Genetic modification of condensed tannin biosynthesis in Lotus corniculatus. 1. Heterologous antisense dihydroflavonol reductase down-regulates tannin accumulation in “hairy root” cultures

An antisense dihydroflavonol reductase (DFR) gene-construct made using the cDNA for DFR from Antirrhinum majus was introduced into the genome of a series of clonal genotypes of Lotus corniculatus via Agrobacterium rhizogenes. After initial screening, 17 antisense and 11 control transformation events were analysed and tannin levels found to be reduced in antisense root cultures. The effect of this antisense construct, (pMAJ2), which consisted of the 5 half of the DFR cDNA sequence, was compared in three different recipient Lotus genotypes. This construct effectively down-regulated tannin biosynthesis in two of the recepient genotypes (s33 and s50); however, this construct was relatively ineffective in a third genotype (s41) which accumulated high levels of condensed tannins in derived transgenic root cultures. Four pMAJ2 antisense and three control lines derived from clonal genotypes s33 and s50 were selected and studied in greater detail. The antisense DFR construct was found to be integrated into the genome of the antisense hairy root cultures, and the antisense RNA was shown to be expressed. Tannin levels were much lower in antisense roots compared to the controls and this reduction in tannin levels was accompanied by a change in condensed tannin subunit composition.     

A comparison of two strategies to modify the hydroxylation of condensed tannin polymers in Lotus corniculatus L

A full-length sense Antirrhinum majus dihydroflavonol reductase (DFR) sequence was introduced into birdsfoot trefoil (Lotus corniculatus L.) in experiments aimed at modifying condensed tannin content and polymer hydroxylation in a predictable manner. Analysis of transgenic plants indicated lines that showed enhanced tannin content in leaf and stem tissues. In contrast to previous data from root cultures, levels of propelargonidin units were not markedly elevated in lines with enhanced tannin content. RT-PCR analysis of four selected lines indicated a correlation between enhanced tannin content and expression of the introduced DFR transgene. Using a contrasting approach we introduced a flavonoid 3'5' hydroxylase (F3'5'H) sequence derived from Eustoma grandiflorum into Lotus root cultures. Expression of the transgene was associated with increased levels of condensed tannins and in this case there was also no alteration in polymer hydroxylation. These results suggest that additional mechanisms may exist that control the hydroxylation state of condensed tannins in this model species.     

Chemical defense production in Lotus corniculatus L. II. Trade-offs among growth,reproduction and defense

Summary Ecological trade-offs between growth, reproduction and both condensed tannins and cyanogenic glycosides were examined in Lotus corniculatus by correlating shoot (leaves and stem) size and reproductive output with chemical concentrations. We found that cyanide concentration was not related to shoot size, but that condensed tannin concentrations were positively correlated with shoot size; larger plants contained higher tannin concentrations. Both tannin and cyanide concentrations were depressed when plants produced fruits. Defense costs change as plants mature and begin to reproduce. These trade-offs indicate that cost of defense chemical production cannot be predicted merely on the basis of molecular size, composition or concentration.     

Wound-induced accumulations of condensed tannins in turtlegrass, Thalassia testudinum

Turtlegrass, Thalassia testudinum, produces high concentrations of proanthocyanidins (condensed tannins) which we hypothesized are induced by grazing, as a component of a general wound response. To test this we quantified condensed tannins in a variety of turtlegrass tissues following simulated fish grazing, grazing by the urchin Lytechinus variegatus, and treatment with the natural plant wound hormone jasmonic acid. We observed that simulated fish grazing triggered rapid induction of condensed tannins by an average of 10 mg tannin g⁻¹ dry mass (DM) after 5 days. Condensed tannin accumulations were correlated with a reduction of blade extension rates. Further, we observed that constitutive tannin levels in developing first-rank leaves were strongly correlated with the width of second-rank leaves on each shoot, with an increase of 7.7 mg tannin g⁻¹ tissue dry mass per millimeter blade width on average. We propose that wider source leaves provide additional resources for phenolic biosynthesis. There was no induction of tannins in leaves, meristematic or sheath tissues in response to grazing by the urchin L. variegatus, the presence of potential waterborne cues from nearby grazed plants, or to treatment with 5 mM jasmonic acid. However, urchin grazing did induce tannin production in root/rhizome tissues, where they accumulated to levels 3–4 times higher than in blades (up to 350 mg tannin g⁻¹ tissue dry mass). These results confirm the potential for rapid wound-induced condensed tannin accumulations in T. testudinum. The link between blade widths and the tannin content of new leaves indicates that leaf morphology may be a useful bioindicator for predicting herbivore and disease-resistance in the field.     

Resource availability affects differentially the levels of gallotannins and condensed tannins in Ceratonia siliqua

Young potted seedlings of the Mediterranean evergreen sclerophyll Ceratonia siliqua were grown in the field under two nutrient and water regimes during the spring growth period. As expected, plants receiving additional nutrients accumulated more above and below ground biomass while the reverse was true for water stressed plants. In accordance with the growth–differentiation balance hypothesis, total leaf phenolics and tannins (astringency) decreased under high nutrients and increased under water stress, with the effects being more pronounced in young leaves. However, the responses of the two tannin types to resource availability were not similar. Only condensed tannins were decreased by nutrient addition while both condensed and gallotannins were increased by water stress. This non-homogeneous behaviour may reflect the different biosynthetic origins of the two tannin types.     

Condensed Tannin Formation by Agrobacterium rhizogenes Transformed Root and Shoot Organ Cultures of Lotus corniculatus

Root cultures of Lotus corniculatus L. cv. Leo transformed withAgrobacterium rhizogenes (C58Cl-pRi15834) grew rapidly in liquidmedium when cultured in the dark and produced large numbersof shoots when illuminated. The shoots, which could be regeneratedto produce fertile plants, were maintained in liquid mediumas shoot-organ cultures The accumulation and cellular distribution of condensed tanninswas determined during the growth of these root and shoot organcultures and in primary callus from non-transformed explants.Root and shoot cultures predominantly accumulated insolublepolymeric tannins which yielded both cyanidin and delphinidinon hydrolysis at ratios equivalent to control plants. Methanol-solublevanillin-positive compounds were isolated but no free oligomericproanthocyanidins, monomeric flavans or dihydroflavonols weredetected in these extracts. Condensed tannin accumulation waslinearly related to root growth and had a similar spatial distributionin ‘tannin’ cells in roots and leaves as comparedto control plants. Tannin-containing cells were absent frommeristematic cells of the root tip and root/shoot interface.Primary callus cultures failed to accumulate condensed tanninson media containing auxins, and exogenously supplied auxinswere found to inhibit tannin accumulation by transformed rootand shoot cultures Key words: Lotus corniculatus, Agrobacterium rhizogenes, hairy roots, condensed tannins, shoot and root cultures.     

Condensed tannins in the tissue culture of sainfoin (Onobrychis viciifolia Scop.) and birdsfoot trefoil (Lotus corniculatus L.)

Two forage legumes, birdsfoot trefoil (Lotus corniculatus L.) and sainfoin (Onobrychis viciifolia Scop.), containing condensed tannins in their leaves and stems were used as source material to study condensed tannins in tissue culture. More protoplasts were isolated from mesophyll tissue of a low tannin-containing strain of birdsfoot trefoil than from a high tannin-containing strain, but more tannin-filled protoplasts were observed in the latter. Growth rates of leaf explant-derived callus tissue were greater for the high-tannin than for the low-tannin strain. In sainfoin, callus cultures from leaf explants produced numerous tannin-filled cells by 21 days. Explants from sainfoin cotyledons and roots, tissues which normally do not contain tannins, also formed callus with tannin-filled cells in 21 days but in almost every case, a cytokinin was required for tannin formation to occur. The occurrence of tannin-filled cells in callus from root and cotyledon explants was variable and genotype specific. These results show that endogenous tannins can affect protoplast isolation and possibly callus growth in birds-foot trefoil, and that the formation of condensed tannins in sainfoin callus culture can be influenced by a growth regulator.Abbreviations BAP benzylaminopurine - KIN kinetin - NAA naphthaleneacetic acid - PAR photosynthetically active radiation Contribution no. 920 of Agriculture Canada Research Station, 107 Science Cres., Saskatoon, Saskatchewan, Canada S7N OX2     

Genotypic Tannin Levels in Populus tremula Impact the Way Nitrogen Enrichment Affects Growth and Allocation Responses for Some Traits and Not for Others

Plant intraspecific variability has been proposed as a key mechanism by which plants adapt to environmental change. In boreal forests where nitrogen availability is strongly limited, nitrogen addition happens indirectly through atmospheric N deposition and directly through industrial forest fertilization. These anthropogenic inputs of N have numerous environmental consequences, including shifts in plant species composition and reductions in plant species diversity. However, we know less about how genetic differences within plant populations determine how species respond to eutrophication in boreal forests. According to plant defense theories, nitrogen addition will cause plants to shift carbon allocation more towards growth and less to chemical defense, potentially enhancing vulnerability to antagonists. Aspens are keystone species in boreal forests that produce condensed tannins to serve as chemical defense. We conducted an experiment using ten Populus tremula genotypes from the Swedish Aspen Collection that express extreme levels of baseline investment into foliar condensed tannins. We investigated whether investment into growth and phenolic defense compounds in young plants varied in response to two nitrogen addition levels, corresponding to atmospheric N deposition and industrial forest fertilization. Nitrogen addition generally caused growth to increase, and tannin levels to decrease; however, individualistic responses among genotypes were found for height growth, biomass of specific tissues, root:shoot ratios, and tissue lignin and N concentrations. A genotype’s baseline ability to produce and store condensed tannins also influenced plant responses to N, although this effect was relatively minor. High-tannin genotypes tended to grow less biomass under low nitrogen levels and more at the highest fertilization level. Thus, the ability in aspen to produce foliar tannins is likely associated with a steeper reaction norm of growth responses, which suggests a higher plasticity to nitrogen addition, and potentially an advantage when adapting to higher concentrations of soil nitrogen.     

Tree resistance to Lymantria dispar caterpillars: importance and limitations of foliar tannin composition

The ability of foliar tannins to increase plant resistance to herbivores is potentially determined by the composition of the tannins; hydrolyzable tannins are much more active as prooxidants in the guts of caterpillars than are condensed tannins. By manipulating the tannin compositions of two contrasting tree species, this work examined: (1) whether increased levels of hydrolyzable tannins increase the resistance of red oak (Quercus rubra L.), a tree with low resistance that produces mainly condensed tannins, and (2) whether increased levels of condensed tannins decrease the resistance of sugar maple (Acer saccharum Marsh.), a tree with relatively high resistance that produces high levels of hydrolyzable tannins. As expected, when Lymantria dispar L. caterpillars ingested oak leaves coated with hydrolyzable tannins, levels of hydrolyzable tannin oxidation increased in their midgut contents. However, increased tannin oxidation had no significant impact on oxidative stress in the surrounding midgut tissues. Although growth efficiencies were decreased by hydrolyzable tannins, growth rates remained unchanged, suggesting that additional hydrolyzable tannins are not sufficient to increase the resistance of oak. In larvae on condensed tannin-coated maple, no antioxidant effects were observed in the midgut, and levels of tannin oxidation remained high. Consequently, neither oxidative stress in midgut tissues nor larval performance were significantly affected by high levels of condensed tannins. Post hoc comparisons of physiological mechanisms related to tree resistance revealed that maple produced not only higher levels of oxidative stress in the midgut lumen and midgut tissues of L. dispar, but also decreased protein utilization efficiency compared with oak. Our results suggest that high levels of hydrolyzable tannins are important for producing oxidative stress, but increased tree resistance to caterpillars may require additional factors, such as those that produce nutritional stress.     

Deciduous sapling responses to season and large herbivores in a semi‐arid African savanna

Impacts of large herbivores (>5 kg) on woody plants in African savannas are potentially most severe among plants shorter than 1.6 m. It is well established that severe browsing leads to longer shoots, yet prevents saplings from recruiting into adult size‐classes in African savannas. Increased shoot length, indicating faster shoot growth, is often associated with reduced concentrations of tannins and increased nutrient concentrations, suggesting carbon limitation. We hypothesized that, on average, large herbivores suppress stem height or circumference, but increase shoot length. We also hypothesized that if there were concomitant positive effects on nutrients, or negative effects on tannin concentrations, they would be greatest early in the wet season. We sampled saplings of four deciduous woody species (Acacia grandicornuta, Dichrostachys cinerea, Combretum apiculatum and Grewia flavescens) at different stages of the wet season in a large‐scale, long‐term herbivore exclusion experiment in Kruger National Park, South Africa. Plant height, shoot length and stem circumference were generally not adversely affected by large herbivores, suggesting C limitation is rarely present among deciduous saplings in semi‐arid African savannas, allowing them to tolerate browsing. Time since first rainfall emerged as a predominant factor consistently affecting nutrient and tannin concentrations, rather than large herbivores. Nitrogen and phosphorus generally decreased (by 20–50%), while condensed tannin concentration increased (150–350%) during the wet season, except for one species. We postulate that A. grandicornuta is less prone than other species to accumulating tannins during the wet season because of high investment of C in spines. Although nutrient and tannin concentrations were generally not affected by large herbivores, species‐specific responses were evident very early in the wet season, which is when herbivore populations are most likely to be affected by differential forage quality among plants.     

Biomass Partitioning in Tomato Plants Infected with Meloidogyne incognita

Tomato plants were inoculated with Meloidogyne incognita at initial populations (Pi) of 0, 1, 10, 50, 100, and 200 (x 1,000) eggs per plant and maintained in a growth chamber for 40 days. Total fresh biomass (roots + shoots) at harvest was unchanged by nematode inoculation with Pi of 1 x 10⁵ eggs or less. Reductions in fresh shoot weight with increasing Pi coincided with increases in root weight. Total fresh biomass declined with Pi above 1 x 10⁵ eggs, whereas total dry biomass declined at Pi above 1 x 10⁴ eggs. The greatest reduction percentages in fresh shoot biomass induced by root-knot nematodes occurred in the stem tissue, followed by the petiole + rachis; the least weight loss occurred in the leaflets. Although biomass varied among shoot tissues, the relationship between biomass of various shoot tissues and Pi was described by quadratic equations. The linear and quadratic coefficients of the equations (stem, petiole + rachis, or leaflets on Pi) did not differ among tissues when calculations were based on standardized values. Meloidogyne incognita-infected plants had thinner leaves (leaf area/leaf weight) than did uninfected plants. Reductions in leaf weight and leaf area with nematode inoculation occurred at nodes 5-15 and 4, 6-14, respectively. Losses in plant height and mass due to nematodes reflected shorter internodes with less plant mass at each node.     

Feeny revisited: condensed tannins as anti-herbivore defences in leaf-chewing herbivore communities of Quercus

Abstract. 1. Community level oak–tannin–insect patterns have been largely unexplored since Paul Feeny's ground‐breaking research. Two hypotheses were tested for Quercus velutina and Q. alba in the Missouri Ozarks: abundance and richness of leaf‐chewing herbivores are negatively correlated with foliar condensed tannin concentrations and variation in condensed tannin concentrations explains variation in herbivore community structure. 2. In 2001, foliar condensed tannins in the understorey and canopy of these two oak species were quantified simultaneously with censuses of herbivores in May, during leaf expansion, and in June and August, when leaves were fully expanded. Thirty‐eight of the 134 species encountered had densities sufficient to be analysed individually (n = 10). Of those, Acronicta increta (Noctuidae) and Attelabus sp. (Curculionidae), both oak specialists, were negatively correlated with condensed tannins in the canopy of Q. alba. One additional specialist, Chionodes pereyra (Gelechiidae), was marginally negatively correlated with condensed tannins in the understorey of Q. velutina. Understorey species richness of May Q. velutina herbivores was negatively correlated with condensed tannins, as were total canopy insect density and species richness of August herbivores on Q. alba. 3. Principal component analysis (PCA) of insect abundances indicated that understorey and canopy Q. velutina and Q. alba had different communities of leaf‐chewing insects. Furthermore, condensed tannin levels contributed significantly to variation in PCA scores for Q. velutina, explaining 25% of the total variation. 4. Overall, these results indicate that specialists were more likely than generalists both to correlate negatively with condensed tannins and to occur in lower tannin habitats; abundance and richness of both early and late season fauna correlated negatively with tannins; and species were more likely to correlate negatively with condensed tannins when feeding on Q. alba than on Q. velutina and when feeding in the canopy than in the understorey. Future studies of tannin–insect interactions should manipulate leaf quality in combination with manipulations of other factors that likely influence community structure.     

Effects of simulated browsing on growth and leaf chemical properties in Colophospermum mopane saplings

Browsing intensity influences a plant's response to herbivory. Plants face a trade-off between investment in the production of secondary compounds and investment in growth. To elucidate this trade-off, we simulated four browsing intensities (0%, 50%, 75% and 100%) on mopane saplings, Colophospermum mopane (J.Kirk ex Benth.) J.Léonard, in a greenhouse experiment. This showed that, with increasing defoliation intensity, plants change their investment strategy. At intermediate levels of defoliation (50%), mopane saplings increased the synthesis of condensed tannins, so that tannin concentrations followed a hump-shaped relation with defoliation intensity, with significantly higher tannin concentration at intermediate defoliation levels. When defoliated heavily (75% and 100%), tannin concentrations dropped, and plants were carbon stressed as indicated by a reduced growth rate of the stem diameter, and leaf production and mean individual leaf mass were reduced. This suggests that, at intermediate defoliation intensity, the strategy of the plants is towards induced chemical defences. With increasing defoliation, the relative costs of the secondary metabolite synthesis become too high, and therefore, the plants change their growing strategy. Hence, browsers should be able to benefit from earlier browsing by either adopting a low or a relatively high browsing pressure.     

油松不同部位多酚与单宁的含量比较研究

油松为我国特有树种,药用历史悠久且分布广泛,其药用部位含有多酚和单宁等生物活性物质。本文采用Folin-Cicalten法和柠檬酸铁铵法对油松不同部位多酚与单宁含量进行了测定。实验结果表明,油松根、茎和叶多酚含量依次为89.24±12.06、68.18±11.20、104.30±12.51 mg·g^-1;单宁含量依次为25.38±5.85、20.92±3.55、39.02±5.68 mg·g^-1。油松多酚与单宁在油松各部位有相同的分布趋势,均为叶中最高,根次之,茎中最低。与其他中草药植物多酚含量相比,油松多酚含量较高,具有较大的开发前景和应用价值。     

Microbial colonisation of tannin-rich tropical plants: Interplay between degradability,methane production and tannin disappearance in the rumen

Condensed tannins in plants are found free and attached to protein and fibre but it is not known whether these fractions influence rumen degradation and microbial colonisation. This study explored the rumen degradation of tropical tannin-rich plants and the relationship between the disappearance of free and bound condensed tannin fractions and microbial communities colonising plant particles using in situ and in vitro experiments. Leaves from Calliandra calothyrsus, Gliricidia sepium, and Leucaena leucocephala, pods from Acacia nilotica and the leaves of two agricultural by-products: Manihot esculenta and Musa spp. were incubated in situ in the rumen of three dairy cows to determine their degradability for up to 96 h. Tannin disappearance was determined at 24 h of incubation, and adherent microbial communities were examined at 3 and 12 h of incubation using a metataxonomic approach. An in vitro approach was also used to assess the effects of these plants on rumen fermentation parameters. All plants contained more than 100 g/kg of condensed tannins with a large proportion (32–61%) bound to proteins. Calliandra calothyrsus had the highest concentration of condensed tannins at 361 g/kg, whereas Acacia nilotica was particularly rich in hydrolysable tannins (350 g/kg). Free condensed tannins from all plants completely disappeared after 24-h incubation in the rumen. Disappearance of protein-bound condensed tannins was variable with values ranging from 93% for Gliricidia sepium to 21% for Acacia nilotica. In contrast, fibre-bound condensed tannin disappearance averaged ～ 82% and did not vary between plants. Disappearance of bound fractions of condensed tannins was not associated with the degradability of plant fractions. The presence of tannins interfered with the microbial colonisation of plants. Each plant had distinct bacterial and archaeal communities after 3 and 12 h of incubation in the rumen and distinct protozoal communities at 3 h. Adherent communities in tannin-rich plants had a lower relative abundance of fibrolytic microbes, notably Fibrobacter spp. whereas, archaea diversity was reduced in high-tannin-containing Calliandra calothyrsus and Acacia nilotica at 12 h of incubation. Concurrently, in vitro methane production was lower for Calliandra calothyrsus, Acacia nilotica and Leucaena leucocephala although for the latter total volatile fatty acids production was not affected and was similar to control. Here, we show that the total amount of hydrolysable and condensed tannins contained in a plant govern the interaction with rumen microbes affecting degradability and fermentation. The effect of protein- and fibre-bound condensed tannins on degradability is less important.     

Enzymatic surface functionalisation of lignocellulosic materials with tannins for enhancing antibacterial properties

Grafting natural antibacterial phenols onto lignocellulosic materials is an environmentally friendly way of imparting antibacterial properties to the substrates. In the present investigation, wood veneer and pulp were treated with tannins in the presence or absence of laccase. Treatments with hydrolysable tannins significantly improved the antibacterial resistance of veneers and paper made from tannin-treated pulp against a Gram-positive bacterium (Staphylococcus aureus) while a more modest protective effect was observed against a Gram-negative bacterium (Escherichia coli). Condensed tannin improved the antibacterial resistance against S. aureus, albeit less than hydrolysable tannin, but had little effect on E. coli. A cationic condensed tannin derivative bearing a quaternary amino group provided far better resistance to pulp against S. aureus and E. coli than the corresponding unmodified condensed tannin. These findings agree with the minimal inhibitory concentrations (MICs) of the tannins and their reactivities toward laccase as determined by O₂ consumption measurements. Due to a better retention of tannins via covalent bonding, treatments with laccase usually resulted in greater antibacterial effects than those without laccase. LC–MS investigations with monomeric tannin and lignin model compounds showed that covalent bonding of tannin to lignin via radical coupling occurred in the presence of laccase.     

Competition- and resource-mediated tradeoffs between growth and defensive chemistry in trembling aspen (Populus tremuloides)

Costs of defense are thought to maintain genetic variations in the expression of defense within plant populations. As with many plant species, aspen exhibits considerable variation in allocation to secondary metabolites. This study examined the independent and interactive effects of genotype, soil fertility and belowground competition on defensive chemistry and growth in trembling aspen (Populus tremuloides). Four aspen genotypes were grown with high and low soil fertility, and with and without root competition. Physiological, morphological and allocational determinants of growth were measured to identify growth-defense tradeoffs. Nutrient limitation and competition decreased growth, leaf mass ratio, leaf nitrogen concentration and photosynthesis, and increased root : shoot ratio and leaf condensed tannin concentrations. The competition treatment also resulted in increased leaf phenolic glycoside (PG) concentrations. Aspen growth was negatively correlated with PG concentrations under low fertility with competition. The relationship between growth and its major determinants was also negatively related to foliar condensed tannins expressed as a proportion of tree mass, indicating an additional indirect cost of allocation to secondary metabolites.