Zhong Zheng Gui

Functional role of aspartic proteinase cathepsin D in insect metamorphosis

BackgroundMetamorphosis is a complex, highly conserved and strictly regulated development process that involves the programmed cell death of obsolete larval organs. Here we show a novel functional role for the aspartic proteinase cathepsin D during insect metamorphosis.ResultsCathepsin D of the silkworm Bombyx mori (BmCatD) was ecdysone-induced, differentially and spatially expressed in the larval fat body of the final instar and in the larval gut of pupal stage, and its expression led to programmed cell death. Furthermore, BmCatD was highly induced in the fat body of baculovirus-infected B. mori larvae, suggesting that this gene is involved in the induction of metamorphosis of host insects infected with baculovirus. RNA interference (RNAi)-mediated BmCatD knock-down inhibited programmed cell death of the larval fat body, resulting in the arrest of larval-pupal transformation. BmCatD RNAi also inhibited the programmed cell death of larval gut during pupal stage.ConclusionBased on these results, we concluded that BmCatD is critically involved in the programmed cell death of the larval fat body and larval gut in silkworm metamorphosis.

Expression profile of cathepsin B in the fat body of Bombyx mori during metamorphosis.

Proteolytic enzymes are involved in insect molting and metamorphosis, and play a vital role in the programmed cell death of obsolete organs. Here we show the expression profile of cathepsin B in the fat body of the silkworm Bombyx mori during development. We also compare the expression profiles of B. mori cathepsins B (BmCatB) and D (BmCatD) during normal development and after RNA interference (RNAi)-mediated inhibition. BmCatB is induced by 20-OH-ecdysone, and is expressed in the fat body of B. mori during molting and the larval-pupal and pupal-adult transformations, where its expression leads to programmed cell death. In particular, BmCatB is highly expressed in the fat body of B. mori during the larval-pupal transformation, and BmCatB RNAi treatment resulted in an arrest of the larval-pupal transformation. RNAi-mediated BmCatB knockdown sustained the expression of BmCatD during the larval-pupal transformation. On the other hand, when BmCatD was inhibited via RNAi, the expression of BmCatB was upregulated. Based on these results, we conclude that BmCatB is involved in the programmed cell death of the fat body during B. mori metamorphosis, and that BmCatB and BmCatD contribute to B. mori metamorphosis.

Molecular cloning and oxidative stress response of a sigma-class glutathione S-transferase of the bumblebee Bombus ignitus

Glutathione S-transferases (EC 2.5.1.18; GSTs) are multifunctional enzymes that are mainly involved in xenobiotic metabolism and protection against oxidative damage. Most studies of GSTs in insects have been focused on their role in detoxifying exogenous compounds in particular insecticides. Here, we show the expression profiles of GSTs of the bumblebee Bombus ignitus in response to oxidative stress. We identified a sigma-class GST from B. ignitus (BiGSTS). The BiGSTS gene consists of 4 exons that encode 201 amino acids. Comparative analysis indicates that the predicted amino acid sequence of BiGSTS shares a high identity with the sigma-class GSTs of hymenopteran insects such as Apis mellifera (70% protein sequence identity) and Solenopsis invicta (59% protein sequence identity). Tissue distribution analyses showed the presence of BiGSTS in all tissues examined, including the fat body, midgut, muscle and epidermis. The oxidative stress responses analyzed by quantitative real-time PCR showed that under H(2)O(2) overload, BiGSTS and BiGSTD (identified in our previous study) were upregulated in all tissues examined, including the fat body and midgut of B. ignitus worker bees. Under uniform conditions of H(2)O(2) overload, the expression profile of GSTs and other antioxidant enzyme genes, such as phospholipid-hydroperoxide glutathione peroxidase (Bi-PHGPx) and peroxiredoxins (BiPrx1 and BiTPx1), showed that other antioxidant enzyme genes are acutely induced at 3h after H(2)O(2) exposure, whereas BiGSTS and BiGSTD are highly induced at 9h after H(2)O(2) exposure in the fat body of B. ignitus worker bees. These findings indicate that GSTs and other antioxidant enzyme genes in B. ignitus are differentially expressed in response to oxidative stress. Taken together, our findings indicate that BiGSTS and BiGSTD are oxidative stress-inducible antioxidant enzymes that may play a role in oxidative stress response.

Molecular characterization of a phospholipid-hydroperoxide glutathione peroxidase from the bumblebee Bombus ignitus

Phospholipid-hydroperoxide glutathione peroxidase (PHGPx or GPx4; EC 1.11.1.12) is an antioxidant enzyme that reduces lipid hydroperoxides in biomembranes. Here, we cloned and characterized cys-PHGPx from the bumblebee Bombus ignitus (Bi-PHGPx). The Bi-PHGPx gene consists of 4 exons, encoding 168 amino acid residues with a canonical cys-codon at residue 45 and active site residues Gln(82) and Trp(134). Recombinant Bi-PHGPx, expressed as a 19 kDa protein in baculovirus-infected insect cells, exhibited enzymatic activity against PLPC-OOH and H(2)O(2) using glutathione as an electron donor. Tissue distribution analyses showed the presence of Bi-PHGPx in all tissues examined. Bi-PHGPx transcripts were upregulated by stresses, such as wounding, H(2)O(2) exposure, external temperature shock, and starvation. Under H(2)O(2) overload, the RNA interference (RNAi)-induced thioredoxin peroxidase (BiTPx1)-knock-down B. ignitus worker bees showed upregulated expression of Bi-PHGPx in the fat body. These results indicate that Bi-PHGPx is a stress-inducible antioxidant enzyme that acts on phospholipid hydroperoxide and H(2)O(2).