Abstract
In higher plants and green algae two types of thylakoids are distinguished,
granum (stacked) and stroma (unstacked) thylakoids. They form a
three-dimensional (3D) network with large lateral heterogeneity: photosystem
II (PSII) and the associated main chlorophyll
a/b light-harvesting complex
(LHCII) are found predominantly in the stacked region, while PSI and LHCI are
located mainly in the unstacked region of the membrane. This picture emerged
from the discovery of the physical separation of the two photosystems
(Boardman and Anderson 1964). Granal chloroplasts possess significant
flexibility, which is essential for optimizing the photosynthetic machinery
under various environmental conditions. However, our understanding concerning
the assembly, structural dynamics and regulatory functions of grana is far
from being complete. In this paper we overview the significance of the
three-dimensional structure of grana in the absorption properties, ionic
equilibrations, and in the diffusion of membrane components between the
stacked and unstacked regions. Further, we discuss the role of chiral
macrodomains in the grana. Lateral heterogeneity of thylakoid membranes is
proposed to be a consequence of the formation of macrodomains constituted of
LHCII and PSII; their long range order permits long distance migration of
excitation energy, which explains the energetic connectivity of PSII
particles. The ability of macrodomains to undergo light-induced reversible
structural changes lends structural flexibility to the granum. In purified
LHCII, which has also been shown to form stacked lamellar aggregates with long
range chiral order, excitation energy migrates for large distances; these
macroaggregates are also capable of undergoing light-induced reversible
structural changes and fluorescence quenching. Hence, some basic properties of
grana appear to originate from its main constituent, the LHCII.
Subject
Plant Science,Agronomy and Crop Science
Cited by
4 articles.
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