Absorption and Translocation of O-Ethyl S,S-Diphenyl Phosphorodithiolate (Hinosan®) in Rice Plants

Absorption and translocation of (O-ethyl S,S-diphenyl phosphorodithiolate (Hinosan) in rice plants were studied by means of techniques of gas-liquid chromatography, radioautograph and ³²P-radioactivity determination. ³²P-labeled Hinosan was used in the present study. Hinosan on the surface of a leaf and on a glass plate was dissipated in a much slower rate than the other phosphorus pesticides tested. Hinosan was chemically transformed to a small extent after taken up into the plant tissues and largely remained in the local region. Up- and downward translocation of Hinosan occurred slightly in the ride seedlings. Translocation and accumulation of Hinosan were also studied concerning with growth stage of rice plants, such as the seedling, the milk-ripening, and the ripening stage. Accumulation in grains was in most cases found to be less than the limit of determination. Translocation of Hinosan was discussed in relation to physiological conditions of rice plants.     

Morphological and Physiological Effects of Maleic Hydrazide on Tobacco

Tobacco plants (Nicotiana tabacum cv. Burley 21) were cultured in the greenhouse to the 18-leaf stage. The apical meristem was removed and subsequent axillary bud growth was removed by hand (controls) or axillary bud development was inhibited by application of maleic hydrazide. Compared with the controls, maleic hydrazide treated plants had a decreased stem diameter and stem weight, but an increased leaf weight and leaf weight/area. Plant height and leaf area were the same for both treatments. Maleic hydrazide inhibited translocation of ¹⁴C from a single leaf exposed to ¹⁴CO₂. Respiration was greater than in the controls three days after application of maleic hydrazide, but 9 and 14 days after application there were no differences in respiration between the two treatments. Maleic hydrazide did not affect photosynthetic activity.     

Influence of Potassium Deficiency on Photosynthesis,Chlorophyll Content,and Chloroplast Ultrastructure of Cotton Plants

In cotton (Gossypium hirsutum L.) grown in controlled-environment growth chamber the effects of K deficiency during floral bud development on leaf photosynthesis, contents of chlorophyll (Chl) and nonstructural saccharides, leaf anatomy, chloroplast ultrastructure, and plant dry matter accumulation were studied. After cotton plants received 35-d K-free nutrient solution at the early square stage, net photosynthetic rate (P _N) of the uppermost fully expanded main-stem leaves was only 23 % of the control plants receiving a full K supply. Decreased leaf P _N of K-deficient cotton was mainly associated with dramatically low Chl content, poor chloroplast ultrastructure, and restricted saccharide translocation, rather than limited stomata conductance in K-deficient leaves. Accumulation of sucrose in leaves of K-deficient plants might be associated with reduced entry of sucrose into the transport pool or decreased phloem loading. K deficiency during squaring also dramatically reduced leaf area and dry matter accumulation, and affected assimilate partitioning among plant tissues.     

Differences between the effects of partial and whole plant chilling on carbon translocation of a C4 grass

Abstract Experiments were conducted with Echinochloa crus-galli to partition the effects of chilling the leaf vs. chilling the whole plant on subsequent ¹¹C translocation. The results clearly demonstrated that whole plant chilling was very detrimental whereas chilling only the leaf had no effect on subsequent translocation nor on ¹¹C uptake. The inhibition of translocation was due to a reduced rate and percentage of export while ¹¹C fixation rate was not significantly altered. When the leaf of a chilled plant was maintained at 22 °C, there was no impairment of the transport system nor of photosynthesis. The decrease in export with whole plant chilling may have been due to carbon movement into storage carbohydrates, resulting in a low sucrose gradient.     

Estimation of seasonal changes in translocation rates in leaves of a Japanese larch stand

To estimate the net rate of translocation in leaves of a larch stand, a new approach based on the summation method was proposed and given by a compartment model. The difference between the rate of translocation into and out of leaf biomass, namely, the net translocation rate (ΔT _r /Δt), was usually expressed by the difference between the growth rate of leaf biomass and the surplus production rate provided that the rate of leaf loss due to leaffall and grazing can be considered negligible. The rate, ΔT _r /Δt in a 19-yr-old larch stand, showed characteristic changes; it was positive from early April to late May, but after that it was negative until leaffall in late October. Our results confirmed that for the growth phase of positive ΔT _r /Δt translocation of assimilate stored in non-photosynthetic organs was indispensable for the growth. To quantify this, the ratio of ΔT _r /Δt to growth rate of leaf biomass was proposed.     

Construction and study of leaf rust-resistant common wheat lines with translocations of <Emphasis Type="Italic">Aegilops speltoides</Emphasis> Tausch. Genetic material

Genotyping was performed for the leaf rust-resistant line 73/00i (Triticum aestivum × Aegilops speltoides). Fluorescence in situ hybridization (FISH) with probes Spelt1 and pSc119.2 in combination with microsatellite analysis were used to determine the locations and sizes of the Ae. speltoides genetic fragments integrated into the line genome. Translocations were identified in the long arms of chromosomes 5B and 6B and in the short arm of chromosome 1B. The Spelt1 and pSc119.2 molecular cytological markers made it possible to rapidly establish lines with single translocation in the long arms of chromosomes 5B and 6B. The line carrying the T5BS · 5BL-5SL translocation was highly resistant to leaf rust, and the lines carrying the T6BS · 6BL-6SL translocation displayed moderate resistance. The translocations differed in chromosomal location from known leaf resistance genes transferred into common wheat from Ae. speltoides. Hence, it was assumed that new genes were introduced into the common wheat genome from Ae. speltoides. The locus that determined high resistance to leaf rust and was transferred into the common wheat genome from the long arm of Ae. speltoides chromosome 5S by the T5BS · 5BL-5SL translocation was preliminarily designated as LrAsp5.     

施氮对半湿润农田生态系统不同冬小麦品种灌浆期物质转移的影响

在年均降水量632 mm的黄土高原南部半湿润红油土上,以NR9405、9430、偃师9号、小偃6号、陕229、西农2208、矮丰3号和商188为供试材料,进行大田试验,研究在不施氮和施氮(90 kg.hm-2)条件下不同品种冬小麦灌浆特性及物质转移效率。结果表明,冬小麦干物质生产及物质转移效率共同受品种和氮肥的影响。开花期老叶、茎鞘和成熟期茎鞘、籽粒干重间存在显著差异。施氮对开花期、成熟期地上部各部位干重均有明显的促进作用。各部位干物质转移量、转移效率和转移量对籽粒的贡献率既与品种有关,也与施氮有关;氮肥的影响又因品种不同而异。干物质转移量、转移效率和转移干物质对籽粒的贡献率在8个供试品种中,最高的是NR9405,最低的是偃师9号,除NR9405和西农2208籽粒中50%以上干物质来自于开花前贮存光合产物的再转移外,其余6个品种籽粒中50%以上的干物质来自于开花后新合成的同化产物。干物质转移量对籽粒的贡献率以穗轴+颖壳部位最低,且多数处理为负值,以茎秆为最大,叶片居中。从总体看,干物质转移量、干物质转移率和干物质转移量对粒重的贡献率在不同品种之间的差异大于施氮处理间的差异,施氮后降低了干物质向籽粒中的转移。     

Plant Growth Based on Interrelation between Carbon and Nitrogen Translocation from Leaves

In individual leaves, the photon-saturated photosynthetic activity (P _sat, expressed on a dry mass basis) was closely related to the nitrogen content (Nc) as follows: P _sat = Cf Nc + P _sat0, where Cf and P _sat0 are constants. On a whole plant basis, the relative growth rate (RGR) was closely related to Nc in canopy leaf as follows: RGR = DMf Nc + RGR₀, where DMf and RGR₀ are constants. However, the coefficients Cf and DMf were markedly different among plant species. To explain these differences, it is suggested that carbon assimilation (or dry matter production) is controlled by both the Nc in a leaf (or leaves) and by the net N translocation from leaves. This is supported by the finding that P _sat is related to the rate of ³⁵S-methionine translocation from leaves. We propose another estimation method for the net N translocation rate (NFR) from leaves: Nc, after full leafing, is expressed as a function of time: Nc = (Nc₀ – Ncd) exp(–Nft) + Ncd, where Nf is a coefficient, t is the number of days after leaf emergence, Nc₀ is the initial value of Nc, and Ncd is the Nc of the dead leaf. The NFR is then calculated as NFR = Nc/t = –Nf (Nc – Ncd). Thus Nf is the coefficient for the NFR per unit Nc. NFR is a good indicator of net N translocation from leaves because NFR is closely related to the rate of ³⁵S-methionine translocation from leaves. Since P _sat is related to the ¹⁴C-photosynthate translocation rate, Cf (or DMf) corresponds to the coefficient of saccharide translocation rate per unit amount of Nc. Cf (or DMf) is closely related to the Nf of individual leaves (or the Nf of canopy leaf). This indicates that C assimilation and C translocation from leaves are related to Nc and N translocation from leaves (net translocation of N). Cf and Nf are negatively correlated with leaf longevity, which is important because a high or low CO₂ assimilation rate in leaves is accompanied by a correspondingly high or low N translocation in leaf, and the degree of N translocation in leaves decreases or increases leaf longevity. Thus, since a relatively high P _sat (or RGR) is accompanied by a rapid Nc decrease in leaves, it is difficult to maintain a high P _sat (or RGR) for a sustained time period.     

Molecular regulation of sink–source transition in rice leaf sheaths during the heading period

The upper leaf sheath of rice (Oryza sativa L.) serves as a temporary starch sink before heading, subsequently becoming a carbon source tissue to the growing panicle at the post-heading stage. The time of sink–source transition in upper leaf sheaths is highly correlated to the panicle exsertion. Here, we found that the expression profiles of starch synthesis genes such as ADP-glucose pyrophosphorylase large subunit 2, granule-bound starch synthase II, soluble starch synthase I, starch branching enzyme (SBE) I, SBEIII, and SBEIV were highly correlated with starch content changes during the heading period in the second leaf sheath below the flag leaf. In addition, the α-amylase2A and β-amylase were considered as major genes that were in charge of starch degradation at the post-heading period. Of the five sucrose transporter (OsSUT) genes, OsSUT1 and OsSUT4 appeared to play an important role in sucrose loading into the phloem of source leaf sheaths. Moreover, the microarray-based data implied that the dominant processes associated with functional leaf sheath transition from sink to source were carbohydrate metabolism and the translocation of the carbon and nitrogen sources and inorganic phosphate.     

The absorption, translocation and distribution of the herbicide glyphosate in maize expressing the CP-4 transgene

Maize (Zea mays L. var. Bonnie) transformed with a gene encoding a 5-enolpyruvylshikimate 3-phosphate synthase with altered sensitivity showed over 100-fold greater resistance to the herbicide glyphosate (N-[phosphonomethyl]glycine) in comparison with its non-transformed progenitor (parental control) at the third-leaf stage. Studies with [¹⁴C]-glyphosate at a dosage lethal to the parental control, but sublethal to the transgenic, revealed that a maximum of 45-65% of the applied dose was absorbed, with greater absorption occurring in transgenic plants. Translocation of glyphosate was closely related to its absorption (r value 0.956) with approximately 15% more of the applied dose being mobilized in transgenic plants than the parental controls. Analysis of electronic autoradiograms along the treated leaf lamina found discrete internal regions of glyphosate accumulation closely associated with the site of application. These regions contained lower amounts of glyphosate present in the treated leaf lamina was almost completely translocated in transgenic plants, while in the parental controls more remained and the leaf became necrotic. In both types of maize there was a small accumulation of herbicide in the tip region of the leaf which was not mobilized. Younger shoot tissues and roots were major sinks for translocated glyphosate accumulating approximately 25-40% of the applied dose depending upon treatment. In the parental control, equal amounts of glyphosate were found distributed between young shoot tissues and roots; while in transgenic plants, the young shoot tissue accumulated around three times more glyphosate than the roots. In both plant types, glyphosate was localized in the meristems and young, actively growing leaves. Specific glyphosate activity (the amount of glyphosate per unit dry weight of tissue) in the major sinks of the transgenic declined towards the end of the treatment period but remained relatively constant in the parental control. In conclusion, enhancing glyphosate resistance by genetic transformation influenced the absorption, translocation and distribution of this herbicide in whole plants.Keywords: Zea mays, glyphosate (N-[phosphonomethyl]-glycine), transgenic, absorption, translocation, source-sink.      

The effects of developmental stage and source leaf position on integration and sectorial patterns of carbohydrate movement in an annual plant, Perilla frutescens (Lamiaceae)

A well-integrated plant shows extensive carbohydrate translocation through the plant body. Even in highly integrated plants, however, translocation patterns will be sectorial if vascular tissue restricts carbon movement to sectors along stems. Both integration and sectorial translocation patterns are sensitive to plant architecture and thus may change as a plant develops. These patterns should vary also with the position of the source leaf because leaves at each node are unique in age and vascular relationship to the rest of the plant. I measured the effects of developmental stage and location of the source leaf on integration and sectoriality in an annual plant, Perilla frutescens, by labeling plants with C at one of three leaves and four developmental stages. Stage and source leaf affected both integration and sectoriality. Most notably, integration declined and sectoriality increased during seed fill, when resource demand at each node was high. Furthermore, translocation was least extensive from the leaf supporting the largest number of seeds on its axillary branch. These results suggest that plants are not homogeneous collections of subunits; rather, the role of each leaf in a plant's carbon budget is a function of its age and location on the plant.     

Ricerche Sull'ultrastruttura dei Tubi Cribrosi di Piccioli di Foglie di Edera

Abstract

The ultrastructure of sieve tubes in leaf petioles of HEDERA HELIX. — The structural organization of the sieve elements in Hedera leaf petiole at the beginning of the second year of life has been studied. At this stage of life the sieve tubes are completely developed, but still in full activity.

Their plasmatic structures, though altered, show that they are still alive. The cytoplasm forms a parietal layer; mitochondria, endoplasmic reticulum and plastids are present although very peculiar in aspect. The cytoplasm is bounded externally by a plasmalemma; on the contrary no tonoplast is detectable.

The data reported in this paper are favourable to the idea of an active partecipation of the sieve tubes in the translocation of organic solutes, in agreement with the findings concerning the oat coleoptile.     

CARBOHYDRATE MOBILIZATION AND MOVEMENT IN ALPINE PLANTS

Starch retention and disappearance from leaves and carbon movement under various temperatures were studied in two alpine species, Oxyria digyna (L.) Hill and Phleum alpinum L., and in two low-elevation species, Helianthus annuus L. and Elymus canadensis L. The alpine species exhibited starch disappearance from the leaf following cool night temperatures, whereas starch retention was noted under similar conditions for the low-elevation species. The alpine species, Oxyria, exhibited the highest rates of starch disappearance from the leaf under cool temperatures as well as the highest carbohydrate translocation under cool temperatures. The low-elevation species had low rates of starch disappearance and carbohydrate translocation under low temperatures, but exhibited relatively higher rates with an increase in temperature. Such a mechanism whereby alpine species can maintain relatively high rates of translocation under cold temperature represents a major form of physiological adaptation to the short, cool, growing season in the alpine tundra.     

Influence of leaf traits on the spatial distribution of insect herbivores associated with an overstorey rainforest tree

Summary The spatial distribution of insect herbivores associated with the Australian rainforest treeArgyrodendron actinophyllum (Sterculiaceae) was investigated by restricted canopy fogging. The foliage of this species was low in nitrogen and water content, and high in fibre content. Herbivore abundance was positively correlated with the amount of young foliage present within the samples and in adjacent samples, and with the nitrogen content of young leaves. In particular, the occurrence of phloem-feeders was correlated with the magnitude of translocation within the samples. The influence of leaf water content upon herbivore distribution was marginal, presumably because this factor is not limiting in rain-forest environments during the wet season, which usually coincides with the season of leaf-flush. Specific leaf weight, leaf size and foliage compactness had little or no apparent effect on herbivore distribution. Since the magnitude of leaf turnover affected both the quantity and the quality, as exemplified by translocation effects, of young foliage available, this factor may be critical to herbivores associated with evergreen rainforest trees which are particularly low in foliar nutrients, such asA. actinophyllum.     

The role of Ca ions in changes induced by excess Cu2+ in bean plants. Growth parameters

The effect of Ca on Cu toxicity in runner bean plants (Phaseolus coccineus L. cv. Piěkny Jaś) grown hydroponically in nutrient solution was studied. The toxic effect of excess Cu on plants depends on their age and Ca content in the medium. Copper applied in excess to the plants at the early phase of leaf development strongly limits the uptake of Ca ions from the nutrient solution, particularly their translocation to leaves. Increased Ca content limits the inhibitory effect of Cu on leaf growth and decreases the content of chloroplast pigments to the level approximate to that of control. At this growth stage the effect of excess Cu is at least partially connected with limited Ca transport to leaves. At the intermediate leaf phase Cu-treated plants react slightly to changed Ca content. At the end of the primary leaf development increased Ca concentration in the medium intensifies senescence processes induced by excess Cu. The changes are partially connected with intensified water deficit. Increased Ca content in the nutrient solution limits Cu accumulation in the individual organs of Cu-treated plants. However, Cu accumulation in leaves is not decreased at a high level of Ca. Copper generally decreases Ca content in the youngest plants, whereas in the oldest ones only in the case of a low level of Ca in the nutrient solution.     

The influence of calcium deficiency on the translocation of photosynthetically fixed 14C in soybeans

Summary Soybean (Glycine max (L.) Merr.) plants were grown at two levels of Ca (0.05 and 2.5 mM Ca) with and without an inorganic source of N in a growth chamber and in the greenhouse. The fourth leaf from the top of the plant was labeled with ¹⁴C, and the distribution of ¹⁴C was measured 24 hours after labeling. The translocation of ¹⁴C out of the labeled leaf was decreased at the low Ca level in both experiments. This decrease occurred before there were any visual Ca deficiency symptoms and before the low Ca level had any effect on dry weight accumulation. The effect of the low Ca level on translocation was the same for plants exposed to an inorganic N source and those that were nodulated. The reduced rate of translocation from the labeled leaf had no measurable effect on the nodule activity as measured by the acetylene reduction method. The data demonstrate the importance of an adequate supply of Ca to the soybean plant for maximum translocation of carbohydrates from the leaves.This paper (76-3-110) is published with the approval of the Director of the Kentucky Agric. Exp. Stn.This paper (76-3-110) is published with the approval of the Director of the Kentucky Agric. Exp. Stn.     

Isolation of an Antibacterial Substance from Mahonia fortunei and its Biological Activity against Xanthomonas oryzae pv. oryzicola

This study aimed to isolate the antibacterial substance from Mahonia fortunei and determine its antibacterial activity against Xanthomonas oryzae pv. oryzicola (Xoc). Bacterial leaf streak of rice, caused by Xoc, is an important rice disease and difficult to control. During a screening of antibacterial plants against plant pathogenic bacteria at an early stage, the extract from M. fortunei was found to have a strong inhibitory effect on Xoc. In this study, the chemical components of M. fortunei stems were extracted using methanol solvent, the antibacterial substance was isolated and purified by liquid–liquid partition and silica gel column chromatography and its structure was identified by nuclear magnetic resonance. The effect and mode of action of the antibacterial substance on bacterial leaf streak of rice were also detected under greenhouse conditions. Two compounds were identified, berberine and jatrorrhizine, which had a strong inhibitory effect on Xoc. The antibacterial activity of berberine was stronger, with a half‐maximal inhibitory concentration (IC₅₀) of 2.9008 mg/l. At the concentration of 0.5 g/l, its control efficacy on bacterial leaf streak of rice was more than 84%. Additionally, berberine could be absorbed by rice leaves and be translocated up and down in the rice plant, and the effective period was long, but its capability of lateral translocation inside the blade was poor.     

Translocation of Photosynthates in Tall and Dwarf Varieties of Pea, Pisum sativum

Quantitative studies of the translocation of radiocarbon from a young expanded leaf of two tall varieties (Improved Pilot and Thomas Laxton) and two dwarf varieties (Little Marvel and Meteor) of Pisum sativum showed that 40 to 45 per cent of the radiocarbon was exported from the ¹⁴CO₂ treated leaf after 24 hours in all four varieties. Although substantial export to the upper shoot always occurred it was more marked in the two tall varieties. Pre-treatment with GA did not affect total fixation but increased total export from the ¹⁴CO₂ treated leaf in cv. Meteor and decreased it in cv. Improved Pilot. GA had no effect on the translocation pattern in the tall plants but modified that of the dwarf plants to correspond to that found in the tall varieties.     

Short feeding period of carrot psyllid (Trioza apicalis) females at early growth stages of carrot reduces yield and causes leaf discolouration

Overwintered adult carrot psyllids [Trioza apicalis Förster (Homoptera: Psylloidea: Triozidae)] damage carrot [(Daucus carota ssp. sativum L.) (Apiaceae)] seedlings by phloem feeding on the leaves. The aim of this study was to investigate the carrot root and shoot growth in relation to carrot psyllid density during early growth stages. One, two, or three carrot psyllids were allowed to feed on carrot seedlings for 3 days. Leaf damage was measured at the 8‐leaf stage, and root, leaf fresh weight, and number of true leaves were measured at harvest. Both the age of the carrot seedling at infestation and the psyllid density had a significant effect on leaf damage at the 8‐leaf stage: seedlings damaged at the cotyledon stage exhibited more leaf damage than seedlings damaged at the 1‐leaf stage. A higher psyllid density significantly reduced the carrot root weight at harvest. The significant interaction of psyllid density with seedling age indicates that differently aged carrot seedlings responded differently to feeding: one psyllid feeding for 3 days at the cotyledon stage caused a significant yield loss, whereas three psyllids were needed to cause the same impact at the 1‐leaf stage. Carrot leaf weight at harvest was not reduced by carrot psyllid feeding: leaves recovered from the damage but roots did not. Our results confirm the farmers’ observations that a trap replacement period of 1 week for carrot psyllid monitoring is too long, especially at the cotyledon stage. Severe leaf discolouration on damaged carrots was observed at harvest. The possible reasons for this discolouration, such as toxin excreted in psyllid saliva or plant pathogenic mycoplasma infection, are discussed.     

Changes in Photosynthesis, Carbon Budget and Mineral Content during the Growth of the First Leaf of Cucumber

The relationships between photosynthesis, dry matter accumulationand translocation have been studied during the development ofthe first true leaf of cucumber. The leaf was grown in an irradianceof 50W m^–2 photosynthetically active radiation for 10h^–1 at 20 C and 2 g m^–3 CO₂. The maximum rate of net photosynthesis, on a leaf area basis,occured at full expansion. Photochemical efficiency, based onincident radiation, also increased up to this stage and wasrelated to the concentration of chlorophyll in the leaf. Darkrespiration and the light compensation point fell over the wholeperiod of leaf expansion. A carbon budget analysis showed that the rate of carbon accumulationin the leaf reached a peak at 70 percent expansion. The leafchanged from a net importer to a net exporter of carbon whenit was about 30 percent expanded. The rate of export increasedwith leaf expansion (and with net photosynthesis) and was twiceas high in the day an in the night at full expansion. At fullleaf expansion there was a reduction in the amount of starchlost overnight, and the carbon exported amounted to 80 per centof the daily net carbon fixed. Cucumber, Cumic satinu L., leaf development, photosynthesis, translocation, carbon budget, mineral content