Tubulin-nucleotide interactions during the polymerization and depolymerization of microtubules
The interactions of nucleotides and their role in the polymerization of tubulin have been studied in detail. GTP promotes polymerization by binding to the exchangeable site (E site) of tubulin. The microtubules formed contain only GDP at the E site, indicating that hydrolysis of E site GTP occurs during or shortly after polymerization. Tubulin prepared by several cycles of polymerization and depolymerization will polymerize in the presence of ATP as well as GTP. Polymerization in ATP is preceded by a distinct lag period which is shorter at higher concentrations of ATP. As reported by others ATP will transphosphorylate bound GDP to GTP. Under polymerizing conditions the maximum level of GTP formation occurs at about the same time as the onset of polymerization, and the lag probably reflects the time necessary to transphosphorylate a critical concentration of tubulin. The transphosphorylated protein can be isolated and will polymerize without further addition of nucleotide. The transphosphorylated GTP is hydrolyzed and the phosphate released during polymerization. About 25% of the phosphate transferred from ATP is noncovalently bound to the subunit as inorganic phosphate and this fraction is also released during polymerization. The nonhydrolyzable analogue of GTP, GMPPNP, will promote microtubule assembly at high concentration. GMPPNP assembled microtubules do not depolymerize in Ca concentrations several fold greater than that which will completely depolymerize GTP assembled tubules; however, addition of Ca prior to inducing polymerization in GMPPNP prevents the formation of microtubules. Thus GTP hydrolysis appears to promote depolymerization rather than polymerization. GDP does not promote microtubule assembly but can inhibit GTP binding and GTP induced polymerization. GDP does not, however, induce the depolymerization of formed microtubules. These experiments demonstrate that tubulin polymerization can not be treated as a thermodynamically reversible process, but must involve one or more irreversible steps. Exchange experiments with [3H]GTP indicate that the "E" site on both microtubules and ring aggregates of tubulin is blocked and does not exchange rapidly. However, during polymerization and depolymerization induced by raising or lowering the temperature, respectively, all the E sites become transiently available and will exchange their nucleotide. This observation does not suggest a direct morphological transition between rings and microtubules. The presence of a blocked E site on the rings explains the apparent transphosphorylation and hydrolysis of "N" site nucleotide reported by others.
SummaryMaintaining the proximity of centrosomes to nuclei is important in several cellular contexts, and LINC complexes formed by SUN and KASH proteins are crucial in this process. Here, we characterize the presumed Drosophila ortholog of the mammalian SUN protein, sperm-associated antigen 4 (Spag4, previously named Giacomo), and demonstrate that Spag4 is required for centriole and nuclear attachment during spermatogenesis. Production of spag4 mRNA is limited to the testis, and Spag4 protein shows a dynamic pattern of association with the germline nuclei, including a concentration of protein at the site of attachment of the single spermatid centriole. In the absence of Spag4, nuclei and centrioles or basal bodies (BBs) dissociate from each other after meiosis. This role of Spag4 in centriolar attachment does not involve either of the two KASH proteins of the Drosophila genome (Klarsicht and MSP-300), but does require the coiled-coil protein Yuri Gagarin. Yuri shows an identical pattern of localization at the nuclear surface to Spag4 during spermatogenesis, and epistasis studies show that the activities of Yuri and dynein-dynactin are downstream of spag4 in this centriole attachment pathway. The later defects in spermatogenesis seen for yuri and spag4 mutants are similar, suggesting they could be secondary to initial disruption of events at the nuclear surface.
A unique feature of the genus Drosophila is the formation of unusually long sperm tails. Sperm lengths of millimeters are common within this group, with the 1.8 mm sperm of D. melanogaster being fairly typical. This marked expansion in sperm length reflects an unusual aspect of spermatogenesis in these organisms: in contrast to other species in which an intraflagellar transport system is used for growth of the sperm flagellum (Scholey, 2006), Drosophila sperm axonemes are assembled in syncytial cysts by a mechanism that does not require, and is not limited by, this system (Han et al., 2003;Sarpal et al., 2003). This unusual sperm axoneme development and the resulting expansion of sperm tail length have led to distinctive features of spermatogenesis not found in other species. In D. bifurca, a special 'sperm roller' has evolved to package its 6-centimeter-long gametes (Joly et al., 2003). In D. melanogaster, a highly evolved individualization process that generates 64 individual sperm from an elongate cyst containing 64 syncytial spermatids has been identified and studied (Noguchi and Miller, 2003;Tokuyasu et al., 1972a). The distinctive molecular mechanisms needed for this process include a motile filamentous actin system (the investment, or actin, cones) that traverses the entire length of the sperm tails, removing excess cytoplasm and investing each sperm in its own plasma membrane. A specialized microtubulerich structure (the dense complex) is also associated with the sperm nuclei and functions to position the basal body and also possibly to strengthen the nuclei as they undergo extreme condensation (A. D. Tates, Cytodifferentiation during spermatogenesis in Drosophila melanogaster, PhD thesis, Rijksuniversiteit Leiden, The Netherlands, 1971) (Tokuyasu, 1974).We have identified a locus, yuri gagarin (yuri), that we show here has multiple roles in the generation of elongate individualized sperm. The gene is only highly conserved in the genus Drosophila, suggesting specialized roles in these organisms. Interestingly, yuri was initially identified through its function in another specialized organ system of insects and arthropods: the chordotonal organs. These are complex mechanosensory structures with roles in proprioception and graviperception. The first mutation at the locus, yuri c263 , was identified in a screen for mutants affecting gravitaxis. Altered gravitaxis was shown to result from perturbed expression of yuri in subsets of chordotonal neurons (Armstrong et al., 2006). The molecular functions of the locus identified here suggest that yuri mediates specialized actin-and microtubule-related activities in Drosophila tissues. ResultsThe yuri locus in D. melanogaster and other Drosophilids In addition to the cDNA (GH14032) encoding a ~30 kDa protein that we used previously (Armstrong et al., 2006), we identified 11 further yuri ESTs/cDNAs from adult testis, ovary, S2 cells and embryos through FlyBase. Sequencing of these new cDNAs established that three major transcript classes are generated from yuri (Fig...
Abstract. Dictyostelium discoideum initiates development when ceils overgrow their bacterial food source and starve. To coordinate development, the cells monitor the extracellular level of a protein, conditioned medium factor (CMF), secreted by starved cells. When a majority of the cells in a given area have starved, as signaled by CMF secretion, the extracellular level of CMF rises above a threshold value and permits aggregation of the starved cells. The cells aggregate using relayed pulses of cAMP as the chemoattractant. Cells in which CMF accumulation has been blocked by antisense do not aggregate except in the presence of exogenous CMF. We find that these cells are viable but do not chemotax towards cAMP. Videomicroscopy indicates that the inability of CMF antisense cells to chemotax is not due to a gross defect in motility, although both video and scanning electron microscopy indicate that CMF increases the frequency of pseudopod formation.The activations of Ca 2+ influx, adenylyl cyclase, and guanylyl cyclase in response to a pulse of cAMP are strongly inhibited in cells lacking CMF, but are rescued by as little as 10 s exposure of cells to CMF. The activation of phospholipase C by cAMP is not affected by CMF. Northern blots indicate normal levels of the cAMP receptor mRNA in CMF antisense cells during development, while cAMP binding assays and Scatchard plots indicate that CMF antisense cells contain normal levels of the cAMP receptor. In Dictyostelium, both adenylyl and guanylyl cyclases are activated via G proteins. We find that the interaction of the cAMP receptor with G proteins in vitro is not measurably affected by CMF, whereas the activation of adenylyl cyclase by G proteins requires cells to have been exposed to CMF. CMF thus appears to regulate aggregation by regulating an early step of cAMP signal transduction.
An epidermis surrounds all vertebrates, forming a water barrier between the external environment and the internal space of the organism. In the zebrafish, the embryonic epidermis consists of an outer enveloping layer (EVL) and an inner basal layer that have distinct embryonic origins. Differentiation of the EVL requires the maternal effect gene poky/ikk1 in EVL cells prior to establishment of the basal layer. This requirement is transient and maternal Ikk1 is sufficient to allow establishment of the EVL and formation of normal skin in adults. Similar to the requirement for Ikk1 in mouse epidermis, EVL cells in poky mutants fail to exit the cell cycle or express specific markers of differentiation. In spite of the similarity in phenotype, the molecular requirement for Ikk1 is different between mouse and zebrafish. Unlike the mouse, EVL differentiation requires functioning Poky/Ikk1 kinase activity but does not require the HLH domain. Previous work suggested that the EVL was a transient embryonic structure, and that maturation of the epidermis required replacement of the EVL with cells from the basal layer. We show here that the EVL is not lost during embryogenesis but persists to larval stages. Our results show that while the requirement for poky/ikk1 is conserved, the differences in molecular activity indicate that diversification of an epithelial differentiation program has allowed at least two developmental modes of establishing a multilayered epidermis in vertebrates.
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