Structure of a novel farnesylated bilin from an insect--formation by α-cleavage of heme A of mitochondrial cytochrome c oxidases?

Biliproteins are present in almost all forms of life, and many of them play vital roles in photobiology. The bilin ligand of a recently characterized 500-kDa biliprotein from an insect has been isolated and its structure elucidated with chemical and spectroscopic techniques (UV-visible, IR, MS, NMR, and CD). This blue pigment, named CV-bilin, represents a unique high molecular mass derivative of biliverdin IXα, with an unusual 10E-configuration and a molecular mass of 852 Da, corresponding to C48H60N4O10. The high mass of this open-chain tetrapyrrole results from the presence of an epoxi-dihydroxyethylfarnesyl substituent at C-18 and a hydroxymethyl substituent at C-13. This substitution pattern exactly reflects that of heme A of mitochondrial cytochrome c oxidases with a hydroxyethylfarnesyl chain and a formyl group at corresponding positions of the cyclic tetrapyrrole. As no other natural product is known to show these structural features (heme O, the precursor of heme A, has a methyl group at C-13), this bilin is presumed to be derived from heme A by cleavage of the α-methine bridge and oxidative modifications at C-13 and the hydroxyethylfarnesyl chain. Possibly, a bilin structurally related to this insect bilin is also produced in other organisms as a result of mitochondrial turnover or degradation. As CV-bilin in complex with a specific protein is accumulated at the end of larval life, stored in the pupa, and finally transferred to the oocytes, a possible role of the free or protein-bound pigment in egg or embryonic development is discussed.