Effect of imazaquin on absorption, translocation, and pattern of distribution of chlormequat chloride in winter wheat

The role of imazaquin in the absorption, translocation, and distribution of chlormequat chloride in CYCOCEL^* CL has been studied in winter wheat. Three treatments were applied to the 5th leaf of the main stem at growth stage 5 (Feekes Large scale): (1)¹⁴C-chlormequat chloride, (2) CYCOCEL^* CL containing¹⁴C-chlormequat chloride, and (3) CYCOCEL^* CL containing¹⁴C-imazaquin. Tracing of the radioactivity was followed in the treated leaf, main stem, tillers, and roots. Results showed that more than 85% of the radioactivity absorbed remained in the treated leaf. Ten days after the application of chlormequat chloride alone, 94.4% of the¹⁴C-chlormequat was found in the treated leaf, 2.9% in the main stem, 1.2% in the tillers, and 1.4% in the root system versus 88.2, 8.2, 2.1, and 1.4%, respectively, for the chlormequat chloride plus imazaquin treatment. It was concluded that imazaquin increases the mobility and the pattern of distribution of chlormequat chloride in the plant.     

Contribution of the wheat (Triticum aestivum L.) flag leaf to grain yield in response to plant growth regulators

In West-Europe, intensive cereal management uses plant growth regulators (PGRs) especially for wheat. A green-house experiment compared the effects of two PGRs on flag leaf characteristics and yield of winter wheat. Chlormequat chloride + choline chloride (CCC) and chlormequat chloride + choline chloride + imazaquin (CCC+I) were applied to winter wheat at growth stage 5 (Feekes Large scale). CCC and CCC+I significantly increased flag leaf surface area at anthesis. Both treatments also enhanced chlorophyll content of the main stem flag leaf. The grain filling period was extended with PGR application by 2 days. CCC and CCC+I significantly increased net CO₂ assimilation rates during the flag leaf life. No effects of PGR spraying were observed on the pattern of ¹⁴C labelled assimilate distribution. Increased grain yield was due to the increase in average grain weight. The results indicate that PGR treatments increased flag leaf contribution to grain filling. The addition of imazaquin (I) to chlormequat (CCC) improved the effects of CCC.     

Effect of decapitation on absorption,translocation, and phytotoxicity of imazamethabenz in wild oat (Avena fatua L.)

The release of apical dominance by the physical destruction in situ of the apical meristem and associated leaf primordia (decapitation) promoted the growth of tillers in non-herbicide-treated wild oat plants, as indicated by increased tiller lengths and fresh weights. At 96 h after [¹⁴C] herbicide treatment following decapitation, the absorption of [¹⁴C]imazamethabenz and total translocation of radioactivity were respectively increased by 28% and 49%. By 96 h after [¹⁴C]imazamethabenz application, the radioactivity detected in the roots of decapitated plants was 45% higher than that in the roots of nondecapitated plants while the radioactivity in tillers of decapitated plants was 2.6-fold that in tillers of intact plants. Decapitation together with foliar spraying of imazamethabenz at 200 g ha^–1 further reduced tiller fresh weight, greatly decreased the total tiller number, and thereafter significantly increased overall phytotoxicity by 32% as measured by total shoot fresh weight. The results of this study support the hypothesis that main shoot apical dominance limits translocation of applied imazamethabenz to lateral shoots, rendering tillers less susceptible to growth inhibition by the herbicide.     

Foliar Uptake and Movement of Chlormequat in Cereals: Influence of Dose and Addition of Related Chemicals

Increased amounts of chlormequat applied to leaves of barleyand wheat resulted in a greater proportion being taken up andmoving to the tips of treated leaves. Combined foliar applicationwith certain other amines also increased uptake and movementof chlormequat - choline and glycine betaine were particularlyeffective - but a few others had the reverse effect. Ammoniumand sodium salts of acetic, butyric and hydrochloric acids alsoincreased movement of ¹⁴C-chlormequat Hordeum vulgare L., barley, Triticum aestivum L., wheat, chlormequat, foliar uptake     

Distribution patterns of assimilated 14C in vegetative and reproductive shoots of Lolium perenne and L. temulentum

The movement of ¹⁴C-labelled assimilate to the terminal meristem, stem, mature leaves, tillers and roots was measured in Loliurn perenn and Lolium temulentum after exposure to ¹⁴C0₂ of the youngest fully-expanded leaf and, on fewer occasions, the oldest healthy leaf on the main shoot. During early vegetative growth, the terminal meristem, tillers and roots received most of the ¹⁴C exported from the youngest leaf. As the shoot aged, more ¹⁴C was exported to the terminal meristem and tillers and less to roots. When the stem became a sizeable sink for ¹⁴C at the six-leaf (L. temulentum) or eleven-leaf (L. perenne) stage, less ¹⁴C moved to tillers and much less to roots. The terminal meristem continued to receive ¹⁴ at a steady rate throughout late vegetative growth. The transition from vegetative to reproductive growth in both species was marked by an abrupt increase in the export of ¹⁴C to stem from the upper leaf, but there was little change in the proportion of ¹⁴C which moved to the developing leaves and incipient inflorescence at the terminal meristem. At the same time, less ¹⁴C moved to tillers and much less to roots. Immediately before ear emergence, the export of ¹⁴C from the upper leaf (flag leaf) to the stem declined and the proportion moving to the ear increased, reaching a maximum of 55–75% as the ear emerged. The relative patterns of export of upper and lower leaves showed that while some ¹⁴ moved from each leaf to all meristems, the proximity of actively growing meristems appeared to be the main factor which determined the destination of most exported ¹⁴C. The distribution of ¹⁴C from upper and lower leaves was most alike in young vegetative plants of L. perenne. At later stages of development of both species, the terminal meristem and stem received most 14¹⁴C from the upper leaf, while roots and tillers received mos 14¹⁴C from the oldest leaf at the base of the shoot.     

Tillers Do Not Influence Phytotoxicity of Imazamethabenz in Wild Oat (Avena fatua)

The response of wild oat to imazamethabenz varies with the growth stage, but the role of tillers in this regard is unclear. Removal of tillers at the three-leaf stage before spraying with imazamethabenz did not significantly affect the total shoot fresh weight measured 3 weeks later. The leaf area and dry weight of intact plants at the three-leaf stage were 17–21% greater than for plants with coleoptilar and first leaf main shoot tillers (T0 and T1) removed. The greater leaf area may have increased herbicide interception per plant. Similar fresh weight reductions in main shoot, total tillers, and total shoots were found whether imazamethabenz was applied to the plant at the two-leaf without tillers or the three-leaf with two tillers stage. Imazamethabenz applied only to the main shoot reduced total shoot dry weight more than an equivalent amount of imazamethabenz applied only to tiller T1 or applied over the whole shoot. Imazamethabenz had the least inhibitory effect on whole plant growth when applied only to T1. When ¹⁴C-herbicide was applied to the first main shoot leaf of plants at the three-leaf stage with two tillers, the ¹⁴C translocated 38% to roots, 33% to the main shoot, and nearly 30% to all tillers. When ¹⁴C-herbicide was applied to the first leaf of T1 then the ¹⁴C translocated 50% to T1, 25% to the main shoot, 20% to roots, and 5% to all other tillers. The translocation pattern and fresh weight values suggested that the presence of early tillers during herbicide application neither increased nor decreased imazamethabenz efficacy in wild oat. Received June 4, 1997; accepted June 5, 1997     

Factors affecting the uptake of chlormequat into cereal leaves

The effects of site of application, growth environment, droplet size, and formulation adjuvants on the retention and uptake of ¹⁴C-chlormequat by wheat cv. Avalon and barley cv. Sonja have been examined using solutions applied by a micro-sprayer. Wheat plants retained a higher proportion of droplets on initial impaction than barley irrespective of growth stage, site of application or formulation. Leaf retention increased approximately two-fold with increase in surfactant concentration (0·03·0–3% w/v) or decrease in droplet size (200-125 μm) but declined markedly with age of leaf. Uptake, which was greater into wheat than barley, increased with increase in surfactant concentration, growth temperature and droplet size, with a combination of decrease in irradiance plus a rise in soil moisture, and after exposure to simulated dew. Droplet reflection increased and chlormequat uptake declined when the fungicide preparations Bavistin and Radar replaced Agral 90 in the spray mixtures. Droplets impacted more readily and spread more extensively over the damaged surfaces of field grown leaves. Both tissue combustion and autoradiography showed that chlormequat translocated readily only in immature tissues.     

Analysis of assimilate distribution by 3H-tracing during recovery period after rice seedling transplanting

In order to characterize assimilate distribution in rice (Oryza sativa L.) seedlings during recovery period after transplanting, the experiments were conducted by using ³H-isotope tracer technique with three rice hybrid combinations. The label introduced into the leaf sheath was distributed and redistributed to young roots, tillers, and young leaves, thus promoting these organs to grow at the initial stage after transplanting. During period from 10 to 30 days after labeling, ³H-assimilate redistribution occurred mainly from the sheath of the main stem; some radioactivity moved to tillers and roots emerged after transplanting. The activity and percentage of ³H-compounds transporting to rooting nodes and roots emerged after transplanting were higher in root-pruned plants than in control, indicating that growth of root-pruned seedlings more depended on the export of the compounds from the sheath of the main stem than growth of control seedlings.     

Modification of seedling growth of triticale and barley by seed-applied chlormequat

Seeds of triticale and barley were soaked in a range of dilutions of chlormequat. Germination was monitored and the growth of seedlings assessed for up to five weeks. Some concentrations of chlormequat produced seedlings with significantly more leaves on the main stem, more primary tillers, a greater leaf lamina area and a higher shoot dry weight. It is argued that these modifications could lead to an increased yield potential.     

Pre-harvest retting of flax with glyphosate: effect of growth stage at application on uptake, translocation and efficacy of glyphosate

Flax cv. Hera was grown in pots at a density of 2000 plants/m². At various stages of maturity plants were either sprayed with glyphosate (Roundup, Monsanto plc) at a rate equivalent to 1.4 kg a.e./ha or the uppermost leaves of the main stem were treated with ¹⁴C-glyphosate. Uniform desiccation to greater than 80% DM within 5 wk was obtained with sprays applied up to and at 2 wk after the mid-point of flowering (MP) and also at 10 wk after MP, when all seed had been shed. Sprays at 4–6 wk after MP caused little or no desiccation of the lower stem. Autoradiography demonstrated that ¹⁴C-glyphosate applied to the 10 uppermost leaves of the main stem at MP, or to the upper stem at 10 wk after MP, was distributed throughout the plant within 48 h. However, no downward translocation was detected within 48 h of applications during seed filling, i.e. at 2 or 5 wk after MP. Quantitative determinations of distribution of ¹⁴C-glyphosate were made at 48 h after application either to the five uppermost leaves on the main stem or, after leaf drop, to the base of the inflorescence. Translocation out of the treated zone was 58–67% of applied ¹⁴C-glyphosate with applications at 0, 2 or 6 wk after MP but only 13% with application to senescing leaves at 4 wk after MP. Little downward translocation occurred with any of these applications, ¹⁴C-glyphosate accumulating mainly in the upper stem and inflorescence. Thus failure of glyphosate to desiccate the lower stem may be related to poor downward translocation during seed development and to reduced uptake into, and export out of, senescing leaves.     

Leaf Blade Dimensions of Rice (Oryza sativa L. and Oryza glaberrima Steud.). Relationships between Tillers and the Main Stem

The effects of genotype and environment on the leaf area indexof rice are well documented, but the rules governing leaf areadistribution among main stem and tillers are less well understood.This study investigated the ontogenetic patterns of leaf bladearea and dimensions on the main stem and tillers of three ricecultivars, IAC47, Javaé (Oryza sativa L.) and CG14 (O.glaberrima Steud.) grown in pots without competition among plants.No differences in phyllochron were observed among culms, butleaves on tillers appeared 0.5 to 0.8 phyllochrons earlier thanthe genealogically corresponding leaves on the main stem (systemof Katayama). Cohorts were thus not fully synchronized. Allculms produced their largest leaves soon after panicle initiation(PI), despite differences in tiller age. Leaves that appearedsubsequently were smaller owing to reduced length but not width,which remained constant. Three different hypothetical rulesgoverning the behaviour of culms were tested: (1) tillers behaveas clones of the main stem; (2) cohorts behave uniformly, and(3) behaviour is determined by leaf position (sum of genealogicalleaf and tiller indices). The results were best explained byhypotheses (2) and (3), with leaf blade width and length showingmarkedly different patterns. Copyright 2001 Annals of BotanyCompany Phenology, phyllochron, leaf area, leaf position, leaf cohorts, summed leaf position, leaf blade length and width     

Distribution between parts of the main shoot and the tillers of photosynthate produced before and after anthesis in the top three leaves of main shoots of Hobbit and Maris Huntsman winter wheat

The top three leaves of main shoots in crops of Hobbit and Maris Huntsman winter wheat were exposed to ¹⁴CO₂ at 22 and 16 days before and at 10 days after anthesis in 1978. The distribution of the ¹⁴C recovered in whole plants at anthesis and at maturity was measured. There was negligible loss of ¹⁴C between these two times, but some redistribution. The percentage in the tillers was negligible when the flag leaf (leaf 1) was exposed to ¹⁴CO₂, and otherwise less than 12% except for ¹⁴C absorbed by the third leaf at 16 days before anthesis, when it averaged 26% but was very variable. When ¹⁴C was supplied before anthesis, about 20% reached the grain whichever leaf had been supplied. The ear structures contained about 10% of that absorbed by the third leaf and 35% of that absorbed by the flag or second leaf. When ¹⁴C was supplied after anthesis, the amounts reaching the grain from the different leaves were: flag 82%, second 68%, third 56%. Most of the remainder was in the stem. The exposed leaf never retained more than 6%. The amount of ¹⁴C that moved from the stem to the grain between anthesis and maturity was about 50% greater in the semi-dwarf variety Hobbit than in Maris Huntsman. There was no significant varietal difference in the percentage of post-anthesis ¹⁴C reaching the grain. The ear structures of Hobbit contained about a third more ¹⁴C than those of Maris Huntsman. An additional 90 kg N ha^-1, which increased grain yield by 46%, had negligible effects on the distribution of ¹⁴C.     

PATTERNS OF CARBON ALLOCATION IN AN ARCTIC TUNDRA GRASS,DUPONTIA FISCHERI (GRAMINEAE), AT BARROW,ALASKA

In Dupontia fischeri R. Br. the pattern of translocation of photosynthetically incorporated ¹⁴C was established within six hr after treatment in situ at Barrow, Alaska. More radiocarbon went to younger rather than older tillers. The most effective sinks were root, lateral root, and rhizome primordia and nonemergent tillers which were actively growing. Substantial amounts of radiocarbon appeared in the stem base and rhizome of the treated tiller. Although relatively little appeared in other plant parts, except for the sinks mentioned above, interdependence of tillers appeared to be maintained until flowering occurred. This pattern of distribution was established early in the season once the soil thawed, and growth began and was maintained until mid-August. Some translocation to active growth centers occurred even while the soil was thawing. Redistribution of radiocarbon to new root and leaf tissues produced after the time of treatment was observed. There was no autoradiographic evidence during the season to indicate storage of large amounts of mobilizable photosynthate in the stem base or rhizome of a tiller at the time these field studies were carried out.     

半湿润地区氮磷钾配施对强筋小麦功能叶光合速率的影响

选用优质强筋小麦品种陕253为材料,研究了不同氮磷钾肥水平及组合对小麦生育后期主茎、主茎分蘖Ⅰ和主茎分蘖Ⅱ功能叶净光合速率的影响,结果表明:在不同的NPK肥配比处理中,功能叶净光合速率在蘖位、叶位间差异均极其显著,不同生育期间存在明显差异,具体表现为:孕穗期高于灌浆期,主茎>主茎分蘖Ⅰ>主茎分蘖Ⅱ,旗叶高于倒二叶.孕穗期以N225P120K120处理对茎蘖功能叶光合速率影响最为明显,分别比CK1和CK2增加20.41%和25.76%;灌浆期以N135P225K120处理对茎蘖旗叶净光合速率作用显著,分别比CK1和CK2增加43.48%和10.83%.研究发现,在一定磷钾肥基础上通过调节氮肥可以调节孕穗期茎蘖功能叶净叶光合速率,提高钾肥用量有利于提高灌浆期各茎蘖功能叶的净光合速率.     

Distribution of photosynthate produced before and after anthesis in tall and semi-dwarf winter wheat, as affected by nitrogen fertiliser

In 2 years the distribution of radioactivity recovered in entire shoots of field-grown winter wheat was determined at various times after exposing the top two leaves (flag leaf or second leaf) to ¹⁴CO₂ for 30 s. In 1976 when ¹⁴C was supplied to either leaf 14 days before anthesis, 30% was in the ear at anthesis. Less than 5% was in the leaf exposed to ^I4CO₂. The remainder was equally divided between the stem above and below the flag-leaf node when the flag leaf had been exposed, and was mainly in the lower part of the stem when the second leaf had been exposed. By maturity the proportion in the stem had decreased; 20% of the total activity was in the grain and 30% was still in the ear structures. When ¹⁴C was supplied 10 days after anthesis, the proportion in the ear 24 h later ranged from 42 to 69% of that in the whole shoot when the flag leaf was exposed, and from 6 to 28% when the second leaf was exposed. At maturity these proportions increased to 92 and 85% when the ¹⁴C had been supplied to flag leaves and second leaves respectively. When ¹⁴C was supplied 25 days after anthesis to either flag leaves or second leaves, more than 90% of the activity was in the mature ears. Less than 5% of the ¹⁴C remaining at maturity from any treatment was still in the leaf exposed to ¹⁴CO₂. Between 2 and 6% of ¹⁴C supplied after anthesis was in the non-grain parts of the ear. The proportion of the ¹⁴C in the ear was greatest for the semi-dwarf varieties Maris Fundin and Hobbit, less for Maris Huntsman, and least for Cappelle-Desprez. These varietal differences were large 24 h after exposure to ¹⁴CO₂, especially in 1976. They were small and rarely significant at maturity. Nitrogen fertiliser up to 210 kg N ha^-1 had negligible effects on the distribution of ¹⁴C, although it greatly increased growth and yield, especially in 1975.     

Amo 1618 and sterol biosynthesis in tissues and sub-cellular fractions of tobacco seedlings

Amo 1618 inhibited the incorporation of MVA-[2-¹⁴C] into sterols (in particular the 4-desmethylsterols) and promoted its accumulation in squalene-2,-3epoxide in intact seedlings, tissues from treated seedlings, and sub-cellular, membraneous fractions of treated 21-day-old tobacco seedlings. The stem tissues appeared to have a greater sterol requirement (on a per gram fresh weight basis) than leaf tissues and incorporation of radioactivity into stem sterols was more susceptible to inhibition by Amo 1618 than incorporation into leaf tissue.     

Effect of triacontanol and chlormequat on growth,plant hormones and artemisinin yield in Artemisia annua L.

Artemisinin and herbage yield of Artemisia annua plants were determined after application of triacontanol (tria.) and chlormequat (2-chloroethyltrimethylammonium chloride). Tria. at 1.0 and 1.5 mgl^–1 produced a statistically significant positive effect on artemisinin level as well as on plant height, leaf and herbage yield. Chlormequat at 1000 and 1500 mgl^–1 also increased artemisinin level, decreased the plant height at higher concentrations and increased the leaf and herbage yield at lower concentrations. Tria. application enhanced GA-like activity, but ABA levels decreased, while chlormequat increased ABA but reduced GA-like substances. The effect of Tria. on artemisinin yield seems to be mediated through its effect on plant growth.CIMAP Publication.     

Effect of nitrogen and chlormequat chloride on the seed yield and oil content of mustard (Brassica juncea L. Czern & Coss)

The growth of mustard was increased significantly when treated with up to 80 kg N ha^–1 (N₈₀). Spraying with (2-chloroethyl) trimethylammoniumchloride (chlormequat chloride) increased seed yield and seed protein content. Spraying nitrogen fertilized plots with chlormequat chloride, increased leaf area, leaf area ratio, leaf area duration, number of siliquae plant^–1, number of seeds siliqua^–1 and length of siliqua. Reducing, non-reducing and total sugars in the leaves at 80 days after sowing were also affected significantly. Chlorophyll a, b and total chlorophyll were little affected. The number of siliquae plant^–1 was highly correlated with seed yield in both the seasons of experimentation. The correlation coefficient value () was 0.586 in 1982/83 and 0.912 in 1983/84.The total accumulation of nutrients, i.e. nitrogen, phosphorus and potassium in seed and straw was significantly affected by N₈₀ × chlormequat chloride interaction.     

Effect of nitrogen deficiency on photosynthesis and the partitioning of 14C-labelled leaf assimilate in unshaded and partially shaded plants of Lolium temulentum

The effect of a deficiency of applied nitrogen on the rate of leaf photosynthesis, and on the subsequent partitioning of ¹⁴C-labelled leaf assimilate between new leaf, stem, tillers and root, was investigated in single plants of Lolium temulentum L., grown normally in controlled environments, or grown with collars shading the base of the plant. The nitrogen deficiency reduced the rate of leaf photosynthesis, increased the retention of assimilate in the leaf, suppressed the export of assimilate to tillers, and generally increased the export of assimilate to roots and to new leaves. Shading the base of the plant generally had little effect on the rate of leaf photosynthesis, reduced the export of assimilate to roots, and increased the export of assimilate to new leaf and to the stem, which elongated when shading was imposed.     

14CO2 Assimilation and 14C-photosynthate Translocation in Different Leaves of Sunflower

Chlorophyll and nitrogen contents were highest in leaves of middle position, similarly as photosynthetic efficiency represented by ¹⁴C fixation (maxima in leaf 5 from the top). All the leaves lost ¹⁴C after 2 weeks of ¹⁴CO₂ exposure. However, the reduction in radioactivity was less in young upper leaves than in the mature lower leaves. Leaves exported ¹⁴C-photosynthates to stem both above and below the exposed leaf. Very little radioactivity was recovered from the seeds of plants in which only first or second leaves were exposed to ¹⁴CO₂ implying thereby that the carbon contribution of first two leaves to seed filling was negligible. The contribution of leaves to seed filling increased with the leaf position up to the sixth leaf from the top and after the seventh leaf their contribution to seed filling declined gradually.