ROSA MARIA CHURA CHAMBI

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2019 - 201912020 - 20223
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Âmbito: Internacional × Percentil: 50.00 - 74.99 ×

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    Artigo IPEN-doc 29049
    Leptolysin, a Leptospira secreted metalloprotease of the pappalysin family with broad-spectrum activity
    2022 - COURROL, DANIELLA dos S.; SILVA, CRISTIANE C.F. da; PRADO, LUAN G.; CHURA-CHAMBI, ROSA M.; MORGANTI, LIGIA; SOUZA, GISELE O. de; HEINEMANN, MARCOS B.; ISAAC, LOURDES; CONTE, FERNANDO P.; PORTARO, FERNANDA C.V.; RODRIGUES-DA-SILVA, RODRIGO N.; BARBOSA, ANGELA S.
    Extracellular proteolytic enzymes are produced by a variety of pathogenic microorganisms, and contribute to host colonization by modulating virulence. Here, we present a first characterization of leptolysin, a Leptospira metalloprotease of the pappalysin family identified in a previous exoproteomic study. Comparative molecular analysis of leptolysin with two other pappalysins from prokaryotes, ulilysin and mirolysin, reveals similarities regarding calcium, zinc, and arginine -binding sites conservation within the catalytic domain, but also discloses peculiarities. Variations observed in the primary and tertiary structures may reflect differences in primary specificities. Purified recombinant leptolysin of L. interrogans was obtained as a ~50 kDa protein. The protease exhibited maximal activity at pH 8.0 and 37°C, and hydrolytic activity was observed in the presence of different salts with maximum efficiency in NaCl. Substrate specificity was assessed using a small number of FRET peptides, and showed a marked preference for arginine residues at the P1 position. L. interrogans leptolysin proteolytic activity on proteinaceous substrates such as proteoglycans and plasma fibronectin was also evaluated. All proteins tested were efficiently degraded over time, confirming the protease´s broad-spectrum activity in vitro. In addition, leptolysin induced morphological alterations on HK-2 cells, which may be partially attributed to extracellular matrix (ECM) degradation. Hemorrhagic foci were observed in the dorsal skin of mice intradermally injected with leptolysin, as a plausible consequence of ECM disarray and vascular endothelium glycocalyx damage. Assuming that leptospiral proteases play an important role in all stages of the infectious process, characterizing their functional properties, substrates and mechanisms of action is of great importance for therapeutic purposes.
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    Artigo IPEN-doc 28852
    Recombinant PilS
    2022 - MUNHOZ, DANIELLE D.; SILVA, JESSIKA C.A.; FREITAS, NATALIA C.; IWAI, LEO K.; AIRES, KARINA A.; OZAKI, CHRISTIANE Y.; SOUZA, CRISTIANE S.; ROCHA, LETICIA B.; SILVA, MIRIAM A.; HENRIQUE, IZABELLA M.; ELIAS, WALDIR P.; CARVALHO, ENEAS; MORGANTI, LIGIA; CHURA-CHAMBI, ROSA M.; PIAZZA, ROXANE M.F.
    Pil-fimbriae is a type IV pili member, which is a remarkably versatile component with a wide variety of functions, including motility, attachment to different surfaces, electrical conductance, DNA acquisition, and secretion of a broad range of structurally distinct protein substrates. Despite the previous functional characterization of Pil, more studies are required to understand the regulation of Pil expression and production, since the exact mechanisms involved in these steps are still unknown. Therefore it is extremely important to have a protein with the correct secondary and tertiary structure that will enable an accurate characterization and a specific antisera generation. For this reason, the aim of this work was to generate potential tools for further investigations to comprehend the mechanisms involved in Pil regulation and its role in pathogenic E. coli infections with the obtaining of a precise native-like recombinant PilS and the corresponding antisera. The pilS gene was successfully cloned into an expression vector, and recombinant PilS (rPilS) was efficiently solubilized and purified by metal affinity chromatography. Protein characterization analyses indicated that rPilS presented native-like secondary and tertiary structures after the refolding process. The generated anti-rPilS sera efficiently recognized recombinant and native proteins from atypical enteropathogenic E. coli strains.
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    Artigo IPEN-doc 28686
    High level SARS-CoV-2 nucleocapsid refolding using mild condition for inclusion bodies solubilization
    2022 - CHURA-CHAMBI, ROSA M.; PRIETO-DA-SILVA, ALVARO R. de B.; DI LELA, MATHEUS M.; OLIVEIRA, JOAO E.; ABREU, PATRICIA E.A.; MEIRELES, LUCIANA R.; ANDRADE JUNIOR, HEITOR F. de; MORGANTI, LIGIA
    SARS-CoV-2 Nucleocapsid (N) is the most abundant viral protein expressed in host samples and is an important antigen for diagnosis. N is a 45 kDa protein that does not present disulfide bonds. Intending to avoid non-specific binding of SARS-CoV-2 N to antibodies from patients who previously had different coronaviruses, a 35 kDa fragment of N was expressed without a conserved motif in E. coli as inclusion bodies (N122-419-IB). Culture media and IB washing conditions were chosen to obtain N122-419-IB with high yield (370 mg/L bacterial culture) and protein purity (90%). High pressure solubilizes protein aggregates by weakening hydrophobic and ionic interactions and alkaline pH promotes solubilization by electrostatic repulsion. The association of pH 9.0 and 2.4 kbar promoted efficient solubilization of N122-419-IB without loss of native-like tertiary structure that N presents in IB. N122-419 was refolded with a yield of 85% (326 mg/L culture) and 95% purity. The refolding process takes only 2 hours and the protein is ready for use after pH adjustment, avoiding the necessity of dialysis or purification. Antibody binding of COVID-19-positive patients sera to N122-419 was confirmed by Western blotting. ELISA using N122-419 is effective in distinguishing between sera presenting antibodies against SARS-CoV-2 from those who do not. To the best of our knowledge, the proposed condition for IB solubilization is one of the mildest described. It is possible that the refolding process can be extended to a wide range of proteins with high yields and purity, even those that are sensible to very alkaline pH.
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    Artigo IPEN-doc 25863
    Protein refolding based on high hydrostatic pressure and alkaline pH
    2019 - CHURA-CHAMBI, ROSA M.; SILVA, CLEIDE M.R. da; PEREIRA, LENNON R.; BARTOLINI, PAOLO; FERREIRA, LUIS C. de S.; MORGANTI, LIGIA
    In this study we evaluated the association of high hydrostatic pressure (HHP) and alkaline pH as a minimally denaturing condition for the solubilization of inclusion bodies (IBs) generated by recombinant proteins expressed by Escherichia coli strains. The method was successfully applied to a recombinant form of the dengue virus (DENV) non-structural protein 1 (NS1). The minimal pH for IBs solubilization at 1 bar was 12 while a pH of 10 was sufficient for solubilization at HHP: 2.4 kbar for 90 min and 0.4 kbar for 14 h 30 min. An optimal refolding condition was achieved by compression of IBs at HHP and pH 10.5 in the presence of arginine, oxidized and reduced glutathiones, providing much higher yields (up to 8-fold) than association of HHP and GdnHCl via an established protocol. The refolded NS1, 109 ± 9.5 mg/L bacterial culture was recovered mainly as monomer and dimer, corresponding up to 90% of the total protein and remaining immunologically active. The proposed conditions represent an alternative for the refolding of immunologically active recombinant proteins expressed as IBs.