32 research outputs found

    Az ingĂĄzĂĄs tĂ©rbeli jellegzetessĂ©geinek vĂĄltozĂĄsa az Észak-DunĂĄntĂșlon, kĂŒlönös tekintettel GyƑr munkaĂŒgyi vonzĂĄskörzetĂ©re

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    A tanulmĂĄnyban megvizsgĂĄljuk a KSH ĂĄltal 2001-ben Ă©s 2011-ben elvĂ©gzett nĂ©pszĂĄmlĂĄlĂĄs ingĂĄzĂĄsra vonatkozĂł fƑbb adatainak Ă©s a kĂ©t felvĂ©tel összehasonlĂ­tĂĄsa sorĂĄn tapasztalt eltĂ©rĂ©sek terĂŒleti konzekvenciĂĄit. A vizsgĂĄlat cĂ©lja elsƑsorban az volt, hogy GyƑr körĂ© szervezƑdƑ ingĂĄzĂł, munkaĂŒgyi vonzĂĄsterek jellegzetessĂ©geit megismerjĂŒk. EzĂ©rt az orszĂĄgos szintƱ vizsgĂĄlatok mellett rĂ©szletesebben koncentrĂĄltunk az Ă©szak-DunĂĄntĂșlra, melynek központrendszerĂ©t tĂĄrtuk fel, s mĂ©g rĂ©szletesebben vizsgĂĄltuk ezen belĂŒl GyƑr, s a vĂĄroskörnyĂ©ki tĂ©r jellegzetessĂ©geit

    N-glycans of Human Protein C Inhibitor: Tissue-Specific Expression and Function

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    Protein C inhibitor (PCI) is a serpin type of serine protease inhibitor that is found in many tissues and fluids in human, including blood plasma, seminal plasma and urine. This inhibitor displays an unusually broad protease specificity compared with other serpins. Previous studies have shown that the N-glycan(s) and the NH2-terminus affect some blood-related functions of PCI. In this study, we have for the first time determined the N-glycan profile of seminal plasma PCI, by mass spectrometry. The N-glycan structures differed markedly compared with those of both blood-derived and urinary PCI, providing evidence that the N-glycans of PCI are expressed in a tissue-specific manner. The most abundant structure (m/z 2592.9) had a composition of Fuc3Hex5HexNAc4, consistent with a core fucosylated bi-antennary glycan with terminal Lewisx. A major serine protease in semen, prostate specific antigen (PSA), was used to evaluate the effects of N-glycans and the NH2-terminus on a PCI function related to the reproductive tract. Second-order rate constants for PSA inhibition by PCI were 4.3±0.2 and 4.1±0.5 M−1s−1 for the natural full-length PCI and a form lacking six amino acids at the NH2-terminus, respectively, whereas these constants were 4.8±0.1 and 29±7 M−1s−1 for the corresponding PNGase F-treated forms. The 7–8-fold higher rate constants obtained when both the N-glycans and the NH2-terminus had been removed suggest that these structures jointly affect the rate of PSA inhibition, presumably by together hindering conformational changes of PCI required to bind to the catalytic pocket of PSA

    Functional analyses of the chitin-binding domains and the catalytic domain of Brassica juncea chitinase BjCHI1

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    We previously isolated a Brassica juncea cDNA encoding BjCHI1, a novel chitinase with two chitin-binding domains. Synthesis of its mRNA is induced by wounding, methyl jasmonate treatment, Aspergillus niger infection and caterpillar (Pieris rapae) feeding, suggesting that the protein has a role in defense. In that it possesses two chitin-binding domains, BjCHI1 resembles the precursor of Urtica dioica agglutinin but unlike that protein, BjCHI1 retains its chitinase catalytic domain after post-translational processing. To explore the properties of multi-domain BjCHI1, we have expressed recombinant BjCHI1 and two derivatives, which lack one (BjCHI2) or both (BjCHI3) chitin-binding domains, as secreted proteins in Pichia pastoris. Recombinant BjCHI1 and BjCHI2 showed apparent molecular masses on SDS-PAGE larger than calculated, and could be deglycosylated using α-mannosidase. Recombinant BjCHI3, without the proline/ threonine-rich linker region containing predicted O-glycosylation sites, did not appear to be processed by α-mannosidase. BjCHI1's ability to agglutinate rabbit erythrocytes is unique among known chitinases. Both chitin-binding domains are essential for agglutination; this property is absent in recombinant BjCHI2 and BjCHI3. To identify potential catalytic residues, we generated site-directed mutations in recombinant BjCHI3. Mutation E212A showed the largest effect, exhibiting 0% of wild-type specific activity. H211N and R361A resulted in considerable (>91%) activity loss, implying these charged residues are also important in catalysis. E234A showed 36% retention of activity and substitution Y269D, 50%. The least affected mutants were E349A and D360A, with 73% and 68% retention, respectively. Like Y269, E349 and D360 are possibly involved in substrate binding rather than catalysis.link_to_subscribed_fulltex

    Crystal structures of a family 19 chitinase from Brassica juncea show flexibility of binding cleft loops

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    Brassica juncea chitinase is an endo-acting, pathogenesis-related protein that is classified into glycoside hydrolase family 19, with highest homology (50-60%) in its catalytic domain to class I plant chitinases. Here we report X-ray structures of the chitinase catalytic domain from wild-type (apo, as well as with chloride ions bound) and a Glu234Ala mutant enzyme, solved by molecular replacement and refined at 1.53, 1.8 and 1.7 Å resolution, respectively. Confirming our earlier mutagenesis studies, the active-site residues are identified as Glu212 and Glu234. Glu212 is believed to be the catalytic acid in the reaction, whereas Glu234 is thought to have a dual role, both activating a water molecule in its attack on the anomeric carbon, and stabilizing the charged intermediate. The molecules in the various structures differ significantly in the conformation of a number of loops that border the active-site cleft. The differences suggest an opening and closing of the enzyme during the catalytic cycle. Chitin is expected to dock first near Glu212, which will protonate it. Conformational changes then bring Glu234 closer, allowing it to assist in the following steps. These observations provide important insights into catalysis in family 19 chitinases. © 2007 The Authors.link_to_subscribed_fulltex

    The first crystal structures of a family 19 class IV chitinase: The enzyme from Norway spruce

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    Chitinases help plants defend themselves against fungal attack, and play roles in other processes, including development. The catalytic modules of most plant chitinases belong to glycoside hydrolase family 19. We report here x-ray structures of such a module from a Norway spruce enzyme, the first for any family 19 class IV chitinase. The bi-lobed structure has a wide cleft lined by conserved residues; the most interesting for catalysis are Glu113, the proton donor, and Glu122, believed to be a general base that activate a catalytic water molecule. Comparisons to class I and II enzymes show that loop deletions in the class IV proteins make the catalytic cleft shorter and wider; from modeling studies, it is predicted that only three N-acetylglucosamine-binding subsites exist in class IV. Further, the structural comparisons suggest that the family 19 enzymes become more closed on substrate binding. Attempts to solve the structure of the complete protein including the associated chitin-binding module failed, however, modeling studies based on close relatives indicate that the binding module recognizes at most three N-acetylglucosamine units. The combined results suggest that the class IV enzymes are optimized for shorter substrates than the class I and II enzymes, or alternatively, that they are better suited for action on substrates where only small regions of chitin chain are accessible. Intact spruce chitinase is shown to possess antifungal activity, which requires the binding module; removing this module had no effect on measured chitinase activity. © 2009 Springer Science+Business Media B.V.link_to_subscribed_fulltex
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