Tsukasa Osaki scite author profile

In arthropods, the melanization reaction is associated with multiple host defense mechanisms leading to the sequestration and killing of invading microorganisms. Arthropod melanization is controlled by a cascade of serine proteases that ultimately activates the enzyme prophenoloxidase (PPO), which, in turn, catalyzes the synthesis of melanin. Here we report the biochemical and genetic characterization of a Drosophila serine protease inhibitor protein, Serpin-27A, which regulates the melanization cascade through the specific inhibition of the terminal protease prophenoloxidase-activating enzyme. Our data demonstrate that Serpin-27A is required to restrict the phenoloxidase activity to the site of injury or infection, preventing the insect from excessive melanization.

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Functional Conversion of Hemocyanin to Phenoloxidase by Horseshoe Crab Antimicrobial Peptides

Nagai

Osaki

Kawabata

2001

Journal of Biological Chemistry

180

109

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Arthropod hemocyanins and phenoloxidases serve different physiological functions as oxygen transporters and enzymes involved in defense reactions, respectively. However, they are equipped with a structurally similar oxygen-binding center. We have shown that the clotting enzyme of the horseshoe crab, Tachypleus tridentatus, functionally converts hemocyanin to phenoloxidase by forming a complex without proteolytic cleavage (Nagai, T., and Kawabata, S. (2000)

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Horseshoe Crab Hemocyte-derived Antimicrobial Polypeptides, Tachystatins, with Sequence Similarity to Spider Neurotoxins

Osaki¹,

Omotezako²,

Nagayama³

et al. 1999

Journal of Biological Chemistry

102

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Antimicrobial peptides, named tachystatins A, B, and C, were identified from hemocytes of the horseshoe crab Tachypleus tridentatus. Tachystatins exhibited a broad spectrum of antimicrobial activity against Gram-negative and Gram-positive bacteria and fungi. Of these tachystatins, tachystatin C was most effective. Tachystatin A is homologous to tachystatin B, but tachystatin C has no significant sequence similarity to tachystatins A and B. Tachystatins A and B showed sequence similarity to -agatoxin-IVA of funnel web spider venom, a potent blocker of voltage-dependent calcium channels. However, they exhibited no blocking activity of the P-type calcium channel in rat Purkinje cells. Tachystatin C also showed sequence similarity to several insecticidal neurotoxins of spider venoms. Tachystatins A, B, and C bound significantly to chitin. A causal relationship was observed between chitin binding activity and antifungal activity. Tachystatins caused morphological changes against a budding yeast, and tachystatin C had a strong cell lysis activity. The septum between mother cell and bud, a chitin-rich region, was stained by fluorescencelabeled tachystatin C, suggesting that the primary recognizing substance on the cell wall is chitin. As horseshoe crab is a close relative of the spider, tachystatins and spider neurotoxins may have evolved from a common ancestral peptide, with adaptive functions.

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Characterization and Properties of a 1,3-β-d-Glucan Pattern Recognition Protein of Tenebrio molitor Larvae That Is Specifically Degraded by Serine Protease during Prophenoloxidase Activation

Zhang

Cho

Kim

et al. 2003

Journal of Biological Chemistry

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Although many different pattern recognition receptors recognizing peptidoglycan and 1,3-␤-D-glucan have been identified in vertebrates and insects, the molecular mechanism of these molecules in the pattern recognition and subsequent signaling is largely unknown. To gain insights into the action mechanism of 1,3-␤-D-glucan pattern recognition protein in the insect prophenoloxidase (proPO) activation system, we purified a 53-kDa 1,3-␤-D-glucan recognition protein (Tm-GRP) to homogeneity from the hemolymph of the mealworm, Tenebrio molitor, by using a 1,3-␤-D-glucan affinity column. The purified protein specifically bound to 1,3-␤-Dglucan but not to peptidoglycan. Subsequent molecular cloning revealed that Tm-GRP contains a region with close sequence similarity to bacterial glucanases. Strikingly, two catalytically important residues in glucanases are replaced with other nonhomologous amino acids in Tm-GRP. The finding suggests that Tm-GRP has evolved from an ancestral gene of glucanases but retained only the ability to recognize 1,3-␤-D-glucan. A Western blot analysis of the protein level of endogenous Tm-GRP showed that the protein was specifically degraded following the activation of proPO with 1,3-␤-Dglucan and calcium ion. The degradation was significantly retarded by the addition of serine protease inhibitors but not by cysteine or acidic protease inhibitor. These results suggest that 1,3-␤-D-glucan pattern recognition protein is specifically degraded by serine protease(s) during proPO activation, and we propose that this degradation is an important regulatory mechanism of the activation of the proPO system.

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A serine protease zymogen functions as a pattern-recognition receptor for lipopolysaccharides

Ariki

Koori

Osaki

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

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Bacterial lipopolysaccharide (LPS)-induced exocytosis of granular hemocytes is a key component of the horseshoe crab's innate immunity to infectious microorganisms; stimulation by LPS induces the secretion of various defense molecules from the granular hemocytes. Using a previously uncharacterized assay for exocytosis, we clearly show that hemocytes respond only to LPS and not to other pathogen-associated molecular patterns, such as ␤-1,3-glucans and peptidoglycans. Furthermore, we show that a granular protein called factor C, an LPS-recognizing serine protease zymogen that initiates the hemolymph coagulation cascade, also exists on the hemocyte surface as a biosensor for LPS. Our data demonstrate that the proteolytic activity of factor C is both necessary and sufficient to trigger exocytosis through a heterotrimeric GTPbinding protein-mediating signaling pathway. Exocytosis of hemocytes was not induced by thrombin, but it was induced by hexapeptides corresponding to the tethered ligands of proteaseactivated G protein-coupled receptors (PARs). This finding suggested the presence of a PAR-like receptor on the hemocyte surface. We conclude that the serine protease zymogen on the hemocyte surface functions as a pattern-recognition protein for LPS.

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Tsukasa Osaki

An Immune-Responsive Serpin Regulates the Melanization Cascade in Drosophila

Functional Conversion of Hemocyanin to Phenoloxidase by Horseshoe Crab Antimicrobial Peptides

Horseshoe Crab Hemocyte-derived Antimicrobial Polypeptides, Tachystatins, with Sequence Similarity to Spider Neurotoxins

Characterization and Properties of a 1,3-β-d-Glucan Pattern Recognition Protein of Tenebrio molitor Larvae That Is Specifically Degraded by Serine Protease during Prophenoloxidase Activation

A serine protease zymogen functions as a pattern-recognition receptor for lipopolysaccharides

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