Genomic instability may be a signal of human embryonic stem cell differentiation

Esteban-Perez, Clara Ines

30 April 2011

Embryonic stem (ES) cells have the ability to maintain pluripotency and self-renewal during in vitro maintenance, which is a key to their clinical applications. ES cells are a model in developmental biology studies due to their potential to differentiate in vitro. Understanding critical pathways of pluripotency, self-renewal, and differentiation during early embryonic development is important for the evaluation of the therapeutic potential of ES cells because of their ability for tumor transformation due to genetic and epigenetic instability acquired during in vitro culture maintenance. Single tandem repeats are sequences of DNA that have been implicated in the deregulation of gene expression in different human conditions. Understanding the origin of repetitive sequence instability and functions in the genome allow characterization of early genomic instability signals in ES cell pluripotency, differentiation, and tumor transformation pathways. The hypothesis of this study was that genetic stability, in repetitive sequences, located near embryonic developmental genes is responsible for pluripotency, self-renewal, differentiation, and chromatin assembly and could be a signal for adaptation, differentiation, or transformation of ES cells in vitro. Our result showed instability in specific repetitive sequences which increased during ES cell passages and embryoid body differentiation in vitro. ES cells displayed significant mean frequencies of genomic instability in repetitive regions that lead to ES cells pluripotency, self-renewal maintenance, or cell lineage specialization. The present study reports potentially biomarkers for identifying accumulation of genomic instability in specific genes that may contributes to adaptation of ES cells and could be the switch that initiates early ES cell lineage commitment in vitro. Determining genetic and epigenetic modifications, including single tandem repeat instability, gene expression changes, and chromatin modifications, is essential for elucidating possible molecular mechanisms of genomic instability and determining novel molecular characterization for diagnostic purposes to ensure ES cell stability and integrity that could potentially lead to use of ES cell derivatives that could then be a safe source needed for regenerative medicine applications

genomic instability

cell lineage commitment

cell differentiation

pluripotency

Embryonic stem cell

repetitive sequences

tumor transformation

Netrin-1 function in somatic cell reprogramming and pluripotency / Fonction de la Nétrine-1 dans la reprogrammation cellulaire et la pluripotence

Ozmadenci, Duygu

24 November 2017

La pluripotence est la capacité d'une cellule à s'auto-renouveler et à donner toutes les cellules somatiques ainsi que les cellules germinales. Les cellules pluripotentes peuvent être aussi reprogrammées à partir de cellules somatiques, ouvrant ainsi de nouvelles opportunités pour l'utilisation thérapeutique des cellules souches dans le traitement des maladies dégénératives. La connaissance des mécanismes moléculaires, en particulier des voix de signalisation qui contrôlent la pluripotence, est cruciale pour l'amélioration de notre compréhension de l'embryogenèse précoce et l'utilisation des iPSC (cellules souches pluripotentes induites) dans la médicine régénérative. Ici, je donne la première description de la Nétrine-1 en tant que régulateur de la reprogrammation et de la pluripotence. La Nétrine-1 et ses récepteurs ont été initialement caractérisés dans le système neuronal, mais il a aussi été montré qu'ils étaient exprimés dans différents types cellulaires et impliqués dans divers processus. Dans la première partie, j'ai contribué à explorer comment Nétrine-1 empêche l'apoptose médiée par son récepteur à dépendance DCC (Deleted in Colon Carcinoma) pendant la reprogrammation. Dans la deuxième partie, j'ai disséqué les fonctions et la régulation de cette voie dans le maintien de la pluripotence et dans l'engagement des lignages / Pluripotency is the ability of embryonic epiblast cells to self-renew and to give rise to all somatic cells as well as germ cells. Somatic cells can also be reprogrammed toward pluripotency, opening new avenues for stem cell based therapies in the treatment of degenerative diseases. Deciphering the molecular mechanisms, and in particular signaling pathways that control pluripotency is crucial to improve our understanding of early embryogenesis and the use of iPSC (inducible Pluripotent Stem Cell) in regenerative medicine.Herein, I provide the first description of Netrin-1 as a regulator of reprogramming and pluripotency. Netrin-1 and its receptors are present in many cell types and are engaged in a variety of cellular processes beyond its initial characterization in the neuronal system. In the first part, I contributed to explore how Netrin-1 prevents apoptosis mediated by its dependence receptor DCC (Deleted in Colon Carcinoma) during reprogramming. In the second part, I dissected the functions and regulation of this pathway in pluripotency maintenance and in lineage commitment

Pluripotence

Reprogrammation

Engagement des lignages

Nétrine-1

Récepteur à Dépendance

Pluripotency

Reprogramming

Lineage commitment

Netrin-1

Dependence Receptor

572.8

The effect of phosphate deficiency on BMP-2 treated C3H10T1/2 mesenchymal stem cells

Bui, Matthew

03 July 2018

There are approximately 600,000 cases of delayed or aberrant fracture healing in people each year, with a small subset of these fractures experiencing disunion. Dietary phosphate deficiency has been shown to impair oxidative phosphorylation and decrease BMP-2 mediated chondrogenic differentiation during fracture healing. Prior studies using pre-committed chondro-progenitor ATDC5 cell line grown in phosphate deficient media showed that energy consumption was linked to protein production and collagen hydroxylation but inversely related to matrix mineralization. The goal of this study was to further define the relationship between energy consumption and BMP-2 mediated stem cell chondrogenic differentiation and further examine how dietary phosphate, and promotion of collagen hydroxylation via ascorbate availability effected these processes. C3H10T1/2 murine cells, a multi-potential cell line, were expanded in pre-differentiation growth medium (DMEM with 10% FBS and 1% Pen/Strep). Once cells reached 60% confluence (day 0), they were grown in differentiating media (α-MEM with 5% FBS and 1X insulin-transferrin-selenium) containing either 100% (1mM) or 25% (0.25mM) inorganic phosphate (Pi), ± 200ng/mL BMP-2(BMP), and ±0.2 mM L-ascorbic acid (AA). In total, there were 8 groups with varying combinations of these three substances. Intracellular lipid, total DNA, protein, and hydroxyproline (HP) content were examined. Chondrocyte gene expression (Col2a1, Acan, ColXa1) and adipocyte gene expression (Pparg, Plin1, Ucp1) were measured to check for cell lineage commitment and specific differentiation of the C3H10T1/2. All measurements were acquired at day 8. The +BMP differentiation media groups contained significantly less DNA content and more protein content than the –BMP differentiation media groups (both p<0.0001). There was also a significant interaction between phosphate and ascorbic acid treatment (p=0.0296), with 25% Pi +AA groups producing significantly more protein than 100% Pi +AA groups. Hydroxyproline production was not different in 100% Pi or 25% Pi conditions (p=0.2951). AA presence in culture media led to greater HP production than culture media lacking AA (p=0.0035) There was a trend of an interaction between phosphate content and AA availability (p=0.0744). 100% Pi ±AA groups produced significantly different amounts of HP while 25% Pi ±AA groups did not produce significantly different amount of HP. Col2a1, Acan, and ColXa1 expression were all increased in +BMP groups. Ascorbic acid treatment groups expressed significantly more Col2a1and Acan than –AA groups. 100% Pi media led to greater Acan expression over 25% Pi groups (p=0.0009), whereas 25% Pi media trended to lead to greater ColXa1 expression over 100% Pi groups (p=0.0734). Pparg and Plin1 expression were increased in the 25% Pi condition. There were no significant differences in expression of Ucp1. C3H10T1/2 cells were significantly affected by phosphate concentration, BMP-2 treatment, and ascorbic acid supplementation. Phosphate deficiency hindered maturation of early chondrocytes into proliferating chondrocytes while also promoting MSC differentiation into the adipocyte cell lineage. Hypertrophic chondrocyte expression was decreased in phosphate deficient media, which may coincide with increased protein production observed in low phosphate conditions. BMP-2 promoted chondrogenesis which resulted in increased protein production. Whereas, lack of ascorbic acid in cell culture media led to decreased hydroxyproline production.

Medicine

Bone development

Bone morphogenetic protein 2

Cell differentiation

Cell lineage commitment

Fracture healing

Mesenchymal stem cell

The emergence and early fate decisions of stem and progenitor cells in the haematopoietic system

Lutteropp, Michael

January 2012

The alternative road map describes the separation of lympho-myeloid and myeloid-megakaryocyte-erythroid (myeloid-Mk-E) lineages as the earliest haematopoietic commitment event. However, a number of aspects of this lineage restriction process remain poorly understood. Herein this work identified a lympho-myeloid restricted progenitor in the embryo, which resembles the adult LMPP, and demonstrated that lymphoid lineage restriction is initiated prior to definitive haematopoiesis, much earlier than previously appreciated. In vivo fate mapping showed that lympho-myeloid progenitors significantly contribute to steady state myelopoiesis in the embryo. The early thymic progenitor (ETP) as most primitive cell in the thymus was characterised and demonstrated to sustain B, T and myeloid but not Mk potentials at the single cell level. The ETP therefore largely resembles the cellular properties of lympho-myeloid progenitors in bone marrow and foetal liver, which points to these cells as candidate thymus seeding progenitors (TSP). Furthermore the existence of a putative Mk progenitor was explored within the LSKCD150⁺CD48⁺Gata1^pos compartment of a Gata1 reporter mouse providing the basis for a future prospective characterisation. Finally, this work evaluated the earliest lineage restriction of von Willebrand factor (Vwf)-EGFP⁺ and EGFP^- haematopoietic stem cells (HSCs) through in vitro paired daughter fate mapping. Single Vwf⁺ HSCs showed heterogeneous Mk priming and more frequently sustained Mk potential after cell division. Moreover, analysis of lineage priming between daughter cells revealed the asymmetric expression of key lineage determinants and stem cell regulators, which might be employed as reporters for future fate mapping studies.

616.02774

Toward Clinical Stem Cell Sourcing And Definition Of Prescriptive Biophysical Protocols To Guide Stem Cell Fate During Healing

Chang, Hana

23 August 2013

No description available.

Biomedical Research

Biomedical Engineering

Biomechanics

Cellular Biology

Developmental Biology

Engineering

Mechanical Engineering

Medicine

Molecular Biology

Scientific Imaging

periosteum

stem cell

tissue engineering

stem cell

mechanics

mechanoadaptation

emergence

fate

lineage commitment

model

cell perfusion

mechanome