Cytotoxic Effects and Intracellular Localization of Bin Toxin from Lysinibacillus sphaericus in Human Liver Cancer Cell Line.

Binary toxin (Bin toxin), BinA and BinB, produced by Lysinibacillus sphaericus has been used as a mosquito-control agent due to its high toxicity against the mosquito larvae. The crystal structures of Bin toxin and non-insecticidal but cytotoxic parasporin-2 toxin share some common structural features with those of the aerolysin-like toxin family, thus suggesting a common mechanism of pore formation of these toxins. Here we explored the possible cytotoxicity of Bin proteins (BinA, BinB and BinA + BinB) against Hs68 and HepG2 cell lines. The cytotoxicity of Bin proteins was evaluated using the trypan blue exclusion assay, MTT assay, morphological analysis and LDH efflux assay. The intracellular localization of Bin toxin in HepG2 cells was assessed by confocal laser scanning microscope. HepG2 cells treated with BinA and BinB (50 µg/mL) showed modified cell morphological features and reduced cell viability. Bin toxin showed no toxicity against Hs68 cells. The EC50 values against HepG2 at 24 h were 24 ng/mL for PS2 and 46.56 and 39.72 µg/mL for BinA and BinB, respectively. The induction of apoptosis in treated HepG2 cells was confirmed by upregulation of caspase levels. The results indicated that BinB mediates the translocation of BinA in HepG2 cells and subsequently associates with mitochondria. The study supports the possible development of Bin toxin as either an anticancer agent or a selective delivery vehicle of anticancer agents to target mitochondria of human cancer cells in the future.

Intracellular localization and cytotoxicity of Bacillus thuringiensis Vip3Aa against Spodoptera frugiperda (Sf9) cells.

Vip3Aa protein is produced by Bacillus thuringiensis during vegetative growth and displays high toxicity against a wide range of lepidopteran insect larvae such as Spodoptera exigua and Spodoptera frugiperda, both important insect pests worldwide. Vip3Aa protein is synthesized as a protoxin (proVip3Aa) and becomes activated by digestion with either trypsin or insect gut proteases. The activated Vip3Aa protein (actVip3Aa) binds to a specific receptor in the brush border epithelial midgut cells, causing cell death via apoptosis, possibly induced by its pore-forming activity. Here we investigated the actVip3Aa intracellular localization to explain the molecular mechanism leading to the cytotoxicity of Vip3Aa toxin. The Spodoptera frugiperda (Sf9) cell line was incubated with fluorescently labeled Vip3Aa, namely Alexa488-actVip3Aa, and the intracellular localization was analyzed through a laser scanning confocal microscope. The Alexa488-actVip3Aa was internalized into the Sf9 cells. Immunofluorescence detection demonstrated that Alexa488-actVip3Aa did not colocalize with early endosomes which is usually implicated in clathrin-mediated endocytosis, suggesting that the actVip3Aa does not use clathrin-dependent endocytosis to transport into the cytosol. Intracellular visualization also shows that actVip3Aa does not directly target to mitochondria upon entry into the cytosol. Following internalization, actVip3Aa causes cell division disruption that subsequently could trigger cell death via apoptosis.

The crystal structure of JNK from Drosophila melanogaster reveals an evolutionarily conserved topology with that of mammalian JNK proteins.

BACKGROUND: The c-Jun N-terminal kinases (JNKs), members of the mitogen-activated protein kinase (MAPK) family, engage in diverse cellular responses to signals produced under normal development and stress conditions. In Drosophila, only one JNK member is present, whereas ten isoforms from three JNK genes (JNK1, 2, and 3) are present in mammalian cells. To date, several mammalian JNK structures have been determined, however, there has been no report of any insect JNK structure. RESULTS: We report the first structure of JNK from Drosophila melanogaster (DJNK). The crystal structure of the unphosphorylated form of DJNK complexed with adenylyl imidodiphosphate (AMP-PNP) has been solved at 1.79 Å resolution. The fold and topology of DJNK are similar to those of mammalian JNK isoforms, demonstrating their evolutionarily conserved structures and functions. Structural comparisons of DJNK and the closely related mammalian JNKs also allow identification of putative catalytic residues, substrate-binding sites and conformational alterations upon docking interaction with Drosophila scaffold proteins. CONCLUSIONS: The DJNK structure reveals common features with those of the mammalian JNK isoforms, thereby allowing the mapping of putative catalytic and substrate binding sites. Additionally, structural changes upon peptide binding could be predicted based on the comparison with the closely-related JNK3 structure in complex with pepJIP1. This is the first structure of insect JNK reported to date, and will provide a platform for future mutational studies in Drosophila to ascertain the functional role of insect JNK.