Enabling the Next Generation of Human Induced Pluripotent Stem Cell Derived Hematopoietic Stem Cell-Based Therapies

Wong, Casey

23 August 2023

Human induced pluripotent stem cells (iPSCs) represent a scalable cell source for the generation of hematopoietic progenitor cells (iHPCs); however, a lack of efficient iHPC expansion in vitro currently limits translational applications. To address this translational bottleneck, we assessed a panel of stem cell agonist cocktails (SCACs), originally developed to enhance cord-blood derived HSPC (CB-HSPC) expansion, on iHPC expansion. Three SCACs and GAS6 (X2A, X2A+GAS6, SM6, or SMA) were supplemented during iHPC differentiation and subsequent expansion using the STEMdiff™ Hematopoietic Kit. This monolayer differentiation strategy yielded a population of CD34⁺CD43⁺ and CD45⁺CD34⁺ iHPC. SCAC supplementation during iHPC differentiation yielded up to 2.5-fold higher frequency of CD34⁺CD43⁺ hematopoietic progenitors and up to 2.9-fold higher frequency of CD45⁺CD34⁺CD45RA⁻CD90⁺ HSC-like cells compared to non-treated controls. Subsequent SCAC supplementation during 2 weeks of expansion culture also significantly increased iHPC expansion (X2A+GAS6: 3.8-fold, X2A: 3.5-fold, SM6: 2.8-fold, SMA: 2.0-fold). The expanded iHPCs retained high levels of CD34⁺CD43⁺ expression but we observed an increase in the expansion of HSC-like cell fraction. The collective expansion observed with the SCACs was 1.5- to 2.8-fold higher than UM171 treatment alone. Furthermore, all SCAC-supplemented iHPCs retained multilineage potency, producing erythroid and granulocyte-macrophage progenitors in CFU assays. However, prolonged expansion, beyond 7 days, reduced multilineage potential, indicating a limited expansion window. Although optimal timing and composition of SCAC supplementation remains to be refined, these results highlight that exploiting the additive and synergistic effects of multiple small molecules represents a promising approach for enhancing iHPC expansion yields and biomanufacturing.

Stem cell agonist cocktail

Small molecule

Human induced pluripotent stem cell

Hematopoietic stem progenitor cell

Multipotent progenitor cell

Expansion

StemRegenin 1

UM171

Valproic acid

AA2P

Generation of induced pluripotent stem cell lines from two patients with Aicardi-Goutières syndrome type 1 due to biallelic TREX1 mutations

Hänchen, Vanessa, Kretschmer, Stefanie, Wolf, Christine, Engel, Kerstin, Khattak, Shahryar, Neumann, Katrin, Lee-Kirsch, Min Ae

16 May 2024

Mutations in TREX1, encoding three prime repair exonuclease 1, cause Aicardi-Goutières syndrome (AGS) 1, an autoinflammatory disease characterized by neurodegeneration and constitutive activation of the antiviral cytokine type I interferon. Here, we report the generation and characterization of induced pluripotent stem cells (iPSCs) derived from fibroblasts from two AGS patients with biallelic TREX1 mutations. These cell lines offer a unique resource to investigate disease processes in a cell-type specific manner.

info:eu-repo/classification/ddc/570

ddc:570

Controle epigenético do gene imprinted SNRPN durante o desenvolvimento e reprogramação nuclear em equídeos / Epigenetic control of the SNRPN imprinted gene during developmental and nuclear reprogramming in equids

Rigoglio, Nathia Nathaly

15 March 2016

A tranferência nuclear de células somáticas (TNCS) está sendo utilizada para produzir cavalos de elite. No entanto, durante este procedimento pode ocorrer a perfuração da zona pelúcida, levando, ocasionalmente, à secção da massa celular interna, e conseqüente derivação de gêmeos monozigóticos. Além de serem relatadas alterações no processo de imprinting genômico, que conduzem ao desenvolvimento de doenças. Com a descoberta da possibilidade de reprogramar as células somáticas a um estado de pluripotência (iPSCs), estas células passaram a ser muito utilizadas em pesquisas de neurociência. Contudo, também ocorrem modificações epigenéticas durante esta reprogramação celular. Portanto, nossas hipóteses são que os gêmeos eqüinos gerados pela TNCS podem levar às irregularidades no desenvolvimento do sistema nervoso. O padrão de metilação do SNRPN nas estruturas dos fetos muares clonados, e as células iPSCs são diferentes dos padrões encontrados nos muares analisados. A expressão dos genes SNRPN, Necdin e UBE3A são maiores no cérebro, enquanto a expressão do H19 é maior nas membranas extra-embrionárias. Em nosso estudo, obtivemos duas gestações gemelares equinas derivadas da TNCS, que foram interrompidas com 40 e 60 dias de gestação, e comparados com gestações eqüinas únicas de idade similar. Diferenças no comprimento entre os embriões gêmeos foram observadas aos 40 (2.0 e 2.2 cm 10%) e aos 60 (6,5 e 8,5 cm 24%) dias de gestação. Somente o plexo coróide do quarto ventrículo apresentou-se mais desenvolvido nos fetos com maior comprimento. Ao analisarmos fetos muares clonados em diferentes idades gestacionais e compará-los com muares, nos períodos embrionário, fetal e adulto, não foi observada diferença no padrão de metilação do gene SNRPN. No entanto, na décima passagem das células iPSC o padrão de metilação alterou, em relação aos muares estudados e ao padrão observado nos fibroblastos. Ao analisarmos os fetos clonados nas diferentes idades gestacionais observou-se no cérebro menor expressão dos gene H19 e UBE3A, e maior expressão do gene SNRPN. Contudo, a expressão do gene Necdin variou entre as estruturas estudadas. Em conclusão, apesar dos gêmeos eqüinos provenientes de TNCS diferirem quanto ao tamanho, morfologicamente são iguais. Dentre as estruturas cerebrais o plexo coróide se apresentou mais desenvolvido nos fetos de maior comprimento. Os fetos muares clonados não apresentaram diferença no padrão de metilação do gene SNRPN. No entanto, as iPSCs apresentaram alteração no padrão de metilação deste gene na décima passagem. Embora os genes SNRPN, Necdin e UBE3A sejam expressos no cérebro, o SNRPN apresentou-se prevalente nessa estrutura / The nuclear transfer of somatic cells (SCNT) is being used to produce elite horses. However, during this procedure can occur drilling of the zona pellucida, leading occasionally to the section of the inner cell mass, and subsequent derivation of monozygotic twins. Besides being related changes in genomic imprinting process, leading to the development of diseases. With the discovery of the possibility to reprogram somatic cells to a pluripotent state (iPSCs), these cells have become widely used in neuroscience research. However, also occur epigenetic changes during this cellular reprogramming. Therefore, our hypothesis is that equine twins caused by equine ART could lead to developmental irregularities of the nervous system. The patterns of SNRPN methylation in the structures of cloned mule fetuses and in iPSCs are different from the patterns found in the analyzed mules. And the expression of SNRPN, Necdin and UBE3A genes are higher in the brain, while the higher expression of H19 gene occurs in the extraembryonic membranes. In our study we derived two equine twin SCNT pregnancies that were interrupted at 40 and 60 days of gestation and compared to singleton fetuses of similar age. Differences in lengths between twin embryos were observed at both 40 (2.0 and 2.2 cm 10%) and 60 (6.5 and 8.5 cm 24%) days of gestation. Only the choroid plexus in the fourth ventricle more developed in the twins with the greatest length. Analyzing mules cloned fetuses at different gestational ages, and compare them with mules at embryonic, fetal and adult period; there was no difference in the pattern of methylation in SNRPN gene. However, in the tenth passage of the iPSCs the methylation pattern was altered in relation to the studied mules and the pattern observed in fibroblasts. When the cloned fetuses at different gestational ages were analyzed, the brain presented lower expression of H19 and UBE3A genes, and higher expression of SNRPN gene. However, the expression of Necdin gene varied among the structures studied. In conclusion, despite the twin horses from SCNT differ in size, they are morphologically identical. Among the brain structures the choroid plexus performed more developed in the fetuses of greater length. Cloned mules fetuses showed no difference in the pattern of methylation SNRPN gene. However, iPSCs have changes in the pattern of methylation of this gene in the tenth passage. Although SNRPN, Necdin and Ube3A genes are expressed in the brain, SNRPN is prevalent in this structure

Células pluripotentes induzidas (iPSC)

Central nervous system development

Desenvolvimento embrionário

Embryonic development

Gestação gemelar

Induced pluripotent stem cell (iPSC)

Somatic cell nuclear transfer (SCNT)

Twin pregnancy

Controle epigenético do gene imprinted SNRPN durante o desenvolvimento e reprogramação nuclear em equídeos / Epigenetic control of the SNRPN imprinted gene during developmental and nuclear reprogramming in equids

Nathia Nathaly Rigoglio

15 March 2016

A tranferência nuclear de células somáticas (TNCS) está sendo utilizada para produzir cavalos de elite. No entanto, durante este procedimento pode ocorrer a perfuração da zona pelúcida, levando, ocasionalmente, à secção da massa celular interna, e conseqüente derivação de gêmeos monozigóticos. Além de serem relatadas alterações no processo de imprinting genômico, que conduzem ao desenvolvimento de doenças. Com a descoberta da possibilidade de reprogramar as células somáticas a um estado de pluripotência (iPSCs), estas células passaram a ser muito utilizadas em pesquisas de neurociência. Contudo, também ocorrem modificações epigenéticas durante esta reprogramação celular. Portanto, nossas hipóteses são que os gêmeos eqüinos gerados pela TNCS podem levar às irregularidades no desenvolvimento do sistema nervoso. O padrão de metilação do SNRPN nas estruturas dos fetos muares clonados, e as células iPSCs são diferentes dos padrões encontrados nos muares analisados. A expressão dos genes SNRPN, Necdin e UBE3A são maiores no cérebro, enquanto a expressão do H19 é maior nas membranas extra-embrionárias. Em nosso estudo, obtivemos duas gestações gemelares equinas derivadas da TNCS, que foram interrompidas com 40 e 60 dias de gestação, e comparados com gestações eqüinas únicas de idade similar. Diferenças no comprimento entre os embriões gêmeos foram observadas aos 40 (2.0 e 2.2 cm 10%) e aos 60 (6,5 e 8,5 cm 24%) dias de gestação. Somente o plexo coróide do quarto ventrículo apresentou-se mais desenvolvido nos fetos com maior comprimento. Ao analisarmos fetos muares clonados em diferentes idades gestacionais e compará-los com muares, nos períodos embrionário, fetal e adulto, não foi observada diferença no padrão de metilação do gene SNRPN. No entanto, na décima passagem das células iPSC o padrão de metilação alterou, em relação aos muares estudados e ao padrão observado nos fibroblastos. Ao analisarmos os fetos clonados nas diferentes idades gestacionais observou-se no cérebro menor expressão dos gene H19 e UBE3A, e maior expressão do gene SNRPN. Contudo, a expressão do gene Necdin variou entre as estruturas estudadas. Em conclusão, apesar dos gêmeos eqüinos provenientes de TNCS diferirem quanto ao tamanho, morfologicamente são iguais. Dentre as estruturas cerebrais o plexo coróide se apresentou mais desenvolvido nos fetos de maior comprimento. Os fetos muares clonados não apresentaram diferença no padrão de metilação do gene SNRPN. No entanto, as iPSCs apresentaram alteração no padrão de metilação deste gene na décima passagem. Embora os genes SNRPN, Necdin e UBE3A sejam expressos no cérebro, o SNRPN apresentou-se prevalente nessa estrutura / The nuclear transfer of somatic cells (SCNT) is being used to produce elite horses. However, during this procedure can occur drilling of the zona pellucida, leading occasionally to the section of the inner cell mass, and subsequent derivation of monozygotic twins. Besides being related changes in genomic imprinting process, leading to the development of diseases. With the discovery of the possibility to reprogram somatic cells to a pluripotent state (iPSCs), these cells have become widely used in neuroscience research. However, also occur epigenetic changes during this cellular reprogramming. Therefore, our hypothesis is that equine twins caused by equine ART could lead to developmental irregularities of the nervous system. The patterns of SNRPN methylation in the structures of cloned mule fetuses and in iPSCs are different from the patterns found in the analyzed mules. And the expression of SNRPN, Necdin and UBE3A genes are higher in the brain, while the higher expression of H19 gene occurs in the extraembryonic membranes. In our study we derived two equine twin SCNT pregnancies that were interrupted at 40 and 60 days of gestation and compared to singleton fetuses of similar age. Differences in lengths between twin embryos were observed at both 40 (2.0 and 2.2 cm 10%) and 60 (6.5 and 8.5 cm 24%) days of gestation. Only the choroid plexus in the fourth ventricle more developed in the twins with the greatest length. Analyzing mules cloned fetuses at different gestational ages, and compare them with mules at embryonic, fetal and adult period; there was no difference in the pattern of methylation in SNRPN gene. However, in the tenth passage of the iPSCs the methylation pattern was altered in relation to the studied mules and the pattern observed in fibroblasts. When the cloned fetuses at different gestational ages were analyzed, the brain presented lower expression of H19 and UBE3A genes, and higher expression of SNRPN gene. However, the expression of Necdin gene varied among the structures studied. In conclusion, despite the twin horses from SCNT differ in size, they are morphologically identical. Among the brain structures the choroid plexus performed more developed in the fetuses of greater length. Cloned mules fetuses showed no difference in the pattern of methylation SNRPN gene. However, iPSCs have changes in the pattern of methylation of this gene in the tenth passage. Although SNRPN, Necdin and Ube3A genes are expressed in the brain, SNRPN is prevalent in this structure

Células pluripotentes induzidas (iPSC)

Desenvolvimento embrionário

Gestação gemelar

Central nervous system development

Embryonic development

Induced pluripotent stem cell (iPSC)

Somatic cell nuclear transfer (SCNT)

Twin pregnancy

Generation of induced pluripotent stem cell lines from three patients with Aicardi-Goutières syndrome type 5 due to biallelic SAMDH1 mutations

Hänchen, Vanessa, Kretschmer, Stefanie, Wolf, Christine, Engel, Kerstin, Khattak, Shahryar, Neumann, Katrin, Lee-Kirsch, Min Ae

16 May 2024

Mutations in SAMHD1, encoding SAM and HD domain-containing protein 1, cause Aicardi-Goutières syndrome (AGS) 5, an infancy-onset autoinflammatory disease characterized by neurodegeneration and chronic activation of type I interferon. Here, we report the generation and characterization of induced pluripotent stem cells (iPSCs) derived from fibroblasts and peripheral blood mononuclear cells from three AGS patients with biallelic SAMHD1 mutations. These cell lines provide a valuable source to study disease mechanisms and to assess therapeutic molecules.

info:eu-repo/classification/ddc/570

ddc:570

Mécanismes électrophysiologiques responsables de l'augmentation de la fréquence cardiaque induite par les œstrogènes lors de la grossesse

Long, Valérie

07 1900

Une accélération de la fréquence cardiaque (FC) au repos est observée chez les femmes enceintes. Au dernier trimestre, la FC accélère en moyenne de 15%, ce qui représente un facteur de risque dans le développement d’arythmies de novo ou dans l’exacerbation d’arythmies cardiaques préexistantes. Ceci est dangereux pour la mère ainsi que pour le fœtus. Cependant, les mécanismes responsables de ce changement cardiovasculaire restent peu connus. Notre laboratoire a récemment démontré que la grossesse était associée à une augmentation de la densité du courant pacemaker (If) et du courant calcique de type L (ICaL), ainsi qu’à des changements de l’homéostasie calcique dans les cellules de nœud sinusal (NS) de souris. Sachant que les concentrations plasmatiques en œstrogènes sont significativement augmentées pendant la grossesse et que ces hormones sexuelles féminines ont la capacité de modifier les propriétés électrophysiologiques du cœur, l’hypothèse de ce projet de recherche est que les œstrogènes jouent un rôle important dans l’augmentation de la FC associée à la grossesse et régulent les propriétés électrophysiologiques du NS. Les objectifs de ce projet de recherche sont de déterminer le rôle du 17β-œstradiol (E2) dans l’augmentation de la FC, d’examiner si ces effets sont régulés par les récepteurs aux œstrogènes alpha (ERα) et/ou bêta (ERβ) ainsi que d’évaluer les différents mécanismes de régulation de l’E2 sur l’électrophysiologie du NS. Des souris femelles adultes non-gestantes (2-4 mois) déficientes en ERα (ERKOα) ou en ERβ (ERKOβ) ont reçu un traitement chronique à l’E2 (30 μg deux fois par jour pendant quatre jours) simulant les concentrations plasmatiques en E2 retrouvées en fin de grossesse (23,3 ± 5,0 nM) chez la souris. L’analyse des électrocardiogrammes de surface montrent que la FC des souris ERKOβ (ERKOβ : 511 ± 15 bpm; ERKOβ +E2 : 580 ± 10 bpm, n = 10, p < 0,001) est significativement accélérée suivant le traitement à l’E2. Toutefois, la FC demeure inchangée chez les souris ERKOα (ERKOα : 520 ± 16 bpm; ERKOα +E2 : 530 ± 21 bpm, n = 7, p = 0,114). La méthode du patch-clamp en mode courant-imposé a permis de démontrer une accélération de l’automaticité des cellules du NS des souris ERKOβ suivant le traitement à l’E2, se traduisant par une augmentation de la fréquence des potentiels d’action spontanés (ERKOβ : 284 ± 24 bpm, n = 8; ERKOβ +E2 : 354 ± 23 bpm, n = 15, p = 0,0395) et par une pente de dépolarisation diastolique plus rapide (ERKOβ : 82 ± 12 mV/s, n = 8; ERKOβ +E2 : 140 ± 14 mV/s, n = 15, p < 0,003). En lien avec ces résultats, le patch-clamp en mode voltage-imposé a permis de démontrer que la densité de If est augmentée suivant un traitement à l’E2 (à -90 mV : ERKOβ : -6,6 ± 0,7 pA/pF, n = 12-15; ERKOβ +E2 : -11 ± 1 pA/pF, n = 9-11, p < 0,05). Cependant, If est similaire chez les souris ERKOα traitées ou non à l’E2. De plus, des cardiomyocytes humains dérivés de cellules souches pluripotentes induites de type nodal (N-hiPSC-CM) ont une accélération de la fréquence des potentiels d’action (CTL : 69 ± 5 bpm, n = 12; +E2 : 99 ± 6 bpm, n = 14, p < 0,001) ainsi qu’une augmentation de la densité de If (à -90 mV : CTL : -0,95 ± 0,14 pA/pF, n = 7-10; +E2 : -1,62 ± 0,17 pA/pF, n = 13-14, p < 0,05) suivant le traitement à l’E2. L’administration d’E2 ne modifie pas la fréquence des transitoires calciques des cellules de NS des souris ERKOα (139 ± 15, n = 13-14; +E2 : 142 ± 14, n = 15-16, p = ns) et ERKOβ (142 ± 11, n = 14-15; +E2 : 147 ± 13, n = 15-16, p = ns). En lien avec ces résultats, le courant ICaL des N-hiPSC-CM est inchangé suivant le traitement d’E2 (à 0 mV : CTL : -14,0 ± 1,3 pA/pF, n = 12-13; +E2 : -14,5 ± 1,4 pA/pF, n = 22, p = ns). En conclusion, l’accélération de l’automaticité cardiaque associée à la grossesse est, entre autres, expliquée par une augmentation de la densité de If, régulée par la voie de signalisation E2-ERα. Cependant, les changements de l’homéostasie calcique observés pendant la grossesse sont indépendants des niveaux élevés en œstrogènes. Les résultats obtenus sur les N-hiPSC-CM concordent avec ce qui est observé dans les cellules de NS de souris, ce qui démontre l’applicabilité humaine des résultats. Notre étude contribue à élucider l’influence de la grossesse et le rôle des hormones sexuelles féminines sur la fonction du NS et l’automaticité cardiaque. Ultimement, notre travail pourrait aider à développer une meilleure gestion des arythmies associées aux fluctuations hormonales féminines et/ou à la grossesse. / An increased heart rate (HR) is observed in pregnant women. In fact, in the last trimester, in average, the HR increases by 15%, which is a known risk factor to developing cardiac arrhythmias or exacerbating pre-existing arrhythmias. This can lead to major consequences for both the mother and fetus. However, the mechanisms underlying this increased HR remain largely unexplored. Our laboratory recently demonstrate that pregnancy is associated with an increased density of the pacemaker current (If) and the L-type calcium current (ICaL) as well as changes in calcium homeostasis of mouse sinoatrial node (SAN) cells. Knowing that estrogens are increased during pregnancy and that these sex hormones can modify cardiac electrophysiological properties, we hypothesized that estrogens play a key role in the pregnancy-induced increased HR and regulate the SAN electrophysiological properties. Our research project aims to determine the role of 17β-estradiol (E2) on the pregnancy-induced increased HR, to determine if these effects are regulated through estrogen receptor alpha (ERα) and/or beta (ERβ) and to study the E2 underlying mechanisms on SAN electrophysiology. Non-pregnant female mice (2-4 months) lacking ERα (ERKOα) or ERβ (ERKOβ) received a chronic E2 treatment (30 μg twice daily for four days) mimicking E2 concentrations found in late pregnancy (23.3 ± 5.0 nM). Surface electrocardiogram analysis showed a significant increased HR in ERKOβ mice (ERKOβ: 511 ± 15 bpm; ERKOβ +E2: 580 ± 10 bpm; n = 10; p<0.001) following E2 administration. However, the HR remains unchanged in ERKOα mice (ERKOα: 520 ± 16 bpm; ERKOα +E2: 530 ± 21 bpm, n = 7, p = 0.114). Following E2 treatment, current-clamp method demonstrates an increase SAN cells automaticity in ERKOβ mice, resulting in an increase in the spontaneous action potential frequency (ERKOβ : 284 ± 24 bpm, n = 8; ERKOβ +E2 : 354 ± 23 bpm, n = 15, p = 0.0395), associated with a steeper diastolic depolarization slope (ERKOβ : 82 ± 12 mV/s, n = 8; ERKOβ +E2 : 140 ± 14 mV/s, n = 15, p < 0.003), a major determinant of cardiac automaticity. In line with these results, voltage-clamp data showed an increased If density in SAN cells of ERKOβ mice treated with E2 (at -90 mV: ERKOβ: -6.6 ± 0.7 pA/pF, n = 12-15; ERKOβ +E2: -11.0 ± 1.3 pA/pF, n = 9-11, p < 0.05). Nevertheless, If density was similar in E2-treated ERKOα mice. E2-treated nodal-like human-induced pluripotent stem cell-derived cardiomyocytes (N-hiPSC-CM) also showed an increased spontaneous action potential frequency (CTL : 69 ± 5 bpm, n = 12; +E2 : 99 ± 6 bpm, n = 14, p < 0.001) and If density (at -90 mV: CTL: -0.95 ± 0.14 pA/pF, n = 7-10; +E2: -1.62 ± 0.17 pA/pF, n = 13-14, p < 0.05). Following E2 administration, the rate of calcium transient was similar in SAN cells from ERKOα (139 ± 15, n = 13-14; +E2 : 142 ± 14, n = 15-16, p = ns) and ERKOβ (142 ± 11, n = 14-15; +E2 : 147 ± 13, n = 15-16, p = ns) mice. In line with these results, no modification was seen on ICaL density in E2-treated N-hiPSC-CM (at 0 mV: CTL: -14.0 ± 1.3 pA/pF, n = 12-13; +E2: -14.5 ± 1.4 pA/pF, n = 22, p = ns). In conclusion, the increased cardiac automaticity observed during pregnancy is, in part, explained by an increased If density. This mechanism is mediated by the E2-ERα pathway. In the other hand, calcium homeostasis changes detected during pregnancy appear to be mediated by an E2-independent mechanism. Finally, results obtained on N-hiPSC-CM are consistent with our observations on mouse SAN cells, demonstrating the human applicability of our results. This study provides novel insight on the effects of female sex hormones on the SAN functions. Ultimately, this information can lead to improved management of arrhythmias associated with female hormone fluctuations and/or pregnancy-induced arrhythmias.

Grossesse

Nœud sinusal

Automaticité cardiaque

Œstrogènes

Récepteurs aux œstrogènes

Courant pacemaker

Courant calcique de type L

Homéostasie calcique

Transitoires calciques

Pregnancy

Sinoatrial node

Cardiac automaticity

Estrogens

Estrogen receptor

Pacemaker current

L-type calcium current

Calcium homeostasis

Calcium transient

Differentiation and characterization of cell types associated with retinal degenerative diseases using human induced pluripotent stem cells

Gupta, Manav

31 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Human induced pluripotent stem (iPS) cells have the unique ability to differentiate into 200 or so somatic cell types that make up the adult human being. The use of human iPS cells to study development and disease is a highly exciting and interdependent field that holds great promise in understanding and elucidating mechanisms behind cellular differentiation with future applications in drug screening and cell replacement studies for complex and currently incurable cellular degenerative disorders. The recent advent of iPS cell technology allows for the generation of patient-specific cell lines that enable us to model the progression of a disease phenotype in a human in vitro model. Differentiation of iPS cells toward the affected cell type provides an unlimited source of diseased cells for examination, and to further study the developmental progression of the disease in vitro, also called the “disease-in-a-dish” model. In this study, efforts were undertaken to recapitulate the differentiation of distinct retinal cell affected in two highly prevalent retinal diseases, Usher syndrome and glaucoma. Using a line of Type III Usher Syndrome patient derived iPS cells efforts were undertaken to develop such an approach as an effective in vitro model for studies of Usher Syndrome, the most commonly inherited disorder affecting both vision and hearing. Using existing lines of iPS cells, studies were also aimed at differentiation and characterization of the more complex retinal cell types, retinal ganglion cells (RGCs) and astrocytes, the cell types affected in glaucoma, a severe neurodegenerative disease of the retina leading to eventual irreversible blindness. Using a previously described protocol, the iPS cells were directed to differentiate toward a retinal fate through a step-wise process that proceeds through all of the major stages of neuroretinal development. The differentiation process was monitored for a period of 70 days for the differentiation of retinal cell types and 150 days for astrocyte development. The different stages of differentiation and the individually derived somatic cell types were characterized by the expression of developmentally associated transcription factors specific to each cell type. Further approaches were undertaken to characterize the morphological differences between RGCs and other neuroretinal cell types derived in the process. The results of this study successfully demonstrated that Usher syndrome patient derived iPS cells differentiated to the affected photoreceptors of Usher syndrome along with other mature retinal cell types, chronologically analogous to the development of the cell types in a mature human retina. This study also established a robust method for the in vitro derivation of RGCs and astrocytes from human iPS cells and provided novel methodologies and evidence to characterize these individual somatic cell types. Overall, this study provides a unique insight into the application of human pluripotent stem cell biology by establishing a novel platform for future studies of in vitro disease modeling of the retinal degenerative diseases: Usher syndrome and glaucoma. In downstream applications of this study, the disease relevant cell types derived from human iPS cells can be used as tools to further study disease progression, drug screening and cell replacement strategies.

Degeneration

Differentiation

Disease Modeling

Glaucoma

Induced Pluripotent Stem Cell

Retina

Usher's syndrome -- Pathophysiology

Glaucoma -- Alternative treatment

Retinitis pigmentosa -- Pathophysiology

Genetic disorders -- Diagnosis

Embryonic stem cells -- Research

Human cell culture -- Research

Cell differentiation -- Analysis

Stem cells -- Transplantation -- Methods

Cellular therapy

Retinal ganglion cells -- Research

Retinal degeneration

Cells -- Morphology

Regenerative medicine -- Research

Transcription factors

Astrocytes -- Morphology

Genetic engineering

Drug testing