Higher plants and green algae colle

Higher plants and green algae collect photons forphotosynthesis by antenna systems consisting of pigment-protein complexes. These complexes contain chlorophyl a and b, and a variety of carotenoids (Cars) with different cyclic end-groups[1]. The various Cars are associated with the photosynthetic complexes in thylakoid membranes. They harvest photons, maintain structure and function of the photosynthetic complexes, quench Chl triplet states, and dissipate excess energy[2,3]. In view of the fact that different Chls and Cars are located within different pigment–protein complexes in the photosynthetic apparatus[4], it is highly desirable to have methods for quantifying the individual pigments[5]. Exposure of plant leaves to excessive photon causes the reduction of photosynthetic efficiency, a phenomenon referred to as photoinhibition[2,6]. The xanthophyll cycle (XC) plays an essential role in the protection of plants and algae against excess photons[7,8], with the involvement of two enzymes, i.e., (1) violaxanthin de-epoxidase (VDE) located in the luminasurfaces of the thylakoid membrane, which catalyzes the conversion of diepoxide VIO to epoxide-free zeaxanthin (ZEA) viamonoepoxide ANT. The enzyme activity required ascorbic acid and an optimal luminal pH of 7.5[9].(2)Zeaxan thinepoxidase (ZE), which is located on the stromal surface of thylakoid membranes, catalyzing the reverse reaction[10]. Antheraxanthin (ANT) and ZEA are effective in the dissipation of excess photon-energy and protect the plants from photoinhibition[11,12].