棉铃虫P450基因CYP6AE12和CYP9A18的克隆与mRNA表达水平

采用RT-PCR和RACE技术克隆到2个新的棉铃虫细胞色素P450基因：CYP6AE12和CYP9A18。CYP6AE12的cDNA编码区长1 569 bp,编码523个氨基酸;CYP9A18的cDNA编码区长1 590 bp,编码530个氨基酸。用实时定量PCR技术分析了这2个基因在棉铃虫YS敏感品系和YS-FP抗性品系(由氰戊菊酯加辛硫磷混剂筛选YS品系而得) 6龄幼虫脂肪体和中肠中mRNA的表达水平。结果表明：CYP6AE12和CYP9A18的mRNA表达具有组织特异性,CYP6AE12在脂肪体中表达量较高,而CYP9A18在中肠中的表达量较高。与相对敏感品系YS相比,CYP6AE12在YS-FP抗性品系中肠和脂肪体中的mRNA表达量分别为YS品系的3.6倍和1.3倍;CYP9A18在YS-FP品系中肠和脂肪体的mRNA表达量分别为YS品系的0.3倍和1.0倍。CYP6AE12的过量表达与YS-FP品系棉铃虫的抗药性可能有一定关系。     

棉铃虫细胞色素P450 CYP6B7基因的克隆与融合表达

细胞色素P450 CYP6B7被推测与棉铃虫Helicoverpa armigera对拟除虫菊酯类杀虫剂的抗性有关,但至今尚无CYP6B7参与杀虫剂代谢方面的直接证据。为揭示CYP6B7的代谢功能,作者以棉铃虫幼虫基因组DNA 为模板,以CYP6B7基因设计特异性引物,扩增出包含321 bp内含子的CYP6B7基因。用反向PCR的方法消除内含子,获得包含完整的CYP6B7基因的开放阅读框。将CYP6B7基因与pMAL-c2X载体连接,并转化E.coli TB1细胞,在IPTG诱导下,CYP6B7能与载体基因编码的麦芽糖结合蛋白（MBP）在大肠杆菌中融合表达,表达产物经直链淀粉（amylose） 柱亲和层析分离洗脱后,得到SDS-PAGE电泳纯的融合蛋白。     

棉铃虫性染色体两种分子标记的克隆及序列分析

为了建立棉铃虫Helicoverpa armigera性染色体的特异性分子标记,利用RAPD-PCR技术对雌雄棉铃虫基因组DNA进行筛选,从500种随机引物中筛选到1 条引物（Operon编号为AF-18）,可扩增出1条约450 bp 的雌性特异片段。经克隆测序并合成特异引物进行验证,表明该片段为棉铃虫雌性特异分子标记,位于W染色体上。利用家蚕、果蝇等昆虫Kettin基因序列,克隆了棉铃虫的同源基因HaKettin片段,并采用荧光定量PCR技术,以棉铃虫的DH-PBAN基因为参照基因,检测棉铃虫雌雄不同个体间HaKettin基因与DH-PBAN基因的拷贝数之比,结果表明：雄体HaKettin∶DH-PBAN=1.0,雌体HaKettin∶DH-PBAN=0.5,据此推断HaKettin基因位于棉铃虫Z染色体上。     

蜕皮激素诱导下家蚕CYP3基因家族的表达变化

为了研究家蚕Bombyx mori CYP3家族基因经蜕皮激素诱导后的表达变化, 用蜕皮激素溶液（2×10^-3 μg/μL）浸泡的桑叶喂食家蚕B. mori 5龄幼虫, 以不用蜕皮激素处理的桑叶喂食家蚕为对照, 采用双跟踪标定定量PCR（dual-spike-in qPCR）方法, 检测在蜕皮激素诱导下家蚕中肠和脂肪体内CYP3基因家族的转录水平。结果表明: 与对照相比, 在蜕皮激素诱导下家蚕幼虫体内脂肪体中CYP302, CYP306和CYP339的转录水平分别上升了191.4, 7.4和421倍, 在中肠中变化不显著; 其余基因转录水平变化不明显或检测不到转录活性。结果说明CYP339基因有可能参与家蚕蜕皮激素的代谢, 这为进一步研究P450基因与内源物质的关系提供理论基础。     

家蚕细胞色素P450基因Bmcyp6u1的克隆、序列分析与表达谱

细胞色素P450第6亚家族基因为昆虫所特有,与抗性相关。为了检测家蚕Bombyx mori cyp6u1基因是否与耐氟性相关,首先克隆了cyp6u1基因。采用生物信息学方法获得与黑腹果蝇Drosophila melanogaster cyp6u1基因同源的家蚕B. mori cyp6u1基因序列, 预测该序列的开放阅读框（ORF）为1 476 bp, 编码491个氨基酸, 推定的蛋白质分子质量为56.15 kD, 等电点为9.23。以家蚕5龄第3天幼虫精巢cDNA为模板, 设计特异引物PCR扩增出一条约1 500 bp的条带, 大小与家蚕cyp6u1序列的ORF预测值接近, 命名为Bmcyp6u1基因（GenBank登录号：HM130560）。同源性分析表明, Bmcyp6u1基因与蜜蜂Apis mellifera的同源基因cyp6AS13的相似性为56%, 与拟南芥Arabidopsis thaliana的cyp72A82的相似性为48%, 与人Homo sapiens的cyp3A7基因的相似性为50%。芯片数据分析表明, Bmcyp6u1基因在家蚕5龄第3天幼虫各组织表达量很低, 只在精巢组织(5龄第3天)稍有表达, 推测该基因具有组织特异性。     

不同杀虫剂选育对家蝇抗药性水平及kdr基因频率的影响

采用杀虫剂（溴氰菊酯和甲基嘧啶磷）筛选及不接触药物自然衰退的方法,研究了家蝇Musca domestica氯氟氰菊酯高抗品系(Cyh-R)对杀虫剂的抗性变化,探讨蝇类抗药性治理的方法。用点滴法测定氯氟氰菊酯对不同家蝇品系的毒力,比较抗药性的变化,结合特异性等位基因PCR扩增（PASA）技术检测了不同家蝇品系的kdr基因频率,探讨kdr基因频率与抗性水平之间的关系。结果表明:甲基嘧啶磷筛选后,氯氟氰菊酯对第2~8代Cyh-R品系的LD₅₀呈递减趋势,从F₀的2.8434 μg/蝇降为F₈的0.4404 μg/蝇,但第8~18代Cyh-R品系的LD₅₀呈逐代递增趋势;溴氰菊酯筛选后,氯氟氰菊酯对Cyh-R品系第2~16代的LD₅₀呈上升趋势,从F₀的2.8434 μg/蝇升至F₁₆的24.3249 μg/蝇;表明了施用有机磷杀虫剂可降低其对氯氟氰菊酯的抗药性,而施用拟除虫菊酯药剂则有助于其对氯氟氰菊酯抗药性的增长;不使用任何杀虫剂也能降低其对氯氟氰菊酯的抗药性,但下降速率低于甲基嘧啶磷。PASA技术检测表明Cyh-R品系的kdr抗性基因频率为88.8%,不经过任何药剂筛选其kdr抗性基因频率下降程度最大,达到69.7%;甲基嘧啶磷筛选后其结果降为78.8%,而经溴氰菊酯筛选后kdr抗性基因频率则明显升高,达到98.9%。通过对kdr抗性基因频率和抗性水平进行相关和回归分析表明kdr抗性基因频率与家蝇对氯氟氰菊酯的LD₅₀呈对数关系,即LD₅₀值高的品系其kdr抗性基因频率相应的也较高。建议在家蝇防治中考虑轮换用药。     

感染稻水象甲的Wolbachia基因组中插入序列的鉴定与分析

共生细菌Wolbachia对宿主的生殖起多种调控作用。以往研究表明, Wolbachia基因组中广泛存在插入序列(insertion sequence, IS), 它们对宿主基因组的可塑性、 多样性和进化起重要作用。稻水象甲Lissorhoptrus oryzophilus Kuschel在东亚是一种外来水稻害虫, 在原产地北美营两性生殖, 而在所有入侵地均营孤雌生殖。本研究采用PCR法从河北唐海孤雌生殖型稻水象甲体内克隆获得了Wolbachia的2条IS序列, 即ISWosp4和ISWosp6; 从美国德克萨斯州两性生殖型稻水象甲成虫体内克隆获得了Wolbachia的2条IS序列, 即ISWosp3和ISWosp5。碱基序列比对显示: ISWosp3和ISWosp4属于IS3家族IS3组成员, ISWosp5为IS4家族IS231组成员, ISWosp6为IS5家族IS1031组成员。对这些IS的ORF结构、 所编码氨基酸序列的结构等进行了分析, 推测ISWosp5具有潜在转座活性。所得结果增进了我们对Wolbachia IS3, IS4和IS5家族插入序列的认识, 同时为今后从IS的角度探讨Wolbachia与稻水象甲生殖的关系奠定了基础。     

家蚕核型多角体病毒egt基因的分子进化分析

过PCR方法获得家蚕核型多角体病毒（Bombyx mori nuclearpolyhedrosis virus,BmNPV）的蜕皮甾体尿苷二磷酸葡萄糖基转移酶基因（egt）片段,序列分析表明该片段带有EGT的完整ORF,推测的多肽可形成EGT结构域的高级结构。为了研究egt的起源,利用家蚕基因组数据库,电子克隆了多个家蚕尿苷二磷酸葡萄糖醛酸转移酶（UGT）基因,在此基础上进行了进化分析,表明BmNPV的EGT为antennal-enriched型UGT;推测核型多角体病毒（nucleopolyhedrivirus,NPV）和颗粒体病毒（granulovirus,GV）的egt基因在进化上来源于昆虫的UGT基因,但GV的egt基因在进化上的起源可能要早于NPV的egt基因;可能在昆虫祖先种进化形成不同昆虫目的某一时期,杆状病毒的祖先种从昆虫中获得了antennal-enriched型UGT基因,并进化为egt基因。家蚕的部分UGT基因与转座子元件连锁的基因组结构特点反映了杆状病毒的egt基因可能通过转座子的传递而获得。     

斜纹夜蛾两个天蚕素D基因的克隆及序列分析

天蚕素是昆虫抵御病菌入侵的一类抗菌肽家族。根据斜纹夜蛾Spodoptera litura天蚕素B基因设计特异引物,通过PCR扩增得到2个新的天蚕素基因部分序列,分别命名为cecD1和cecD2（GenBank登录号分别为EF555567和EF555568）。2个基因编码同一个天蚕素D蛋白,该蛋白的成熟肽与天蚕素B存在2个氨基酸残基差异。序列分析发现cecD1和cecD2中分别包含568 bp和377 bp的内含子序列,它们有相同的5′和3′拼接位点,A+T含量分别为59.7%和69.8%,符合大多数真核生物内含子高A+T含量的特征。     

中国菲寄蝇属分类研究(双翅目: 寄蝇科)

经研究发现中国菲寄蝇属现共有9种,其中包括4新种：金额菲寄蝇Phebellia aurifrons sp. nov.,褐粉菲寄蝇Ph. fulvipollinis sp. nov.,宽叶菲寄蝇Ph. latisurstyla sp. nov.和毛基节菲寄蝇Ph. setocoxa sp. nov.。我国新记录3种：叶蜂菲寄蝇Ph. clavellariae (Brauer & Bergenstamm),灰粉菲寄蝇Ph. glauca (Meigen)和拟灰粉菲寄蝇Ph. glaucoides Herting。本文除详细描述新种特征及绘制特征图外,还提供中国菲寄蝇属已知种类的分种检索表。     

Pinpointing P450s associated with pyrethroid metabolism in the dengue vector, Aedes aegypti: developing new tools to combat insecticide resistance

Background

Pyrethroids are increasingly used to block the transmission of diseases spread by Aedes aegypti such as dengue and yellow fever. However, insecticide resistance poses a serious threat, thus there is an urgent need to identify the genes and proteins associated with pyrethroid resistance in order to produce effective counter measures. In Ae. aegypti, overexpression of P450s such as the CYP9J32 gene have been linked with pyrethroid resistance. Our aim was to confirm the role of CYP9J32 and other P450s in insecticide metabolism in order to identify potential diagnostic resistance markers.

Methodology/Principal Findings

We have expressed CYP9J32 in Escherichia coli and show that the enzyme can metabolize the pyrethroids permethrin and deltamethrin. In addition, three other Ae. aegypti P450s (CYP9J24, CYP9J26, CYP9J28) were found capable of pyrethroid metabolism, albeit with lower activity. Both Ae. aegypti and Anopheles gambiae P450s (CYP''s 6M2, 6Z2, 6P3) were screened against fluorogenic and luminescent substrates to identify potential diagnostic probes for P450 activity. Luciferin-PPXE was preferentially metabolised by the three major pyrethroid metabolisers (CYP9J32, CYP6M2 and CYP6P3), identifying a potential diagnostic substrate for these P450s.

Conclusions/Significance

P450s have been identified with the potential to confer pyrethroid resistance in Ae.aegypti. It is recommended that over expression of these enzymes should be monitored as indicators of resistance where pyrethroids are used.     

CYP9A17v2组成型过量表达参与棉铃虫对拟除虫菊酯的抗性

微粒体细胞色素P450氧化酶介导的解毒代谢增强是棉铃虫Helicoverpa armigera对拟除虫菊酯类杀虫剂产生抗性的主要原因。作者前期的研究表明, CYP9A12和CYP9A14组成型过量表达与棉铃虫YGF品系对拟除虫菊酯的高水平抗性相关, CYP9A12和CYP9A14的功能表达研究结果为其参与对拟除虫菊酯抗性提供了直接证据。本研究通过对棉铃虫CYP9A17v2的克隆、mRNA表达水平和功能表达的研究, 以期明确该基因是否参与棉铃虫对拟除虫菊酯的抗性。结果表明: CYP9A17v2与CYP9A12的氨基酸序列具有很高的相似性（94%）。与棉铃虫对照品系（YG）相比, CYP9A17v2在YGF抗性品系末龄幼虫脂肪体中具有10.9倍的组成型过量表达, 而在中肠中未发现过量表达。用酿酒酵母Saccharomyces cerevisiae异源表达的CYP9A17v2能够代谢多种拟除虫菊酯（顺式氰戊菊酯、溴氰菊酯和氟氯氰菊酯）。据此认为CYP9A17v2组成型过量表达参与了棉铃虫对拟除虫菊酯的抗性。至此, CYP9A亚家族中已有3个P450基因（CYP9A12, CYP9A14 和 CYP9A17v2）被证实参与了棉铃虫对拟除虫菊酯的氧化解毒代谢。     

Characterization of mosquito CYP6P7 and CYP6AA3: differences in substrate preference and kinetic properties

Cytochrome P450 monooxygenases are involved in insecticide resistance in insects. We previously observed an increase in CYP6P7 and CYP6AA3 mRNA expression in Anopheles minimus mosquitoes during the selection for deltamethrin resistance in the laboratory. CYP6AA3 has been shown to metabolize deltamethrin, while no information is known for CYP6P7. In this study, CYP6P7 was heterologously expressed in the Spodoptera frugiperda (Sf9) insect cells via baculovirus‐mediated expression system. The expressed CYP6P7 protein was used for exploitation of its enzymatic activity against insecticides after reconstitution with the An. minimus NADPH‐cytochrome P450 reductase enzyme in vitro. The ability of CYP6P7 to metabolize pyrethroids and insecticides in the organophosphate and carbamate groups was compared with CYP6AA3. The results revealed that both CYP6P7 and CYP6AA3 proteins could metabolize permethrin, cypermethrin, and deltamethrin pyrethroid insecticides, but showed the absence of activity against bioallethrin (pyrethroid), chlorpyrifos (organophosphate), and propoxur (carbamate). CYP6P7 had limited capacity in metabolizing λ‐cyhalothrin (pyrethroid), while CYP6AA3 displayed activity toward λ‐cyhalothrin. Kinetic properties suggested that CYP6AA3 had higher efficiency in metabolizing type I than type II pyrethroids, while catalytic efficiency of CYP6P7 toward both types was not significantly different. Their kinetic parameters in insecticide metabolism and preliminary inhibition studies by test compounds in the flavonoid, furanocoumarin, and methylenedioxyphenyl groups elucidated that CYP6P7 had different enzyme properties compared with CYP6AA3. © 2011 Wiley Periodicals, Inc.     

棉铃虫细胞色素P450 CYP9A12基因5′-上游区的克隆及序列分析

细胞色素P450基因CYP9A12的过量表达已被证实与棉铃虫Helicoverpa armigera对拟除虫菊酯的抗性相关。为探明棉铃虫CYP9A12基因的表达调控机理,根据棉铃虫CYP9A12基因cDNA全长的5′-末端核苷酸序列,采用基因组步移方法,获得CYP9A12的5′-上游区序列（总长为3 575 bp）。与cDNA序列进行比对,表明在起始密码子上游3 bp处有一长为2 124 bp的内含子。利用NNPP分析软件预测出转录起始位点,与根据CYP9A12全长cDNA序列推测的结果是一致的。TFSEARCH 1.3软件分析转录因子结合位点的结果显示,该序列不仅包含启动子的核心结构序列——TATA-box和CAAT-box,亦包含多个转录因子结合位点,如GATA-1,CdxA,Dfd等。本研究结果为深入研究棉铃虫CYP9A12的表达调控机制及其参与杀虫剂抗性的分子机理奠定了一定基础。     

Functional Expression of House Fly (Musca domestica) Cytochrome P450 CYP6D1 in Yeast (Saccharomyces cerevisiae)

Cytochrome P450 CYP6D1 from the house fly is important in the detoxication of xenobiotics and in resistance to pyrethroid insecticides. In house fly microsomes CYP6D1 requires cytochrome b₅ for the metabolism of some substrates, such as benzo[a]pyrene, but does not require cytochrome b₅ for the metabolism of other substrates such as methoxyresorufin. To examine the molecular mechanisms involved in its metabolism of pyrethroids and other substrates, a system for the heterologous expression of CYP6D1 in the yeast Saccharomyces cerevisiae was developed. Heterologous CYP6D1 can be inducibly expressed by culture in media with galactose as the sole carbon source, and is successfully inserted into the yeast microsomes. CYP6D1 is enzymatically active, as measured by methoxyresorufin-O-demethylation, indicating that CYP6D1 is able to interact with yeast P450 reductase. However, CYP6D1 expression did not result in measurable benzo[a]pyrene hydroxylation, suggesting that CYP6D1 cannot interact with yeast cytochrome b₅, or that there is insufficient cytochrome b₅ in the yeast microsomes to support this CYP6D1-mediated activity. Some suggestions are made for improving the yeast microsomal oxidoreductase environment in order to optimize CYP6D1 function.     

An overexpressed cytochrome P450 CYP439A1v3 confers deltamethrin resistance in Laodelphax striatellus Fallén (Hemiptera: Delphacidae)

Deltamethrin resistance in Laodelphax striatellus had been associated with its oxidative detoxification by overexpression of four cytochrome P450 monooxygenases like CYP353D1v2, CYP6FU1, CYP6AY3v2, and CYP439A1v3. The first three P450s have been validated for insecticide‐metabolizing capability and only CYP6FU1 was found to degrade deltamethrin. In this study, an investigation was conducted to confirm the capability of CYP439A1v3 to degrade deltamethrin. The CYP439A1v3 was first expressed in Sf9 cell line and its recombinant enzyme was tested for metabolic activity against different insecticides using substrate depletion assay combined with metabolite identification. Sodium dodecyl sulfate‐polyacrylamide gel electrophoresis (SDS‐PAGE) and carbon monoxide (CO)‐difference spectra analysis showed that the intact cytochrome P450 protein was successfully expressed. Tests with probe substrates proved its enzyme activity, as p‐nitroanisole, ethoxycoumarin, and ethoxyresorufin were preferentially metabolized (specific activity 7.767 ± 1.22, 1.325 ± 0.37, and 0.355 ± 0.37 nmol/min per mg of protein, respectively) while only luciferin‐HEGE was not. In vitro incubation of the recombinant CYP439A1v3 protein with deltamethrin revealed hydroxylation by producing hydroxydeltamethrin. On the contrary, no metabolite/metabolism was seen with nonpyrethroid insecticide, including imidacloprid, buprofezin, chlorpyrifos, and fipronil. To the best of our knowledge, this is the first study to link a CYP450 from family 439 to confer pyrethroid resistance to L. striatellus. This finding should help in the design of appropriate insecticide resistance management for control of this strain of L. striatellus.