Late complications of haemopoietic stem cell transplantation

Szeto, Ching-ho., 司徒精豪.

January 2004

published_or_final_version / Medical Sciences / Master / Master of Medical Sciences

Analysis of parameters that determine the acquisition of pluripotency in vitro

Barrandon, Ornella

January 2011

No description available.

572

Cytology ; Stem cells

Human neuroepithelial stem cells from the embryonic hindbrain

Tailor, Jignesh Kishor

January 2013

No description available.

572

Rhombencephalon ; Stem cells

Early molecular events conferring haematopoietic potential to human pluripotent stem cells

Jayasundar, Smruthi

January 2013

No description available.

617

Hematopoiesis ; Stem cells

Human mesenchymal stem cells express a myofibroblastic phenotype in vitro

Ngo, Melanie Allison

10 January 2012

There is emerging evidence to suggest that cardiac myofibroblasts (CMyfbs) participating in cardiac fibrosis represent a heterogeneous population in origin. We hypothesized that bone marrow derived mesenchymal stem cells (MSCs) readily adopt a myofibroblastic phenotype in culture. We assessed and compared human primary MSCs and human CMyfbs with respect to their phenotypic and functional characteristics by examining their gene expression profile, ability to contract collagen gels, and ability to synthesize collagen. We also examined the role of non-muscle myosin II (NMMII) in modulating the myofibroblast function using siRNA and blebbistatin to inhibit NMMII activity. The data revealed that MSCs adopt a myofibroblastic phenotype in culture and demonstrate the capability to contract collagen gels and synthesize collagen similar to human CMyfbs. Inhibition of NMMII activity with blebbistatin completely inhibits gel contractility without affecting cell viability. Thus, MSCs exhibit similar physiological and functional characteristics as CMyfbs, and may contribute to cardiac fibrosis.

mesenchymal stem cells

myofibroblasts

To characterise the role of RTEL1 DNA helicase in the maintenance of intestinal stem/progenitor cells

Seshadri, Nivedita

05 February 2015

RTEL1 (Regulator of telomere length1) DNA helicase has been demonstrated to be vital for the maintenance of telomere length and genomic stability. However, its biological role during development is unknown. Our recent finding that RTEL1 is selectively expressed in several types of adult stem cells, suggests that RTEL1 could play an essential role in the maintenance of these cells. Depending on the function of RTEL1 in the maintenance of genomic stability, we hypothesize that RTEL1 could be required for protecting adult stem cells from genomic instability, whose dysfunction may not only impair tissue homeostasis/regeneration, but also could transform these cells to form tumors. In this study, we have used mouse intestinal stem/progenitor cells model to address this hypothesis. With a transgenic lineage tracing assay, we demonstrated that RTEL1-expressing cells in intestinal crypts can self renew and differentiate to the progeny cells required for intestinal homeostasis. Using a conditional knockout approach, we also showed that loss of RTEL1 function could induce genomic instability in intestinal stem/progenitor cells, which significantly affected the survival of intestinal stem cells and intestinal regeneration. Finally, in this study, we also observed intestinal hyperplasia in our RTEL1 conditional knockout mice, indicating that loss of RTEL1 function may initiate intestinal tumorigenesis. All of these findings strongly support that RTEL1 could be one the key molecules necessary for the maintenance of intestinal stem/progenitor cells and this function could be important for preventing intestinal tumorigenesis.

intestinal stem cells

RTEL1

Human mesenchymal stem cells express a myofibroblastic phenotype in vitro

Ngo, Melanie Allison

10 January 2012

There is emerging evidence to suggest that cardiac myofibroblasts (CMyfbs) participating in cardiac fibrosis represent a heterogeneous population in origin. We hypothesized that bone marrow derived mesenchymal stem cells (MSCs) readily adopt a myofibroblastic phenotype in culture. We assessed and compared human primary MSCs and human CMyfbs with respect to their phenotypic and functional characteristics by examining their gene expression profile, ability to contract collagen gels, and ability to synthesize collagen. We also examined the role of non-muscle myosin II (NMMII) in modulating the myofibroblast function using siRNA and blebbistatin to inhibit NMMII activity. The data revealed that MSCs adopt a myofibroblastic phenotype in culture and demonstrate the capability to contract collagen gels and synthesize collagen similar to human CMyfbs. Inhibition of NMMII activity with blebbistatin completely inhibits gel contractility without affecting cell viability. Thus, MSCs exhibit similar physiological and functional characteristics as CMyfbs, and may contribute to cardiac fibrosis.

mesenchymal stem cells

myofibroblasts

Granulocyte colony-stimulating factor : structure-function studies

Somerville, Linda Elizabeth

January 1998

No description available.

572.8

Haematopoiesis; Stem cells

A Self-renewing Multi-potent Population of Cells and their Progeny Maintain Homeostasis of the Mesenchymal Compartment

Sarugaser, Rahul

01 August 2008

Recent evidence suggests that “mesenchymal stem cells” (MSCs) are resident in the perivascular compartment of connective tissues. However, since the definition of a stem cell assumes that these progenitors have clonal self-renewal and multi-lineage differentiation potential, the term “MSC” has been criticised, as it has been impossible to isolate definitive clonally derived “MSCs.” To test for this most basic definition of a stem cell, here it is shown that human umbilical cord perivascular cells (HUCPVCs) are capable of multilineage differentiation in vitro and, more importantly, in vivo, displaying the ability to differentiate into functionally synthetic cells that direct and contribute to rapid connective tissue healing by producing bone, cartilage and fibrous stroma in a mouse injury model. Uniquely, these cells can be enriched to >1:3 clonogenic frequency in early passage culture, making it possible to isolate clones and daughter sub-clones from mixed gender suspensions, determined to be definitively single-cell-derived by Y-chromosome fluorescent in situ hybridization (FISH) analysis. Each clone was assayed for multi-lineage differentiation capacity into the five mesenchymal lineages: myogenic, adipogenic, chondrogenic, osteogenic and fibroblastic (stroma). The observation that daughter sub-clones possess equal or lesser differentiative potential to their respective parent clones demonstrated the two intrinsic properties of stem cells in vitro: clonal self-renewal and multi-lineage differentiation. This evidence provides a new hierarchical structure of robust MSCs self-renewing to produce more restricted progenitors that gradually lose differentiation potential until a state of complete restriction to the fibroblast is reached. The methods described herein combined with recognition of this lineage hierarchy provides a significant advance to the understanding of MSC biology, and will enable interrogation of the properties of robust self-renewal and differentiation of MSCs in serially transplanted living recipients.

Mesenchymal

Stem Cells

0541

???Stem Cell Pathway??? gene expression in human foetal limbus and cadaveric human limbal epithelium

Figueira, Edwin C, Medical Sciences, Faculty of Medicine, UNSW

January 2006

Stem cells play a vital role in the turn over of permanently self-renewing tissues (e.g. corneal epithelium, epidermis, bone marrow). Stratified cornea epithelia serve, as ideal tissue models for studying ???stemness???, as the site of cells in the different stages of differentiation are anatomically easily identifiable. Studies targeting limbal stem cell maintenance, in-vitro gene expression during storage and differentiation will benefit future therapeutic applications (e.g. corneal transplantation). Knowledge of stem cell behaviour will help explain the pathophysiology of corneal related ocular surface disorders (e.g. idiopathic limbal stem cell deficiency, pterygium and limbal dermoids), establish new treatment modalities (e.g. allogenic cellular transplants) and help promote invivo expansion of residual stem cell populations in deficiency states. The major obstacle in the progress of research on limbal stem cells is the lack of knowledge of phenotypic markers of limbal epithelial stem cells. This project first studied the limbal expression of phenotypic markers that were discovered in other human adult and embryonic stem cell populations using microarray differential expression studies. Gene expression profiles of the relatively primitive human foetal limbus were compared with that of the central cornea. Microarray was also performed to identify the differential gene expression profile of cultured primary human limbal epithelial cells, when compared to the limbal epithelial cell population isolated after 5 serial cultures. 33 genes were upregulated in the human foetal limbus and primary cultured human limbal epithelium, when compared respectively to the central foetal cornea (first experiment) and the limbal epithelial cell population after the 5th trypsin passaged culture (second experiment). Four foetal limbal and primary limbal epithelial upregulated genes (CK15, CK14, Cdh3, and Wnt4) were confirmed to be upregulated by semi quantitative RT-PCR and immunohistochemical experiments on the human foetal cornea, adult human cadaveric cornea and cultured human limbal epithelial cells. The microarray defined phenotypic profile of both the foetal limbus and cultured adult limbal epithelial cells will help identify these cells in in-vitro and in-vivo states. The expression of these 4 selected markers in the limbal dermoid and pterygium suggests that limbal epithelial cells containing a stem cell population are involved in the pathogenesis of these two disorders.

Stem cells -- Research

Genetics