ebook img

desarrollo de un multibiosensor de adn para el diagnóstico temprano de cáncer de mama PDF

198 Pages·2008·5.12 MB·Spanish
by  
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview desarrollo de un multibiosensor de adn para el diagnóstico temprano de cáncer de mama

DESARROLLO DE UN MULTIBIOSENSOR DE ADN PARA EL DIAGNÓSTICO TEMPRANO DE CÁNCER DE MAMA Tesis para optar al grado de Doctora en Bioquímica LAURA GARCÍA CARRASCOSA Dirigida por Prof. Laura M. Lechuga Tutor: Catedrático José M. Cuezva Presentada ante el Departamento de Biología Molecular de la Facultad de Ciencias de la Universidad Autónoma de Madrid Llevada a cabo en el Instituto de Microelectrónica de Madrid del Centro Nacional de Microelectrónica (IMM-CNM-CSIC) y en el Centro de Investigación en Nanociencia y Nanotecnología (CIN2:CSIC-ICN) Madrid, Junio 2008 A mis padres SSSSiiii bbbbuuuussssccccaaaassss rrrreeeessssuuuullllttttaaaaddddoooossss ddddiiiissssttttiiiinnnnttttoooossss,,,, nnnnoooo hhhhaaaaggggaaaassss ssssiiiieeeemmmmpppprrrreeee lllloooo mmmmiiiissssmmmmoooo.... Albert Einstein SSSSUUUUMMMMMMMMAAAARRRRYYYY This Thesis describes the development of a new methodology based on label-free biosensing to detect multiple mutations within a gene. As proof of concept it has been chosen the BRCA1 gene, which is related to early onset of inherited breast cancer. Two different biosensing technologies, Nanomechanical and Surface Plasmon Resonance (SPR) biosensors have been evaluated as an alternative tool to routine analytical methods for the detection of DNA point mutations. For setting up an optimised biosensor method for this type of diagnostics, the following issues have been addressed: - The enhancement of DNA immobilization onto gold surfaces at both biosensing platforms: It has been used the well-known method of thiol self- assembly manolayers to immobilize DNA sequences in a controlled way. Three different thiol groups have been evaluated to test DNA linking to the gold surface in order to maximize quimisorption and minimize fisisorption phenomena, leading to highly dense DNA receptor monolayers. - The enhancement of hybridization onto DNA monolayers surfaces at both biosensing platforms: Different strategies, as the use of lateral and vertical spacers, have been tested to control the self-assembly method and to improve target accessibility, leading to higher hybridization efficiency. - Evaluation of both biosensing platforms for DNA detection: Detection of 12 and 25 mer DNA sequences have been tried. Only SPR biosensor were able to detect hybridization and to discriminate a single mismatch within a sequence. Nanomechanical biosensors that use a single microcantilever as transducer were unable to differentiate between a fully complementary sequence and a non-complementary one. For the nanomechanical biosensor a reference cantilever must be used in order to compensate other events not related to hybridization which could hide the detection of the specific hybridization. On the other hand, SPR biosensors were able to detect 12 mer and 25 complementary sequences with a 10 nM and 100 nM limit of detection, respectively. In addition, a clear discrimination of a single mismatch was demonstrated. Therefore this biosensing method was chosen for setting up a multianalyte label-free detection format. - Set-up of a multi-analyte detection format able to discriminate a single mismatched in PCR like products: A methodology of DNA immobilization of multiple receptor sequences, based on the simultaneous co-inmobilization of two and four different sequences related to BRCA1 gene have been tried. Sequential detection of several PCR like target products using the same DNA monolayer was demonstrated, addressing a detection limit at the nM range (50 nM). The main goal of this Thesis has been the demonstration of the ability of the SPR biosensor system for DNA detection and discrimination of single mismatches through a multiplex format. The multiplex detection format has never been described before. The establishment of this methodology, as well as its ability to address a limit of detection in the nM range, sets a landmark in the direct and label-free detection of DNA by biosensor devices. This allocates the biosensor technology as a competitive and complementary tool for DNA analysis. INDICE ÍÍÍÍNNNNDDDDIIIICCCCEEEE 1. MOTIVACIÓN Y OBJETIVOS……………………………………………..5 2. ESTRUCTURA……………………………………………………………….9 3. INTRODUCCIÓN…………………………………………………………..11 3.1 Biosensores …………………………………………………………………11 3.1.1. INTRODUCCIÓN……………………………………………………11 3.1.2 TIPOS DE BIOSENSORES…………………………………………...14 3.1.3 BIOSENSORES ÓPTICOS……………………………………………20 3.1.3.1 Biosensor de resonancia de plasmón superficial………………...22 3.1.4 BIOSENSORES NANOMECÁNICOS……………………………….26 3.1.5 BIOSENSORES DE ADN…………………………………………….30 3.2 Inmovilización de biomoléculas sobre superficies biosensoras de oro …36 3.3 Detección precoz de cáncer de mama hereditario………………………..42 3.3.1. IMPORTANCIA DE LA GENÉTICA EN EL DESARROLLO DEL CÁNCER………………………………………………………….…...42 3.3.1.1 Susceptibilidad genética y cáncer………………………….……..44 3.3.1.2 Tipos de mutaciones involucradas en cáncer……………………45 3.3.2 GENÉTICA DEL CÁNCER DE MAMA HEREDADO …………....48 3.3.2.1 Implicación de los genes BRCA1 y BRCA2……………………..49 3.3.2.2 El gen BRCA1………………………………………………….51 a) Estructura, expresión y función………………………………51 b) Mutaciones más frecuentes en el BRCA-1……………………53 3.3.2.3 Evaluación de riesgo genético en el cáncer de mama hereditario..54 3.3.3 TEST GENÉTICOS ACTUALES PARA LA DETECCIÓN DE MUTACIONES EN LOS GENES BRCA1 Y BRCA2……………….58 1 ÍNDICE 4. MATERIALES Y MÉTODOS………………………………………….63 4.1 Selección de secuencias de ADN y preparación de muestras reales de pacientes con cáncer de mama heredado………………………………64 4.1.1 SECUENCIAS DE ADN DE CARÁCTER GENÉRICO……….64 4.1.2 SECUENCIAS DE ADN TIPO PCR PORTADORAS DE MUTACIONES EN EL GEN BRCA-1…………………………65 4.2 Descripción de los sistemas biosensores empleados………………….69 4.2.1 BIOSENSOR DE RESONANCIA DE PLASMÓN SUPERFICIAL (SPR)………………………………………………………….….69 4.2.2 BIOSENSOR NANOMECÁNICO……………………………...73 4.3 Técnicas ex-situ empleadas para apoyo a la caracterización de la inmovilización e hibridación de ADN en biosensores……………….75 4.3.1 FLUORESCENCIA……………………………………………...75 4.3.2 MARCAJE RADIOACTIVO…………………………………….77 4.3.3 ESPECTROSCOPÍA FOTOELECTRÓNICA DE RAYOS X (XPS)…………………………………………………………….77 4.4 Protocolos de inmovilización y hibridación……………………………79 4.4.1 BIOSENSOR SPR…………………………………………..……80 4.4.2 BIOSENSORES NANOMECÁNICOS………………………….81 4.4.3 TÉCNICAS EX-SITU …………………………………………....82 5 RESULTADOS……………………………………………………………83 5.1 Caracterización de los procesos de inmovilización e hibridación en biosensores SPR y nanomecánicos………………….………………….83 5.1.1 CONDICIONES DE INMOVILIZACIÓN……………………..83 5.1.2 CONDICIONES DE HIBRIDACIÓN…………………………..96 5.1.3 OPTIMIZACIÓN DE LA DETECCIÓN POR MEJORA DE LA ACCESIBILIDAD…………………………………………...…...98 5.2 Condiciones para la detección de mutaciones en SPR……………….105 5.3 Detección en SPR de mutaciones vinculadas al BRCA-1….......…….109 5.3.1 FORMATO DE DETECCIÓN DE UN ÚNICO ANALITO.....110 5.3.2 FORMATO DE DETECCIÓN MULTI-ANALITO................…112 2

Description:
Evaluation of both biosensing platforms for DNA detection: Detection of 12 and 25 mer DNA sequences have been tried. Only SPR biosensor.
See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.