Responses of Lotus corniculatus to environmental change. 4: Root carbohydrate levels at defoliation and regrowth climatic conditions are major drivers of phenolic content and forage quality.

MAIN CONCLUSION: Differential accumulation of root carbohydrates at defoliation have a higher impact than regrowth environmental conditions on the phenolic content and feed quality of the perennial forage legume Lotus corniculatus. The unpredictable nature of proanthocyanidin (condensed tannin) accumulation in regrowth vegetation of the perennial forage legume Lotus corniculatus represents a dilemma to the wider use of this species in agriculture, and a potential problem in the nutritional ecology of some terrestrial herbivores, as variable condensed tannin levels can result in either beneficial or detrimental effects on animal nutrition. However, the source of this variation has not been extensively explored. High levels of carbon allocation to roots during low-temperature preconditioning of clonal plants were found to significantly increase condensed tannin and flavonol levels in regrowth foliage, while low levels of carbon allocation to roots during periods of high-temperature preconditioning significantly decreased condensed tannin and flavonol levels. Phenolic accumulation and tissue digestibility were also differentially affected by regrowth of these defoliated plants at high CO2 concentrations and by drought. Lower rates of digestion generally paralleled increases in tannin levels in regrowth leaves under the different environmental conditions, with rates of digestion falling in high tannin plants, despite correspondingly higher levels of leaf carbohydrates. Differential accumulation of root carbohydrates between seasons and years may therefore explain some of the variability found in the nutritional quality of the forage of this species.

Sn, a maize bHLH gene, modulates anthocyanin and condensed tannin pathways in Lotus corniculatus.

Anthocyanins and condensed tannins are major flavonoid end-products in higher plants. While the transactivation of anthocyanins by basic helix-loop-helix (bHLH) transcription factors is well documented, very little is known about the transregulation of the pathway to condensed tannins. The present study analyses the effect of over-expressing an Sn transgene in Lotus corniculatus, a model legume, with the aim of studying the regulation of anthocyanin and tannin end-products. Contrary to expectation, effects on anthocyanin accumulation were subtle and restricted to the leaf midrib, leaf base and petiole tissues. However, the accumulation of condensed tannin polymers was dramatically enhanced in the leaf blade and this increase was accompanied by a 50-fold increase in the number of tannin-containing cells in this tissue. A detailed analysis of selected lines indicated that this transactivational phenotype correlated with high steady-state transcript levels of the introduced transgene and the introduction of a single copy of the CaMV35S-Sn construct into these clonal genotypes. While the levels of condensed tannins in leaves were increased by up to 1% of the dry weight, other major secondary end-products (flavonols, lignins and inducible phytoalexins) were unaltered in transactivated lines. These results give an initial insight into the developmental and higher-order regulation of polyphenolic metabolism in Lotus and other higher plant species.