Molecular dissection of Bruton's tyrosine kinase signaling in hematopoietic cells using RNAi /

Heinonen, Juhana E.,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.

Διερεύνηση του ρόλου της Geminin στην ανάπτυξη και διαφοροποίηση αρχέγονων/προγονικών κυττάρων του αιμοποιητικού συστήματος σε γενετικά τροποποιημένους μύες

Καραμήτρος, Δημήτριος

30 May 2012

Κατά την ανάπτυξη ενός οργανισμού η απόκτηση εξειδικευμένων κυτταρικών λειτουργιών είναι μια προοδευτική διαδικασία η οποία περιλαμβάνει την ασύμμετρη διαίρεση των βλαστικών κυττάρων για την παραγωγή προγονικών κυττάρων τα οποία σταδιακώς εξέρχονται από τον κυτταρικό κύκλο και διαφοροποιούνται μέσω της εγκαθίδρυσης του κατάλληλου μεταγραφικού προγράμματος. Προκειμένου να κατανοήσουμε τη ρύθμιση αυτών των γεγονότων μελετήσαμε την Geminin, ένα κεντρικό ρυθμιστή του κυτταρικού κύκλου, στο ανοσοποιητικό σύστημα. Δημιουργήσαμε ζωικά μοντέλα στα οποία απενεργοποιήσαμε το γονίδιο της Geminin στα λεμφοκύτταρα. Τα αποτελέσματα μας έδειξαν ότι η απενεργοποίηση της Geminin στα λεμφοκύτταρα δεν επηρεάζει σημαντικά τη διαφοροποίηση των προγονικών Τ κυττάρων στο θύμο. Απουσία της Geminin τα προγονικά θυμοκύτταρα δεσμεύονται προς διαφοροποίηση στην Τ κυτταρική σειρά και παράγουν διαφοροποιημένα θυμοκύτταρα. Παρατηρήθηκαν μικρές μειώσεις στον αριθμό των DN1, DN4 και DP κυττάρων. Σε αντίθεση τα αθώα (naïve), ρυθμιστικά (regulatory) και Τ κύτταρα μνήμης (memory T cells), παρουσίασαν σημαντικές μειώσεις απουσία της Geminin. Επιπλέον βρήκαμε ότι ο πολλαπλασιασμός των περιφερικών Τ κυττάρων ύστερα από την ενεργοποίηση τους μέσω του TCR υποδοχέα παρουσίασε σημαντικές ανωμαλίες ενώ παρατηρήθηκαν και σημαντικές διαταραχές της προόδου του κυτταρικού κύκλου απουσία της Geminin. Οι μεταβολές που παρατηρήθηκαν στην έκφραση του Cdt1 και σε κυκλίνες των ενεργοποιημένων περιφερικών Τ κυττάρων μπορεί να εμπλέκονται στο μηχανισμό που εξηγεί τις διαταραχές των περιφερικών Τ κυττάρων απουσία της Geminin. Επίσης Τ κύτταρα από τα οποία είχε απενεργοποιηθεί η Geminin δεν είναι ικανά να αποικίσουν τα λεμφοειδή όργανα μυών από τους οποίους απουσιάζουν τα λεμφοκύτταρα, αποτέλεσμα το οποίο δείχνει διαταραχές του ομοιοστατικού πολλαπλασιασμού αυτών των κυττάρων. Συμπερασματικά η Geminin είναι απαραίτητη για την αυστηρή ρύθμιση των επαναλαμβανόμενων κυτταρικών διαιρέσεων των περιφερικών Τ κυττάρων αλλά δεν επηρεάζει σημαντικά την διαφοροποίηση των προγονικών Τ κυττάρων. Επιπλέον τα αποτελέσματα αυτά προτείνουν ότι υπάρχουν εγγενείς διαφορές στην ρύθμιση του κυτταρικού κύκλου μεταξύ θυμοκυττάρων και περιφερικών Τ κυττάρων. / During development, acquisition of specialized function is a progressive, gradual process that involves the asymmetric divisions of stem cells to generate progeny that will exit the cell cycle and terminally differentiate through the establishment of an appropriate transcriptional program. In order to understand this process we studied Geminin, a key cell cycle regulator, that has been shown to affect cellular decisions of differentiation. Towards this direction we focused on the immune system and investigated the role of Geminin in self-renewal and differentiation of stem and progenitor cells. In order to gain insight into the in vivo role of Geminin in progenitor cell division and differentiation, we have deleted Geminin in cells of the lymphoid lineage. The inactivation of Geminin in the lymphoid lineage does not alter progenitor T cell differentiation in the thymus. In the absence of Geminin progenitor T cells commit, differentiate and generate differentiated thymocytes. Minor reduction in the number of DN1, DN4 and DP progenitor T cells were observed. In contrast naïve, regulatory and memory peripheral T cells show a significant reduction in the absence of Geminin. Moreover, proliferation of Geminin deficient peripheral T cells upon TCR activation is severely compromised, accompanied by cell cycle progression defects. The deregulated protein levels of Cdt1 and cyclins in activated peripheral T cells lacking Geminin, may be involved in the mechanism responsible for the observed phenotype of Geminin deficient peripheral T cells. More importantly Geminin deficient T cells fail to repopulate lymphopenic hosts suggesting defects in homeostatic proliferation. In conclusion Geminin is essential to regulate the repeated divisions of peripheral T cells but does not significantly affect progenitor T cell differentiation. In addition our results suggest that there are intrinsic differences in cell cycle regulation of thymocytes and peripheral T cells.

Αυτο-ανανέωση

Διαφοροποίηση

571.84

Self-renewal

Differentiation

Hematopoietic stem cells

Hematopoietic progenitor cells

Geminin

Efeito da concentração e combinação de crioprotetores na viabilidade medida por citometria de fluxo das células tronco hematopoiéticas congeladas em freezer mecânico

Fischer, Gustavo Brandão

January 2014

O Transplante de Células Tronco Hematopoiéticas (TCTH) baseia-se no princípio de infusão de Células Tronco Hematopoiéticas (CTH) CD34 + num receptor condicionado. Sabe-se que tais células são capazes de gerar uma nova hematopoiese bem como que o benefício do aumento de dose de CD34 + estende-se de aproximadamente 2 x 106 CD34/Kg a 5 x 106 CD34/Kg do receptor. A determinação do número de CD34 baseia-se no número total de CD34, porém sabe-se que apenas uma pequena porção celular do grupo de CD34 está associada à recuperação medular. Uma maneira de refinar a detecção desse grupo de células quando comparado com a quantificação do CD34 total, é a análise citométrica dos padrões de tamanho e granularidade citoplasmática. No contexto do TCTH autólogo e algumas vezes no TCTH alogênico, onde a infusão das células precursoras é feita com intervalo superior a três dias após a sua coleta, o congelamento das CTH CD34 +as faz-se necessário para que as células permaneçam viáveis. O agente crioprotetor mais comumente usado é o Dimetilsulfóxido (DMSO), que em temperaturas extremamente baixas protege as CTH da morte celular, porém em temperatura ambiente torna-se tóxico. As reações adversas do receptor no momento da infusão são atribuídas, em geral, ao DMSO. Portanto existem diferentes protocolos de congelamento de CTH que usam diferentes concentrações desse agente, com o intuito de reduzir as reações adversas e, ao mesmo tempo, evitar a morte celular decorrente de temperaturas baixas. Alguns estudos concluem que a viabilidade das CTH congeladas pode ser mantida com concentrações baixas de DMSO ou com celularidade elevada nos produtos congelados. Além do DMSO, a albumina e o Hidroxetilamido (HES) são usados como adjuvantes na proteção celular ao frio. Alguns protocolos de criopreservação usam apenas o DMSO enquanto outros indicam a necessidade do uso dos três agentes juntos. Não há consenso a respeito do protocolo de criopreservação ideal. Um expressivo número de trabalhos sugere o uso do DMSO 5 a 10% juntamente com a albumina 20% e HES 6% em enxertos com celularidade até 3 x 108 células nucleadas/ml, porém existem sugestões de protocolos diferentes desse padrão que usam o DMSO como agente único assim como concentrações menores de DMSO. Com relação ao efeito tóxico do DMSO, os eventos adversos do paciente no momento da infusão são atribuídos diretamente a ele. Porém evidências recentes apontam outras possíveis causas: citocinas liberadas durante o período de armazenamento e infundidas com o enxerto e micro-agregados leucocitários decorrentes da elevada celularidade do enxerto. O presente estudo pretendeu verificar a viabilidade das CTH através da medida da Anexina-V e 7-AAD pela técnica de citometria de fluxo usando-se diferentes concentrações de DMSO, bem como comparou tal desfecho entre amostras que foram congeladas apenas com DMSO e amostras congeladas com DMSO, HES e albumina. Além disso, foram verificados os níveis de citocinas inflamatórias nos enxertos e sua relação com a concentração de DMSO. / Bone Marrow Transplantation (BMT) is based on the principle of hematopoietic CD34 stem cells infusion in a conditioned recipient. It is known that such cells are capable of generating a new hematopoiesis, as well as known that the benefit of the increase of CD34 dose is goes best when it is between from 2 and to 5 x 106 CD34 by patient’s body weight. The CD34 determination is based on the total CD34 number. However it is known that only a small portion of the CD34 population is related to the marrow repopulating capacity. An alternative way of detecting such cells when compared to total CD34 dose is the cytometric analysis of citoplasmatic granularity and size patterns. In the autologous BMT context and, sometimes in the allogeneic type where the graft infusion occurs more than three days after the graft harvest, the CD34 cells freezing is necessary to keep their viability. The crioprotective agent most commonly used is the DMSO, which at extremely low temperatures this agent protects the CD34 cells from dying. However at temperatures above 30°C it became toxic and causing adverse events in the patient receiving them. The adverse reactions at the infusion moment in general are linked to DMSO, thus there are some different cryopreservative protocols using different DMSO concentrations aiming to reduce the incidence of collateral damage and at the same time avoid the CD34 from dying at low temperatures. Some studies conclude that CD34 viability can be maintained with the use of high mononuclear cellularity in the graft or with low DMSO concentrations. Besides DMSO, albumin and Hydroxietilstarch (HES) are cryoprotectants adjuvants. Some Cryopreservation protocols only use DMSO as cryoprotective agent, while others indicate the three agents together. There is no consensus about the ideal cryopreservation protocol. An important number of studies suggests the use of DMSO 5 to 10% with albumin 20% and HES 6% in grafts with cellularity number of no more than 3 x 108 cells/ml, however there are some new different protocols that use DMSO alone and at lower concentrations. As to adverse events during the infusion moment, it is known that DMSO causes the effects. However, there are evidences that other causes could cause these events: cytokines released during the storage freezing time and infused with the graft and leukocyte micro-clots caused by the high cellularity in the graft. The present study aimed to study the viability of CD34 cells using the Annexin-V and 7-AAD apoptosis reagents through the flow cytometry technique in different DMSO concentrations as well as compared such outcome among the samples only frozen with DMSO and samples frozen with DMSO, HES and albumin. Besides, it was verified the inflammatory cytokine levels and their relationship with the DMSO concentration.

Transplante homólogo

Medula óssea

Citocinas

Criopreservação

Sobrevivência celular

Hematopoietic stem cell

CD34 positive

Flow cytometry

Hematopoietic stem cell transplantation

Cryobiology

Cellular viability

Cytokines

Efeito da concentração e combinação de crioprotetores na viabilidade medida por citometria de fluxo das células tronco hematopoiéticas congeladas em freezer mecânico

Fischer, Gustavo Brandão

January 2014

O Transplante de Células Tronco Hematopoiéticas (TCTH) baseia-se no princípio de infusão de Células Tronco Hematopoiéticas (CTH) CD34 + num receptor condicionado. Sabe-se que tais células são capazes de gerar uma nova hematopoiese bem como que o benefício do aumento de dose de CD34 + estende-se de aproximadamente 2 x 106 CD34/Kg a 5 x 106 CD34/Kg do receptor. A determinação do número de CD34 baseia-se no número total de CD34, porém sabe-se que apenas uma pequena porção celular do grupo de CD34 está associada à recuperação medular. Uma maneira de refinar a detecção desse grupo de células quando comparado com a quantificação do CD34 total, é a análise citométrica dos padrões de tamanho e granularidade citoplasmática. No contexto do TCTH autólogo e algumas vezes no TCTH alogênico, onde a infusão das células precursoras é feita com intervalo superior a três dias após a sua coleta, o congelamento das CTH CD34 +as faz-se necessário para que as células permaneçam viáveis. O agente crioprotetor mais comumente usado é o Dimetilsulfóxido (DMSO), que em temperaturas extremamente baixas protege as CTH da morte celular, porém em temperatura ambiente torna-se tóxico. As reações adversas do receptor no momento da infusão são atribuídas, em geral, ao DMSO. Portanto existem diferentes protocolos de congelamento de CTH que usam diferentes concentrações desse agente, com o intuito de reduzir as reações adversas e, ao mesmo tempo, evitar a morte celular decorrente de temperaturas baixas. Alguns estudos concluem que a viabilidade das CTH congeladas pode ser mantida com concentrações baixas de DMSO ou com celularidade elevada nos produtos congelados. Além do DMSO, a albumina e o Hidroxetilamido (HES) são usados como adjuvantes na proteção celular ao frio. Alguns protocolos de criopreservação usam apenas o DMSO enquanto outros indicam a necessidade do uso dos três agentes juntos. Não há consenso a respeito do protocolo de criopreservação ideal. Um expressivo número de trabalhos sugere o uso do DMSO 5 a 10% juntamente com a albumina 20% e HES 6% em enxertos com celularidade até 3 x 108 células nucleadas/ml, porém existem sugestões de protocolos diferentes desse padrão que usam o DMSO como agente único assim como concentrações menores de DMSO. Com relação ao efeito tóxico do DMSO, os eventos adversos do paciente no momento da infusão são atribuídos diretamente a ele. Porém evidências recentes apontam outras possíveis causas: citocinas liberadas durante o período de armazenamento e infundidas com o enxerto e micro-agregados leucocitários decorrentes da elevada celularidade do enxerto. O presente estudo pretendeu verificar a viabilidade das CTH através da medida da Anexina-V e 7-AAD pela técnica de citometria de fluxo usando-se diferentes concentrações de DMSO, bem como comparou tal desfecho entre amostras que foram congeladas apenas com DMSO e amostras congeladas com DMSO, HES e albumina. Além disso, foram verificados os níveis de citocinas inflamatórias nos enxertos e sua relação com a concentração de DMSO. / Bone Marrow Transplantation (BMT) is based on the principle of hematopoietic CD34 stem cells infusion in a conditioned recipient. It is known that such cells are capable of generating a new hematopoiesis, as well as known that the benefit of the increase of CD34 dose is goes best when it is between from 2 and to 5 x 106 CD34 by patient’s body weight. The CD34 determination is based on the total CD34 number. However it is known that only a small portion of the CD34 population is related to the marrow repopulating capacity. An alternative way of detecting such cells when compared to total CD34 dose is the cytometric analysis of citoplasmatic granularity and size patterns. In the autologous BMT context and, sometimes in the allogeneic type where the graft infusion occurs more than three days after the graft harvest, the CD34 cells freezing is necessary to keep their viability. The crioprotective agent most commonly used is the DMSO, which at extremely low temperatures this agent protects the CD34 cells from dying. However at temperatures above 30°C it became toxic and causing adverse events in the patient receiving them. The adverse reactions at the infusion moment in general are linked to DMSO, thus there are some different cryopreservative protocols using different DMSO concentrations aiming to reduce the incidence of collateral damage and at the same time avoid the CD34 from dying at low temperatures. Some studies conclude that CD34 viability can be maintained with the use of high mononuclear cellularity in the graft or with low DMSO concentrations. Besides DMSO, albumin and Hydroxietilstarch (HES) are cryoprotectants adjuvants. Some Cryopreservation protocols only use DMSO as cryoprotective agent, while others indicate the three agents together. There is no consensus about the ideal cryopreservation protocol. An important number of studies suggests the use of DMSO 5 to 10% with albumin 20% and HES 6% in grafts with cellularity number of no more than 3 x 108 cells/ml, however there are some new different protocols that use DMSO alone and at lower concentrations. As to adverse events during the infusion moment, it is known that DMSO causes the effects. However, there are evidences that other causes could cause these events: cytokines released during the storage freezing time and infused with the graft and leukocyte micro-clots caused by the high cellularity in the graft. The present study aimed to study the viability of CD34 cells using the Annexin-V and 7-AAD apoptosis reagents through the flow cytometry technique in different DMSO concentrations as well as compared such outcome among the samples only frozen with DMSO and samples frozen with DMSO, HES and albumin. Besides, it was verified the inflammatory cytokine levels and their relationship with the DMSO concentration.

Transplante homólogo

Medula óssea

Citocinas

Criopreservação

Sobrevivência celular

Hematopoietic stem cell

CD34 positive

Flow cytometry

Hematopoietic stem cell transplantation

Cryobiology

Cellular viability

Cytokines

Efeito da concentração e combinação de crioprotetores na viabilidade medida por citometria de fluxo das células tronco hematopoiéticas congeladas em freezer mecânico

Fischer, Gustavo Brandão

January 2014

O Transplante de Células Tronco Hematopoiéticas (TCTH) baseia-se no princípio de infusão de Células Tronco Hematopoiéticas (CTH) CD34 + num receptor condicionado. Sabe-se que tais células são capazes de gerar uma nova hematopoiese bem como que o benefício do aumento de dose de CD34 + estende-se de aproximadamente 2 x 106 CD34/Kg a 5 x 106 CD34/Kg do receptor. A determinação do número de CD34 baseia-se no número total de CD34, porém sabe-se que apenas uma pequena porção celular do grupo de CD34 está associada à recuperação medular. Uma maneira de refinar a detecção desse grupo de células quando comparado com a quantificação do CD34 total, é a análise citométrica dos padrões de tamanho e granularidade citoplasmática. No contexto do TCTH autólogo e algumas vezes no TCTH alogênico, onde a infusão das células precursoras é feita com intervalo superior a três dias após a sua coleta, o congelamento das CTH CD34 +as faz-se necessário para que as células permaneçam viáveis. O agente crioprotetor mais comumente usado é o Dimetilsulfóxido (DMSO), que em temperaturas extremamente baixas protege as CTH da morte celular, porém em temperatura ambiente torna-se tóxico. As reações adversas do receptor no momento da infusão são atribuídas, em geral, ao DMSO. Portanto existem diferentes protocolos de congelamento de CTH que usam diferentes concentrações desse agente, com o intuito de reduzir as reações adversas e, ao mesmo tempo, evitar a morte celular decorrente de temperaturas baixas. Alguns estudos concluem que a viabilidade das CTH congeladas pode ser mantida com concentrações baixas de DMSO ou com celularidade elevada nos produtos congelados. Além do DMSO, a albumina e o Hidroxetilamido (HES) são usados como adjuvantes na proteção celular ao frio. Alguns protocolos de criopreservação usam apenas o DMSO enquanto outros indicam a necessidade do uso dos três agentes juntos. Não há consenso a respeito do protocolo de criopreservação ideal. Um expressivo número de trabalhos sugere o uso do DMSO 5 a 10% juntamente com a albumina 20% e HES 6% em enxertos com celularidade até 3 x 108 células nucleadas/ml, porém existem sugestões de protocolos diferentes desse padrão que usam o DMSO como agente único assim como concentrações menores de DMSO. Com relação ao efeito tóxico do DMSO, os eventos adversos do paciente no momento da infusão são atribuídos diretamente a ele. Porém evidências recentes apontam outras possíveis causas: citocinas liberadas durante o período de armazenamento e infundidas com o enxerto e micro-agregados leucocitários decorrentes da elevada celularidade do enxerto. O presente estudo pretendeu verificar a viabilidade das CTH através da medida da Anexina-V e 7-AAD pela técnica de citometria de fluxo usando-se diferentes concentrações de DMSO, bem como comparou tal desfecho entre amostras que foram congeladas apenas com DMSO e amostras congeladas com DMSO, HES e albumina. Além disso, foram verificados os níveis de citocinas inflamatórias nos enxertos e sua relação com a concentração de DMSO. / Bone Marrow Transplantation (BMT) is based on the principle of hematopoietic CD34 stem cells infusion in a conditioned recipient. It is known that such cells are capable of generating a new hematopoiesis, as well as known that the benefit of the increase of CD34 dose is goes best when it is between from 2 and to 5 x 106 CD34 by patient’s body weight. The CD34 determination is based on the total CD34 number. However it is known that only a small portion of the CD34 population is related to the marrow repopulating capacity. An alternative way of detecting such cells when compared to total CD34 dose is the cytometric analysis of citoplasmatic granularity and size patterns. In the autologous BMT context and, sometimes in the allogeneic type where the graft infusion occurs more than three days after the graft harvest, the CD34 cells freezing is necessary to keep their viability. The crioprotective agent most commonly used is the DMSO, which at extremely low temperatures this agent protects the CD34 cells from dying. However at temperatures above 30°C it became toxic and causing adverse events in the patient receiving them. The adverse reactions at the infusion moment in general are linked to DMSO, thus there are some different cryopreservative protocols using different DMSO concentrations aiming to reduce the incidence of collateral damage and at the same time avoid the CD34 from dying at low temperatures. Some studies conclude that CD34 viability can be maintained with the use of high mononuclear cellularity in the graft or with low DMSO concentrations. Besides DMSO, albumin and Hydroxietilstarch (HES) are cryoprotectants adjuvants. Some Cryopreservation protocols only use DMSO as cryoprotective agent, while others indicate the three agents together. There is no consensus about the ideal cryopreservation protocol. An important number of studies suggests the use of DMSO 5 to 10% with albumin 20% and HES 6% in grafts with cellularity number of no more than 3 x 108 cells/ml, however there are some new different protocols that use DMSO alone and at lower concentrations. As to adverse events during the infusion moment, it is known that DMSO causes the effects. However, there are evidences that other causes could cause these events: cytokines released during the storage freezing time and infused with the graft and leukocyte micro-clots caused by the high cellularity in the graft. The present study aimed to study the viability of CD34 cells using the Annexin-V and 7-AAD apoptosis reagents through the flow cytometry technique in different DMSO concentrations as well as compared such outcome among the samples only frozen with DMSO and samples frozen with DMSO, HES and albumin. Besides, it was verified the inflammatory cytokine levels and their relationship with the DMSO concentration.

Transplante homólogo

Medula óssea

Citocinas

Criopreservação

Sobrevivência celular

Hematopoietic stem cell

CD34 positive

Flow cytometry

Hematopoietic stem cell transplantation

Cryobiology

Cellular viability

Cytokines

Congenital amegakaryocytic thrombocytopenia iPS cells exhibit defective MPL-mediated signaling / 先天性無巨核球性血小板減少症患者由来のiPS細胞はMPLを介した細胞内シグナルが欠落している

Hirata, Shinji

26 March 2018

京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13159号 / 論医博第2146号 / 新制||医||1029(附属図書館) / (主査)教授 河本 宏, 教授 前川 平, 教授 髙折 晃史 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

disease-specific iPSC

Thrombopoietin (TPO)

hematopoietic progenitor cell (HPC)

490

Obstacles and Circumvention Strategies for Hematopoietic Stem Cell Transduction by Recombinant Adeno-associated Virus Vectors

Maina, Caroline Njeri

18 March 2009

Indiana University-Purdue University Indianapolis (IUPUI) / High-efficiency transduction of hematopoietic stem cells (HSCs) by recombinant adeno-associated virus serotype 2 (AAV2) vectors is limited by (i) inadequate expression of cellular receptor/co-receptors for AAV2; (ii) impaired intracellular trafficking and uncoating in the nucleus; (iii) failure of the genome to undergo second-strand DNA synthesis; and (iv) use of sub-optimal promoters. Systematic studies were undertaken to develop alternative strategies to achieve high-efficiency transduction of primary murine HSCs and lineage-restricted transgene expression in a bone marrow transplant model in vivo. These included the use of: (i) additional AAV serotype (AAV1, AAV7, AAV8, AAV10) vectors; (ii) self-complementary AAV (scAAV) vectors; and (iii) erythroid cell-specific promoters. scAAV1 and scAAV7 vectors containing an enhanced green-fluorescent protein (EGFP) reporter gene under the control of hematopoietic cell-specific enhancers/promoters allowed sustained transgene expression in an erythroid lineage-restricted manner in both primary and secondary transplant recipient mice. Self complementary AAV vectors containing an anti-sickling human beta-globin gene under the control of either the beta-globin gene promoter/enhancer, or the human parvovirus B19 promoter at map-unit 6 (B19p6) were tested for their efficacy in a human erythroid cell line (K562), and in primary murine hematopoietic progenitor cells (c-kit+, lin-). These studies revealed that (i) scAAV2-beta-globin vectors containing only the HS2 enhancer are more efficient than ssAAV2-beta-globin vectors containing the HS2+HS3+HS4 enhancers; (ii) scAAV-beta-globin vectors containing only the B19p6 promoter are more efficient than their counterparts containing the HS2 enhancer/beta-globin promoter; and (iii) scAAV2-B19p6-beta-globin vectors in K562 cells, and scAAV1-B19p6-beta-globin vectors in murine c-kit+, lin- cells, yield efficient expression of the beta-globin protein. These studies suggest that the combined use of scAAV serotype vectors and the B19p6 promoter may lead to expression of therapeutic levels of beta-globin gene in human erythroid cells, which has implications in the potential gene therapy of beta-thalassemia and sickle cell disease.

Adeno-associated virus

AAV serotype

gene therapy

hematopoietic stem cells

sickle cell disease

Hematopoietic stem cells

Sickle cell anemia

Gene therapy

The role of Rho GTPases in hematopoietic stem cell biology: RhoA GTPase regulates adult HSC engraftment and Rac1 GTPases is important for embryonic HSC migration

Ghiaur, Gabriel

23 April 2008

No description available.

Molecular Biology

Hematopoietic stem cell

Hematopoietic ontogeny

yolk sac

AGM

Fetal Liver

Bone marrow transplantation

gene therapy

Rho GTPase

Rac

RhoA

Hematopoietic stem cells in co-culture with mesenchymal stromal cells - modeling the niche compartments in vitro

Ordemann, Rainer, Jing, Duohui, Fonseca, Ana-Violeta, Alakel, Nael, Fierro, Fernando A., Muller, Katrin, Bornhauser, Martin, Ehninger, Gerhard, Corbeil, Denis

04 January 2016

Background Hematopoietic stem cells located in the bone marrow interact with a specific microenvironment referred to as the stem cell niche. Data derived from ex vivo co-culture systems using mesenchymal stromal cells as a feeder cell layer suggest that cell-to-cell contact has a significant impact on the expansion, migratory potential and ‘stemness’ of hematopoietic stem cells. Here we investigated in detail the spatial relationship between hematopoietic stem cells and mesenchymal stromal cells during ex vivo expansion. Design and Methods In the co-culture system, we defined three distinct localizations of hematopoietic stem cells relative to the mesenchymal stromal cell layer: (i) those in supernatant (non-adherent cells); (ii) those adhering to the surface of mesenchymal stromal cells (phase-bright cells) and (iii) those beneath the mesenchymal stromal cells (phase-dim cells). Cell cycle, proliferation, cell division and immunophenotype of these three cell fractions were evaluated from day 1 to 7. Results Phase-bright cells contained the highest proportion of cycling progenitors during co-culture. In contrast, phase-dim cells divided much more slowly and retained a more immature phenotype compared to the other cell fractions. The phase-dim compartment was soon enriched for CD34+/CD38− cells. Migration beneath the mesenchymal stromal cell layer could be hampered by inhibiting integrin β1 or CXCR4. Conclusions Our data suggest that the mesenchymal stromal cell surface is the predominant site of proliferation of hematopoietic stem cells, whereas the compartment beneath the mesenchymal stromal cell layer seems to mimic the stem cell niche for more immature cells. The SDF-1/CXCR4 interaction and integrin-mediated cell adhesion play important roles in the distribution of hematopoietic stem cells in the co-culture system.

Biotechnologie

hämatopoetische Stammzellen

hematopoietic stem cells

CXCR4

integrin β1

biotechnology

ddc:610

rvk:XA 10000

In-vitro study of the cryopreserved intervertebral disc

Chan, Chun-wai., 陳春慧.

January 2008

published_or_final_version / Orthopaedics and Traumatology / Master / Master of Philosophy

Homografts.