On the function of the Dictyostelium Argonaute A protein (AgnA) in epigenetic gene regulation

With molecular biology methods and bioinformatics, the Argonaute proteins in Dictyostelium discoideum were characterized, and the function of the AgnA protein in RNAi and DNA methylation was investigated, as well as cellular features. Also interaction partners of the PAZ-Piwi domain of AgnA (PAZ-PiwiAgnA) were discovered. The Dictyostelium genome encodes five Argonaute proteins, termed AgnA/B/C/D/E. The expression level of Argonaute proteins was AgnB/D/E > AgnA > AgnC. All these proteins contain the characteristic conserved of PAZ and Piwi domains. Fluorescence microscopy revealed that the overexpressed C-terminal GFP-fusion of PAZ-PiwiAgnA (PPWa-GFP) localized to the cytoplasm. Overexpression of PPWa-GFP leaded to an increased gene silencing efficiency mediated by RNAi but not by antisense RNA. This indicated that PAZ-PiwiAgnA is involved in the RNAi pathway, but not in the antisense pathway. An analysis of protein-protein interactions by a yeast-two-hybrid screen on a cDNA library from vegetatively grown Dictyostelium revealed that several proteins, such as EF2, EF1-I, IfdA, SahA, SamS, RANBP1, UAE1, CapA, and GpdA could interact with PAZ-PiwiAgnA. There was no interaction between PAZ-PiwiAgnA and HP1, HelF and DnmA detected by direct yeast-two-hybrid analysis. The fluorescence microscopy images showed that the overexpressed GFP-SahA or IfdA fusion proteins localized to both cytoplasm and nuclei, while the overexpressed GFP-SamS localized to the cytoplasm. The expression of SamS in AgnA knock down mutants was strongly down regulated on cDNA and mRNA level in, while the expression of SahA was only slightly down regulated. AgnA knock down mutants displayed defects in growth and phagocytosis, which suggested that AgnA affects also cell biological features. The inhibition of DNA methylation on DIRS-1 and Skipper retroelements, as well as the endogenous mvpB and telA gene, observed for the same strains, revealed that AgnA is involved in the DNA methylation pathway. Northern blot analysis showed that Skipper and DIRS-1 were rarely expressed in Ax2, but the expression of Skipper was upregulated in AgnA knock down mutants, while the expression of DIRS-1 was not changed. A knock out of the agnA gene failed even though the homologous recombination of the disruption construct occurred at the correct site, which indicated that there was a duplication of the agnA gene in the genome. The same phenomenon was also observed in ifdA knock out experiments.

Die Rolle des Zelladhäsionsmoleküls L1 in der Tumorprogression

Das neuronale Adhäsionsmolekül L1 wird neben den Zellen des Nervensystems auf vielen humanen Tumoren exprimiert und ist dort mit einer schlechten Prognose für die betroffenen Patienten assoziiert. Zusätzlich zu seiner Funktion als Oberflächenmolekül kann L1 durch membranproximale Spaltung in eine lösliche Form überführt werden. In der vorliegenden Arbeit wurde der Einfluss von L1 auf die Motilität von Tumorzellen untersucht. Lösliches L1 aus Asziten führte zu einer Integrin-vermittelten Zellmigration auf EZM-Substraten. Derselbe Effekt wurde durch Überexpression von L1 in Tumorlinien beobachtet. Weiterhin führt die L1-Expression zu einer erhöhten Invasion, einem verstärkten Tumorwachstum in NOD/SCID Mäusen und zur konstitutiven Aktivierung der MAPK ERK1/2. Eine Mutation in der zytoplasmatischen Domäne von hL1 (Thr1247Ala/Ser1248Ala)(hL1mut) führte hingegen zu einer Blockade dieser Funktionen. Dies weist daraufhin, dass nicht nur lösliches L1, sondern auch die zytoplasmatische Domäne von L1 funktionell aktiv ist. Im zweiten Teil der Arbeit wurde der Mechanismus, der L1-vermittelten Signaltransduktion untersucht. Die zytoplasmatische Domäne von L1 gelangt nach sequenzieller Proteolyse durch ADAM und Presenilin-abhängiger γ-Sekretase Spaltung in den Zellkern. Diese Translokation im Zusammenspiel mit der Aktivierung der MAPK ERK1/2 durch L1-Expression führt zu einer L1-abhängigen Genregulation. Die zytoplasmatische Domäne von hL1mut konnte ebenfalls im Zellkern detektiert werden, vermittelte jedoch keine Genregulation und unterdrückte die ERK1/2 Phosphorylierung. Die L1-abhängige Induktion von ERK1/2-abhängigen Genen wie Cathepsin B, β3 Integrin und IER 3 war in Zellen der L1-Mutante unterdrückt. Die Expression des Retinsäure-bindenden Proteins CRABP-II, welches in hL1 Zellen supprimiert wird, wurde in der L1-Mutante nicht verändert. Weitere biochemische Untersuchungen zeigen, dass die zytoplasmatische Domäne von L1 Komplexe mit Transkriptionsfaktoren bilden kann, die an Promoterregionen binden können. Die dargestellten Ergebnisse belegen, dass L1-Expression in Tumoren an drei Funktionen beteiligt ist; (i) L1 erhöht Zellmotilität, (ii) fördert Tumorprogression durch Hochregulation von pro-invasiven und proliferationsfördernden Genen nach Translokation in den Nukleus und (iii) schützt die Zellen mittels Regulation pro- bzw. anti-apoptotischer Gene vor Apoptose. Die mutierte Phosphorylierungsstelle im L1-Molekül ist essentiell für diese Prozesse. Die Anwendung neuer Therapien für Patienten mit L1-positiven Karzinomen kann mit Hinblick auf die guten Erfolge der Antikörper-basierenden Therapie mit dem mAk L1-11A diskutiert werden.

DNA methylation in Dictyostelium discoideum

DNA methyltransferases of type Dnmt2 are a highly conserved protein family with enigmatic function. The aim of this work was to characterize DnmA, the Dnmt2 methyltransferase in Dictyostelium discoideum, and further to investigate its implication in DNA methylation and transcriptional gene silencing. The genome of the social amoeba Dictyostelium encodes DnmA as the sole DNA methyltransferase. The enzyme bears all ten characteristic DNA methyltransferase motifs in its catalytic domain. The DnmA mRNA was found by RT-PCR to be expressed during vegetative growth and down regulated during development. Investigations using fluorescence microscopy showed that both DnmA-myc and DnmA-GFP fusions predominantly localised to the nucleus. The function of DnmA remained initially unclear, but later experiment revealed that the enzyme is an active DNA methyltransferase responsible for all DNA (cytosine) methylation in Dictyostelium. Neither in gel retardation assays, nor by the yeast two hybrid system, clues on the functionality of DnmA could be obtained. However, immunological detection of the methylation mark with an α - 5mC antibody gave initial evidence that the DNA of Dictyostelium was methylated. Furthermore, addition of 5-aza-cytidine as demethylating agent to the Dictyostelium medium and subsequent in vitro incubation of the DNA isolated from these cells with recombinant DnmA showed that the enzyme binds slightly better to this target DNA. In order to investigate further the function of the protein, a gene knock-out for dnmA was generated. The gene was successfully disrupted by homologous recombination, the knock-out strain, however, did not show any obvious phenotype under normal laboratory conditions. To identify specific target sequences for DNA methylation, a microarray analysis was carried out. Setting a threshold of at least 1.5 fold for differences in the strength of gene expression, several such genes in the knock-out strain were chosen for further investigation. Among the up-regulated genes were the ESTs representing the gag and the RT genes respectively of the retrotransposon skipper. In addition Northern blot analysis confirmed the up-regulation of skipper in the DnmA knock-out strain. Bisufite treatment and sequencing of specific DNA stretches from skipper revealed that DnmA is responsible for methylation of mostly asymmetric cytosines. Together with skipper, DIRS-1 retrotransposon was found later also to be methylated but was not present on the microarray. Furthermore, skipper transcription was also up-regulated in strains that had genes disrupted encoding components of the RNA interference pathway. In contrast, DIRS 1 expression was not affected by a loss of DnmA but was strongly increased in the strain that had the RNA directed RNA polymerase gene rrpC disrupted. Strains generated by propagating the usual wild type Ax2 and the DnmA knock-out cells over 16 rounds in development were analyzed for transposon activity. Northern blot analysis revealed activation for skipper expression, but not for DIRS-1. A large number of siRNAs were found to be correspondent to the DIRS-1 sequence, suggesting concerted regulation of DIRS-1 expression by RNAi and DNA methylation. In contrast, no siRNAs corresponding to the standard skipper element were found. The data show that DNA methylation plays a crucial role in epigenetic gene regulation in Dictyostelium and that different, partially overlapping mechanisms control transposon silencing for skipper and DIRS-1. To elucidate the mechanism of targeting the protein to particular genes in the Dictyostelium genome, some more genes which were up-regulated in the DnmA knock-out strain were analyzed by bisulfite sequencing. The chosen genes are involved in the multidrug response in other species, but their function in Dictyostelium is uncertain. Bisulfite data showed that two of these genes were methylated at asymmetrical C-residues in the wild type, but not in DnmA knock-out cells. This suggested that DNA methylation in Dictyostelium is involved not only in transposon regulation but also in transcriptional silencing of specific genes.