Jeffrey R. Bloomquist

Expression of a gene encoding a scorpion insectotoxin peptide in yeast, bacteria and plants

The nucleotide sequence encoding the scorpion insectotoxin I5A was chemically synthesized and expressed in yeast, bacteria and tobacco. The I5A peptides produced in these organisms were purified using an immunoaffinity chromatography procedure. I5A produced using the bacterial secretion system was efficiently secreted and released into the culture medium. In contrast, only a trace amount of I5A was detected in bacterial cytosols when expressed from a direct expression vector, suggesting that I5A was unstable in bacterial cells. I5A secreted from yeast using an alpha-factor signal sequence was shown to have an N-terminal (Glu-Ala)2 extension, indicating incomplete processing of the secreted peptide by dipeptidyl aminopeptidase A. In tobacco, a nonsecreted form of the protein was produced. No measurable insect toxicity was observed when insect larvae were assayed, regardless of whether I5A was produced in yeast, bacteria or tobacco. The lack of toxicity is almost certainly the result of improper folding due to incorrect disulfide bond formation. The inability to produce a biologically active peptide must be overcome before scorpion toxins might be used for the genetic engineering of plants for insect resistance. The yeast and bacterial expression systems described here may be useful for further studies on the problem of expressing a biologically active peptide.

Molecular Mechanisms of Insecticide Resistance

Four decades of intensive use of synthetic organic insecticides to control arthropod pests and disease vectors have led to the selection of insecticide or acaricide resistance in approximately 450 arthropod species (Georghiou 1986). In the most extreme cases, such as the Colorado potato beetle (Leptinotarsa decemlineata) in parts of the eastern United States, populations are resistant to virtually all chemicals available for control (Forgash 1984). The deleterious consequences of pesticide resistance in arthropods include increased levels of environmental contamination and risks of applicator and agricultural worker exposure from higher rates of pesticide application; increases in pest control costs; disruption of ecologically sound pest control strategies; increased incidence of human, animal, and plant diseases in which transmission depends on insect vectors; and, in the most extreme case, the complete destruction of agricultural production systems on a local or regional basis.

Striatal Dopaminergic Pathways as a Target for the Insecticides Permethrin and Chlorpyrifos

Because insecticide exposure has been linked to both Parkinsons disease and Gulf War illness, the neurotoxic actions of pyrethroid and organophosphate insecticides on behavior and striatal dopaminergic pathways were investigated in C57BL/6 mice treated with permethrin (three i.p. doses at 0.2-200 mg/kg) or chlorpyrifos (three s.c. doses at 25-100 mg/kg) over a 2-week period. Permethrin altered maximal [3H]dopamine uptake in striatal synaptosomes from treated mice, with changes in Vmax displaying a bell-shaped curve. Uptake was increased to 134% of control at a dose of 1.5 mg/kg. At higher doses of PM (25 mg/kg), dopamine uptake declined to a level significantly below that of control (50% of control at 200 mg/kg, P < 0.01). We also observed a small, but statistically significant decrease in [3H]dopamine uptake by chlorpyrifos, when given at a dose of 100 mg/kg. There was no significant effect on the Km for dopamine transport. Evidence of cell stress was observed in measures of mitochondrialfunction, which were reduced in mice given high-end doses of chlorpyrifos and permethrin. Although cytotoxicity was not reflected in decreased levels of striatal dopamine in either 200 mg/kg PM or 100 mg/kg CPF treatment groups, an increase in dopamine turnover at 100 mg/kg CPF was indicated by a significant increase in titers of the dopamine metabolite, 3,4-dihydroxyphenylacetic acid. Both permethrin and chlorpyrifos caused a decrease in open field behavior at the highest doses tested. Although frank Parkinsonism was not observed, these findings confirm that dopaminergic neurotransmission is affected by exposure to pyrethroid and organophosphorus insecticides, and may contribute to the overall spectrum of neurotoxicity caused by these compounds.

Effects of haloperidol metabolites on neurotransmitter uptake and release: possible role in neurotoxicity and tardive dyskinesia

This research explored the effects of haloperidol (HP) metabolites on biogenic amine uptake and release, and compared them to those of MPTP and its toxic metabolite, MPP+. In synaptosome preparations from mouse striatum and cortex, the HP metabolites haloperidol pyridinium (HPP+), reduced haloperidol pyridinium (RHPP+), and haloperidol tetrahydropyridine (HPTP) inhibited the presynaptic uptake of dopamine and serotonin, with greater affinity for the serotonin transporter. HPP+ was the most potent inhibitor of dopamine uptake, and HPTP of serotonin uptake, both with IC50 values in the low micromolar range. RHPP+ was less active than the other metabolites, but was more active than the parent compound, HP. Inhibition of uptake was reversed when free drug was removed by centrifugation and then resuspension of the synaptosomes in fresh buffer, suggesting that inhibition of uptake was due to interaction with the transporters and was not due to irreversible cytotoxicity. HPP+ showed noncompetitive inhibition of both serotonin and dopamine uptake, suggesting that it has a relatively slow dissociation rate for its interaction with the transporter proteins. In experiments on amine release, HPP+ and HPTP were four-fold less potent than MPP+ for releasing preloaded dopamine from striatal synaptosomes, and only MPP+-dependent release was antagonized by the uptake blocker, mazindol. In contrast, RHPP+ displayed little ability to release either amine neurotransmitter. HPTP was about two-fold more potent than MPP+ for releasing serotonin from cortical synaptosomes, whereas HPP+ was less active than MPP+. The specific serotonin transport blocker fluoxetine was only able to antagonize release induced by MPP+. These results suggest that HP metabolites bind to the transporters for dopamine and serotonin, but are not transporter substrates. In contrast to their potent effects on amine release, HPP+ and HPTP were unable to release preloaded GABA from cortical synaptosomes. The implications of these results concerning a possible role of HP metabolites in the development of tardive dyskinesia are discussed.

Toxicology, mode of action and target site-mediated resistance to insecticides acting on chloride channels

1. The discovery that the avermectins and cyclodienes affected the chloride channels of excitable membranes generated intense research interest among academic and industrial scientists. 2. The results of biochemical and neurophysiological studies indicate that the gamma-aminobutyric acid (GABA)-gated chloride channel is an important, if not the primary site of action for these compounds. 3. The action of insecticides on the functional properties of the GABA receptor differs by structural class. The cyclodienes block the chloride ion channel and the avermectins activate it. 4. Blockage of the GABA-gated chloride channel by cyclodienes reduces neuronal inhibition, which leads to hyper-excitation of the central nervous system, convulsions, and death. For avermectins, activation of the channel suppresses neuronal activity, resulting in ataxia, paralysis and death. Although actions on the GABA-gated chloride channel can explain many of the effects of these compounds, there is evidence supporting the participation of other ligand- and voltage-gated chloride channels in the overall intoxication process. This consideration is especially true for the avermectins. 5. Several structural series of experimental insecticides have been synthesized which possess a blocking action on the GABA-gated chloride channel similar to that of the cyclodienes. 6. Resistance to cyclodienes usually occurs through an altered target site, and extends to all experimental compounds that block chloride channels. However, the resistance does not afford protection against the avermectins. 7. The continued search for new insecticides directed against chloride channels may lead to compounds with less environmental impact and greater selectivity than that of the cyclodienes. Given the pre-selection for resistance by the cyclodienes, new compounds with a similar mode of action must be used judiciously in order to suppress or delay the re-emergence of widespread resistance.

Selective Effects of Insecticides on Nigrostriatal Dopaminergic Nerve Pathways

A degeneration of the nigrostriatal pathway is a primary component of Parkinsons disease (PD), and we have investigated the actions of insecticides on this pathway. For in vivo exposures, C57BL/6 mice were treated three times over a 2-week period with heptachlor, the pyrethroids deltamethrin and permethrin, or chlorpyrifos. One day after the last treatment, we observed that heptachlor and the pyrethroids increased maximal [3H]dopamine uptake in striatal synaptosomes from treated mice, with dose-dependent changes in Vmax displaying a bell-shaped curve. Western blot analysis confirmed increased levels of dopamine transporter (DAT) protein in the striatum of mice treated with heptachlor and permethrin. In contrast, we observed a small, but statistically significant decrease in dopamine uptake by 100 mg/kg chlorpyrifos. For heptachlor, doses that upregulated DAT expression had little or no effect on serotonin transport. Permethrin did cause an upregulation of serotonin transport, but required a 30-fold greater dose than that effective on dopamine uptake. Other evidence of specificity was found in transmitter release assays, where heptachlor and deltamethrin released dopamine from striatal terminals with greater potency than other transmitter types. These findings confirm that insecticides possess specificity for effects on striatal dopaminergic neurotransmission.

GABA and Glutamate Receptors as Biochemical Sites for Insecticide Action

The γ-aminobutyric acid (GABA) receptor/chloride ionophore complex has been the focus of intense interest by industrial and academic scientists as a site of insecticide action (Bloomquist 1993). This receptor was initially exploited as a site of action for commercial insecticides over 40 years ago by the polychlorocycloalkane compounds (e.g., cyclodienes, toxaphene, and lindane), although the suggestion that they might be disrupting GABA receptor function was not advanced until 1982 (Ghiasuddin and Matsumura 1982). This hypothesis was roughly contemporaneous with the discovery of the avermectins, which were originally hypothesized to affect GABA-gated chloride channels, but now are thought to mainly affect the glutamate-gated chloride channel of invertebrate muscle (Rohrer and Arena 1995).

Differential up-regulation of striatal dopamine transporter and α-synuclein by the pyrethroid insecticide permethrin

The effects of permethrin on striatal dopaminergic biomarkers were assessed in this study. Retired breeder male C57 B1/6 mice were given an ip dose of permethrin (0.1-200 mg/kg) at 7-day intervals, over a 2-week period (Days 0, 7, and 14). Animals were then sacrificed 1 day (t = 1), 14 days (t = 14), or 28 days after the last treatment (t = 28). Dopamine transporter (DAT) protein as assayed by Western blotting was increased to 115% in the 0.8 mg/kg group over that of control mice at t = 1 (P < 0.05). At t = 14, this value increased to 140% of control, and declined slightly to 133% of control at t = 28. The mice given the 1.5 mg/kg dose displayed a significant increase in DAT protein only at t = 28, to 145% of controls. Thus, upregulation of the DAT at low doses of PM is variable 24 h after treatment, and seems to stabilize by t = 28. The threshold dose for increasing DAT expression in Western blots by t = 28 was 0.2 mg/kg permethrin. [(3)H]GBR 12935, used to assay DAT binding, followed the same trend as that for the Western blotting data for 0.8 and 1.5 mg/kg doses of permethrin over the 4 weeks posttreatment. At 200 mg/kg permethrin, DAT protein was unchanged vs controls (t = 1), but had significantly increased by t = 14 and continued to increase at t = 28, suggesting that the reduced dopamine transport at this dose was due to nerve terminal stress and that recovery had occurred. The protein alpha-synuclein was also significantly induced at the 1.5 mg/kg dose at t = 1; however, unlike DAT up-regulation, this effect had declined to control values by t = 14. Maximal induction of alpha-synuclein protein occurred at a dose of 50 mg/kg permethrin. These data provide evidence that the pyrethroid class of insecticides can modulate the dopaminergic system at low doses, in a persistent manner, which may render neurons more vulnerable to toxicant injury.

NOVEL INSECTICIDAL PEPTIDES FROM TEGENARIA AGRESTIS SPIDER VENOM MAY HAVE A DIRECT EFFECT ON THE INSECT CENTRAL NERVOUS SYSTEM

Fractionation of venom from an agelenid spider, Tegenaria agrestis, resulted in the isolation of a family of three peptides with potent insecticidal activity. These peptide toxins, TaITX-1, -2, and -3, whose sequences were revealed from cloned cDNAs, each consist of 50 amino acid residues, six of which are cysteines. They appear to be amidated at their C-termini and exhibit greater than 90% sequence identity. Unlike other reported spider toxins, the TaI toxins are processed from precursors containing no propeptide sequences. In lepidopteran larvae and corn rootworm beetles, the insecticidal Tegenaria toxins caused an unusual excitatory symptomatology with 50% paralytic doses ranging from 0.23 to 2.6 nmol/g. In a series of electrophysiological experiments performed in house fly larvae, these toxins caused an elevated rate of firing from central nervous system neurons. No significant effects were found when any peripheral sensory or motor systems were examined. Thus, it appears that the TaI toxins may act in a fashion not previously reported for insecticidal peptide toxins; they may act directly on the insect central nervous system.

Chemical control of the Asian citrus psyllid and of huanglongbing disease in citrus

By 2014, huanglongbing (HLB), the most destructive disease of citrus, and its insect vector, the Asian citrus psyllid (ACP), Diaphorina citri (Kuwayama), became established in all major citrus-growing regions of the world, including the United States, with the exception of California. At present, application of insecticides is the most widely followed option for reducing ACP populations, while application of antibiotics for suppressing HLB disease/symptoms is being practiced in some citrus-growing regions. Application of insecticides during the dormant winter season, along with cultivation of HLB-free seedlings and early detection and removal of symptomatic and asymptomatic trees, has been very effective in managing ACP. Area-wide management of ACP by application of insecticides at low volume in large areas of citrus cultivation has been shown to be effective in managing HLB and reducing management costs. As insecticide resistance is a major problem in sustainable management of ACP, rotation/alternation of insecticides with different chemistries and modes of action needs to be followed. Besides control of the insect vector, use of antibiotics has temporarily suppressed the symptoms of HLB in diseased trees. Recent efforts to discover and screen existing as well as new compounds for their antibiotic and antimicrobial activities have identified some promising molecules for HLB control. There is an urgent need to find a sustainable solution to the HLB menace through chemical control of ACP populations and within HLB-infected trees through the judicious use of labeled insecticides (existing and novel chemistries) and antibiotics in area-wide management programs with due consideration to the insecticide resistance problem.