Dissertations / Theses on the topic 'Phenomena of intergroup differentiation'

This thesis consists of two studies together with a preliminary study, focusing on the issue of ingroup representation of the ü
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group. The first study, addressing the problems of stereotype content, stereotype accuracy, and stereotype consensus, was based on in-depth interviewing with twenty members of the ü
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group. It was hypothesized that the group members, when their social identities were salient, would locate the ingroup within a chronic way of looking at the world, namely the perceived context. The accuracy of stereotypes and the stereotype consensus commonly observed among group members depended upon the efficiency of this perceived context as an explanation. Moreover, the favorability of stereotype content also derived heavily from this perceived context. The second study, based on two hundreds ü
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group members, examined the effects of target group (ingroup, close outgroup, distant outgroup), type of attributes (favorable, unfavorable), comparative context (intragroup, intergroup with close outgroup, intergroup with distant outgroup, multigroup), and level of identification with the ingroup (high-identifiers, low-identifiers) on the perceptions of homogeneity. A number of hypotheses were tested and the following results were found: First, group members perceived the ingroup as more positively homogeneous than both the close and the distant outgroup. Moreover, the close outgroup was perceived as more positively homogeneous than the distant outgroup. In fact, the distant outgroup was perceived as negatively homogeneous. Second, group members perceived both the ingroup and the close outgroup as more positively homogeneous in terms of unfavorable attributes than in terms of favorable ones. On the contrary, they tended to perceive the distant outgroup as more negatively homogeneous in terms of favorable attributes than in terms of unfavorable ones. Third, the above perceptions were less accentuated in the intragroup context, while they were more accentuated in the multigroup context. Fourth, the above perceptions were more accentuated for the high-identifiers than for the low-identifiers. Apart from these main effects, a number of complicated interactions were also discovered and these results were discussed with reference to the relevant literature.

Different cell types in multi-cellular organisms heritably maintain different gene expression patterns despite carrying the same genome; a phenomenon termed epigenetics. It is widely believed that the packaging state of the genome, known as chromatin structure, carries epigenetic information. How chromatin states are inherited and how chromatin structure changes during development, moreover how different epigenomes, such as chromatin and DNA modifications communicate with each other during these processes are important questions. Accordingly, understanding the mechanisms that govern pluripotency and differentiation requires details of chromatin dynamics. The major goal of my doctoral thesis was to understand the genome wide view of chromatin dynamics in embryonic stem cells. My studies centered on two aspects of chromatin dynamics in mouse embryonic stem cells—localization and function of two antagonistic chromatin regulators and genome-wide histone variant dynamics. In the first part, we examined the roles of several chromatin regulators whose loss affects the pluripotent state of ES cells. We found that two such regulators, Mbd3 and Brg1, control a large number of genes in ES cells via antagonistic effects on promoter nucleosome occupancy. Moreover, we found that both Mbd3 and Brg1 play key roles in the biology of 5-hydroxymethylcytosine (5hmC), a newly identified DNA modification. Mbd3, which was named by homology to known cytosine methyl binding domains, yet does not bind methylcytosine in vitro, co-localized in ES cells with 5hmC. Furthermore, Mbd3 localization was lost in knockdown cells lacking the major 5mC hydroxylase, Tet1. Our results suggest, contrary to current dogma, that 5hmC is more than just an intermediate in cytosine demethylation pathways, that it may regulate genes via the Mbd3/NuRD complex. Finally, we showed that both Mbd3 and Brg1 are themselves required for normal levels of 5hmC in vivo, identifying a feedback loop between 5hmC and Mbd3. Together, our results identified a possible effector for 5hmC, thereby suggesting a functional role for this DNA modification. Moreover, Brg1 and Mbd3 can now be added to the growing list of regulators with opposite effects on ES cell gene expression, suggesting that pairs of antagonistic chromatin binding proteins may be a common phenomenon in ES cell transcription regulation (Yildirim et al., Cell 2011). The second part of my dissertation concerns the dynamics of several histone variants. Seminal studies in the Henikoff lab showed that certain histone variants are replaced throughout the cell cycle, in contrast to the predominant replication-coupled mode of histone assembly. Work in yeast and flies showed that rapid histone turnover occurs at epigenetically-regulated genomic regions, such as chromatin boundary elements or Polycomb/Trithorax binding sites. Notably, promoter regions of actively transcribed genes exhibit rapid turnover, suggesting that histone turnover may have an important role in gene regulation, as higher histone turnover rate would provide higher probability of DNA element exposure and faster erasure of chromatin marks of the replaced histones. In order to extend such studies to a model for pluripotency and differentiation, we developed a system for measuring histone replacement in mouse ES cells. To be able to carry out turnover experiments in ES cells, we generated stable ES cell lines that can be induced to express epitope-tagged histone variants. Our results confirmed that histone turnover patterns are conserved from yeast to mammals and that turnover profiles are histone variant specific. Murine H3.3 turnover is similar to H3.3 turnover in flies, with peaks at the promoters of highly transcribed genes. MacroH2A2, a variant generally linked to gene repression, had a more complex turnover profile. Surprisingly, we found rapid exchange of macroH2A2 occurring around transcription start sites of a number of highly expressed genes. At poorly expressed genes, on the other hand, macroH2A2 localizes upstream or downstream of transcription start sites and is incorporated slowly, either via slow turnover or via replication-coupled incorporation. Finally, we have used those inducible ES cell lines to generate mice, which will enable future studies on tissue-specific histone replacement in vivo. In summary, my thesis work not only significantly extends our understanding of chromatin regulation in general but also provides a more detailed landscape of chromatin structure and regulation in ES cells. Extending these analyses to differentiating cells and in vivo tissue specific dynamics should provide us with a better understanding not only of cell type specific chromatin organization but also improve our ability to program and re-program genomic landscapes in vitro.

Proliferation and differentiation are essential processes for the growth and development of higher eukaryotic organisms. Regulation of gene expression is essential for control of cell division and differentiation. Normal eukaryotic cells have a limited proliferative capacity, and ultimately undergo cellular senescence and apoptosis. Terminal differentiation of cells is associated with loss of proliferative capacity and acquisition of specialized functions. Proliferation and differentiation are processes required for the creation and maintenance of diverse tissues both during embryonic development and postnatal life. The cell cycle is the process by which cells reproduce, and requires duplication and segregation of hereditary material. Loss of cell cycle control leads to genetic instability and cancer. Expression of replication-dependent histone genes is tightly coupled to DNA synthesis, thus making histone genes a good model for studying cell cycle regulation. The HiNF-D complex interacts with all five classes (H1, H2A, H2B, H3 and H4) of histone genes in a cell cycle-dependent manner. The CCAAT displacement protein (CDP)/Cux and the tumor suppressor pRB are key components of the HiNF-D complex. However, the molecular interactions that enable CDP/Cux and pRB to form a complex and thus convey cell growth regulatory information onto histone gene promoters are poorly understood. Transient transfection assays show that CDP/Cux represses the histone H4 promoter and that the pRB large pocket domain functions with CDP/Cux as a co-repressor. Direct interaction between CDP/Cux C-terminus and the pRB pocket domain was observed in GST pull-down assays. Furthermore, co-immunoprecipitation assays and immunofluorescence microscopy established that CDP/Cux and pRB form complexes in vivo and associate in situ. pRB interaction and co-repression with CDP/Cux is independent of pRB phosphosphorylation sites, as revealed by GST pull-down assays and transient transfection assays using a series of pRB mutant proteins. Thus, several converging lines of evidence indicate that complexes between CDP/Cux and pRB repress cell cycle-regulated histone gene promoters. CDP/Cux is regulated by phosphorylation and acetylation at the C-terminus, which contains two repressor domains and interacts with histone deacetylase HDAC1. In vivo function of the CDP/Cux C-terminus in development and gene regulation was assessed in genetically targeted mice (Cutl1tm2Ejn, referred to as Cutl1ΔC). The mice express a mutant CDP/Cux protein with a deletion of the C-terminus including the homeodomain. Indirect immunofluorescence microscopy showed that the mutant protein exhibited significantly reduced nuclear localization in comparison to the wildtype protein. Consistent with these data, DNA binding activity of HiNF-D was lost in nuclear extracts derived from mouse embryonic fibroblasts (MEFs) or adult tissues of homozygous mutant (Cutl1 ΔC -/-) mice, indicating the functional loss of CDP/Cux in the nucleus. No significant difference in growth characteristics or total histone H4 mRNA levels was observed between wildtype and Cutl1 ΔC -/- MEFs in culture. However, the histone H4.1 (murine FO108) gene containing CDP/Cux binding sites have reduced expression levels in homozygous mutant MEFs. Stringent control of growth and differentiation appears to be compromised in vivo. Homozygous mutant mice exhibit stunted growth (20-50% weight reduction), a high postnatal death rate of 60-70%, sparse abnormal coat hair and severely reduced fertility. Hair follicle deformities and severely diminished fertility in Cutl1 ΔC -/- mice suggest that CDP/Cux is required for normal development of dermal tissues and reproductive functions. Together the data presented in this dissertation provide new insight into the in vivo functions of CDP/Cux in the regulation of histone gene expression, growth control and differentiation.

Members of the Runx family of transcription factors play essential roles in the differentiation and development of several organ systems. Here we address the contribution of the osteoblast-related Runx gene, Runx2, to the osteogenic and chondrogenic differentiation of mesenchymal stem cells. Using a transgenic mouse model, we observe Runx2 transcription through one of its two known promoters (designated P1 in pre-cartilaginous mesenchymal condensations as early as E9.5. Runx2 gene activity is later repressed at the onset of cartilage formation, both in vivo and in vitro, necessitating examination of the regulation and function of Runx2 in mesenchymal stem cells. We demonstrate that Runx2 gene activity is repressed by the direct interaction of the homeodomain transcription factor Nkx3.2 with the proximal Runx2 P1 promoter. This repression was found to be required for the progression of BMP-induced chondrogenesis, thereby identifying Runx2 as a modulator of BMP activity in the chondrogenic as well as osteogenic differentiation program. To further understand the regulation of the Runx2 P1 promoter and to determine the contribution of P1-derived gene product, Runx2 Type II, to the formation of mineralized tissue, we have generated a Runx2 Type II-LacZ gene replacement mouse model in which the initial coding sequences and splice donor sites of the Type II isoform are replaced with the LacZ reporter gene. Activity of the endogenous P1 promoter can therefore be monitored by β-galactosidase production. Analysis of Runx2 Type II-LacZ mice demonstrates that the P1 promoter is transcriptionally most active in mature osteoblasts, but its product, Runx2 Type II is dispensable for embryonic skeletal formation. Lastly, we examine the link between growth control and osteogenic differentiation by tissue-specific deletion of the Mdm2 proto-oncogene in developing skeletal tissues of the mouse embryo. Loss of Mdm2 results in impaired bone formation, with skeletal elements exhibiting lower bone mineral content and higher porosity. Ex vivo cultures of calvarial osteoprogenitor cells exhibit severely decreased osteoblastogenesis and bone nodule formation accompanied by a failure to activate Runx2 gene activity. These findings suggest that Mdm2 is required for inhibition of p53 activity that ultimately allows for post-confluent proliferation and induction of Runx2 during maturation of the osteogenic phenotype. Taken together, our findings suggest that Runx2 modulates the commitment of progenitor cells to the osteogenic and chondrogenic lineages, and that Runx2 activity is inextricably linked to mechanisms that control cellular proliferation.

Chromatin has a compact organization in which most DNA sequences are structurally inaccessible and functionally inactive. Reconfiguration of thechromatir required to activate transcription. This reconfiguration is achieved by the action of enzymes that covalently modify nucleosomal core histones, and by enzymes that disrupt histone-DNA interactions via ATP hydrolysis. TheSWI/SNF family of ATP-dependent chromatin remodeling enzymes has been implicated not only in gene activation but also in numerous cellular processes including differentiation, gene repression, cell cycle control, recombination and DNA repair. PPARγ, C/EBPα and C/EBPβ are transcription factors with well established roles in adipogenesis. Ectopical expression of each of these factors in non-adipogenic cells is sufficient to convert them to adipocyte-like cells. To determine the requirements of SWI/SNF enzymes in adipocyte differentiation, we introduced PPARγ, C/EBPα or C/EBPβ into fibroblasts that inducibly express dominant-negative versions of the Brahma-Related Gene 1 (BRG1) or human Brahma (BRM), which are the ATPase subunits of the SWI/SNF enzymes. We found that adipogenesis and expression of adipocyte genes were inhibited in the presence of mutant SWI/SNF enzymes. Additionally, in cells expressing C/EBPα or C/EBPβ, PPARγ expression was SWI/SNF dependent. These data indicate the importance of these remodeling enzymes in both early and late gene activation events. Subsequently, we examined by chromatin immunoprecipitation (ChIP) assay the functional role of SWI/SNF enzymes in the activation of PPARγ2, the master regulator of adipogenesis. Temporal analysis of factors binding to the PPARγ2 promoter showed that SWI/SNF enzymes are required to promote preinitiation complex assembly and function. Additionally, our studies concentrated on the role of C/EBP family members in the activation of early and late genes during adipocyte differentiation. During adipogenesis, C/EBPβ and δ are rapidly and transiently expressed and are involved in the expression of PPARγ and C/EBPα, which together activate the majority of the adipocyte genes. Our studies determined the temporal recruitment of the C/EBP family at the promoters of early and late genes by ChIP assay during adipocyte differentiation. We found that all of the C/EBP members evaluated are present at the promoters of early and late genes, and the binding correlated with the kinetics of the C/EBPs expression. Binding of C/EBPβ and δ is transient, subsequently being replaced by C/EBPα. These studies demonstrated that C/EBPβ and δ are not only involved in the regulation of PPARγ and C/EBPα, but also in the activation of late expressed adipocyte genes.

The promoter sequence of the mouse high affinity neurotensin receptor, Ntr-1, gene was cloned and characterized, sequences required for positive regulation in N1E-115 cells were localized, and at least two different peptides from these cells were shown to make specific contacts within the most potent positive regulatory element. A mouse neuroblastoma cell line, N1E-115, treated with 1.5% DMSO for 72 hours induces gene expression of both endogenous Ntr-l, and reporter constructs driven by the NTR-1 promoter, by 3 - 4 fold. The sequence ofthe NTR-1 promoter has no canonical TATA box, but is GC rich and contains consensus SP1, CACCC, CRE, and initiator elements. These elements are located within a 193 base positive regulatory region required for DMSO responsive activity and contains the transcriptional start site. Detailed mutational analysis of this region revealed that a CACCC box and the central region of a large GC rich palindrome are crucial cis-regulatory elements for DMSO induction. The SP1 element, an NGFI-A-related element, and the 5' end of the positive regulatory region are required for maintaining basal expression in N1E-115 cells. Cell type differences in the cis-regulatory elements that mediate both DMSO induction and maintenance of basal expression are observed. Characterization of proteins in N1E-115 cells that make specific contacts within the CACCC element identified at least two peptides with predicted sizes of 57 kd and 97 kd. Two dimensional UV crosslinking indicates that these proteins might contribute to inducible gel shift complexes that require the CACCC element. Several previously characterized CACCC binding proteins, belonging to the Kruppel-like family of transcription factors, were tested by supershift analysis for their ability to contribute to NTR-1 CACCC complexes. In fact, a protein closely related to SP1 does bind the CACCC element in N1E-115 cells, but of the other Kruppel-like protein tested, only BKLF contributes to a minor complex in N1E-115 cells. These results provide evidence for the complex regulation of Ntr-1 gene expression mediated by the cooperation of several cis-regulatory elements including a CACCC Kruppel-like binding element.

The Runx family of transcription factors performs an essential role in animal development by controlling gene expression programs that mediate cell proliferation, growth and differentiation. The work described in this thesis is concerned with understanding mechanisms by which Runx proteins support this program of gene expression within the architectural context of the mammalian cell nucleus. Multiple aspects of nuclear architecture are influenced by Runx2 proteins including sequence-specific DNA binding at gene regulatory regions, organization of promoter chromatin structure, and higher-order compartmentalization of proteins in nuclear foci. This work provides evidence for several functional activities of Runx2 in relation to architectural parameters of gene. expression for the control of cell growth and differentiation. First, the coordination of SWI/SNF mediated chromatin alterations by Runx2 proteins is found to be a critical component of osteoblast differentiation for skeletal development. Several chromatin modifying enzymes and signaling factors interact with the developmentally essential Runx2 C-terminus. A patent-pending microscopic image analysis strategy invented as part of this thesis work - called intranuclear informatics - has contributed to defining the C-terminal portion of Runx2 as a molecular determinant for the nuclear organization of Runx2 foci and directly links Runx2 function with its organization in the nucleus. Intranuclear informatics also led to the discovery that nuclear organization of Runx2 foci is equivalently restored in progeny cells following mitotic division - a natural perturbation in nuclear structure and function. Additional microscopic studies revealed the sequential and selective reorganization of transcriptional regulators and RNA processing factors during progression of cell division to render progeny cells equivalently competent to support Runx2 mediated gene expression. Molecular studies provide evidence that the Runx proteins have an active role in retaining phenotype by interacting with target gene promoters through sequence-specific DNA binding during cell division to support lineage-specific control of transcriptional programs in progeny cells. Immunolocalization of Runx2 foci on mitotic chromosome spreads revealed several large foci with pairwise symmetry on sister chromatids; these foci co-localize with the RNA polymerase I transcription factor, Upstream Binding Factor (UBFl) at nucleolar organizing regions. A series of experiments were carried out to reveal that Runx2 interacts directly with ribosomal DNA loci in a cell cycle dependent manner; that Runx2 is localized to UBF foci within nucleoli during interphase; that Runx2 attenuates rRNA synthesis; and that this repression of ribosomal gene expression by Runx2 is associated with cell growth inhibition and induction of osteoblast-specific gene expression. This thesis has identified multiple novel mechanisms by which Runx2 proteins function within the hierarchy of nuclear architecture to control cell proliferation, growth and differentiation.

PC12 rat pheochromocytoma cells respond to nerve growth factor (NGF) by neuronal differentiation and partial growth arrest. Mouse c-myc and adenovirus E1A genes were introduced into PC12 cells to study the influence of these nuclear oncogenes on neuronal differentiation. Expression of myc and E1A blocked morphological differentiation and caused NGF to stimulate rather than inhibit cell proliferation. NGF binding to cell surface receptors, activation of ribosomal S6 kinase, and ornithine decarboxylase induction were similar in myc and E1A expressing clones compared with wild-type PC12 cells, suggesting that changes in the cellular response to NGF were at a post-receptor level. The ability of myc and E1A expression to block the transcription-dependent induction of microtubule associated proteins by NGF further suggested that these genes may inhibit differentiation by interfering with NGP's ability to regulate transcription. These results illustrate that NGF can promote either growth or differentiation of PC12 cells, and that myc or E1A alter the phenotypic responses to growth factors.

T lymphocytes are distinguished by the expression of αβ TCR or γδ TCR on their cell surface. The kinetic differences in the effector functions classifies γδ T cells as innate-like lymphocytes and αβ T cells as adaptive lymphocytes. Although distinct, αβ and γδ T cell lineages produce a common array of cytokines to mount an effective immune response against a pathogen. The production of cytokine IL-17 is a shared characteristic between the γδ T (Tγδ17) cells and the CD4 T (Th17) cells. γδ T cells develop into Tγδ17 cells in the thymus whereas CD4 T cells differentiate into Th17 cells in response to antigens in the peripheral lymphoid tissues. γδ T cells exported from the thymus, as pre-made effectors, are the early IL-17 producers compared with the late IL-17 producing Th17 cells. In this thesis we describe how TGFβ-SMAD2 dependent pathway selectively regulates Th17 cell differentiation but not Tγδ17 cells generation. We further illustrate the requirement of WNT-HMG box transcription factor (TF) signaling for the thymic programming of Tγδ17 cells. Cytokine TGFβ in co-operation with IL-6 induces the differentiation of Th17 cells. Conversely, TGFβ signaling also regulates the differentiation and maintenance of CD4+FOXP3+ regulatory T cells. The mechanism by which TGFβ signals synergize with IL-6 to generate inflammatory versus immunosuppressive T cell subsets is unclear. TGFβ signaling activates receptor SMADs, SMAD2 and SMAD3, which associate with a variety of nuclear factors to regulate gene transcription. Defining relative contributions of distinct SMAD molecules for CD4 T cell differentiation is critical for mapping the versatile intracellular TGFβ signaling pathways that tailor TGFβ activities to the state of host interaction with pathogens. We show here that SMAD2 is essential for Th17 cell differentiation and that it acts in part by modulating the expression of IL-6R on T cells. While mice lacking SMAD2 specifically in T cells do not develop spontaneous lymphoproliferative autoimmunity, Smad2-/- T cells are impaired in their response to TGFβ in vitro and in vivo and they are more pathogenic than controls when transferred into lymphopenic mice. These results demonstrate that SMAD2 is essential for TGFβ signaling in CD4+ T effector cell differentiation and that it possesses functional capabilities distinct from SMAD3. Although SMAD2 is essential for the differentiation of Th17 cells, TGFβ signaling via SMAD2 is not required for the thymic programming of innate Tγδ17 cells. Among different γδ T cells, Vγ2+ (V2) γδ T cells are the major IL-17 producing subsets. We demonstrate that Sry-high mobility group (HMG) box TFs regulate the development of V2 Tγδ17 cells. We show that the HMG box TF, SOX13 functions in a positive loop for the intrathymic generation of V2 Tγδ17 cells. SOX13 regulates the programming of Tγδ17 cells by controlling the expression of B-lymphoid kinase (BLK) in developing immature V2 γδ T cells. BLK is an Src-family kinase expressed by all Tγδ17 cells. Furthermore, we show another HMG box TF, TCF1, the nuclear effector of canonical WNT signaling, is the primary negative regulator of IL-17 production by all γδ T cells. We propose that the antagonism of SOX13 and TCF1 determines the generation of IL-17 producing γδ T cells. We also show that extrinsic cues from αβ T cells do not affect the generation of IL-17 producing γδ T cells. Using OP9-DL1 culture system, we demonstrate that the progenitors of V2 Tγδ17 cells are the c-Kit+ early thymic precursors.

Jak3, a member of the Janus family of tyrosine kinases, is essential for signaling via the receptors for IL-2, IL-4, IL-7, IL-9, IL-15 and IL-21. These Jak3-dependent cytokines primarily activate STAT5 and are critical for lymphoid generation and differentiation. Using naïve CD4+ T cells from Jak3-deficient mice and wild type CD4+ T cells treated with a pharmacological inhibitor of Jak3, we report that Jak3-dependent cytokine signals are not required for the proliferation of naïve CD4+ T cells. This is illustrated by the similar percentage of divided cells, comparable cell divisions, intact cell cycle progression and unaffected regulation of cell cycle proteins in the absence of Jak3. In contrast to proliferation, differentiation of naïve CD4+ T cells into Th1 effector cells requires Jak3-dependent cytokine signals. In the absence of Jak3, naïve CD4+ T cells proliferate robustly, but produce little IFN-γ after Th1 polarization in vitro. This defect is not due to reduced activation of STAT1 or STAT4, nor to impaired up-regulation of the transcription factor T-bet. Instead, we find that T-bet binding to the Ifng promoter is greatly diminished in the absence of Jak3-dependent signals, correlating with a decrease in Ifng promoter accessibility and histone acetylation. These data indicate that while Jak3-dependent signals are dispensable for naïve CD4+ T cell proliferation, Jak3 regulates epigenetic modification and chromatin remodeling of the Ifng locus during Th1 differentiation.

Somatic cells could be reprogrammed into an ES-like state called induced pluripotent stem cells (iPSCs) by expression of four transcriptional factors: Oct4, Sox2, Klf4 and cMyc. iPSCs have full potentials to generate cells of all lineages and have become a valuable tool to understand human development and disease pathogenesis. However, reprogramming process suffers from extremely low efficiency and the molecular mechanism remains poorly understood. This dissertation is focused on studying the role of small non-coding RNAs (microRNAs) and kinases during the reprogramming process in order to understand how it is regulated and why only a small percentage of cells could achieve fully reprogrammed state. We demonstrate that loss of microRNA biogenesis pathway abolished the potential of mouse embryonic fibroblasts (MEFs) to be reprogrammed and revealed that several clusters of mES-specific microRNAs were highly induced by four factors during early stage of reprogramming. Among them, miR-93 and 106b were further confirmed to enhance iPSC generation by promoting mesenchymal-to-epithelial transition (MET) and targeting key p53 and TGFβ pathway components: p21 and Tgfbr2, which are important barrier genes to the process. To expand our view of microRNAs function during reprogramming, a systematic approach was used to analyze microRNA expression profile in iPSC-enriched early cell population. From a list of candiate microRNAs, miR-135b was found to be most highly induced and promoted reprogramming. Subsequent analysis revealed that it targeted an extracellular matrix network by directly modulating key regulator Wisp1. By regulating several downstream ECM genes including Tgfbi, Nov, Dkk2 and Igfbp5, Wisp1 coordinated IGF, TGFβ and Wnt signaling pathways, all of which were strongly involved in the reprogramming process. Therefore, we have identified a microRNA-regulated network that modulates somatic cell reprogramming, involving both intracellular and extracellular networks. In addition to microRNAs, in order to identify new regulators and signaling pathways of reprogramming, we utilized small molecule kinase inhibitors. A collection of 244 kinase inhibitors were screened for both enhancers and inhibitors of the process. We identified that inhibition of several novel kinases including p38, IP3K and Aurora kinase could significantly enhance iPSC generation, the effects of which were also confirmed by RNAi of specific target genes. Further characterization revealed that inhibition of Aurora A kinase enhanced phosphorylation and inactivation of GSK3β, a process mediated by Akt kinase. All together, in this dissertation, we have identified novel role of both small non-coding RNAs and kinases in regulating the reprogramming of MEFs to iPSCs.

Immunologic self-tolerance is maintained by both central and peripheral mechanisms. Furthermore, regulation of mature lymphocyte responses is governed by inhibitory as well as stimulatory signals. TCR recognition of cognate peptide bound to MHC molecules provides the initial stimulus leading to T lymphocyte activation and determines the antigen specificity of any subsequent response. However, lymphocytes must discriminate between foreign and self antigens presented by self-MHC molecules to maintain self tolerance and avoid pathological autoimmunity. Consequently, TCR ligation alone is reported to result in abortive activation, T cell anergy, apoptosis, and tolerance. Under normal physiological conditions, costimulatory signals modify lymphocyte responsiveness to TCR ligation to prevent autoimmunity while enabling robust responses to foreign antigen. Members of the CD28/B7 superfamily provide the critical secondary signals essential for normal immune cell function. CD28 is an essential positive costimulatory molecule with critical functions in thymic development, lineage commitment, and regulation of peripheral lymphocyte responses to antigenic stimuli. CD28 ligation by APC-expressed B7 molecules alters proximal signaling events subsequent to MHC/TCR interactions, and initiates unique signaling pathways that alter mRNA stability and gene transcription. Furthermore, CD28 signaling is required for regulatory T cell development and function. Thus, CD28 has a central role in both potentiating lymphocyte activation mediated by TCR engagement and regulating peripheral tolerance. In contrast, Ctla-4 mediates an inhibitory signal upon binding B7 molecules on an antigen-presenting cell. Its importance in governing lymphocyte responses is manifested in the fatal lymphoproliferative disorder seen in Ctla-4-/- mice. The lymphocyte proliferation is polyclonal, antigen and CD28 dependent, and arises from defects in peripheral CD4+T cell regulation. The high percentage of peripheral T lymphocytes expressing activation markers is accompanied by lymphocyte infiltration into numerous non-lymphoid tissues and results in death by 3-4 weeks. While still controversial, Ctla-4 signaling has been reported to be essential for induction of peripheral T lymphocyte tolerance in vivo and in some model systems is proposed to regulate both T lymphocyte anergy induction and the immune suppressive effects of some regulatory T cells in the prevention of autoimmunity. Signaling pathways activated by TCR ligation and CD28 costimulation have been extensively characterized. In contrast, the mechanisms mediating Ctla-4 maintenance of tolerance remain largely unknown. Ctla-4 gene expression is tightly controlled during T cell development and activation, and its intracellular localization and expression on the cell surface is regulated by numerous pathways and intermediates. While a tailless Ctla-4 mutant is capable of inhibiting T cell activation, recent studies have shown that a ligand independent form of Ctla-4 is also capable of providing an inhibitory signal to T lymphocytes. In conjunction with the strictly controlled expression kinetics and the perfect amino acid homology between the intracellular domains of mouse and human Ctla-4, this data suggests that Ctla-4 may participate in the modulation or initiation of intracellular signaling pathways. Positive and negative costimulatory receptors on the T cell modify lymphocyte responses by altering both quantitative and qualitative aspects of the lymphocyte response including threshold of activation, cytokine secretion, and memory responses. Positive costimulation augments T cell responses, in part, by downregulating the expression of genes that actively maintain the quiescent phenotype. This study was initiated to determine the role of Ctla-4 ligation in modifying the global gene expression profile of stimulated T cells and to determine if the Ctla-4 mediated maintenance of T cell tolerance was achieved, in part, by altering the transcription of quiescence genes necessary for the prevention of T cell activation subsequent to TCR and CD28 stimulation. Previous studies investigating the influence of Ctla-4 ligation on transcriptional profiles of activated lymphocytes detected only quantitative alterations in the transcriptional regulation initiated by CD28 signaling. In contrast, our data suggests that quantitative effects of Ctla-4 ligation that differentially influence pathways acting downstream of stimulatory receptors results in a stable and qualitatively unique phenotype detectable at the level of the transcriptome. Thus, the cumulative effect of Ctla-4 signaling is unique and not constrained to reversing alterations in expression initiated by CD28. In addition, Ctla-4 ligation can be shown to influence T lymphocyte responsiveness and the resulting global expression profile within 4 hours after stimulation and prior to detectable Ctla-4 surface expression. In a subpopulation of T cells, TCR stimulation activates pathways that result in commitment to activation with 2-6 hours. In contrast, CD28 signaling must be maintained for 12-16 hours to ensure maximal responses at the population level. The period of sensitivity to Ctla-4 inhibition of activation is more constrained and does not extend beyond 12 hours. Together, these data support a potential role for Ctla-4 in modification of the early transcriptional response and may explain various alterations in phenotype resulting from Ctla-4 ligation that have been reported in secondary responses. Identification of genes involved in lymphocyte activation, maintenance of selftolerance, and attenuation of immune responses opens the door to therapeutic manipulation of the pathways implicated. CD28 costimulation results in general amplification of TCR-initiated transcriptional responses, and specifically alters the expression profile of a subset of genes. In contrast, Ctla-4 ligation directly and specifically alters the expression of a select group of genes when ligated, and results in minimal suppression of the global CD28-mediated costimulatory transcriptional response. Ctla-4 regulated genes comprise a heterogeneous family, but include known quiescence factors, transcriptional regulators, and various determinants of cell cycle progression and senescence. The role of Ctla-4 in maintaining self-tolerance indicates that targeted manipulation of these gene products presents a novel therapeutic opportunity, and suggests that the mechanisms involved in Ctla-4-mediated maintenance of peripheral T cell tolerance and regulation of immune responsiveness is more nuanced than previously thought. In addition, this study provides the most comprehensive description of global gene expression during primary lymphocyte activation yet available. The integration of statistical and bioinfomatics analyses with large scale data mining tools identifies genes not previously characterized in lymphocytes and can direct future work by predicting potentially interacting gene products and pathways.

Mature αβ and γδ T cells arise from a common precursor population in the thymus. Much debate has focused on the mechanism of T cell lineage choice made by these multi-potential precursor cells. It is widely believed that the decision of these precursor cells to commit to the γδ or αβ T cell lineages is regulated primarily by a specific instructive signal relayed through the appropriate T cell receptor. Contrary to this model, we present evidence for a TCR-independent lineage commitment process. Comparison of global gene expression profiles from immature αβ and γδ lineage thymocytes identified Sox13, an HMG-box transcription factor, as a γδ T cell-specific gene. Unlike other HMG-box transcription factors such as TCF1, LEF1 and SOX4, that are critical for proper αβ T cell development, Sox13 expression is restricted to early precursor subsets and γδ lineage cells. Importantly, SOX13 appears to influence the developmental fate of T cell precursors prior to T cell receptor expression on the cell surface. Transgenic over-expression of Sox13 in early T cell precursors strongly inhibits αβ lineage development, in part, by inhibiting precursor cell proliferation and concomitantly, leading to increased cell death among αβ lineage subsets. Steady-state γδ T cell numbers, however, appear unaffected. Strikingly, the DP αβ lineage cells that do develop in Sox13 transgenic mice are imprinted with a γδ- or precursor-like molecular profile, suggesting that SOX13 plays an active role in the lineage fate decision process or maintenance. Sox13-deficient mice, on the other hand, have selectively reduced numbers of γδ thymocytes, indicating that SOX13 is essential for proper development of γδ T cells. We present additional data demonstrating that SOX13 is a canonical WNT signaling antagonist modulating TCF1 activity, raising a strong possibility that WNT signals, and their modulators, are at the nexus of γδ versus αβ T cell lineage commitment.

Чебанова Т. О. Соціальні детермінанти міжгрупової диференціації гендерних груп : кваліфікаційна робота магістра спеціальності 053 «Психологія» / наук. керівник М. Г. Ткалич. Запоріжжя : ЗНУ, 2020. 83 с.
UA : Робота викладена на 83 сторінці, 2 рисунка, 6 таблиць. Перелік посилань включає 68 джерел. Об’єкт дослідження: міжгрупова диференціація як соціально-психологічний феномен. Основою для формування гендерних відносин є поляризація, диференціація позицій чоловіків і жінок (як представників різних гендерних груп), яка, на наш погляд, пов’язана з феноменами нерівності, домінування, влади, підпорядкування. При цьому, важливим є не лише усвідомлення приналежності до певної гендерної групи і ідентифікації з нею, – актуальним є налагодження відносин між членами різних груп як загалом, так і зокрема. Аспектів життя, де чоловіки та жінки зустрічаються задля безпосередньої взаємодії безліч – це соціальна, економічна, політична, культурна, сімейна, сексуальна та інші сфери. На наш погляд, знання механізмів взаємодії гендерних груп та міжгрупової диференціації дозволить уникнути негативних наслідків взаємодії та налагодити співпрацю в будь-якій сфері життя: професійної, сімейної, особистої та ін. Наукова новизна кваліфікаційної роботи полягає в а) визначенні особливостей впливу феноменів інгрупового фаворитизму та аутгрупової дискримінації при взаємодії гендерних груп; б) розробці практичного підходу до впровадження програми подолання негативних наслідків міжгрупової диференціації в гендерних групах в процесі їх взаємодії.
EN : The work is set out on 83 pages, 2 figures, 6 tables. The list of links includes 68 sources. Object of study: Intergroup differentiation as a socio-psychological phenomenon. The basis for the formation of gender relations is the polarization, differentiation of the positions of men and women (as representatives of different gender groups), which, in our opinion, is related to the phenomena of inequality, domination, power, subordination. Not only is awareness of and identification with a particular gender group important, it is also important to establish relationships between members of different groups, both in general and in particular. Aspects of life where men and women meet for the sake of direct interaction are many - social, economic, political, cultural, family, sexual and other spheres. In our opinion, knowledge of the mechanisms of interaction between gender groups and intergroup differentiation will avoid the negative consequences of interaction and establish cooperation in any sphere of life: professional, family, personal and others. The scientific novelty of the qualification work is a) to determine the features of the influence of the phenomena of group favoritism and outgroup discrimination in the interaction of gender groups; b) developing a practical approach to the implementation of the program to overcome the negative effects of intergroup differentiation in gender groups in the process of their interaction.

The Rho family GTPases Cdc42 and Rac1 are critical regulators of the actin cytoskeleton and are essential for skin and hair function. Wiskott-Aldrich syndrome family proteins act downstream of these GTPases, controlling actin assembly and cytoskeletal reorganization, but their role in epithelial cells has not been characterized in vivo. Here, we used a conditional knockout approach to assess the role of neural Wiskott-Aldrich syndrome protein (N-WASP), the ubiquitously expressed Wiskott-Aldrich syndrome-like (WASL) protein, in mouse skin. We found that N-WASP deficiency in mouse skin led to severe alopecia, epidermal hyperproliferation, and ulceration, without obvious effects on epidermal differentiation and wound healing. Further analysis revealed that the observed alopecia was likely the result of a progressive and ultimately nearly complete block in hair follicle (HF) cycling by 5 months of age. N-WASP deficiency also led to abnormal proliferation of skin progenitor cells, resulting in their depletion over time. Furthermore, N-WASP deficiency in vitro and in vivo correlated with decreased GSK-3beta phosphorylation, decreased nuclear localization of beta-catenin in follicular keratinocytes, and decreased Wnt-dependent transcription. Our results indicate a critical role for N-WASP in skin function and HF cycling and identify a link between N-WASP and Wnt signaling. We therefore propose that N-WASP acts as a positive regulator of beta-catenin-dependent transcription, modulating differentiation of HF progenitor cells.