@phdthesis{Agarwal2010, author = {Agarwal, Shruti}, title = {Functional characterization of four CDK-like kinases and one Calmodulin-dependent kinase of the human malaria parasite, Plasmodium falciparum}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-48522}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Malaria still persists as one of the deadliest infectious disease in addition to AIDS and tuberculosis. lt is a leading cause of high mortality and morbidity rates in the developing world despite of groundbreaking research on global eradication of the disease initiated by WHO, about half a century ago. Lack of a commercially available vaccine and rapid spread of drug resistance have hampered the attempts of extinguishing malaria, which still leads to an annual death toll of about one million people. Resistance to anti-malarial compounds thus renders search for new target proteins imperative. The kinome of the human malaria parasite Plasmodium falciparum comprises representatives of most eukaryotic protein kinase groups, including kinases which regulate proliferation and differentiation processes. Several reports till date have suggested involvement of parasite kinases in the human host and as well as in the mosquito vector. Kinases essential for life cycle stages of the parasite represent promising targets for anti-malarial compounds thus, provoking characterization of additional malarial kinases. Despite extensive research on most plasmodial enzymes, very little information is available regarding the four identified members of the cyclin dependent kinase like kinase (CLK) family. Thus, the present thesis dealt with the functional characterization of four members of the PfCLK kinase family of the parasite denoted as PfCLK-1/Lammer, PfCLK-2, PfCLK-3 and PfCLK-4 with a special focus on the first two kinases. Additionally, one Ca2+/Calmodulin dependent putative kinase-related protein, PfPKRP, presumed to be involved in sexual stage development of the parasite, was investigated for its expression in the life cycle of the parasite. In other eukaryotes, CLK kinases regulate mRNA splicing through phosphorylation of Serine/Arginine-rich proteins. Transcription analysis revealed abundance of PfCLK kinase genes throughout the asexual blood stages and in gametocytes. By reverse genetics approach it was demonstrated that all four kinases are essential for completion of the asexual replication cycle of P. falciparum. PfCLK 1/Lammer possesses two nuclear localization signals and PfCLK-2 possesses one of these signals upstream of the C-terminal catalytic domains. Protein level expression and sub-cellular localization of the two kinases was determined by generation of antiserum directed against the kinase domains of the respective kinase. Indirect immunofluorescence, Western blot and electron microscopy data confirm that the kinases are primarily localized in the parasite nucleus, and in vitro assays show that both enzymes are associated with phosphorylation activity. Finally, mass spectrometric analysis of co immunoprecipitated proteins shows interactions of the two PfCLK kinases with proteins, which have putative nuclease, phosphatase or helicase functions. PfPKRP on the other hand is predominantly expressed during gametocyte differentiation as identified from transcriptional analysis. Antiserum directed against the catalytic domain of PfPKRP detected the protein expression profile in both asexual and gametocyte parasite lysates. Via immunofluorescence assay, the kinase was localized in the parasite cytoplasm in a punctuated manner, mostly in the gametocyte stages. Reverse genetics resulted in the generation of PfPKRP gene-disruptant parasites, thus demonstrating that unlike CLK kinases, PfPKRP is dispensable for asexual parasite survival and hence might have crucial role in sexual development of the parasite. On one hand, characterization of PfCLK kinases exemplified the kinases involved in parasite replication cycle. Successful gene-disruption and protein expression of PfPKRP kinase on the other hand, demonstrated a role of the kinase in sexual stage development of the parasite. Both kinase families therefore, represent potential candidates for anti-plasmodial compounds.}, subject = {Plasmodium falciparum}, language = {en} } @phdthesis{Engelhardt2004, author = {Engelhardt, Catherine Marie}, title = {Identification and characterisation of the Spred protein family}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-11456}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {The subject of this thesis was the cloning and the initial biochemical and functional characterisation of novel human proteins with an N-terminal Ena-VASP homology (EVH)-1 domain and a C-terminal Sprouty homologous region (SPR), which are related to the Drosophila AE33 protein. During the course of this work, three mouse homologues of the AE33 fly protein have been reported and termed Sprouty-related protein with an EVH-1 domain 1, 2 and 3 (Spred-1, -2, -3)(Wakioka et al, 2001; Kato et al, 2003). Spred-1, -2 and -3 are membrane associated substrates of receptor tyrosine kinases and they act as negative regulators of the Ras pathway during growth factor stimulation. As the Spred-family members seem to exert similar functions, the specific function of each member remains enigmatic. Therefore, we investigated the mRNA and protein expression patterns of the two murine protein family members Spred-1 and Spred-2 on the whole organ level. Furthermore, we focussed on the cellular localisation and the role of human and murine Spred-2 in the organism. The expression patterns of Spred-1 and Spred-2 differed markedly among various tissues and cell types. In mouse, Spred-1 is abundantly expressed in adult brain, cerebellum, and fetal tissues, whereas Spred-2 was ubiquitously expressed. In humans, Spred-2 was found to be strongly expressed in glandular epithelia and in invasive cytotrophoblasts, and at the subcellular level its immunoreactivity was associated with secretory vesicles and was found to colocalise with Rab11 GTPase. The new human Spred gene family was investigated in detail. Cloning of the fulllength form of human Spred-2 resulted in an 1254 bp coding sequence, corresponding to a 418 amino-acids protein. Immunoblotting with a set of affinitypurified antibodies confirmed the expression of a 47 kDa protein and suggested the presence of additional differently sized variants. Cloning of various shortened Spred- 2 mRNAs and identification of 2 additional human Spred genes (localised on different chromosomes) with their respective EST (expressed sequence tag) revealed that the new human Spred gene family displays extensive splicing, leading to the generation of short and long Spred proteins. All protein isoforms and splicing variants contain an EVH1-domain located at the N-terminus of the protein. The full-length forms ("a" forms) comprised the SPR, another functional domain localised at the C-terminus whereas the short variants (Spred-1b, 2 c-e, 3 c) lack the entire C-terminal SPR domain or part of it. The existence of short and long splicing variants of Spred-1, -2 and -3 revealed a common principle of organisation and splicing pattern in the Spred family. Functional analyses of the 5 cloned Spred-2 splicing variants revealed differential subcellular localisation and differential regulation of serum- and EGF- mediated ERK activation in HEK-293 cells. Taken together, these results indicate a highly specific expression pattern of Spred-1 and Spred-2 in various tissues suggesting a specific physiological role for the individual Spred isoform in these tissues. For example, Spred-2 appears to be involved in regulating secretory pathways. Furthermore, the human Spred family contains three genes, which are subject to extensive alternative splicing resulting in at least 8 different proteins with differential subcellular localisation and differential regulatory potential of the MAPK pathways during growth factor stimulation.}, subject = {Spred Protein}, language = {en} }