An analysis of CD2 expression and the use of CD2 sequences for thymus directed oncogenesis

Greenberg, David

January 1991

No description available.

572.8

Thymic tumours

Direct analysis of stem cells and their entry to the thymus

Johns, Michael

January 2001

No description available.

616

Thymic endothelium

Receptors and signal transduction pathways that regulate thymocyte development

O'Shea, Clodagh Catherine

January 1997

No description available.

610

Thymic ontogeny

Differentiation in the thymus

Paterson, D. J.

January 1986

No description available.

611

Thymic differentiation

Interactions between the immune system, stress and thymulin

Christian, Richard L., (Richard Leroy), 1971-

04 March 1997

This study was conducted to determine the effects of shipping stress on the immune system in domestic lambs (Ovis aries) and to determine the potential of the thymic peptide, thymulin, to reduce those effects of stress on the immune system. Treatments consisted of no shipping (as unstressed controls), shipping (as stressed controls) or shipping plus two doses of thymulin. The shipping procedure was conducted for two consecutive days. The responses were measured in three ways. First, the ability of peripheral blood mononuclear cells (PBMN) to respond to four different doses of the mitogen, Interleukin-2 (IL-2), was measured. Second, antibody response to a standard antigen dose over a three week period following the stress was examined. Third, the plasma cortisol concentrations in stressed versus unstressed and in thymulin treated lambs were compared. There were no differences between any of the four treatment groups (p>0.44) with respect to the animals' lymphocyte proliferative ability. Although there were no detectable differences, caution should be used in interpreting these results, because of technical difficulties encountered with a key reagent in the assay. Antibody titers were measured at weekly intervals for each of three consecutive weeks following the stressing procedure. These results also showed no treatment effect between any of the four groups (p>0.39). A comparison of cortisol levels in the four groups revealed that shipping stress increased plasma cortisol concentrations, and thymulin treatment at either dose and on both days of shipment inhibited (p<0.0001 and p<0.047, for day one and two, respectively) that stress-induced increase in cortisol. Interestingly, these results indicate that treatment with thymulin was effective in negating the stress-associated increase in plasma cortisol levels in the lambs. These in vivo data support a possible immunomodulatory function of thymulin. / Graduation date: 1997

Thymic hormones -- Immunology

Proliferation and lineage potential in fetal thymic epithelial progenitor cells

Cook, Alistair Martin

January 2010

The thymic stroma primarily comprises epithelial, mesenchymal and endothelial cells, interspersed with those of haematopoietic origin. Thymic epithelial cells (TECs) are highly heterogeneous, but can be divided into two broad lineages, cortical and medullary, based on phenotype, functionality and location. A population of Plet1+ TEC progenitors have been identified which, when isolated from mouse E12.5 or E15.5 fetal thymus, reaggregated, and grafted, can produce a functional thymus. However, the potential of individual progenitors to form cortex and/or medulla is undefined. The main aim of this thesis was to use retrospective clonal analysis to ascertain the point during thymus ontogeny at which the cortical and medullary lineages diverge. To this end, I used transgenic mice carrying a ubiquitous ROSA26laacZ reporter gene (where a duplication within lacZ encodes non-functional b-galactosidase). Here, rare, random laacZ-lacZ genetic recombinations result in heritable expression of functional b-gal, producing labelled clones. As this occurs at a known frequency, determination of TEC numbers would enable calculation of the expected number of TEC clones present throughout ontogeny. Due to the lack of quantitative data on all thymic cell populations, I determined the size not only of TEC (lin-EpCAM+), but also haematopoietic (CD45+), mesenchymal (lin-PDGFRa+ and/or lin-PDGFRb+) and endothelial (lin-CD31+) populations from E12.5 until E17.5. I then showed that the absolute number of Plet1+ TECs remains constant during this time, although the proportion of Plet1+ cells in cycle decreases. From these collective data, I propose a model for the role of the Plet1+ population in thymus development, in which Plet1+ cells continually give rise to Plet1- TECs in a self-renewing manner. Finally, I present a ‘dual origin coefficient’ strategy for analysis of a library of prospective TEC clones. I calculated the number of TEC lacZ+ clones expected to be present throughout thymus ontogeny, selecting an appropriate developmental stage for analysis. Although I observed several clones of apparent mesenchymal origin, supporting a single origin for intrathymic and capsular mesenchyme at E15.5, I observed no TEC clones in this extensive analysis. The CpG content of the ROSA26 promoter suggests a possibility of methylation-induced silencing brought about by de novo methylation of the lacZ reporter gene.

571.96

Functional analysis of the CD8β polypeptide and its role in T cell differentiation

McNeill, Louise

January 1999

No description available.

572.8

Prevention and reversal of thymus involution mediated by the transcription factor Foxn1

Bredenkamp, Nicholas

January 2011

Central to the age-associated decrease in immune system function, characterised by the increase in the frequency and severity of infections and autoimmune diseases, is the decrease in production of naïve T cells by the thymus. This results from the targeted degeneration or involution of the thymus with age. One of the principal causes of involution is the loss of organisation and functionality of the thymic epithelium, which confers the primary function of the organ via interactive regulation of T cell development. Although the mechanisms that govern the deterioration of the thymic epithelium are poorly understood, a number of recent reports indicate that the transcription factor, Foxn1, is required to maintain this compartment in the postnatal thymus. Thus, the first aim of this study was to precisely profile Foxn1 expression levels in aging postnatal thymic epithelial cells. The second aim was to investigate the effects of upregulating Foxn1 in the aging thymus, which was achieved using a novel, regulatable Foxn1 mouse model generated during this study. In this study I show that Foxn1 is expressed at different levels in different postnatal thymic epithelial cell (TEC) sub-populations suggesting a dosage-dependent mode of action for Foxn1. Additionally, using two experimental approaches, I show that Foxn1 expression decreases with age in TECs, supporting the current data that implicate the loss of Foxn1 as a potential cause of thymus involution. Next, I generated a tissue-specific, regulatable Foxn1 mouse model that allowed me to modulate Foxn1 expression in the postnatal thymus. Firstly, using this model, I show that thymus involution can be prevented by the up-regulation and maintenance of Foxn1 expression from the onset of involution. Thymi that up-regulated Foxn1 were overtly larger and exhibited greater cellularity in both the thymocyte and epithelial compartments compared to age matched controls. Additionally, the larger TEC compartment contained a higher proportion of functional and proliferating TECs that upregulated a panel of genes involved in TEC development and function. Next, I show that Foxn1 up-regulation in aged, involuted thymi is sufficient to partially reverse involution, as shown by an increase in TEC organisation and intrathymic T cell numbers. While other strategies that promote thymic rebound or reversal have been reported, including cytokine treatment or sex steroid ablation, these approaches are complicated by side effects and toxicity. Hence, I propose a novel model for immune reconstitution through the regulation of Foxn1 expression in the postnatal thymus.

616.07

Cbx4 regulates the proliferation of thymic epithelial cells and thymus function.

Liu, B., Liu, Y.F., Du, Y.R., Mardaryev, Andrei N., Yang, W., Chen, H., Xu, Z.M., Xu, C.Q., Zhang, X.R., Botchkarev, Vladimir A., Zhang, Y., Xu, G.L.

January 2013

no / Thymic epithelial cells (TECs) are the main component of the thymic stroma, which supports T-cell proliferation and repertoire selection. Here, we demonstrate that Cbx4, a Polycomb protein that is highly expressed in the thymic epithelium, has an essential and non-redundant role in thymic organogenesis. Targeted disruption of Cbx4 causes severe hypoplasia of the fetal thymus as a result of reduced thymocyte proliferation. Cell-specific deletion of Cbx4 shows that the compromised thymopoiesis is rooted in a defective epithelial compartment. Cbx4-deficient TECs exhibit impaired proliferative capacity, and the limited thymic epithelial architecture quickly deteriorates in postnatal mutant mice, leading to an almost complete blockade of T-cell development shortly after birth and markedly reduced peripheral T-cell populations in adult mice. Furthermore, we show that Cbx4 physically interacts and functionally correlates with p63, which is a transcriptional regulator that is proposed to be important for the maintenance of the stemness of epithelial progenitors. Together, these data establish Cbx4 as a crucial regulator for the generation and maintenance of the thymic epithelium and, hence, for thymocyte development.

REF 2014

Découverte de cellules souches potentielles de l’épithélium thymique

Dumont-Lagacé, Maude

05 1900

Le thymus subit un vieillissement précoce, appelé involution thymique, qui cause une perte de fonction du thymus avec l’âge. À ce jour, les mécanismes de renouvellement des cellules épithéliales thymiques (TECs) sont encore mal compris, c’est pourquoi nous avons voulu identifier les cellules souches de l’épithélium thymique. Comme les cellules souches sont quiescentes dans plusieurs tissus, les objectifs de notre étude étaient de déterminer si l’épithélium thymique contenait des cellules quiescentes et d’étudier la cinétique de prolifération des TECs chez les souris jeunes et adultes. Pour ce faire, nous avons utilisé une souris transgénique (H2B-GFP Tet-On) nous permettant d’identifier les cellules ne se divisant pas sur une longue période de temps (LRC, label-retaining cells¬). Nous avons d’abord montré que les TECs proliféraient plus rapidement chez les femelles que les mâles. De plus, nous avons trouvé plusieurs différences entre l’épithélium thymique post-natal et adulte : (1) les TECs corticales (cTECs) et médullaires (mTECs) ont un taux de prolifération similaire chez les jeunes souris, mais chez l’adulte, les cTECs prolifèrent plus lentement que les mTECs; (2) les TECs prolifèrent plus rapidement chez les souris jeunes que adultes; (3) des LRC sont détectées chez l’adulte, mais pas chez les jeunes souris. Les LRC, retrouvées dans le compartiment cTEC, sous-expriment des gènes associés à la sénescence et surexpriment des gènes importants pour le développement et le renouvellement des TECs. Ces résultats montrent que ces cellules sont quiescentes et suggèrent qu’elles pourraient bel et bien être les progéniteurs thymiques responsables du renouvellement des TECs adultes. / The thymus undergoes a rapid degeneration with age termed thymic involution that causes a loss of function of the thymus with age. To this day, mechanisms of thymic maintenance are still unknown. This is why we aimed to identify thymic epithelial stem cells. Since stem cells are quiescent in many tissues in adults, our main objectives were to determine whether the thymic epithelium contains quiescent cells and study the proliferation kinetics of thymic epithelial cells in neonatal and adult mice. To this end, we used the transgenic mouse model H2B-GFP Tet-On, a label-retaining assay allowing us to identify cells that have not divided for a prolonged period of time, which are called label-retaining cells (LRC). First, we showed that in the adult thymus, females’ thymic epithelial cells (TECs) proliferated more actively than males’ TECs. We observed three main differences between neonatal and adult thymi: (1) cTECs and mTECs have similar proliferation rates in young, but mTECs cycled more actively in adult mice; (2) neonatal TECs have a higher turnover rate than adult’s TECs, and (3) we were able to detect LRC in adult mice, but not in neonatal mice. These LRC are contained in the cTEC compartment and express very low levels of senescence-associated proteins and show a high expression of genes important for thymic development and. These results show that the LRC identified in adult thymi are not senescent cells and therefore might represent the elusive thymic progenitor cells responsible for thymic maintenance and regeneration in adult mice.

Cellules épithéliales thymiques

Involution thymique

Cellules souches

Développement thymique

Label-retaining assay

Thymic epithelial cells

Thymic involution

Stem cells

Thymic development