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Phosphorylation of proteins on tyrosine residues has been shown to govern many cellular processes, but little work has focused on the role of tyrosine phosphorylation during germination. Under optimal conditions, D. discoideum spores synchronously germinate each liberating a single amoeba. The total amount of phosphotyrosine containing proteins observed in spores was greatest during quiescence with a gradual decline during spore activation and emergence of nascent amoeba. During dormancy, tyrosine residues of actin were heavily phosphorylated, but they gradually underwent dephosphorylation upon spore activation and this process continued through emergence. Interestingly, an endogenous autoinhibitor(s), which blocks germination, induces tyrosine phosphorylation of actin. Conversely, the removal of the autoinhibitor(s) was followed by a decrease in phosphorylation. Thus, during germination of Dictyostelium spores, actin is dephosphorylated, with the level of phosphorylation regulated by the autoinhibitor(s) and/or the autoactivator. This change in actin phosphorylation appears to play a direct role since actin dephosphorylation and reorganization is a necessary prelude to germination.

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The role of protein kinase C (PKC) during fertilization in the model eukaryote Dictyostelium discoideum was studied. Inhibition of PKC activity using staurosporine, chelerythrine, and bisindoylmaleimide resulted in a dose-dependent decrease in gamete fusion without any detectable effect on cell morphology or growth. At 1.0 microM, staurosporine led to a greater than 90% inhibition of gamete fusion. In support of this, chelerythrine and bisindoylmaleimide at 10 microM inhibited gamete cell fusion by 98 and 99%, respectively. In all cases, subsequent removal of the inhibitor allowed for the completion of sexual development in a manner indistinguishable from untreated, control cultures. In contrast, the stimulation of PKC by the addition of the phorbol ester 12-O-tetradecanoylphorbol-13-acetate at 5 nM resulted in a 56% enhancement of cell fusion. In order to identify PKC substrates that may regulate fertilization in D. discoideum, in vitro phosphorylation was carried out followed by SDS-PAGE. A number of proteins were phosphorylated, only one of which, a protein of about 50,000 M(r), appears to be a PKC substrate. In total, these results coupled with earlier work suggest that PKC functions as part of a calcium-mediated signaling pathway that regulates fertilization in D. discoideum, suggesting that the dual signaling pathway that regulates fertilization in higher eukaryotes may have evolved very early.

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One of the developmental pathways used by the social amoeba Dictyostelium discoideum produces dormant spores. As with any temporary resistant stage, these spores must be able to germinate rapidly in response to positive environmental stimuli. One such stimulus is the autoactivator, an endogenous, diffusible molecule that is secreted by spores. Previous work has shown that three phases of germination, autoactivation, spore swelling and amoebal emergence, require the activity of the Ca(2+)-dependent, regulatory protein calmodulin, implicating Ca2+ as an essential cation during germination. In this study we used a pharmacological approach coupled with the direct measurement of Ca2+ levels in germinating spore populations by atomic adsorption to examine Ca(2+)-dependent signal transduction during spore activation and germination in D. discoideum. Inhibitors of both phospholipase C and internal Ca2+ release inhibited autoactivation while exogenously added Ins(1,4,5)P3, acted synergistically with the autoactivator. The antagonists specifically affected spore activation as mediated by the autoactivator, since neither had any effect on heat-activated spores. In contrast, La3+, an inhibitor of Ca2+ uptake, had little or no effect on either autoactivation or the swelling of autoactivated spores. However, an inhibition of Ca2+ influx by La3+ inhibited both the swelling of heat-activated spores and amoebal emergence following each period of autoactivation or heat activation. Ca2+ levels change in the spore population during germination. During activation and swelling, Ca2+ efflux occurs from the spores. Both of the activating stimuli used here, the autoactivator and heat, caused this Ca2+ efflux. The efflux is reversed during emergence when there is a net Ca2+ uptake by the spores and cells from the medium. Together these data provide the first evidence that autoactivation is mediated by Ca(2+)-dependent signal transduction, leading to Ca2+ efflux, and that the late event of germination, amoebal emergence, requires Ca2+ uptake to proceed. The data also suggest that the responses of the spore to the each of autoactivator and heat, i.e. Ca2+ movements and germination, are mediated by different mechanisms.

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Dictyostelium discoideum spores can be activated to initiate germination either endogenously via a diffusible autoactivator, or exogenously via heat. Following activation, three successive stages of germination occur, the lag stage, spore swelling and amoebal emergence. A previous study [Lydan M. A. and Cotter D. A. (1994) FEBS Lett. 115, 137-142] has shown that spore swelling is dependent on the activity of calmodulin. In this study, the calmodulin antagonists trifluoperazine and calmidazolium inhibited autoactivation, but had no effect upon heat activation. These agents also inhibited amoebal emergence following either form of activation. The effects caused by the anti-calmodulin agents were specific to an inhibition of calmodulin function since agents which modulate the activity of protein kinase C had no effect upon spore germination. A calcium-dependent calmodulin-binding protein of about 64,000 M(r) may be associated with the process of autoactivation since it was only seen in those spores which respond to the autoactivator. Overall, this study provides evidence to show that calmodulin plays a regulatory role during autoactivation and amoebal emergence during spore germination in D. discoideum and provides evidence for the calmodulin-dependent mechanisms which mediate each of these phases of germination.

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Extensive protein phosphorylation occurs during all phases of spore germination in Dictyostelium discoideum. The developmental changes were prevented when germination was inhibited by inhibitors of calmodulin function. In addition, differences in patterns of phosphorylation were detected based upon the method of spore activation. Several phosphoproteins were lost in heat activated as compared to autoactivated spores. In spite of the fact that several aspects (i.e. autoactivation, emergence) are calmodulin-dependent, there was no evidence that calcium- or calmodulin-dependent protein kinase activity is present during any phase of spore germination. This suggests that other CaM-dependent processes mediate the diverse aspects of spore germination in D. discoideum.

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Many calmodulin-dependent biological phenomena are regulated by calmodulin-dependent phosphorylation and dephosphorylation. In Dictyostelium discoideum, cell and pronuclear fusion during fertilization are both calmodulin-dependent biomembrane fusion events. Calmodulin-dependent phosphorylation and dephosphorylation activity was present in sexually developing D. discoideum cells suggesting it has a role during fertilization. In support of this, a discrete calmodulin-independent kinase was present only during cell and pronuclear fusion.

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The calcium-dependent regulatory protein calmodulin (CaM) mediates diverse cellular functions via a large number of calmodulin-binding and -dependent proteins (CaMBPs). The use of [35S]calmodulin, labeled during its expression (VU-1-CaM) in Escherichia coli, visualized over 25 CaMBPs in Dictyostelium discoideum. Seven, with M(r)s of 155,000, 91,000, 85,000, 48,000, 46,000, 38,000, and 28,000, were present only during sexual development. In addition, intracellular calmodulin levels were low during gamete formation but rose during cell fusion in response to the presence of extracellular calcium. Thus, calmodulin appears to mediate gamete formation and fusion through two distinct mechanisms: first, via unique developmentally regulated CaMBPs, and, second, via the regulation of intracellular calmodulin levels. The identification of the CaMBP spectrin in sexually developing Dictyostelium cells suggests that this cytoskeleton/plasma membrane, crosslinking protein may function during biomembrane fusion in D. discoideum as it does in other organisms.

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Biotin-dependent enzymes are involved in carboxylation, decarboxylation and transcarboxylation reactions. Here, we have used sodium dodecyl sulfate polyacrylamide gel electrophoresis and electroblotting followed by probing with avidin to identify biotin-containing polypeptides in Dictyostelium discoideum. Twenty biotinyl polypeptides were visualized, with a 23 kDa protein appearing transiently. Based upon the molecular mobility of the biotinyl polypeptides, D. discoideum may contain the biotin-dependent enzymes acetyl CoA carboxylase, proprionyl CoA carboxylase, pyruvate carboxylase, and 3-methylcrotonyl CoA carboxylase.

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During early sexual development in Dictyostelium discoideum cell and pronuclear fusion are negatively regulated by an endogenous autoinhibitor. Here, the autoinhibitor was partially purified from the culture medium and found to inhibit both cell and pronuclear fusion while augmenting gamete numbers. These developmental effects suggested that calmodulin might be an intracellular target for the autoinhibitor. In support of this data, the partially purified autoinhibitor inhibited the calmodulin-dependent activation of phosphodiesterase in a dose-dependent manner, but had no effect on either a calmodulin-insensitive form of phosphodiesterase or the calmodulin-independent enzymes acid and alkaline phosphatase. Thus, the autoinhibitor of sexual development in Dictyostelium discoideum appears to regulate cell and pronuclear fusion at least in part by a direct effect on calmodulin.

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During the first 24 h of sexual development in Dictyostelium discoideum, three sequential events of membrane fusion occur: gamete fusion, pronuclear fusion, and phagocytosis. The early events of sexual development are regulated by a diverse group of endogenous molecules: (i) a volatile sexual pheromone, (ii) a protein cell fusion inducing factor (CFIF), (iii) a low molecular weight autoinhibitor, (iv) and cyclic AMP. CFIC enhances cell fusion while the autoinhibitor and cyclic AMP both inhibit the event. Both extracellular and intracellular calcium ions are essential for cell and pronuclear fusion. Pharmacological analyses show that the intracellular functions of the divalent cation in these processes are mediated by calmodulin. The autoinhibitor appears to function by inhibiting calmodulin activity. Glucose, mannose, and N-acetylglucosamine containing glycoproteins have been shown to function in both cell fusion and phagocytosis. The interplay between all of these diverse molecules is examined and a review of all of the recent literature is presented.

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The calmodulin antagonists trifluoperazine and compound R24571 were used to study the function of calmodulin during sexual development in Dictyostelium discoideum. Calmodulin activity is required for both cell fusion and pronuclear fusion. However, cell fusion and pronuclear fusion were each maximally inhibited at different concentrations of the same inhibitor suggesting differential calmodulin activity during these events. In contrast, trifluoperazine and R24571 were both found to enhance rather than inhibit the formation of gametes. This suggests an additional role for calmodulin as a negative regulator of gamete development. These results provide evidence of a role for calmodulin as both a positive (biomembrane fusion) and a negative (gamete development) regulator of developmental events in Dictyostelium. They also reveal calmodulin as a mediator of pronuclear fusion for zygote development in this eukaryote.

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