Application of proximity Ligation for Detection of Proteins, Biomolecular Interactions, and Single Copies of Pathogens

Sammanfattning: Proximity ligation is a recently established technique that can provide answers to questions about the concentration, localization, interactions, modifications and functions of proteins. The method enables sensitive protein measurements with a detection limit in the low femtomolar range in complex biological samples. In proximity ligation, the challenge of detecting specific proteins is converted to the analysis of specific DNA sequences. Proximity probes containing oligonucleotide extensions are designed to bind pairwise to target proteins, and to form amplifiable tag sequences upon ligation when brought in proximity. Protocols for the conversion of monoclonal or polyclonal antibodies into proximity probes through the attachment of oligonucleotide sequences are described in the thesis. In addition, the thesis describes the adaptation of the proximity ligation technology for detection of microbial pathogens, analysis of interactions between proteins and nucleic acids, and of inhibition of receptor-ligand interactions. Nucleic acid amplification allows specific detection of pathogens with single-copy sensitivity. There are many circumstances, however, when analysis of pathogen surface antigens or the antibody response can provide increased diagnostic value. Proximity ligation reactions were used to measure numbers of virus and bacteria by detection of viral or bacterial surface proteins. Detection sensitivities similar to those of nuclear acid-based detection reactions were achieved directly in infected samples for a parvovirus and for an intracellular bacterium. Biological processes are orchestrated by interactions of proteins with molecules in their environment, and investigations of interactions between proteins and other biomolecules are thus of great importance. Protocols were established for very specific and sensitive homogeneous-phase analysis of interactions between proteins and specific nucleic acid sequences. Finally, the proximity ligation mechanism was used to monitor interactions between VEGF-A and two of its receptors, VEGFR-1 and VEGFR-2, and to characterize the effects of agents disrupting this interaction.