Generation of Endotoxin-Specific Monoclonal Antibodies by Phage and Yeast Display for Capturing Endotoxin.

Endotoxin, a synonym for lipopolysaccharide (LPS), is anchored in the outer membranes of Gram-negative bacteria. Even minute amounts of LPS entering the circulatory system can have a lethal immunoactivating effect. Since LPS is omnipresent in the environment, it poses a great risk of contaminating any surface or solution, including research products and pharmaceuticals. Therefore, monitoring LPS contamination and taking preventive or decontamination measures to ensure human safety is of the utmost importance. Nevertheless, molecules used for endotoxin detection or inhibition often suffer from interferences, low specificity, and low affinity. For this reason, the selection of new binders that are biocompatible, easy to produce, and that can be used for biopharmaceutical applications, such as endotoxin removal, is of high interest. Powerful techniques for selecting LPS-binding molecules in vitro are display technologies. In this study, we established and compared the selection and production of LPS-specific, monoclonal, human single-chain variable fragments (scFvs) through two display methods: yeast and phage display. After selection, scFvs were fused to a human constant fragment crystallizable (Fc). To evaluate the applicability of the constructs, they were conjugated to polystyrene microbeads. Here, we focused on comparing the functionalized beads and their LPS removal capacity to a polyclonal anti-lipid A bead. Summarized, five different scFvs were selected through phage and yeast display, with binding properties comparable to a commercial polyclonal antibody. Two of the conjugated scFv-Fcs outperformed the polyclonal antibody in terms of the removal of LPS in aqueous solution, resulting in 265 times less residual LPS in solution, demonstrating the potential of display methods to generate LPS-specific binding molecules.

Remoção de endotoxina presente em meio fermentado contendo biomoléculas utilizando sistemas micelares de duas fases aquosas / Endotoxin removal from fermentation broth containing biomolecules using two-phase micellar system

Foi investigada a utilização de Sistema Micelar de Duas Fases Aquosas (SMDFA) para remoção de lipolissacarídeos (LPS) de preparações contendo proteínas recombinantes de interesse farmacêutico, como a proteína verde fluorescente (GFPuv). Os SMDFA são constituídos por soluções de tensoativos contendo micelas e oferecem ambientes hidrofóbico e hidrofílico, que possibilitam seletividade na partição de biomoléculas de acordo com sua hidrofobicidade, permitindo a remoção de LPS contaminante. Neste trabalho, foi realizada a implementação do método para a quantificação de LPS em amostras contaminadas e a obtenção de LPS e GFPuv puros a partir de cultivo de E. coli recombinante. Além disso, foi estudada a influência do Triton X-114 na metodologia de quantificação de LPS, e a adição de MgSO4, CaCl2, KI e (NH4)2SO4 na partição de GFPuv e LPS puros em SMDFA. E ainda, realizou-se um planejamento experimental (22) para avaliar os maiores KGFPuv e porcentoRECGFPuv. O homogeneizado celular de E. coli foi testado nas melhores condições obtidas com o planejamento experimental. E finalmente, o processo por cromatografia de afinidade por íons metálicos (IMAC) foi empregado para investigar a adsorção de LPS em matriz IDA-Ca2+. Conforme os resultados obtidos, o TX-114 causou elevada interferência no método cinético cromogênico, em função da similaridade desta molécula com os LPS. Os LPS apresentaram partição preferencial para a fase concentrada em micelas, com altos valores de remoção, por centoREMLPS>98,0 por cento. Ao contrário, a GFPuv foi recuperada preferencialmente na fase diluída, na qual existe maior volume disponível, resultando em valores de KGFPuv>1. A adição de sais ocasionou diminuição nos valores KGFPuv, provavelmente por causa da carga negativa que GFPuv adquiriu nas condições avaliadas. Os resultados do planejamento experimental mostraram que a melhor condição de partição obtida foi na região do ponto central, 4,0 por cento (p/p) a 60,0°C, com KGFPuv>10. O processo por IMAC apresentou as maiores...

The Aqueous Two-Phase Micellar System (ATPMS) was investigated for endotoxin (LPS) removal from preparations containing recombinant proteins of pharmaceutical interest, such as the green fluorescent protein (GFPuv). These systems usually consist of micellar surfactants solutions and offer both hydrophobic and hydrophilic environments, providing selectivity to the biomolecules partitioning according to its hydrophobicity. In this work, the implementation of the method for LPS quantification in contaminated samples was accomplished, as well as the obtaining of pure LPS and GFPuv from recombinant E. coli. Furthermore, the influence of Triton X-114 in the methodology for LPS quantification was studied, as the addition of MgSO4, CaCl2, KI, and (NH4)2SO4 into the partition of pure GFPuv and LPS in ATPMS. In addition, a statistical design (22) was carried out to evaluate the highest KGFPuv and percentRECGFPuv. The E. coli cell lysate was tested under optimum conditions obtained with the statistical design. And, finally, the process by ionmetal affinity chromatography (IMAC) was used to investigate the adsorption of LPS in IDA-Ca2+ matrix. The results showed that the TX-114 caused high interference in the kinetic chromogenic method, according to the similarity of this molecule to LPS. The LPS showed preferential partitioning to the micellerich phase, with high values of removal, percentREMLPS>98.0 percent. In the other hand, the GFPuv was preferentially recovered in the micelle-poor phase, in which there is greater volume available resulting in values of KGFPuv>1. The addition of salts caused a reduction in the values KGFPuv, probably because of the negative charge that the GFPuv acquired at the conditions evaluated. The results of the statistical design showed that the best partitioning condition obtained was in the central point region, 4.0 percent (wt/wt) at 60.0°C, with KGFPuv>10. The process by IMAC showed the highest adsorption of LPS-IDA-Ca+2 capacities at the conditions of lower pH...