Low doses of glyphosate change the responses of soyabean to subsequent glyphosate treatments          下载免费PDF全文

F M L Silva  S O Duke  F E Dayan  E D Velini 《Weed Research》2016,56(2):124-136

Many herbicides promote plant growth at doses well below the recommended application rate (hormesis). The objectives of this study were to evaluate glyphosate‐induced hormesis in soyabean (Glycine max) and determine whether pre‐treating soyabean seedlings with low doses of glyphosate would affect their response to subsequent glyphosate treatments. Seven doses (1.8–720 g a.e. ha^?1) of glyphosate were applied to 3‐week‐old seedlings, and the effects on the electron transport rate (ETR), metabolite (shikimate, benzoate, salicylate, AMPA, phenylalanine, tyrosine and tryptophan) levels and dry weight were determined. The lowest dose stimulated ETR and increased biomass the most. Benzoate levels increased 203% with 3.6 g a.e. ha^?1 glyphosate. Salicylate content and tyrosine content were unaffected, whereas phenylalanine and tryptophan levels were increased by 60 and 80%, respectively, at 7.2 g a.e. ha^?1. Dose–response curves for these three amino acids were typical for hormesis. In another experiment that was replicated twice, soyabean plants were pre‐treated with low doses of glyphosate (1.8, 3.6 or 7.2 g a.e. ha^?1) and treated with a second application of glyphosate (1.8, 3.6, 7.2, 36, 180 or 720 g a.e. ha^?1) 14 days later. For total seedling dry weight, a 3.6 and 7.2 g a.e. ha^?1 glyphosate dose preconditioned the soyabean seedlings to have greater growth stimulation by a later glyphosate treatment than plants with no preconditioning glyphosate exposure. Optimal hormetic doses were generally higher with pre‐treated plants than plants that had not been exposed to glyphosate. Thus, pre‐exposure to low doses of glyphosate can change the hormetic response to later low‐dose exposures.  相似文献   

Characteristics of glyphosate inhibition of growth in soybean and tobacco callus cultures   总被引：1，自引：0，他引：1  

T. T. LEE 《Weed Research》1980,20(6):365-369

Callus cultures or tobacco (Nicotiana tabacum L. cv. While Gold and N. glauca-langsdorffii, a tumour-forming amphidiploid hybrid) and soybean Glycine max L., cv. Chippewa) were used lo study the effect of glyphosate [N-(phosphonnmethyl) glycine) un growth and interactions with growth hormones. Glyphosate inhibited growth both in the dark and light but showed a greater toxicity in the dark. This was contrary to its effect on chlorophyll degradation which was accelerated by light. The inhibition of growth was not reversed by simultaneous addition of aromatic amino acids to the medium. Thus the results suggest a multiple glyphosate action. The tobacco callus tissue was more sensitive to glyphosate than the soybean callus tissue, confirming a difference in tolerance between plant species. Despite the inhibitory effect of glyphosate. the treated tissue revived after being transferred to a glyphosate-free medium. The glyphosate-induced growth inhibition in soybean and tumour-forming tobacco callus cultures also was reversible by high levels of indole-3-acetic acid (IAA), which itself was inhibitory Theglyphosate-IAA interaction in the tissues which were sensitive to IAA suggests that the inhibition of growth by glyphosate was related to auxin levels in these tissues.  相似文献   

Evolved glyphosate-resistant weeds around the world: lessons to be learnt   总被引：2，自引：0，他引：2  

Powles SB 《Pest management science》2008,64(4):360-365

Glyphosate is the world's most important herbicide, with many uses that deliver effective and sustained control of a wide spectrum of unwanted (weedy) plant species. Until recently there were relatively few reports of weedy plant species evolving resistance to glyphosate. Since 1996, the advent and subsequent high adoption of transgenic glyphosate-resistant crops in the Americas has meant unprecedented and often exclusive use of glyphosate for weed control over very large areas. Consequently, in regions of the USA where transgenic glyphosate-resistant crops dominate, there are now evolved glyphosate-resistant populations of the economically damaging weed species Ambrosia artemissifolia L., Ambrosia trifida L., Amaranthus palmeri S Watson, Amaranthus rudis JD Sauer, Amaranthus tuberculatus (Moq) JD Sauer and various Conyza and Lolium spp. Likewise, in areas of transgenic glyphosate-resistant crops in Argentina and Brazil, there are now evolved glyphosate-resistant populations of Sorghum halepense (L.) Pers and Euphorbia heterophylla L. respectively. As transgenic glyphosate-resistant crops will remain very popular with producers, it is anticipated that glyphosate-resistant biotypes of other prominent weed species will evolve over the next few years. Therefore, evolved glyphosate-resistant weeds are a major risk for the continued success of glyphosate and transgenic glyphosate-resistant crops. However, glyphosate-resistant weeds are not yet a problem in many parts of the world, and lessons can be learnt and actions taken to achieve glyphosate sustainability. A major lesson is that maintenance of diversity in weed management systems is crucial for glyphosate to be sustainable. Glyphosate is essential for present and future world food production, and action to secure its sustainability for future generations is a global imperative.  相似文献   

Technical performance of some commercial glyphosate-resistant crops     

Pline-Srnic W 《Pest management science》2005,61(3):225-234

Glyphosate-resistant (GR) crops have been sold commercially in the USA since 1996. The use of glyphosate alone or with conventional pre- and post-emergence herbicides with different modes of action gives growers many options for affordable, safe, easy, effective wide-spectrum weed control. Despite the overwhelming popularity of this technology, technical issues have surfaced from time to time as US growers adopt these crops for use on their farms. The types of concern raised by growers vary from year to year depending on the crop and the environment, but include perceptions of increased sensitivity to diseases, increased fruit abortion, reduced pollination efficiency, increased sensitivity to environmental stress, and differences in yield and agronomic characteristics between transgenic and sister conventional varieties. Although several glyphosate-resistant crops are commercially available, maize, soybean and cotton constitute the largest cultivated acreage and have likewise been associated with the highest number of technical concerns. Because glyphosate is rapidly translocated to and accumulates in metabolic sink tissues, reproductive tissues and roots are particularly vulnerable. Increased sensitivity to glyphosate in reproductive tissues has been documented in both glyphosate-resistant cotton and maize, and results in reduced pollen production and viability, or increased fruit abortion. Glyphosate treatments have the potential to affect relationships between the GR crop, plant pathogens, plant pests and symbiotic micro-organisms, although management practices can also have a large impact. Despite these potential technical concerns, this technology remains popular, and is a highly useful tool for weed control in modern crop production.  相似文献   

Glyphosate-resistant weeds of South American cropping systems: an overview     

Vila-Aiub MM  Vidal RA  Balbi MC  Gundel PE  Trucco F  Ghersa CM 《Pest management science》2008,64(4):366-371

Herbicide resistance is an evolutionary event resulting from intense herbicide selection over genetically diverse weed populations. In South America, orchard, cereal and legume cropping systems show a strong dependence on glyphosate to control weeds. The goal of this report is to review the current knowledge on cases of evolved glyphosate-resistant weeds in South American agriculture. The first reports of glyphosate resistance include populations of highly diverse taxa (Lolium multiflorum Lam., Conyza bonariensis L., C. canadensis L.). In all instances, resistance evolution followed intense glyphosate use in fruit fields of Chile and Brazil. In fruit orchards from Colombia, Parthenium hysterophorus L. has shown the ability to withstand high glyphosate rates. The recent appearance of glyphosate-resistant Sorghum halepense L. and Euphorbia heterophylla L. in glyphosate-resistant soybean fields of Argentina and Brazil, respectively, is of major concern. The evolution of glyphosate resistance has clearly taken place in those agroecosystems where glyphosate exerts a strong and continuous selection pressure on weeds. The massive adoption of no-till practices together with the utilization of glyphosate-resistant soybean crops are factors encouraging increase in glyphosate use. This phenomenon has been more evident in Argentina and Brazil. The exclusive reliance on glyphosate as the main tool for weed management results in agroecosystems biologically more prone to glyphosate resistance evolution.  相似文献   

Glyphosate-resistant soybean as a weed management tool: Opportunities and challenges   总被引：3，自引：0，他引：3  

KRISHNA N. REDDY 《Weed Biology and Management》2001,1(4):193-202

Transgenic soybean, resistant to glyphosate, represents a revolutionary breakthrough in weed control technology. Transgenic soybean is the most dominant among all transgenic crops grown commercially in the world. In 2000, glyphosate-resistant (GR) soybean was planted to 25.8 million hectares globally, which amounts to 58% of the total global transgenic crop area. The United States soybean area planted with GR soybean has increased from 2% in 1996 to 68% in 2001. Glyphosate-resistant soybean as a weed management tool has provided farmers with the opportunity and flexibility to manage a broad spectrum of weeds. The use of glyphosate in GR soybean offers another alternative to manage weeds that are resistant to other herbicides. The rapid increase in GR soybean area is caused by the simplicity of using only one herbicide and a lower cost for weed control. Adoption of GR soybean has resulted in a dramatic decrease in the area treated with other herbicides. Glyphosphate-resistant soybean should not be relied on solely to the exclusion of other weed control methods, and should be used within integrated weed management systems. Over-reliance on GR soybean could lead to problems such as shifts in weed species and population, and the development of glyphosate-resistant weeds. The challenge is for soybean farmers to understand these problems, and for weed scientists to communicate with farmers that continuous use of glyphosate may diminish the opportunity of GR soybean as a weed management tool in the future.  相似文献   

转G2_EPSPS和GAT基因大豆栽培地生存竞争能力以及对节肢动物多样性的影响          下载免费PDF全文

赵宝广  曹宝祥  栾凤侠  陶波  李松宇  李荣兴  刘章雄 《中国生物防治学报》2020,36(6):954-962

转基因作物的全球快速发展，其对环境的安全性影响成为人们关注的热点。我国转基因大豆的发展还处于试验研究阶段，对转基因大豆环境安全性进行科学严谨评价是我国转基因大豆商业发展的有力支撑，具有非常重要的理论和实践生产意义。本研究以转G2_EPSPS和GAT双价基因抗草甘膦大豆材料GE-J16与受体材料Jack以及当地主栽品种中黄37为研究对象。采用田间栽培试验，比较其生长时期的竞争能力以及成熟期繁育和生存能力的差异，研究了转基因和非转基因大豆栽培环境生存竞争安全性；连续3年调查供试大豆品种田间节肢动物的种类与数量，分析其多样性指数、优势集中性指数、均匀性指数的动态变化，明确转基因和非转基大豆以及草甘膦除草剂对豆田节肢动物群落多样性的影响。试验结果显示，不同生育时期的3个大豆品种的株高、复叶数、田间覆盖度、繁育系数和落粒性都基本一致无差异显著性，无栽培地生存竞争优势；转基因大豆GE-J16人工除草、转基因大豆GE-J16喷施草甘膦和非转基因大豆Jack人工除草三个处理3年的节肢动物的多样性指数、均匀性指数、优势集中性指数变化趋势一致，且3个处理同一生育时期之间各指标无显著性差异，说明耐草甘膦转基因大豆以及草甘膦除草剂并不会引起豆田节肢动物群落多样性的明显变化。  相似文献   

Integrating soil conservation practices and glyphosate-resistant crops: impacts on soil     

Locke MA  Zablotowicz RM  Reddy KN 《Pest management science》2008,64(4):457-469

BACKGROUND: Conservation practices often associated with glyphosate-resistant crops, e.g. limited tillage and crop cover, improve soil conditions, but only limited research has evaluated their effects on soil in combination with glyphosate-resistant crops. It is assumed that conservation practices have similar benefits to soil whether or not glyphosate-resistant crops are used. This paper reviews the impact on soil of conservation practices and glyphosate-resistant crops, and presents data from a Mississippi field trial comparing glyphosate-resistant and non-glyphosate-resistant maize (Zea mays L.) and cotton (Gossypium hirsutum L.) under limited tillage management. RESULTS: Results from the reduced-tillage study indicate differences in soil biological and chemical properties owing to glyphosate-resistant crops. Under continuous glyphosate-resistant maize, soils maintained greater soil organic carbon and nitrogen as compared with continuous non-glyphosate-resistant maize, but no differences were measured in continuous cotton or in cotton rotated with maize. Soil microbial community structure based on total fatty acid methyl ester analysis indicated a significant effect of glyphosate-resistant crop following 5 years of continuous glyphosate-resistant crop as compared with the non-glyphosate-resistant crop system. Results from this study, as well as the literature review, indicate differences attributable to the interaction of conservation practices and glyphosate-resistant crop, but many are transient and benign for the soil ecosystem. CONCLUSIONS: Glyphosate use may result in minor effects on soil biological/chemical properties. However, enhanced organic carbon and plant residues in surface soils under conservation practices may buffer potential effects of glyphosate. Long-term field research established under various cropping systems and ecological regions is needed for critical assessment of glyphosate-resistant crop and conservation practice interactions.  相似文献   

Can glyphosate stimulate photosynthesis?     

Nina Cedergreen  Charlotte F. Olesen 《Pesticide biochemistry and physiology》2010,96(3):140-148

Gas-exchange and biomass growth was measured on barley plants sprayed with glyphosate in order to investigate what might cause the growth increase observed in low dose glyphosate treated plants. Gas-exchange over 7 days after spraying was measured together with photosynthesis/irradiance and photosynthesis/CO₂ curves. In addition, growth experiments at 100, 200, 400 and 800 ppm CO₂ were conducted. Dark respiration rates increased in response to the glyphosate treatment, but so did photosynthesis at doses of 11-45 g a.e. ha⁻¹. The increase in photosynthetic rates was mainly due to an increased efficiency of CO₂ fixation under irradiance and CO₂ saturated conditions. The photosynthesis measurements were confirmed by the growth experiments, where glyphosate growth stimulations were observed only at 400 and 800 ppm CO₂. It can, hence, be concluded that low glyphosate doses can stimulate photosynthesis, though the causes behind this increase is still not understood.  相似文献   

The control of Asian rust by glyphosate in glyphosate-resistant soybeans     

Feng PC  Clark C  Andrade GC  Balbi MC  Caldwell P 《Pest management science》2008,64(4):353-359

BACKGROUND: Glyphosate is a widely used broad-spectrum herbicide. Recent studies in glyphosate-resistant (GR) crops have shown that, in addition to its herbicidal activity, glyphosate exhibits activity against fungi, thereby providing disease control benefits. In GR wheat, glyphosate has shown both preventive and curative activities against Puccinia striiformis f. sp. tritici (Erikss) CO Johnston and Puccinia triticina Erikss, which cause stripe and leaf rusts respectively. RESULTS: Laboratory studies confirmed earlier observations that glyphosate has activity against Phakopsora pachyrhizi Syd & P Syd which causes Asian soybean rust (ASR) in GR soybeans. The results showed that glyphosate at rates between 0.84 and 1.68 kg ha(-1) delayed the onset of ASR in GR soybeans. However, field trials conducted in Argentina and Brazil under natural infestations showed variable ASR control from application of glyphosate in GR soybeans. Further field studies are ongoing to define the activity of glyphosate against ASR. CONCLUSIONS: These results demonstrate the disease control activities of glyphosate against rust diseases in GR wheat and GR soybeans.  相似文献   

草甘膦水剂在抗草甘膦转基因大豆田除草效果及安全性研究     

曹洪玉  李香菊  刘士阳  崔海兰  牛宏波 《杂草科学》2011,29(3):22-25

采用田间试验,研究了41%草甘膦水剂在抗草甘膦转基因大豆田使用的除草效果和抗草甘膦大豆的安全性。结果表明,41%草甘膦水剂对大豆田主要杂草马唐、反枝苋和铁苋菜等均有理想防效,药后30 d,41%草甘膦水剂1 537.5 g a.i./hm2剂量下对大豆田杂草防效达90%以上。41%草甘膦水剂对4种抗除草剂大豆材料（356043、87701RR2Y、06-698和07-1568）安全性较好,在922.5～2 460.0 g a.i./hm2剂量范围内,上述大豆材料无药害症状,其株高、复叶数、每荚粒数及百粒重均没有降低。与不用药对照相比,上述材料施用41%草甘膦水剂后增产显著。  相似文献   

Sustainable use of glyphosate in North American cropping systems     

Gustafson DI 《Pest management science》2008,64(4):409-416

Roundup Ready (glyphosate-resistant) cropping systems enable the use of glyphosate, a non-selective herbicide that offers growers several benefits, including superior weed control, flexibility in weed control timing and economic advantages. The rapid adoption of such crops in North America has resulted in greater glyphosate use and concern over the potential for weed resistance to erode the sustainability of its efficacy. Computer modeling is one method that can be used to explore the sustainability of glyphosate when used in glyphosate-resistant cropping systems. Field tests should help strengthen the assumptions on which the models are based, and have been initiated for this purpose. Empirical evaluations of published data show that glyphosate-resistant weeds have an appearance rate of 0.007, defined as the number of newly resistant species per million acres treated, which ranks low among herbicides used in North America. Modeling calculations and ongoing field tests support a practical recommendation for growers occasionally to include other herbicides in glyphosate-resistant cropping systems, to lower further the potential for new resistance to occur. The presented data suggest that the sustainability of glyphosate in North America would be enhanced by prudent use of additional herbicides in glyphosate-resistant cropping systems.  相似文献   

Monitoring glyphosate residues in transgenic glyphosate-resistant soybean     

Arregui MC  Lenardón A  Sanchez D  Maitre MI  Scotta R  Enrique S 《Pest management science》2004,60(2):163-166

The availability of Roundup Ready (RR) varieties of soybean has increased the use of glyphosate for weed control in Argentina. Glyphosate [(N-phosphonomethyl)glycine] is employed for the eradication of previous crop vegetation and for weed control during the soybean growing cycle. Its action is effective, and low environmental impact has been reported so far. No residues have been observed in soil or water, either of glyphosate or its metabolite, AMPA (aminomethylphosphonic acid). The objective of this work was to monitor glyphosate and AMPA residues in soybean plants and grains in field crops in Santa Fe Province, Argentina. Five sites were monitored in 1997, 1998 and 1999. Individual soybean plants were sampled from emergence to harvest, dried and ground. Analysis consisted in residue extraction with organic solvents and buffers, agitation, centrifugation, clean-up and HPLC with UV detection. In soybean leaves and stems, glyphosate residues ranged from 1.9 to 4.4 mg kg(-1) and from 0.1 to 1.8 mg kg(-1) in grains. Higher concentrations were detected when glyphosate was sprayed several times during the crop cycle, and when treatments approached the flowering stage. AMPA residues were also detected in leaves and in grains, indicating metabolism of the herbicide.  相似文献   

Glyphosate-resistant crops: history, status and future   总被引：16，自引：0，他引：16  

Dill GM 《Pest management science》2005,61(3):219-224

The commercial launch of glyphosate-resistant soybeans in 1996 signaled the beginning of a new era in weed management in row crops. Today, over 80% of the soybeans grown in the USA are glyphosate resistant. Since that time, many crops have been transformed that have allowed crop applications of many classes of herbicide chemistries. Crops currently under production include maize, soybean, cotton and canola. Transformation technology and selection methods have improved and the rate of development as well as the breadth of crops being considered as commercial targets has increased. On the basis of recent adoption rates by growers around the world, it appears that glyphosate-resistant crops will continue to grow in number and in hectares planted. However, global public acceptance of biotechnology-derived products will continue to impact the rate of adoption of this and other new innovations derived from transformation technology.  相似文献   

The benefits of herbicide-resistant crops     

JM Green 《Pest management science》2012,68(10):1323-1331

Since 1996, genetically modified herbicide-resistant crops, primarily glyphosate-resistant soybean, corn, cotton and canola, have helped to revolutionize weed management and have become an important tool in crop production practices. Glyphosate-resistant crops have enabled the implementation of weed management practices that have improved yield and profitability while better protecting the environment. Growers have recognized their benefits and have made glyphosate-resistant crops the most rapidly adopted technology in the history of agriculture. Weed management systems with glyphosate-resistant crops have often relied on glyphosate alone, have been easy to use and have been effective, economical and more environmentally friendly than the systems they have replaced. Glyphosate has worked extremely well in controlling weeds in glyphosate-resistant crops for more than a decade, but some key weeds have evolved resistance, and using glyphosate alone has proved unsustainable. Now, growers need to renew their weed management practices and use glyphosate with other cultural, mechanical and herbicide options in integrated systems. New multiple-herbicide-resistant crops with resistance to glyphosate and other herbicides will expand the utility of existing herbicide technologies and will be an important component of future weed management systems that help to sustain the current benefits of high-efficiency and high-production agriculture. Copyright © 2012 Society of Chemical Industry  相似文献   

Molecular identification of weedy glyphosate-resistant Lolium (Poaceae) in California     

A M SHERWOOD  & M JASIENIUK 《Weed Research》2009,49(4):354-364

The origins of invasive weed populations can involve multiple species, introductions and genotypes. In California, USA, self-incompatible (SI) Lolium species are highly successful agricultural weeds. During the last decade, resistance to glyphosate has evolved in California populations of Lolium . However, the species identity of glyphosate-resistant populations is unclear. Occurrence of three SI species, L. multiflorum , L. rigidum and L. perenne , and the lack of reproductive barriers between them, suggests that any or all species may be contributing to resistant populations. To elucidate the identity and evolutionary history of resistant Lolium , we assessed genetic variation of known species and unknown California individuals using five simple sequence repeat loci, a nuclear DNA sequence and a chloroplast DNA sequence. Employing two analytical approaches, we identified three major genetic groups within the accessions of SI species that were similar, but not identical, to the taxonomic species identities. California glyphosate-resistant and susceptible plants were most closely related to the L. multiflorum group. However, a few glyphosate-resistant plants and a third of the glyphosate-susceptible plants also identified with L. rigidum and L. perenne . While L. rigidum and L. perenne contribute to invasive populations within California, the majority of glyphosate-resistant individuals tested were L. multiflorum .  相似文献   

草甘膦对七种作物的安全性     

杨洪李  黄红娟  王兆振  武传志  姜晓龙  张朝贤  张连洪 《植物保护》2022,48(2):220-226

本文对草甘膦喷施土壤后对作物的安全性进行了初步研究。采用室内盆栽的方法,测定了不同剂量的35%草甘膦水剂在壤土和砂土条件下对小麦Triticum aestivum L.、玉米Zea mays L.、大豆Glycine max(L.) Merr.、甘蓝Brassica oleracea var.capitata L.、小白菜Brassica pekinensis L.、番茄Lycopersicon esculentum L.和茄子Solanum melongena L.等7种作物的叶色、叶长、叶宽、植株鲜重和光合作用等生长、生理指标的影响。研究结果表明：在标签剂量(1 575 g/hm~2)下施用于壤土时,草甘膦对茄子的叶长和叶宽影响显著,对其他6种作物的各测定指标未产生显著影响;在砂土条件使用时,除对小麦和茄子的叶色、番茄的叶宽、小白菜和番茄的鲜重方面有显著影响外,对玉米、大豆和甘蓝都安全。在2倍标签剂量(3 150 g/hm~2)下,在壤土和砂土条件下使用时,除对茄子在叶色、叶长、叶宽和鲜重4个指标都有显著影响外,对番茄的光合效率也有显著影响,同时对其他作物的其他指标也有不同的影响,...  相似文献   

Glyphosate-resistant crops: adoption, use and future considerations   总被引：6，自引：0，他引：6  

Dill GM  Cajacob CA  Padgette SR 《Pest management science》2008,64(4):326-331

BACKGROUND: Glyphosate-resistant crops (GRCs) were first introduced in the United States in soybeans in 1996. Adoption has been very rapid in soybeans and cotton since introduction and has grown significantly in maize in recent years. GRCs have grown to over 74 million hectares in five crop species in 13 countries. The intent of this paper is to update the hectares planted and the use patterns of GRC globally, and to discuss briefly future applications and uses of the technology. RESULTS: The largest land areas of GRCs are occupied by soybean (54.2 million ha), maize (13.2 million ha), cotton (5.1 million ha), canola (2.3 million ha) and alfalfa (0.1 million ha). Currently, the USA, Argentina, Brazil and Canada have the largest plantings of GRCs. Herbicide use patterns would indicate that over 50% of glyphosate-resistant (GR) maize hectares and 70% of GR cotton hectares receive alternative mode-of-action treatments, while approximately 25% of GR soybeans receive such a treatment in the USA. Alternative herbicide use is likely driven by both agronomic need and herbicide resistance limitations in certain GR crops such as current GR cotton. Tillage practices in the USA indicate that > 65% of GR maize hectares, 70% of GR cotton hectares and 50% of GR soybean hectares received some tillage in the production system. Tillage was likely used for multiple purposes ranging from seed-bed preparation to weed management. CONCLUSION: GRCs represent one of the more rapidly adopted weed management technologies in recent history. Current use patterns would indicate that GRCs will likely continue to be a popular weed management choice that may also include the use of other herbicides to complement glyphosate. Stacking with other biotechnology traits will also give farmers the benefits and convenience of multiple pest control and quality trait technologies within a single seed.  相似文献   

Herbicides can stimulate plant growth     

N CEDERGREEN 《Weed Research》2008,48(5):429-438

Low dose stimulations by toxicants have long been observed. Great controversies exist concerning the interpretation of these observations, spanning from believing that they are a general stress response occurring for all chemicals, to simply being an experimental artefact resulting from poorly growing control plants or from biomass allocation between plant parts. This study investigates the growth response and biomass allocation pattern of barley exposed to 10–15 doses of eight different herbicides. The results show that the globally most widely used herbicide, glyphosate, together with the sulfonylurea, metsulfuron‐methyl, can induce a real stimulation in biomass growth of approximately 25% when applied at doses corresponding to 5–10% field rate. The other six herbicides tested did not induce consistent hormesis, thereby undermining the theory of hormesis being a general stress response. Biomass allocations between plant parts did take place, but were not the cause of the hormetic growth stimulations. The results demonstrate that plant physiological responses to low herbicide doses cannot be extrapolated from our knowledge of effects of higher, commercially used, doses. Other physiological mechanisms seem to be triggered in the low dose‐range, and the investigation of these mechanisms poses new challenges for agronomists, environmentalists and plant physiologists.  相似文献   

Phytotoxic activity of root absorbed glyphosate in corn seedlings (Zea mays L.)     

RODRIGO WAGNER  MARCELO KOGAN  ANA M. PARADA 《Weed Biology and Management》2003,3(4):228-232

Growth chamber experiments were conducted in order to study the absorption, translocation and activity of glyphosate when applied to roots with aqueous solution avoiding any glyphosate–substrate interaction. Corn seedlings at the first leaf stage were set up in individual graduated cylinders containing different solutions of ¹⁴C-glyphosate (0–30 mg ae kg⁻¹). After 26 h of root exposure, plants were transferred to fresh nutrient solution and grown for the next 5 days. After harvest, plants were separated into seed, root, mesocotyle, coleoptile, cotyledon, first leaf and all new leaves (apex), and quantified ¹⁴C radioactivity contained in each part. Glyphosate uptake was only 11% of the theoretical mass flow into the plant. The amount of glyphosate translocated from roots was positively correlated with plant uptake ( P  < 0.01). Total plant fresh weight presented a logistic response to glyphosate amounts, including a growth stimulant effect (hormesis), when plants absorbed less than 0.6 µg. The treated plants presented a normal pattern of glyphosate allocation, with the apex the principal sink, accumulating more than 38% of mobilized glyphosate. When corn plants absorbed more than 0.6 µg they showed a decrease in growth. The relatively high glyphosate quantities allocated in the new leaves showed the relevance of the symplastic pathway in the translocation process for root absorbed glyphosate.  相似文献