Estudo, por modelagem molecular, da inibição da enzima acetohidroxiácido sintase utilizando diferentes derivados pirimidinilsalicilatos

Silva, Viviane Aparecida

31 March 2017

CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Herbicides inhibitors of the enzyme acetohydroxyacid synthase (AHAS) present high efficiency in the inhibitory activity with low doses of application and low toxicity for man and the environment. However, several weeds are getting resistence to some classes of herbicides, mainly in the case of AHAS group. Therefore, a proper computational planning of new bioactive compounds is crucial area to model new herbicides. In this study, the enzyme-herbicide interactions were analyzed from the analogous derivated of the pyrimidinylsalicylates group (PSA) which are AHAS inhibitors using quantum- mechanical and molecular docking calculations. The molecular properties obtained after running computer calculation shown that the volume and molecular area can make influence on the inhibition capacity of the ligand, neverthenless, the substituent group has more influence on this parameter. Electronical properties from the HOMO orbitals can certanly make influence on the biological activity due its electron donor capability. The binding free energies of the ligand on the enzyme after docking calculation ranged from - 1.88 to 4.50 kcal mol- 1 , whereas, H, CH3, COCH3 , OH, NO2 and NH2 had the best scored binding energies as substituent groups. Those favorable binding free energies can be justified by the intermolecular interactions between PSAs ligands and AHAS active site residues. In terms of effiency, hydrogen bonds formation can be explained by carboxylate group from the ligands and ARG-377 group from AHAS. / Os herbicidas inibidores da enzima acetohidroxiácido sintase (AHAS) apresentam alta eficiência na atividade inibitória com baixas doses de aplicação com baixa toxicidade para o homem e o meio ambiente. No entanto, várias ervas daninhas estão obtendo resistência a algumas classes de herbicidas, principalmente no caso do grupo AHAS. Portanto, um planejamento computacional adequado de novos compostos bioativos é área crucial para modelar novos herbicidas. Neste estudo, as interações enzima-herbicida foram analisadas a partir do derivado análogo do grupo pirimidinilsalicilato (PSA) que são inibidores de AHAS usando cálculos mecânicoquânticos e de docking molecular. As propriedades moleculares obtidas mostraram que o volume e a área molecular podem influenciar a capacidade de inibição do ligante, mesmo que o grupo substituinte tenha mais influência sobre este parâmetro. As propriedades eletrônicas dos orbitais HOMO podem certamente influenciar a atividade biológica devido à sua capacidade de doação de elétrons. As energias livres de ligação do ligante na enzima após o cálculo de docking variaram de -1,88 a - 4,50 kcal mol- 1 , enquanto que H, CH3, COCH3, OH, NO2 e NH2 apresentaram as melhores energias de ligação pontuadas como grupos substituintes. Estas energias livres de ligação favoráveis podem ser justificadas pelas interações intermoleculares entre ligantes de PSAs e resíduos de sítio ativo de AHAS. Em termos de eficiência, a formação de ligações de hidrogênio pode ser explicada pelo grupo carboxilato partir dos ligantes e do grupo ARG-377 de AHAS. / Dissertação (Mestrado)

Herbicidas

Herbicides

Pirimidinilsalicilatos (PSA)

Pyrimidinylsalicylates (PSA)

Enzima AHAS

AHAS enzyme

Docking molecular

Molecular Docking

Interações Moleculares

Molecular Interactions

Cell selection, characterization and regeneration of chlorsulfuron-resistant variants in asparagus

Ganeshan, Dharshini

January 1999

This thesis reports the cell culture establishment and a somatic cell selection system optimized for the isolation of chlorsulfuron-resistant variants in asparagus (Asparagus officinalis L.). The development of this cell selection system benefited the isolation of chlorsulfuron-resistant variants from an elite asparagus genotype. A cell culture system, suitable for somatic cell selection, was established for asparagus genotype CRD 168. Friable callus was initiated from etiolated shoots in darkness and used to produce a high density of single cells in suspension. Cell density was estimated based on a linear relationship with settled cell volume. A mean plating efficiency of 0.19 % was recorded between 1-4x10⁵ cells/Petri dish. In vitro cell selection techniques were developed to identify mutant asparagus cells with resistance to a sulfonylurea herbicide, chlorsulfuron. A few key aspects were important to achieve this: a cell culture system for cell selection was initially established; a toxic concentration for the complete growth inhibition of the wild type asparagus cells was defined; rare, resistant cell colonies were isolated and characterized; and chlorsulfuron-resistant plants were regenerated. From about 50 million cells, 165 cell colonies were isolated in the presence of 8 nM chlorsulfuron. Characterization of these selected cell colonies yielded 24 escapes, 98 unstable variants, and 43 stable-resistant variants. Callus cultures from 34 of these stable variants retained resistance following 11 months growth in the absence of the selection agent. Plants were regenerated from 36 of these stable herbicide-resistant variants. Six of these chlorsulfuron-resistant variants were screened for their degree of resistance to chlorsulfuron, cross resistance to other acetohydroxyacid synthase (AHAS) inhibiting herbicides and AHAS enzyme activity. Cross resistance to imazamox was evident in four of the resistant variants, while lack of cross resistance to metsulfuron methyl was observed in all six resistant variants. A varying degree of resistance to chlorsulfuron was observed among the resistant variants. Both in the original and secondary callus, an uninhibited AHAS enzyme activity in all six resistant variants was recorded in the presence of high chlorsulfuron concentration (70-140 nM), compared to the total inhibition in the wild type. One chlorsulfuron-resistant variant, R-45, was used to compare the biochemical and physiological basis of resistance with the wild type. The AHAS enzyme activity in the tissue culture and greenhouse foliage of R-45 was significantly higher in the presence of up to 280 nM chlorsulfuron compared with the wild type. Chlorsulfuron retention was considerably higher due to the reduction of epicuticular wax deposits on the foliage of R-45, in comparison with the wild type. Consequently, the resistant line absorbed at least 1.6 fold more chlorsulfuron than the wild type plants. Therefore, foliar application of 15 g a.i./ha Glean (commercial formulation of chlorsulfuron) produced typical symptoms of chlorosis in R-45, similar to the wild type, in the greenhouse plants. Somatic cell selection was carried out using two elite asparagus genotypes, CRD 74 and Clone X. Of the 33 rare cell colonies isolated from Clone X, 22 unstable variants and 6 escapes were discarded. All five remaining resistant variants produced plants. One of the stable-resistant variants (Clone X-24) was evaluated for resistance to chlorsulfuron. Both in vitro shoot cultures and greenhouse-grown plants of Clone X-24 showed increased resistance to chlorsulfuron compared with the wild type. The AHAS enzyme activity in the foliar extracts also showed the presence of higher enzyme activity in Clone X-24.

AHAS enzyme

AHAS inhibitors

Asparagus officinalis L.

cell culture

cell plating

chlorsulfuron

cross resistance

elite genotypes

herbicide resistance

resistant variants

somatic cell selection

sulfonylurea

0601 - Biochemistry and Cell Biology