Conformational antibodies against classical PKCs and their applications

The protein kinase C family (PKC) is composed of ten isoenzymes, which are capable of phosphorylating serine and threonine amino acid residues. PKC activation involves conformational changes, such as removing the pseudo-substrate from the active site and binding of the enzyme to lipids in biological membranes. In addition, PKC undergoes three phosphorylations that are important for the maturation/ folding of the enzyme and are not linked with activation status. Despite the fact that these kinases are involved in various pathological processes, such as carcinogenesis and cardiovascular disease, a relationship between PKC activation status with these diseases has not yet been established. This is partly due to the lack of tools to detect active PKC in tissue samples. In this thesis, based on conformational changes suffered by PKC during its activation, two antibodies against active cPKCs were rationally developed; a polyclonal antibody (anti-C2Cat) and a monoclonal (4.8E). Anti-C2Cat was produced after immunization of rabbits with a peptide located at the interface between the C2 and catalytic domains of cPKCs in an inactive PKC. The monoclonal antibody 4.8E was produced after immunization of Balb/C mice with total lysates from HEK293T cells overexpressing constitutively active forms of PKCβI. The anti-C2Cat and 4.8E specificity by active cPKCs was demonstrated by ELISA and immunoprecipitation assays, where the antibodies always showed higher affinity to active cPKCs. Anti-C2Cat was able to detect the temporal and spatial dynamics of cPKC activation upon receptor (morphine, ATP or glutamate) or phorbol ester stimulation in neuroblastoma lines (Neuro-2A and SK-N-SH). Futhermore, anti-C2Cat is able to detect active PKC in human tissues. Higher levels of active cPKC were observed in the more aggressive triple negative breast cancer tumors as compared to the less aggressive estrogen receptor positive tumors. Also, both antibodies were applied to study signaling pathways that lead to carcinogenesis in MDA-MB-231 cells by performing co-immunoprecipitation and mass spectrometry. Using this approach, the results suggest that active cPKCs may be involved in translation of proteins involved in cell migration, such as actin. Taken together, the results obtained in this thesis showed two rational ways to develop antibodies against active cPKCs and some applications for these tools were demonstrated. Strategies based on conformational changes, similar to those presented herein may be used for rational production of antibodies against other kinases and proteins. (AU)