Effect of different herbicides on Bidens pilosa and Euphorbia heterophylla biotypes resistant to ALS inhibitors

Select herbicides with different mechanism of action is a satisfactory option for resistant weed control. Then, the present work aimed to study the efficiency of different herbicides and their mixtures on Bidens pilosa (blackjack) and Euphorbia heterophylla (wild poinsettia) biotypes, resistant to ALS herbicides in two development stages. The trials we arranged in a completely randomized design with four replications. The treatments tested were (g a.i/a.e ha-1): imazethapyr at 70 and 140 (WG formulation) + 1.0% Assist; imazethapyr at 57.6 and 72 (SL formulation) + 1.0% Assist; imazapic + imazethapyr at 56 and 70 + 1.0% Assist; glyphosate + imazethapyr (596); saflufenacil + glyphosate at 35 + 720 + 0.5% Dash in tank mix, glyphosate at 720 and, a control without herbicide application. Control efficiency was evaluated, as well as dry matter accumulation at the end of the studies. Plants of both species were more susceptible to herbicides at the early stage of development (2 to 4 leaves). The treatments with saflufenacil + glyphosate, (imazethapyr + glyphosate) and glyphosate promoted the best controls, regardless of the species studied and the application stage. The mixture with saflufenacil provided the highest control speed, and the mixture (imazethapyr + glyphosate) was less efficient among three excellent treatments when applied to plants in the 4-6 leaf stage. The treatments (imazethapyr, in both formulations) and (imazethapyr + imazapic) were ineffective in controlling the studied biotypes, regardless of dose and developmental stage studied.

Effects of monosulfuron-ester on metabolic processes of nitrogen-fixing cyanobacteria Anabaena flos-aquae and Anabaena azotica

Abstract Presence of the relatively new sulfonylurea herbicide monosulfuron-ester at 0.03-300 nmol/L affected the growth of two non-target nitrogen-fixing cyanobacteria (Anabaena flos-aquae and Anabaena azotica) and substantially inhibited in vitro Acetolactate synthase activity, with IC50 of 3.3 and 101.3 nmol/L for A. flos-aquae and A. azotica, respectively. Presenting in 30-300 nmol/L, it inhibited protein synthesis of the cyanobacteria with less amino acids produced as its concentration increased. Our findings support the view that monosulfuron-ester toxicity in both nitrogen-fixing cyanobacteria is due to its interference with protein metabolism via inhibition of branch-chain amino acid biosynthesis, and particularly Acetolactate synthase activity.

Characterization of the acetohydroxyacid synthase multigene family in the tetraploide plant Chenopodium quinoa

Background Currently, the technology called Clearfield® is used in the development of crops resistant to herbicides that inhibit the enzyme acetohydroxy acid synthase (AHAS, EC 2.2.1.6). AHAS is the first enzyme of the biosynthetic pathway that produces the branched-chain of the essential amino acids valine, leucine, and isoleucine. Therefore, multiple copies of the AHAS gene might be of interest for breeding programs targeting herbicide resistance. In this work, the characterization of the AHAS gene was accomplished for the Chenopodium quinoa Regalona-Baer cultivar. Cloning, sequencing, and Southern blotting were conducted to determine the number of gene copies. Results The presence of multiple copies of the AHAS gene as has been shown previously in several other species is described. Six copies of the AHAS gene were confirmed with Southern blot analyses. CqHAS1 and CqAHAS2 variants showed the highest homology with AHAS mRNA sequences found in the NR Database. A third copy, CqAHAS3, shared similar fragments with both CqAHAS1 and CqAHAS2, suggesting duplication through homeologous chromosomes pairing. Conclusions The presence of multiple copies of the gene AHAS shows that gene duplication is a common feature in polyploid species during evolution. In addition, to our knowledge, this is the first report of the interaction of sub-genomes in quinoa.

Propriedades enzimáticas da enzima ALS de Cyperus difformis e mecanismo de resistência da espécie ao herbicida pyrazosulfuron-ethyl / Enzymatic properties of Cyperus difformis ALS enzyme and mechanism resistance of the species to pyrazosulfuron-ethyl herbicide

Cyperus difformis L. é uma planta daninha ocorrente em lavouras de arroz irrigado, que tem apresentado dificuldade de controle devido à resistência a herbicidas inibidores da enzima ALS. Os objetivos deste trabalho foram investigar características cinéticas da enzima ALS de biótipos de C. difformis e determinar as bases bioquímicas da resistência da espécie ao herbicida pyrazosulfuron-ethyl. Para isso, foram conduzidos experimentos em laboratório do BIOAGRO/UFV. O método utilizado baseou-se na metologia utilizada por CAREY et al. (1997) e adaptada por VARGAS et al. (1999), com algumas modificações. Foram avaliadas a concentração de substrato (piruvato) que fornece velocidade inicial igual à metade da velocidade máxima de reação (K M) e velocidade máxima de reação (Vmáx), bem como a atividade da enzima ALS na presença do inibidor (pyrazosulfuron-ethyl). Diante dos resultados, pode-se observar que a resistência de C. difformis a pyrazosulfuron-ethyl é decorrente da insensibilidade da enzima ALS ao herbicida, não acarretando, porém, prejuízo aos parâmetros cinéticos K M e Vmáx da enzima ALS.

Cyperus difformis L. is a weed that occurs in flooded rice, which has presented difficulty in controlling due to the resistance to ALS inhibiting herbicides. The objectives of this research were to investigate kinetic characteristics of ALS enzyme from C. difformis biotypes and to determine the biochemical bases of resistance from the species to pyrazosulfuron-ethyl herbicide. For that, experiments were conducted at the BIOAGRO/UFV laboratory. The method used was based on the methodology used by CAREY et al. (1997) and adapted by VARGAS et al. (1999), with some modifications. It was evaluated substratum concentration (pyruvate) that provides initial velocity equal to half the speed reaction (K M) and maximum velocity of reaction (Vmáx), as well the activity of the ALS enzyme in the presence of the inhibitor (pyrazosulfuron-ethyl). According to the results, it is possible to observe that C. difformis resistance to pyrazosulfuron-ethyl is due to the insensibility of the ALS enzyme to the herbicide, however without penalty to K M and Vmáx kinetic parameters of the ALS enzyme.

Isolamento do gene ALS e investigação do mecanismo de resistência a herbicidas em Sagittaria montevidensis / Isolation of the ALS gene and investigation of the mechanism of herbicide resistance in Sagittaria montevidensis

Diversos biótipos de sagitária (Sagittaria montevidensis Cham. & Schlecht) foram constatados como resistentes a herbicidas inibidores da enzima ALS no Brasil e em outros locais do mundo. Os objetivos deste trabalho foram isolar e sequenciar o gene ALS de sagitária de forma a identificar a ocorrência de mutações relacionadas ao mecanismo de resistência de insensibilidade do local da ação de herbicidas. O material vegetal consistiu de sementes de sagitária coletadas em lavouras de arroz irrigado localizadas na região Sul do Estado de Santa Catarina. Nove pares de sequências nucleotídicas iniciadoras foram desenhadas para a amplificação dos domínios C, A e D do gene ALS. As sequências nucleotídicas dos fragmentos amplificados com quatro pares de oligonucleotídeos inciadores resultaram em amplicons com 360 a 393 nucleotídeos. Essas sequências apresentaram homologia com o gene ALS padrão de Arabdopsis thaliana e arroz, possuindo apenas três mutações de ponto. Uma dessas alterações foi a mutação Pro197Phe, que é relacionada à ocorrência de resistência à herbicida em diversas espécies vegetais. As sequências obtidas evidenciaram que o gene ALS avaliado encontrava-se em heterozigose. Esses resultados sugerem a ocorrência de insensibilidade do local de ação como mecanismo de resistência a herbicidas inibidores de ALS em sagitária. A prevenção e o controle da resistência a herbicidas inibidores da ALS em sagitária devem ser fundamentados na rotação de herbicidas com diferentes mecanismos de ação.

California arrowhead (Sagittaria montevidensis Cham. & Schlecht) is an aquatic weed often found in rice paddy fields. Several biotypes of California arrowhead resistant to ALS-inhibiting herbicides were found in Brazil and in several rice fields worldwide. The objective of this study was to sequence the ALS gene of California arrowhead and to identify the occurrence of mutations related to target site insensitivity as the mechanism of herbicide resistance. The plant material consisted of seeds collected in rice paddy fields located in the state of Santa Catarina, Brazil. Nine pairs of primers were designed for the amplification of the domains C, A and D of the ALS gene. PCR reactions with four pairs of primers resulted in amplification of fragments with size close to expected, ranging from 360 to 393 nucleotides. These sequences showed high homology to the standard ALS gene Arabdopsis thaliana and rice having only three point mutations. One of these mutations was Pro197Phe that is related with herbicide resistance in several weeds. The sequences obtained indicated that the ALS gene evaluated was heterozygous. These results suggest the occurrence of insensitivity of the site of action as the mechanism of resistance to ALS-inhibitors herbicides in California arrowhead. The prevention and control of resistance to ALS-inhibitors in California arrowhead should be based on the rotation of herbicides with different mechanisms of action.