Determining the signalling pathways that govern human naive pluripotency

Myers, Samuel Philip

January 2018

Conventional or “primed” human embryonic stem cells (hESCs) rely on FGF and TGFβ signalling for self-renewal, and occupy a developmentally advanced state of pluripotency comparable to mouse EpiSCs. Recent reports demonstrate that a naïve state of human pluripotency can be consistently derived either through transient histone deacetylase inhibition mediated resetting of conventional hESCs or via isolation of the inner cell mass. Long-term propagation of this state can be achieved using a cocktail of MEK, GSK3 and PKC inhibition in conjunction with leukaemia inhibitory factor (LIF) supplementation (t2iLGö) and a feeder layer of inactivated mouse embryonic fibroblasts. However, the way in which this signalling environment is interpreted in order to maintain naïve pluripotency remains unclear. I demonstrate a substrate consisting of a high concentration of tissue-derived laminin in combination with t2iLGö is sufficient to replace the feeder layer. Cultures maintained under these conditions are karyotypically normal, maintain a naive pluripotent transcriptional profile and exhibit reduced aberrant expression of mesodermal and endodermal lineage markers. I utilise the increased stringency of this culture system in combination with small molecule inhibitors to examine the roles of FGF, Activin/Nodal and JAK/STAT signalling in human naïve pluripotency. Naïve hESCs proliferate and maintain pluripotency marker expression in the presence of FGF receptor inhibition. In contrast, TGFβ signalling inhibition leads to rapid downregulation of human specific naïve pluripotency marker, KLF17, followed by the eventual collapse of the naïve transcription factor circuitry. Naïve hESCs self-renew in both the absence of LIF and presence of JAK/STAT inhibitors. However, further investigation of JAK/STAT signalling identified the increased potency of Interleukin 6 (IL-6) over LIF to activate the JAK/STAT pathway. Supplemental IL-6 improves colony-forming capacity under self-renewing conditions and attenuates differentiation following inhibitor withdrawal. Furthermore, prolonged activation of IL-6 signalling suppresses expression of GATA2 and GATA3 and upregulates KLF4 transcripts. Finally, I investigate whether ablation of PKCι is sufficient to replace the activity of the PKC inhibitor, Gö6983. Established naïve cultures that are PKCι null continue to express naïve markers and suppress upregulation of lineage makers following withdrawal of Gö6983. Furthermore, ablation of PKCι in conventional ESCs enables the maintenance of NANOG expression and the emergence of KLF17 expression in the absence of Gö6983 during histone deactylase mediated resetting.

Autotaxin-mediated lipid signaling intersects with LIF and BMP signaling to promote the naive pluripotency transcription factor program / Autotaxinによる脂質シグナリングはLIFおよびBMPシグナル伝達経路と交わり、ナイーブ型多能性転写因子プログラムの形成を促進する

Cody, West Kime

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第21025号 / 医科博第86号 / 新制||医科||6(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 斎藤 通紀, 教授 渡邊 直樹, 教授 岩井 一宏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Naive pluripotency

LPA lipid signaling

Reprogramming

BMP signaling

LIF signaling

Stem cells

491

Relations fonctionnelles entre les régulateurs de pluripotence et le cycle cellulaire dans les cellules souches embryonnaires pluripotentes / Functional relationships between pluripotency regulators and cell cycle in the pluripotent embryonic stem cells

Gonnot, Fabrice

27 September 2016

Les cellules souches embryonnaires de souris (mESC) présentent un cycle cellulaire atypique caractérisé par l'absence d'une voie Rb fonctionnelle et la forte expression de la cycline E pendant toutes les phases du cycle cellulaire. En conséquence, les mESC sont constitutivement amorcées pour la réplication de l'ADN. Pour comprendre comment la cycline E, un régulateur clé de la transition de la phase G1 à S, est régulée dans les mESC, nous avons analysé la régulation transcriptionnelle de son gène Ccne1 par des facteurs de transcription du réseau de pluripotence naïve. Nous avons observé que les facteurs Esrrb, Klf4 et Tfcp2l1 se lient à la région du promoteur de Ccne1 sur plusieurs sites situés entre 0 et 1kb en amont du site d'initiation de la transcription. Un test luciférase nous a permis de monter qu'une mutation de ces sites de liaison diminue ou abolie l'activité transcriptionnelle du promoteur. De plus, la surexpression inductible à la doxycycline des facteurs Esrrb, Klf4 et Tfcp2l1 augment le niveau d'expression d'ARNm de Ccne1. Ces résultats suggèrent que Esrrb, Klf4 et Tfcp2l1 contrôlent l'expression de la cycline E. Ils mettent en évidence un lien direct entre le réseau de pluripotence naïve et la régulation du cycle mitotique dans les mESC. Nous avons utilisé le système rapporteur FUCCI pour étudier en fonction du cycle cellulaire l'expression des facteurs de transcription qui forment le réseau de pluripotence naïve. Nous avons observé que l'expression de Esrrb, Klf4, Tfcp2l1 et Nanog oscille au cours du cycle cellulaire avec une diminution de l'expression entre la phase G1 précoce et le début de S, puis une ré-augmentation entre le début de S et la phase G2/M. Ces résultats suggèrent que le réseau de pluripotence naïve est déstabilisé transitoirement lors du passage de la phase G1 à la phase S du cycle cellulaire / Mouse embryonic stem cells (mESCs) display an unorthodox cell cycle characterised by the lack of a functional Rb pathway and robust expression of cyclin E during all cell cycle phases. Therefore, mESCs are constitutively primed for DNA replication. To understand how cyclin E, a key regulator of the G1-to-S phase transition, is regulated in mESCs, we analysed the transcriptional regulation of Ccne1 by transcription factors of the naive pluripotency network. We observed that Esrrb, Klf4 and Tfcp2l1 bound the Ccne1 promoter region on multiple sites between 0 and 1kb upstream transcription start site. Disrupting the binding sites reduced or abolished transcriptional activity in a luciferase assay. Moreover, the doxycyclin-inducible expression of Essrb, Klf4 and Tfcp2l1 up-regulated the Ccne1 mRNA level. Taken together, these results strongly suggest that Essrb, Klf4 and Tfcp2l1 control Cyclin E expression and highlight a direct connection between the naïve pluripotency network and regulation of the mitotic cycle in mESCs. We used the FUCCI reporter system to study cell-cycle dependent expression of the transcription factors that form the naïve pluripotency network. Esrrb, Klf4, Tfcp2l1 and Nanog expression oscillated during the cell cycle with a down-regulated expression between the early G1-phase and the beginning of S-phase, and then up-regulated expression between the beginning of S-phase and the G2/M-phase. These results suggest that the naive pluripotency network is destabilized transiently during the transition from the G1-phase to the S-phase of the cell cycle

Cellules souches embryonnaires

Cycle cellulaire

Pluripotence naïve

Autorenouvellement

Différenciation

Cycline E

Ccne1

Esrrb

Embryonic stem cells

Cell cycle

Naive pluripotency

Self-renewal

Differentiation

Cyclin E

Ccne1

Esrrb

571.6