Dynamic Expression Of Three

Tekin, Elif

01 September 2011

RNA-binding proteins (RBP) shuttle between cellular compartments either constitutively or in response to stress and regulate localization, translation and turn over of mRNAs. In our laboratory, cytosolic proteome map of Phanerochaete chrysosporium was established and upon Pb exposure, the changes in cytosolic protein expressions were determined. The identified RBPs were a newly induced polyadenylate-binding protein (RRM superfamily) as well as two up-regulated proteins, namely splicing factor RNPS1 and ATP-dependent RNA helicase, all being very important candidates of post-transcriptional control in response to stress. This finding inspired us to conduct Real Time PCR studies in order to have a better understanding of the changes in the expression of corresponding genes at mRNA level in response to Pb exposure, thus the present study aims at examining the effect of lead exposure on the transcript levels of the genes coding for ATP-dependent RNA helicase, splicing factor RNPS1 and polyadenylate binding protein. As shown via expression analysis based on Real Time PCR, the mRNA level of splicing factor RNPS1 showed 2.68, 2.62 and 4.86 fold increases in a dose-dependent manner when the cells were grown for 40 h in the presence of 25, 50 and 100 &micro / M Pb, repectively. ATP-dependent RNA helicase mRNA level showed no significant increase in response to 25 &micro / M Pb exposure while increased 2 and 1.84 fold in response to 50 and 100 &micro / M Pb, respectively. Polyadenylate binding protein mRNA levels revealed no significant increase when exposed to 25, 50 and 100 &micro / M Pb. As to the mRNA dynamics as a function of duration of lead exposure, the mRNA level of this protein showed 2.54-fold increase upon 1 h exposure to 100 &micro / M Pb. Splicing factor RNPS1 mRNA level showed a significant increase of 19.22 fold at 2nd h of 50 &micro / M Pb exposure. Expression level of ATP-dependent RNA helicase was not affected by the time of exposure to Pb.

QH General Biology 301-705

Phanerochaete chrysosporium

Real Time PCR

expression analysis, mRNA dynamics.

Quantitative analysis of RET signaling dynamics and crosstalk

Chow, Jennifer Marie

18 March 2018

Most existing studies of receptor signaling are qualitative, which can lead scientists to misinterpret or overlook key information about the extent and timing of key events. To overcome these shortcomings, we have applied quantitative approaches to characterize receptor activation and signaling events. Most signaling studies focus on events occurring at a particular level in the system (e.g., on the membrane, at the level of phosphorylation of intracellular signaling molecules, or at the level of transcription). Instead, we are interested in taking a longitudinal view of signaling by achieving a quantitative understanding of a single signaling pathway from initial stimulation of the receptor by its growth factor (GF) ligand, through to gene expression, and functional cellular responses. As a model system for our studies, we used the growth factor receptor tyrosine kinase, REarranged during Transfection (RET), which requires a ligand and a glycosylphosphatidylinositol-anchored co-receptor for activation. RET mediates the response of cells to members of the glial cell-line derived neurotrophic factor (GDNF) family of neurotrophins, which are important in the development and maintenance of a subset of neuronal cells as well as in other cell types and tissues. We have characterized the molecular mechanisms of RET activation and signaling by pursuing the following four aims: 1) We developed a sensitive and robust luciferase reporter gene assay for RET signaling. 2) We characterized the dynamic relationship between receptor activation and downstream signaling events, including gene transcription and translation of three target genes. 3) We used the reporter gene assay, and other detection approaches, to test and quantify crosstalk between RET and other GF receptors. 4) We developed a FRET reporter system to enable monitoring of the assembly of the activated RET receptor complex on cells, as a means to distinguish between ligand-induced oligomerization and pre-associated oligomer mechanisms. Through these four aims, we have established new methods to quantitatively elucidate mechanisms of GF receptor activation, new insights into how signals are propagated from the receptor to the nucleus and into a functional response, and have established crosstalk between RET and other GF receptor pathways.

Biochemistry

Cell signaling

Growth factor receptor

mRNA dynamics

Protein dynamics

Signaling dynamics

Signaling kinetics

ERK signal duration decoding by mRNA dynamics

Uhlitz, Florian Sören

17 June 2019

Der RAF-MEK-ERK-Signalweg steuert grundlegende, oftmals entgegengesetzte zelluläre Prozesse wie die Proliferation und Apoptose von Zellen. Die Dauer des vermittelten Signals wurde als entscheidener Faktor für die Steuerung dieser Prozesse identifiziert. Es ist jedoch nicht eindeutig geklärt, wie die verschiedenen früh und spät reagierenden Genexpressionsmodule kurze und lange Signale unterscheiden können und durch welche kinetischen Merkmale ihre Antwortzeit bestimmt wird. In der vorliegenden Arbeit wurden sowohl Proteinphosphorylierungsdaten als auch Genexpressionsdaten aus HEK293-Zellen gewonnen, die ein induzierbares Konstrukt des Proto-Onkogens RAF tragen. Hierbei wurde ein neues Genexpressionsmodul identifiziert, dass sich aus sofort induzierten aber spät antwortenden Genen zusammensetzt. Es unterscheidet sich in der Genexpressionsdynamik und Genfunktion von anderen Modulen, und wurde mit Hilfe mathematischer Modellierung experimenteller Daten identifiziert. Es wurde festgestellt, dass diese Gene aufgrund von langen Halbwertszeiten der vermitteltenden mRNA in der Lage sind spät auf das eingehende Signal zu reagieren und die Dauer des Signals in die Amplitude der Genantwort zu übersetzen. Trotz der langsamen Akkumulation und damit späten Antwortzeit, konnte aufgrund einer GC-reichen Promoterstruktur zunächst vermutet und mit Hilfe eines Markerverfahrens bestätigt werden, dass die Transkription dieser Gene instantan mit Beginn der ERK-Aktivierung startet. Eine vergleichende Analyse zeigte, dass das Prinzip der Signaldauer-Entschlüsselung in PC12-Zellen und MCF7-Zellen, zwei paradigmatischen Zellsystemen für die ERK-Signaldauer, konserviert ist. Insgesamt deuten die Ergebnisse der Untersuchung darauf hin, dass das neu identifizierte Genexpressionsmodul der Entschlüsselung der ERK-Signaldauer dient und das mRNA Halbwertszeiten sowohl hierfür, als auch für die zeitliche Abfolge der Genantwort eine entscheidende Rolle spielen. / The RAF-MEK-ERK signalling pathway controls fundamental, often opposing cellular processes such as proliferation and apoptosis. Signal duration has been identified to play a decisive role in these cell fate decisions. However, it remains unclear how the different early and late responding gene expression modules can discriminate short and long signals and what features govern their timing. Both protein phosphorylation and gene expression time course data was obtained from HEK293 cells carrying an inducible construct of the proto-oncogene RAF. A new gene expression module of immediate-late genes (ILGs) distinct in gene expression dynamics and function was identified by mathematical modelling. It was found that mRNA longevity enables these ILGs to respond late and thus translate ERK signal duration into response amplitude. Despite their late response, their GC-rich promoter structure suggested and metabolic labelling with 4SU confirmed that transcription of ILGs is induced immediately. A comparative analysis showed that the principle of duration decoding is conserved in PC12 cells and MCF7 cells, two paradigm cell systems for ERK signal duration. Altogether, the findings of this study indicate that ILGs decode ERK signal duration and that both decoding capacity and gene expression timing are governed by mRNA half-life.

ERK-Signalweg

mRNA-Halbwertszeit

Signaldauerdekodierung

mRNA-Dynamiken

ERK signalling

mRNA half-life

Signal duration decoding

mRNA dynamics

570 Biologie

WG 1940

WE 5320

WD 5355

ddc:570