Identification of target genes of the T-box proteins in Drosophila melanogaster

In a prior bioinformatic analysis by Hüyseyin Binbas, potential Tbx targets sequences in wing-related genes have been identified. Guided by this information, enhancer trap/reporter lacZ insertions were characterized by X-gal staining first in wildtype and then in l(1)omb imaginal discs.rnIn several lines I observed an increase in reporter expression in a l(1)omb mutant background. Since Omb is assumed to function predominantly as a transcriptional repressor, this may indicate direct regulation. Repression by Omb was observed e.g. for brk and tkv. These genes are negatively regulated by Dpp, while omb is induced by Dpp. Omb which mediates the effects of Dpp on proliferation could, thus, also mediate the Dpp effect on patterning of the wing disc. However, brk and tkv were not completely derepressed in l(1)omb indicating that Dpp represses these genes also by an Omb-independent mechanism.rnMore frequently I observed loss of reporter expression in an l(1)omb mutant background. In these cases, regulation by Omb presumably is indirect. For example, STAT92E-lacZ expression in the wildtype eye was symmetrically expressed at the dorsal and ventral margins. In l(1)omb, ventral expression was selectively lost. Loss of omb is known to cause ventral overproliferation of the eye by activation of the Jak/STAT pathway. STAT92E expression is negatively regulated by Jak/STAT signaling suggesting that loss of omb activates Jak/STAT further upstream in the pathway.rnRegional overproliferation of eye and wing in the l(1)omb mutant background proved a complicating issue in the search for Omb targets. This effect made it difficult to decide whether an expanded reporter expression pattern was due to tissue expansion or reporter gene derepression. For instance hth-lacZ appeared to expand along the ventral eye disc margin in l(1)omb. Without addtional experiments it cannot be concluded whether this is due to de-repression or to activation in association with the proliferative state. Parallel to my experiments, evidence accumulated in our laboratory that loss of omb may attenuate Wg and Hegehog signaling. Since these diffusible proteins are the main patterning molecules in the wing imaginal disc, with dpp being downstream of Hh, many of the observed effects could be secondary to reduced Wg and Hh activity. Examples are ab-lacZ, Dll-lacZ and vgBE-lacZ (reduced expression on the dorso-ventral boundary) and inv-lacZ (late larval expression in the anterior wing disc compartment is lost) or sal-lacZ. Epistasis experiment will be required to clarifiy these issues.rnFurthermore, loss of omb appeared to induce cell fate changes. It was reported previously that in an omb null mutant, the dorsal determinant apterous (ap) is ectopically expressed in the ventral compartment (an effect I did not observe with the strongly hypomorphic l(1)omb15, indicating strong dose dependence). Ventral repression of ap is maintained by epigenetic mechanisms. The patchy and variable nature of ectopic expression of ap or grn-1.1-lacZ points to an effect of omb on epigenetic stability.rnIn the second part of my thesis, an analysis of Omb expression in the Drosophila embryonic ventral nervous system was performed. Omb was found co-expressed with Eve in the medial aCC and RP2 motorneurons as well as the fpCC interneuron and the mediolateral CQ neurons. Additionally, Omb was detected in the Eg positive NB7-3 GW serotonergic motoneuron and the N2-4 neurons. Omb was not found in Repo positive glial cells. During embryonic stage 14, Omb showed some coepression with Dpn or Pros. At the embryonic stage 16, Omb was expressed in minor subset of Mid and Wg positive cells.

Leishmania major promastigote entry of an autophagy-like compartment and amastigote escape from the parasitophorous vacuole

In this thesis, we investigated the interaction of the obligate intracellular parasite Leishmania (L.) major with two phenotypes of human monocyte derived macrophages (hMDMs). Thereby we focused on the development and maturation of the parasitophorous vacuole (PV) and could show that compartment development is dependent on the parasite stage.rnFocusing on the ultrastructure of PVs containing axenic amastigotes, we demonstrated that the parasites are partially located in damaged PVs or in the cytoplasm of the host. Moreover, we visualized multiple amastigotes in a common PV 144 h p.i. in pro-inflammatory hMDM I but not in anti-inflammatory hMDM II indicating different PV development. rnRegarding the promastigote form, we demonstrated a different uptake of viable and apoptotic L. major promastigotes by hMDMs. Viable promastigotes are predominantly taken up via the flagellum tip whereas apoptotic promastigotes enter the cells via the parasite body. Analyzing compartment maturation, we found that 20-30% of the PVs get positive for the early maturation markers PI3P and EEA1 independent of the viability of the parasites and unaffected by the human macrophage type. Subsequently, 25-40% of the parasites acquire the autophagy marker LC3 on their PV, what is independent of the viability of the parasites as well. We quantified this and in hMDM II less LC3-positive compartments formed compared to hMDM I. Analyzing the ultrastructure, we investigated that the compartments consist of a single-membrane PV characteristic for LC3-associated phagocytosis (LAP). Involvement of LAP was confirmed by demonstrating that the protein kinase ULK1 is dispensable for LC3-compartment formation around Leishmania PVs. Visualizing compartment dynamics in real time showed that apoptotic promastigotes are degraded in LC3-positve compartments, whereas viable promastigotes are able to get rid of LC3-protein on their PV suggesting an involvement in parasite development and survival. In this thesis, we established a lentiviral based fluorescent imaging technique that we combined with High-Pressure-Freezing (HPF) and high-resolution 3D electron microscopy. We visualized a promastigote in a LC3-compartment whose ultrastructure showed an opening of the PV to the outside. To identify new LAP markers involved in Leishmania infection, we established an immuno-magnetic isolation protocol for the purification of Leishmania containing compartments.rnIn conclusion, this study suggests that L. major compartment biogenesis and maturation in pro- and anti-inflammatory human macrophages is dependent on the parasite stage and is different between axenic amastigotes, viable promastigotes and apoptotic promastigotes. Understanding the development and maturation of Leishmania parasites in human host cells is important to control and combat the neglected disease leishmaniasis in the future.rn