Boron is an essential element for higher plants, yet the primary funct
ions remain unclear. In intact tissues of higher plants, this element
occurs as both water soluble and water insoluble forms. In this review
, the intracellular localisation of B and possible function of B in ce
ll walls of higher plants are discussed. The majority of the water sol
uble B seems to be localised in the apoplastic region as boric acid. T
he water insoluble B is associated with rhamnogalacturonan II (RG-II)
and the complex is ubiquitous in higher plants. In the Brassicaceae, A
piaceae, Chenopodiaceae, Asteraceae, Amaryllidaceae, and Liliaceae, ne
arly all the cell wall B is associated with RG-II, while in the Cucurb
itaceae, only half of the cell wall B is in this complex. In duckweed,
a different type of B-polysaccharide complex has been identified. Ana
lysis of the structure of the B-RG-II complex reveals that the complex
is composed of boric acid and two chains of monomeric RG-II. Boric ac
id does not merely bind to sugars but crosslinks two chains of pectic
polysaccharide at the RG-II region through borate-diester bonding, thu
s forming a network of pectic polysaccharides in cell walls. The B-RG-
II complex is reconstituted in vitro only by mixing monomeric RG-II an
d boric acid at pH 4.0. In the in vitro reconstitution, germanic acid
can substitute for boric acid to some extent. The RG-II epitope, which
cross reacts with the antibody toward the B-RG-II complex, is detecte
d in walls of every cell in radish roots. The epitope is also detected
in growing pollen tube cell walls, which are claimed to require B. Wh
ilst it is now clear that boric acid links some cell wall components,
it is not yet clear whether there is a structural requirement for B in
cell wall function.