Phosphorylation controls autoinhibition of cytoplasmic linker protein-170

Author Posting. © American Society for Cell Biology, 2010. This article is posted here by permission of American Society for Cell Biology for personal use, not for redistribution. The definitive version was published in Molecular Biology of the Cell 21 (2010): 2661-2673, doi:10.1091/mbc.E09-12-1036.Cytoplasmic linker protein (CLIP)-170 is a microtubule (MT) plus-end-tracking protein that regulates MT dynamics and links MT plus ends to different intracellular structures. We have shown previously that intramolecular association between the N and C termini results in autoinhibition of CLIP-170, thus altering its binding to MTs and the dynactin subunit p150Glued (J. Cell Biol. 2004: 166, 1003–1014). In this study, we demonstrate that conformational changes in CLIP-170 are regulated by phosphorylation that enhances the affinity between the N- and C-terminal domains. By using site-directed mutagenesis and phosphoproteomic analysis, we mapped the phosphorylation sites in the third serine-rich region of CLIP-170. A phosphorylation-deficient mutant of CLIP-170 displays an "open" conformation and a higher binding affinity for growing MT ends and p150Glued as compared with nonmutated protein, whereas a phosphomimetic mutant confined to the "folded back" conformation shows decreased MT association and does not interact with p150Glued. We conclude that phosphorylation regulates CLIP-170 conformational changes resulting in its autoinhibition.This work was supported by National Institutes of Health grant GM-25062 (to G.G.B.); Netherlands Organization for Scientific Research grants (to A. A. and N. G.); a Cancer Genomics Centre grant (to J.v.H.); and Presidential Program of Russian Academy of Sciences and RFBP grant 05-04-4915 (to E.S.N.)

Melanosome transfer, photoreception and toxicity assays in melanophores

Many animals such as fish and frogs have developed the ability to change colour of their skin to adapt to the environment or to signal to other individuals. This ability is due to specialised skin cells called melanophores. Melanophores contain thousands of melanosomes, small membrane-enclosed organelles containing the black or brown pigment melanin. The melanosomes can aggregate to the cell centre rendering the cells pale or disperse throughout the cell to become dark. The intracellular transport of melanosomes is regulated by neuronal or hormonal external stimuli. Fast colour change is achieved by aggregation/dispersion of melanosomes but long-term colour change can also be achieved by melanosome transfer to surrounding skin cells. An amphibian immortalized melanophore cell line was used from the African claw frog, Xenopus laevis to study transfer of melanosomes to co-cultured fibroblasts. Melanosome transfer was observed and up regulated by the hormone α-MSH . The transfer was quantified using light-, fluorescence and electron microscopy. A new and powerful method for transfer experiments was developed. Fluorescent semiconductor nanocrystals, qdots, were used in combination with flow cytometry. The qdots were taken up by the cultured Xenopus laevis melanophores, localised to the melanosomes and transferred to co-cultured fibroblasts. The method is a step towards enabling large scale analysis of pigment transfer. Xenopus laevis melanophores can be cultivated in 96-well culture plates which allow quantification of aggregation or dispersion in a fast and reproductive way. Glyphosate containing herbicides, i.e. Roundup, are commonly used in the world, but some toxic effects have been found on amphibians in vivo and human and mouse cells in vitro. To learn more about potential effects on intracellular transport and the cytoskeleton in animal Roundup, glyphosate, glyphosateisopropylamine and isopropylamine were tested on the transport of melanosomes to the cell centre by spectrophotmetry and by fluorescence microscopy on microtubules and actin filaments. All tested compounds inhibited the aggregation and affected the morphology of the cytoskeleton. The effect was found to be pH dependent. Amphibian melanophores can be regulated directly by light via a melanopsin receptor. Photoreception was found in cultured early embryos of the zebrafish Danio rerio. Light induced dispersion of the melanophores was contrast to what is found at adults when light causes aggregation of the melanosomes due to signals from the CNS. At least one subclass of melanopsin was detected in the zebrafish retinal pigment epithelial cells

Rhabdomeric phototransduction initiated by the vertebrate photopigment melanopsin

Melanopsin is the photopigment that confers light sensitivity on intrinsically photosensitive retinal ganglion cells. Mammalian intrinsically photosensitive retinal ganglion cells are involved in the photic synchronization of circadian rhythms to the day–night cycle. Here, we report molecular components of melanopsin signaling using the cultured Xenopus dermal melanophore system. Photo-activated melanopsin is shown to initiate a phosphoinositide signaling pathway similar to that found in invertebrate photo-transduction. In melanophores, light increases the intracellular level of inositol trisphosphate and causes the dispersion of melanosomes. Inhibition of phospholipase C and protein kinase C and chelation of intracellular calcium block the effect of light on melanophores. At least four proteins, 43, 74, 90, and 134 kDa, are phosphorylated by protein kinase C upon light stimulation. This provides evidence of an invertebrate-like light-activated signaling cascade within vertebrate cells