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A cascade of histone acetylation events with subsequent incorporation of a histone H2A variant plays an essential part in transcription regulation in various model organisms. A key player in this cascade is the chromatin remodelling complex SWR1, which replaces the canonical histone H2A with its variant H2A.Z. Transcriptional regulation of polycistronic transcription units in the unicellular parasite Trypanosoma brucei has been shown to be highly dependent on acetylation of H2A.Z, which is mediated by the histone-acetyltransferase HAT2. The chromatin remodelling complex which mediates H2A.Z incorporation is not known and an SWR1 orthologue in trypanosomes has not yet been reported. In this study, we identified and characterised an SWR1-like remodeller complex in T. brucei that is responsible for Pol II-dependent transcriptional regulation. Bioinformatic analysis of potential SNF2 DEAD/Box helicases, the key component of SWR1 complexes, identified a 1211 amino acids-long protein that exhibits key structural characteristics of the SWR1 subfamily. Systematic protein-protein interaction analysis revealed the existence of a novel complex exhibiting key features of an SWR1-like chromatin remodeller. RNAi-mediated depletion of the ATPase subunit of this complex resulted in a significant reduction of H2A.Z incorporation at transcription start sites and a subsequent decrease of steady-state mRNA levels. Furthermore, depletion of SWR1 and RNA-polymerase II (Pol II) caused massive chromatin condensation. The potential function of several proteins associated with the SWR1-like complex and with HAT2, the key factor of H2A.Z incorporation, is discussed.
The steroid hormones corticosterone/cortisol and aldosterone are synthesized and secreted by the adrenal gland in response to stress or an altered salt-water balance. This is controlled by a negative feedback mechanism referred to as the HPA axis and the RAAS. Actions of these steroid hormones are mediated by the glucocorticoid receptor (GR) and the mineralocorticoid receptor (MR), which reside in the cytoplasm in a complex with heat-shock proteins. Both, the GR and the MR belong to the nuclear receptor superfamily and share a common protein structure consisting of three separate domains. However, they have different affinities for various ligands, their actions depend on hormone concentration, they are modulated by pre-receptor mechanisms such as the 11β-HSD2 and they are differently distributed in several tissues. Aldosterone acts via the MR in epithelial and in non-epithelial cells and regulates sodium-water homeostasis, cardiovascular function, neuronal excitability and adipocyte differentiation. So far the analysis of gene inactivation in vivo was limited to mice, but disease models in rats sometimes more closely reflect the situation encountered in humans. Since embryonic stem cells and thus gene targeting in rats is not available, we generated MR knock-down transgenic rats by lentiviral delivery of a shRNA. The F1 progeny of the founder rats showed a wide range of reduced MR mRNA and protein levels in kidney and hippocampus, the two major sites of MR expression. In contrast, expression of the highly homologous GR was unaltered, indicating specificity of gene inactivation. The two MR target genes, Sgk1 and ENaC, were up-regulated while the mRNA levels of other genes such as IK1 and SCD2 was reduced. Similar to the knock-out mice and human patients, the knock-down rats displayed typical signs of pseudohypoaldosteronism type I such as increased serum levels of aldosterone and renin as well as growth retardation. Importantly, we found a linear relationship between MR mRNA expression in kidney, serum aldosterone levels and body weight. Thus, our MR knock-down rats are amongst the first examples of RNAi in vivo and confirm that this technique allows to accomplish graded levels of gene inactivation that mimick human genetic diseases. Secondly, we investigated the role of the GR and the MR for the immunomodulatory activities of glucocorticoids (GCs) in peritoneal macrophages. GCs are involved in the modulation of macrophage function and thereby control the host’s immune responses to pathogens. Therefore, GCs are widely used for the treatment of inflammation and autoimmune diseases. However, concerning these GC activities neither the role of hormone concentration nor the differential contribution of the GR and the MR are known. At first we confirmed that both receptors but not 11β-HSD2 are expressed in peritoneal macrophages. Next, we showed that low levels of corticosterone enhance NO production as well as mRNA expression of pro-inflammatory cytokines, chemokines and enzymes required for mediator synthesis. In contrast, at high corticosterone concentrations macrophage function was strongly repressed. Importantly, inactivation of the GR by lentiviral delivery of siRNAs abrogated both the immunostimulatory and the immunosuppressive GC actions whereas inactivation of the MR had no effect. Furthermore, removal of endogenous GCs by adrenalectomy in vivo induced a pre-activated state in macrophages that could be modulated by corticosterone. We conclude that GCs exert distinct effects on macrophage function dependent on their concentration, and that they act through the GR despite concomitant expression of the MR. In summary, our results confirm that lentiviral delivery of shRNAs is an efficient means to down-regulation gene expression in primary cells and transgenic rats and thereby allows to perform functional studies on gene function that were previously limited to mice.
5’-3’ decay is the major mRNA decay pathway in many eukaryotes, including trypanosomes. After deadenylation, mRNAs are decapped by the nudix hydrolase DCP2 of the decapping complex and finally degraded by the 5’-3’ exoribonuclease. Uniquely, trypanosomes lack homologues to all subunits of the decapping complex, while deadenylation and 5’-3’ degradation are conserved. Here, I show that the parasites use an ApaH-like phosphatase (ALPH1) as their major mRNA decapping enzyme. The protein was recently identified as a novel trypanosome stress granule protein and as involved in mRNA binding. A fraction of ALPH1 co-localises exclusively with the trypanosome 5’-3’ exoribonuclease XRNA to a special granule at the posterior pole of the cell, indicating a connection between the two enzymes. RNAi depletion of ALPH1 is lethal and causes a massive increase in total mRNAs that are deadenylated, but have not yet started 5’-3’ decay. These data suggest that ALPH1 acts downstream of deadenylation and upstream of mRNA degradation, consistent with a function in mRNA decapping. In vitro experiments show that recombinant, N-terminally truncated ALHP1 protein, but not a catalytically inactive mutant, sensitises the capped trypanosome spliced leader RNA to yeast Xrn1, but only if an RNA 5’ polyphosphatase is included. This indicates that the decapping mechanism of ALPH1 differs from the decapping mechanism of Dcp2 by leaving more than one phosphate group at the mRNA’s 5’ end. This is the first reported function of a eukaryotic ApaH-like phosphatase, a bacterial-derived class of enzymes present in all phylogenetic super-groups of the eukaryotic kingdom. The substrates of eukaryotic ApaH-like phosphatases are unknown. However, the substrate of the related bacterial enzyme ApaH, diadenosine tetraphosphate, is highly reminiscent of a eukaryotic mRNA cap.
Visual Attention in Flies-Dopamine in the Mushroom Bodies Mediates the After-Effect of Cueing
(2016)
Visual environments may simultaneously comprise stimuli of different significance. Often such stimuli require incompatible responses. Selective visual attention allows an animal to respond exclusively to the stimuli at a certain location in the visual field. In the process of establishing its focus of attention the animal can be influenced by external cues. Here we characterize the behavioral properties and neural mechanism of cueing in the fly Drosophila melanogaster. A cue can be attractive, repulsive or ineffective depending upon (e.g.) its visual properties and location in the visual field. Dopamine signaling in the brain is required to maintain the effect of cueing once the cue has disappeared. Raising or lowering dopamine at the synapse abolishes this after-effect. Specifically, dopamine is necessary and sufficient in the αβ-lobes of the mushroom bodies. Evidence is provided for an involvement of the αβ\(_{posterior}\) Kenyon cells.
Cryptochrome (CRY) is the primary photoreceptor of Drosophila’s circadian clock. It resets the circadian clock by promoting light-induced degradation of the clock protein Timeless (TIM) in the proteasome. Under constant light, the clock stops because TIM is absent, and the flies become arrhythmic. In addition to TIM degradation, light also induces CRY degradation. This depends on the interaction of CRY with several proteins such as the E3 ubiquitin ligases Jetlag (JET) and Ramshackle (BRWD3). However, CRY can seemingly also be stabilized by interaction with the kinase Shaggy (SGG), the GSK-3 beta fly orthologue. Consequently, flies with SGG overexpression in certain dorsal clock neurons are reported to remain rhythmic under constant light. We were interested in the interaction between CRY, Ramshackle and SGG and started to perform protein interaction studies in S2 cells. To our surprise, we were not able to replicate the results, that SGG overexpression does stabilize CRY, neither in S2 cells nor in the relevant clock neurons. SGG rather does the contrary. Furthermore, flies with SGG overexpression in the dorsal clock neurons became arrhythmic as did wild-type flies. Nevertheless, we could reproduce the published interaction of SGG with TIM, since flies with SGG overexpression in the lateral clock neurons shortened their free-running period. We conclude that SGG does not directly interact with CRY but rather with TIM. Furthermore we could demonstrate, that an unspecific antibody explains the observed stabilization effects on CRY.