A.S.D Pang

Glutathione S-transferase from the spruce budworm, Choristoneura fumiferana: identification, characterization, localization, cDNA cloning, and expression

A 23-kDa protein that was present at higher levels in diapausing 2nd instar larvae than in feeding 2nd instar larvae of Choristoneura fumiferana was purified, and polyclonal antibodies were raised against this protein. The antibodies were subsequently used to screen a cDNA library that was constructed using RNA from 2nd instar larvae. Eight identical cDNA clones were isolated. The cDNA clone had a 665-bp insert and the longest open reading frame coded for a 203-amino acid protein with a predicted molecular mass of 23.37 kDa. The deduced amino acid sequence showed high similarity to glutathione S-transferases and therefore, the cDNA clone was named C. fumiferana glutathione S-transferase (CfGST). Identity of CfGST was confirmed by using affinity-purification as well as enzyme activity assay. CfGST was closer in similarity to insect GST2 members than GST1 members. The apparent Vmax of the purified CfGST towards the substrates glutathione and 1-chloro-2,4-dinitrobenezene (CDNB) were similar. However, the enzyme had a three-fold higher affinity towards CDNB than glutathione. Analyses using Northern blot, immunoblot and immunocytochemistry demonstrated that the fat body was the major tissue where the enzyme was synthesized and stored. Higher levels of CfGST protein were present in diapausing 2nd instar larvae compared to feeding 2nd and 6th instar larvae, suggesting that besides detoxification CfGST may have other roles during insect development that are not readily apparent at present. The CfGST cDNA was expressed in a recombinant baculovirus expression system and an active enzyme was produced.

SYNTHESIS OF THE SAME TWO PROTEINS PRIOR TO LARVAL DIAPAUSE AND PUPATION IN THE SPRUCE BUDWORM, CHORISTONEURA FUMIFERANA

Spruce budworm larvae produce large quantities of two proteins (Choristoneura fumiferana diapause associated proteins 1 and 2, CfDAP1 and CfDAP2) that are diapause related. These proteins appeared soon after hatching and increased in abundance, reaching maximum levels by four days into the 1st instar, and they remained at high levels until three days after the termination of diapause. These two proteins were purified to homogeneity and their NH2-terminal sequences were obtained. Oligonucleotide primers designed on the basis of these NH2-terminal sequences were used in RT-PCR to isolate the cDNA fragments coding for these proteins. These PCR fragments were then used as probes to isolate the cDNAs that contained the complete coding region. The 2.5kb mRNAs coding for these proteins started to appear 24hr after hatching and large quantities of these mRNAs were detected in 1st instar and 2nd instar larvae until the 2nd instar larvae entered diapause. Low levels of these mRNAs were detected in the 2nd instar larvae that were preparing to enter diapause, in those that were in diapause as well as in those that terminated diapause. Low levels of CfDAP1 mRNA were also detected on days 1 and 2 after ecdysis to the 3rd instar. However, no CfDAP1 and CfDAP2 mRNAs could be detected during the 4th and 5th instar larval stages. The mRNAs reappeared 24hr after the 5th instar larvae molted into the 6th instar and increased to reach maximum levels by 60hr after ecdysis. The mRNA levels remained high until 156hr after ecdysis into the 6th instar (36-48hr before pupal ecdysis), after which they disappeared once again. Immunocytochemical analyses showed that CfDAP1 protein was present in 2nd and 6th instar larval fat body but not in 5th instar larval fat body. Thus, the same two genes were expressed for the first time before C. fumiferana larvae entered diapause and for a 2nd time before pupation.

Comparison of the response of midgut epithelial cells and cell lines from lepidopteran larvae to CryIA toxins from Bacillus thuringiensis

The cytotoxic responses of midgut epithelial cells (MEC) from spruce budworm (SBW), gypsy moth (GM) and silkworm (SW) larvae were compared with the cytotoxic response of lepidopteran cell lines (SF-9, SE-1a, and CF-1) to CryIA toxins from Bacillus thuringiensis. The MEC from SBW, SW and GM had binding proteins for CryIA(a,b,c) toxins, whereas the lepidopteran cell lines had binding proteins for CryIA(c). Single MEC exposed to CryIA(a,b,c) toxins in a qualitative lawn assay were equally susceptible to the toxins with a threshold response at about 1ng. The cell lines were not susceptible to CryIA(a,b) toxins in the dose range tested, but had threshold responses for CryIA(c) of 3.4ng for SF-9, 50.2ng for SE-1a and 5.9ng for CF-1. In the quantitative Live/Dead assay, MEC were equally susceptible to CryIA(a,b,c) toxins with a threshold effect at about 1ng and a maximum effect at about 10ng. CF-1 was most sensitive to CryIA(c) with a threshold effect at 0.39ng and a maximal effect at about 1ng. In contrast, a 25-50 times greater dose of CryIA(a) or CryIA(b) was required to elicit a similar response as CryIA(c) for CF-1. SF-9 and SE-1a were most susceptible to CryIA(c) with a threshold effect observed at about 0.5ng and maximal effects at about 2ng. SF-9 cells have a threshold and maximum response to CryIA(a,b) of about 10ng and 20ng, respectively. SE-1a cells have a threshold and maximal response to CryIA(a,b) of 5ng and 10ng, respectively. Intact midgut epithelium exposed to CryIA(a,b,c) toxins had a threshold dose of 2ng for CryIA(b), 10-30ng for CryIA(a) and 2-30ng for CryIA(c). This study has shown that MEC are affected by a broader spectrum of toxins compared to the lepidopteran larvae and insect cell lines.

Detection of Bacillus cereus virulence factors in commercial products of Bacillus thuringiensis and expression of diarrheal enterotoxins in a target insect

We examined isolates from 4 commercial bioinsecticides based on different strains of Bacillus thuringiensis subspecies (kurstaki, israelensis, aizawai, and tenebrionis) for the presence of genes encoding proteins with known enterotoxigenicity (nhe, hbl, cytk, ces) and various other putative virulence genes (piplc, sph, bceT, entFM, entS, entT). The piplc and bceT sequences were present in all the isolates; sph was found in aizawai and israelensis; entFM only in israelensis; and entS in kurstaki, israelensis, and tenebrionis. Our results corroborate previous findings that isolates used in commercial products contain all nhe and hbl component genes but not the ces gene. We ascertained that the cytK gene present in the kurstaki-, israelensis-, and aizawai-based products belongs to the cytK-2 type and not the more toxigenic cytK-1 variant originally isolated from enterotoxic Bacillus cereus. We provide the first evidence that hemolytic (hblA) and nonhemolytic (nheA, nheB, nheC) enterotoxin genes are expressed during septicemia in a target insect. This opens the door for their possible participation in pathogenesis in target insects. If enterotoxins do not contribute to bacterial pathogenesis in target insects, their genes could be deleted from commercial production strains to pre-empt perceptions of public health risks.

Molecular analysis of overwintering diapause

Publisher Summary Diapause is a genetically determined, hormonally mediated state of suppressed development, and is an important adaptive mechanism for insect survival during unfavourable environmental conditions, such as low winter temperatures. The spruce budworm, Choristonuera fumiferana, overwinters as a diapausing second-instar larva. Molecular analyses of larvae in prediapause, diapause, and postdiapause stages led to the identification of sugars and proteins that are related to diapause or overwintering. C . fumiferana produces the disaccharide trehalose and proteins, such as diapause associated proteins 1&2 and glutathione S-transferase that are diapause related. The glycerol and the defensin-like protein that the larvae produce appear to be related to the overwintering process. Glycerol production and synthesis of defensin-like protein are clearly overwintering related events, and these happen only after the larvae are exposed to cold treatment for certain lengths of time. If the larvae are not exposed to the cold treatment, they fail to synthesize glycerol or defensin-like protein. On the other hand, increases in trehalose levels and synthesis of CfDAPl and CfDAP2, as well as increased synthesis of CfGST, occur as soon as the larvae hatch and start preparing for diapause. They also start spinning hibemacula at this time. These are probably diapause-related events. Absence of ecdysteroids in the diapausing second instars prevents molting and metamorphosis, allowing them to overwinter in this stage. This chapter describes the simultaneous occurrence of obligatory diapauses and the overwintering process in the second-instar larvae of the spruce budworm, C. fumiferana . However, these two physiological events can be distinguished from each other on the basis of some of the biochemical changes that occur in these larvae during the obligatory overwintering diapause.