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Die Alveoläre Echinokokkose ist eine bedeutende, gefährliche Parasitose des Menschen. Über die molekularen Grundlagen und Mechanismen der Wirt-Parasit- Interaktion ist bislang nur wenig bekannt. In den letzten Jahren konnten Hinweise erlangt werden, dass Wirt und Parasit über evolutionsgeschichtlich konservierte Signalsysteme kommunizieren. Eines dieser Systeme ist das TGF-b/BMP-Signaltransduktionssystem. TGF-β-Signaltransduktionskomponenten steuern grundlegende Prozesse der Entwicklung und Differenzierung in allen Tieren. Über dieses Signalsystem wird ein weites Spektrum von zellulären Prozessen wie Proliferation, Apoptose und Differenzierung reguliert. Dieses System besteht aus strukturell verwandten Zytokinen der TGF-β (transforming growth factor β) bzw. BMP (bone morphogenetic protein)-Familie, membranständigen Rezeptoren der TGF-β-Rezeptorfamilie (Typ I und Typ II) sowie intrazellulären Signaltransduktoren der Smad-Familie. Bislang konnten verschiedene Echinokokken Smad-Faktoren (EmSmadA, EmSmadB, EmSmadC und EmSmadD) sowie drei Echinokokken Rezeptoren der Typ I Familie (EmRSK1, EmRSK2, EmRSK3) in E. multilocularis identifiziert werden. Ein Mitglied der TGF-β Typ II-Rezeptorfamilie war bislang noch nicht beschrieben. In dieser Arbeit wird ein solches Molekül vorgestellt, EmRSK4 (=TGF-b Typ IISerin/ Threonin Kinase Rezeptor aus Echinococcus multilocularis). Genexpressionsanalysen und immunhistochemische Untersuchungen zeigen an, dass EmRSK4 in der Germinalschicht des E. multilocularis Metacestoden zusammen mit EmRSK1 (=BMP Typ I-Serin/Threonin Kinase Rezeptor) exprimiert wird. Studien an heterolog exprimierten Rezeptoren zeigten, dass EmRSK4 funktionell aktiv ist und mit humanen Typ I-Rezeptoren einen Komplex bilden kann. Diese Studien zeigen auch, dass EmRSK4 mit EmRSK1 einen aktiven heterologen Typ I-/Typ II-Rezeptorkomplex in HEK293-T Zellen bildet, der durch Wirts-BMP2 stimuliert wird und EmSmadB aktiviert. In Untersuchungen mit EmRSK2 (= TGF-β Typ ISerin/ Threonin Kinase Rezeptor) konnte gezeigt werden, dass bei Anwesenheit beider Rezeptoren, EmRSK2 und EmRSK4, eine Phosphorylierung von EmSmadC nachweisbar ist, während eine Phosphorylierung von EmSmadA auch ohne die Anwesenheit von EmRSK4 stattfindet. Desweiteren konnte gezeigt werden, dass der Inhibitor SB-431452 die Kinaseaktivität von EmRSK2 hemmt. Nach Zugabe von exogenem BMP2 zu Metazestodenvesikel konnten Hinweise erhalten werden, dass ein bislang noch nicht charakterisiertes, zusätzliches EmSmad aktiviert wird. Zusammengenommen lässt die Co-Expression von EmRSK1 mit EmRSK4 in der Germinalschicht, die Bildung eines BMP-responsiven Komplexes aus beiden Rezeptoren und die Phosphorylierung mindestens eines zellulären Faktors nach exogener Zugabe von Wirts-BMP2 zu Metacestodenvesikeln darauf schließen, dass beide Rezeptoren während einer Infektion an der Sensierung von BMP Signalen des Wirts beteiligt sein könnten
Parasitic helminths share a large degree of common genetic heritage with their various hosts. This includes cell-cell-communication mechanisms mediated by small peptide cytokines and lipophilic/steroid hormones. These cytokines are candidate molecules for host-parasite cross-communication in helminth diseases. In this work the function of two evolutionary conserved signaling pathways in the model cestode Echinococcus multilocularis has been studied. First, signaling mechanisms mediated through fibroblast growth factors (FGF) and their cognate receptors (FGFR) which influence a multitude of biological functions, like homeostasis and differentiation, were studied. I herein investigated the role of EmFR which is the only FGFR homolog in E. multilocularis. Functional analyses using the Xenopus oocyte expression system clearly indicate that EmFR can sense both acidic and basic FGF of human origin, resulting in an activation of the EmFR tyrosine kinase domain. In vitro experiments demonstrate that mammalian FGF significantly stimulates proliferation and development of E. multilocularis metacestode vesicles and primary cells. Furthermore, DNA synthesis and the parasite’s Erk-like MAPK cascade module was stimulated in the presence of exogenously added mammalian FGF. By using the FGFR inhibitor BIBF1120 the activity of EmFR in the Xenopus oocyte system was effectively blocked. Addition of BIBF1120 to in vitro cultivated Echinococcus larval material led to detrimental effects concerning the generation of metacestode vesicles from parasite stem cells, the proliferation and survival of metacestode vesicles, and the dedifferentiation of protoscoleces towards the metacestode. In conclusion, these data demonstrate the presence of a functional EmFR-mediated signaling pathway in E. multilocularis that is able to interact with host-derived cytokines and that plays an important role in larval parasite development. Secondly, the role of nuclear hormone receptor (NHR) signaling was addressed. Lipophilic and steroid hormone signaling contributes to the regulation of metazoan development. By means of in silico analyses I demonstrate that E. multilocularis expresses a set of 17 NHRs that broadly overlaps with that of the related flatworms Schistosoma mansoni and S. japonicum, but also contains several NHR encoding genes that are unique to this parasite. One of these, EmNHR1, is homolog to the DAF-12/HR-96 subfamily of NHRs which regulate cholesterol homeostasis in metazoans. Modified yeast-two hybrid analyses revealed that host serum contains a ligand which induces homodimerization of the EmNHR1 ligand-binding domain. Also, a HNF4-like homolog, EmHNF4, was characterized. Human HNF4 plays an important role in liver development. RT-PCR experiments showed that both isoforms of the EmHNF4 encoding gene are expressed stage-dependently suggesting distinct functions of the two isoforms in the parasite. Moreover, specific regulatory mechanisms on the convergence of NHR signaling and TGF-β/BMP signaling pathways in E. multilocularis have been identified. On the one hand, EmNHR1 directly interacted with the EmSmadC and on the other hand EmHNF4b interacted with EmSmadD, EmSmadE which are all downstream signaling components of the TGF-β/BMP signaling pathway. This suggests cross-communication in order to regulate target gene expression. With these results, further studies on the role of NHR signaling in the cestode will be facilitated. Also, the first serum-free in vitro cultivation system for E. multilocularis was established using PanserinTM401 as medium. Serum-free co-cultivation with RH-feeder cells and an axenic cultivation method have been established. With the help of this serum-free cultivation system investigations on the role of specific peptide hormones, like FGFs, or lipophilic/steroid hormones, like cholesterol, for the development of helminths will be much easier.
Echinococcus multilocularis is the causative agent of alveolar echinococcosis (AE), a life-threatening disease with limited options of chemotherapeutic treatment. Anti-AE chemotherapy is currently based on a single class of drugs, the benzimidazoles. Although acting parasitocidic in vitro, benzimidazoles are merely parasitostatic during in vivo treatment of AE and cause severe site effects. In the case of operable lesions, the resection of parasite tissue needs to be supported by a prolonged chemotherapy. Thus, the current treatment options for AE are inadequate and require alternatives. In the present work, the flatworm signaling pathways were analyzed to establish potential targets for novel therapeutic approaches. I focused on factors that are involved in development and proliferation of E. multilocularis using molecular, biochemical and cell biological methods. Among the analysed factors were three MAP kinases of the parasite, EmMPK1, an Erk-1/2 orthologue, EmMPK2, a p38 orthologue and EmMPK3, an Erk7/8 orthologue. Further, I identified and characterized EmMKK2, a MEK1/2 orthologue of the parasite, which, together with the known kinases EmRaf and EmMPK1, forms an Erk1/2-like MAPK module. Moreover, I was able to demonstrate several influences of host growth factors such as EGF (epidermal growth factor) and insulin on worm signaling mechanisms and larval growth, including the phosphorylation of Elp, an ezrin-radixin-moesin like protein, EmMPK1, EmMPK3 and increased mitotic activity of Echinococcus cells. In addition, several substances were examined for their efficacy against the parasite including (i) general tyrosine kinase inhibitors (PP2, leflunamide), (ii) compounds designed to inhibit the activity of receptor tyrosine kinases, (iii) anti-neoplastic agents (miltefosine, perifosine), (iv) serine/threonine kinase inhibitors that have been designed to block the Erk1/2 MAPK cascade and (v) inhibitors of p38 MAPKs. In these studies, EmMPK2 proved to be a promising drug target for the following reasons. Amino acid sequence analysis disclosed several differences to human p38 MAPKs, which is likely to be the reason for the observed enhanced basal activity of recombinant EmMPK2 towards myelin basic protein in comparison to human recombinant p38 MAPK-α. In addition, the prominent auto-phosphorylation activity of the recombinant EmMPK2 protein together with the absence of an interaction with the Echinococcus MKKs suggest a different mechanism of regulation compared to the human enzyme. EmMPK2 activity could be effectively inhibited in vitro and in cultivated metacestode vesicles by treatment with SB202190 and ML3403, two ATP-competitive pyridinyl imidazole inhibitors of p38 MAPKs, in a concentration-dependent manner. Moreover, both compounds, in particular ML3403, caused parasite vesicle inactivation at concentrations which did not affect cultured mammalian cells. Likewise, during the cultivation of Echinococcus primary cells, the presence of ML3403 prevented the generation of new vesicles. Targeting members of the EGF signaling pathway, particulary of the Erk1/2-like MAPK cascade, with Raf and MEK inhibitors prevented the phosphorylation of EmMPK1 in metacestodes cultivated in vitro. However, although parasite growth was prevented under these conditions, the structural integrity of the metacestode vesicles maintained during long-term cultivation in the presence of the MAPK cascade inhibitors. Similar results were obtained when studying the effects of other drugs mentioned above. Taken together, several targets could be identified that reacted with high sensitivity to the presence of inhibitory substances, but did not cause the parasite’s death with one exception, the pyridinyl imidazoles. Based on the presented data, I suggest pyridinyl imidazoles as a novel class of anti-Echinococcus drugs and imply EmMPK2 as survival signal mediating factor, the inhibition of which could be used for the treatment of AE.
Alveolar echinococcosis (AE), a severe and life-threatening disease is caused by the small fox tapeworm Echinococcus multilocularis. Currently, the options of chemotherapeutic treatment are very limited and are based on benzimidazole compounds, which act merely parasitostatic in vivo and often display strong side effects. Therefore, new therapeutic drugs and targets are urgently needed. In the present work the role of two evolutionarily conserved signalling pathways in E. multilocularis, namely the insulin signalling cascade and Abl kinases, has been studied in regard to host-parasite interaction and the possible use in anti-AE chemotherapy.
Die alveoläre Echinokokkose (AE) ist eine lebensbedrohliche Erkrankung des Menschen, welche durch das infiltrative Wachstum des Metazestoden-Larvenstadiums des Fuchsbandwurms (Echinococcus multilocularis) in der Leber verursacht wird. Das tumorartige Wachstum des Metazestoden beruht auf einer Echinococcus-spezifischen Modifikation der anterior-posterioren-Körperachse (AP Achse). Es wird vermutet, dass dabei der anteriore Pol der invadierenden Oncospären-Larve zunächst abgeschaltet wird und sich der Metazestode anschließend asexuell als vesikuläres, posteriorisiertes Gewebes im Wirt vermehrt. Nach massiver Proliferation wird der anteriore Pol reetabliert und führt zur Bildung zahlreicher Bandwurm-Kopfanlagen (Protoskolizes). Da die Ausbildung der AP Körperachse evolutionsgeschichtlich konserviert über den wingless-related (Wnt)-Signalweg gesteuert wird, wurde in dieser Arbeit die Rolle von Wnt-Signaling bei der Musterbildung von E. multilocularis über molekular- und zellbiologische Studien näher beleuchtet.
Zentraler methodischer Ansatz der vorliegenden Arbeit war ein E. multilocularis Stammzell-Kultursystem, das Primärzellsystem, welches die in vitro-Generierung von Metazestoden-Vesikeln durch Proliferation und Differenzierung von germinativen Zellen (Stammzellen) erlaubt. Über RNA-Sequenzierung wurde zunächst gezeigt, dass in Primärzellkulturen sowohl Markergene für posteriore Entwicklung in Richtung Metazestode wie auch für Anterior-und Protoskolexmarker exprimiert werden. Unter Verwendung von RNA-Interferenz (RNAi) wurde anschließend ein erfolgreicher Knockdown des vermuteten Hauptregulators des kanonischen Wnt-Signalwegs, β Catenin (em-bcat1), erreicht und führte zu einem charakteristischen, sogenannten ‚red dot‘ Phänotyp, dem ersten jemals beschriebenen RNAi Phänotyp für E. multilocularis-Primärzellen. Primärzellkulturen nach em-bcat1 RNAi zeigten eine stark verminderte Fähigkeit, Metazestoden-Vesikel zu bilden sowie eine Überproliferation von germinativen Zellen. Zusätzliche RNA-Seq-Analysen des Transkriptoms von RNAi(em-bcat1)-Kulturen zeigten eine signifikant verringerte Expression von Posterior- und Metazestodenmarkern, während Anterior- und Protoskolexmarker deutlich überexprimiert wurden. Durch umfangreiche Whole-mount-in-situ-Hybridisierung (WMISH)-Experimente wurden diese Daten für eine Reihe ausgewählter Markergene für posteriore (Metazestode; em-wnt1, em-wnt11b, em-muc1) und für anteriore Entwicklung (Protoskolex; em sfrp, em-nou-darake, em npp36, em-frizzled10) verifiziert. In allen genannten Fällen zeigte sich durch Änderung der Polarität eine verminderte Genexpression von Posteriormarkern, während Anteriormarker deutlich erhöht exprimiert wurden. Ähnlich wie bei den verwandten, freilebenden Planarien, führt demnach ein Knockdown des zentralen Wnt-Regulators β-Catenin bei E. multilocularis zu einer anteriorisierten, Anterior- und Protoskolexmarker dominierte Genexpression, welche der posteriorisierten Entwicklung zum Metazestoden entgegenwirkt.
Neben Markergenen für die Ausbildung der AP-Achse wurden in dieser Arbeit auch solche für die medio-laterale (ML)-Körperachse bei Zestoden erstmals beschrieben. So zeigte sich, dass ein Slit-Ortholog (em slit) im E. multilocularis Protoskolex im Bereich der Körper-Mittellinie exprimiert wird und lieferte Hinweise darauf, dass, ähnlich zur Situation bei Planarien, die ML Achse von E. multilocularis durch Morphogengradienten aus slit (Mittellinie) und wnt5 (lateral) definiert wird. Im Metazestoden wird hingegen nur em-slit exprimiert. Der Metazestode besitzt damit als posterior-medianisiertes Gewebe Anlagen zur Polarität zur AP- und ML-Achse, welche erst mit Bildung von Protoskolizes vollständig etabliert werden. Schließlich deuten die Ergebnisse dieser Arbeit darauf hin, dass bei der Wiederherstellung der Körperachsen während der Entwicklung von Protoskolizes Hedgehog (Hh)-Signale entscheidend mitwirken.
Zusammenfassend wurde in dieser Arbeit der zentrale Faktor des kanonischen Wnt Signalwegs, β-Catenin, als Hauptregulator der Entwicklung des tumorartig wachsenden E. multilocularis-Metazestoden identifiziert. Zudem wurde gezeigt, dass zur Metazestodenbildung neben einer Echinococcus-spezifischen Modifikation der AP Körperachse auch eine solche der ML Achse beiträgt. In humanen malignen Tumoren sind der Wnt-, Slit-Robo- und Hh-Signalweg gut erforschte Wirkstofftargets und könnten in Zukunft in ähnlicher Weise für eine zielgerichtete Therapie von AE dienen.
Alveolar echinococcosis, which is caused by the metacestode stage of the small fox tapeworm Echinococcus multilocularis, is a severe zoonotic disease with limited treatment options. For a better understanding of cestode biology the genome of E. multilocularis, together with other cestode genomes, was sequenced previously. While a few studies were undertaken to explore the E. multilocularis transcriptome, a comprehensive exploration of global transcription profiles throughout life cycle stages is lacking. This work represents the so far most comprehensive analysis of the E. multilocularis transcriptome. Using RNA-Seq information from different life cycle stages and experimental conditions in three biological replicates, transcriptional differences were qualitatively and quantitatively explored. The analyzed datasets are based on samples of metacestodes cultivated under aerobic and anaerobic conditions as well as metacestodes obtained directly from infected jirds. Other samples are stem cell cultures at three different time points of development as well as non-activated and activated protoscoleces, the larval stage that can develop into adult worms. In addition, two datasets of metacestodes under experimental conditions suitable for the detection of genes that are expressed in stem cells, the so-called germinative cells, and one dataset from a siRNA experiment were analyzed. Analysis of these datasets led to expression profiles for all annotated genes, including genes that are expressed in the tegument of metacestodes and play a role in host-parasite interactions and modulation of the host's immune response. Gene expression profiles provide also further information about genes that might be responsible for the infiltrative growth of the parasite in the liver.
Furthermore, germinative cell-specific genes were identified. Germinative cells are the only proliferating cells in E. multilocularis and therefore of utmost importance for the development and growth of the parasite. Using a combination of germinative cell depletion and enrichment methods, genes with specific expression in germinative cells were identified. As expected, many of these genes are involved in translation, cell cycle regulation or DNA replication and repair. Also identified were transcription factors, many of which are involved in cell fate commitment. As an example, the gene encoding the telomerase reverse transcriptase (TERT) was studied further. Expression of E. multilocularis tert in germinative cells was confirmed experimentally. Cell culture experiments indicate that TERT is required for proliferation and development of the parasite, which makes TERT a potentially interesting drug target for chemotherapy of alveolar echinococcosis.
Germinative cell specific genes in E. multilocularis also include genes of densoviral origin. More than 20 individual densovirus loci with information for non-structural and structural densovirus proteins were identified in the E. multilocularis genome. Densoviral elements were also detected in many other cestode genomes. Genomic integration of these elements suggests that densovirus-based vectors might be suitable tools for genetic manipulation of tapeworms. Interestingly, only three of more than 20 densovirus loci in the E. multilocularis genome are expressed. Since the canonical piRNA pathway is lacking in cestodes, this raises the question about potential silencing mechanisms. Exploration of RNA-Seq information indicated natural antisense transcripts as a potential gene regulation mechanism in E. multilocularis. Preliminary experiments further suggest DNA-methylation, which was previously shown to occur in platyhelminthes, as an interesting avenue to explore in future.
The transcriptome datasets also contain information about genes that are expressed in differentiated cells, for example the serotonin transporter gene that is expressed in nerve cells. Cell culture experiments indicate that serotonin and serotonin transport play an important role in E. multilocularis proliferation, development and survival.
Overall, this work provides a comprehensive transcription data atlas throughout the E. multilocularis life cycle. Identification of germinative cell-specific genes and genes important for host-parasite interactions will greatly facilitate future research. A global overview of gene expression profiles will also aide in the detection of suitable drug targets and the development of new chemotherapeutics against alveolar echinococcosis.
Alveolar and cystic echinococcosis, caused by Echinococcus multilocularis and Echinococcus
granulosus respectively, are severe zoonotic diseases with limited treatment
options. The sole curative treatment is the surgical removal of the complete parasite
material. Due to late diagnosis, chemotherapeutic treatment often is the only treatment
option. Treatment is based on benzimidazoles, which merely act parasitostatic
and often display strong side effects. Therefore, new therapeutic drugs are urgently
needed.
Evolutionarily conserved signalling pathways are known to be involved in hostparasite
cross-communication, parasite development and survival. Moreover, they
represent potential targets for chemotherapeutic drugs. In this context the roles of
the serotonin- and cAMP-signalling pathways in Echinococcus were studied.
Genes encoding serotonin receptors, a serotonin transporter and enzymes involved in
serotonin biosynthesis could be identified in the E. multilocularis and E. granulosus
genomes indicating that these parasites are capable of synthesizing and perceiving
serotonin signals. Also the influence of exogenous serotonin on parasite development
was studied. Serotonin significantly increased metacestode vesicle formation
from primary cells and re-differentiation of protoscoleces. Inhibition of serotonin
transport with citalopram significantly reduced metacestode vesicle formation from
primary cells and caused death of protoscoleces and metacestodes. Furthermore, it
could be shown that serotonin increased phosphorylation of protein kinase A substrates.
Taken together, these results show that serotonin and serotonin transport
are essential for Echinococcus development and survival. Consequently, components
of the serotonin pathway represent potential drug targets.
In this work the cAMP-signalling pathway was researched with focus on G-protein
coupled receptors and adenylate cyclases. 76 G-protein coupled receptors, including
members of all major families were identified in the E. multilocularis genome.
Four genes homologous to adenylate cyclase IX were identified in the E. multilocularis
genome and three in the E. granulosus genome. While glucagon caused
no significant effects, the adenylate cyclase activator forskolin and the adenylate
cyclase inhibitor 2’, 5’ didesoxyadenosine influenced metacestode vesicle formation
from primary cells, re-differentiation of protoscoleces and survival of metacestodes.
It was further shown that forskolin increases phosphorylation of protein kinase A
substrates, indicating that forskolin activates the cAMP-pathway also in cestodes.
These results indicate that the cAMP signalling pathway plays an important role in
Echinococcus development and survival.
To complement this work, the influence of different media and additives on E. granulosus protoscoleces was investigated. Anaerobic conditions and the presence of FBS
prolonged protoscolex survival while different media influenced protoscolex activation
and development.
Taken together, this work provided important insights into developmental processes
in Echinococcus and potential drug targets for echinococcosis chemotherapy.
The insulin receptor ortholog EmIR of the fox-tapeworm Echinococcus multilocularis displays significant structural homology to the human insulin receptor (HIR) and has been suggested to be involved in insulin sensing mechanisms of the parasite’s metacestode larval stage. In the present work, the effects of host insulin on Echinococcus metacestode vesicles and the proposed interaction between EmIR and mammalian insulin have been studied using biochemical and cell-biological approaches. Human insulin, exogenously added to in vitro cultivated parasite larvae, (i) significantly stimulated parasite survival and growth, (ii) induced DNA de novo synthesis in Echinococcus, (iii) affected overall protein phosphorylation in the parasite, and (iv) specifically induced the phosphorylation of the parasite’s Erk-like MAP kinase orthologue EmMPK1. These results clearly indicated that Echinococcus metacestode vesicles are able to sense exogenous host insulin which induces a mitogenic response. To investigate whether EmIR mediates these effects, anti-EmIR antibodies were produced and utilized in biochemical assays and immunohistochemical analyses. EmIR was shown to be expressed in the germinal layer of the parasite both on the surface of glycogen storing cells and undifferentiated germinal cells. Upon addition of exogenous insulin to metacestode vesicles, the phosphorylation of EmIR was significantly induced, an effect which was suppressed in the presence of specific inhibitors of insulin receptor-like tyrosine kinases. Furthermore, upon expression of EmIR/HIR receptor chimera containing the extracellular ligand binding domain of EmIR in HEK 293 cells, a specific autophosphorylation of the chimera could be induced through the addition of exogenous insulin. These results indicated the capability of EmIR to sense and to transmit host insulin signals to the Echinococcus signaling machinery. The importance of insulin signaling mechanisms for parasite survival and growth were underscored by in vitro cultivation experiments in which the addition of an inhibitor of insulin receptor tyrosine kinases led to vesicle degradation and death. Based on the above outlined molecular data on the interaction between EmIR and mammalian insulin, the parasite’s insulin receptor orthologue most probably mediates the insulin effects on parasite growth and is, therefore, a potential candidate factor for host-parasite communication via evolutionary conserved pathways. In a final set of experiments, signaling mechanisms that act downstream of EmIR have been analyzed. These studies revealed significant differences between insulin signaling in Echinococcus and the related cestode parasite Taenia solium. These differences could be associated with differences in the organo-tropism of both species.
Molecular and developmental characterization of the Echinococcus multilocularis stem cell system
(2014)
The metacestode larva of Echinococcus multilocularis is the causative agent of alveolar echinococcosis (AE), one of the most dangerous zoonotic diseases in the Northern Hemisphere. Unlike “typical” metacestode larvae from other tapeworms, it grows as a mass of interconnected vesicles which infiltrates the liver of the intermediate host, continuously forming new vesicles in the periphery. From these vesicles, protoscoleces (the infective form for the definitive host) are generated by asexual budding. It is thought that in E. multilocularis, as in other flatworms, undifferentiated stem cells (so-called germinative cells in cestodes and neoblasts in free-living flatworms) are the sole source of new cells for growth and development. Therefore, this cell population should be of central importance for the progression of AE.
In this work, I characterized the germinative cells of E. multilocularis, and demonstrate that they are indeed the only proliferating cells in metacestode vesicles. The germinative cells are a population of undifferentiated cells with similar morphology, and express high levels of transcripts of a novel non-autonomous retrotransposon family (ta-TRIMs). Experiments of recovery after hydroxyurea treatment suggest that individual germinative cells have extensive self-renewal capabilities. However, germinative cells also display heterogeneity at the molecular level, since only some of them express conserved homologs of fgfr, nanos and argonaute genes, suggesting the existence of several distinct sub-populations. Unlike free-living flatworms, cestode germinative cells lack chromatoid bodies. Furthermore, piwi and vasa orthologs are absent from the genomes of cestodes, and there is widespread expression of some conserved neoblast markers in E. multilocularis metacestode vesicles. All of these results suggest important differences between the stem cell systems of free-living flatworms and cestodes.
Furthermore, I describe molecular markers for differentiated cell types, including the nervous system, which allow for the tracing of germinative cell differentiation. Using these molecular markers, a previously undescribed nerve net was discovered in metacestode vesicles. Because the metacestode vesicles are non-motile, and the nerve net of the vesicle is independent of the nervous system of the protoscolex, we propose that it could serve as a neuroendocrine system. By means of bioinformatic analyses, 22 neuropeptide genes were discovered in the E. multilocularis genome. Many of these genes are expressed in metacestode vesicles, as well as in primary cell preparations undergoing complete metacestode regeneration. This suggests a possible role for these genes in metacestode development. In line with this hypothesis, one putative neuropeptide (RGFI-amide) was able to stimulate the proliferation of primary cells at a concentration of 10-7 M, and the corresponding gene was upregulated during metacestode regeneration.
Die alveoläre Echinokokkose ist eine, vorrangig in der nördlichen Hemisphäre verbreitete, parasitäre Erkrankung. Verursacht wird sie beim Menschen durch das Larvenstadium des Fuchsbandwurms. Homeoboxgene sind hochkonservierte Gene, die die Morphogenese von Lebewesen steuern. Die Anzahl und die Bedeutung von Homeoboxgenen in der Entwicklung von E.multilocularis waren bislang unbekannt. Im Rahmen dieser Arbeit konnten mit Hilfe von Sequenzanalysen im Genom des Fuchsbandwurms erstmals Homeoboxgene identifiziert und deren Expressionsmuster mittels PCR in verschiedenen Larvenstadien charakterisiert werden. Von insgesamt 23 gefundenen Homeoboxgenen wurden 15 Gene auf ihre larvenstadienspezifische Expression untersucht. Neun der untersuchten Gene zeigten in dem gewählten Versuchsaufbau eine Expression in den untersuchten Larvenstadien, fünf davon zeigten eine verstärkte Expression in den späten Larvenstadien. Für acht dieser neun Gene ließen sich darüber hinaus Hinweise auf eine Prozessierung ihrer mRNA über den Mechanismus des Trans-Spleißens finden. Vorangehende Versuche der Arbeitsgruppe von Prof. Brehm hatten einen Zusammenhang zwischen einer Stimulation früher Entwicklungsstadien der Parasitenlarven mit dem Zytokin BMP-2 und dessen rascherer Entwicklung in spätere Entwicklungsstadien nahegelegt. Die Auswirkung einer Behandlung früher Entwicklungsstadien mit dem Zytokin BMP-2 auf die jeweilige Genexpression wurde daher für die ausgewählten 15 Gene überprüft. Fünf Gene zeigten unter dessen Einfluss eine verstärkte Expression. Zwei darunter waren solche, die eine stärkere Expression in späten Larvenstadien aufwiesen. Diese zwei Gene stellen nun Kandidaten dar, die an der Entwicklung von E.multilocularis maßgeblich beteiligt sein könnten. Durch die Untersuchungen dieser Arbeit ergaben sich wichtige Hinweise auf die Entwicklung und die Regulationsmechanismen der Genexpression von E. multilocularis. Sie bilden eine Grundlage, die Rolle der Homeoboxgene für den Fuchsbandwurm näher zu beschreiben und die hormonelle Kreuzregulation zwischen Parasit und Wirt weiter zu studieren.