfunction (ED), commonly found in patients with CAD, impairs the ability for revascularization to occur. We hypothesized that culture on a collagen matrix will improve survival and function of circulating progenitor cells (CPCs) isolated from a mouse model of ED. Overall, ED decreased the expression of endothelial markers in CPCs and impaired their function, compared to normal mice. Culture of CPCs from ED mice on collagen was able to increase cell marker expression, and improve migration and adhesion potential, compared to CPCs on fibronectin. Nitric oxide production was reduced for CPCs on collagen for the ED group; however, CPCs on collagen had better viability under conditions of serum deprivation and hypoxia, compared to fibronectin. This study suggests that a collagen matrix may improve the function of therapeutic CPCs that have been exposed to ED.

coronary artery disease

circulating progenitor cells

endothelial dysfunction

nitric oxide

collagen matrix

B-cell Lymphoma-2 (Bcl-2) Is an Essential Regulator of Adult Hippocampal Neurogenesis

Ceizar, Maheen

19 September 2012

Of the thousands of dividing progenitor cells (PCs) generated daily in the adult brain only a very small proportion survive to become mature neurons through the process of neurogenesis. Identification of the mechanisms that regulate cell death associated with neurogenesis would aid in harnessing the potential therapeutic value of PCs. Apoptosis, or programmed cell death, is suggested to regulate death of PCs in the adult brain as overexpression of B-cell lymphoma 2 (Bcl-2), an anti-apoptotic protein, enhances the survival of new neurons. To directly assess if Bcl-2 is a regulator of apoptosis in PCs, this study examined the outcome of removal of Bcl-2 from the developing PCs in the adult mouse brain. Retroviral mediated gene transfer of Cre into adult floxed Bcl-2 mice eliminated Bcl-2 from developing PCs and resulted in the complete absence of new neurons at 30 days post viral injection. Similarly, Bcl-2 removal through the use of nestin-induced conditional knockout mice resulted in reduced number of mature neurons. The function of Bcl-2 in the PCs was also dependent on Bcl-2-associated X (BAX) protein, as demonstrated by an increase in new neurons formed following viral-mediated removal of Bcl-2 in BAX knockout mice. Together these findings demonstrate that Bcl-2 is an essential regulator of neurogenesis in the adult hippocampus.

Adult Neurogenesis

Apoptosis

Bcl-2

Hippocampus

Transgenic Mouse Model

BAX

Progenitor Cells

Retrovirus

Inducible Knock out

Generation and Characterization of Induced Neural Progenitor Cell Lines

DesaiI, Ridham

19 January 2012

Large-scale expansion of lineage-committed stem cells can provide an excellent ex vivo model for studying complex molecular pathways governing cell fate choices. Also, such cells could be useful for implementing cell therapeutic approaches for treatment of specific disorders involving extensive cellular damage within that lineage. Using growth factors, pluri- and multipotent stem cells have been successfully isolated and cultured from pre- and peri-implantation stage embryos, including trophectoderm, primitive ectoderm, epiblast and primitive endoderm. However, ex vivo expansion of lineage restricted cells from later embryonic lineages and adult tissues have been a challenge. N-myc is a well-characterized member of myc gene family that is known to be essential for the proliferation of numerous progenitor cell types during normal embryonic development of diverse organs including lungs, liver, heart, kidneys and brain. Considering this important role of N-myc, we hypothesized that its regulated activation in these progenitors might allow their expansion in culture. To test this hypothesis, we generated a novel doxycycline-inducible transgenic mouse line that expresses N-myc uniformly across all tissues. Using cortical precursors derived from mid-gestation embryos of these mice, we show that upon doxycycline induced N-myc expression, we can achieve at least a million-fold expansion of multipotent neural precursors within a short span of time in culture. When doxycycline is withdrawn, N-myc expression is turned off and the cells differentiate into neurons and glia. An extensive characterization of the expanded cells revealed that the cells retained their differentiation potential, genomic stability and commitment specific to their origin. The tetracycline-inducible N-myc expressing mouse line might also serve as a source for establishing other than neural lineage committed progenitor cell lines where N-myc has a known role in regulating cell proliferation and differentiation decisions.

Neural Progenitor Cells

Doxycycline Inducibile Expression

N-MYC

Regenerative Medicine

0369

0307

0317

Generation and Characterization of Induced Neural Progenitor Cell Lines

DesaiI, Ridham

19 January 2012

Large-scale expansion of lineage-committed stem cells can provide an excellent ex vivo model for studying complex molecular pathways governing cell fate choices. Also, such cells could be useful for implementing cell therapeutic approaches for treatment of specific disorders involving extensive cellular damage within that lineage. Using growth factors, pluri- and multipotent stem cells have been successfully isolated and cultured from pre- and peri-implantation stage embryos, including trophectoderm, primitive ectoderm, epiblast and primitive endoderm. However, ex vivo expansion of lineage restricted cells from later embryonic lineages and adult tissues have been a challenge. N-myc is a well-characterized member of myc gene family that is known to be essential for the proliferation of numerous progenitor cell types during normal embryonic development of diverse organs including lungs, liver, heart, kidneys and brain. Considering this important role of N-myc, we hypothesized that its regulated activation in these progenitors might allow their expansion in culture. To test this hypothesis, we generated a novel doxycycline-inducible transgenic mouse line that expresses N-myc uniformly across all tissues. Using cortical precursors derived from mid-gestation embryos of these mice, we show that upon doxycycline induced N-myc expression, we can achieve at least a million-fold expansion of multipotent neural precursors within a short span of time in culture. When doxycycline is withdrawn, N-myc expression is turned off and the cells differentiate into neurons and glia. An extensive characterization of the expanded cells revealed that the cells retained their differentiation potential, genomic stability and commitment specific to their origin. The tetracycline-inducible N-myc expressing mouse line might also serve as a source for establishing other than neural lineage committed progenitor cell lines where N-myc has a known role in regulating cell proliferation and differentiation decisions.

Neural Progenitor Cells

Doxycycline Inducibile Expression

N-MYC

Regenerative Medicine

0369

0307

0317