Challenging Development of a Humanized Mouse Model for Evaluating the HTLV-1 Infection and Leukemogenic Process in vivo

Villaudy, Julien

22 December 2011

Human T-cell Leukemia Virus type 1 (HTLV-1) is the etiologic agent of the Adult T-cell Leukemia (ATL), an aggressive lymphoproliferation of activated CD4+ T cells. The lack of a reliable small animal model to reproduce in vivo the leukemogenic process associated with HTLV-1 infection has impaired the understanding of the early stages of this process as well as the discovery of effective therapeutic approaches. Recently, improvement in the models of humanized mouse models were achieved allowing the development of a human immune system in mice. Injection of human hematopoietic stem and progenitors cells purified from cord blood into Balb/c Rag2-/-γc-/- newborns allows the de novo production of human dendritic, B and T cells. We infected humanized mice with HTLV-1 producing cell lines resulting in infection of human cells within the mice and the development of lymphomas and leukemias. This infection also results in the alteration of the T-cell development within the thymus pushing the thymocytes toward a more mature phenotype. This small animal model recapitulating in vivo the HTLV-1 infection and its associated pathogenesis gave us the opportunity to study the evolution of the clonality of the virus among human cells in different lymphoid organs. Based on these observations, preliminary results on the use of a new therapeutic approach were obtained. We finally tried to adjust the humanization protocol in order to obtain better engraftment in this model.

HTLV-1

ATL

Leukemia

Lymphoma

Humanized Mice

Thymus

T-cell Development

Functional Characterization of T-lineage Cells derived in vitro from Human Hematopoietic Stem Cells

Awong, Geneve

05 January 2012

T lymphocytes play a critical role in adaptive immunity by eliciting and regulating specific immune responses against viral and bacterial pathogens. The development of T cells occurs within the highly specialized thymus and follows a defined set of stage-specific differentiation steps. However, the molecular and cellular events occurring at early stages of human T-cell development remain to be fully elucidated. This was in part due to the inability to obtain substantial numbers of T-lineage cells from hybrid/human fetal thymic organ culture (FTOC) and the inability to recapitulate human T-lymphopoiesis using other systems. To address the molecular and cellular events occurring during early human T-lymphopoiesis, human umbilical cord-blood (UCB) hematopoietic stem cells (HSCs) were induced to differentiate to the T-lineage utilizing OP9-DL1 stromal cells. A developmental program involving a sequential and temporally discrete expression of key differentiation markers was revealed. In addition, this Thesis demonstrates that in vitro-generated CD34+CD7++ progenitors effectively engrafted the thymus of immunodeficient mice. In addition, two distinct progenitor subsets, CD34+CD45RA+CD7++CD5-CD1a- (proT1) and CD34+CD45RA+CD7++CD5+CD1a- (proT2), were identified with proT2 cells showing a 3-fold enhanced engrafting capacity than the proT1 subset. As proT2 cells exhibit superior engrafting capacity, these cells were tested for their ability to enhance T cell generation following hematopoietic stem cell transplant (HSCT). We observe that when HSCs are coinjected with proT2 cells, a dramatic improvement in HSC-derived T-lymphopoiesis is observed. This Thesis demonstrates that in vitro-derived proT2 cells reorganize the thymus stromal compartment of the host NOD/SCID/γcnull mouse compared to the highly disorganized cortical and medullary compartments in mice not receiving proT cells. This alteration in thymic architecture likely favours the recruitment of BM derived progenitors. Lastly, we address whether functional CD8 T cells can be generated in vitro using hematopoietic stem cells (HSCs) in coculture with OP9-DL1 cells and indeed these cells were capable of proliferating, and secreting effector molecules typical of cytotoxic T cells. Taken together, the ability to generate proT cells and mature T cells from Notch-ligand cultures offers a new tool to study human T cell development.

Notch

hematopoietic stem cell

T cell development

immune-reconstitution

progenitors

hematopoiesis

Functional Characterization of T-lineage Cells derived in vitro from Human Hematopoietic Stem Cells

Awong, Geneve

05 January 2012

T lymphocytes play a critical role in adaptive immunity by eliciting and regulating specific immune responses against viral and bacterial pathogens. The development of T cells occurs within the highly specialized thymus and follows a defined set of stage-specific differentiation steps. However, the molecular and cellular events occurring at early stages of human T-cell development remain to be fully elucidated. This was in part due to the inability to obtain substantial numbers of T-lineage cells from hybrid/human fetal thymic organ culture (FTOC) and the inability to recapitulate human T-lymphopoiesis using other systems. To address the molecular and cellular events occurring during early human T-lymphopoiesis, human umbilical cord-blood (UCB) hematopoietic stem cells (HSCs) were induced to differentiate to the T-lineage utilizing OP9-DL1 stromal cells. A developmental program involving a sequential and temporally discrete expression of key differentiation markers was revealed. In addition, this Thesis demonstrates that in vitro-generated CD34+CD7++ progenitors effectively engrafted the thymus of immunodeficient mice. In addition, two distinct progenitor subsets, CD34+CD45RA+CD7++CD5-CD1a- (proT1) and CD34+CD45RA+CD7++CD5+CD1a- (proT2), were identified with proT2 cells showing a 3-fold enhanced engrafting capacity than the proT1 subset. As proT2 cells exhibit superior engrafting capacity, these cells were tested for their ability to enhance T cell generation following hematopoietic stem cell transplant (HSCT). We observe that when HSCs are coinjected with proT2 cells, a dramatic improvement in HSC-derived T-lymphopoiesis is observed. This Thesis demonstrates that in vitro-derived proT2 cells reorganize the thymus stromal compartment of the host NOD/SCID/γcnull mouse compared to the highly disorganized cortical and medullary compartments in mice not receiving proT cells. This alteration in thymic architecture likely favours the recruitment of BM derived progenitors. Lastly, we address whether functional CD8 T cells can be generated in vitro using hematopoietic stem cells (HSCs) in coculture with OP9-DL1 cells and indeed these cells were capable of proliferating, and secreting effector molecules typical of cytotoxic T cells. Taken together, the ability to generate proT cells and mature T cells from Notch-ligand cultures offers a new tool to study human T cell development.

Notch

hematopoietic stem cell

T cell development

immune-reconstitution

progenitors

hematopoiesis

RHOF PROMOTES MURINE MARGINAL ZONE B CELL DEVELOPMENT

MARUYAMA, MITSUO, MATSUSHITA, TADASHI, NAOE, TOMOKI, KIYOI, HITOSHI, KUNISHIMA, SHINJI, KOJIMA, TETSUHITO, IKAWA, MASAHITO, TAKAGI, AKIRA, IKEJIRI, MAKOTO, SUZUKI, NOBUAKI, KATSUMI, AKIRA, YANASE, SHOUGO, MATSUDA, TAKENORI, KISHIMOTO, MAYUKO

08 1900

No description available.

Marginal Zone B cell

B cell development

Rho GTPase family

RhoF

The Role of Tcrb Subnuclear Positioning in V(D)J Recombination

Chan, Elizabeth Ann Wilcox

January 2014

<p>T cells and B cells each express unique antigen receptors used to identify, eliminate, and remember pathogens. These receptors are generated through a process known as V(D)J recombination, in which T cell receptor and B cell receptor gene loci undergo genomic recombination. Interestingly, recombination at certain genes is regulated so that a single in-frame rearrangement is present on only one allele per cell. This phenomenon, termed allelic exclusion, requires two steps. First, recombination can occur only on one allele at a time. In the second step, additional recombination must be prevented. Though the mechanism of the second step is well-understood, the first step remains poorly understood.</p><p>The first step of recombination necessitates that alleles rearrange one at a time. This could be achieved either through inefficient recombination or by halting further recombination in the presence of recombination. To separate these mechanisms, we analyzed recombination in nuclei unable to complete recombination. We found that rearrangement events accumulated at antigen receptor loci, suggesting that the presence of recombination does not stop additional rearrangements and asynchronous recombination likely results from inefficient recombination at both alleles.</p><p>Association with repressive subnuclear compartments has been proposed to reduce the recombination efficiency of allelically excluded antigen receptor loci. Of the alleleically excluded loci, <italic>Tcrb</italic> alleles are uniquely regulated during development. Other allelically excluded alleles are positioned at the transcriptionally-repressive nuclear periphery prior to recombination, and relocate to the nuclear interior at the stage in which they recombine. However <italic>Tcrb</italic> alleles remain highly associated with the nuclear periphery during rearrangement. Here we provide evidence that this peripheral subnuclear positioning of <italic>Tcrb</italic> alleles does suppress recombination. We go on to suggest that peripheral localization mediates the first step of allelic exclusion.</p><p>In search of the mechanism by which recombination is suppressed on peripheral <italic>Tcrb</italic> alleles, we investigated the subnuclear localization of a recombinase protein. Two recombinase proteins are required for recombination, one of which is recruited to actively transcribing (and more centrally located) DNA. Here we demonstrate that one recombinase protein is unable to localize to peripheral <italic>Tcrb</italic> alleles, potentially serving as the mechanism by which recombination is suppressed on peripheral alleles.</p> / Dissertation

Immunology

Allelic exclusion

T cell

T cell development

T cell receptor

V(D)J recombination

Two sides of the plant nuclear pore complex and a potential link between Ran GTPase and plant cell division

Xu, Xianfeng,

January 2007

Thesis (Ph. D.)--Ohio State University, 2007.

Biochemical characterization of Medicago truncatula root knots induced by Meloidogyne incognita

Guhl, Katherine Elizabeth.

January 2006

Thesis (M.S.)--University of Delaware, 2006. / Principal faculty advisor: Darla J. Sherrier, Dept. of Plant and Soil Science. Includes bibliographical references.

Hormonal control of wood formation in radiata pine : a thesis submitted in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Plant Cell Biology, University of Canterbury /

Welsh, Shayne K.

January 1900

Thesis (Ph. D.)--University of Canterbury, 2006. / Typescript (photocopy). Includes bibliographical references (leaves 109-118). Also available via the World Wide Web.

ELUCIDATING THE ROLE OF POLYBROMO-1 IN TARGETING THE PBAF COMPLEX UNDER STRESS

Elizabeth G Porter (6615521)

15 May 2019

DNA organization is an intricate and dynamic process. The approximately two meters of DNA in a single cell is wrapped around small proteins called histones. Histones can be compacted into dense coils or loosely distributed along DNA, allowing for cells to control gene expression. This combination of DNA and histones forms chromatin. This work has focused on understanding the role of Polybromo1 (PBRM1), which is a member of a chromatin remodeling complex. PBRM1 is mutated in 3% of all human cancers and is mutated in 40% of renal clear cell carcinomas (ccRCC), the most common type of kidney cancer. Through my work characterizing PBRM1 as a tumor suppressor, we have found PBRM1 acts as a stress sensor. PBRM1 is a member of the Polybromo1 BRG1 associating factors (PBAF) complex which is a subtype of the larger BAF family of chromatin remodelers. Although BAF is essential for cell viability, knockdown of PBRM1 shows minor phenotypic changes in many cell types under standard cell culturing conditions. However, when cells without PBRM1 experience external stress, the reactive oxygen species levels in the cells are elevated and remain high compared to cells with wild type PBRM1. Depending on the cellular environment of the cell, increase in ROS can be growth promoting or growth inhibiting. PBRM1 is a structurally unique protein, containing two bromo-adjacent homologs, a high mobility group and six tandem bromodomains. Due to the multiple reader domains, it is likely PBRM1 acts to target the complex. Taking advantage of a RCCC cell line not expressing PBRM1, we re-expressed full length PBRM1 containing an asparagine to alanine mutation in each bromodomain, disrupting the acetyl-lysine binding. We have found that the bromodomains are cooperative and are facilitating binding of PBAF to chromatin. We found defects in PBRM1’s ability to suppress growth, bind to chromatin, and regulate gene expression when any of the bromodomains were mutated besides the third bromodomain. These results correlated with patient data. Using acetylated histone peptides, we have identified potential combinations of marks that PBRM1 prefers over single marks. Further work needs to be done to characterize how these histone modifications are altered under stress and they contribute to the role of PBRM1 in stress response.

Cancer

chromatin remodelling complexes

Polybromo-1

Stress

Characterization of lin-42/period transcriptional regulation by the Ikaros/hunchback-family transcription factor ZTF-16 in Caenorhabditis elegans

Meisel, Kacey Danielle

03 June 2013

The gene lin-42 is an ortholog of the mammalian period gene, a component of the circadian pathway that converts environmental stimuli into behavioral and physiological outputs over 24 hours. Mammalian period also regulates adult stem cell differentiation, although this function is poorly understood. The structure, function and expression of lin-42 are all similar to period. Therefore, we are studying lin-42 regulation and function during C. elegans larval development as a model for understanding period control of mammalian stem/progenitor cell development. Previous work has shown that ZTF-16 is a regulator of lin-42 transcription. The lin-42 locus encodes three isoforms, and we have characterized lin-42 isoform specific regulation by ZTF-16 through phenotypic assays and analysis of transcriptional reporter strains. Our data show that ZTF-16 regulates the cyclic expression of lin-42A and lin-42B during larval development. However, ztf-16 is not expressed during the adult stage and does not regulate lin-42C, which is expressed only in adults and may be responsible for the circadian functions of lin-42. We also show that ztf-16 reduction-of-function mutations phenocopy loss-of- function phenotypes of the lin-42A/B isoforms. Finally, we have found that deletion of a putative ZTF-16 transcription factor binding site within the lin-42BC promoter abolishes tissue-specific expression patterns. Together, these data indicate that ZTF-16 is required to regulate the expression of lin-42A/B during C. elegans development, and may do this by direct binding to the lin-42BC promoter. Our  findings pave the way for testing the possible regulation of period expression by HIL-family transcription factors in mammalian tissues. / Master of Science

lin-42

period

ZTF-16

stem cell development

C. elegans

microbombardment

transcriptional reporter