Variation in Phenolic Compounds Content and Antioxidant Activity of Different Plant Organs from Rumex crispus L. and Rumex obtusifolius L. at Different Growth Stages

Land-adapted plants appeared between about 480 and 360 million years ago in the mid-Palaeozoic era, originating from charophycean green algae. The successful adaptation to land of these prototypes of amphibious plants - when they emerged from an aquatic environment onto the land - was achieved largely by massive formation of "phenolic UV light screens". In the course of evolution, plants have developed the ability to produce an enormous number of phenolic secondary metabolites, which are not required in the primary processes of growth and development but are of vital importance for their interaction with the environment, for their reproductive strategy and for their defense mechanisms. From a biosynthetic point of view, beside methylation catalyzed by O-methyltransferases, acylation and glycosylation of secondary metabolites, including phenylpropanoids and various derived phenolic compounds, are fundamental chemical modifications. Such modified metabolites have altered polarity, volatility, chemical stability in cells but also in solution, ability for interaction with other compounds (co-pigmentation) and biological activity. The control of the production of plant phenolics involves a matrix of potentially overlapping regulatory signals. These include developmental signals, such as during lignification of new growth or the production of anthocyanins during fruit and flower development, and environmental signals for protection against abiotic and biotic stresses. For some of the key compounds, such as the flavonoids, there is now an excellent understanding of the nature of those signals and how the signal transduction pathway connects through to the activation of the phenolic biosynthetic genes. Within the plant environment, different microorganisms can coexist that can establish various interactions with the host plant and that are often the basis for the synthesis of specific phenolic metabolites in response to these interactions. In the rhizosphere, increasing evidence suggests that root specific chemicals (exudates) might initiate and manipulate biological and physical interactions between roots and soil organisms. These interactions include signal traffic between roots of competing plants, roots and soil microbes, and one-way signals that relate the nature of chemical and physical soil properties to the roots. Plant phenolics can also modulate essential physiological processes such as transcriptional regulation and signal transduction. Some interesting effects of plant phenolics are also the ones associated with the growth hormone auxin. An additional role for flavonoids in functional pollen development has been observed. Finally, anthocyanins represent a class of flavonoids that provide the orange, red and blue/purple colors to many plant tissues. According to the coevolution theory, red is a signal of the status of the tree to insects that migrate to (or move among) the trees in autumn. Copyright © 2013 Elsevier Masson SAS. All rights reserved.

The human intestinal tract is home to a complex microbial community called microbiota. This gut microbiota, whilst playing essential roles in the maintenance of the health of the host, is exposed to the impact of external factors such as the use of medication or dietary patterns. Alterations in the composition and/or function of the microbiota have been described in several disease states, underlining the role of the gut microbiota in keeping the health status. Among the different dietary compounds, polyphenols constitute a very interesting group as some of them have been found to possess important biological activities, including antioxidant, anticarcinogenic or antimicrobial activities. The term polyphenol comprises thousands of molecules presenting a phenol ring and are widely distributed in plant foods. The bioactivity of these compounds is highly dependent on their intestinal absorption and often they are ingested as non-absorbable precursors that are transformed into bioactive forms by specific microorganisms in the intestine. Some of these microorganisms have been identified and the enzymatic steps involved have been elucidated. However, little is known about the impact of these ingested polyphenols upon the human gut microbiota. The heterogeneity of the polyphenol compounds and their food sources, as well as their coexistence with other bioactive compounds within a normal diet, together with the complexity of the human gut microbiota make difficult the understanding of the interactions between dietary polyphenols and gut microbes. This is, however, an important area of research which promises to expand our knowledge on the food functionality area through understanding the microbiota-food component interaction.