Manipulating Diastereomeric Bicyclononynes to Sensitively Determine Enzyme Activity and Facilitate Macromolecule Conjugations.

Bicyclo[6.1.0]nonyne (BCN) is one of the most commonly used cycloalkynes in strain-promoted azide-alkyne cycloaddition (SPAAC). The synthesis of BCN produces two diastereomers, exo-BCN and endo-BCN. The potential significance of the different steric structures of the tricyclic fused rings in SPAAC products synthesized from the BCN diastereomers has not been previously studied. We first demonstrated that only endo-BCN could reduce the level of fluorescence quenching in SPAAC reaction products. The reduction was likely due to the presence of extended tricyclic fused ring systems. This hypothesis was supported by the synthesis of a fluorescence always-on construct by substituting endo-BCN for exo-BCN in a previously reported chemical probe that was characterized with good contact fluorescence quenching. We also synthesized bis-BCN derivatives to enhance the steric structural differences in the corresponding SPAAC products. A constitutional isomer of the azido-derivatized 5(6)-carboxyfluorescein [5(6)-FAM] was reacted with both bis-exo-BCN and bis-endo-BCN compounds. However, one form of the bis-exo-BCN-based product did not augment contact fluorescence quenching, while a second bis-exo-BCN product could not further reduce contact fluorescence quenching. Nevertheless, a new fluorescence turn-on chemical probe was employed to determine the activities of two serum biomarkers, butyrylcholinesterase and paraoxonase 1. Moreover, bis-endo-BCN was exploited to successfully conjugate BSA with a 5-FAM derivative compound.

Sensitive Assay for the Lactonase Activity of Serum Paraoxonase 1 (PON1) by Harnessing the Fluorescence Turn-On Characteristics of Bioorthogonally Synthesized and Geometrically Controlled Chemical Probes.

The lactonase activity of paraoxonase 1 (PON1) has a crucial antiatherogenic function, and also serves as an important biochemical marker in human blood because the aberrant lactonase activity of PON1 is a key indicator for a number of diverse human diseases. However, no sensitive fluorescence assays that detect PON1 lactonase activity are available. We report the synthesis of two fluorescence turn-on chemical probes 16a and 16b (16) able to quantify PON1 lactonase activity. The chemical probes were constructed utilizing a disulfide-containing bicyclononyne, derivatives of rhodamine B and carboxyfluorescein, and reactions including copper-free azide-alkyne cycloaddition. Fluorescence quenching in 16 was characterized by spectroscopic studies and was mainly attributed to the effect of contact quenching. Kinetic analysis of 16b confirmed the outstanding reactivity and specificity of 16b with thiols in the presence of general base catalysts. The 16b-based assay was employed to determine PON1 lactonase activity, with a linear range of 10.8-232.1 U L-1 and detection limit (LOD) of 10.8 U L-1, to quantify serum PON1 activity in human sera, and to determine the Ki of 20.9 µM for the 2-hydroxyquinoline inhibition of PON1 lactonase. We are employing 16b to develop high-throughput assays for PON1 lactonase activity.