OBJECTIVETo investigate the toxicity of indigenous Bacillus thuringiensis (B. thuringiensis)isolates from Malang City for controlling Aedes aegypti (Ae. aegypti) larvae.

METHODSSoil samples were taken from Purwantoro and Sawojajar sub-districts. Bacterial isolation was performed using B. thuringiensis selective media. Phenotypic characteristics of the isolates were obtained with the simple matching method. The growth and prevalence of spores were determined by the Total Plate Count method, and toxicity tests were also performed on the third instar larval stage of Ae. aegypti. The percentage of larval mortality was analysed using probit regression. The LC50 was analysed by ANOVA, and the Tukey HSD interval was 95%.

RESULTSAmong the 33 selected bacterial isolates, six were obtained (PWR4-31, PWR4-32, SWJ4-2b, SWJ4-4b, SWJ-4k and SWJ5-1) that had a similar phenotype to reference B. thuringiensis. Based on the dendrogram, all of the bacterial isolates were 71% similar. Three isolates that had a higher prevalence of reference B. thuringiensis were PWR4-32, SWJ4-4b and SW5-1, of which the spore prevalence was 52.44%, 23.59%, 34.46%, respectively. These three indigenous isolates from Malang City successfully killed Ae. aegypti larvae. The PWR4-32 isolates were the most effective at killing the larvae.

CONCLUSIONSSix indigenous B. thuringiensis isolates among the 33 bacterial isolates found in the Sawojajar and Purwantoro sub-districts were toxic to the third instar larvae of Ae. aegypti. The PWR4-32 isolates were identical to the reference B. thuringiensis and had 88% phenotype similarity. The PWR4-32 isolates had the highest spore prevalence (52.44%), and the early stationary phase occurred at 36 h. The PWR4-32 isolates were the most effective at killing Ae. aegypti larvae (LC50-72 h=2.3×10(8) cells/mL).

Aedes ; microbiology ; Animals ; Bacillus thuringiensis ; isolation & purification ; physiology ; Biological Control Agents ; Indonesia ; Insecticides ; Larva ; microbiology ; Lethal Dose 50 ; Mosquito Control

The research progress on Chinese medicine plant resources with pesticide activities, the active components and their reaction mechanism as well as the application and prospect were reviewed in this paper. Some proposals on the exploitation of traditional Chinese medicine plant origin pesticide were given. It is suggested to found compounds with pesticide activities from heat clearing and toxic clearing medicinal plants.
Fungicides, Industrial ; isolation & purification ; pharmacology ; Fusarium ; drug effects ; Insecticides ; isolation & purification ; pharmacology ; Lectins ; isolation & purification ; pharmacology ; Pesticides ; isolation & purification ; pharmacology ; Plant Oils ; isolation & purification ; pharmacology ; Plant Viruses ; drug effects ; Plants, Medicinal ; chemistry

Growing patterns of pediculocidal drug resistance towards head louse laid the foundation for research in exploring novel anti-lice agents from medicinal plants. In the present study, various extracts of Pongamia pinnata leaves were tested against the head louse Pediculus humanus capitis. A filter paper diffusion method was conducted for determining the potential pediculocidal and ovicidal activity of chloroform, petroleum ether, methanol, and water extracts of P. pinnata leaves. The findings revealed that petroleum ether extracts possess excellent anti-lice activity with values ranging between 50.3% and 100% where as chloroform and methanol extracts showed moderate pediculocidal effects. The chloroform and methanol extracts were also successful in inhibiting nymph emergence and the petroleum ether extract was the most effective with a complete inhibition of emergence. Water extract was devoid of both pediculocidal and ovicidal activities. All the results were well comparable with benzoyl benzoate (25% w/v). These results showed the prospect of using P. pinnata leave extracts against P. humanus capitis in difficult situations of emergence of resistance to synthetic anti-lice agents.
Animals ; Drug Evaluation, Preclinical ; Insecticides/isolation & purification/*pharmacology ; Lice/*drug effects ; Millettia/*chemistry ; Plant Extracts/isolation & purification/*pharmacology ; Plant Leaves/*chemistry ; Survival Analysis

The vip3 A gene in a size of 2.3 kb amplified from wild-type Bacillus thuringiensis strain S184 by PCR was cloned into pGEM-T Easy vector and its sequence was analysized by DNASTAR. The plasmid pOTP was constructed by inserting vip3A-S184 gene into the expression vector pQE30 and then was transformed into E. coli M15. E. coli M15 cells harbouring the plasmid pOTP were induced with 1 mmol/L IPTG to express 89 kD protein which was confirmed to be Vip3A-S184 by Western blot. Experiments showed that about 19% of Vip3A-S184 proteins were soluble, and others were insoluble proteins and formed inclusion bodies observed by transmission electron microscopy(TEM). The target protein was purified under the native condition and the polyclonal antibody was prepared by immunizing rabbits. The polyclonal antibody was used to detect Vip3A proteins expressed in Bacillus thuringiensis. Bioassay showed that Vip3A-S184 showed a high toxicity against 3 tested insect larvae including Spodoptera exigua, Spodoptera litura and Helicoverpa armigera.
Animals ; Bacillus thuringiensis ; genetics ; Bacterial Proteins ; genetics ; isolation & purification ; pharmacology ; Base Sequence ; Cloning, Molecular ; Escherichia coli ; genetics ; Insecticides ; pharmacology ; Molecular Sequence Data ; Pest Control, Biological ; Recombinant Proteins ; biosynthesis ; isolation & purification ; pharmacology ; Spodoptera

Vip3A, a novel insecticidal protein, is secreted by Bacillus thuringiensis (Bt) during vegetative growth. Vip3A protein possesses insecticidal activity against a wild spectrum of lepidopteran insect larvae. Since the first cloning of vip3A gene from Bt, many other vip3A genes have been isolated. To investigate vip3A genes contribution to Bt and reflect the revolution relationships, the strains containing vip3A genes were screened and gene similarity was analyzed. 114 wild-type Bacillus thuringiensis (Bt) strains isolated from different regions and 41 standard Bt strains from the Institute of Pasteur were screened for the vip3A genes using PCR amplification. 39 strains including B. thuringiensis subsp. kurstaki (Btk) HD-1 were found to contain the vip3A genes. Because acrystallerous strain Cry- B derived from Btk HD-1 was proved not to contain vip3A gene, it suppose that the vip3A gene may be located at the plasmids. Vip3A proteins expressed in these strains were detected with polyclonal antibody by Western blot and 4 strains among them were shown not to express the Vip3A proteins. The vip3A genes amplified from wild-type Bacillus thuringiensis strains S101 and 611 with different levels of activity against lepidopteran insect larvae were cloned into pGEM-T Easy vector. Alignment of these 2 putative Vip3A proteins with 6 others (Vip3A (a), Vip3A(b), Vip3A-S, Vip3A-S184, Vip83 and Vip3V) in the GenBank data base and 2 reported Vip3A proteins (Vip14 and Vip15) showed that vip3A genes are highly conservative. The plasmids pOTP-S101 and pOTP-611 were constructed by in- serting 2 vip3A genes (vip3A-S101 and vip3A-611) into the expression vector pQE30 respectively and were transformed into E. coli M15. E. coli M15 cells harboring the pOTP plasmids were induced with 1 mmol/L IPTG to express 89 kDa protein. Experiments showed that the level of soluble proteins of Vip3A-S101 in E. coli M15[pOTP-S101] and Vip3A-611 in E. coli M15 [pOTP-611] were about 48% and 35% respectively. Bioassay showed that each of these Vip3A proteins had similar toxicity against neonate Spodoptera litura larvae, indicating that some amino acids change had little effect on the insecticidal activity of proteins. Although vip3A genes are conservative, the unknown insecticidal spectrum is still to be brought out. Vip3A genes can be used for the construction of the Bt engineered strains and transgenic plants. In addition, vip3A genes are excellent candidates for delay of the pest resistance due to the difference of the action model from that of Bt delta-endotoxins.
Animals ; Bacillus thuringiensis ; genetics ; isolation & purification ; metabolism ; Bacterial Proteins ; genetics ; metabolism ; toxicity ; Blotting, Western ; Electrophoresis, Polyacrylamide Gel ; Insecticides ; metabolism ; toxicity ; Larva ; drug effects ; Models, Biological ; Polymerase Chain Reaction ; Spodoptera ; drug effects ; Toxicity Tests