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179. Abstract
Carbohydrate researchers may think it is reasonable to believe that
the synthesis and structure of a crystalline beta-1,4 glucan
would be quite straightforward; however, this is not the case.
The pitfalls and detours of research have been
counterbalanced by exciting new discoveries in cellulose structure,
biosynthesis, and molecular biology. Cellulose exists in
crystalline and non-crystalline states, with the metastable cellulose
I allomorph being the most abundant native crystalline
form. Two stages of cellulose I crystallization will be described
as well as a new form of ordered, non-crystalline
cellulose known as quasi-tactic cellulose. The biosynthesis of cellulose
is exceedingly complex, involving many genes and
enzymes. Ordered membrane complexes (TCs) control the polymerization
and crystallization to form cellulose microfibrils.
Biochemical investigations have proven to be very difficult; however,
recent breakthroughs on in vitro cellulose I assembly
lend confidence that this part of cellulose research will soon yield
great advances. The greatest success has come from
molecular genetics research where the genes for cellulose biosynthesis
from Acetobacter have been identified, cloned,
mutated, and expressed in other systems. The multi-domain architecture
of beta-glycosyl transferases has led to a better
understanding of glucan chain polymerization leading to the twofold
screw axis in cellulose as well as finding similar
domains hypothesized to function in higher plant cellulose biosynthesis.
The recent flurry of activity in this field promises to
give even more clues to the developmental regulation of cellulose biosynthesis
among plants, including the major textile and
forest crops.
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Last modified March 13, 2008
This document is maintained by R.
Malcolm Brown, Jr.