The role of Ken&Barbie in JAK/STAT signalling during development of Drosophila melanogaster

Cell-cell interactions during embryonic development are crucial in the co-ordination of growth, differentiation and maintenance of many different cell types. To achieve this co-ordination each cell must properly translate signals received from neighbouring cells, into spatially and temporally appropriate developmental responses. A surprisingly limited number of signal pathways are responsible for the differentiation of enormous variety of cell types. As a result, pathways are frequently 'reused' during development. Thus, in mammals the JAK/STAT pathway is required during early embryogenesis, mammary gland formation, hematopoiesis and, finally, plays a pivotal role in immune response. In the canonical way, the JAK/STAT pathway is represented by a transmembrane receptor associated with a Janus kinase (JAK), which upon stimulation by an extra-cellular ligand, phosphorylates itself, the receptor and, finally, the signal transducer and activator of transcription (STAT) molecules. Phosphorylated STATs dimerise and translocate to the nucleus where they activate transcription of target genes. The JAK/STAT pathway has been conserved throughout evolution, and all known components are present in the genome of Drosophila melanogaster. Besides hematopoietic and immunity functions, the pathway is also required during development for processes including embryonic segmentation, tracheal morphogenesis, posterior spiracle formation etc. This study describes Drosophila Ken&Barbie (Ken) as a selective regulator of JAK/STAT signalling. ken mutations identified in a screen for modulators of an eye overgrowth phenotype, caused by over-expression of the pathway ligand unpaired, also interact genetically with the pathway receptor domeless (dome) and the transcription factor stat92E. Over-expression of Ken can phenocopy developmental defects known to be caused by the loss of JAK/STAT signalling. These genetic interactions suggest that Ken may function as a negative regulator of the pathway. Ken has C-terminal Zn-finger domain, presumably for DNA binding, and N-terminal BTB/POZ domain, often found in transcriptional repressors. Using EGFP-fused construct expressed in vivo revealed nuclear accumulation of Ken. Therefore, it is proposed that Ken may act as a suppresser of STAT92E target genes. An in vitro assay, termed SELEX, determined that Ken specifically binds to a DNA sequence, with the essential for DNA recognition core overlapping that of STAT92E. This interesting observation suggests that not all STAT92E sites may also allow Ken binding. Strikingly, when effects of ectopic Ken on the expression of putative JAK/STAT pathway target genes were examined, only a subset of the genes tested, namely vvl, trh and kni, were down-regulated by Ken, whereas some others, such as eve and fj, appeared to be unresponsive. Further analysis of vvl, one of the genes susceptible to ectopic Ken, was undertaken. In the developing hindgut, expression of vvl is JAK/STAT pathway dependent, but remains repressed in the posterior spiracles, despite the stimulation of STAT92E by Upd in their primordia. Importantly, ken is also expressed in the developing posterior spiracles. Strikingly, up-regulation of vvl is observed in these tissues in ken mutant embryos. These imply that while ectopic Ken is sufficient to repress the expression of vvl in the hindgut, endogenous Ken is also necessary to prevent its activation in the posterior spiracles. It is therefore conceivable that ectopic vvl expression in the posterior spiracles of the ken mutants may be the result of de-repression of endogenous STAT92E activity. Another consequence of these observations is a fine balance that must exist between STAT92E and Ken activities. Apparently, endogenous level of Ken is sufficient to repress vvl, but not other, as yet unidentified, JAK/STAT pathway targets, whose presumable activation by STAT92E is required for posterior spiracle development as the embryos mutant for dome, the receptor of the pathway, show severe spiracle defects. These defects are also observed in the embryos mis-expressing Ken. Though it is possible that the posterior spiracle phenotype caused by higher levels of Ken results from a JAK/STAT pathway independent activity, it seems to be more likely that Ken acts in a dosage dependent manner, and extra Ken is able to further antagonise JAK/STAT pathway target genes. While STAT92E binding sites required for target gene expression have been poorly characterised, the existence of genome data allows the prediction of candidate STAT92E sites present in target genes promoters to be attempted. When a 6kb region containing the putative regulatory domains flanking the vvl locus are examined, only a single potential STAT92E binding site located 825bp upstream of the translational start can be detected. Strikingly, this site also includes a perfect Ken binding sequence. Such an in silico observation, though consistent with both Ken DNA binding assay in vitro and regulation of STAT92E target genes in vivo, however, requires further analysis. The JAK/STAT pathway is implicated in a variety of processes during embryonic and larval development as well as in imago. In each case, stimulation of the same transcription factor results in different developmental outcomes. While many potential mechanisms have been proposed and demonstrated to explain such pleiotropy, the present study indicates that Ken may represent another mechanism, with which signal transduction pathways are controlled. Ken selectively down-regulates a subset of potential target genes and so modifies the transcriptional profile generated by activated STAT92E - a mechanism, which may be partially responsible for differences in the morphogenetic processes elicited by JAK/STAT signalling during development.

Identifizierung und funktionelle Charakterisierung neuer A-Kinase-Ankerproteine (AKAPs) im Modellorganismus C. elegans

In dieser Arbeit sollten neue Interaktionspartner der regulatorischen Untereinheit (R-UE) der Proteinkinase A (PKA) und des Modellorganismus C. elegans identifiziert und funktionell charakterisiert werden. Im Gegensatz zu Säugern (vier Isoformen), exprimiert der Nematode nur eine PKA-R-Isoform. Mittels in silico Analysen und so genannten „Pulldown“ Experimenten, wurde insbesondere nach A Kinase Ankerproteinen (AKAP) in C. elegans gesucht. Aus in silico Recherchen resultiert das rgs5 Protein als mögliches Funktionshomolog des humanen AKAP10. Rgs5 enthält eine potenzielle, amphipathische Helix (AS 421-446, SwissProt ID A9Z1K0), die in Peptide-SPOT-Arrays (durchgeführt im Biotechnologie Zentrum in Oslo, AG Prof. K. Taskén) eine Bindung an RI und RII-UE zeigt. Eine ähnliche Lokalisation von rgs5 und hAKAP10 in der Zelle, sowie vergleichende BRET² Studien, weisen auf eine mögliche Funktionshomologie zwischen AKAP10 und rgs5 hin. Die hier durchgeführten Analysen deuten darauf hin, dass es sich bei rgs5 um ein neues, klassisches AKAP mit „RII bindender Domäne“ Motiv im Modellorganismus C. elegans handelt. Basierend auf so genannten „pulldown“ Versuchen können, neben „klassischen“ AKAPs (Interaktion über amphipathische Helices), auch Interaktionspartner ohne typische Helixmotive gefunden werden. Dazu gehört auch RACK1, ein multifunktionales Protein mit 7 WD40 Domänen, das ubiquitär exprimiert wird und bereits mehr als 70 Interaktionspartner in unterschiedlichsten Signalwegen komplexiert (Adams et al., 2011). Durch BRET² Interaktionsstudien und Oberflächenplasmonresonanz (SPR) Analysen konnten hRI und kin2 als spezifische Interaktionspartner von RACK1 verifiziert werden. Untersuchungen zur Identifikation der Interaktionsflächen der beiden Proteine RACK1 und hRI zeigten im BRET² System, dass RACK1 über die WD40 Domänen 1-2 und 6-7 interagiert. Die Analyse unterschiedlicher hRI-Deletionsmutanten deutet auf die DD-Domäne im N-Terminus und zusätzlich auf eine potenzielle BH3 Domäne im C-Terminus des Proteins als Interaktionsfläche mit RACK1 hin. Die Koexpression von hRI BH3 und RACK1 zeigt einen auffälligen ein Phänotyp in Cos7 Zellen. Dieser zeichnet sich unter anderem durch eine Degradation des Zellkerns, DNA Kondensation und eine starke Vakuolisierung aus, was beides als Anzeichen für einen programmierten Zelltod interpretiert werden könnte. Erste Untersuchungen zum Mechanismus des ausgelösten Zelltods deuten auf eine Caspase unabhängige Apoptose (Paraptose) hin und einen bislang unbekannten Funktionsmechanismus der PKA hin.