Insecticidal Effect of Labramin, a Lectin—Like Protein Isolated from Seeds of the Beach Apricot Tree,<i>Labramia bojeri</i>, on the Mediterranean Flour Moth,<i>Ephestia kuehniella</i>

Martinez, Diego Stéfani T.; Freire, Maria das Graças Machado; Mazzafera, Paulo; Júnior, Roberto T. Araujo; Bueno, Regiane Cristina Oliveira de Freitas; Macedo, Maria Lígia Rodrigues

doi:10.1673/031.012.6201

Cited by 20 publications

(14 citation statements)

References 38 publications

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“…Martinez et al (2012) also generated similar results from the evaluation of the insecticidal potential of a lectin-like protein (labramin) in Ephestia kuehniella. Similar growth patterns in the presence of toxic compounds have been obtained in insects (Farrar et al, 1989;Weeler and Isman, 2001).…”

Section: Discussionmentioning

confidence: 55%

Status of Insecticide Resistance in Field-collected Populations of Rhynchophorus ferrugineus (Olivier) (Coleoptera: Curculionidae)

Al-Ayedh¹,

Hussain²,

Rizwan-ul-Haq³

et al. 2015

IJAB

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To cite this paper: Al-Ayedh, H., A. Hussain, M. Rizwan-ul-Haq and A.M. Al-Jabr, 2016. Status of insecticide resistance in field-collected populations of Rhynchophorus ferrugineus (Olivier) (Coleoptera: Curculionidae AbstractThe first monitoring of the resistance to two organophosphates (methidathion and ethion) and one pyrethroid (cypermethrin) insecticides presented by three field collections of different Rhynchophorus ferrugineus (Olivier) populations was performed in this study. The LD50 doses of three insecticides against newly moulted eighth-instar R. ferrugineus larvae were estimated through toxicity bioassays, in which the larvae were fed on artificial diet supplemented with different individual doses of cypermethrin, methidathion or ethion. A population of R. ferrugineus collected from Wadi Ad-Dawasir was chosen as the reference strain, because of its susceptibility to each of the tested insecticide. Compared with the susceptible strain, populations sampled from Al-Ahsa and Al-Qatif showed 8.72 and 4.51-folds increase in resistance to cypermethrin and 3.77 and 2.85-fold increases in resistance to ethion, respectively. The LD50 values of cypermethrin (1.62 ppm), methidathion (3.15 ppm) and ethion (9.12 ppm) in the susceptible population (Wadi Ad-Dawasir) were used to investigate the feeding performances and physiological impacts on eighth-instar R. ferrugineus larvae. The larvae showed no resistance to the most potent insecticide (methidathion) resulting highest growth reduction. However, moderate resistance was observed from red palm weevil population collected from Al-Qatif and Al-Ahsa against cypermethrin resulting lowest reduction in the efficacy of conversion of ingested food (ECI) and digested food (ECD). In addition, glutathione-S-transferase (GST) activity assay further strengthen our findings. Results suggest that enhanced GST activity likely contributes to cypermethrin and ethion resistance exhibited by the R. ferrugineus populations sampled from Al-Qatif and Al-Ahsa. Toxicity bioassays, dietary utilization experiments and GST assays examined in this study support the use of methidathion against R. ferrugineus as the most potent insecticide against all the sampled populations. However, cypermethrin and ethion resistance appears to be evolving in the R. ferrugineus populations from Al-Qatif and Al-Ahsa, justifying the concern of farmers regarding the low efficacy of insecticides.

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Section: Discussionmentioning

confidence: 55%

Status of Insecticide Resistance in Field-collected Populations of Rhynchophorus ferrugineus (Olivier) (Coleoptera: Curculionidae)

Al-Ayedh¹,

Hussain²,

Rizwan-ul-Haq³

et al. 2015

IJAB

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“…These unique functions of the PM, as well as its accessibility, make it an attractive target for pest control strategies. It is also believed that alterations to the PM inhibit infection (Kelkenberg, Odman‐Naresh, Muthukrishnan, & Merzendorfer, ; Martinez et al, ). These research results were in agreement with the PM functioning analogously to the vertebrate intestinal mucosa layer (Zhang et al, ).…”

Section: Introductionmentioning

confidence: 99%

Identification and characterization of two novel peritrophic membrane (PM) genes in the Chinese mitten crab Eriocheir sinensis that exhibit activity against high-pH stress and Aeromonas hydrophila challenge

et al. 2018

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The peritrophic membrane (PM) is located in the gut of most insects and protects them from invasion by pathogens or toxins ingested during feeding. Peritrophins are a principal component of the PM and contribute to the structure and function of the PM. The PM has also been observed in the gastrointestinal tract of the Chinese mitten crab (Eriocheir sinensis). In this study, full‐length cDNA sequences of two PM genes from E. sinensis were obtained, namely, Es‐peritrophin1 and Es‐peritrophin2, which were 855 bp and 1,611 bp respectively. The deduced proteins were composed of 267 and 468 amino acids and contained 3 and 1 chitin binding domains respectively. Both Es‐peritrophin1 and Es‐peritrophin2 contained a signal peptide sequence at the N terminus, indicating that both proteins were secretory proteins. Phylogenetic analysis revealed that Es‐peritrophin1 and Es‐peritrophin2 were divided into the CPAP3‐B and CPAP1‐H branches respectively. Nevertheless, sequence alignment demonstrated that they had lower homology to other known PMs, indicating they were two novel peritrophins. Quantitative real‐time PCR (qRT‐PCR) analysis showed that both the Es‐peritrophin1 and Es‐peritrophin2 transcript levels were high in the stomach and hindgut and lower in the midgut, indicating that the PM might be assembled locally in E. sinensis. The expression of Es‐peritrophin1 and Es‐peritrophin2 was downregulated by high‐pH stress and Aeromonas hydrophila challenge in the examined tissues except in the hindgut, where the expression of both genes was upregulated by A. hydrophila challenge. These results indicated that Es‐peritrophin1 and Es‐peritrophin2 are two novel peritrophin genes related to immune defence in E. sinensis.

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“…They bind reversibly to specific mono-and oligosaccharides and thus affect digestion through binding to food glycoproteins, polysaccharides (chitin) of the peritrophic membrane, or directly to digestive enzymes. Both increased (Martinez et al, 2012) and decreased (Coelho et al, 2007;Ramzi et al, 2013) trypsin activity have been recorded in the gut of insects fed on lectin-containing diets. Unadapted insects also exhibit increased trypsin activity in feces pointing to impaired function of the peritrophic membrane and recycling mechanism for trypsin (Coelho et al, 2007;Martinez et al, 2012).…”

Section: Adjusting Trypsin Activity To Plant Defensesmentioning

confidence: 99%

“…Both increased (Martinez et al, 2012) and decreased (Coelho et al, 2007;Ramzi et al, 2013) trypsin activity have been recorded in the gut of insects fed on lectin-containing diets. Unadapted insects also exhibit increased trypsin activity in feces pointing to impaired function of the peritrophic membrane and recycling mechanism for trypsin (Coelho et al, 2007;Martinez et al, 2012). On the other hand, in resistant insects, lectins are more sensitive to proteolytic degradation or have low ligand-binding ability (Coelho et al, 2007).…”

Section: Adjusting Trypsin Activity To Plant Defensesmentioning

confidence: 99%

Dietary and phylogenetic correlates of digestive trypsin activity in insect pests

Lazarević

Janković-Tomanić

2015

Entomologia Exp Applicata

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Because food proteins are crucial for insect survival, growth, and fecundity, enzymes involved in their digestion have attracted the attention of fundamental entomologists studying the mechanisms and patterns of dietary specialization, and applied entomologists searching for more efficient modes of pest control. Most insects digest proteins using trypsin, an endopeptidase that cleaves polypeptide chains on the carboxyl side of arginine and lysine, two basic amino acids. As the most ancestral proteinase, trypsin is wide-spread in the digestive tract of insects from various orders and with various feeding habits. The present review focuses on biochemical and molecular characteristics, mechanisms of regulation, and adaptive/non-adaptive changes of trypsin activity in response to heterogeneous food environments in a phylogenetic context. Within-and among-species variations in trypsin structure and regulation that contribute to better matching with specific food types are emphasized. We also discuss the relevance of these data for choosing an appropriate strategy for control of insect pests. Pest control strategies to reduce trypsin activity by interfering with substrate binding or trypsin synthesis and secretion have been suggested. Successful application of these procedures requires a multidisciplinary approach and knowledge about digestive physiology of the pest, as well as the structural characteristics of trypsins that determine their interaction with proteinaceous inhibitors and other food compounds, about patterns of developmental changes in trypsin gene expression, adaptive responses of insects to food composition, and various environmental effects on trypsin activity.

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Insecticidal Effect of Labramin, a Lectin—Like Protein Isolated from Seeds of the Beach Apricot Tree,Labramia bojeri, on the Mediterranean Flour Moth,Ephestia kuehniella

Cited by 20 publications

References 38 publications

Status of Insecticide Resistance in Field-collected Populations of Rhynchophorus ferrugineus (Olivier) (Coleoptera: Curculionidae)

Status of Insecticide Resistance in Field-collected Populations of Rhynchophorus ferrugineus (Olivier) (Coleoptera: Curculionidae)

Identification and characterization of two novel peritrophic membrane (PM) genes in the Chinese mitten crab Eriocheir sinensis that exhibit activity against high-pH stress and Aeromonas hydrophila challenge

Dietary and phylogenetic correlates of digestive trypsin activity in insect pests

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