• Title/Summary/Keyword: serpin

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Identification and in silico analysis of two types of serpin genes from expressed sequence tags (ESTs) of the Oriental land snail, Nesiohelix samarangae (동양달팽이 (Nesiohelix samarangae) 의 expressed sequence tags (ESTs) 로부터 분리한 2종류의 Serpin 유전자 분석)

  • Park, So Young;Jeong, Ji Eun;Hwang, Hee Ju;Wang, Tae Hun;Park, Eun Bi;Kim, Yong Min;Lee, Jun-Sang;Han, Yeon Soo;Yang, Seung-Ha;Lee, Yong Seok
    • The Korean Journal of Malacology
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    • v.30 no.2
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    • pp.155-163
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    • 2014
  • Serpins are a group of proteins involved in the regulation of serine and other type of proteases, and have been identified in many kinds of organisms from invertebrates to vertebrates. Serpins are known to regulate the proteolytic cascades of the innate immune pathways in addition to their roles in blood coagulation, angiogenesis, fibrinolysis, inflammation and tumor suppression. In this study, we have isolated two partial serpin gene fragments from expressed sequence tags (ESTs) of Nesiohelix samarangae. Dotplot analysis indicates that they are of two different types, Ns-serpin type 1 and Ns-serpin type 2. Ns-serpin type 1 has 819 bp coding region (272 amino acids), whereas Ns-serpin type 2 has 555 bp coding region (185 amino acids). Molecular phylogenetic analysis shows that the identified serpins have high similarities to their counterparts in the California see slug, Aplysia californica. Yet, the precise biological and immunological roles of these Ns-serpins remain to be further investigated using RNA interference and other molecular techniques.

Anti-Apoptotic Effects of SERPIN B3 and B4 via STAT6 Activation in Macrophages after Infection with Toxoplasma gondii

  • Song, Kyoung-Ju;Ahn, Hye-Jin;Nam, Ho-Woo
    • Parasites, Hosts and Diseases
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    • v.50 no.1
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    • pp.1-6
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    • 2012
  • $Toxoplasma$ $gondii$ penetrates all kinds of nucleated eukaryotic cells but modulates host cells differently for its intracellular survival. In a previous study, we found out that serine protease inhibitors B3 and B4 (SERPIN B3/B4 because of their very high homology) were significantly induced in THP-1-derived macrophages infected with $T.$ $gondii$ through activation of STAT6. In this study, to evaluate the effects of the induced SERPIN B3/B4 on the apoptosis of $T.$ $gondii$-infected THP-1 cells, we designed and tested various small interfering (si-) RNAs of SERPIN B3 or B4 in staurosporine-induced apoptosis of THP-1 cells. Anti-apoptotic characteristics of THP-1 cells after infection with $T.$ $gondii$ disappeared when SERPIN B3/B4 were knock-downed with gene specific si-RNAs transfected into THP-1 cells as detected by the cleaved caspase 3, poly-ADP ribose polymerase and DNA fragmentation. This anti-apoptotic effect was confirmed in SERPIN B3/B4 overexpressed HeLa cells. We also investigated whether inhibition of STAT6 affects the function of SERPIN B3/B4, and vice versa. Inhibition of SERPIN B3/B4 did not influence STAT6 expression but SERPIN B3/B4 expression was inhibited by STAT6 si-RNA transfection, which confirmed that SERPIN B3/B4 was induced under the control of STAT6 activation. These results suggest that $T.$ $gondii$ induces SERPIN B3/B4 expression via STAT6 activation to inhibit the apoptosis of infected THP-1 cells for longer survival of the intracellular parasites themselves.

Elucidation of Serpin's Conformational Switch Mechanism By Rapid Kinetic Study

  • Kang, Un-Beom;Lee, Cheolju;Baek, Je-Hyun;Seunghyun Ryu;Kim, Joon;Yu, Myeong-Hee
    • Proceedings of the Korean Biophysical Society Conference
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    • 2003.06a
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    • pp.62-62
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    • 2003
  • The native form of serpin (serine protease inhibitor) is kinetically trapped in metastable state. Metastability in these proteins is critical to their biological function. Serpins inhibit target proteases by forming a stable covalent complex in which the cleaved reactive site loop of the serpin is inserted into $\beta$-sheet A of the serpin with concomitant translocation of the protease to the opposite of the initial binding site. Despite recent determination of the crystal structures of a Michaelis protease-serpin complex as well as a stable covalent complex, details on the kinetic mechanism remain unsolved. In this study we constructed several $\alpha$$_1$-antitrypsin variants and examined their kinetic mechanism of loop translocation and formation of protease-serpin complex by stopped-flow experiments of fluorescence resonance energy transfer as well as quenched-flow experiment. We report here the relationship of serpin's conformational switch mechanism with Inhibitory activity. There is little direct correlation between loop insertion rate and inhibitory activity. Rather, disrupting a salt bridge between R196 and E354 accelerates loop translocation even though it impairs the inhibitory activity. Moreover, the serpin's reactive site loop is translocated, at least partially, prior to loop cleavage.

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Conformational Switch of the Strained Native Serpin Induced by Chemical Cleavage of the Reactive Center Loop

  • Im, Ha-Na;Yu, Myeong-Hee
    • BMB Reports
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    • v.33 no.5
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    • pp.379-384
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    • 2000
  • The native conformation of serpins (serine protease inhibitors) is strained. Upon cleavage of the reactive center loop of serpins by a protease, the amino terminal portion of the cleaved loop is inserted into the central ${\beta}-sheet$, A sheet, as the fourth strand, with the concomitant release of the native strain. We questioned the role of protease in this conformational switch from the strained native form into a stable relaxed state. Chemical cleavage of the reactive center loop of ${\alpha}_1-antitrypsin$, a prototype serpin, using hydroxylamine dramatically increased the stability of the serpin. A circular dichroism spectrum and peptide binding study suggests that the amino terminal portion of the reactive center loop is inserted into the A sheet in the chemically-cleaved ${\alpha}_1-antitrypsin$, as in the enzymatically-cleaved molecule. These results indicate that the structural transformation of a serpin molecule does not require interaction with a protease. The results suggest that the serpin conformational switch that occurred during the complex formation with a target protease is induced by the cleavage of the reactive center loop per se.

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Determination of Translocation and Deacylation Rate Constants for Complex Formation between Serpin and Protease

  • Shin, Jong-Shik;Yu, Myeong-Hee
    • Proceedings of the Korean Biophysical Society Conference
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    • 2001.06a
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    • pp.62-62
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    • 2001
  • Serpins inhibit target proteases by forming tight acyl complex Via incorporation of the reactive center loop into ${\beta}$-sheet A. Metastability of the serpins control the translocation of the protease from the initial binding site to the opposite pole of the serpin. Recently the crystal structure of a serpin-protease complex revealed that the active site of the protease is distorted.(omitted)

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CRYSTAL STRUCTURE OF AN UNCLEAVED $\alpha_1$-ANTITRYPSIN WITH SEVEN STABILIZING MUTATIONS AT 2.7 $\{AA}$ RESOLUTION

  • Ryu, Seong-Eon;Park, Hee-Jeong;Kwon, Ki-Sun;Lee, Kee-Nyung;Yu, Myung-Hee
    • Proceedings of the Korean Biophysical Society Conference
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    • 1996.07a
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    • pp.4-4
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    • 1996
  • $\alpha$$_1$-arantitrypsin, a member of the serpin (serine protease inhibitor) family, undergoes a large structural rearrangement upon the cleavage and insertion of the reactive site loop. This conformational change is driven by the metastability of the native serpin structures and has an important role in the regulation of the inhibitory-serpin function. (omitted)

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Regulatory Role of the Serpin Strain

  • Seo, Eun-Joo;Yu, Myeong-Hee
    • Proceedings of the Korean Biophysical Society Conference
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    • 2002.06b
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    • pp.30-30
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    • 2002
  • The native forms of common globular proteins are in their most stable state but the native forms of plasma serpins (serine protease inhibitors) show high-energy state interactions. The high-energy state strain of a ${\alpha}$$_1$-antitrypsin, a prototype serpin, is distributed throughout the whole molecule, but the strain that regulates the function directly appears to be localized in the region where the reactive site loop is inserted during complex formation with a target protease.(omitted)

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