Your search keyword '"Castillo, Johanna"' showing total 4 results

1. Detection of Pathogenic E. Coli by Electro-chemical Biosensors Based on Aptamers Designed by Bioinformatic Tools.

Author

Ropero-Vega, Jose L., Albiares-Sánchez, Leidy J., León-Sanchez, Wendy R., Valdivieso-Quintero, Wilfredo, and Flórez-Castillo, Johanna M.

Subjects

ESCHERICHIA coli, BIOSENSORS, APTAMERS, BIOINFORMATICS, DETECTION of microorganisms

Abstract

In this work, we present the in-silico design of a new aptamer (named Apt917) capable of interacting with E. coli and its evaluation as a recognition element in electrochemical biosensors. A search and bioinformatic analysis of various aptamers reported in the literature was carried out. Parameters such as low dissociation constant and short sequences were considered to design and model new hybrid sequences. The designed Apt917 has a minimum free energy and high percent to frequency, making it promising compared to the initial ones. Apt917 was synthesized and immobilized on gold nanoparticles-modified screen-printed electrodes. The evaluation of the obtained biosensor shows a promising detection of E. coli O157:H7 with limits of detection and quantification of 8 and 27 CFU/mL, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

2. New PEPTIR-2.0 Peptide Designed for Use as Recognition Element in Electrochemical Biosensors with Improved Specificity towards E. coli O157:H7.

Author

Ropero-Vega, Jose Luis, Redondo-Ortega, Joshua Felipe, Rodríguez-Caicedo, Juliana Paola, Rondón-Villarreal, Paola, and Flórez-Castillo, Johanna Marcela

Subjects

ESCHERICHIA coli, PEPTIDES, INTERMOLECULAR forces, BIOSENSORS, AMINO acid sequence

Abstract

The detection of pathogens through alternative methodologies based on electrochemical biosensors is being studied. These devices exhibit remarkable properties, such as simplicity, specificity, and high sensitivity in monitoring pathogens. However, it is necessary to continue conducting studies that adequately improve these characteristics, especially the recognition molecule. This work aims to design and evaluate a new peptide, named PEPTIR-2.0, as a recognition molecule in electrochemical biosensors to detect E. coli O157:H7 in water. PEPTIR-2.0 was obtained from modifications of the PEPTIR-1.0 peptide sequence, which was previously reported and exhibited excellent properties for detecting and quantifying this pathogenic microorganism. PEPTIR-1.0 is a peptide analogous to the TIR (Translocated Intimin Receptor) protein capable of interacting with the Intimin outer membrane. The basis of this study was to obtain, by using bioinformatics tools, a molecule analogous to PEPTIR-1.0 that maintains its three-dimensional structure but increases the hydrophobic interactions between it and Intimin, since these intermolecular forces are the predominant ones. The designed PEPTIR-2.0 peptide was immobilized on screen-printed electrodes modified with gold nanoparticles. The detection capacity of E. coli O157:H7 in water was evaluated using electrochemical impedance spectroscopy in the presence of other microorganisms, such as P. aeruginosa, S. aureus, and non-pathogenic E. coli. The results showed that PEPTIR-2.0 confers remarkable specificity to the biosensor towards detecting E. coli, even higher than PEPTIR-1.0. [ABSTRACT FROM AUTHOR]

Published

2022

3. A Bioinspired Peptide in TIR Protein as Recognition Molecule on Electrochemical Biosensors for the Detection of E. coli O157:H7 in an Aqueous Matrix.

Author

Ropero-Vega, Jose Luis, Redondo-Ortega, Joshua Felipe, Galvis-Curubo, Yuli Juliana, Rondón-Villarreal, Paola, Flórez-Castillo, Johanna Marcela, Sulka, Grzegorz D., and Bogdanowicz, Robert

Subjects

BIOSENSORS, MEMBRANE proteins, MOLECULES, DETECTION limit

Abstract

Currently, the detection of pathogens such as Escherichia coli through instrumental alternatives with fast response and excellent sensitivity and selectivity are being studied. Biosensors are systems consisting of nanomaterials and biomolecules that exhibit remarkable properties such as simplicity, portable, affordable, user‑friendly, and deliverable to end‑users. For this, in this work we report for the first time, to our knowledge, the bioinformatic design of a new peptide based on TIR protein, a receptor of Intimin membrane protein which is characteristic of E. coli. This peptide (named PEPTIR‑1.0) was used as recognition element in a biosensor based on AuNPs‑modified screen‑printed electrodes for the detection of E. coli. The morphological and electrochemical characteristics of the biosensor obtained were studied. Results show that the biosensor can detect the bacteria with limits of detection and quantification of 2 and 6 CFU/mL, respectively. Moreover, the selectivity of the system is statistically significant towards the detection of the pathogen in the presence of other microorganisms such as P. aeruginosa and S. aureus. This makes this new PEPTIR‑1.0 based biosensor can be used in the rapid, sensitive, and selective detection of E. coli in aqueous matrices. [ABSTRACT FROM AUTHOR]

Published

2021

4. Evaluación de Péptidos Análogos a la Proteína Tir Como Moléculas de Reconocimiento en Biosensores Electroquímicos para la Detección de Escherichia Coli O157:H7 en Matrices Acuosas

Author

Redondo Ortega, Joshua Hugo Felipe, Ropero Vega, José Luis, Flórez Castillo, Johanna-Marcela, and Rondón Villarreal, Paola

Subjects

Biomoléculas, Biomolecules, Biosensors, Intimina, Biosensores, Nanomateriales, Intimin, Nanomaterials

Abstract

Digital, Los biosensores son sistemas basados en nanomateriales y biomoléculas que exhiben notables propiedades, tales como: simplicidad, portabilidad, eficiencia y facilidad de usar para la detección de patógenos como Escherichia coli. En este trabajo se informa por primera vez sobre el diseño de nuevos péptidos basados en la proteína TIR, un receptor de la proteína de membrana intimina característica de E. coli. Estos nuevos péptidos se utilizaron como elementos de reconocimiento para la detección de E. coli. Para este estudio, utilizando la herramienta LigPlot, se realizó un análisis de interacción entre intimina y TIR utilizando la estructura PDB: 2ZQK. Posteriormente, la secuencia asociada a la zona de interacción de TIR fue modelada con PEP-FOLD. Finalmente, a partir de los modelos obtenidos se realizó un estudio de Docking molecular y análisis de interacción, que permitieron definir dos moléculas de reconocimiento denominadas PEPTIR 1 y PEPTIR 2.0, las cuales fueron inmovilizadas en un transductor electroquímico basado en nanomateriales y se evaluó su capacidad de detección de E. coli mediante técnicas electroquímicas. El biosensor basado en PEPTIR 1.0 mostró la capacidad de detectar E. coli, exhibiendo un rango de trabajo lineal entre 0 a 500 UFC / mL y límites de detección y cuantificación de 2 y 6 UFC / mL, respectivamente. Además, el dispositivo mostró la capacidad de detectar de manera selectiva E. coli en presencia de otros microorganismos como P. aeruginosa y S. aereus. Por lo que se destacan la posibilidad de que este dispositivo pueda ser utilizado en la detección rápida, sensible y selectiva de E coli en matrices acuosas. Mientras que el biosensor basado en PEPTIR 2.0 mostró un gran potencial para ser evaluado en su capacidad para detectar con un mayor espectro, microorganismos gramnegativos en una matriz acuosa., Biosensors are systems based on nanomaterials and biomolecules that exhibit remarkable properties, such as: simplicity, portability, efficiency and ease of use for the detection of pathogens such as Escherichia coli. This work reports for the first time on the design of new peptides based on the TIR protein, a receptor for the intimin membrane protein characteristic of E. coli. These new peptides are used as recognition elements for the detection of E. coli. For this study, using the LigPlot tool, an interaction analysis between intimin and TIR was performed using the PDB: 2ZQK structure. Subsequently, the sequence associated with the TIR interaction zone was modeled with PEP-FOLD. Finally, from the obtained models, a molecular docking study and interaction analysis were carried out, which allowed defining two recognition molecules called PEPTIR 1 and PEPTIR 2.0, which were immobilized in an electrochemical transducer based on nanomaterials and their capacity was evaluated. detection of E. coli by electrochemical techniques. The biosensor based on PEPTIR 1.0 showed the ability to detect E. coli, exhibiting a linear working range between 0 to 500 CFU / mL and detection and quantification limits of 2 and 6 CFU / mL, respectively. Furthermore, the device showed the ability to selectively detect E. coli in the presence of other microorganisms, such as P. aeruginosa and S. aereus. Therefore, the possibility that this device can be used in the rapid, sensitive and selective detection of E coli in aqueous matrices stands out. While the biosensor based on PEPTIR 2.0 showed great potential to be evaluated in its ability to detect with a wider spectrum, gram-negative microorganisms in an aqueous matrix., Maestría, Magister en Biotecnología, 1 ed., Introducción .................................................................................................................................. 17 1. Marco de Referencia ................................................................................................................. 22 1.1 Marco de Antecedentes ................................................................................................... 22 1.2 Marco Legal ..................................................................................................................... 25 1.3 Marco Teórico ................................................................................................................. 29 1.3.1 E. coli O157:H7 y sus Proteínas de Adhesión: Intimina y TIR .................................... 29 1.3.2 Biosensores Electroquímicos ........................................................................................ 32 1.3.3 Nanopartículas de Oro (AuNPs) en el Diseño de Biosensores Electroquímicos ......... 32 1.3.4 Péptidos ........................................................................................................................ 35 1.3.5 Proteínas de Membrana Externa ................................................................................... 35 1.3.6 Bioinformática Estructural ........................................................................................... 36 2. Objetivos ................................................................................................................................... 37 2.1 Objetivo General .............................................................................................................. 37 2.2 Objetivos Específicos ...................................................................................................... 37 3. Péptido Bioinspirado en la Proteína Tir como Molécula de Reconocimiento en Biosensores Electroquímicos Modificados con Aunps para la Detección de E. Coli O157: H7 en Matrices Acuosas ......................................................................................................................................... 38 3.1 Resumen .......................................................................................................................... 38 3.2 Metodología ..................................................................................................................... 39 3.2.1 Reactivos, Materiales e Instrumentos ........................................................................... 39 3.2.2 Diseño de Péptidos Análogos a la Proteína TIR de E. Coli O157:H7 Mediante Herramientas Bioinformáticas ............................................................................................... 40 3.2.3 Preparación del Biosensor Electroquímico Utilizando el Péptido Diseñado ............... 42 3.2.4 Evaluación de la Capacidad de Detección de E. coli O157:H7 del Biosensor Electroquímico Utilizando los Péptidos Diseñados............................................................... 47 3.3 Resultados ........................................................................................................................ 49 3.3.1 Diseño de Péptidos Análogos a la Proteína TIR de E. coli O157:H7 Mediante Herramientas Bioinformáticas ............................................................................................... 49 3.3.2 Docking Molecular entre la Proteína Intimina y el Péptido Diseñado ......................... 53 3.3.3 Preparación del Biosensor Electroquímico Utilizando el Péptido Diseñado ............... 56 3.3.4 Evaluación de la Capacidad de Detección de E. Coli O157:H7 del Biosensor Electroquímico Utilizando los Péptidos Diseñados............................................................... 61 3.4 Conclusiones Parciales .................................................................................................... 69 5. Nueva Molécula de Reconocimiento Diseñada a Partir de Peptir 1.0 para la Detección de E. Coli O157: H7 en Matrices Acuosas Mediante Biosensores Electroquímicos ............................. 70 5.1 Resumen .......................................................................................................................... 70 5.2 Metodología ..................................................................................................................... 72 5.2.1 Reactivos, Materiales e Instrumentos ........................................................................... 72 5.2.2 Modelado de Secuencias Análogas a la Molécula Peptir 1.0 ....................................... 72 5.2.3 Preparación del Biosensor Electroquímico Utilizando AuNPs y la Molécula de Reconocimiento Peptir 2.0 .................................................................................................... 74 5.2.4 Evaluación de la Capacidad de Detección del Biosensor Electroquímico Utilizando Peptir 2.0 como Molécula de Reconocimiento ...................................................................... 74 5.3 Resultados ........................................................................................................................ 75 5.3.1 Modelado de Secuencias Análogas a la Molécula Peptir 1.0 ....................................... 75 5.3.2 Preparación del Biosensor Electroquímico Utilizando AuNPs y la Molécula de Reconocimiento Peptir 2.0 .................................................................................................... 79 5.3.3 Evaluación de la Capacidad de Detección del Biosensor Electroquímico Utilizando Peptir 2.0 como Molécula de Reconocimiento ...................................................................... 82 5.4 Conclusiones Parciales .................................................................................................... 87 6. Conclusiones Generales ............................................................................................................ 89 7. Recomendaciones ..................................................................................................................... 91 Referencias Bibliográficas ............................................................................................................ 93 Apéndice ..................................................................................................................................... 105

Published

2021