Global ETD Search

41	Erythroid Kruppel-Like Factor and the Cell Cycle: A Role beyond Globin Gene Regulation Michael Tallack Unknown Date (has links) Erythropoiesis, the process of producing mature erythrocytes from the haematopoietic stem cells (HSCs) that reside in the bone marrow, is tightly regulated at both the cell and molecular level by a well defined set of extracellular cytokine signals and intracellular transcription factors. Diseases affecting erythropoiesis are among the most commonly inherited conditions and result from disturbances to the cellular and molecular events that normally regulate this process. Erythroid Kruppel-like factor (EKLF/KLF1) is a transcription factor that is essential for erythropoiesis. EKLF is the founding member of the Kruppel-like factor family of transcription factors that bind to GC rich CACC-Box elements within gene promoters and activate transcription. The β-like globin genes are critical targets of EKLF through its binding at sites within the proximal promoters and the upstream locus control region (LCR) enhancer. Mice lacking EKLF die prior to birth by E16 with a phenotype that closely resembles the human disease thalassaemia. Thalassaemia is due to mutations in the α or β-globin genes, leading to globin chain imbalance, red cell destruction and ineffective erythropoiesis. However, restoration of expression of γ-globin (a β-like gene) failed to prevent embryonic lethality in EKLF knockout mice and suggested that additional target genes were critical to erythropoiesis. This thesis describes investigation into the transcriptional network of EKLF and an in depth analysis of previously uncharacterised phenotypes present in the EKLF knockout mouse. I have identified a suite of target genes for EKLF that include critical components of the cells cycle. I have also tested the hypothesis that EKLF is able to function in vivo as a tumour suppressor gene. Additionally, I report a role for EKLF in the determination of cell fate within the haematopoietic system and describe the development of a new approach to globally understanding erythroid transcription factor function. A previously performed microarray transcriptional profiling study provided a set of potential target genes for EKLF. I have expanded on this study by identifying that the cell cycle genes p18INK4c, and E2f2 are direct transcriptional targets of EKLF, where binding of EKLF occurs at the promoter and a novel intronic enhancer region, respectively. I have also described a previously undiscovered cell cycle phenotype of aberrant entry into S-phase in EKLF -/- erythroid cells that is directly related to abrogated expression of E2f2. The Kruppel-like factor family of genes have been implicated as players in the tumour process. By constructing a model for the loss of EKLF within HSCs in vivo, I have tested whether EKLF is functional as a tumour suppressor. The loss of EKLF in vivo was found to be insufficient to generate erythroleukaemia, however did result in erythroid hyperplasia, extramedullary haematopoieis and a mild macrocytic anaemia. In addition to regulation of erythropoiesis, EKLF performs a critical role in the lineage choice for a megakaryocyte-erythroid progenitor (MEP) between the megakaryocytic and erythroid lineages. This thesis describes that in the absence of EKLF, MEPs fail to commit properly to either lineage and proceed along a promiscuous pathway sharing the hallmarks of both megakaryocytes and erythroid cells. A detailed molecular mechanism for this phenotype remains undetermined, but is likely to involve interactions with the megakaryocyte transcription factor Fli1 and other members of the Kruppel-like factor family, such as BKLF (KLF3). While the transcriptional mechanisms that drive erythropoiesis have been slowly discovered, the development of chromatin immunoprecipitation (ChIP) assays and next generation DNA sequencing technology has presented the potential to rapidly enhance the progression of these studies. In this thesis I describe the development of ChIP-seq using Applied Biosystems SOLiD technology, an approach to rapidly identify binding sites for erythroid transcription factors in an unbiased genome wide approach. The work described in this thesis has expanded the transcriptional network of EKLF to include critical components of the cell cycle and has suggested many additional target genes from ChIP-seq requiring validation. As one of the major transcription factor players during erythropoiesis, EKLF performs many critical functions that include the regulation of the cell cycle, lineage selection and erythroid development. I suggest that current and future studies of EKLF function will influence our understanding of erythropoiesis and refine our understanding of human conditions such as thalassaemia and erythroleukaemia. Eklf Transcription Factor Erythropoiesis cell cycle E2f p18INK4c Tumour Suppressor Megakaryopoiesis chromatin immunoprecipitation Erythroleukaemia
42	Studies of the Ribosomal Protein S19 in Erythropoiesis / Studier av Ribosom-protein S19 i erytropoesen Matsson, Hans January 2004 (has links) <p>Ribosomal proteins are components of the ribosome, the protein synthesis machinery. The ribosomal protein S19 gene (<i>RPS19</i>) is mutated in Diamond-Blackfan anemia, DBA, which is a rare congenital anemia with absence or reduction of erythroid precursors in bone marrow. In this thesis, the role of RPS19 in erythropoiesis is investigated.</p><p>A genetic analysis of <i>RPS19</i> in 24 DBA cases was performed. Four novel <i>RPS19</i> mutations were identified with evidence of wide clinical expression of the disease.</p><p>Due to the clinical overlap in Transient Erythroblastopenia of Childhood, TEC, and DBA, the two diseases may be caused by a common genetic factor. In a study of seven TEC families, all affected shared at least one parental haplotype in the <i>RPS19</i> gene region. Coding exons of <i>RPS19</i> were normal for all affected, although mutations in intronic and regulatory sequences are not excluded. This indicates a genetic factor behind TEC and a possible association between <i>RPS19</i> and TEC. </p><p>To investigate the role of RPS19 in erythropoiesis in a mammal, we created a mouse model for the targeted disruption of the homologue <i>Rps19</i> on the C57BL/6J genetic background. Null mutants are embryonic lethal prior to implantation. The <i>Rps19</i><sup>+/-</sup> mice, however, are viable with normal development including the hematopoietic system. The <i>Rps19</i> transcript level in <i>Rps19</i><sup>+/-</sup> mice is normal. Accordingly, RPS19 protein levels are similar in <i>Rps19</i><sup>+/-</sup> and <i>Rps19</i><sup>+/+</sup> mice. This argues for a transcriptional up-regulation to compensate for the loss of one <i>Rps19</i> allele. </p><p>Peripheral blood is normal in <i>Rps19</i><sup>+/-</sup> mice also on the FVB/NJ strain which argues against strain-specific effects of the <i>Rps19</i> disruption. Preliminary results indicate a reduced erythroid proliferation in response to erythropoietin in <i>Rps19</i><sup>+/-</sup> mice, suggesting the requirement of both <i>Rps19</i> alleles for normal erythroid proliferation under stress. This would support a mechanism by which haplo-insufficiency for RPS19 causes DBA.</p> Molecular genetics RPS19 Rps19 erythropoiesis erythroblastopenia Diamond-Blackfan anemia Genetik Genetics Genetik
43	Identification of Epo-independent red cell progenitors : the E-cad+ progenitors Lemke, Britt January 2004 (has links) Erythrozyten zählen zu den am häufigsten vorkommenden terminal differenzierten Zelltypen des menschlichen Körpers. Durchschnittlich werden täglich ca. 2 x 1011 von ihnen im Körper eines erwachsenen Menschen produziert. Die reifen Erythrozyten entstehen aus multipotenten hämatopoetischen Stammzellen, die über Stadien von erythroiden Vorläuferzellen, erst den sogenannten burst forming units-erythroid (BFU-E) und später den colony forming units-erythroid (CFU-E), zu kernlosen hämoglobinisierten Zellen differenzieren. <br /> <br /> Für die Untersuchung der molekularen Mechanismen der humanen Erythropoese ist die effektive in vitro Amplifizierung einer weitgehend homogenen Population der Vorläuferzellen der einzelnen Entwicklungsstadien notwendig. Den Wachstumsfaktoren stem cell factor (SCF) und Erythropoietin (Epo) fällt dabei eine entscheidende Rolle zu. Unter ihrem synergistischen Einfluß lassen sich Epo-abhängige Zellpopulationen, die sich aus BFU-E und CFU-E Typ Zellen zusammensetzen, ausreichend amplifizieren (Panzenböck et al., 1998). Freyssinier et al., 1999 beschrieb erstmals die Isolierung einer Epo-unabhängigen Population von Vorläuferzellen (CD36+ Vorläuferzellen), die ebenfalls erythroide Eigenschaften aufweisen.<br /> <br /> Ziel dieser Arbeit war die Isolierung und Charakterisierung von Epo-unabhängigen Vorläuferzellen, die eine frühe erythroide und möglichst homogene Vorläuferzellpopulation darstellen und möglicherweise ein höheres Proliferationspotential aufweisen.<br /> <br /> Für die Identifizierung der Epo-unabhängigen Vorläuferzellen, wurden CD34+ Zellen aus Nabelschnurblut aufgereinigt und unter serumfreien Kulturbedingungen und unter Zusatz der Wachstumsfaktoren SCF, Interleukin 3 (IL-3) und eines Fusionsproteins aus IL-6 und löslichem IL-6 Rezeptor (hyper-IL-6) über einen Zeitraum von 8 Tagen kultiviert. Anschließend wurde eine Population von E-cadherin positiven (E-cad+) Zellen über immunomagnetische Selektion isoliert. Diese neu gewonnenen Epo-unabhängigen E-cad+ Vorläuferzellen wurden hinsichtlich ihres proliferativen Potentials und ihrer Differenzierungseigenschaften mit SCF/Epo-Vorläuferzellen und CD36+ Vorläuferzellen verglichen. Von allen drei Zelltypen wurden des weiteren detailierte molekulargenetische Analysen mittels DNA microarray Technologie durchgeführt und die resultierenden Genexpressionsmuster miteinander verglichen.<br /> <br /> Die Ergebnisse zeigen, dass die E-cad+ Vorläuferzellen eine frühe, weitgehend homogene Epo-unabhängige Population vom BFU-E Typ darstellen und durch entsprechende Änderungen der Kulturbedingungen zu einer in vitro Differenzierung angeregt werden können. Die E-cad+ Vorläuferzellen sind hinsichtlich ihres proliferativen Potentials, ihrer Reaktion auf verschiedene Wachstumsfaktoren, der Expression spezifischer Oberflächenmoleküle und ihrer Genexpressionsmuster mit SCF/Epo-Vorläuferzellen und CD36+ Vorläuferzellen vergleichbar.<br /> <br /> Aufgrund der Identifizierung unterschiedlich exprimierter Gene zwischen den Epo-unabhängigen E-cad+ und den Epo-abhängigen SCF/Epo Vorläuferzellen konnten Kanditatengene wie Galectin-3, Cyclin D1, der Anti-Müllerian Hormonrezeptor, Prostata-Differenzierungsfaktor und insulin-like growth factor binding protein 4 identifiziert werden, die als potentielle Regulatoren der Erythropoese in Betracht kommen könnten. Es konnte weiterhin gezeigt werden, dass CD36+ Vorläuferzellen, die aus der selben Zellpopulation wie die E-cad+ Vorläuferzellen immunomagnetisch selektioniert wurden, eine heterogene Population darstellen, die sowohl E-cadherin positive als auch negative Zellen enthält. Die Analyse der Genexpressionsmuster zeigte, dass in den CD36+ Vorläuferzellen zwar auch die Expression erythroid-spezifischen Gene nachgewiesen werden kann, hier aber im Gegensatz zu den E-cad+ Vorläuferzellen auch für Megakaryozyten spezifische Gene stark exprimiert sind.<br /> <br /> Die Ergebnisse dieser Arbeit tragen zu einem neuen Modell der in vivo Abläufe der Entwicklung roter Blutzellen bei und werden der weiteren Untersuchung der molekularen Mechanismen der Erythropoese dienen. / Red cell development in adult humans results in the mean daily production of 2x1011 erythrocytes. Mature hemoglobinized and enucleated erythrocytes develop from multipotent hematopoietic stem/progenitor cells through more committed progenitor cell types such as BFU-E and CFU-E. The studies on the molecular mechanisms of erythropoiesis in the human system require a sufficient number of purified erythroid progenitors of the different stages of erythropoiesis. Primary human erythroid progenitors are difficult to obtain as a homogenous population in sufficiently high cell numbers. Various culture conditions for the in vitro cell culture of primary human erythroid progenitors have been previously described. Mainly, the culture resulted in the generation of rather mature stages of Epo-dependent erythroid progenitors. In this study our efforts were directed towards the isolation and characterization of more early red cell progenitors that are Epo-independent.<br /> <br /> To identify such progenitors, CD34+ cells were purified from cord blood and cultured under serum free conditions in the presence of the growth factors SCF, IL-3 and hyper-IL-6, referred to as SI2 culture conditions. By immunomagnetic bead selection of E-cadherin (E-cad) positive cells, E-cad+ progenitors were isolated. These Epo-independent E-cad+ progenitors have been amplified under SI2 conditions to large cell numbers. The E-cad+ progenitors were characterized for surface antigen expression by flow cytometry, response to growth factors in proliferation assay and for their differentiation potential into mature red cells. Additionally, the properties of E-cad+ progenitors were compared to those of two other erythroid progenitors: Epo-dependent progenitors described by Panzenböck et al. (referred to as SCF/Epo progenitor), and CD36+ progenitors described by Freyssinier et al. (Panzenböck et al., 1998; Freyssinier et al., 1999). Finally, the gene expression profile of E-cad+ progenitors was compared to the profiles of SCF/Epo progenitors and CD36+ progenitors using the DNA microarray technique.<br /> <br /> Based on our studies we propose that Epo-independent E-cad+ progenitors are early stage, BFU-E like progenitors. They respond to Epo, despite the fact that they were generated in the absence of Epo, and can completely undergo erythroid differentiation. Furthermore, we demonstrate that the growth properties, the growth factor response and the surface marker expression of E-cad+ progenitors are similar to those of the SCF/Epo progenitors and the CD36+ progenitors. By the comparison of gene profiles, we were also able to demonstrate that the Epo-dependent and Epo-independent red cell progenitors are very similar. Analyzing the molecular differences between E-cad+ and SCF/Epo progenitors revealed several candidate genes such as galectin-3, cyclin D1, AMHR, PDF and IGFBP4, which are potential regulators involved in red cell development. We also demonstrate that the CD36+ progenitors, isolated by immunomagentic bead selection, are a heterogeneous progenitor population containing an E-cad+ and an E-cad- subpopulation. Based on their gene expression profile, CD36+ progenitors seem to exhibit both erythroid and megakaryocytic features.<br /> <br /> These studies led to a more updated model of erythroid cell development that should pave the way for further studies on molecular mechanisms of erythropoiesis. Life sciences
44	Studies of the Ribosomal Protein S19 in Erythropoiesis / Studier av Ribosom-protein S19 i erytropoesen Matsson, Hans January 2004 (has links) Ribosomal proteins are components of the ribosome, the protein synthesis machinery. The ribosomal protein S19 gene (RPS19) is mutated in Diamond-Blackfan anemia, DBA, which is a rare congenital anemia with absence or reduction of erythroid precursors in bone marrow. In this thesis, the role of RPS19 in erythropoiesis is investigated. A genetic analysis of RPS19 in 24 DBA cases was performed. Four novel RPS19 mutations were identified with evidence of wide clinical expression of the disease. Due to the clinical overlap in Transient Erythroblastopenia of Childhood, TEC, and DBA, the two diseases may be caused by a common genetic factor. In a study of seven TEC families, all affected shared at least one parental haplotype in the RPS19 gene region. Coding exons of RPS19 were normal for all affected, although mutations in intronic and regulatory sequences are not excluded. This indicates a genetic factor behind TEC and a possible association between RPS19 and TEC. To investigate the role of RPS19 in erythropoiesis in a mammal, we created a mouse model for the targeted disruption of the homologue Rps19 on the C57BL/6J genetic background. Null mutants are embryonic lethal prior to implantation. The Rps19+/- mice, however, are viable with normal development including the hematopoietic system. The Rps19 transcript level in Rps19+/- mice is normal. Accordingly, RPS19 protein levels are similar in Rps19+/- and Rps19+/+ mice. This argues for a transcriptional up-regulation to compensate for the loss of one Rps19 allele. Peripheral blood is normal in Rps19+/- mice also on the FVB/NJ strain which argues against strain-specific effects of the Rps19 disruption. Preliminary results indicate a reduced erythroid proliferation in response to erythropoietin in Rps19+/- mice, suggesting the requirement of both Rps19 alleles for normal erythroid proliferation under stress. This would support a mechanism by which haplo-insufficiency for RPS19 causes DBA. Molecular genetics RPS19 Rps19 erythropoiesis erythroblastopenia Diamond-Blackfan anemia Genetik Genetics Genetik
45	Ribosomal Proteins in Diamond-Blackfan Anemia : Insights into Failure of Ribosome Function Badhai, Jitendra January 2009 (has links) Diamond-Blackfan anemia (DBA) is a severe congenital anemia characterized by a defect in red blood cell production. The disease is associated with growth retardation, malformations, a predisposition for malignant disease and heterozygous mutations in either of the ribosomal protein (RP) genes RPS7, RPS17, RPS19, RPS24, RPL5, RPL11 and RPL35a. In a cellular model for DBA, siRNA knock-down of RPS19 results in a relative decrease of other ribosomal (r) proteins belonging to the small subunit (RPS20, RPS21, RPS24) when compared to r-proteins from the large ribosomal subunit (RPL3, RPL9, RPL30, RPL38). RPS19 mutant cells from DBA patients show a similar and coordinated down-regulation of small subunit proteins. The mRNA levels of the small subunit r-proteins remain relatively unchanged. We also show that RPS19 has an extensive number of transcriptional start sites resulting in mRNAs of variable 5’UTR length. The short variants are translated more efficiently. Structural sequence variations in the 5’UTR of RPS19 found in DBA patients show a 20%-30% reduced translational activity when compared to normal transcripts. Primary fibroblast from DBA patients with truncating mutations in RPS19 or RPS24 showed specific cell cycle defects. RPS19 mutant fibroblasts accumulate in the G1 phase whereas the RPS24 mutant cells show a defect in G2/M phase. The G1 phase arrest is associated with a reduced level of phosphorylated retinoblastoma (Rb) protein, cyclin E and cdk2 whereas the G2/M phase defect is associated with increased levels of p21, cyclin E, cdk4 and cdk6. RPS19 interacts with PIM-1 kinase. We investigated the effects of targeted disruptions of both Rps19 and Pim-1 in mice. Double mutant (Rps19+/-, Pim-1-/-) mice have increased peripheral white- and red blood cell counts when compared to the wild-type mice (Rps19+/+, Pim-1+/+). Bone marrow cells in Rps19+/-, Pim-1-/- mice showed up-regulated levels of c-Myc and the anti-apoptotic factors Bcl2, Bcl-xl and Mcl-1 and reduced levels of the apoptotic factors Bak and Caspase 3 as well as the cell cycle regulator p21. In summary, this thesis clarifies several mechanisms in the pathogenesis of DBA. Mutations in RPS19 results in coordinated down-regulation of several small subunit r-proteins causing haploinsufficiency for the small ribosomal subunit. RPS19 have multiple transcriptional start sites and mutations in the RPS19 5’UTR found in DBA patients result in reduced translational activity. At the cellular level, mutations in RPS19 and RPS24 cause distinct cell cycle defects and reduced cell proliferation. Finally, PIM-1 kinase and RPS19 cooperates in the proliferation of myeloid cells. Diamond-Blackfan anemia RPS19 Ribosomal proteins Haploinsufficiency cell cycle Apoptosis Erythropoiesis Medical genetics Medicinsk genetik
46	Understanding the Mechanism of Aberrant FLVCR1 Splicing and Disrupted erythropoiesis in Diamond-Blackfan Anemia Aidoo, Francisca Ama 24 July 2012 (has links) Diamond Blackfan Anemia (DBA) is a congenital disorder characterized by a specific reduction in erythroid progenitor cells. Approximately 55% of patients have heterozygous mutations in ribosomal protein with 25% of these mutations in RPS19. However, it is unclear how a defect in ribosomal proteins specifically disrupts erythroid development. FLVCR1, a heme exporter, has been implicated as a potential DBA factor. FLVCR1 is essential for erythropoiesis as its disruption leads to apoptosis and disrupted erythroid differentiation. Though no FLVCR1 mutations have been found in DBA patients, our lab has shown that it is aberrantly spliced in DBA erythroid cells. Using RPS19 reduced K562 erythroid cells, I found that disruption of RPS19 leads to aberrant FLVCR1 splicing, disrupted erythropoiesis and reduced Tra2-β, ASF2 and SRp30c protein expression. This was specific to DBA as I did not find these features in a cell culture model of Shwachmann Diamond Syndrome, another ribosomal disorder. Diamond-Blackfan Anemia FLVCR1 aberrant splicing RPS19 Erythropoiesis SR proteins Tra2Beta
47	Understanding the Mechanism of Aberrant FLVCR1 Splicing and Disrupted erythropoiesis in Diamond-Blackfan Anemia Aidoo, Francisca Ama 24 July 2012 (has links) Diamond Blackfan Anemia (DBA) is a congenital disorder characterized by a specific reduction in erythroid progenitor cells. Approximately 55% of patients have heterozygous mutations in ribosomal protein with 25% of these mutations in RPS19. However, it is unclear how a defect in ribosomal proteins specifically disrupts erythroid development. FLVCR1, a heme exporter, has been implicated as a potential DBA factor. FLVCR1 is essential for erythropoiesis as its disruption leads to apoptosis and disrupted erythroid differentiation. Though no FLVCR1 mutations have been found in DBA patients, our lab has shown that it is aberrantly spliced in DBA erythroid cells. Using RPS19 reduced K562 erythroid cells, I found that disruption of RPS19 leads to aberrant FLVCR1 splicing, disrupted erythropoiesis and reduced Tra2-β, ASF2 and SRp30c protein expression. This was specific to DBA as I did not find these features in a cell culture model of Shwachmann Diamond Syndrome, another ribosomal disorder. Diamond-Blackfan Anemia FLVCR1 aberrant splicing RPS19 Erythropoiesis SR proteins Tra2Beta
48	Διερεύνηση του μηχανισμού αναιμίας στη χρόνια λεμφογενή λευχαιμία σε μοριακό και κυτταρικό επίπεδο / Investigation of mechanisms of anemia in CLL in molecular and cellular level Τσοπρά, Όλγα 19 August 2009 (has links) Η αναιμία σχετιζόμενη με τη νόσο στη χρόνια λεμφογενή λευχαιμία (ΧΛΛ) είναι διάγνωση εξ΄ αποκλεισμού και διαπιστώνεται στις περιπτώσεις που δεν ανευρίσκεται άλλο εμφανές αίτιο αναιμίας. Δεδομένου ότι η παθογένεια της αναιμίας αυτής δεν είναι διευκρινισμένη, μελετήσαμε διάφορες παραμέτρους της ερυθροποίησης σε πρωτοδιαγνωσθέντες ασθενείς με ΧΛΛ και αναιμία σχετιζόμενη με τη νόσο και τις συγκρίναμε με τα αντίστοιχα ευρήματα ασθενών με ΧΛΛ χωρίς αναιμία και χωρίς να έχουν λάβει θεραπεία και με αυτά των υγιών μαρτύρων. Η διήθηση του μυελού των οστών από τα κακοήθη Β-λεμφοκύτταρα δεν ήταν αποκλειστικά υπεύθυνη για την πρόκληση αναιμίας. Τα CD34+ κύτταρα του μυελού των οστών στη ΧΛΛ δεν εμφάνισαν ενδογενή διαταραχή στη στροφή και περαιτέρω διαφοροποίησή τους προς την ερυθρά σειρά. Επιπλέον, δε διαπιστώθηκαν ανεπαρκή επίπεδα ερυθροποιητίνης ορού ούτε ελαττωματική απάντηση των ερυθροποιητικών προδρομικών κυττάρων στην ΕΡΟ στον άξονα ΕΡΟ-ΕΡΟ υποδοχέα κατά τη διέγερσή τους με ΕΡΟ ± TNF-α. Από την άλλη μεριά, τα επίπεδα του TNF-α βρέθηκαν αυξημένα στους ασθενείς με ΧΛΛ και αναιμία σχετιζόμενη με τη νόσο και φάνηκε ο TNF-α να ασκεί άμεση κατασταλτική δράση στη διαφοροποίηση των CD34+ κυττάρων προς κύτταρα της ερυθράς σειράς in vitro. Η μελέτη μας έδειξε ότι η αναιμία σχετιζόμενη με τη νόσο στη ΧΛΛ δεν οφείλεται σε ενδογενείς διαταραχές των ερυθροποιητικών προδρομικών κυττάρων, αλλά πιθανότατα να αποδίδεται στην απευθείας κατασταλτική επίδραση του TNF-α . / Disease-related anemia in chronic lymphocytic leukemia (CLL) occurs when the obvious causes are excluded while its pathogenesis is still obscure. To investigate its underlying mechanisms we studied parameters of erythropoiesis at cellular and molecular level in newly diagnosed CLL patients with disease-related anemia in comparison with those of non-anemic CLL patients and normal controls. Bone marrow (BM) infiltration by leukemic B cells was not exclusively responsible for the presence and the severity of disease-related anemia and BM CD34+ cells were intrinsically capable of generating erythroid precursors. No deficiency of serum erythropoietin (EPO) or defective intracellular response of erythroid precursors to EPO ± Tumor Necrosis Factor-α (TNF-α) stimulation was also observed. On the other hand, serum TNF-α levels were found increased in patients with CLL and disease-related anemia and TNF-α appeared to exert a direct inhibitory effect on the differentiation of CD34+ cells towards the erythroid lineage in vitro. Our study showed that disease-related anemia in CLL was not due to intrinsic defects of erythroid precursors, but might result from the direct suppressive effect of TNF-α on the erythroid production. Αναιμία Ερυθροποιητίνη Ερυθροποίηση Chronic lymphocytic leukemia (CLL) Anemia Erythropoietin Erythropoiesis
49	The contribution of host-and parasite-derived factors to erythropoietic suppression underlying the development of malarial anemia / Thawani, Neeta. January 2007 (has links) Severe anemia is the most prevalent life-threatening complication of malaria infection. In addition to destruction of red blood cells (RBC), decreased RBC production or erythropoietic suppression has been shown to contribute to malarial anemia. The mechanism of this suppression is unknown, but it is considered to be multifactorial since erythropoietic suppression can be observed in the presence of both inflammatory mediators and parasite-derived factors. Experiments presented in this thesis aimed at determining the role of host cytokines released in response to blood-stage malaria infection and parasite-derived factors in erythropoietic suppression underlying the development of malarial anemia. Pro-inflammatory cytokines released during malaria infection have been proposed to play a central role in erythroid suppression. To dissect the discrete roles of these cytokines in the processes leading to anemia, mice were treated with CpG-oligodeoxynucleotides (CpG-ODN) which, like malaria infection in humans and experimental mouse models, induces an acute type 1 pro-inflammatory response. CpG-ODN treatment induced anemia, which was associated with suppressed erythropoiesis and reduced RBC survival. Importantly, CpG-ODN-induced IFN-gamma was found to be the major factor mediating erythropoietic suppression but not decreased RBC survival. We also studied the roles of Th1, Th2 and anti-inflammatory cytokines produced in response to Plasmodium chabaudi AS infection in the development of erythropoietic suppression during blood-stage malaria. Signal transducer and activator of transcription (STAT)6, required for signaling of the Th2 cytokines IL-4 and IL-13, was shown to play a critical role in malarial anemia by inhibiting the proliferation and differentiation of erythroid cells. We also observed that suppressed erythropoiesis is a general feature in mice infected with various rodent Plasmodium species that differ in their clinical manifestations and immune responses. Since parasite-derived factors have been shown to contribute to malarial pathogenesis including anemia, the contribution of P. falciparum - and P. yoelii-derived products to erythropoietic suppression was investigated. Both Plasmodium-derived and synthetic hemozoin (Hz) suppressed the proliferation but not the maturation of erythroid progenitor cells in vitro. However, P. yoelii-derived Hz but not synthetic Hz induced transient anemia in mice. These findings provide novel insights into the complex interactions between the parasite and host immune system and the regulation of erythropoiesis during severe malarial anemia. Anemia -- parasitology. Malaria -- parasitology. Erythrocyte Count. Erythrocytes -- parasitology. Erythropoiesis. Plasmodium chabaudi.
50	Analysis of the novel Lyn-associated cytoskeletal modular protein, LACM McCarthy, David James January 2009 (has links) A yeast-two hybrid screen with Lyn identified a novel 130 kDa multidomain protein with a 36% identity to Actin Filament Associated Protein (AFAP) 110 and similar domains, including PH domains, potential sites of tyrosine and serine/threonine phosphorylation, a leucine-zipper domain, a potential actin binding site and multimerization site. AFAP110 has been shown to have a role in modulating actin filament integrity and induce lamellipodia formation, and is known to interact with Src family kinases. The aim of this thesis was to characterize this novel protein named Lyn-Associated Cytoskeletal Modulator (LACM) and determine any molecular interactions in order to attempt to elucidate a role for the protein in cell signaling through Lyn. LACM is encoded by a gene consisting of 18 exons and is located on human chromosome 5q33.1 and mouse chromosome 18 E1. LACM protein is expressed through a number of cell types including the R11 erythroid cell line, and mouse tissues including brain, lung, heart and embryos. LACM was shown to multimerize, and subcellular localization of the protein was observed to concentrate around the cell membrane at sites of filamentous actin in filopodia, lamellipodia and stress fibres. The carboxy-terminus of LACM was observed to localize the protein to sites at the cell membrane and through the cytoplasm. Removal of this terminal region resulted in all LACM protein localizing to the nucleus in punctuate spots. LACM protein was observed in heart muscle and potentially has a role at sites of nerve junctions on cardiac myocytes. LACM was shown to interact with the SH3 domain of Lyn at a polyproline motif on LACM. LACM was observed to co-localize and co-immunoprecipitate with Lyn and was tyrosine phosphorylated by the kinase domain of Lyn. Interestingly, the consititutively active Lyn and LACM caused transfected cells to Cellular signal transduction Cytoskeleton Cytoskeletal proteins Erythropoiesis Protein-tyrosine kinase Cell signalling Cytoskeleton LACM Lyn

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