Design of biosensor exploiting conformational changes in biomolecules

  1. Hernández Hincapie, Frank Jeyson
Dirigée par:
  1. Cengiz Ozalp Directeur/trice
  2. Ioanis Katakis Directeur/trice

Université de défendre: Universitat Rovira i Virgili

Fecha de defensa: 23 octobre 2008

Jury:
  1. Agustín Costa García President
  2. Magdalena Constantí Garriga Secrétaire
  3. Arben Merkoçi Rapporteur
  4. Mamantos Prodromidis Rapporteur
  5. Mònica Campàs Homs Rapporteur

Type: Thèses

Teseo: 276095 DIALNET lock_openTDX editor

Résumé

The present study exploits two different molecules as biorecognition elements for biosensing. In the first case, a protein biosensor was performed using maltose-binding protein (MBP). The ability to manipulate protein function rationally also offers the possibility of creating new proteins of biotechnological value. Our design has been used to test the understanding of allosteric transitions in proteins. Here we examined a simple conformational change that can represent the biorecognition principle for a reagentless biosensor. Previously, modular strategies for transducing ligand-binding events into fluorescent and electrochemical responses have been reported. Starting with a study of the conformational changes of MBP this research will further develop electrochemical maltose biosensors. The responses of four individual mutations (K46C-MBP-MT, N282C MBP-MT, Q72C-MBP-MT; and K25C-MBP-MT) were evaluated using square wave voltammetry. The possibility of using this type of transduction mechanism for sensor configurations and analyte specificity is discussed.The second part of this work involves SELEX (systematic evolution of ligands by exponential enrichment) and aptamers as biorecognition molecules. As a result of the SELEX method, we can obtain oligonucleotide sequences (aptamers) with recognition properties similar to antibodies. These synthetic elements play an important role in molecular recognition because of their capability for specifically binding of a target molecule. A new approach for the separation step has been performed, termed Soluble-SELEX. This new SELEX method uses hybridization as partitioning mechanism for separating the bound and unbound DNA members from the target-molecule. Hybridization procedure has been evaluated by fluorescence studies as partitioning mechanism for SELEX method. Herein, we exploited the incorporation of an aptamer for biosensing detection of a specific target molecule. Three different transduction methods such as fluorescence, electrochemistry and surface plasmon resonance (SPR) were evaluated. In all three cases, the biosensing procedure was successful.In conclusion, this research has evaluated the translation of a fluorescent biosensor into an electrochemical biosensor using maltose-binding protein as biorecognition element. On the other hand, a new SELEX method has been developed. However, future improvements are required in order to optimize the method. As result of SELEX a new avidin-aptamer was selected and three different transduction systems were employed to construct fluorescent, surface Plasmon resonance and electrochemical biosensors.