Investigating the Role of Shroom3 in Kidney Development

Hunjan, Ashmeet

January 2021

Nephrons develop from a specialized group of mesenchyme cells known as the nephron progenitors. Nephron progenitors can very dynamic as they can self-renew, migrate, and change their cell morphology. These alterations are essential for orientating and organizing select cells for progression through various stages of nephrogenesis. However, the underlying mechanisms that drive these dynamic morphological changes are not fully understood. Shroom3 is an actin-binding protein that regulates cell shape changes by modulating the actin cytoskeleton. In mice and humans, mutations in Shroom3 are associated with poor nephron function and chronic kidney disease. Despite these findings, the underlying mechanisms of Shroom3 function and how genetic mutations contribute to abnormal nephron formation are unclear. Here, we investigated functional roles for Shroom3 in the nephron progenitor population by analyzing E13.5 and E18.5 Wildtype and Shroom3 deficient mice (termed Shroom3-/-). First, using in-situ hybridization (ISH) and immunofluorescence (IF), we confirm Shroom3 expression in select nephron progenitors. Next, we demonstrated abnormal cell shape and abnormal nephron progenitor cell clustering using H&E staining and Pax2 immunofluorescence. We showed a reduction in nephron progenitor cell numbers and decreased cell length in E13.5 Shroom3-/- kidneys. Using markers of cell orientation, we discovered altered cell orientation in some but not all nephron progenitor cells. While analyzing the cell cytoskeleton, we also demonstrated the abnormal distribution of F-actin in Shroom-/- nephron progenitors. Lastly, immunofluorescence and transmission electron microscopy analysis of Shroom3-/- nephron progenitors confirmed the abnormal shape and reduced filopodia-like thin actin-based membrane protrusions. Our findings conclude that Shroom3 is essential for maintaining and regulating nephron progenitor cell morphology. Taken together, these findings could help explain why Shroom3 mutations are highly associated with kidney disease. / Thesis / Master of Science in Medical Sciences (MSMS)

Kidney Development

Nephron formation

Shroom3

Nephron progenitor cells

Establishment of Methods for Isolation of Pnmt+ Cardiac Progenitor Cells

Varudkar, Namita

01 January 2014

Cardiovascular disease is the leading cause of death in the United States. Millions of patients suffer each year from endothelial dysfunction and/or debilitating myocardial damage resulting in decreased quality of life and increased risk of death or disablement. Current pharmacological approaches are only partly effective at treating cardiovascular disease, and hence, better strategies are needed to provide significant improvements in treatment options. Cardiac stem/progenitor cells have the potential to regenerate myocardial tissue and repair damaged heart muscle. There are many different types of cardiac progenitor cells, and each may have certain unique properties and characteristics that would likely be useful for particular clinical applications. A current challenge in the field is to identify, isolate, and test specific cardiac stem/progenitor cell populations for their ability to repair/regenerate myocardial tissue. Our laboratory has discovered a new type of cardiac progenitor cell that expresses the enzyme, Phenylethanolamine-n-methyltransferase (Pnmt). My initial studies focused on identification of Pnmt+ cells based on knock-in of a nuclear-localized Enhanced Green Fluorescent Protein (nEGFP) reporter gene into exon 1 of the Pnmt gene in a stable recombinant Pnmt-nEGFP mouse embryonic stem cell (mESC) line. These cells were differentiated into cardiomyocytes, and I identified nEGFP+ cells using fluorescence, immunofluorescence, and phase-contrast microscopy techniques. Our results showed that only about 0.025% ( 1 per 4000) of the cardiac-differentiating stem cells expressed the nEGFP+ marker. Because of the relative rarity of these cells, optimization of isolation methods proved initially challenging. To overcome this technical barrier, I used a surrogate cell culture system to establish the methods of isolation based on expression of either a fluorescent cell marker (EGFP), or a unique cell surface receptor represented by an inactivated (truncated) version of the human low-affinity nerve growth factor receptor (LNGFR). Plasmid DNA containing these reporter genes was transiently transfected into a permissive cell line (RS1), and reporter gene expression was used to identify and isolate transfected from non-transfected cells using either Fluorescence-Activated Cell Sorting (FACS) or Magnetic-Activated Cell Sorting (MACS) methods. The main objective of the study was to establish the isolation techniques based on the expression of reporter genes (EGFP and LNGFR) in RS1 cells. Following transfection, EGFP+ cells were successfully isolated via FACS as verified by flow cytometric and microscopic analyses, which showed that approximately 96% of the isolated cells were indeed EGFP+. Despite the relative purity of the isolated cell population, however, their viability in culture following FACS was substantially compromised ( 50% attrition). In contrast, MACS enabled efficient isolation of LNGFR+ cells, and the vast majority of these ( 90%) retained viability in culture following MACS. The LNGFR expression was verified using RT-PCR. Further, MACS methods enabled isolation of marked cells in about 5-7 mins, whereas it took 2-4 hours to using FACS to perform similar isolations from the same amount of starting material (10^6 cells). In addition, MACS is a more economical method in that it does not require the use of an expensive laser-based instrument to perform the sorting. These results suggest that MACS was a more efficient, gentle, and feasible technique than FACS for isolation of reporter-tagged mammalian cells. Consequently, future studies aimed at isolation of Pnmt+ cardiac progenitor cells will thus primarily focus on MACS methods.

Cardiac progenitor cells

stem cells

pnmt

Biotechnology

Molecular Biology

Role of Amyloid Precursor Protein in Neuroregeneration on an In Vitro Model in Alzheimer's Patient-Specific Cell Lines

Bedoya Martinez, Lina S

01 January 2019

Alzheimer's disease (AD) leads to neurodegeneration resulting in cognitive and physical impairments. AD is denoted by accumulation of intracellular neurofibrillary tangles, known as tau, and extracellular plaques of the amyloid beta protein (Aβ). Aβ results from the proteolytic cleavage of the amyloid precursor protein (APP) by β- and gamma-secretases in the amyloidogenic pathway. Although, Aβ has been widely studied for neurodegeneration, the role of APP in both, the healthy and diseased conditions, has not yet been entirely understood. The function that APP has in neural stem cell (NSC) proliferation, differentiation, and migration during adult neurogenesis has been previously studied. Additionally, APP has be shown to be overexpressed after neural damage resulted from conditions, such as AD and traumatic brain injury (TBI). In this study, the role of APP in in vitro damaged neural tissue cells was further investigated by evaluating neural progenitor cell proliferation, migration, and differentiation after a scratch assay. For these purposes, induced pluripotent stem (iPS) cells from AD patients were differentiated into neural progenitor cells to model the disease conditions and later treated with Phenserine to reduce their levels of APP expression. The results suggested that APP may enhance neural progenitor cell proliferation and glial differentiation while inhibiting neural progenitor cell migration and neuronal cell specialization after neural tissue damage.

Neural Stem Cells

Neural Progenitor Cells

iPSCs

Diseases

Neurology

Mesenchymal progenitor cells in adult marrow

Dennis, James Edmund

January 1995

No description available.

Biology, Cell

Bone marrow, adult

Progenitor cells

Mice, transgenic

Comparison of bone marrow mesenchymal stem cells and tendon progenitor cells cultured on collagen surfaces

Brown, James Augustus

26 May 2010

Tendon injuries are a significant cause of morbidity in performance horses with superficial digital flexor tendon injury reported to represent up to 43% of overall Thoroughbred racehorse injuries. Natural repair is slow and results in inferior structural organization and biomechanical properties and, therefore, reinjury is common. The inability of tendon to regenerate after injury, or to heal with mechanical properties comparable to the original tissue, is likely attributable to low vascularity and cellularity of the tissue, low number of resident progenitor cells, and healing under weight-bearing conditions. Strategies to improve tendon healing have focused on enhancing the metabolic response of tenocytes, modulating the organization of the newly synthesized extracellular matrix, or administering progenitor cells to enhance repair. Significant research effort has been directed at the use of adult mesenchymal stem cells as a source of progenitor cells for equine tendon repair and recent clinical applications have utilized adult autologous stem cells derived either from adipose tissue or bone marrow aspirates. Isolation of a homogenous population of stem cells from bone marrow is time-consuming, and there is much variation in cell numbers, cell viability and growth rates among samples. Recently, a population of progenitor cells has been isolated from equine flexor tendons, thus providing an alternative source of progenitor cells from the target tissue for therapeutic intervention. The interaction between cells and the extracellular matrix (ECM) is an important factor in regulation of cell function. Proliferation, migration, differentiation and gene expression of many cell types are altered by adhesion to and interaction with matrix proteins and the extracellular environment. Tendon progenitor cells reside within a niche that comprises primarily parallel collagen fibers, and this niche plays an important role in regulating their function and differentiation. Culture conditions replicating this environment could be beneficial for both cell growth and matrix gene expression. The objectives of the study were to compare cell growth kinetics and biosynthetic capabilities of bone marrow mesenchymal stem cells (BMMSCs) and tendon derived progenitor cells (TPCs) cultured on commercially available bovine, highly purified bovine, porcine, and rattus collagen sources and standard tissue culture surfaces. We hypothesized that collagen type I matrix would preferentially support TPC proliferation and up regulate gene expression for collagens and organizational components of tendon and therefore provide a culture system and progenitor cell type with advantages over the current practice of BMMSC expansion on standard cell culture plastic surfaces. Cells were isolated from 6 young adult horses, expanded, and cultured on collagen-coated tissue culture plates, and no collagen control for 7 days. Samples were analyzed for cell number on days 4 and 7, and for mRNA expression of collagen type I, collagen type III, cartilage oligomeric matrix protein (COMP), and decorin on day 7. Glycosaminoglycan (GAG) synthesis was analyzed on day 7. Differences of cell number between collagen groups and cell type, and in gene expression and GAG synthesis between collagen groups and cell types, were evaluated by use of mixed-model repeated measures ANOVA. Pair-wise comparisons were made on significant differences identified with ANOVA using Tukey's post hoc test. Statistical significance was set at P<0.05. A statistical significant (P=0.05) increase in cell number for TPCs grown on rattus collagen versus control on day 4 was observed. No difference in GAG synthesis or expression of collagen type I, collagen type III, COMP or decorin mRNA was observed between collagen groups and non-collagen controls for either cell type on day 7. TPCs cultured on all collagen types yielded more cells than similarly cultured BMMSCs on day 4, but only porcine collagen was superior on day 7. TPCs synthesized more GAG than BMMSCs when cultured on control surfaces only. BMMSCs expressed more collagen type I mRNA when cultured on control, porcine and highly-purified collagen, and more collagen type III when cultured on control, porcine, highly-purified collagen, and rattus collagen, than TPCs. Tendon-progenitor cells expressed significantly more COMP when cultured on control and all collagen types, and decorin when cultured on porcine, highly purified bovine and bovine collagen when compared to BMMSCs. The results of this study revealed an advantage to culturing TPCs on randomly organized rattus collagen during the early growth phase. The beneficial effects of collagen-coated surfaces on cell proliferation is likely related to increased surface area for attachment and expansion provided by the random collagen matrix, and/or collagen-cell interactions. Tendon progenitor cells showed superior growth kinetics and expression of the matrix organizational components, COMP and decorin, than similarly cultured BMMSCs that expressed more collagen types III and I. TPCs synthesize more GAG compared to BMMSCs when cultured on plastic surfaces and there was no induction by collagen. Tendon progenitor cells should be considered as an alternative source of progenitor cells for injured equine tendons. Further in vitro studies characterizing factors that influence gene expression of both cell types is warranted. / Master of Science

tendon progenitor cells

collagen

Bone marrow mesenchymal stem cells

Horses

Role of Stromal Cell-Derived Factor-1 in Neoangiogenesis in Endometriosis Lesions

VIRANI, SOPHIA

22 December 2011

Endometriosis affects 5-10% of women and is characterized by the growth of endometrial tissue outside of the uterus. Treatment for endometriosis primarily focuses on symptom relief, is short term with severe side effects and often leads to recurrence of the condition. Establishing new blood supply is a fundamental requirement for endometriosis lesions growth. This has led to the idea that antiangiogenic therapy may be a successful approach for inhibiting endometriosis. Recent evidence indicates that endothelial progenitor cells (EPCs) contribute to neoangiogenesis of endometriotic lesions. These EPCs are recruited to the lesion site by stromal cell-derived factor-1 (SDF-1). We hypothesize that SDF-1 is central to the neoangiogenesis and survival of endometriotic lesions and that administration of SDF-1 blocking antibody will inhibit lesion growth by inhibiting angiogenesis in a murine model of endometriosis. Immunohistochemistry for SDF-1 and CD34 was performed on human endometriosis and normal endometrial samples. Quantification of SDF-1 and EPCs was performed in the blood of endometriosis patients and controls using ELISA and flow cytometry, respectively. A new mouse model of endometriosis was developed using BALB/c-Rag2-/-/IL2rg-/- mice to investigate role of SDF-1 in neoangiogenesis. Either SDF-1 blocking antibody or an isotype control was administered on a weekly basis for four weeks. Weekly samples of peripheral blood from mice were analyzed for SDF-1, other cytokines of interest and EPCs. Mice were euthanized at seven weeks to observe lesion growth and blood vessel development. Our results indicate overabundance of SDF-1 and CD34+ progenitor cells in human endometriotic lesions compared to eutopic endometrium. In the mouse model, SDF-1 and circulating EPC levels decreased from pre-treatment levels after one week, and remained constant over the course of the treatment in both SDF-1 blocking antibody and isotype control groups. In the SDF-1 blocking group, reduced vascularity of lesions, identified by immunofluorescence staining for CD31, was revealed compared to isotype controls. These findings suggest that SDF-1 may be responsible for CD34+ progenitor cell recruitment to the neoangiogenic sites in endometriosis. Blocking of SDF-1 reduces neovascularization of human endometriotic lesions in a mouse model. Further studies on blocking SDF-1 in combination with other antiangiogenic agents are needed. / Thesis (Master, Anatomy & Cell Biology) -- Queen's University, 2011-12-21 19:34:43.054

endothelial progenitor cells

EPCs

endometriosis

endometrium

mouse model of endometriosis

stromal cell-derived factor-1

cEPCs

circulating endothelial progenitor cells

SDF-1

angiogenesis

Human and mouse meniscus progenitor cells and their role in meniscus tissue regeneration

Muhammad, Hayat

07 May 2014

Osteoarthritis (OA) ist eine degenerative Erkrankung des hyalinen Knorpels. Knorpel ist ein avaskuläres Gewebe. Wenn dieser beschädigt wird, ist es schwierig, ihn zu reparieren. Der Gelenkknorpel ist verantwortlich für die glatte, reibungs- und schmerzlose Bewegung des Kniegelenks. Schwere Verluste oder die komplette Zerstörung des Gelenkknorpels führen zu hoher Reibung und Schmerzen bei der Bewegung des Kniegelenks, wie es oft in den späten Stadien der OA der Fall ist. Der komplette Gelenkersatz bleibt die ultimative Lösung. Jedoch gibt es viele andere Möglichkeitenden Knorpel über die Implantation von Stammzellen zu reparieren oder zu regenerieren, jedoch oft mit schwerwiegenden Folgen. Die Transplantation embryonaler Stammzellen kann beispielsweise zu Teratombildung führen. Die Nutzung von induzierten pluripotenten Stammzellen ermöglicht die Virusintegration in das Genom. Alternativ entstand das Konzept der Vorläufer- oder Reparaturzellen in situ. Beispielsweise fand man in späten Stadien der Osteoarthritis im menschlichen Knorpel chondrogene Vorläuferzellen mit migratorischen Fähigkeiten (CPCs). Bei Knorpelregeneration mit diesen Zellen sind bisher keine Risokofaktoren bekannt. Sie haben eine enorme Fähigkeit für die Knorpelreparatur ohne das schwerwiegende Risikofaktoren bisher bekannt waren. Allerdings bestehen noch Fragen zum Beispiel wie man CPCs in situ induziert, um das Gewebe auf physiologische Weise zu reparieren. Zweitens haben CPCs eine begrenzte Lebensdauer, zumindest in vitro. Darüber hinaus gibt es keine verfügbare optimierte Methode, um eine vollständige chondrogene Differenzierung von Stammzellen zu erreichen. Vor kurzem wurden primäre Zilien gefunden, die hilfreich für die Stammzelldifferenzierung sein könnten. Diese Zilien arbeiten als Dual-Sensor für mechanochemische Signale. Dieser Sensor wurde auch auf CPCs gefunden, bei Chondrozyten gewonnen aus Kiefergelenken (TMJ) von Discoidin-Domänen- Rezeptor-1- Knockout- Mäusen (DDR- 1 KO). OA ist nicht nur auf die großen Gelenke beschränkt, sondern wirkt sich auch auf die kleinen Gelenke wie das Kiefergelenk aus. Es ist gut bekannt, dass Chondrozyten im Gelenkknorpel keinen direkten Zell-zu-Zell-Kontakt besitzen vielmehr beruht die Kommunikation auf Zell-Matrix - Wechselwirkungen über Zellrezeptoren z.B Integrine oder DDRs. DDR -1- KO-Mäuse zeigen typische Symptome der Arthrose des Kiefergelenkknorpels. Die aus dem Kiefergelenknorpel der DDR - 1 KO Mäuse abgeleiteten Chondrozyten behielten ihre Arthroseeigenschaften. Einerseits wiesen sie eine hohe Expression von runx2 und Kollagen Typ I als typische osteogene Signaturen auf sowie andererseits eine geringe Expression von sox9, Kollagen Typ II und Aggrecan, welche relevant für die chondrogene Differenzierung sind. Die osteoarthritischen Charakteristika könnten zu einem normalen Chondrozyten- Typ umgekehrt werden über den Knockdown von runx2 oder der Exposition dieser Zellen in einer dreidimensionalen Umgebung und in Gegenwart von extrazellulärer Matrix (ECM) -Komponenten wie Laminin und Nidogen. Die Umkehr in Richtung des chondrogenen Phänotyps ist auch für die Pathogenese der Meniskusdegeneration von großer Bedeutung. Der Meniskus ist in den meisten Fällen der Ausgangspunkt für die Entwicklung von OA des Kniegelenks. Der Meniskus ist ein Bindegewebsknorpel, der als Stoßdämpfer wirkt. Hierbei verschlimmert eine Menikusschädigung die OA Pathogenese durch verstärkten Knorpelabbau. Der innere Teil des Meniskus ist avaskulärer Natur und hat eine sehr begrenzte Eigenreparaturfähigkeit. Es gibt jedoch andere Möglichkeiten, wie die teilweise Entfernung des Meniskus, die zu einer kurzfristigen Entlastung führt. Dies verhindert jedoch nicht die langfristigen Folgen, die letztlich zur Entwicklung von OA führen. Der innere Teil des menschlichen Meniskus birgt einzigartige Vorläuferzellen (MPC) und kann zur Meniskus-Regeneration über den TGFß -Signalweg aktiviert werden. Darüber hinaus wurden Maus-Meniskus-Progenitorzellen (MMPCs) in gesundem Meniskusgewebe untersucht. Diese Zellen wurden mittels immunohistochemischen Techniken ex vivo charakterisiert und behielten ihre Stammzelleigenschaften auch in vitro. Mit der Anwendung verschiedener Stammzellen zur Therapie der Knorpelregeneration sind viele kritische Konsequenzen assoziiert. Im Fokus standen deshalb gewebespezifische Zellen auch in situ Vorläuferzellen genannt, die bereits in erkranktem Knorpel vorhanden sind. Diese Zellen können sich in chondrogener Richtung entwickeln. Hierfür benötigen sie möglicherweise nur geringe Manipulationen, um daraufhin hyalinen Knorpel zu produzieren.

570

Biologie (PPN619462639)

The Protective Effects of miR-210 Modified Endothelial Progenitor Cells Released Exosomes in Hypoxia/Reoxygenation Injured Neurons

Yerrapragada, Sri Meghana

27 August 2021

No description available.

Biomedical Research

Pharmaceuticals

Pharmacology

Toxicology

Science Education

Medicine

Endothelial progenitor cells

miRNA

microRNA-210

Exosomes

Hypoxia

neurons

Endothelial progenitor cells

oxidative stress

hypoxia and reoxygenation injury

Dichotomy effects of Akt signaling in breast cancer

Peng, Zhengang, Weber, Jennifer, Han, Zhaosheng, Shen, Rulong, Zhou, Wenchao, Scott, James, Chan, Michael, Lin, Huey-Jen

January 2012

BACKGROUND:The oncogenic roles contributed by the Akt/PKB kinase family remain controversial and presumably depend on cell context, but are perceived to be modulated by an interplay and net balance between various isoforms. This study is intended to decipher whether distinct Akt kinase isoforms exert either redundant or unique functions in regulating neoplastic features of breast cancer cells, including epithelial-mesenchymal transition (EMT), cell motility, and stem/progenitor cell expansion.RESULTS:We demonstrate that overactivation of Akt signaling in nonmalignant MCF10A cells and in primary cultures of normal human mammary epithelial tissue results in previously unreported inhibitory effects on EMT, cell motility and stem/progenitor cell expansion. Importantly, this effect is largely redundant and independent of Akt isoform types. However, using a series of isogenic cell lines derived from MCF-10A cells but exhibiting varying stages of progressive tumorigenesis, we observe that this inhibition of neoplastic behavior can be reversed in epithelial cells that have advanced to a highly malignant state. In contrast to the tumor suppressive properties of Akt, activated Akt signaling in MCF10A cells can rescue cell viability upon treatment with cytotoxic agents. This feature is regarded as tumor-promoting.CONCLUSION:We demonstrate that Akt signaling conveys novel dichotomy effects in which its oncogenic properties contributes mainly to sustaining cell viability, as opposed to the its tumor suppressing effects, which are mediated by repressing EMT, cell motility, and stem/progenitor cell expansion. While the former exerts a tumor-enhancing effect, the latter merely acts as a safeguard by restraining epithelial cells at the primary sites until metastatic spread can be moved forward, a process that is presumably dictated by the permissive tumor microenvironment or additional oncogenic insults.

Activated Akt signaling

Breast epithelia

Epithelial-mesenchymal transition

Motility

Stem-progenitor cells

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