Flavonoid based proanthocyanidins and cinnamyl alcohol
based lignins
are chemically complex phenolic oligomers/polymers that are found
in food plants. Although structurally very different, these two biopolymers
are often not distinguished, for example, in the (quantitative) compositional
analysis of cell walls and dietary fiber. Here, we analytically distinguish
lignin and proanthocyanidins in dietary fiber samples by using degradative
and nondegradative techniques and provide information about their
occurrence, abundance, and structural characteristics in seeds of
chokeberries, cranberries, raspberries, red currants, and grapes.
These data revealed that the seeds of botanically diverse fruits largely
differ in terms of their phenolic fiber polymers. The mostly hardened
tissue of the seeds is not necessarily based on lignified cell walls.
For example, red currant and chokeberry seeds almost exclusively contain
proanthocyanidins, and raspberry seeds were clearly lignified (G-H-lignin)
but did not contain proanthocyanidins. Our data also allows for estimating
the bias of proanthocyanidins on different approaches of lignin analysis.
Sugar beet pectins
(SBPs) are known for their emulsifying properties,
but it is yet unknown which structural elements are most important
for functionality. Recent results indicated that the arabinose content
has a decisive influence, but the approach applied did not allow causality
to be established. In this study, a mostly intact SBP was selectively
modified and the obtained pectins were analyzed for their molecular
structure and their emulsifying properties. De-esterification only
resulted in a moderate increase in droplet size. The length of the
pectin backbone only influenced the emulsifying properties when the
homogalacturonan backbone was cleaved to a higher extent. By using
different arabinan-modifying enzymes, it was demonstrated that both
higher portions and chain lengths of arabinans positively influence
the emulsifying properties of SBPs. Therefore, we were able to refine
the structure–function relationships for acid-extracted SBPs,
which can be used to optimize extraction conditions.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.