Schizonts of Theileria annulata interact with the microtubuli network of their host cell via the membrane protein TaSP.

Intracellular leukoproliferative Theileria are unique as eukaryotic organisms that transform the immune cells of their ruminant host. Theileria utilize the uncontrolled proliferation for rapid multiplication and distribution into host daughter cells. The parasite distribution into the daughter cells is accompanied by a tight association with the host cell mitotic apparatus. Since the molecular basis for this interaction is largely unknown, we investigated the possible involvement of the immunodominant Theileria annulata surface protein, TaSP, in the attachment of the parasite to host cell microtubule network. Confocal microscopic analyses showed co-localization of the TaSP protein with alpha-tubulin and reciprocal immuno-co-precipitation experiments demonstrated an association of TaSP with alpha-tubulin in vivo. In addition, the partially expressed predicted extracellular domain of TaSP co-localized with the mitotic spindle of dividing cells and was co-immunoprecipitated with alpha-tubulin in transiently transfected Cos-7 cells devoid of other T. annulata expressed proteins. Pull-down studies showed that there is a direct interaction between TaSP and polymerized microtubules. Analysis of the interaction of TaSP and host microtubulin during host cell mitosis indicated that TaSP co-localizes and interacts with the spindle poles, the mitotic spindle apparatus and the mid-body. Moreover, TaSP was demonstrated to be localized to the microtubule organizing center and to physically interact with gamma-tubulin. These data support the notion that the TaSP-microtubule interaction may be playing a potential role in parasite distribution into daughter host cells and give rise to the speculation that TaSP may be involved in regulation of microtubule assembly in the host cell.

Cloning, expression, purification, and characterization of a designer protein with repetitive sequences.

An artificial protein containing alternating hydrophilic-hydrophobic blocks of amino acids was designed in order to mimic the structure of synthetic multiblock copolymers. The hydrophobic block consisted of the six amino acids Ala Ile Leu Leu Ile Ile (AILLII) and the hydrophilic block of the eight amino acids Thr Ser Glu Asp Asp Asn Asn Gln (TSEDDNNQ). The coding DNA sequence of the cluster was inserted into an commercial pET 30a(+) vector using a two step strategy. The expression of the artificial protein in Escherichia coli was optimized using a temperature shift strategy. Only at cultivation temperature of 24 degrees C after induction expression was observed, whereas at 30 and 37 degrees C no target protein could be detected. Cells obtained from a 15L bioreactor cultivation of E. coli were disintegrated by mechanical methods. Interestingly, glass bead milling and high pressure homogenization resulted in a different solubility of the target protein. The further purification was carried out by affinity chromatography using the soluble homogenized protein. Extreme conditions (6M urea, 0.5M NaCl) were applied in order to prevent aggregation to insoluble particles. The designer protein showed an extremely high tendency to form dimers or trimers caused by intermolecular interactions which were even not broken under the conditions of SDS-polyacrylamide gel electrophoresis, rendering the behavior during purification different from proteins usually found in nature. The protein preparation was not completely pure according to SDS-PAGE stained by Coomassie blue or silver. In MALDI-TOF-MS, nano-ESI qTOF-MS of the entire protein preparation and nano-ESI-MS after digestion by trypsin and chymotrypsin impurities were not detectable.