Bio-orthogonal Toolbox for Monitoring Nitric Oxide in Targeted Organelles of Live Cells and Zebrafishes.

Abstract

Nitric oxide (NO), playing crucial roles as a cellular messenger and as a toxic ROS, is highly related to the physiological and pathological states of living systems. The very wide but very uneven distribution of this radical gas in the inhomogeneous biological microenvironment imposes big challenges for specifically detecting its local level in certain subcellular areas, which calls for a long list of NO probes for each target. In order to simplify the syntheses and designs of these probes, herein it is proposed to construct a versatile NO-sensing toolbox based on a bio-orthogonal concept, i.e., inverse electron demand Diels-Alder click reaction between tetrazine and strained alkyne BCN. On the one hand, rhodamine-o-phenylenediamine as the NO-responsive scaffold is coupled with a tetrazine unit to generate a general probe TMR-Tz-NO, which, to our knowledge, is the first case of the tetrazine-coupled analyte-responsive probe. On the other hand, the BCN moiety is connected to different targeting groups, such as TPP, morpholine, and Ac4ManN, targeting to mitochondria, lysosomes, and membranes, respectively. It works well to use TMR-Tz-NO to match with any targetable BCN counterpart in this toolbox to achieve the imaging of NO in the corresponding subcellular area. For example, through metabolism, Ac4ManN-BCN is effectively taken and grows on the cell membranes. The bio-orthogonal reaction between TMR-Tz-NO and Ac4ManN-BCN makes the NO probe anchored to the membrane surface permanently. The zebrafish experiment revealed that this bio-orthogonal pair can track and image the NO produced during inflammation in vivo.