家蚕羧酸酯酶基因克隆及差异表达

家蚕浓核病毒 (Bombyx mori densonucleosis virus,BmDNV)是蚕业生产上危害比较严重的一类病毒。用完全抗浓核病中国镇江株(BmDNV-Z)的家蚕品系秋丰、感性品系华八及以华八为轮回亲本回交8代和自交8代构建的近等基因系BC₈为材料,采用mRNA荧光差显技术首次分离克隆了家蚕羧酸酯酶（B. mori carboxylesterase,BmCarE）基因全长cDNA,并用实时荧光定量PCR检测了添毒后12 h、36 h、72 h BmCarE在感、抗BmDNV-Z家蚕品系中肠内的表达差异。结果表明： （1）添毒后12 h不同品系家蚕中肠BmCarE表达差异最大,抗性品系BC₈和秋丰分别是感性品系华八的17.714倍和3.602倍,三者彼此间的差异达到极显著水平;（2）同一品系添毒后12 h与添清水后12 h BmCarE表达也有较大差异, BC₈添毒是BC₈添清水的15.08倍, 秋丰添毒是秋丰添清水的3.39倍, 差异达到极显著水平,而华八添毒和添清水的BmCarE表达量均低,二者差异不显著;（3）同一品系添毒后不同时间BmCarE表达也有较大差异, BC₈和秋丰添毒后12 h BmCarE表达量最高,显著高于各自添毒后36 h和72 h表达水平,而添毒后36 h与72 h表达无显著差异;华八添毒后12 h、36 h和72 h,BmCarE表达无显著差异。上述结果提示羧酸酯酶基因可能与家蚕抗浓核病毒有一定关系。     

斜纹夜蛾羧酸酯酶基因的克隆、序列分析及表达水平

为了明确斜纹夜蛾Spodoptera litura对溴氰菊酯产生抗性的分子机理, 本研究利用RT-PCR技术和RACE方法获得了1个斜纹夜蛾羧酸酯酶基因的全长cDNA序列, 命名为Slest2。序列分析表明, 该cDNA全长1 796 bp（GenBank 登录号: DQ445461）, 5′和3′UTR区分别长63和119 bp,开放阅读框编码一个由537个氨基酸残基组成的羧酸酯酶蛋白。通过对氨基酸同源性分析表明, 该羧酸酯酶与其他物种的酯酶均具有很高的氨基酸相似性,并具有多个在不同酯酶蛋白家族中均保守的区域。采用实时定量PCR技术比较了Slest2在斜纹夜蛾抗、感品系中的表达水平。当以cDNA为模板检测mRNA转录水平时发现, Slest2在抗性品系中的转录水平是敏感品系的46.85倍; 以基因组DNA为模板检测Slest2基因的拷贝数时发现, Slest2在抗、感性品系中的拷贝数无显著差异（前者为后者的1.16倍）。这些结果表明, 抗性与敏感品系具有相似的Slest2基因拷贝数, 但它们在抗性品系中的转录水平显著升高。由此推测Slest2基因的转录水平升高与斜纹夜蛾对溴氰菊酯的抗药性密切相关。     

家蚕抗BmNPV品系与感性品系血淋巴液蛋白质组的差异分析

利用遗传学的原理, 通过杂交和回交的方法, 建立家蚕抗BmNPV、感BmNPV以及近等基因系模型, 利用2-D电泳和MALDI TOF/TOF MS质谱技术, 从蛋白质组水平上研究家蚕对BmNPV抵抗性。其结果是获得家蚕高抗NB, 高感306, 近等基因系BC8五龄起蚕血淋巴液蛋白质差异表达谱, 分别获得180、190、187个蛋白点, 其中80%的蛋白点集中在等电点5~9范围之内。从三块凝胶上共获得明显差异蛋白点12个, 由质谱鉴定出5种蛋白, 其中氨基酰化酶(Aminoacylase)仅出现在抗性品系NB、近等基因系图谱中, 感性品系没有出现, 初步推测是家蚕抗BmNPV特有蛋白, 这是首次报道结果。     

家蚕抗BmNPV品系与感性品系血淋巴液蛋白质组的差异分析

利用遗传学的原理, 通过杂交和回交的方法, 建立家蚕抗BmNPV、感BmNPV以及近等基因系模型, 利用2-D电泳和MALDI TOF/TOF MS质谱技术, 从蛋白质组水平上研究家蚕对BmNPV抵抗性。其结果是获得家蚕高抗NB, 高感306, 近等基因系BC8五龄起蚕血淋巴液蛋白质差异表达谱, 分别获得180、190、187个蛋白点, 其中80%的蛋白点集中在等电点5~9范围之内。从三块凝胶上共获得明显差异蛋白点12个, 由质谱鉴定出5种蛋白, 其中氨基酰化酶(Aminoacylase)仅出现在抗性品系NB、近等基因系图谱中, 感性品系没有出现, 初步推测是家蚕抗BmNPV特有蛋白, 这是首次报道结果。     

中国野蚕一种强抗病毒蛋白的基因分析和活性鉴定

以最近报道的家蚕抗病毒蛋白基因为线索,从中国野蚕（Bombyx mandarina Moore）中肠内克隆了抗家蚕BmNPV病毒的SP-2 cDNA（GenBank登录号：AY945210）,基因大小855bp,编码284个氨基酸的蛋白质,分子量29．6kD,基因组全长1376bp,包含5个外显子和4个内含子．该基因的表达仅限于中肠,具有组织特异性,在幼虫龄中表达水平较高,而在眠期和熟蚕没有表达．推导其氨基酸序列,发现其C端氨基酸序列与已报道的家蚕相应序列差别较大,有8个氨基酸完全不同．通过体外重组技术,由高效基因表达系统获得大量重组蛋白,发现该蛋白具有很强的抗家蚕BmNPV活性,与家蚕对应的抗病毒蛋白BmSP-2相比,其抗BmNPV活性高1．6倍．初步认为,该蛋白质C端序列差异可能是造成家蚕与野蚕抗病毒活性差别的主要原因．     

甜菜夜蛾泛素延伸蛋白基因cDNA的3′RACE-PCR扩增及其克隆和表达

根据已知的草地夜蛾Spodoptera frugiperda的泛素延伸基因 5'端核苷酸序列设计引物,应用3'RACE-PCR技术,从甜菜夜蛾S. exigua脂肪体组织总RNA中反转录扩增泛素基因的cDNA片段。扩增得到的片段全长513 bp,3'末端有123 bp的非翻译区,翻译区编码一个长为129个氨基酸残基的蛋白质,预测分子量为14.8 kD。同源分析表明,此cDNA序列为ubiquitin-53aa extension protein(ubi-53) 基因,在泛素蛋白后融合了一个核糖体L40蛋白（ribosomal L40 protein）。用MagAlign和Genedoc软件对cDNA编码的氨基酸序列进行了同源性分析,结果表明： 甜菜夜蛾的ubi-53基因与真核生物家蚕Bombyx mori、草地夜蛾、果蝇Drosophila melanogaster和人Homo sapienes泛素的同源性分别为96.9%、98.5%、95.3%和93.0%,与甜菜夜蛾核型多角体病毒(SeNPV)泛素的同源性为78.8%,说明真核生物的泛素基因与核型多角体病毒的泛素基因可能存在不同的分子进化途径。将甜菜夜蛾的ubI-53基因克隆到原核表达载体pET-28a上,转化至BL21（DE3）中,用IPTG进行诱导表达,用异源泛素单克隆抗体进行Western blot检测,证明原核表达蛋白是目的蛋白。     

家蚕中肠组织抗核型多角体病毒病的相关蛋白分析

家蚕中肠上皮是病毒经口侵入遇到的第一个组织。昆虫幼虫抵御杆状病毒的感染,可通过选择性的使感染的中肠上皮细胞发生调亡并在释放病毒粒子进入血淋巴之前使感染的细胞从中肠脱落。为研究家蚕抗核型多角体病毒(Bombyx mori nucleopolyhedrovirus, BmNPV)病的机制,通过对BmNPV高度抗性和高度敏感性的家蚕品系杂交和回交构建了近等基因系。本文对家蚕高抗,敏感及近等基因系5龄起蚕中肠组织的蛋白质表达谱进行了二维电泳 (two-dimensional gel electrophoresis,2-DE) 分析,并利用基质辅助激光解吸电离飞行时间 (matrix-assisted laser desorption/ionization-time of flight, MALDI-TOF) 质谱对差异蛋白进行鉴定。结果发现了5个差异表达的蛋白。推测这些蛋白可能与家蚕中肠对BmNPV的抗性或感性有关。     

家蚕CVDAR品系对BmNPV的抗性特征分析

【目的】家蚕核型多角体病毒(Bombyx mori nucleopolyhedrovirus,BmNPV)促使的血液型脓病是一种产业上非常严重的家蚕疾病,目前有效的防控方法较少。本研究以大造和CVDAR家蚕品系(对BmNPV有较强抗性的品系)为试验材料,通过分析CVDAR对BmNPV抗性特征,以期确定CVDAR对BmNPV的抗性机制。【方法】本研究通过半致死剂量分析,发现CVDAR品系比大造品系对BmNPV感染的半致死剂量提高10倍以上;进一步HE染色分析大造与CVDAR品系病毒感染前后的中肠组织的变化,具体解析抗性品系CVDAR的抗BmNPV机制。【结果】感染BmNPV 72 h后,大造中肠细胞细胞核明显膨大,着色变浅,到96h后,细胞核持续增大有脱落趋势;而CVDAR抗性品系只在感染96 h后有中肠部分细胞核膨大,但排列整齐;同时通过荧光定量分析大造与CVDAR品系病毒感染后的增殖情况,结合各个时期代表病毒基因的转录水平分析比较发现,感染BmNPV后0–12h也没有发现抗性品系CVDAR和大造之间的病毒拷贝数以及病毒基因转录水平的不同,但感染24h后发现抗性品系CVDAR无论是病毒拷贝数还是病毒基因的转录表达水平都明显低于对照大造。【结论】证明CVDAR口服添毒后中肠中病毒基因的转录在第一轮复制期间不受影响,之后转录水平降低。鉴定CVDAR品系抑制BmNPV增殖的关键时期是在感染BmNPV后的24 h,为解析抗性机制奠定基础。     

利用Red系统快速敲除家蚕核型多角体病毒orf60基因

用Red重组系统和最近构建的家蚕核型多角体病毒（BmNPV）bacmid在大肠杆菌BW25113中快速地敲除BmNPV orf60基因。从大肠杆菌BmDH10Bac中提取BmNPV bacmid,将其电转化到含有质粒pKD46（能表达Red重组酶）的大肠杆菌菌株BW25113中,获得了可用于BmNPV基因打靶的菌株BW25113-Bac。设计一对长63bp的引物（5′端为orf60基因的左右同源臂,长45bp;3′端长18bp,为氯霉素抗性基因（cat）的首尾序列）,以pKD3质粒（含cat）为模板,PCR扩增携带orf60左右同源臂的cat,即打靶线性化片段。将该线性化片段电转入BW25113-Bac菌株,在Red重组酶的作用下,线性化片段与BmNPV bacmid中的orf60基因发生同源重组。设计3对特异引物,用PCR方法证明cat成功地替换了BmNPV orf60基因。重组bacmid DNA转染BmN细胞后,Western blot分析未检测到orf60基因的表达。     

Identification and characterization of an NPV infection-related gene Bmsop2 in Bombyx mori L.

Abstract:  Using the fluorescent differential display technique, we analysed the differential expression of genes related to Bombyx mori nuclear polyhedrosis virus (BmNPV) resistance. Silkworm strains studied included the highly resistant strain NB, highly susceptible strain 306 and near-isogenic line 306NNZZ. One novel gene was identified and named Bmsop2 for its high similarity with the Sop2 protein of other species. It was identified to be linked to BmNPV susceptibility by Northern blotting and real-time polymerase chain reaction. The results indicated that it was actively expressed in midguts of strains 306, NB and the eighth generation of backcross (BC₈) of strain 306NNZZ which had been treated with BmNPV. But the expression level was low in the midguts of the control. In the mean time, the expression of Bmsop2 was the highest in strain 306 treated with BmNPV while it was the lowest in strain 306 not treated with BmNPV. Our study showed that Bmsop2 is a differentially expressed gene in strains NB, 306 and 306NNZZ which have different levels of resistance to BmNPV.     

Comparative proteomic analysis reveals that caspase-1 and serine protease may be involved in silkworm resistance to Bombyx mori nuclear polyhedrosis virus

The silkworm Bombyx mori is of great economic value. The B. mori nuclear polyhedrosis virus (BmNPV) is one of the most common and severe pathogens for silkworm. Although certain immune mechanisms exist in silkworms, most silkworms are still susceptible to BmNPV infection. Interestingly, BmNPV infection resistance in some silkworm strains is varied and naturally existing. We have previously established a silkworm strain NB by genetic cross, which is highly resistant to BmNPV invasion. To investigate the molecular mechanism of silkworm resistance to BmNPV infection, we employed proteomic approach and genetic cross to globally identify proteins differentially expressed in parental silkworms NB and 306, a BmNPV-susceptible strain, and their F(1) hybrids. In all, 53 different proteins were found in direct cross group (NB♀, 306♂, F(1) hybrid) and 21 in reciprocal cross group (306♀, NB♂, F(1) hybrid). Gene ontology and KEGG pathway analyses showed that most of these different proteins are located in cytoplasm and are involved in many important metabolisms. Caspase-1 and serine protease expressed only in BmNPV-resistant silkworms, but not in BmNPV-susceptible silkworms, which was further confirmed by Western blot. Taken together, our data suggests that both caspase-1 and serine protease play a critical role in silkworm resistance against BmNPV infection.     

V-ATPase Is Involved in Silkworm Defense Response against Bombyx mori Nucleopolyhedrovirus

Silkworms are usually susceptible to the infection of Bombyx mori (B. mori) nucleopolyhedrovirus (BmNPV), which can cause significant economic loss. However, some silkworm strains are identified to be highly resistant to BmNPV. To explore the silkworm genes involved in this resistance in the present study, we performed comparative real-time PCR, ATPase assay, over-expression and sub-cellular localization experiments. We found that when inoculated with BmNPV both the expression and activity of V-ATPase were significantly up-regulated in the midgut column cells (not the goblet cells) of BmNPV-resistant strains (NB and BC8), the main sites for the first step of BmNPV invasion, but not in those of a BmNPV-susceptible strain 306. Furthermore, this up-regulation mainly took place during the first 24 hours post inoculation (hpi), the essential period required for establishment of virus infection, and then was down-regulated to normal levels. Amazingly, transient over-expression of V-ATPase c subunit in BmNPV-infected silkworm cells could significantly inhibit BmNPV proliferation. To our knowledge this is the first report demonstrating clearly that V-ATPase is indeed involved in the defense response against BmNPV. Our data further suggests that prompt and potent regulation of V-ATPase may be essential for execution of this response, which may enable fast acidification of endosomes and/or lysosomes to render them competent for degradation of invading viruses.     

家蚕瘫痪肽结合蛋白基因克隆与分析

ENF肽家族具有保守的N末端结构（Glu—Asn—Phe-）。该家族成员肽大多具有重叠功能活性,在鳞翅目昆虫的免疫反应,生长调控和自体调节等方面都发挥着重要的作用。在昆虫的免疫反应中,血细胞尤其是淋巴液的黏附性是针对外来侵入物的免疫应答过程中的重要因素。家蚕瘫痪肽（paralytic peptide）是ENF肽家族的一种,其具有多种的生物学活性,包括致瘫痪性及在家蚕血细胞免疫反应中的促吞噬细胞扩散活性。ENF肽家族的另一成员,粘虫（Pseudaletia separata）的生长阻抑肽（Growth-blocking peptide）,同家蚕瘫痪肽一样能够在粘虫的血细胞免疫反应中起到调节吞噬细胞的功能。目前,关于昆虫细胞免疫应答的终端调控分子机制的研究还比较少,有文献报道粘虫的生长阻抑肽结合蛋白（GBP—BP）能够起到沉默生长阻抑肽活性的功能,从而可能参与调节细胞免疫应答的终端调控。在本研究中,利用荧光差异显示技术（FDD）分析了家蚕感染BmNPV病毒后基因表达差异情况,在血淋巴中获得了一条差异条带G12782＊通过5＇-RACE技术,首次在家蚕中克隆得到了该基因的全长cDNA序列。通过同源性分析得知,该基因所编码的蛋白质与粘虫的生长阻抑肽结合蛋白具有很大的同源性,并被命名为家蚕瘫痪肽结合蛋白（Bmori paralytic peptide binding protein,PP-BP）。通过RT-PCR研究发现,该蛋白基因在血淋巴中大量表达。同时,利用实时荧光定量PCR（Real-time quantitative PCR）技术分析了该基因在正常饲养家蚕与添食BmNPV病毒的家蚕中的表达差异,结果显示该基因在家蚕添食BmNPV病毒后的表达量大大增强,这就暗示该基因可能与BmNPV病毒刺激后所引起的家蚕血液细胞免疫反应相关。利用生物信息学方法对该基因的结构进行了分析,发现该基因具有两个外显子和一个内含子。这个基因已经登入GenBank数据库,收入号为DQ306881。     

Molecular characterization and expression analysis of BmNOX in two strains of Bombyx mori with contrasting viral resistance phenotype

We recently documented the identification of a 26.5 kDa protein named BmNox in the gut fluid of Nistari strain of Bombyx mori, which possessed antiviral activity against BmNPV in vitro. In this report, we report the characterization of the full‐length gene encoding BmNOX and the levels of expression of this gene in select tissues of silkworm larvae from a BmNPV‐susceptible and a BmNPV‐resistant strain to the defense capability in Bombyx mori larvae challenged with BmNPV. We also evaluated the BmNox expression in various stages of larval life of a resistant and a susceptible strain of Bombyx mori selected from among a panel of strains of silkworm. Nistari, a multivoltine strain of silkworm, expressed BmNOX during all five larval stages, and were highly resistant to BmNPV infection. In sharp contrast, CSR₂, a bivoltine strain, showed weaker expression of BmNOX in the anterior midgut in larval life and was highly susceptible to BmNPV infection. BmNOX is a secretory protein with dual expression in gut fluid and mid gut tissue. BmNOX is expressed heavily in the posterior mid gut, with weaker expression in the fore‐ and mid‐gut regions. © 2010 Wiley Periodicals, Inc.     

Arginine kinase is highly expressed in a resistant strain of silkworm (Bombyx mori, Lepidoptera): Implication of its role in resistance to Bombyx mori nucleopolyhedrovirus

A gene encoding Bombyx mori arginine kinase (BmAK) has been indentified differentially expressed in the midguts of Bombyx mori strain NB which is resistant to nucleopolyhedrovirus (BmNPV), strain 306 which is susceptible to NPV and a near isogenic line BC(8) with similar genetic background to 306 but resistant to NPV by two-dimensional gel electrophoresis (2-DE). In this study, we characterized the expression profiles of BmAK using RT-PCR and real-time quantitative PCR. The expression level of BmAK fluctuated in various developing stage and various tissue. Remarkably, the expression level of BmAK increased more than 10-fold 24 hours post inoculation (h p.i.) of NPV in strain NB and BC(8), while such increment was abraded in strain 306 although the basal expression level of BmAK in strain 306 was higher than that of strain NB and BC(8). Western blotting analysis using polyclonal antibody against BmAK verified such observation, and immunofluoresence analysis indicated for the first time that BmAK was mainly located to the cytoplasm or some structures in cytoplasm. These findings suggest that arginine kinase is involved in the antiviral process of Bombyx mori larvae against NPV infection.