Endocrine and neuroendocrine effects of Azadirachtin in adult females of the earwig Labidura riparia

Azadirachtin directly or indirectly affects the abundance of intestinal flora of Spodoptera litura and the energy conversion of intestinal contents mediates the energy balance of intestine-brain axis, and along with decreased expression CREB in the brain neurons

Azadirachtin is a good growth inhibitor for Lepidopteran larvae, but its effect on the brain neurons, intestinal flora and intestinal contents caused by the growth inhibition mechanism has not been reported yet. This study explored the mechanism of azadirachtin on the growth and development of Spodoptera litura larvae and brain neurons through three aspects: intestinal pathology observation, intestinal flora sequencing, and intestinal content analysis. The results showed that the treatment of azadirachtin led to the pathological changes in the structure of the midgut and the goblet cells in the intestinal wall cells to undergo apoptosis. Changes in the host environment of the intestinal flora lead to changes in the abundance value of the intestinal flora, showing an increase in the abundance value of harmful bacteria such as Sphingomonas and Enterococcus, as well as an increase in the abundance value of excellent flora such as Lactobacillus and Bifidobacterium. Changes in the abundance of intestinal flora will result in changes in intestinal contents and metabolites. The test results show that after azadirachtin treatment, the alkane compounds in the intestinal contents of the larvae are greatly reduced, and the number of the long carbon chain and multi-branched hydrocarbon compounds is increased, unsaturated fatty acids, silicon‑oxygen compounds and ethers. The production of similar substances indicates that azadirachtin has an inhibitory effect on digestive enzymes in the intestines, which results in the inhibition of substance absorption and energy transmission, and ultimately the inhibition of larval growth and brain neurons.

Interaction of azadirachtin with the lipid-binding domain: Suppression of lipid transportation in the silkworm, Bombyx mori

This study investigates the effects of the insect growth regulator azadirachtin on lipid transportation to the ovary of the silkworm, Bombyx mori. Lipids are hydrophobic in nature and require a carrier for circulation in the blood. Protein-lipid interactions play a vital role in lipid transport, thereby keeping the system balanced. In general, lipids bind to lipoproteins in a specific region called the lipid-binding domain (LBD). In this study, B. mori apolipophorin amino acid sequences were retrieved from NCBI and the LBD was identified. The LBD structure was predicted by (PS)² and validated in ProSA. The LBD structure was docked with DMPC, POPC and sphingomyelin by SwissDock, each binding with GLN 171, ASN 162, and ASN 160 and 162, respectively. Interestingly, azadirachtin binds with ASN 160 and 162 and GLN 171, which shows that lipids and azadirachtin are binding with the same amino acid residues in the LBD. Later, this result was confirmed with wet lab work using a fluorescent phospholipid probe. Azadirachtin binding with the LBD was indirectly proportional to the fluorescent lipid binding. These results suggest that azadirachtin binds with the LBD instead of the lipids and interrupts the protein-lipid interaction, leading to the suppression of lipid transportation to the ovary.

Azadirachtin Affects the Growth of Spodoptera litura Fabricius by Inducing Apoptosis in Larval Midgut

Azadirachtin, the environmentally friendly botanical pesticide, has been used as an antifeedant and pest growth regulator in integrated pest management for decades. It has shown strong biological activity against Spodoptera litura, but the mechanism of toxicity remains unclear. The present study showed that azadirachtin inhibited the growth of S. litura larvae, which was resulted by structure destroy and size inhibition of the midgut. Digital gene expression (DGE) analysis of midgut suggested that azadirachtin regulated the transcriptional level of multiple unigenes involved in mitogen-activated protein kinase (MAPK) and calcium apoptotic signaling pathways. Simultaneously, the expression patterns of some differentially expressed unigenes were verified by quantitative real time-PCR (qRT-PCR). In addition, the enhanced terminal deoxynucleotidyl transferase biotin-dUTP nick end labeling (TUNEL) staining, the increased expression of caspase family members and apoptosis-binding motif 1 (IBM1) on both gene and protein level and the release of cytochrome c from mitochondria to cytoplasm were induced in midgut after azadirachtin treatment. These results demonstrated that azadirachtin induced structural alteration in S. litura larval midgut by apoptosis activation. These alterations may affect the digestion and absorption of nutrients and eventually lead to the growth inhibition of larvae.

Biopesticide-induced behavioral and morphological alterations in the stingless bee Melipona quadrifasciata

Because of their natural origin, biopesticides are assumed to be less harmful to beneficial insects, including bees, and therefore their use has been widely encouraged for crop protection. There is little evidence, however, to support this ingrained notion of biopesticide safety to pollinators. Because larval exposure is still largely unexplored in ecotoxicology and risk assessment on bees, an investigation was performed on the lethal and sublethal effects of a diet treated with 2 bioinsecticides, azadirachtin and spinosad, on the stingless bee, Melipona quadrifasciata, which is one of the most important pollinators in the Neotropics. Survival of stingless bee larvae was significantly compromised at doses above 210 ng a.i./bee for azadirachtin and 114 ng a.i./bee for spinosad. No sublethal effect was observed on larvae developmental time, but doses of both compounds negatively affected pupal body mass. Azadirachtin produced deformed pupae and adults as a result of its insect growth regulator properties, but spinosad was more harmful and produced greater numbers of deformed individuals. Only spinosad compromised walking activity of the adult workers at doses as low as 2.29 ng a.i./bee, which is 1/5000 of the maximum field recommended rate. In conclusion, the results demonstrated that bioinsecticides can pose significant risks to native pollinators with lethal and sublethal effects; future investigations are needed on the likelihood of such effects under field conditions.

Lethal and sublethal effects of azadirachtin on the bumblebee Bombus terrestris (Hymenoptera: Apidae)

Azadirachtin is a biorational insecticide commonly reported as selective to a range of beneficial insects. Nonetheless, only few studies have been carried out with pollinators, usually emphasizing the honeybee Apis mellifera and neglecting other important pollinator species such as the bumblebee Bombus terrestris. Here, lethal and sublethal effects of azadirachtin were studied on B. terrestris via oral exposure in the laboratory to bring out the potential risks of the compound to this important pollinator. The compound was tested at different concentrations above and below the maximum concentration that is used in the field (32 mg L(-1)). As most important results, azadirachtin repelled bumblebee workers in a concentration-dependent manner. The median repellence concentration (RC50) was estimated as 504 mg L(-1). Microcolonies chronically exposed to azadirachtin via treated sugar water during 11 weeks in the laboratory exhibited a high mortality ranging from 32 to 100 % with a range of concentrations between 3.2 and 320 mg L(-1). Moreover, no reproduction was scored when concentrations were higher than 3.2 mg L(-1). At 3.2 mg L(-1), azadirachtin significantly inhibited the egg-laying and, consequently, the production of drones during 6 weeks. Ovarian length decreased with the increase of the azadirachtin concentration. When azadirachtin was tested under an experimental setup in the laboratory where bumblebees need to forage for food, the sublethal effects were stronger as the numbers of drones were reduced already with a concentration of 0.64 mg L(-1). Besides, a negative correlation was found between the body mass of male offspring and azadirachtin concentration. In conclusion, our results as performed in the laboratory demonstrated that azadirachtin can affect B. terrestris with a range of sublethal effects. Taking into account that sublethal effects are as important as lethal effects for the development and survival of the colonies of B. terrestris, this study confirms the need to test compounds on their safety, especially when they have to perform complex tasks such as foraging. The latter agrees with the recent European Food Safety Authority guidelines to assess 'potentially deleterious' compounds for sublethal effects on behavior.

Resistance to bio-insecticides or how to enhance their sustainability: a review

After more than 70 years of chemical pesticide use, modern agriculture is increasingly using biological control products. Resistances to conventional insecticides are wide spread, while those to bio-insecticides have raised less attention, and resistance management is frequently neglected. However, a good knowledge of the limitations of a new technique often provides greater sustainability. In this review, we compile cases of resistance to widely used bio-insecticides and describe the associated resistance mechanisms. This overview shows that all widely used bio-insecticides ultimately select resistant individuals. For example, at least 27 species of insects have been described as resistant to Bacillus thuringiensis toxins. The resistance mechanisms are at least as diverse as those that are involved in resistance to chemical insecticides, some of them being common to bio-insecticides and chemical insecticides. This analysis highlights the specific properties of bio-insecticides that the scientific community should use to provide a better sustainability of these products.

Neuroendocrine disruption: more than hormones are upset

Only a small proportion of the published research on endocrine-disrupting chemicals (EDC) directly examined effects on neuroendocrine processes. There is an expanding body of evidence that anthropogenic chemicals exert effects on neuroendocrine systems and that these changes might impact peripheral organ systems and physiological processes. Neuroendocrine disruption extends the concept of endocrine disruption to include the full breadth of integrative physiology (i.e., more than hormones are upset). Pollutants may also disrupt numerous other neurochemical pathways to affect an animal's capacity to reproduce, develop and grow, or deal with stress and other challenges. Several examples are presented in this review, from both vertebrates and invertebrates, illustrating that diverse environmental pollutants including pharmaceuticals, organochlorine pesticides, and industrial contaminants have the potential to disrupt neuroendocrine control mechanisms. While most investigations on EDC are carried out with vertebrate models, an attempt is also made to highlight the importance of research on invertebrate neuroendocrine disruption. The neurophysiology of many invertebrates is well described and many of their neurotransmitters are similar or identical to those in vertebrates; therefore, lessons learned from one group of organisms may help us understand potential adverse effects in others. This review argues for the adoption of systems biology and integrative physiology to address the effects of EDC. Effects of pulp and paper mill effluents on fish reproduction are a good example of where relatively narrow hypothesis testing strategies (e.g., whether or not pollutants are sex steroid mimics) have only partially solved a major problem in environmental biology. It is clear that a global, integrative physiological approach, including improved understanding of neuroendocrine control mechanisms, is warranted to fully understand the impacts of pulp and paper mill effluents. Neuroendocrine disruptors are defined as pollutants in the environment that are capable of acting as agonists/antagonists or modulators of the synthesis and/or metabolism of neuropeptides, neurotransmitters, or neurohormones, which subsequently alter diverse physiological, behavioral, or hormonal processes to affect an animal's capacity to reproduce, develop and grow, or deal with stress and other challenges. By adopting a definition of neuroendocrine disruption that encompasses both direct physiological targets and their indirect downstream effects, from the level of the individual to the ecosystem, a more comprehensive picture of the consequences of environmentally relevant EDC exposure may emerge.

TOXICIDADE DE ÓLEO DE NIM PARA PUPAS E ADULTOS DE CHRYSOPERLA EXTERNA (HAGEN) (NEUROPTERA: CHRYSOPIDAE)

RESUMO O objetivo do presente trabalho foi avaliar os efeitos do Nim-I-Go® sobre pupas e adultos de Chrysoperla externa (Hagen) (Neuroptera: Chrysopidae). As concentrações (%) do Nim-I-Go® utilizadas no experimento com pupas foram as seguintes: 0,5; 1,0; 2,0 e 5,0; correspondendo a (mg de azadirachtina/L de água) 5 mg/L, 10 mg/L, 20 mg/L e 50 mg/L, respectivamente. No experimento com adultos foram utilizadas as seguintes concentrações: 0,25; 0,5; 0,75; 1,0 e 2,0; correspondendo a (mg de azadirachtina/L) 2,5 mg/L, 5,0 mg/L, 7,5 mg/L, 10 mg/L e 20 mg/L, respectivamente. Clorpirifós foi utilizado como testemunha negativa (0,48 g i.a./L) nos dois experimentos e água como testemunha positiva. Os bioensaios foram conduzidos a 25 ± 2 o C, UR de 70 ± 10% e fotofase de 12 horas. As pulverizações foram realizadas por meio de torre de Potter com aplicação de 1,5 ± 0,5 mg de calda química/cm2. Avaliaram-se a viabilidade dos ovos, a sobrevivência de pupas e adultos e o efeito dos inseticidas sobre a capacidade reprodutiva dos indivíduos. A toxicidade foi calculada em função do efeito total (E), conforme metodologia padrão estabelecida pela “IOBC”. Nim-I-Go® nas diversas concentrações foi inócuo a pupas e adultos do predador. Clorpirifós foi nocivo para pupas e adultos de C. externa.

Identification of a putative azadirachtin-binding complex from Drosophila Kc167 cells

Cell-proliferation in Drosophila Kc167 cells was inhibited by 50% when cell cultures contained 1.7 x 10(-7) M azadirachtin for 48 h (a tertranortriterpenoid from the neem tree Azadirachta indica). Drosophila Kc167 cells exhibited direct nuclear damage within 6-h exposure to azadirachtin (5 x 10(-7) M and above) or within 24 h when lower concentrations were used (1 x 10(-9) M). Fractionation of an extract of Drosophila Kc167 cells combined with ligand overlay technique resulted in the identification of a putative azadirachtin binding complex. Identification of the members of this complex by Peptide Mass Fingerprinting (PMF) and N-terminal sequencing identified heat shock protein 60 (hsp60) as one of its components.

Alterations in acetylcholinesterase and electrical activity in the nervous system of cockroach exposed to the neem derivative, azadirachtin

Botanical insecticides are relatively safe and biodegradable, and are readily available sources of bioinsecticides. In recent years, the neem derivative, azadirachtin, has been examined as an alternative to synthetic insecticides because of its broad-spectrum insecticidal action. Because many of the natural products and synthetic compounds used in the control of insect pests are known to exhibit electrophysiological effects, in this paper we focused our studies on the alterations in the activity of the enzyme acetylcholinesterase (AChE) and electrical activity in the nervous system of the cockroach, Periplaneta americana, exposed to azadirachtin. Exposure to azadirachtin produced an excitatory effect on spontaneous electrical activity as well as cercal sensory-mediated giant-fiber responses in the cockroach. Topical exposure to sublethal doses of azadirachtin did not result in any significant alterations in the AChE activity in different regions of the nervous system. We suggest that azadirachtin exerts excitatory action on the electrical activity in the nervous system of cockroach by interfering with the ion channels in the nerve membrane, the probable target of several insecticides.

The antimitotic effect of the neem terpenoid azadirachtin on cultured insect cells

When cultured insect cells (Sf9) were grown in the presence of 5 x 10(-6) M azadirachtin, there was a rapid increase in the mitotic index, with the appearance of many aberrant mitotic figures. Flow cytometry established that cells accumulated in the G2/M phase of the cell cycle, and that the effect was concentration-dependent. At 10(-8) M a period of 20 h was necessary to raise the proportion in G2/M to 42% above the control values, but at 5 x 10(-6) M more than 90% of the cells were in this phase. Azadirachtin had the same effect on C6/36 mosquito cells, but failed to affect L929 murine fibroblast cells even at a concentration of 10(-4) M over 72 h. Experiments with colchcine and taxol showed similarities of action between azadirachtin and colchicine, and azadirachtin was apparently able to displace colchicine-fluorescein from binding-sites in living insect cells. Another similarity between azdirachtin and colchicine was that both phytochemicals prevented the polymerisatrion in vitro of mammalian tubulin, although the azadirachtin was much less effective.

Ultrastructural changes in the corpus allatum after azadirachtin and 20-hydroxyecdysone treatment in adult females of Labidura riparia (Dermaptera)

In previous reports, we have shown that the injection of azadirachtin (AZA) as well as 20-hydroxyecdysone (20E) into vitellogenic females of Labidura riparia induces inhibition of vitellogenin synthesis and ovarian development. Juvenile hormone (JH) treatment rescues vitellogenin synthesis and ovarian growth (Sayah et al., 1995, 1996). In this work, we have studied ultrastructural changes of corpus allatum (CA) after injection of 200, 400, and 600 ng of 20E or 1, 3, and 5 microg of AZA. CA cells exhibit signs of inactivity in both AZA and females treated with 20E at doses of 3 microg and 400 ng, respectively. Conspicuous cytological effects consisting of multivesicular bodies with dense contents, abnormally large intercellular spaces comprising myelinic structures, and rare smooth endoplasmic reticula occurred in cytoplasm of CA glandular cells in both experimental females. However, the CA ultrastructure of females injected with 20E differs from CA cells of females injected with AZA in having a cytoplasm containing numerous electron-lucent intracellular areas and marked glycogen zones. They also differ in having abundant microtubules and well-developed junctional membranes. At a dose of 600 ng of 20E or 5 microg of AZA, the intensity of the cytotoxic effects is more apparent. CA cells display pycnotic nuclei, spherical mitochondria, large multivesicular bodies, and vacuolization of the cytoplasm. These results are discussed and compared with observations made on other insect species.

Azadirachtin potentiates the action of ecdysteroid agonist RH-2485 in Spodoptera littoralis

Edysteroid agonist RH-2485 induces an immediate and fatal molt in Spodoptera littoralis when added to the diet of the 2nd and 4th instar larvae at 1 ppm, and to that of the 6th instar larvae at 0.001 ppm concentration. Ten times lower doses fed to the larvae continuously allow an apparently normal larval development that is terminated by a supernumerary larval molt. The other effects of RH-2485 include death during metamorphosis and impaired fertility of emerged adults. The number of progeny is reduced even with low RH-2485 doses that do not interfere with moltings; e.g., insects fed 0.0001 ppm since the 2nd, 4th, and 6th instar produce 72%, 62%, and 22%, respectively, less progeny than the controls. Feeding larvae with 10-1000 ppm Suneem oil (containing about 0.1-10 ppm azadirachtin) causes, in a stage- and dose-dependent manner, a cessation or reduction of feeding, delay of molts, death of larvae and pupae, and sterility of emerged adults; with 10 ppm Suneem oil, the number of progeny is reduced by 20-32%. Presence of Suneem oil in the diet does not influence the potential of RH-2485 to induce a prompt molt, but it increases ten times the potency to elicit a supernumerary larval molt. Certain combinations of RH-2485 with Suneem oil provoke up to 3 extra larval molts. Lethal developmental derangements and sterility are more frequent, and the response of larvae of different age is more uniform, when Suneem oil and RH-2485 are combined than when each of these agents is administered alone.

Extracellular and intracellular actions of azadirachtin on the electrophysiological properties of cultured rat DRG neurones

The distinct electrophysiological actions of extracellular and intracellular azadirachtin (type A) were investigated using cultured dorsal root ganglion neurones from neonatal rats and the whole cell variant of the patch clamp technique. The cultured mammalian neurones were relatively insensitive to azadirachtin compared with some invertebrate preparations, such as insect chemosensory systems. Insect preparations have been found to respond to 1-100 nM azadirachtin. However, at concentrations of azadirachtin between 10 and 100 microM significant changes in the electrophysiological properties of cultured DRG neurones were seen. Extracellular application of azadirachtin prolonged the late repolarization phase of evoked action potentials and consistent with this produced modulation of voltage-activated K+ currents. This modulation involved an initial transient increase in K+ current followed by reversible inhibition when azadirachtin was applied at a concentration of 10 microM. Higher concentrations of azadirachtin (50 and 100 microM), had only inhibitory effects on voltage-activated K+ currents. Azadirachtin produced a degree of voltage-dependent inhibition, with a greater level of K+ current inhibition observed when neurones were held at -90 mV compared with -40 mV. Prolonged application of azadirachtin for 24 h reversibly reduced action potential amplitude. In contrast intracellular application of 100 microM azadirachtin via the patch pipette solution had no significant effects on action potentials but produced an increase in conductance. Intracellular azadirachtin activated several conductances including a TEA-sensitive K + current and an inward current that had an estimated reversal potential close to 0 mV. In conclusion, data showed that azadirachtin had different effects when it was applied inside and outside the neurones and that azadirachtin at high concentrations reversibly altered neuronal excitability mainly by modulating potassium conductances. It appears that rat cultured DRG neurones are less affected by azadirachtin than some insect sensory systems.