Effects of Long-Term Exposure of Normal C57BL/6J Inbred Mice to 17β-Estradiol on Gene Expression in Lymphocytes: mRNA Analysis of Lymphokines and bcl-2/fas

Yin, Zhi-Jun

18 August 1997

It is now clear that human and animal exposure to estrogenic compound occurs through several sources. This include: i) naturally occurring endogenous estrogens, ii) exogenous or intentional estrogens for prophylactic (e.g. oral contraceptive) and therapeutic (e.g. as replacement therapy for ovulation in nulliparous women and in menopausal women, and in some men suffering from prostate cancer) purposes, iii) accidental via estrogenic chemical exposure (e.g. pesticides, industrial byproducts) and phytoestrogens (e.g. soybeans). It has long been recognized that estrogen, a female sex hormone, functions not only on the reproductive system, but also on various other systems including the immune system. Estrogens are thought to be of both physiologic and pathologic importance. Female in general, have better immune capabilities than males, a phenomenon attributed to the action of sex hormones on the immune system. There is also a female-gender bias in susceptibility to autoimmune diseases. Estrogens have been linked either directly or indirectly to the etiology and pathogenesis of various female-predominant autoimmune diseases. Estrogens have also been linked to the onset of cancer, and conditions where the immune system often malfunctions. Estrogen affects the functions of both B and T cells, possibly by regulating such factors as lymphokine gene expression and/or cellular death by apoptosis. However, the functioning of both B and T cells under the influence of long-term exposure to estrogen has not been fully understood. The primary aim of this thesis was to investigate the effect of long-term exposure to 17β-estradiol on lymphokine and bcl-2/fas (proto-oncogenes) mRNA expression. We evaluated the effects of estrogen on the expression of genes for lymphokines, which are essential for the immune response. It is hypothesized that estrogen may regulate the immune system by modifying the expression of lymphokine genes and/or genes that regulate apoptosis. The results demonstrated that long-term 17β-estradiol exposure reduced the viability of lymphocytes when compared to lymphocytes from placebo-treated mice. IL-2 and IFN-g mRNA was consistently higher in ConA-stimulated lymphocytes from estrogen-treated mice (P < 0.05). The mRNA for TGF-β₁ lymphokine was also increased but was not consistent at all time points of incubation. The expression of IL-4 mRNA was not noticeably affected by estrogen treatment of mice. Long-term exposure to 17β-estradiol appear to have some influence on the mRNA expression of proto-oncogenes fas and bcl-2 in splenic and thymic T lymphocytes. There was a trend of increased bcl-2 mRNA expression in estrogen-treated mice compared to placebo-treated mice, whereas the mRNA expression of fas gene appeared to be lower compared to controls. Overall, these findings suggest that 17β-estradiol may selectively influence lymphokine and proto-oncogene mRNA expression. These results suggest that the one mode of modulation of the immune response by 17β-estradiol may be through alterations in the lymphokine and proto-oncogene expression. Since estrogen-treatment markedly induces atrophy of the thymus and diminishes the cellularity of the lymphoid organs (e.g. Spleen), it became necessary to perform multiple assays on the same cells, particularly lymphokine and apoptosis gene expression. A secondary objective of this thesis was to investigate whether lymphocytes, which have undergone proliferation in Lympho-Pro™ assay (Alamar Blue assay), could be utilized for further analysis. In this regard, we found that a non-radioactive assay that utilizes Alamar Blue had significant advantages over the conventional ³H-thymidine incorporation assay. By using cells from estrogen and placebo-treated mice in the Alamar Blue assay, we found that this assay not only allowed determination of lymphocyte proliferation, but also the assessment of mRNA expression, cytogenetics, apoptosis and immunophenotyping of the same lymphocytes. / Master of Science

IL-4

TGF-beta

IFN-gamma

IL-2

cytokine

T cells

splenocytes

thymocytes

17beta-estradiol(E2)

Fas

Bcl-2

autoimmune diseases

A função do gene Autoimmune Regulator (Aire) no controle da adesão de células tímicas epiteliais medulares com timócitos / The fuction of Autoimmune Regulator (Aire) gene in the control of adhesion between medullary thymic epithelial cells with thymocytes

Pezzi, Nicole

26 February 2016

O crosstalk entre timócitos e células epiteliais tímicas é crucial para o desenvolvimento das células T e estabelecimento da tolerância central. Células tímicas epiteliais medulares (mTECs) contribuem para a autotolerância por meio da expressão ectópica de antígenos restritos aos tecidos (TRAs). A expressão de TRAs em mTECs é altamente dependente do gene Autoimmune Regulator (Aire). Por meio do reconhecimento de TRAs com alta afinidade, células T autoreativas são selecionadas negativamente do pool de timócitos em desenvolvimento. Apesar do papel de Aire na indução da tolerância central ser bem conhecido, os mecanismos celulares e moleculares precisos do processo permanecem obscuros. Nesse estudo, hipotetizamos que perturbações na expressão do gene Aire influenciam a adesão entre mTECs e timócitos, o que poderia resultar em um desequilíbrio na imunotolerância a antígenos próprios. Um ensaio funcional realizado com timócitos frescos, extraídos de um timo normal de camundongo e cocultivados com células epiteliais tímicas medulares da linhagem mTEC 3.10, demonstrou que a inibição do gene Aire por meio de RNA de interferência reduziu significativamente a capacidade das mTECs de promover a adesão dos timócitos. Análises por microarray revelaram que o silenciamento do gene Aire nas células mTEC 3.10 causou a modulação de mais de 1000 genes, alguns que codificam TRAs, outros que codificam proteínas envolvidas na adesão celular, como VCAM-1, e também outros que codificam moléculas coestimuladoras como CD80. Esses resultados contribuem para uma melhor compreensão do papel de Aire no controle da adesão mTEC-timócitos, a qual constitui um processo essencial para a seleção negativa de timócitos autoreativos / The crosstalk between thymocytes and thymic epithelial cells is critical for T cell development and the establishment of central tolerance. Medullary thymic epithelial cells (mTECs) contribute to self-tolerance through the ectopic expression of tissuerestricted antigens (TRAs) in the thymus. TRAs expression in mTECs is largely dependent on Autoimmune Regulator (Aire) gene. Through the recognition of TRAs with high affinity, developing autoreactive T cells are negatively select from the pool of developing thymocytes. Although the role of Aire in the induction of central tolerance is well known, the precise cellular and molecular mechanisms remain unclear. In this study, we hypothesize that disturbance in Aire gene expression influences adhesion between mTECs and thymocytes, which could result in an imbalance in immune-tolerance to self-antigens. A functional assay performed with fresh thymocytes dissociated from a normal mouse thymus and co-cultured with a medullary thymic epithelial cell line named mTEC 3.10, demonstrated that Aire RNAi knockdown significantly decreased the ability of mTECs to promote thymocyte adhesion. Microarray analysis revealed that Aire knockdown of the murine mTEC 3.10 cell line led to the modulation of more than 1000 genes, some of them coding for TRAs, others for proteins involved in cell adhesion like VCAM-1 and also for costimulatory molecules like CD80. These results contribute to a better understanding of the role of Aire in the control of mTEC-thymocyte adhesion, which is an essential process for negative selection of autoreactive thymocytes

Autoimmune Regulator (Aire) gene

Cell adhesion assay

Ensaio de adesão celular

Expressão gênica

Gene Autoimmune Regulator (Aire)

Gene expression

Medullary thymic epithelial cells(mTECs)

Thymocytes

Timócitos

A função do gene Autoimmune Regulator (Aire) no controle da adesão de células tímicas epiteliais medulares com timócitos / The fuction of Autoimmune Regulator (Aire) gene in the control of adhesion between medullary thymic epithelial cells with thymocytes

Nicole Pezzi

26 February 2016

O crosstalk entre timócitos e células epiteliais tímicas é crucial para o desenvolvimento das células T e estabelecimento da tolerância central. Células tímicas epiteliais medulares (mTECs) contribuem para a autotolerância por meio da expressão ectópica de antígenos restritos aos tecidos (TRAs). A expressão de TRAs em mTECs é altamente dependente do gene Autoimmune Regulator (Aire). Por meio do reconhecimento de TRAs com alta afinidade, células T autoreativas são selecionadas negativamente do pool de timócitos em desenvolvimento. Apesar do papel de Aire na indução da tolerância central ser bem conhecido, os mecanismos celulares e moleculares precisos do processo permanecem obscuros. Nesse estudo, hipotetizamos que perturbações na expressão do gene Aire influenciam a adesão entre mTECs e timócitos, o que poderia resultar em um desequilíbrio na imunotolerância a antígenos próprios. Um ensaio funcional realizado com timócitos frescos, extraídos de um timo normal de camundongo e cocultivados com células epiteliais tímicas medulares da linhagem mTEC 3.10, demonstrou que a inibição do gene Aire por meio de RNA de interferência reduziu significativamente a capacidade das mTECs de promover a adesão dos timócitos. Análises por microarray revelaram que o silenciamento do gene Aire nas células mTEC 3.10 causou a modulação de mais de 1000 genes, alguns que codificam TRAs, outros que codificam proteínas envolvidas na adesão celular, como VCAM-1, e também outros que codificam moléculas coestimuladoras como CD80. Esses resultados contribuem para uma melhor compreensão do papel de Aire no controle da adesão mTEC-timócitos, a qual constitui um processo essencial para a seleção negativa de timócitos autoreativos / The crosstalk between thymocytes and thymic epithelial cells is critical for T cell development and the establishment of central tolerance. Medullary thymic epithelial cells (mTECs) contribute to self-tolerance through the ectopic expression of tissuerestricted antigens (TRAs) in the thymus. TRAs expression in mTECs is largely dependent on Autoimmune Regulator (Aire) gene. Through the recognition of TRAs with high affinity, developing autoreactive T cells are negatively select from the pool of developing thymocytes. Although the role of Aire in the induction of central tolerance is well known, the precise cellular and molecular mechanisms remain unclear. In this study, we hypothesize that disturbance in Aire gene expression influences adhesion between mTECs and thymocytes, which could result in an imbalance in immune-tolerance to self-antigens. A functional assay performed with fresh thymocytes dissociated from a normal mouse thymus and co-cultured with a medullary thymic epithelial cell line named mTEC 3.10, demonstrated that Aire RNAi knockdown significantly decreased the ability of mTECs to promote thymocyte adhesion. Microarray analysis revealed that Aire knockdown of the murine mTEC 3.10 cell line led to the modulation of more than 1000 genes, some of them coding for TRAs, others for proteins involved in cell adhesion like VCAM-1 and also for costimulatory molecules like CD80. These results contribute to a better understanding of the role of Aire in the control of mTEC-thymocyte adhesion, which is an essential process for negative selection of autoreactive thymocytes

Ensaio de adesão celular

Expressão gênica

Gene Autoimmune Regulator (Aire)

Timócitos

Autoimmune Regulator (Aire) gene

Cell adhesion assay

Gene expression

Medullary thymic epithelial cells(mTECs)

Thymocytes

L'activador del CDK2 relacionat amb l'apoptosi: clonatge i estudi bioquímic del seu paper regulador de la mort cel·lular programada

Brunet Roig, Maurici

14 July 2006

L´apoptosi, o mort cel.lular programada, és un procés actiu que mobilitza els recursos cel.lulars amb l´objectiu de mantenir l´homeostasi de l´organisme a expenses del suïcidi de cèl.lules individuals. Diferents estudis han mostrat un increment de l´activiat d´algunes cdk, especialment Cdk1 i Cdk2, en correlació amb la progressió dels primers estadis apoptòtics. En el nostre laboratori l´estudi de l´apoptosi en timòcits, els quals no tenen una activitat cdk significativa degut a l´aturada del cicle cel.lular en G1, demostren que la inducció de l´activitat de Cdk2 després del tractament amb radiació gamma o amb glucocorticoides és necessària per l´inici de l´apoptosi. Mentre cap de les ciclines conegudes sembla ser la proteïna activadora de Cdk2 en apoptosi, en el nostre laboratori hem identificat un nou membre de la família de les ciclines, denominada Ciclina O, capaç d´activar aquesta kinasa in vivo en línies cel.lulars. L´expressió d´aquesta nova ciclina en el timus, i altres teixits, s´indueix ràpidament després del tractament amb radiació gamma i coincideix amb l´aparició de l´apoptosi. Aquests resultats posicionen la Ciclina O com a millor candidat a ser l´activador de Cdk2 necessari per induïr la mort cel.lular programada en el timus, i probablement també en altres òrgans. / The apoptosis, also called programmed cell death, is an active process able to use the cellular mechanisms to kill individual cells in order to keep the functional homeostasis of the whole organism. Different studies had shown a correlation between the first apoptotic events and the induction of some cdk proteins, particularly Cdk1 and Cdk2. The studies of thymocytes in our laboratory, wich lacks the most amount of cdk activity related to the cell cycle because of its arrest in G1, had shown that the induction of Cdk2 activity after the treatment with gamma radiation or glucocorticoids is a necessary step for the apoptosis induction. While any of the cyclins described at the moment seems to be the Cdk2 activator for apoptosis a new member of the cyclin family able to activate the kinase Cdk2 in vivo in cell lines has been identified in our laboratory. The expresion of this cyclin, known as Cyclin O, is quickly induced in the thymus after the treatment with gamma radiation and correlates with the induction of apoptosis. These results position Cyclin O as the best candidate to activate Cdk2 and inuce the programmed cell death in the thymus, and probably other tissues.

fosforilació

thymocytes

post-translational control

programed cell death

phosphorylation

kinase activity

genotoxic damage

cyclin

gamma radiation

checkpoint

cellular stress

cell cycle

apoptosis

timòcits

punt de control

regulació post-traduccional

radiació gamma

mort cel.lular programada

p53

estrès cel.lular

dany genotòxic

ciclina

cicle cel.lular

Cdk2

ATM/ATR

activitat kinasa

apoptosi

576

577

Study of the regulation and signalling of cdk2-Cyclin o complexes during apoptosis

Roset i Huguet, Ramon

04 April 2008

The aim of this thesis is the characterization of a protein involved in apoptosis. Our group has identified an early step common to different forms of intrinsic apoptosis stimuli. This step requires de novo synthesis of a novel Cyclin, Cyclin O, that upon apoptosis induction in lymphoid cells forms active complexes, primarily with Cdk2. Cyclin O expression precedes glucocorticoid and gamma radiation-induced apoptosis in vivo in mouse thymus and its overexpression induces apoptosis in cultured cells. Knocking down the endogenous expression of Cyclin O by shRNA leads to the inhibition of glucocorticoid and DNA damage-induced apoptosis while leaving CD95 death receptor mediated apoptosis intact. This data demonstrates that apoptosis induction in lymphoid cells is one of the physiological roles of Cyclin O and it does not act by perturbing a normal cellular process such as the cell cycle. In addition we have identified c-Myb a substrate of Cdk2-Cyclin O complexes and we show that c-Myb is downregulated during apoptosis of lymphoid cells. / L'objectiu d'aquesta tesi és la caracterització d'una proteïna involucrada en l'apoptosi. El nostre grup ha identificat un pas primerenc comú en diversos estímuls apoptòtics de la ruta intrínseca. Aquest pas requereix la síntesi de novo d'una nova Ciclina, Ciclina O, que quan s'indueix apoptosi en cèl·lules limfoides forma complexes actius majoritàriament amb Cdk2. L'expressió de la Ciclina O és prèvia a l'apoptosi induïda per glucocorticoids i radiació gamma i la seva sobreexpressió indueix apoptosi en cultius cel·lulars. La baixada dels nivells d'expressió de la Ciclina O endògena amb shRNA provoca una inhibició de l'apoptosi induïda per glucocorticoids o agents que danyen el DNA, mentre que l'apoptosi mediada pel receptor CD95 es manté intacta. Aquests resultats demostren que la inducció d'apoptosi en cèl·lules limfoides és una de les funcions fisiològiques de la Ciclina O i que no es deu a una pertorbació de processos cel·lulars normals com ara el cicle cel·lular. A més a més, hem identificat c-Myb com a substrat dels complexes Cdk2-Ciclina O i demostrem que els nivells de c-Myb baixen durant l'apoptosis de cèl·lules limfoides.

Doble híbrid en llevat

Dany al DNA

Ciclina

Apoptosis

Yeast two Irbid

WEHI7.2

Translation

Transcription

Thymus

Thymocytes

siRNA

Programmed cell death

p53

Mitochondria

Mouse Embryonic Fibroblasts

Lymphocytes

Glucocorticoids

Gamma radiation

Etoposide

DNA-damage

Cyclin

c-Myb

Cdk

Cdc25

Caspases

Bim

Bid

BH3-only

Bcl-2

Apoptosis

Etopòsit

Fibroblasts Embrionaris de Ratolí

Glucocorticoids

Limfòcits

Mitocondri

Mort cel·lular programada

Radiació gamma

Timòcits

Timus

Traducció

Transcripció

57

61

Les oncogènes NUP98-PHF23 et NUP98-HOXD13 confèrent un potentiel aberrant d’auto-renouvellement aux progéniteurs thymiques

Tardif, Magalie

09 1900

No description available.

thymocytes

NUP98-PHF23 (NP23)

NUP98-HOXD13 (NHD13)

auto-renouvellement

reprogrammation

souris transgénique

preleukemic stem cell (pre-LSC)

self-renewal

transgenic mouse model