Characterisation and functional analysis of the developmentally regulated expression site associated gene 9 family in Trypanosoma brucei

Barnwell, Eleanor M.

January 2009

Trypanosoma brucei is a protozoan parasite that is the causative agent of sleeping sickness in sub-Saharan Africa. T. brucei has a complex life cycle involving passage between a mammalian host and the tsetse fly. The parasite evades the mammalian immune system via expression of Variant Surface Glycoprotein (VSG) on the cell surface. VSG genes are expressed at telomeric expression sites and at these sites are a number of Expression Site Associated Genes (ESAGs). One unusual ESAG, ESAG9, is developmentally regulated: RNA for these genes accumulates during the transition from slender to stumpy cells in the mammalian bloodstream and cellassociated protein is only detected transiently in stumpy and differentiating cells. Transgenic cell lines were generated which ectopically express one or more members of the ESAG9 gene family. Biochemical and cytological analyses using these cell lines indicated that some members of this family are glycosylated and GPI-anchored, and also that one gene, ESAG9-K69, is secreted. ESAG9-K69 is also secreted by wild-type stumpy parasites. In vivo experiments with tsetse flies did not conclusively show whether ESAG9 proteins play a role in the establishment of a tsetse fly mid-gut infection by transgenic trypanosomes. However, In vivo and ex vivo experiments using the mouse model of trypanosomiasis indicated that expression of ESAG9 proteins may alter parasitaemia in the mouse and results in a significant decrease in the proportion of CD4+ T cells in the mouse spleen.

591.35

Antigenic variation in Trypanosoma brucei: analysis of its control and a transcription factor involved

Kassem, Ali

27 March 2015

African trypanosomes are a major plague in sub-Saharan Africa. They cause sleeping sickness in humans and nagana in cattle. These parasites are transmitted between their mammalian hosts by tsetse flies. They are adapting to their different environments through differentiation processes. These processes involve, amongst other things, the expression of different surface coats. These coats are made of procyclin protein at the insect midgut procyclic stage and of variant surface glycoprotein (VSG) at the mammalian bloodstream stage. At a given time, one VSG is expressed from a single VSG gene out of a repertoire of more than 1500 VSG genes present in the trypanosomes genome. The expressed VSG gene is always located at one of fifteen telomeric polycistronic transcription units called expression sites (ES). The VSG coat is changed regularly in a process called antigenic variation allowing trypanosomes to escape the immune response. The exact mechanism controlling the selection of the active ES is not yet known and controversies have been raised concerning the ES transcription control. Although several molecular factors involved in the ES monoallelic-expression have been identified, none of them seems to be a critical regulator.<p><p>Thus during my thesis we decided to explore two aspects of ES expression: (A) deciphering the level at which this expression is controlled and (B) fishing for new protein factors controlling this expression.<p>A) It is not even clear at which level the ES transcription control takes place. In particular, there has been debate on whether it is taking place at the transcription initiation or elongation level. Previous experiments generated contradictory conclusions and gave rise to two different models. The first model suggested that transcription initiation takes place in all ESs simultaneously. The second model suggested that transcription is initiated in only two ESs, one being fully active and a second being pre-active. These two models were equally able to account for the finding of transcripts from different ES within a trypanosome population provided the pre-active ES differs between individual cells. In order to decide if a single or multiple ES promoters can initiate transcription in a given cell, single cell RT-PCR targeting the beginning of the ES was required. Thus single cell RT-PCR was performed and an analysis of the obtained transcripts showed that transcription initiation is taking place on many ES while only one VSG is transcribed. This permitted the unambiguous conclusion that the monoallelic expression of VSG is exerted by controls operating downstream from transcription initiation, suggesting transcription elongation or RNA processing as critical control steps. <p>B) We have characterized a new nuclear protein, Tb alba3, involved in the repression of silent VSGs. Its invalidation lead to chromatin opening in the silent expression sites and to a raise in their expression. As this protein is cytoplasmic and binding procyclin mRNAs at the procyclic stage, it could be a new versatile factor, shuttling between the cytoplasm and the nucleus and involved both in the inverse regulation of major surface antigens at different differentiation stages and the control of antigenic variation.<p><p>These results enhance our understanding of ES transcription control and of ES monoallelic expression. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Biologie

Trypanosoma brucei

Parasite antigens -- Variation

Trypanosoma brucei

Antigènes parasitaires -- Variation

antigenic variation

VSG

expression site

monoallelic expression

transcription

trypanosoma brucei

ALBA protein

Rôle de la tolérance centrale et périphérique des lymphocytes T autoréactifs dans deux nouveaux modèles murins double transgéniques

Chabot, Sylvie

05 1900

Les maladies autoimmunes sont des affections chroniques, le plus souvent invalidantes, qui touchent plus de 5% de la population dans les pays développés. L’autoimmunité résulte de la rupture des mécanismes de tolérance du système immunitaire vis-à-vis des autoantigènes exprimés par les tissus de l’organisme, entraînant la destruction d’un ou de plusieurs organes-cibles par les lymphocytes T et/ou B. L’hépatite autoimmune et le diabète autoimmun se caractérisent par la destruction sélective des hépatocytes et des cellules beta pancréatiques, respectivement. De plus en plus d’arguments suggèrent une implication des lymphocytes T CD8+ dans le déclenchement, la progression et la régulation des réponses associées à plusieurs maladies autoimmunes. Dans ce projet, nous avons suivi l’évolution de clones de lymphocytes T CD8+ spécifiques à un antigène particulier dont le site d’expression différait. Pour ce faire, nous avons développé deux nouveaux modèles murins double transgéniques par croisement entre une lignée de souris exprimant un TCR transgénique spécifique à la nucléoprotéine (NP) du virus de la chorioméningite lymphocytaire (LCMV), et une souris exprimant cette NP-LCMV : 1) uniquement dans les hépatocytes (modèle d’hépatite autoimmune), ou 2) simultanément dans le thymus et le pancréas (modèle de diabète autoimmun). L’avidité fonctionnelle des lymphocytes T CD8+ spécifiques à la NP chez les souris TCR transgéniques était inversement proportionnelle au niveau d’expression du TCR. Le répertoire lymphocytaire dans le thymus, la rate, les ganglions et le sang périphérique a été caractérisé pour chacune des lignées de souris double transgéniques, de même que la capacité fonctionnelle et le phénotype (marqueurs d’activation/mémoire) des lymphocytes T CD8+ autoréactifs. Chacun des deux nouveaux modèles présentés dans cette étude ont montré que les lymphocytes T CD8+ spécifiques à la NP sont aptes à briser la tolérance centrale et périphérique et à provoquer une réaction d’autoimmunité spontanée. Dans le modèle d’hépatite autoimmune, où l’expression de l’autoantigène était restreinte au foie, la surexpression du TCR transgénique a entraîné une délétion thymique quasi-totale des lymphocytes T CD8+ spécifiques à la NP prévenant le développement d’une hépatite spontanée. alors qu’un niveau de TCR comparable à celui d’une souris de type sauvage a permis une sélection positive des lymphocytes autoréactifs qui se sont accumulés dans le foie où ils se sont activés pour provoquer une hépatite autoimmune spontanée. Dans le modèle de diabète autoimmun, où l’autoantigène était exprimé dans le pancréas et le thymus, les souris des deux lignées double transgéniques ont montré une délétion thymique partielle, peu importe le niveau d’expression du TCR. Seuls les mâles adultes développaient un diabète spontané et une partie de leurs lymphocytes T CD8+ exprimaient une combinaison particulière de marqueurs d’activation/mémoire (CD44, CD122, PD-1). Cette population lymphocytaire était absente chez les souris femelles et les mâles sains. L’étude de la tolérance des lymphocytes T CD8+ autoréactifs dans nos deux nouveaux modèles murins double transgéniques a permis d’identifier des mécanismes alternatifs possiblement impliqués dans la tolérance et l’activation, et de mieux comprendre le rôle des lymphocytes T CD8+ autoréactifs dans le processus autoimmun menant à l’hépatite autoimmune et au diabète autoimmun. Ces découvertes seront utiles pour développer de nouvelles approches thérapeutiques ciblant les lymphocytes T CD8+ autoréactifs. / Autoimmune diseases are chronic and often invalidating disorders affecting more than 5% of the population in developed countries. Autoimmunity results from a breach in tolerance mechanisms towards autoantigens expressed in tissues and organs leading to the destruction of one or more target-organs by T and/or B lymphocytes. Autoimmune hepatitis and autoimmune diabetes are characterised by selective destruction of hepatocytes or pancreatic beta cells respectively. Accumulating evidences suggest a direct implication for CD8+ T cells in initiation, progression and regulation processes associated with many autoimmune diseases. To study the development of CD8+ T cell clones towards a particular antigen whose expression site was different, we developed two new double transgenic mice models. Each mice model was obtained after breeding of a mouse expressing a TCR specific for the nucleoprotein (NP) from lymphocytic choriomeningitis virus (LCMV) with a second mouse expressing this LCMV-NP either 1) exclusively in hepatocytes (autoimmune hepatitis model), or 2) broadly in the pancreas and thymus (autoimmune diabetes model). The functional avidity of the NP-specific CD8+ T cells clones in TCR transgenic mice lines was inversely correlated with their respective TCR expression level. The lymphocyte repertoire was characterized in each line of double transgenic mouse, and functional capacities and phenotype (activation/memory markers) of NP-reactive CD8+ T cells were assessed. Both new models of double transgenic mice showed that NP-reactive CD8+ T cells could break central and peripheral tolerance and provoke a spontaneous autoimmune response. In the autoimmune hepatitis model, where autoantigen was expressed only in the liver, overexpression of the transgenic TCR led to massive thymic deletion of the NP-specific CD8+ T cells and no hepatitis developed, whereas TCR expression matching wild-type level allowed positive selection of autoreactive CD8+ T cells which accumulated in the liver, became activated and led to hepatitis development. In the autoimmune diabetes model, where autoantigen was expressed both in the pancreas and thymus, both double transgenic mouse lines showed a partial thymic deletion of NP-specific CD8+ T cells, regardless of the TCR expression level. Only adult male mice developed spontaneous diabetes, and a population of their autoreactive CD8+ T cells expressed a singular combination of activation/memory markers (CD44, CD122, PD-1) which was not seen in female and healthy male mice. The study of the tolerance of autoreactive CD8 + T cells in our two new double transgenic mouse models led us to identify alternative mechanisms potentially involved in tolerance and activation, and to better understand the role of autoreactive CD8 + T cells in the autoimmune processes leading to autoimmune hepatitis and autoimmune diabetes. These findings will be useful in developing new therapeutic approaches targeting autoreactive CD8+ T cells

Souris transgénique

Hépatite autoimmune

Diabète autoimmun

Lymphocyte T CD8+

Tolérance

TCR

Site d'expression antigénique

Phénotype

Transgenic mouse

Autoimmune hepatitis

Autoimmune diabetes

CD8+ T cells

Tolerance

Antigen expression site

Phenotype