Intergenic long noncoding RNAs provide a novel layer of post-transcriptional regulation in development and disease

Tan, Jennifer Yihong

January 2014

Recent genome-wide sequencing projects revealed the pervasive transcription of intergenic long noncoding RNAs (lincRNAs) in eukaryotic genomes (reviewed in Ponting et al. 2009). For the vast majority of lincRNAs, their mechanisms of function remain largely unrecognized. However, the genome-wide signatures of functionality associated with many lincRNAs, including apparent evolutionary sequence conservation, spatial and temporal-restricted expression patterns, strong associations with epigenetic marks, and reported molecular and cellular functions, reinforce their biological relevance. My work investigates lincRNAs that post-transcriptionally regulate gene abundance by competing for the binding of common microRNAs (miRNAs) with protein-coding transcripts, termed competitive endogenous RNAs (ceRNAs) acting lincRNAs (lnceRNAs). First, I examine the biological relevance of this post-transcriptional regulation of gene abundance by ceRNAs. Next, I estimate the genome-wide prevalence of lnceRNAs in mouse embryonic stem cells (mESCs) and characterize their properties. Finally, using two specific examples of lnceRNAs, I show the contributions of lnceRNAs to human monogenic and complex trait diseases. Collectively, these results illustrate that lnceRNAs provide a novel layer of post-transcriptional regulation via a miRNA-mediated mechanism that contributes to organismal and cellular biology.

572.8

Induction and Selection of Sox17-Expressing Endoderm Cells Generated from Murine Embryonic Stem Cells

Schroeder, Insa S., Sulzbacher, Sabine, Nolden, Tobias, Fuchs, Jörg, Czarnota, Judith, Meisterfeld, Ronny, Himmelbauer, Heinz, Wobus, Anna M.

January 2012

Embryonic stem (ES) cells offer a valuable source for generating insulin-producing cells. However, current differentiation protocols often result in heterogeneous cell populations of various developmental stages. Here we show the activin A-induced differentiation of mouse ES cells carrying a homologous dsRed-IRES-puromycin knock-in within the Sox17 locus into the endoderm lineage. Sox17-expressing cells were selected by fluorescence-assisted cell sorting (FACS) and characterized at the transcript and protein level. Treatment of ES cells with high concentrations of activin A for 10 days resulted in up to 19% Sox17-positive cells selected by FACS. Isolated Sox17-positive cells were characterized by defini- tive endoderm-specific Sox17/Cxcr4/Foxa2 transcripts, but lacked pluripotency-associated Oct4 mRNA and protein. The Sox17-expressing cells showed downregulation of extraembryonic endoderm (Sox7, Afp, Sdf1)-, mesoderm (Foxf1, Meox1)- and ectoderm (Pax6, NeuroD6)-specific transcripts. The presence of Hnf4α, Hes1 and Pdx1 mRNA demonstrated the expression of primitive gut/foregut cell-specific markers. Ngn3, Nkx6.1 and Nkx2.2 transcripts in Sox17-positive cells were determined as properties of pancreatic endocrine progenitors. Immunocytochemistry of activin A-induced Sox17-positive embryoid bodies revealed coexpression of Cxcr4 and Foxa2. Moreover, the histochemical demonstration of E-cadherin-, Cxcr4-, Sox9-, Hnf1β- and Ngn3-positive epithelial-like structures underlined the potential of Sox17-positive cells to further differentiate into the pancreatic lineage. By reducing the heterogeneity of the ES cell progeny, Sox17-expressing cells are a suitable model to evaluate the effects of growth and differentiation factors and of culture conditions to delineate the differentiation process for the generation of pancreatic cells in vitro. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/610

ddc:610

Functionalized Nanofiber Substrates for Nerve Regeneration

Silantyeva, Elena A.

26 June 2019

No description available.

Polymer Chemistry

Polymers

Biomedical Engineering

RGD

A Model-Based Analysis of Culture-Dependent Phenotypes of mESCs

Herberg, Maria, Kalkan, Tüzer, Glauche, Ingmar, Smith, Austin, Roeder, Ingo

11 July 2014

Mouse embryonic stem cells (mESCs) can be maintained in a proliferative and undifferentiated state over many passages (self-renewal) while retaining the potential to give rise to every cell type of the organism (pluripotency). Autocrine FGF4/Erk signalling has been identified as a major stimulus for fate decisions and lineage commitment in these cells. Recent findings on serum-free culture conditions with specific inhibitors (known as 2i) demonstrate that the inhibition of this pathway reduces transcription factor heterogeneity and is vital to maintain ground state pluripotency of mESCs. We suggest a novel mathematical model to explicitly integrate FGF4/Erk signalling into an interaction network of key pluripotency factors (namely Oct4, Sox2, Nanog and Rex1). The envisaged model allows to explore whether and how proposed mechanisms and feedback regulations can account for different expression patterns in mESC cultures. We demonstrate that an FGF4/Erk-mediated negative feedback is sufficient to induce molecular heterogeneity with respect to Nanog and Rex1 expression and thus critically regulates the propensity for differentiation and the loss of pluripotency. Furthermore, we compare simulation results on the transcription factor dynamics in different self-renewing states and during differentiation with experimental data on a Rex1GFPd2 reporter cell line using flow cytometry and qRT-PCR measurements. Concluding from our results we argue that interaction between FGF4/Erk signalling and Nanog expression qualifies as a key mechanism to manipulate mESC pluripotency. In particular, we infer that ground state pluripotency under 2i is achieved by shifting stable expression pattern of Nanog from a bistable into a monostable regulation impeding stochastic state transitions. Furthermore, we derive testable predictions on altering the degree of Nanog heterogeneity and on the frequency of state transitions in LIF/serum conditions to challenge our model assumptions.

Embryonale Stammzellen

Mäuse

Grundrauschen

Zelldifferenzierung

Signaltransduktion

Feedback-Hemmung

Durchflusszytometrie

Netzwerkanalyse

Pluripotenz

TU Dresden

Publikationsfonds

Mouse embryonic stem cells

mESCs

Background noise (acoustics)

Cell differentiation

ERK signaling cascade

Feedback regulation

Flow cytometry

Network analysis

Pluripotency

Signaling networks

Technical University Dresden

Publication funds

ddc:500

ddc:610

rvk:TA 1000

rvk:XA 10000

A Model-Based Analysis of Culture-Dependent Phenotypes of mESCs

Herberg, Maria, Kalkan, Tüzer, Glauche, Ingmar, Smith, Austin, Roeder, Ingo

11 July 2014

Mouse embryonic stem cells (mESCs) can be maintained in a proliferative and undifferentiated state over many passages (self-renewal) while retaining the potential to give rise to every cell type of the organism (pluripotency). Autocrine FGF4/Erk signalling has been identified as a major stimulus for fate decisions and lineage commitment in these cells. Recent findings on serum-free culture conditions with specific inhibitors (known as 2i) demonstrate that the inhibition of this pathway reduces transcription factor heterogeneity and is vital to maintain ground state pluripotency of mESCs. We suggest a novel mathematical model to explicitly integrate FGF4/Erk signalling into an interaction network of key pluripotency factors (namely Oct4, Sox2, Nanog and Rex1). The envisaged model allows to explore whether and how proposed mechanisms and feedback regulations can account for different expression patterns in mESC cultures. We demonstrate that an FGF4/Erk-mediated negative feedback is sufficient to induce molecular heterogeneity with respect to Nanog and Rex1 expression and thus critically regulates the propensity for differentiation and the loss of pluripotency. Furthermore, we compare simulation results on the transcription factor dynamics in different self-renewing states and during differentiation with experimental data on a Rex1GFPd2 reporter cell line using flow cytometry and qRT-PCR measurements. Concluding from our results we argue that interaction between FGF4/Erk signalling and Nanog expression qualifies as a key mechanism to manipulate mESC pluripotency. In particular, we infer that ground state pluripotency under 2i is achieved by shifting stable expression pattern of Nanog from a bistable into a monostable regulation impeding stochastic state transitions. Furthermore, we derive testable predictions on altering the degree of Nanog heterogeneity and on the frequency of state transitions in LIF/serum conditions to challenge our model assumptions.

info:eu-repo/classification/ddc/500

ddc:500

info:eu-repo/classification/ddc/610

ddc:610

Dynamic regulation of co-transcriptional processes during neuronal maturation

Fernandes, Ana Miguel

21 August 2020

Koordinierte Phosphorylierung der C-terminale Domäne von RNA Polymerase II (RNAPII) ist essentiell für eine effiziente Kupplung von naszierender RNA Synthese und co-transkriptionalem RNA Prozessierens. Zirkuläre RNAs (circRNAs) sind eine neue Klasse von RNA Molekülen mit hoher Prävalenz in neuronalen Zelltypen. Die Biogenese von circRNAs ist noch ungeklärt, insbesondere die Frage warum das Intron upstream der circRNA während der Transkription des circRNA Exons zurückbehalten wird um Rück-Spleißen zu ermöglichen. Verschiede Belege suggerieren, dass unzulängliche Rekrutierung des Spleiceosoms zur circRNA Formation führen kann. In dieser Arbeit untersuche ich die Mechanismen die zu Defekten in der Erkennung und des Spleißens des Introns upstream der circRNA führen. Mit diesem Ziel erfasste ich die genomweite Verteilung von chromatinassoziierter RNAPII mit verschiedenen Phosphorylierungen, sowie Spleißfaktoren und Transkriptionsreglern mittels ChIP-seq in neuronaler Differenzierung von murinen embryonalen Stammzellen zu dopaminergen und Motoneuronen. Während der gesamten Differenzierung, aber insbesondere in den differenzieren Neuronen, konnten circRNAs detektiert werden. In meiner Arbeit finde ich, dass circRNAs detektiert werden, wenn Gene hohe Levels an mRNA exprimieren und, dass die Produktion von circRNA mit einer Dysbalance zwischen dem Laden der RNA-Polymerase II auf die DNA und dem Rekruitieren der Splice-Maschinerie zusammen hängt. Um funktionell mit den Pausier-Mechanismen der RNA-Polymerase II zu interferieren, habe ich einen ''promotor-proximal-pausing'' Faktor depletiert. Dabei stellte ich fest, dass diese Depletion genügt, um die circRNA Levels in embryonalen Stamzellen zu erhöhen. Die Ergebnisse die in dieser Arbeit gezeigt werden, beschreiben die Beteiligung des Pausierens der RNA-Polymerase II and der Formierung von circRNAs. / Coordinated phosphorylation of RNA polymerase II (RNAPII) C-terminal domain is essential for efficient coupling of nascent RNA synthesis with co-transcriptional RNA processing events. Circular RNAs (circRNAs) are a novel class of RNAs whose biogenesis remains ill understood, namely why the upstream intron is not spliced before the circRNA-exon is fully transcribed. Indirect evidence suggests that altered spliceosome recruitment can lead to circRNA formation. To investigate the mechanisms that may be involved in deficient recognition and splicing of introns upstream of exons included in circRNAs, I mapped the chromatin occupancy of RNAPII phosphorylated forms, splicing factors, and transcription regulators by ChIP-seq during mouse ESC differentiation to dopaminergic and spinal motor neurons. CircRNAs are detected throughout differentiation, peaking in differentiated neurons, as expected. I found that circRNAs are detected when genes express high levels of mRNA, and that circRNA production is associated with an imbalance between RNAPII loading and recruitment of the splicing machinery. To mechanistically interfere with pausing mechanisms, I depleted an RNAPII promoter-proximal pausing factor, and found that it was sufficient to increase the formation of circRNAs in stem cells. Results shown in this work implicate RNAPII regulation mechanisms in the formation of circRNAs.

RNA Polymerase II

Zirkuläre RNAs

Rekrutierung des Spleiceosoms

NELF

dopaminerge Neuronen

spinale Motorneuronen

murinen embryonalen Stammzellen

"promotor-proximal-pausing"

RNA polymerase II

Circular RNAs

Spliceosome recruitment

Mouse embryonic stem cells

Spinal motor neurons

Dopaminergic neurons

NELF

Promoter-proximal pausing

570 Biologie

WD 5355

WG 1900

ddc:570