Structural heterogeneity in biliverdin modulates spectral properties of Sandercyanin fluorescent protein

Sandercyanin, a blue homo-tetrameric lipocalin protein purified from Canadian walleye (Stizostedion vitreus), is the first far-red fluorescent protein reported in vertebrates(1-3). Sandercyanin binds non-covalently to biliverdin IX (BLA) and fluoresces at 675nm on excitation at 375nm and 635nm(1). Sandercyanin fluorescence can be harnessed for many in vivo applications when engineered into a stable monomeric form. Here, we report the spectral properties and crystal structures of engineered monomeric Sandercyanin-BLA complexes. Compared to wild-type protein, monomeric Sandercyanin ([~]18kDa) binds BLA with similar affinities and show a broad red-shifted absorbance spectra but possess reduced quantum efficiency. Crystal structures reveal D-ring pyrrole of BLA rotated around the C14-C15 bond, which is stabilized by neighboring aromatic residues and increased water-mediated polar contacts in the BLA-binding pocket. A tetrameric Sandercyanin variant (Tyr-142-Ala) co-displaying red- and far-red absorbing states, and reduced fluorescence shows similar conformational changes in BLA binding pocket. Our results suggest that D-ring flexibility of BLA and its rearrangement reduces the fluorescence quantum-yield of monomeric Sandercyanin. Structures of monomeric Sandercyanin could be utilized as prototypes to generate bright BLA-inducible fluorescent proteins. Further, our study postulates a mechanism for modulating photo-states in BLA-bound lipocalins, known only in phytochromes till date. Significance StatementSandercyanin is a tetrameric red fluorescent protein from a blue variant of walleye (Stizostedion vitreum) that binds to biliverdin IX (BLA). Its biophysical properties and structures have been published earlier(1). A bright and stable monomeric Sandercyanin could be utilized as a fusion protein for fluorescence-based applications. Here we report the first structures and spectral properties of fluorescent monomeric Sandercyanin-BLA complexes and describe the molecular basis of modulated spectral properties due to rotated D-ring pyrrole around C14-C15 bond and re-shuffling of BLA-binding pocket. BLA-bound monomeric Sandercyanin could be engineered into brighter variants for in-vivo applications. Our study also reveals an unfamiliar mechanism in BLA-binding lipocalins that regulates red- and far-red absorbance states.