Studies on the {beta}-glucosidase System of Trifolium repens L.

Using DEAE-cellulose two distinct ß-glucosidase enzymeshave been identified in white clover; one form is primarilyassociated with the seed, the other with young leaves. Evidenceis presented for the separate nature of ß-glucosidaseand ß-galactosidase activity in dry seed flour andin young leaf tissue. These results are considered in relationto the function of the Li locus in white clover, which is shownto control both ß-glucosidase and ß-galactosidaseactivity in expanding leaves.     

Phosphate and Membrane Electropotentials in Trifolium repens L.

In Trifolium repens L. there were immediate transient depolarizationsof the membrane electropotential (E_vo) when KH₂PO₄ was addedto phosphate-free media, but these were of the same magnitudeas the controls (K²SO⁴ and KCI). Furthermore, the extents ofdepolarization were the same as the expected effect of the addedK⁺ calculated using the Goldman equation. There was no significantdepolarization on adding H₃PO₄ to buffered media. Consequently,there was no evidence for a depolarization caused by phosphate.This result provides evidence that the H⁺–H₂PO₄ symportin roots of T. repens operates with a stoichiometry of 1: 1. In a group of control plants ( + P plants) and a group whichwere stressed by reducing the supply of phosphate (– Pplants), the – P plants had lower values for E_vo than+P plants (– 118 mV and – 130 mV, respectively).The absence of phosphate from the measurement media also reducedE_vo (mean effect = 9 mV). A significant difference in E_vo between– P and + P plants persisted when phosphate was addedto – P plants. The electropotential difference acrossthe tonoplast (E_vo) in – P plants became more positivewith time. Key words: White clover, membrane transport, roots, tonoplast, symport     

The inheritance of cyanoglucoside content in Trifolium repens L.

A four generation backcross breeding program was undertaken. Analysis of the levels of cyanoglucoside in Acac progeny shows that the level of cyanoglucoside (linamarin and lotaustralin) is inherited and that part of the inherited variation in cyanoglucoside levels is attributable to the existence of different Ac alleles in the parent plant. In vitro microsomal cyanoglucoside biosynthetic activity was measured in a high-level and a low-level parent plant. There was no evidence for the presence of microsomes with different qualitative properties in the two plants. The Ac locus was shown to segregate independently of the S incompatibility locus.This research was supported in part by SERC Grant GRA 95550.     

Transformation of the forage legume Trifolium repens L. using binary Agrobacterium vectors

A system was established for introducing cloned genes into white clover (Trifolium repens L.). A high regeneration white clover genotype was transformed with binary Agrobacterium vectors containing a chimaeric gene which confers kanamycin resistance. Transformed kanamycin resistant callus was obtained by culturing Agrobacterium inoculated stolon internode segments on selective medium. The kanamycin resistance phenotype was stable in cells and in regenerated shoots. Transformation was confirmed by the expression of an unselected gene, nopaline synthase in selected cells and transgenic shoots and by the detection of neomycin phosphotransferase II enzymatic activity in kanamycin resistant cells. Integration of vector DNA sequences into plant DNA was demonstrated by Southern blot hybridisation.     

Studies on {beta}-Glucosidase Production in Cultured Tissue of Trifolium repens L.

Variation observed in the growth and cytology of white clovercells is considered in relation to enzyme production in culturedtissue. Variation also occurred in the production of ß-glucosidaseby groups of cultured cells derived from the same plant andwith identical cultural histories. This variability betweencultures grown in a completely defined medium, provided an approachto the investigation of the factors affecting ß-glucosidaseproduction in cultured cells. Evidence was obtained from Michaelisconstants that two distinct ß-glucosidases were producedby cultured tissue.     

Accumulation of Metabolites during Seed Development in Trifolium repens L.

Metabolite deposition during seed development was examined histochemicallyin Trifolium repens by light- and fluorescence microscopy. Allendosperm haustorium at the chalazal pole of the embryo sacand wall protrusions in cell walls of the suspensor and theembryo sac suggest that transfer of metabolites from maternalto offspring tissue takes place primarily at these sites. Thisis further supported by prominent cutinization of the interpolarregion of the embryo sac wall, accumulation of starch in integumentaltissue at the embryo sac poles, and breakdown of interpolarendothelial cells. Decomposition of osteosclereid starch isfollowed by accumulation in the cellular endosperm and subsequentlyin the embryo parallel to endosperm degradation. The starchaccumulates gradually inward from the subepidermal cells ofthe embryo to the stele. Protein bodies are formed in the vacuolesalong the tonoplast, later to be cut off in vesicles releasedinto the cytoplasm. At maturity the embryo is packed with proteinand starch, but without lipid reserves. Phytin is observed inthe protein bodies. The mature embryo is surrounded by a proteinand starch containing aleurone layer which originates from theendosperm.Copyright 1994, 1999 Academic Press White clover, protein, starch, cuticle, embryo sac wall     

Genetic analysis of shikimate dehydrogenase allozymes in Trifolium repens L.

 A genetic analysis was carried out on progeny families from pair crosses among plants polymorphic for shikimate dehydrogenase (SDH) isozymes in white clover (Trifolium repens L.). SDH was controlled by two independently assorting disomic loci. This result is consistent with the presence of a single gene (Sdh) represented in this putative allotetraploid by one locus in each of the genomes. One of the Sdh loci is linked (6.0±2.0 cM) to the linamarase (Li) locus. There was no evidence for differentiation of the duplicate Sdh loci (both carry common alleles). White clover behaves genetically as a diploidised allotetraploid but the possibility of a low frequency of multivalent formation and homoeologous pairing has not been ruled out. The SDH locus is likely to be useful for the marker-assisted selection of agronomic traits. Received: 5 June 1997 / Accepted: 19 November 1997     

Physiological integration in the clonal perennial herb Trifolium repens L.

Summary Translocation of ¹⁴C-labelled carbohydrates between the parent stolon and branches, and among branches, of Trifolium repens plants was investigated in two glasshouse experiments to determine patterns of physiological organisation in this clonal species. Differential defoliation treatments were applied to the parent stolon and/or branches to test the sensitivity of translocation to the short-term carbon needs of defoliated sinks. Strong reciprocal exchange of carbohydrate between the parent stolon and branches was observed, with 18 41% of the ¹⁴C exported from leaves on the parent stolon moving to branches, while branches simulta-neously exported 25% (for old source branches) to 54% (for young source branches) of the ¹⁴C they assimilated to the parent plant, including translocation to other branches. Branch-to-branch translocation occurred both acropetally and basipetally. Parent-to-branch, branch-to-parent and branch-to-branch carbon fluxes all increased in response to defoliation of the sink, at the expense of carbon supply to stolon tissue or roots of the source module. Reduced export to stolon tissue of the parent axis played a major role in facilitating C reallocation from leaves on the parent stolon to defoliated branches. The observed patterns of C allocation and translocation could be adequately explained by accepted source-sink theory, and are consistent with a high degree of intra-plant physiological integration in resource supply and utilisation. This information provides mechanistic explanations for aspects of the growth dynamics and ecological interactions of T. repens in the patchy environment of a grazed pasture.     

The Carbon Economy of Clonal Plants of Trifolium repens L.

Fluxes of carbon between sources and sinks were quantified forclonal plants of Trifolium repens L. (cv. Blanca) in two glasshouseexperiments. Carbon sources were (a) leaves on the parent (=main)stolon apex, or (b) leaves on either young or old branches,and the major sinks of interest were the parent stolon apex,branches, and the adventitious root arising at the same parentstolon node as a young source branch. Defoliation treatmentswere applied to the parent stolon and/or branches (excludingsource branches). Carbon moved freely from the parent stolon to branches and vice-versa;these bidirectional exchanges of C provided important supplementarysources of carbohydrate for the sinks and buffered them againstthe effects of defoliation. Young branches exported more C tothe parent plant (mean=6.3µmol d^–1) than they importedfrom leaves on the parent stolon (5·2µmol d^–1)which, in turn, exceeded the amount fixed by leaves on the branchand utilized within the branch itself (2·7µmold^–1). In contrast, the C economy of old branches was largelyself-contained with, on average, 25·4µmol d^–1exported to the parent plant, 1·8µmol d^–1imported from the parent, and 63·0µmol d^–1fixed and utilized by the branch itself. Thus the growth ofyoung branches was immediately reduced by removal of parentstolon leaves, but old branches were unaffected. An estimated 42% of the C utilized by the main stolon apex originatedfrom branches, while by far the largest proportion (84%) ofthe C used for growth of young nodal roots originated from theassociated branch and not from leaves on the parent stolon towhich the root was directly attached. Key words: Trifolium repens, clonal growth, carbon economy, physiological integration, defoliation     

Direct measurement of nitrogen fixation by Trifolium repens L. and Alnus glutinosa L. using 15N2

A closed-system flow-through enclosure apparatus was used tomeasure symbiotic nitrogen fixation directly. A legume-basedsystem comprising 6-week-old Trifolium repens L. (white clovercv. Blanca) growing with Lolium perenne L. (perennial ryegrasscv. Trani) in an agricultural soil was incubated for 19 d ina ¹⁵N-enriched atmosphere (mean value 3.663 atom%). An actinorhizal-basedsystem comprising 1 -year-old Alnus glutinosa L. (alder) saplingsgrowing with Festuca rubra L. (red fescue) in open-cast coalspoil was incubated for 21 d in a ¹⁵N-enriched atmosphere (meanvalue 3.265 atom%). Indirect estimates of N2 fixation were carriedout concurrently using N difference and ¹⁵N isotope dilutiontechniques. The theory underlying the three techniques and modificationswhich were adopted for comparative purposes are discussed. Thedirect measurements of N2 fixation were then compared with theindirect estimates using P_inc, the proportion of the N incrementduring the measurement period that was derived from fixation.The simple N difference method gave similar values for Pinc(0.94 and 0.97) as those derived from more complicated isotopemethodologies, both indirect (0.91) and direct (0.90). Valuesfor alder were far more variable, ranging from 0.16 to 0.92;this was due largely to variability within the trees and a verysmall N increment during the measurement period. Key words: N₂ fixation, ¹⁵N₂, white clover, alder, enclosure apparatus     

Developmental and Physiological Studies on the Cyanogenic Glucosides of White Clover, Trifolium repens L.

Cyanogenesis in Trifolium repens L. is under the control oftwo loci; Ac/ac and Li/Hi control cyanogenic glucoside and linamaraseproduction respectively. Results obtained show that neitherthe dominant allele (Ac) coding for cyanogenic glucoside productionnor the dominant allele (Li) coding for linamarase productionare expressed in roots, seeds or seedlings before shoot emergence.Both linamarase and cyanogenic glucoside are produced duringshoot growth and there is little turnover of cyanogenic glucosidein mature leaves. As the leaves senesce there is breakdown ofthe mechanism separating cyanogenic glucoside and linamarase,since cyanogenic glucoside is lost in plants of genotype AcAc Li Li but not in those of genotype Ac Ac Li Li. About 60%of the cyanogenic glucoside produced was lotaustralin, in shootsof plants which were fed with equal quantities of the precursoramino acids L-valine and L-isoleucine. In contrast, the proportionof cyanogenic glucoside as lotaustralin found in leaves of oneplant, was only 40%. Different plants were shown to producedifferent quantities of cyanogenic glucoside, and the amountproduced was dependent on temperature.     

On the origin of the cyanogenic polymorphism in Trifolium repens L.

Trifolium repens L. and Trifolium nigrescens Viv. are two of the approximately six cyanogenic species known in the genus Trifolium. The two species are closely related: T. nigrescens is considered to be one of the diploid ancestors of the amphidiploid T. repens . We studied morphology, meiosis and the cyanogenic system in T. repens (amphidiploid), T. nigrescens (diploid) and their reciprocal hybrids. A comparison of the enzyme linamarase in the species and hybrids shows that there is a general resemblance between their linamarases. Immunological studies indicate that the linamarases must have a somewhat different three-dimensional structure. These facts are consistent with the view that T. nigrescens (or an ancestral form of this species) has donated the Li gene of T. repens . The other putative parent, T. occidentale has probably not donated an active Li gene. The hypothesis of the origin of the Li gene does not explain its polymorphism in European populations of T. repens , as T. nigrescens is monomorphic for cyanogenesis and amphidiploids do not segregate for genes which are homozygous dominant in one of the parents. Segregation for Li could be caused by a gene mutation or a small exchange between homeologous chromosomes. The latter event is more probable. A nigrescens-repens exchange would give rise to a chromosomal region with reduced homology to both parental chromosomes. The genes in the region of exchange will be tightly linked due to diminished cross-over frequency. It has been known for years that Li has effects on the vegetative and reproductive characters in T. repens and we have recently shown that these effects must be the result of genes linked to Li . As the associated characters influence the fitness of the cyanotypes, not only the origin but also the maintenance of the cyanogenic polymorphism is closely related to the evolutionary history of T. repens .     

Ovule abortion in white clover (Trifolium repens L.)

Plants of white clover ( Trifolium repens L.) cv. Olwen were grown in an open glasshouse maintained at a mean temperature of 20^oC and ovule growth and seed production measured. Differences in the rate of growth of ovules within ovaries were observed as early as 2 days after pollination. Ovules reached a maximum size after 8 days with the smallest only half the size of the largest. After 8 days, the smallest ovules became flaccid and shrivelled. Ovule position within the ovary had little effect on the frequency of seed set and although there was an apparently higher probability that central ovules produced a seed than those nearer the peduncle or style this was not statistically significant. Inflorescence position and floret position on the inflorescence had a significant effect on the number of seeds per floret and seed weight; the first formed inflorescences and the first florets to be pollinated on each inflorescence had more seeds per floret and heavier seeds and fewer florets with no seed than later pollinated florets. There were also differences between florets within the same whorl. The role of a number of factors which may influence floret site utilisation are discussed.     

Nitrogen relations of a low nitrate uptake inbred line of white clover (Trifolium repens L.)

The nitrogen relations of an inbred line of white clover (Trifolium repens L.) thought to exhibit an abnormally low capacity for NO₃ ^– uptake (line LNU) were compared with a line regarded as normal with respect to NO₃ ^– uptake (line NNU). Growth, nodulation, N₂ fixation and NO₃ ^– uptake were measured over 7 weeks in flowing solution culture (Experiment 1) by plants dependent for N acquisition on either (i) NO₃ ^– uptake, (ii) NO₃ ^– uptake +N₂ fixation, or (iii) N₂ fixation only. Effects of plant N status on the short-term uptake and translocation of ¹⁵NH₄ ⁺ and ¹⁵NO₃ ^– were also investigated (Experiment 2). Nitrate uptake per plant by –fix/+NO₃ ^– line LNU was 50% of uptake by line NNU over 35 days, and there were significant differences in specific uptake rates of NO₃ ^– between the lines over the first 24 days. The `low NO<sub>3</sub> <sup>–</sup> uptake' phenotype was indistinct under +fix/+NO<sub>3</sub> <sup>–</sup> treatment. Nitrate lowered specific rates of nitrogen fixation by line NNU but had no effect on line LNU. Only low N status line LNU plants had lower short-term rates of NH<sub>4</sub> <sup>+</sup> and NO<sub>3</sub> <sup>–</sup> uptake than line NNU. It is concluded that the `low NO₃ ^– uptake' phenotype of line LNU is inconsistently expressed. Circumstantial evidence points to increased NO₃ ^– efflux and decreased xylem translocation of NO₃ ^– as possible explanations for the lower NO₃ ^– uptake by line LNU.     

酸水浸泡下钙盐溶液浸种的白三叶'海法'种子萌发特性初探

研究5～25 mmol·L-1CaCl2溶液浸种的白三叶品种'海法'种子萌发特性的结果表明,酸水胁迫下经CaCl2溶液浸种过的白三叶种子的发芽势、发芽率、发芽指教、活力指数以及幼苗鲜重和干重均增大,且均随着溶液中CaCl2浓度的上升而增大,白三叶种子浸种以15～20mmol·L-1CaCl2的效果为最佳.     

Influence of Temperature and Floret Age on Nectar Secretion in Trifolium repens L.

The influence of temperature on nectar secretion in non-pollinatedflorets of Trifolium repens was investigated in growth chambersat 10, 14, 18 and 22°C. The effect of temperature on therate of nectar secretion was significant in all clones. Theoptimum temperature for secretion in three clones varied from10°C for a clone of Icelandic origin, to 18°C in a cloneselected from a Danish variety. Similarly, the average nectaryield varied significantly among clones of different geographicalorigin. One clone secreted two to four times more than othersat 10°C. The optimum day temperature for nectar secretionwas higher when the plants were exposed to low night temperature,presumably a result of decreased night respiration. Nectar accumulatedat the floret base until senescence. Evidence for reabsorptionof nectar was obtained in four clones. Sucrose, fructose andglucose were identified as the major sugars in the nectar. Highnight temperatures led to decreased sucrose percentage in favourof glucose and fructose. The frequency of new florets openingper day was not influenced by temperatures between 10 and 22°Cin one clone, whereas low temperatures significantly decreasedthe number of new florets in another. Few or no modified stomatawere observed in the epidermis of the nectary. The high variationwith respect to nectar secretion at low temperatures, alongwith the high heritability of this quality, suggests that breedingfor high nectar production at low temperature is plausible.The significance of nectar yield in pollination biology is discussed.Copyright1994, 1999 Academic Press Trifolium repens, white clover, nectar, temperature, floret age, flowering, nectary     

Differences between Natural Populations of Trifolium repens L. in Response to Mineral Nutrients

The response to phosphate of samples of natural local populationsof T. repens, collected from soils of different phosphate contents,was determined over a wide range of phosphate levels in sandculture. A marked correlation (r = +0.96) was found betweenresponse of populations to phosphate at low phosphate levelsand the amount of phosphate in the native soil of the population;populations from soils high in phosphate showed larger reductionsin growth at low phosphate levels than did those from soilslow in phosphate. It is concluded that response to phosphateis one aspect of the physiological adaptation of the naturalpopulations to particular soil conditions. Populations alsodiffered in response to very high levels of phosphate, and inthe range of phosphate levels tolerated; the possible adaptivesignificance of this is discussed in relation to the phosphatebuffering effects of the native soils. Populations tolerantof low phosphate levels had higher concentrations of phosphorusin the shoot material, and a higher uptake of phosphorus perunit weight of roots, than did intolerant populations. The differencesbetween populations in response to phosphate are therefore believedto be due to difference in uptake rather than to differencein metabolic requirement of phosphate.     

Current Nitrogen Fixation Is Involved in the Regulation of Nitrogenase Activity in White Clover (Trifolium repens L.)

Previous studies have shown that nitrogenase activity decreases dramatically after defoliation, presumably because of an increase in the O2 diffusion resistance in the infected nodules. It is not known how this O2 diffusion resistance is regulated. The aim of this study was to test the hypothesis that current N2 fixation (ongoing flux of N2 through nitrogenase) is involved in the regulation of nitrogenase activity in white clover (Trifolium repens L. cv Ladino) nodules. We compared the nitrogenase activity of plants that were prevented from fixing N2 (by continuous exposure of their nodulated root system to an Ar:O2 [80:20] atmosphere) with that of plants allowed to fix N2 (those exposed to N2:O2, 80:20). Nitrogenase activity was determined as the amount of H2 evolved under Ar:O2. An open flow system was used. In experiment I, 6 h after complete defoliation and the continuous prevention of N2 fixation, nitrogenase activity was higher by a factor of 2 compared with that in plants allowed to fix N2 after leaf removal. This higher nitrogenase activity was associated with a lower O2 limitation (measured as the partial pressure of O2 required for highest nitrogenase activity). In experiment II, the nitrogenase activity of plants prevented from fixing N2 for 2 h before leaf removal showed no response to defoliation. The extent to which nitrogenase activity responded to defoliation was different in plants allowed to fix N2 and those that were prevented from doing so in both experiments. This leads to the conclusion that current N2 fixation is directly involved in the regulation of nitrogenase activity. It is suggested that an N feedback mechanism triggers such a response as a result of the loss of the plant's N sink strength after defoliation. This concept offers an alternative to other hypotheses (e.g. interruption of current photosynthesis, carbohydrate deprivation) that have been proposed to explain the immediate decrease in nitrogenase activity after defoliation.