Browsing by Subject "TRP ion channels"
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Publication Funktionen N- und C-terminaler Proteindomänen für Assemblierung, subzelluläre Lokalisation und Physiologie der TRP-Ionenkanäle in Drosophila Photorezeptoren(2011) Oberacker, Tina; Huber, ArminIn the photoreceptor cells of Drosophila melanogaster, the cation channels TRP and TRPL are responsible for generating the receptor potential. Previous publications have shown that the TRPL ion channel changes its subcellular localization depending on light conditions, while TRP is located in the rhabdomeres irrespective of light conditions. TRP and TRPL form tetramers. However, it is under debate in the scientific literature if TRP and TRPL form ho-momultimers only or also heteromultimers. In the present study, co-immunoprecipitations (Co-IPs) of untagged TRP or TRPL channels demonstrated that the tetrameric channels in the photoreceptors of Drosophila are composed of homomultimers exclusively. Co-IPs of eGFP-tagged TRP or TRPL channels showed that the tetramers consist of eGFP-tagged and the corresponding untagged channel subunits. To study the biochemical and physiological properties of the cytosolic N- and C-termini of TRP and TRPL, eGFP-tagged chimeric TRP/TRPL ion channels were generated and ex-pressed in the photoreceptor cells R1-R6 of Drosophila. The effect of these termini on trans-location of channels between the rhabdomere and the cell body and on ion channel assembly was studied. Studies of the subcellular localization of eGFP-tagged chimeras showed that a chimera com-posed of the transmembrane regions of TRP and both the N- and the C-terminus of TRPL displayed a light-dependent translocation behavior like TRPL. Interestingly, the translocation of this chimera was much faster than the TRPL-eGFP translocation. The exchange of either the N-terminus or the C-terminus of TRPL with the respective termini of TRP caused a locali-zation of these chimeras mainly in the cell body. This localization neither corresponded to the translocation of TRPL nor to the rhabdomeric localization of TRP. Therefore, motifs inducing light-dependent translocation of TRPL must be located in both termini and are only effective in concert. Co-IPs of the eGFP-tagged chimeras demonstrated that the C-terminus of TRPL appears to be more important than the N-terminus of TRPL. For interaction with the TRP channel the C-terminus of TRP also seems to be more important than the N-terminus. TRPL-TRPL or TRP-TRP interaction via the N-terminus could only be observed by Co-IPs in certain chimeras. In contrast to the termini, the transmembrane regions of both ion channels are not necessary for interaction. Assuming that an interaction between the eGFP-tagged chimera and endogenous channel subunits might cause a mislocalization of the endogenous subunit, immunocytochemical stu-dies were carried out. On cross sections through the eyes of dark and light adapted flies ex-pressing eGFP-tagged chimeras the localization of these eGFP-tagged channels was visua-lized by the eGFP fluorescence, while the localization of the endogenous subunits was de-termined by labeling with specific antibodies. It was found that those chimeras which show a strong interaction with the endogenous channels in Co-IPs cause a mislocalization of the corresponding endogenous channels. This thesis clarified that TRP and TRPL exclusively form homomutlimers in the photorecep-tors of Drosophila. Furthermore, it could be shown, which termini are responsible for the TRP and TRPL homomultimerization and which regions of the TRPL ion channel are necessary for TRPL translocation.