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APPLIED AND ENVIRONMENTAL MICROBIOLOGY, June 1995, p. 2402–2407 0099-2240/95/$04.0010 Copyright q 1995, American Society for Microbiology Vol. 61, No. 6 BYUNG-SIK SHIN,1* SEUNG-HWAN PARK,1 SOO-KEUN CHOI,1 BON-TAG KOO,1 SUNG-TAIK LEE,2 1 AND JEONG-IL KIM Genetic Engineering Research Institute, Korea Institute of Science and Technology,1 and Department of Biotechnology, Korea Advanced Institute of Science and Technology,2 Taejon, Korea Received 14 November 1994/Accepted 8 March 1995 DNA dot blot hybridizations with a cryV-specific probe and a cryI-specific probe were performed to screen 24 Bacillus thuringiensis strains for their cryV-type (lepidopteran- and coleopteran-specific) and cryI-type (lepidopteran-specific) insecticidal crystal protein gene contents, respectively. The cryV-specific probe hybridized to 12 of the B. thuringiensis strains examined. Most of the cryV-positive strains also hybridized to the cryI-specific probe, indicating that the cryV genes are closely related to cryI genes. Two cryV-type genes, cryV1 and cryV465, were cloned from B. thuringiensis subsp. kurstaki HD-1 and B. thuringiensis subsp. entomocidus BP465, respectively, and their nucleotide sequences were determined. The CryV1 protein was toxic to Plutella xylostella and Bombyx mori, whereas the CryV465 protein was toxic only to Plutella xylostella. sequence but, rather, show only the amplified region of the cryV-type genes of interest. In this study, we used DNA dot blot hybridizations with a cryV-specific probe to determine the cryV-type gene content of B. thuringiensis strains and the content of cloned cryV-type genes from B. thuringiensis subsp. kurstaki HD-1 and B. thuringiensis subsp. entomocidus BP465. The nucleotide sequences of cloned genes and the insecticidal activity of the gene products have also been analyzed. Bacillus thuringiensis is a gram-positive bacterium that produces proteinaceous crystals during sporulation. Many different B. thuringiensis crystal protein genes have been identified, and the toxicity of the encoded proteins has been investigated. At least four major classes of insecticidal protein genes have been identified: cryI, cryII, cryIII, and cryIV. These genes encode lepidopteran-specific (CryI), lepidopteran- and dipteranspecific (CryII), coleopteran-specific (CryIII), and dipteranspecific (CryIV) proteins, respectively (11). After the discovery of various B. thuringiensis strains that have toxicity against a wide spectrum of insect pests, these bacteria have been developed as the most successful commercial microbial insecticide for the control of various insect pests. However, several insect pest species of globally important crops have little or no susceptibility to the existing insecticidal protein of various B. thuringiensis strains. Development of resistance in insect pests is another significant problem in the use of B. thuringiensis as a successful microbial insecticide. B. thuringiensis had been used commercially for more than two decades without reports of substantial resistance development in field populations. However, the diamondback moth, Plutella xylostella, has evolved resistance in the open field in Hawaii and more recently in Florida and Asia (6, 22, 23). Recently, Tailor et al. (25) reported a new class of crystal protein gene, cryV, cloned from B. thuringiensis subsp. kurstaki JHCC4835. The encoded protein (CryV) has a molecular mass of 81 kDa and is toxic to larvae of members of both the orders Lepidoptera and Coleoptera. The known cryV genes are, however, silent in B. thuringiensis strains (9, 25), so we thought that some B. thuringiensis strains may carry cryV-type genes that encode insecticidal proteins having toxic activities against the insensitive or resistant insect pests. Previously, PCR with cryVspecific primers was used to screen the cryV-type gene content (9), but PCR screenings do not work well with cryV-type genes that have low homology with cryV-specific primers. Also, PCR screenings do not show any information about the remainder MATERIALS AND METHODS Bacterial strains and plasmids. B. thuringiensis strains were obtained from the Bacillus Genetic Stock Center, Department of Biochemistry, The Ohio State University, Columbus. B. thuringiensis subsp. entomocidus BP465 was isolated from the phylloplane of an oak tree by procedures described by Smith et al. (20). Plasmid pUC19 was the vector used to construct the genomic library, and plasmid pKK233-2 (Pharmacia) was used to facilitate the expression of toxin genes in Escherichia coli JM109. Chemicals and enzymes. Chemicals were purchased from Sigma Chemical Co. unless otherwise specified. Restriction endonucleases, DNA-modifying enzymes, and chemicals used for DNA manipulations were purchased from Boehringer Mannheim Biochemicals and used as specified by the manufacturer. Preparation of DNA. Plasmids were isolated by the alkali lysis method (1). Total DNA was purified from B. thuringiensis strains as described by Kalman et al. (13). Preparation of probe DNA. The cryV-specific probe was prepared from total DNA of B. thuringiensis subsp. kurstaki HD-1 by PCR with primers cry5A (59ATGAAACTAAAGAATCAAGA-39) and cry5B (59-ACCTGTGCTATACCA TTTCA-39), which correspond to nucleotides 1 to 20 and 726 to 707, respectively, of the cryV gene. The cryI-specific probe was prepared from B. thuringiensis subsp. kurstaki HD-73 with primers LEP2A (59-CCGAGAAAGTCAAACAT GCG-39) and LEP2B (59-TACATGCCCTTTCACGTTCC-39) specific for regions 2003 to 2022 and 2988 to 2969 of the cryIA(c) gene as described by Carozzi et al. (4). The DNA template for PCR was the same as the total DNA prepared for DNA hybridizations. The PCR mix was as described in the GeneAmp kit (Perkin-Elmer Cetus) with the addition of 0.2 mM each primer, 10 ng of template DNA, and 1.0 U of Taq DNA polymerase. PCR amplification was carried out as recommended by Perkin-Elmer Cetus. PCR-amplified cryV gene fragments were excised from a 0.8% agarose gel and purified with a Geneclean II kit (Bio 101 Inc., La Jolla, Calif.). Both double-stranded DNA probes were labeled with digoxigenin-dUTP by nick translation. DNA-DNA hybridization. DNA dot blot hybridizations were carried out as follows. A 1-ml (1-mg) portion of each total DNA sample was dispensed onto the positively charged nylon membrane (Boehringer Mannheim Biochemicals), the * Corresponding author. Fax: 82-42-860-4594. 2402 Downloaded from http://aem.asm.org/ on January 13, 2012 by KRIBB(Korea Res Inst of Biosci & Biotech) Distribution of cryV-Type Insecticidal Protein Genes in Bacillus thuringiensis and Cloning of cryV-Type Genes from Bacillus thuringiensis subsp. kurstaki and Bacillus thuringiensis subsp. entomocidus B. THURINGIENSIS cryV-TYPE GENES VOL. 61, 1995 RESULTS Screening. We prepared the cryV-specific probe from total DNA of B. thuringiensis subsp. kurstaki HD-1 by PCR as described above. Nucleotide sequences of the 0.7-kb PCR product in both strands were analyzed (data not shown), and it was confirmed that sequences in the probe region of the cryV gene from strain HD-1 were exactly the same as those of the cryV gene cloned from B. thuringiensis subsp. kurstaki JHCC4835 (25). DNA dot blot hybridization was carried out to survey 24 B. thuringiensis strains for the presence of cryV-type genes. The cryV-specific probe hybridized to 12 of the 24 strains screened (Table 1). We also carried out DNA dot blot hybridization with TABLE 1. Results of DNA dot blot hybridizations for the presence of cryV-type and cryI-type genes in B. thuringiensis strains B. thuringiensis subspecies and strain kurstaki HD-1 kurstaki HD-73 thuringiensis HD-2 finitimus HD-3 alesti HD-4 dendrolimus HD-7 morrisoni HD-12 kenya HDB-23 galleriae HD-29 aizawai HD-137 darmstadiensis HD-146 toumanoffi HD-201 pakistani HD-395 dakota HD-511 indiana HD-521 tolworthi HD-537 kyushuensis HD-541 thompsoni HD-542 israelensis HD-567 tohokuensis 4V1 colmeri HD-847 kumamotoensis HD-867 tochigiensis HD-868 entomocidus BP465 Hybridization to probea: cryV type cryI type 111 111 111 111 1 111 1 11 1 111 1 11 11 11 11 111 111 111 111 11 11 11 11 111 11 111 Levels of signal intensities are relative to that of strain HD-1: 111, strong; 11, medium; 1, weak. a a cryI-specific probe that is highly homologous to all known cryI genes in order to compare the relative distribution of cryV and cryI genes among B. thuringiensis strains. Of the 24 strains, 14 showed a positive signal to the cryI-specific probe, indicating that these strains contain cryI-type genes (Table 1). Except for B. thuringiensis subsp. thompsoni HD-542, all of the remaining cryV-positive strains were also cryI-positive strains, which indicates that cryV-type genes are highly associated with cryI-type genes. However, B. thuringiensis subsp. kurstaki HD-73, B. thuringiensis subsp. thuringiensis HD-2, and B. thuringiensis subsp. darmstadiensis HD-146 seemed to contain only cryI-type genes; there were no positive signals to the cryV-specific probe in these three strains. Neither cryV-specific nor cryI-specific probes hybridized to nine strains (Table 1). Southern hybridization and cloning of the cryV-type genes. B. thuringiensis subsp. entomocidus BP465 was isolated from the phylloplane of an oak tree and showed insecticidal activity against Spodoptera exigua species (data not shown). Total DNAs prepared from strains HD-1 and BP465 were digested with various restriction enzymes, electrophoresed through a 0.8% agarose gel, transferred to nylon membrane, and hybridized to the cryV-specific probe prepared from strain HD-1. When total DNAs were digested with ClaI, 4.5-kb bands were detected in both HD-1 and BP465 strains (Fig. 1, lane 1). Because a ClaI site is present 0.3 kb 59 of the cryV gene (25), we could deduce the BamHI site to be at approximately 0.5 kb 39 of the cryV gene by double digestion with ClaI and BamHI (lane 2), and we could locate the PvuII site at approximately 0.6 kb 59 of the cryV gene by double digestion with BamHI and PvuII (lane 3). Although these restriction enzyme sites of the flanking region of cryV genes were shown to be the same in both strains, different hybridization patterns were obtained when DNAs were digested with other restriction enzymes, which are present in the intragenic region of the cryV gene Downloaded from http://aem.asm.org/ on January 13, 2012 by KRIBB(Korea Res Inst of Biosci & Biotech) DNA was denatured by transferring the membrane for 5 min to a Whatman paper saturated with 0.5 N NaOH and 1.5 M NaCl, and then the DNA was neutralized by transferring the membrane for 5 min to a Whatman paper saturated with 1.0 M Tris-HCl (pH 7.5) and 1.5 M NaCl. Southern hybridization was carried out by separating the restricted DNAs by electrophoresis in 0.8% agarose gels and transferring them to a nylon membrane via a Trans-Vac TE80 vacuum blotter (Hoefer Scientific). The DNAs were fixed to the nylon membrane by exposing the wet membrane to UV light for 3 min. Prehybridization and hybridization of DNA-bound membranes were performed in a solution of 53 SSC (13 SSC is 0.15 M NaCl plus 0.015 M sodium citrate), 0.1% N-lauroylsarcosine, 0.02% sodium dodecyl sulfate (SDS), and 1.0% blocking reagent (Boehringer Mannheim Biochemicals) at 658C for 15 h. The membrane was subsequently washed twice for 5 min at room temperature with 23 SSC containing 0.1% SDS and twice for 20 min at 658C with 13 SSC containing 0.1% SDS. The stringency of these hybridization conditions is expected to be approximately 80% homology. Hybridized DNA was detected with the Dig nucleic acid detection kit (Boehringer Mannheim Biochemicals) as specified in the instruction manual. Construction of genomic libraries. Total DNAs purified from B. thuringiensis subsp. kurstaki HD-1 and B. thuringiensis subsp. entomocidus BP465 were digested with PvuII and BamHI and electrophoresed through a 0.8% agarose gel, and 2- to 5-kb DNA fragments were excised and purified with a Geneclean II kit. Purified DNA fragments were ligated with pUC19 digested with HindII and BamHI at a 1:1 molar ratio and at a final DNA concentration of 20 mg/ml. After ligation, the DNAs were used to transform E. coli JM109; preparation of competent cells and transformations were as described by Inoue et al. (12). DNA sequencing. DNA sequences were obtained by the dideoxy-chain termination method (19) with the Dig Taq DNA sequencing kit (Boehringer Mannheim Biochemicals). Appropriate subclones were generated for sequencing by the unidirectional progressive deletion method with exonuclease III (10). DNA samples for electrophoresis were obtained by PCR with a digoxigenin-labeled sequencing primer as specified in the instruction manual. DNA and amino acid sequence analyses were performed with the DNASIS V. 6.01 (Hitachi Soft Engineering Co.) program. Protein analysis. The E. coli cells harboring the cloned crystal protein genes were grown in LB medium (1% tryptone [Difco], 0.5% yeast extract [Difco], 0.5% NaCl [pH 7.0]) for 24 h. After detection of inclusion bodies in cells by phase-contrast microscopic observations, the cultured broths were concentrated fivefold in 10 mM Tris-HCl (pH 8.0) buffer containing 1 mM phenylmethylsulfonyl fluoride, and the cells were disrupted by ultrasonic treatment until lysis was complete. The lysates were then centrifuged at 10,000 3 g to collect the inclusion bodies, and, finally, the pellet was suspended at 1/10 the volume of the lysate in the same buffer. These protein preparations were examined by SDS-polyacrylamide gel electrophoresis (SDS-PAGE) (12.5% polyacrylamide) before being used for the analysis of the insecticidal activity. Protein concentrations were determined by the protein assay method of Lowry et al. (17). Insect toxicity assays. Insecticidal activity against the silkworm, Bombyx mori (Lepidoptera: Bombycidae), was measured by incorporating suspensions containing twofold serial dilutions of purified inclusions into the artificial diet. Silkworms used were Ingong-saryo (Dongbang Co., Seoul, Korea). Toxicity studies on larvae of the diamondback moth, Plutella xylostella (Lepidoptera: Plutellidae); the brassica leaf beetle, Phaedon brassicae (Coleoptera: Chrysomelidae); and the alder leaf beetle, Agelastica coerulea (Coleoptera: Chrysomelidae), were done on fresh leaf disks (diameter, 6 cm) by leaf residue bioassays (24). Disks cut from leaves of cabbages grown in the greenhouse were used for Plutella xylostella and Phaedon brassicae, and disks cut from leaves of alder, Alnus japonica, were used for A. coerulea. Ten third-instar larvae were each placed on a artificial diet or a leaf disk, and larval death was monitored after 2 days for Plutella xylostella (24), after 3 days for B. mori, and after 7 days for A. coerulea and Phaedon brassicae. Bioassays were repeated at least twice, and the 50% lethal concentration (LC50) was calculated by probit analysis (7). Nucleotide sequence accession numbers. The nucleotide sequence data reported in this paper have been filed in the EMBL/GenBank database under accession numbers L36338 for cryV1 and U07642 for cryV465. 2403 2404 SHIN ET AL. (lanes 4 to 6). When total DNAs were digested with ClaI and EcoRI, the cryV-specific probe not only detected the expected 1.4-kb fragment in HD-1 DNA but also unexpectedly detected a fragment of approximately 2.4 kb in BP465 DNA (lane 4). We also detected more, smaller ClaI-HindIII and ClaI-XhoI fragments in BP465 than in HD-1. These data suggest the presence of a novel cryV-type gene in strain BP465. The same 3.3-kb PvuII-BamHI fragments containing the putative cryV-type genes of HD-1 and BP465 were isolated, and restriction maps of the resulting recombinant plasmids, designated pBC70 for HD-1 and pBC80 for BP465, were constructed (Fig. 2). We could generate the positions and orientations of the cryV-type genes, designated cryV1 for HD-1 and cryV465 for BP465, within 3.3-kb PvuII-BamHI fragments (Fig. 2). To sequence the cloned genes, the 3.0-kb ClaI-BamHI fragments of both cryV1 and cryV465 were cloned into pUC19. The sequence analysis (Fig. 3) showed the presence of an open reading frame encoding a protein of 719 amino acid residues and having a predicted molecular mass of 81 kDa. Nucleotide sequences of the cryV1 gene were almost identical to those of the cryV gene reported by Tailor et al. (25). There were only two different nucleotides at positions 2133 (G to C) and 2134 (C to G). These two nucleotide differences result in two amino acid changes: lysine to asparagine and glutamine to glutamic acid transitions at amino acid residues 711 and 712, respectively. The deduced amino acid sequence of the CryV465 protein was found to be 93% identical to the sequence of the CryV1 protein and 90% identical to the sequence of the partially identified CryV-type protein of B. thuringiensis subsp. FIG. 2. Restriction maps of plasmid pBC70 and pBC80 inserts. Black boxes and arrows indicate the positions and orientations, respectively, of the crystal protein genes. The hatched box indicates the cryV-specific probe region. Vector sequences have been omitted. aizawai EG6346 in the N-terminal 380-amino-acid overlap (5). Amino acid differences between the CryV1 and CryV465 proteins appeared to occur randomly throughout the N-terminal 460 amino acid residues, and the remaining C-terminal amino acid residues were nearly identical. The CryV465 protein also has the five conserved blocks identified by Hofte and Whiteley (11), but eight amino acid differences between CryV465 and CryV1 are present within the region of the second conserved block. Expression of the cryV1 and cryV465 genes in E. coli. E. coli cells harboring the cryV1 or cryV465 gene failed to produce the toxin protein. It seems that transcription from the lac promoter of pUC19 is prevented by the transcriptional terminator structure of the cryI gene present upstream of the cryV gene. Thus, we cloned the cryV1 and cryV465 genes into pKK233-2. The cryV1 gene was eluted as PstI-SmaI from pBC70 and inserted into pKK233-2 digested with HindIII after cohesive ends were filled in with the Klenow fragment, generating pBC73. The cryV465 gene was also cloned into pKK233-2 by the same procedure to make pBC83. E. coli JM109 harboring pBC73 or pBC83 expressed the toxin protein constitutively without the addition of isopropyl-b-D-thiogalactopyranoside. We could detect the refractile inclusion bodies in E. coli cells after 12 h of growth by phase-contrast microscopic observations. The CryV1 and CryV465 proteins were partially purified from E. coli recombinant strains as described in Materials and Methods, and SDS-PAGE analysis followed by densitometric scanning analysis showed that about 48% of the total protein was the 81-kDa CryV protein (data not shown). Insect toxicity assays. Insecticidal activities of the purified CryV1 and CryV465 proteins against two lepidopteran and two coleopteran insects are summarized in Table 2. The CryV1 protein was highly active against Plutella xylostella and B. mori, whereas the CryV465 protein was toxic only to Plutella xylostella, with a higher LC50 than that of CryV1 protein. The CryV1 and CryV465 proteins did not show any toxicity against Phaedon brassicae, one of major agricultural insect pests in Korea, or against A. coerulae, one of the major forest insect pests in Korea. DISCUSSION A wide distribution of the cryV-type genes among many different B. thuringiensis strains has been indicated by previous researchers (9, 25). However, there are some discrepancies between their and our results. We could not detect the cryVtype gene in B. thuringiensis subsp. kurstaki HD-73, which was reported to contain a cryV-type gene (25). Also, B. thuringiensis subsp. alesti HD-4, B. thuringiensis subsp. morrisoni HD-12, and B. thuringiensis subsp. toumanoffi HD-201 showed weak signals in response to the cryV-specific probe we prepared, although they were reported to produce no PCR products when PCR was performed with a cryV-specific probe (9). It appears that the sequences of cryV-type genes of these strains have low homology to the cryV-specific probe, so that PCR products were not previously observed. DNA sequence comparisons with other cry genes indicate that the cryV gene is most closely related to the cryIB gene (9, 25). The cryV-specific probe region we used also has 67% homology with the cryIB gene at the DNA level. However, the stringency conditions used in the hybridizations we performed could distinguish the cryV-type gene from the cryIB gene. B. thuringiensis subsp. thuringiensis HD-2 has a cryIB gene (2), and our cryV-specific probe did not hybridize to the total DNA of the strain HD-2 (Table 1). The cryV-type genes have been found to be located in close Downloaded from http://aem.asm.org/ on January 13, 2012 by KRIBB(Korea Res Inst of Biosci & Biotech) FIG. 1. Southern blot analysis of B. thuringiensis subsp. kurstaki HD-1 and B. thuringiensis subsp. entomocidus BP465. Total DNAs were digested with various restriction enzymes and hybridized to the cryV-specific probe. Lanes: 1, ClaI; 2, ClaI plus BamHI; 3, BamHI plus PvuII; 4, ClaI plus EcoRI; 5, ClaI plus HindIII; 6, ClaI plus XhoI; 7, HindIII-digested l DNA. Sizes (in kilobases) are on the right. APPL. ENVIRON. MICROBIOL. VOL. 61, 1995 B. THURINGIENSIS cryV-TYPE GENES 2405 Downloaded from http://aem.asm.org/ on January 13, 2012 by KRIBB(Korea Res Inst of Biosci & Biotech) FIG. 3. Nucleotide sequences and deduced amino acid sequences of the cryV1 and cryV465 genes. The 2.8-kb cryV465 gene insert and deduced amino acid sequences are presented. These sequences were aligned with the cryV1 gene sequences and its predicted amino acid sequences; only the differences in the open reading frame of cryV1 DNA and amino acid sequences are shown. Both genes have 719 amino acid residues and the same start and stop codons. The inverted repeat is marked with arrows above the sequence. 2406 SHIN ET AL. APPL. ENVIRON. MICROBIOL. TABLE 2. Toxicity of CryV1 and CryV465 proteins produced by E. coli recombinant cells LC50 (mg/ml)a of: Insect CryV465 CryV1 a 10.9 (7.0–17.0) 17.4 (9.7–29.2) .1,900 .1,900 .260 147.8 (79.2–285.2) .2,600 .2,600 95% confidence intervals are shown in parentheses. proximity to and downstream of the cryI genes (5, 9, 25). We detected a cryID-like gene located approximately 0.5 kb 59 of the cryV465 gene, and this type of cryI-cryV linkage is very common in other cryV-type genes. We also detected a cryIA(a)cryV gene linkage in B. thuringiensis subsp. kurstaki HD-1, a cryIE-cryV gene linkage in B. thuringiensis subsp. tolworthi HD537, and a cryID-like–cryV-like gene linkage in B. thuringiensis subsp. morrisoni HD-12 (data not shown). However, there was one exception. B. thuringiensis subsp. thompsoni HD-542 seemed to contain only a cryV gene. The cryI-specific probe could not detect any cryI-related sequences in this strain. There is, of course, still a possibility that a cryI-type gene, such as a cryIG gene (21), with a very low homology with our probe, is located upstream of the cryV gene. Most of the characterized crystal protein genes have been shown to be monocistronic, but there are some crystal protein genes that constitute an operon with other open reading frames, such as the cryIIA gene from B. thuringiensis subsp. kurstaki (27), and cry40 and cry32 genes from B. thuringiensis subsp. thompsoni (3). However, it is not likely that the cryI-cryV gene linkage is an operon structure, because the strong cryI transcriptional terminator is present in the intergenic sequence of the two genes. We cloned the cryV465 gene from B. thuringiensis subsp. entomocidus BP465 and found that a very similar gene was also present in B. thuringiensis subsp. galleriae HD29. It seems that strains BP465 and HD-29 are very similar in terms of the genotype of the crystal protein gene and some biochemical characteristics. Both strains have a cryID-like-cryV465 gene linkage. Strain HD-29 was reported to have a silent cryIC(b) gene (13), which had toxicity to Spodoptera exigua when the gene was expressed in E. coli cells. We found that strain BP465 also has the cryIC(b) gene (data not shown). Furthermore, the two strains showed the same results from four kinds of biochemical tests that were used for identification of B. thuringiensis (18): esculin utilization, acid formation from salicin and sucrose, and lecithinase production. However, the insecticidal activities of the sporulated cultures of these strains are clearly different. While strain BP465 had toxicity against S. exigua, strain HD29 had no significant toxic activity against Spodoptera species (13). The amino acid sequences of CryV1 and CryV465 proteins were highly homologous to each other, but only the CryV1 protein was toxic to B. mori. The specificity domain of CryItype proteins responsible for toxicity against B. mori had been located between residues 332 and 450 (8, 15). This region corresponds to domain II, which was proposed as the region involved in receptor binding (16). It is possible that the difference in toxicities between CryV1 and CryV465 against B. mori can be explained by the variability of amino acid sequences in domain II. However, amino acid differences between CryV1 and CryV465 appeared to occur randomly throughout the Nterminal 460 amino acid residues, and thus a detailed domain ACKNOWLEDGMENT This study was supported by grant N80980 from the Ministry of Science and Technology of Korea. REFERENCES 1. Birnboim, H. C., and J. Doly. 1979. A rapid alkaline extraction procedure for screening recombinant plasmid DNA. Nucleic Acids Res. 7:1513–1523. 2. Brizzard, B. L., and H. R. Whiteley. 1989. Nucleotide sequence of an additional crystal protein gene cloned from Bacillus thuringiensis subsp. thuringiensis. Nucleic Acids Res. 16:2723–2724. 3. Brown, K. L., and H. R. Whiteley. 1992. Molecular characterization of two novel crystal protein genes from Bacillus thuringiensis subsp. thompsoni. J. Bacteriol. 174:549–557. 4. Carozzi, N. B., V. C. Kramer, G. W. Warren, S. Evola, and M. G. Koziel. 1991. Prediction of insecticidal activity of Bacillus thuringiensis strains by polymerase chain reaction product profiles. Appl. Environ. Microbiol. 57: 3057–3061. 5. Chambers, J. A., A. Jelen, M. P. Gilbert, C. S. Jany, T. B. Johnson, and C. Gawron-Burke. 1991. Isolation and characterization of a novel insecticidal crystal protein gene from Bacillus thuringiensis subsp. aizawai. J. Bacteriol. 173:3966–3976. 6. Ferre, J., M. D. Real, J. Van Rie, S. Jansens, and M. Peferoen. 1991. Resistance to the Bacillus thuringiensis bioinsecticide in a field population of Plutella xylostella is due to a change in a midgut membrane receptor. Proc. Natl. Acad. Sci. USA 88:5119–5123. 7. Finney, D. J. 1971. Probit analysis. Cambridge University Press, Cambridge. 8. Ge, A. Z., N. I. Shivarova, and D. H. Dean. 1989. Location of the Bombyx mori specificity domain on a Bacillus thuringiensis d-endotoxin protein. Proc. Natl. Acad. Sci. USA 86:4037–4041. 9. Gleave, A. P., R. Williams, and R. J. Hedges. 1993. Screening by polymerase chain reaction of Bacillus thuringiensis serotypes for the presence of cryV-like insecticidal protein genes and characterization of a cryV gene cloned from B. thuringiensis subsp. kurstaki. Appl. Environ. Microbiol. 59:1683–1687. 10. Henikoff, S. 1984. Unidirectional digestion with exonuclease III creates targeted breakpoints for DNA sequencing. Gene 28:351–359. 11. Hofte, H., and H. R. Whiteley. 1989. Insecticidal crystal proteins of Bacillus thuringiensis. Microbiol. Rev. 53:242–255. 12. Inoue, H., H. Nojima, and H. Okayama. 1990. High efficiency transformation of Escherichia coli with plasmids. Gene 96:23–28. 13. Kalman, S., K. L. Kiehne, J. L. Libs, and T. Yamamoto. 1993. Cloning of a novel cryIC-type gene from a strain of Bacillus thuringiensis subsp. galleriae. Appl. Environ. Microbiol. 59:1131–1137. 14. Koo, B. Unpublished data. 15. Lee, M. K., R. E. Milne, A. Z. Ge, and D. H. Dean. 1992. Location of a Bombyx mori receptor binding region on a Bacillus thuringiensis d-endotoxin. J. Biol. Chem. 267:3115–3121. 16. Li, J., J. Carroll, and D. J. Ellar. 1991. Crystal structure of insecticidal d-endotoxin from Bacillus thuringiensis at 2.5 A resolution. Nature (London) 353:815–821. 17. Lowry, O. H., N. J. Rosebrough, A. L. Farr, and R. J. Randall. 1951. Protein Downloaded from http://aem.asm.org/ on January 13, 2012 by KRIBB(Korea Res Inst of Biosci & Biotech) Bombyx mori Plutella xylostella Phaedon brassicae Agelastica coerulae study with hybrid genes must be carried out to identify the specificity domain of B. mori. The CryV1 and CryV465 proteins did not show any toxic activity against the coleopteran insects tested, including alder leaf beetle, A. coerulae, which is sensitive to the CryIIIA protein (14). It seems that toxicity of the CryV protein against the Colorado potato beetle, reported by Tailor et al. (25), is the only reported case in which the CryV protein has toxicity against a coleopteran pest. Gleave et al. (9) also failed to prove the toxicity of their CryV protein against another coleopteran insect, Tenebrio molitor. Although we could not demonstrate the insecticidal activities of the CryV1 and CryV465 toxins against the two kinds of coleopteran insects, both toxin proteins, especially CryV1, showed significant toxic activity against Plutella xylostella. Plutella xylostella is a major vegetable pest, and substantial resistance to B. thuringiensis toxins has been found in the field (6, 22, 23). However, in most cases, resistance to one B. thuringiensis toxin does not confer cross-resistance to other toxins, which suggests that toxin proteins with different binding properties can be used to avoid resistance problems (6, 26). The toxicity of the CryV1 protein may be useful for management of Plutella xylostella strains that are resistant to existing B. thuringiensis preparations. VOL. 61, 1995 2407 (Lepidoptera: Plutellidae). J. Econ. Entomol. 83:1671–1676. 24. Tabashnik, B. E., N. Finson, C. F. Chilcutt, N. L. Cushing, and M. W. Johnson. 1993. Increasing efficiency of bioassays: evaluation of resistance to Bacillus thuringiensis in diamondback moth (Lepidoptera: Plutellidae). J. Econ. Entomol. 86:635–644. 25. Tailor, R., J. Tippett, G. Gibb, S. Pells, D. Pike, L. Jordan, and S. Ely. 1992. Identification and characterization of a novel Bacillus thuringiensis d-endotoxin entomocidal to coleopteran and lepidopteran larvae. Mol. Microbiol. 6:1211–1217. 26. Van Rie, J., W. H. McGaughey, D. E. Johnson, B. D. Barnett, and H. Van Mellaert. 1990. Mechanism of insect resistance to the microbial insecticide Bacillus thuringiensis. Science 247:72–74. 27. Widner, W. R., and H. R. Whiteley. 1989. Two highly related insecticidal crystal proteins of Bacillus thuringiensis subsp. kurstaki possess different host range specificities. J. Bacteriol. 171:965–974. Downloaded from http://aem.asm.org/ on January 13, 2012 by KRIBB(Korea Res Inst of Biosci & Biotech) measurement with the Folin phenol reagent. J. Biol. Chem. 193:265–275. 18. Martin, P. A. W., and R. S. Travers. 1989. Worldwide abundance and distribution of Bacillus thuringiensis isolates. Appl. Environ. Microbiol. 55: 2437–2442. 19. Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463–5467. 20. Smith, R. A., and G. A. Couche. 1991. The phylloplane as a source of Bacillus thuringiensis variants. Appl. Environ. Microbiol. 57:311–315. 21. Smulevitch, S. V., A. L. Osterman, A. B. Shevelev, S. V. Kaluger, A. I. Karasin, R. M. Kadyrov, O. P. Zagnitko, G. G. Chestukhina, and V. M. Stepanov. 1991. Nucleotide sequence of a novel d-endotoxin gene cryIg of Bacillus thuringiensis ssp. galleriae. FEBS Lett. 293:25–28. 22. Tabashnik, B. E. 1994. Evolution of resistance to Bacillus thuringiensis. Annu. Rev. Entomol. 39:47–79. 23. Tabashnik, B. E., N. L. Cushing, N. Finson, and M. W. Johnson. 1990. Field development of resistance to Bacillus thuringiensis in diamondback moth B. THURINGIENSIS cryV-TYPE GENES