Bioluminescence and secondary structure properties of aequorin mutants produced for site-specific conjugation and immobilization.

Aequorin is one of several photoproteins that emits visible light upon binding to calcium ions. It has been widely used as a Ca(2+)-indicator and as an alternative highly sensitive bioluminescent label in binding assays. The apoprotein of aequorin binds an imidazopyrazine compound (coelenterazine) and molecular oxygen to form a stable photoprotein complex. Upon addition of calcium, the photoprotein undergoes a conformational change leading to the oxidation of the chromophore with the release of CO(2) and blue light. To gain more information of structure-function relationships within the photoprotein that will aid in the design of mutants suitable for site-specific conjugation and immobilization, polymerase chain reaction (PCR)-based site-directed mutagenesis was employed to produce five different aequorin mutants. The five mutants included a cysteine-free mutant and four other mutants with single cysteine residues at selected positions within the protein. The aequorin mutants exhibited different bioluminescence emission characteristics with two mutants showing a decrease in relative light production in comparison to the cysteine-free mutant. Additionally, circular dichroism (CD) spectra revealed that the single amino acid substitutions made for two of the aequorin mutants did alter their secondary structures.