Defining the functional roles of post-SET domain basic stretch for K36 methyltransferases

Szczepski, Kacper

03 1900

Posttranslational modifications of nucleosomes play a crucial role for the proper functioning of the cell. One of the modifications called methylation is conducted by a family of SET-domain containing proteins called NSD1, NSD2, and NSD3. Recently, more evidence about the involvement of NSD proteins and their mutations in the oncogenesis has emerged. Various studies have found that post-SET domain and basic post-SET extension of NSD proteins are crucial for nucleosome interactions and for conducting enzymatic reactions. In this thesis, I attempt to define the role of post-SET domain basic extension on DNA binding, using nuclear magnetic resonance and isothermal titration calorimetry. Additionally, I have attempted to establish a methodology for obtaining nucleosomes, which could be used in future studies. NMR results showed that the post-SET domain extension is required for DNA to bind to NSD2 and NSD3 methyltransferases. The mutant form of NSD2, E1099K, exhibits stronger binding to DNA than does the wild type of NSD2. NMR results also show that the transplanted version of NSD3 containing the post-SET extension of NSD2 have an affinity similar to that of the NSD2 wild type. The NSD2 transplanted with a post-SET extension of NSD3 has close to 4 times less affinity towards DNA than does NSD2 wild type. The affinity of NSD3 T1232A and wild type could not be obtained, as the proteins could not be expressed in a sufficient amount for ITC experiments. However, the present literature confirms lower affinity of NSD3 (around 4 times less than NSD2) towards nucleosomes. Based on the empirical data and literature-based information, it can be assumed that post-SET domain basic extension determines the binding affinity of a NSD protein towards DNA. Additionally, a successful methodology for obtaining nucleosomes was established for future studies.

Methyltransferase

PKMT

NMR

A proteome-wide screen utilizing second generation sequencing for the identification of lysine and arginine methyltransferase protein interactions

Weimann, Mareike

13 September 2012

Proteinmethylierung spielt eine immer größere Rolle in der Regulierung zellulärer Prozesse. Die Entwicklung effizienter proteomweiter Methoden zur Detektion von Methylierung auf Proteinen ist limitiert und technisch schwierig. In dieser Arbeit haben wir einen neuen Hefe-Zwei-Hybrid-Ansatz (Y2H) entwickelt, der Proteine, die miteinander wechselwirken, mit Hilfe von Sequenzierungen der zweiten Generation identifiziert (Y2H-Seq). Der neue Y2H-Seq-Ansatz wurde systematisch mit dem Y2H-Seq-Ansatz verglichen. Dafür wurde ein Bait-Set von 8 Protein-Arginin-Methyltransferasen, 17 Protein-Lysin-Methyltransferasen und 10 Demethylasen gegen 14,268 Prey-Proteine getestet. Der Y2H-Seq-Ansatz ist weniger arbeitsintensiv, hat eine höhere Sensitivität als der Standard Y2H-Matrix-Ansatz und ist deshalb besonders geeignet, um schwache Interaktionen zwischen Substraten und Protein-Methyltransferasen zu detektieren. Insgesamt wurden 523 Wechselwirkungen zwischen 22 Bait-Proteinen und 324 Prey-Pr oteinen etabliert, darunter 11 bekannte Methyltransferasen-Substrate. Netzwerkanalysen zeigen, dass Methyltransferasen bevorzugt mit Transkriptionsregulatoren, DNA- und RNA-Bindeproteinen wechselwirken. Diese Daten repräsentieren das erste proteomweite Wechselwirkungsnetzwerk über Protein-Methyltransferasen und dienen als Ressource für neue potentielle Methylierungssubstrate. In einem in vitro Methylierungsassay wurden exemplarisch mit Hilfe massenspektrometrischer Analysen die methylierten Aminosäurereste einiger Kandidatenproteine bestimmt. Von neun getesteten Proteinen waren sieben methyliert, zu denen gehören SPIN2B, DNAJA3, QKI, SAMD3, OFCC1, SYNCRIP und WDR42A. Wahrscheinlich sind viele Methylierungssubstrate im Netzwerk vorhanden. Das vorgestellte Protein-Protein-Wechselwirkungsnetzwerk zeigt, dass Proteinmethylierung sehr unterschiedliche zelluläre Prozesse beeinflusst und ermöglicht die Aufstellung neuer Hypothesen über die Regulierung Molekularer Mechanismen durch Methylierung. / Protein methylation on arginine and lysine residues is a largely unexplored posttranslational modification which regulates diverse cellular processes. The development of efficient proteome-wide approaches for detecting protein methylation is limited and technically challenging. We developed a novel workload reduced yeast-two hybrid (Y2H) approach to detect protein-protein interactions utilizing second generation sequencing. The novel Y2H-seq approach was systematically evaluated against our state of the art Y2H-matrix screening approach and used to screen 8 protein arginine methyltransferases, 17 protein lysine methyltransferases and 10 demethylases against a set of 14,268 proteins. Comparison of the two approaches revealed a higher sensitivity of the new Y2H-seq approach. The increased sampling rate of the Y2H-seq approach is advantageous when assaying transient interactions between substrates and methyltransferases. Overall 523 interactions between 22 bait proteins and 324 prey proteins were identified including 11 proteins known to be methylated. Network analysis revealed enrichment of transcription regulator activity, DNA- and RNA-binding function of proteins interacting with protein methyltransferases. The dataset represents the first proteome-wide interaction network of enzymes involved in methylation and provides a comprehensively annotated resource of potential new methylation substrates. An in vitro methylation assay coupled to mass spectrometry revealed amino acid methylation of candidate proteins. Seven of nine proteins tested were methylated including SPIN2B, DNAJA3, QKI, SAMD3, OFCC1, SYNCRIP and WDR42A indicating that the interaction network is likely to contain many putative methyltransferase substrate pairs. The presented protein-protein interaction network demonstrates that protein methylation is involved in diverse cellular processes and can inform hypothesis driven investigation into molecular mechanisms regulated through methylation.

Proteinmethylierung

Protein-Arginin-Methyltransferase (PRMT)

Protein-Lysin-Methyltransferase (PKMT)

Demethylase

Protein-Protein-Wechselwirkung (PPI)

Hefe-Zwei-Hybrid-System (Y2H)

Sequenzierung der zweiten Generation

Protein-Wechselwirkungsnetzwerk

PPI network

Protein methylation

protein lysine methyltransferase (PKMT)

demethylase

protein-protein interaction (PPI)

yeast-two hybrid system (Y2H)

second/next generation sequencing

570 Biowissenschaften, Biologie

32 Biologie

WD 5085

ddc:570