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1.
The effects of paraquat and 2,4,5-T on the photochemical activities of chloroplasts from the leaves of the woody species Carissa spinarum, Maba buxifolia, Flacourtia sepiaria, Chomelia asiatica, Gymnosporia emarginata and Dodonaea viscosa were investigated by comparing the effects on isolated chloroplasts from untreated leaves with those on chloroplasts isolated from herbicide-sprayed plants. DCPIP and NADP reduction of chloroplasts incubated in paraquat or 2,4,5-T solution was inhibited, whereas that of chloroplasts isolated from most species sprayed with these herbicides was enhanced after 24 and 48 h. The enhancement was smaller or disappeared after 72 h. The cyclic and noncyclic photophosphorylation rates were suppressed in chloroplasts isolated from herbicide-treated plants, and also in those from most untreated plants incubated in the herbicide solutions. The differences in reactions of chloroplasts from herbicide-treated and untreated plants are discussed. 相似文献
2.
Isolated spinach (Spinacia oleracea L.) chloroplasts contain a Mg+2-dependent ATPase that is activated by light in the presence of dithiothreitol (DTT) and phenazine methosulfate (PMS). Effects of 11 herbicides, known to affect photophosphorylation in isolated chloroplasts, were measured on ATPase activity when added prior to illumination, on the postillumination dark activity of the ATPase, and on the light-induced synthesis of ATP mediated by DTT and PMS.When added prior to illumination, activity of the ATPase was stimulated by low, and inhibited by high, molar concentrations of chlorpropham, dicryl, dinoseb, ioxynil, oryzalin, perfluidone, propanil, and 4,6,7-trichloro-2-(trifluoromethyl)benzimidazole (TCTFB). The light activation of the ATPase was not affected by diuron, bromacil, or atrazine. Perfluidone, dinoseb, ioxynil, and TCTFB stimulated, whereas chlorpropham, dicryl, oryzalin, propanil, atrazine, bromacil, and diuron had no effect on postillumination hydrolytic activity. The light-induced synthesis of ATP mediated by DTT and PMS was inhibited strongly by chlorpropham, dicryl, dinoseb, ioxynil, oryzalin, perfluidone, propanil, and TCTFB.Because the ATPase reactions are considered to represent the reversal of the terminal reactions of photophosphorylation, inhibition of these reactions implies that the compounds tested, except for diuron, atrazine, and bromacil, have a site of action on the ATP-generating pathway that is separate from the site involved in the inhibition of the Hill reaction. 相似文献
3.
Effects of dichlobenil (2,6-dichlorobenzonitrile) and its phenolic degradation products (2,6-dichloro-3-hydroxybenzonitrile and 2,6-dichloro-4-hydroxybenzonitrile) were compared on electron transport and phosphorylation in isolated spinach (Spinacia oleracea L.) chloroplasts and mung bean (Phaseolus aureus Roxb.) mitochondria. In chloroplasts, the hydroxylated derivatives inhibited both photoreduction and coupled photophosphorylation with water as the electron donor and with ferricyanide as oxidant, and cyclic photophosphorylation with phenazine methosulfate as the electron mediator under an argon gas phase. In mitochondria, the phenolic derivatives acted as uncouplers of oxidative phosphorylation as evidenced by the stimulation of ADP-limited respiration, circumvention of oligomycin-inhibited non-ADP-limited respiration, and the induction of ATPase activity. Treatment of excised mung bean hypocotyls by the phenolic derivatives also resulted in a very rapid and drastic lowering of ATP levels. In all assays, only limited, if any, interference was expressed by dichlobenil even at relatively high molar concentrations.Inhibition of oxidative and photophosphorylation by the phenolic degradation products, but not by dichlobenil, suggests that if there is a delay between the formation of the hydroxylated compounds and their conjugation, photosynthesis and respiration will be inhibited. Because biochemical and physiological processes depend on oxidative and photophosphorylation for the energy (ATP) needed to drive the reactions, interference with ATP production could be one of the major mechanisms through which phytotoxicity is expressed by the phenolic degradation compounds of the herbicide, if they should accumulate in the free from. Species selectivity may be related to the rate of formation of the phenolic products in different plants and the rapidity of conjugate formation. 相似文献
4.
Atrazine [2-chloro-4-(ethylaminol-6-(isopropyl-amino)-s-triazine] resistant biotypes of lamb's quarters (Chenopodium athum L) were reported in the maize growing areas of Ontario, where the herbicide had been used fur a number of years. Field samples from four locations proved tolerant to higber than recommended rates of atrazine in controlled environment screening trials. A resistant biotype was not killed with up to 40 kg/ha atrazine. Diuron at 5 x10-5 M inhibited the Hill reaction with isolated chloroplasts of resisiant and susceptible biotypes of lamb's-quarters. However, with 10-4 M atrazine, the photochemical activity was inhibited in chloroplasts isolated from the susceptible biotype but not in chloroplasts from the resisiant biotype. With maize chloroplasts, inhibition with 10-4 M atrazine was the same as with the susceptible biotype of lamb's-quarters. These studies suggested that a new mechanism of intraspecific resistance in lamb's quarters to atrazine was involved, other than differences in uptake, translocation and metabolism reported with interspecific comparisons involving the s-triazines and other herbicides, It was also concluded that atrazine and diuron did not have precisely the same mechanism of action as photosynthetic inhibitors with lamb's-quarters, and that external and or internal structure or function of chloroplasts in relation to atrazine inhibition can vary significantly even in biotypes of the same species. 相似文献
5.
The effects of nine phenoxy-phenoxypropionic acid derivatives and structurally related compounds on the incorporation of [14C]-acetate into free fatty acids in isolated bean and maize chloroplasts were studied. The compounds tested were esters and the corresponding free acids, OH-diclofop, a nonherbicidal metabolite of diclofop in plants, and d and l enantiomers of diclofop. Fatty acid biosynthesis in bean chloroplasts was not affected by all compounds. OH-Diclofop had a weak inhibitory effect on fatty acid synthesis in maize chloroplasts, while free acids were stronger inhibitors than the corresponding esters in the same system. Uptake studies with diclofop-methyl and diclofop indicated that the esters showed higher uptake rates in chloroplasts suspension. d-Diclofop (I50, 9 × 10?8M) was a more potent inhibitor than l-diclofop (I50, 4 × 10?6M). This agrees with the low herbicidal activity of the l enantiomer in vivo. The results suggest that the mode of action in this type of herbicide may be closely linked with the inhibition of fatty acid biosynthesis. The tolerance of beans could be based on an insensitivity of the target site. 相似文献
6.
Carl Fedtke 《Pesticide biochemistry and physiology》1974,4(4):386-392
Spring wheat (Triticum aestivum L. “Kolibri”) was grown in vermiculite treated with the photosynthesis inhibiting herbicide methabenzthiazuron (1-(benzothiazol-2-yl)-1,3-dimethylurea) either before germination or when the plants were 13 days old. The plants were analyzed from 2 days before until 11 days after treatment or up to a plant age of 23 days.The results are interpreted to fit the concept of a “shade adaptation reaction” caused by a herbicidal photosynthesis inhibition. Soluble reducing sugars have been found to decrease 4 hr after treatment and to stay at a low level throught the experiment. The ATP level was decreased 1 day after treatment but increased above control values 4 days later. This increase was accompanied by a decrease of the chlorophyll ratio. The explanation is given that the ATP level was first decreased because of a lowered carbohydrate supply for substrate and oxidative phosphorylation, and was afterwords increased as a result of an increased cyclic photophosphorylation activity.The soluble protein content and the incorporation of [14C]leucine into protein were increased 4 days after herbicidal treatment. The total protein was slightly decreased beginning 1 day after treatment. The nitrate concentration and the in vitro nitrate reductase activity were both increased 1 day after treatment. The increase of the nitrate concentration occurred in two phases: a first increase by 50% 1 and 2 days after treatment and a second, much stronger increase beginning on the third day. The first increase is interpreted as the result of a decreased in vivo nitrate reductase activity. The second increase possibly was the result of an increased rate of nitrate uptake. 相似文献
7.
Bentazon, 3-isopropyl-2,1,3-benzothiadiazin-4-one-2,2-dioxide is effective for weed control in flooded rice fields not only as a foliar treatment but also as a flooded-water or paddy soil treatment. Generally the herbicidal effect develops slowly only after translocation of the herbicide has occurred, but when the weeds contacted directly with relatively high concentrations of the herbicide, the effects appear rather rapid.The slow herbicidal effect appears to be an important mode of action of bentazon applied practically on weeds under flooded rice field conditions. The slow effect may be caused by inhibition of photosynthesis as supported by the following experimental results: a) Bentazon inhibited the Hill reaction in isolated chloroplasts; b) bentazon rapidly inhibited photosynthetic CO2 fixation in susceptible Cyperus serotinus and other plants; c) the herbicidal effects appeared much slower when bentazon was applied as a flooded-water treatment; d) bentazon injury was prevented by endogenous or exogenously supplied carbohydrates. 相似文献
8.
Walter Oettmeier Klaus Masson Carl Fedtke Jörg Konze Robert R. Schmidt 《Pesticide biochemistry and physiology》1982,18(3):357-367
In chloroplasts isolated from susceptible and atrazine-resistant Amaranthus retroflexus, the inhibition of photosynthetic electron transport by various classes of herbicides has been investigated. Resistance of mutant Amaranthus is not restricted to s-triazines but also extends to uracils, 1,2,4-triazine-5-ones, and ureas. For 1,2,4-triazin-5-ones and chloroplasts of both biotypes, a correlation between inhibition of photosynthetic electron transport and the partition coefficient could be established. In the case of phenolic herbicides only modestly decreased or even higher sensitivity of chloroplasts from the resistant biotype as compared to the susceptible one could be observed. These results are confirmed by binding of radioactively labeled herbicides to chloroplasts of both plants. Specific binding of atrazine or metribuzin to resistant chloroplasts is completely abolished, and that of diuron or phenisopham diminished as compared to susceptible chloroplasts. In contrast, binding of phenolic herbicides generally is enhanced in resistant chloroplasts. Photoaffinity labeling of thylakoids from both biotypes by 2-azido-4-nitro-6-[2′,3′-3H]isobutylphenol yields almost identical labeling patterns. These results are consistent with a recently proposed model (W. Oettmeier, K. Masson, and U. Johanningmeier, Biochim. Biophys. Acta679, 376 (1982) of two different herbicide binding proteins at the reducing side of photosystem II: a 32- to 34-kdalton protein responsible for binding of triazines, triazinones, ureas, and related herbicides and a photosystem II reaction center protein for binding of phenolic herbicides. 相似文献
9.
In a soil application, Torilis arvensis was nearly as susceptible as Lolium rigidum to simazine but was 18-fold more tolerant to diuron. Treat ment with diuron inhibited photosynthesis in L. rigidum but had only a limited effect in T. arvensis although chloroplasts isolated from both species displayed similar susceptibility. 14C-diuron degradation in plants was limited, with the formation of conjugates of mono-methyl-diuron in T. arvensis and N-dealkylated derivatives of diuron in L. rigidum. 14C-diuron entered the roots and was translocated throughout the leaves of L. rigidum but was restricted to stems, leaf petioles and leaf veins of T. arvensis. This difference in transport pattern is proposed to explain the tolerance of T. arvensis to diuron. 相似文献
10.
The objectives of this study were to show that: (a) a herbicide, such as ametryn, which interferes with the photosynthetic electron transport system, causes nitrite to accumulate in illuminated leaves and (b) that nitrite is toxic and contributes to the herbicidal damage and death of the plant. Tests were conducted on wheat seedlings grown on 5 mM nitrate, 5 mM ammonia, and zero nitrogen. Ametryn treatment decreased in vivo and in vitro nitrate reductase activity (NRA) within a 26-hr period. In vivo NRA decreased more rapidly than in vitro NRA. Compared with control tissue, only 3% in vivo NRA remained at the end of 26 hr. The in vivo assay conducted in light confirmed the inhibition of photosynthetic electron flow by ametryn within the leaf tissue. Nitrate-grown, ametryn-treated plants accumulated nitrite and, after 10 days were the only plants that were completely desiccated and dead. Ammonia- and zero-nitrogen, ametryn-treated plants did not accumulate nitrite, were only partially chlorotic after the 10-day period, and were still living. Low levels of NO(X) (NO2 and/or NO) emissions were demonstrated by nitrate-grown ametryn-treated plants. 相似文献
11.
Summary. The influence of thiobencarb at 1500 ppm on levels of nitrate reductase, nitrite reductase and on 2,6-dichlorophenolindophenol (DCPIP) photoreduction was studied in rice ( Oryza sativa L.) and Echinochloa crus-galli (L.) (barnyardgrass) to understand the different sensitivities of these two plants to the herbicide. The herbicide treatment did not cause appreciable inhibition of nitrate reductase and nitrite reductase in rice leaf sections. In barnyard grass, the treatment strongly lowered nitrite reductase activity. DCPIP photoreduction by isolated chloroplasts of the treated rice leaves was not greatly affected. On the other hand DCPIP photoreduction by both mesophyll and bundle sheath chloroplasts from treated barnyardgrass was inhibited by 70%. Herbicide caused accumulation of nitrite in treated barnyard grass leaves when compared to rice. Thiobencarb phytotoxicity to barnyard grass may be due to impairment of the Hill reaction that in turn caused accumulation of nitrite in the leaf tissue. 相似文献
12.
Leaf chlorophyll fluorescence (LCF) of atrazine-susceptible Sinapis arvensis L. (wild mustard) biotype was greatly increased (119–181%)and the Hill reaction activity of isolated chloroplasts was inhibited by 104 M of either atrazine, metribuzin or diuron. In contrast the LCF as well as photochemical activity of the chloroplasts of resistant biotype remained unaffected by 104 M atrazine. However, in response to 104 M metribuzin, LCF of the resistant biotype increased by 43% and Hill reaction activity of the chloroplasts was partially blocked. Complete inhibition of the Hill reaction and a 96% LCF increase in response to diuron indicated that the atrazine-resistant S. arvensis biotype had no tolerance to diuron. Similar chloroplast photoreaction responses were observed when the known atrazine-susceptible and resistant Brassica campestris L. (bird's rape) biotypes and B. napus L. cv. Laurentian (rutabaga) genotypes were subjected to the triazine and urea herbicides. These results indicate that resistance to atrazine, in the resistant S. arvensis biotype, is based in the chloroplasts and could involve a selective modification of the PS II complex with respect to the triazine herbicides. Résistance chloroplastique aux herbicides de la famille des triazines chez Sinapsis arvensis L. (moutarde des champs) Chez un biotype de Sinapis arvensis L. (Moutarde des champs) sensible à l'atrazinc. la fluorescence chlorphyllienne des feuilles était fortement augmentée (de 119 à 181%), et la réaction de Hill des chioroplastes isolés, fortement diminuée, par des traitements à l'atrazinc. la métribuzine ou le diuron 104 M. Par contre, ni la fluorescence chlorophyllienne ni la réaction de Hill n'étaient affectées par de l'atrazine 104 M chez un biotype résistant. Toutefois, en réponse à de la métribuzine 104 M, la fluorescence chlorophyllienne du biotype résistant était augmentée de 43%, et la réaction de Hill chez les chioroplastes était partiellement bloquée. L'inhibition complète de la réaction de Hill et une augmentation de 96% de la fluorescence chlorophyllienne après traitement au diuron indiquaient que le biotype de S. arvensis résistant à l'atrazine ne manifestait pas de tolérance à l'égard du diuron. Par comparaison, des réponses chloroplasliques similaires ont été obtenues lorsque des biotypes de Brassica campestris L. (navette des oiseaux) et des génotypes de B. napus L. cv Laurentian (rutabaga) sensibles ou résistants à l'atrazinc ont été traités par des herbicides de la famille des triazines et des urées substituées. Ces résultats montrent que la résistance à l'atrazine, chez le biotype S. arvensisétudié, est un caractère chloroplastique et implique probablement une modification sélective du complexe PS II à l'égard des triazines. Chlaraplastenresistenz gegen Triazinherbizide bei Sinapis arvensis L. (Ackersenf) Bei atrazinempfindlichen Biotypen von Sinapis arvensis L. wurde die Blattchlorophyll-Fluores-zenz (LCF) in isolierten Chloroplasten durch 104m Atrazin, Metribuzin oder Diuron stark gesteigert (119–181%), die Hillreaktion aber gehemmt. In resistenten Biotypen hingegen blieben LCF und die photochemische Aktivität durch 10?4m Atrazin unbeeinflusst. Resistente Biotypen reagierten auf 10?4m Metribuzin mit einer Erhöhung der LCF um 43% während die Hillreaktion in den Chloroplasten teilweise blockiert wurde. Eine komplette Hemmung der Hillreaktion und eine um 96% gesteigerte LCF durch Diuron weisen darauf hin, dass atrazinresistente Biotypen von S. arvensis gegenüber Diuron nicht resestent sind. Aehnliche Veränderungen der Photoreaktionen in Chloroplasten konnten beobachtet werden, wenn atrazinemp-findliche und -resistente Brassica campestris L., Biotypen (Ackerkohl) und B. napus L. cv. Laurentian, Genotypen (Kohlrübe) Triazin- und Harnstoffherbiziden exponiert wurden. Diese Ergebnisse weisen darauf hin, dass die Ursache der Unempfindlichkeit gegenüber Atrazin bei den resistenten S. arvensis-Biotypen in den Chloroplasten liegt und dass eine selektive Veränderung des PS II Komplexes in Bezug auf die Triazinherbizide eingeleitet werden kann. 相似文献
13.
Magdalina I. Luzhnova Lyudmila M. Shekhtman 《Pesticide biochemistry and physiology》1975,5(3):205-210
The effect of meturine on the light processes of photosynthesis was studied.Meturine is a herbicide for weed control in potato and cotton crops. It is a N-phenyl—N-hydroxy—N′-methylurea.The experiments were carried out on isolated pea and spinach chloroplasts.When examining photosystem I, reduced DPIP was used as an electron donor, whereas methyl-viologen served as an electron acceptor. When examining photosystem II, DPIP represented the electron acceptor.The obtained experimental results have pointed to the absence of the effect of meturine upon the photoreaction I.Unlike N-phenyl—N′, N′-dimethylureas (CMU, DCMU) meturine has been a very weak inhibitor of photoreaction II.The authors explain the photoreaction II inhibition of chloroplasts from plants treated with herbicidal doses of meturine by conversion of N-phenyl—N-hydroxy—N′-methylurea into Hill reaction inhibitor(s). N-Phenyl—N′-methylurea can be one of such meturine metabolites.Meturine herbicidal action is accounted for by meturine transformation into Hill reaction inhibitor(s) in the plant tissues. 相似文献
14.
Carl Fedtke 《Pest management science》1973,4(5):653-664
Spring wheat (Triticum aestivum L. “Caribo”) was grown in vermiculite containing methabenzthiazuron (N-(benzothiazol-2yl)-NN′-dimethylurea) presowing. Effects of the herbicide on plant development and plant composition were analysed up to an age of 4 weeks. Inhibition of photosynthetic oxygen evolution represented the primary effect induced by the herbicidal treatment and led to a decreased concentration of soluble reducing sugars. Photosynthetic activity however recovered after 3 weeks and even increased above control values. Secondary effects following methabenzthiazuron treatment included a delayed chlorophyll breakdown, a decreased chlorophyll a/b ratio, enlarged chloroplasts, an increased concentration of soluble amino acids and of soluble protein, and an increased in vitro nitrate reductase activity. These responses are taken to indicate an increased photosynthetic and metabolic capacity in methabenzthiazuron treated wheat plants. Comparable results can be obtained with plants grown at low light intensities. It is concluded that the “physiological effects” observed in wheat plants after treatment with methabenzthiazuron are similar to a natural adaptation reaction to low light intensities. It is assumed that this adaptation reaction is caused by a low concentration of soluble reducing sugars. Experiments with plants growing at different light intensities indicated that effects due to herbicidal action were more pronounced at high light intensities. Measurements on daily fluctuations revealed a peak around noon for the sugar content and the nitrate reductase activities measured in vivo as well as in vitro. In vivo nitrate reductase activity in plants treated with 5 parts/million methabenzthiazuron was very low, presumably because of lack of sugars for the production of NADH. The protein concentration was increasing and the amino acids were decreasing during the day in herbicide treated plants, possibly indicating increased protein synthesis in the light in plants treated with methabenzthiazuron. 相似文献
15.
M.C. Giardina M. de Agazio M.T. Giardi R. Buffone 《Pesticide biochemistry and physiology》1983,19(1):11-14
The action of atrazine and its biodegradation products on the membrane transport of potassium in roots was evaluated in both sensitive and resistant plants. Excised roots of maize and oat showed inhibition of potassium uptake efficiency in the presence of 1.4 × 10?4M atrazine and 1.4 × 10?4M deethylated atrazine. Other biodegradation products such as 2-chloro-4-amino-6-ethylamino-1,3,5-triazine,2-chloro-4,6-,bisamino-1,3,5-triazine, and 2-chloro-4-amino-1,3,5-triazine showed no inhibitory effect on the K+ uptake capacity. Two maize hybrids showing different uptake efficiency were inhibited differently by atrazine. We suggest that atrazine and deethylated atrazine inhibited the K+ transport interacting directly with the plant cell membranes without discerning between resistant and sensitive plants. 相似文献
16.
The diphenyl ethers acifluorfen (sodium-5-[2-chloro-4-(trifluoromethyl)-phenoxyl]-2-nitrobenzoate), acifluorfen-methyl (methyl-5-[2-chloro-4-(trifluoromethyl)-phenoxyl]-2-nitrobenzoate), and oxyfluorfen (2-chloro-1-[3-ethoxy-4-nitrophenoxy]-4-(trifluoromethyl)benzene have an absolute light requirement for herbicidal activity. CO2-dependent O2 evolution was inhibited in leaf disks obtained from 5-week-old spinach plants as a result of incubation in the light in the presence of each of the three diphenyl ethers. I50's were determined for inhibition by the diphenyl ethers of CO2-dependent O2 evolution in intact chloroplasts obtained from three species of varying susceptibilities (spinach, coffeeweed, and pea). Rankings obtained correlated well with relative susceptibilities and with relative effectiveness of the three compounds tested. Coupled and uncoupled photosynthetic electron transport in susceptible species were unaffected by the three compounds at concentrations in the I50 range. Exposure to herbicidally inactive isomeric analogs of oxyfluorfen and acifluorfen did not affect photosynthesis in leaf disks but was effective in inhibiting photosynthesis in isolated chloroplasts. Photosynthetic abilities of intact tissue were not affected by herbicide treatment in red light. Red light was, however, as effective as white light in mediating the inhibition of photosynthesis in isolated intact chloroplasts by diphenyl ethers. The existence of two photoreceptors for diphenyl ether action, one located at the chloroplast envelope and a second outside of the chloroplast, is suggested as a possible basis for these findings. 相似文献
17.
Gary Gardner K.H. Pilgram Lloyd J. Brown G.A. Bozarth 《Pesticide biochemistry and physiology》1985,24(3):285-297
The use of N-cyclopropyl-N′-(2-fluorophenyl) urea as a selective herbicide in grain sorghum has recently been disclosed (U.S.P. 4,344,916). Evaluation of analogs of this compound has included two assays on isolated pea chloroplasts—photosynthetic electron transport and competition for atrazine binding sites. Of all the analogs studied in at least one of these assays, the most active in vitro were the N-cyclopropyl-, N-n-butyl-, and N-n-pentyl-derivatives of 2,5-difluorophenyl urea. The two in vitro assays correlated well with each other, and binding activity demonstrated a strong correlation with whole-plant phytotoxicity following postemergence application. Several postulated sorghum metabolites of N-cyclopropyl-N′-(2-fluorophenyl) urea showed weak or no activity in vitro, as would be expected from the compoud's selectivity properties. 相似文献
18.
Non-cyclic electron transport by isolated chloroplasts from the alga Bumilleriopsis is inhibited by bentazone, while the activity of photosystem I is not affected. Chloroplast material isolated from cells grown for several days in the presence of bentazone also shows inhibition of photosystem II activity, similar to the decreased cellular photosynthesis. A slow partial recovery is possible, whereas it is fast and complete after exposure of cells or isolated chloroplasts to the herbicide for some hours only. Irreversibility of longterm inhibition could be a metabolic process which brings about the binding of bentazone (or an active derivative) to the thylakoids in vivo, but not in vitro. 相似文献
19.
Annual applications of the herbicides atrazine, simazine, linuron and diuron at 45 kg/ha were made to the same plots for 9 consecutive years from 1963 to 1971 in a peach (Prunus persica (L.) Batsch.) orchard located on sandy loam soil near Harrow, Ontario. Soil samples from these plots were collected in late October for the last 3 years (1969–1971) and trees were cut down in December, 1969. Herbicide residues were determined by bioassays based on the fresh and dry weight of oats (Avena sativa L.) and in one year results were confirmed by chemical analysis. Significant accumulation of herbicides was not observed. The maximum residue levels measured in October over the 3 years of sampling were 7′3 kg/ha for diuron, 3–8 kg/ha for linuron, 1–6 kg/ha for simazine and 04 kg/ha for atrazine in the top 15 cm of the soil profile. Simazine and atrazine showed a rapid decrease in amount after treatment but diuron and linuron were degraded more slowly. Measurable residues of all herbicides were confined to the upper 15 cm of the soil profile and the majority of herbicide remained in the 0–5-cm soil layer. Oats were planted in the orchard plots from 1972 to 1974 to follow the disappearance of the herbicides. All herbicides caused highly significant yield decreases in 1972, atrazine causing the least (38%) and diuron the greatest (86%) reductions. Diuron reduced the yield of oats in 1973 and caused a highly significant decrease in the weight of young oat plants in 1974. 相似文献