P74 mediates specific binding of Autographa californica M nucleopolyhedrovirus occlusion-derived virus to primary cellular targets in the midgut epithelia of Heliothis virescens Larvae

P74, an envelope protein of the occlusion-derived virus (ODV) of Autographa californica M nucleopolyhedrovirus (AcMNPV), is critical for oral infection of Trichoplusia ni larvae. The role of P74 during primary infection, however, is unknown. Here we provide evidence that P74 facilitates binding of AcMNPV ODV to a specific receptor within the larval midgut epithelia of another host species, Heliothis virescens. We adapted a fluorescence dequenching assay to compare binding, fusion, and competition of wild-type AcMNPV ODV in vivo with itself and with the ODV of a p74-deficient AcMNPV mutant. We found that relative to wild-type ODV, binding and fusion of ODV deficient in P74 were both qualitatively and quantitatively different. Unlike wild-type ODV, an excess of P74-deficient ODV failed to compete effectively with wild-type ODV binding, and the overall binding level of the mutant ODV was one-third that of the wild type. These results implicated P74 as an ODV attachment protein that binds to a specific receptor on primary target cells within the midgut.     

Characterization of novel components of the baculovirus per os infectivity factor complex

Baculovirus occlusion-derived virus (ODV) infects insect midgut cells under alkaline conditions, a process mediated by highly conserved per os infectivity factors (PIFs), P74 (PIF0), PIF1, PIF2, PIF3, PIF4, and PIF5 (ODV-E56). Previously, a multimolecular complex composed of PIF1, PIF2, PIF3, and P74 was identified which was proposed to play an essential role during ODV entry. Recently, more proteins have been identified that play important roles in ODV oral infectivity, including PIF4, PIF5, and SF58, which might work in concert with previously known PIFs to facilitate ODV infection. In order to understand the ODV entry mechanism, the identification of all components of the PIF complex is crucial. Hence, the aim of this study was to identify additional components of the PIF complex. Coimmunoprecipitation (CoIP) combined with proteomic analysis was used to identify the components of the Autographa californica multiple nucleopolyhedrovirus (AcMNPV) PIF complex. PIF4 and P95 (AC83) were identified as components of the PIF complex while PIF5 was not, and this was confirmed with blue native PAGE and a second CoIP. Deletion of the pif4 gene impaired complex formation, but deletion of pif5 did not. Differentially denaturing SDS-PAGE further revealed that PIF4 forms a stable complex with PIF1, PIF2, and PIF3. P95 and P74 are more loosely associated with this complex. Three other proteins, AC5, AC68, and AC108 (homologue of SF58), were also found by the proteomic analysis to be associated with the PIF complex. Finally the functional significance of the PIF protein interactions is discussed.     

In situ cleavage of baculovirus occlusion-derived virus receptor binding protein P74 in the peroral infectivity complex

Proteolytic processing of viral membrane proteins is common among enveloped viruses and facilitates virus entry. The Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) occlusion-derived virus (ODV) protein P74 is part of a complex of essential peroral infectivity factors (PIFs). Here we report that P74 is efficiently cleaved into two fragments of about equal size by an occlusion body (OB) endogenous alkaline protease during ODV release when AcMNPV OBs are derived from larvae. The cleavage is specific for P74, since the other known peroral infectivity factors in the same complex (PIF1, PIF2, and PIF3) were not cleaved under the same conditions. P74 cleavage was not observed in OBs produced in three different insect cell lines, suggesting a larval host origin of the responsible protease. P74 in OBs produced in larvae of two different host species was cleaved into fragments with the same apparent molecular mass, indicating that the virus incorporates a similar alkaline protease from different hosts. Coimmunoprecipitation analysis revealed that the two P74 subunit fragments remain associated with the recently discovered PIF complex. We propose that under in vivo ODV infection conditions, P74 undergoes two sequential cleavage events, the first one being performed by an ODV-associated host alkaline protease and the second carried out by trypsin in the host midgut.     

Baculovirus Per Os Infectivity Factors Form a Complex on the Surface of Occlusion-Derived Virus

Five highly conserved per os infectivity factors, PIF1, PIF2, PIF3, PIF4, and P74, have been reported to be essential for oral infectivity of baculovirus occlusion-derived virus (ODV) in insect larvae. Three of these proteins, P74, PIF1, and PIF2, were thought to function in virus binding to insect midgut cells. In this paper evidence is provided that PIF1, PIF2, and PIF3 form a stable complex on the surface of ODV particles of the baculovirus Autographa californica multinucleocapsid nucleopolyhedrovirus (AcMNPV). The complex could withstand 2% SDS-5% β-mercaptoethanol with heating at 50°C for 5 min. The complex was not formed when any of the genes for PIF1, PIF2, or PIF3 was deleted, while reinsertion of these genes into AcMNPV restored the complex. Coimmunoprecipitation analysis independently confirmed the interactions of the three PIF proteins and revealed in addition that P74 is also associated with this complex. However, deletion of the p74 gene did not affect formation of the PIF1-PIF2-PIF3 complex. Electron microscopy analysis showed that PIF1 and PIF2 are localized on the surface of the ODV with a scattered distribution. This distribution did not change for PIF1 or PIF2 when the gene for PIF2 or PIF1 protein was deleted. We propose that PIF1, PIF2, PIF3, and P74 form an evolutionarily conserved complex on the ODV surface, which has an essential function in the initial stages of baculovirus oral infection.The entry mechanism of enveloped viruses includes two major steps: virus binding to host receptors and subsequent fusion of the viral membrane with the cell membrane. For many viruses the processes of binding and fusion are mediated by a machinery composed of several membrane proteins working in concert with sequential events triggered by conformational changes upon interaction with host (co)receptors. Examples are herpes simplex virus (HSV) (4) and vaccinia virus (23), which have an entry machinery composed of four and eight proteins, respectively. The entry of the occlusion-derived virus (ODV) form of baculoviruses into insect midgut epithelial cells upon oral infection of insect larvae may involve a similar strategy, but little is known about the role of ODV membrane proteins.Baculovirus ODVs are orally infectious, enveloped virus particles embedded in a protein crystal called an occlusion body (OB) that infect midgut epithelial cells (24). After ingestion of OBs by the host, the proteinaceous OB crystal dissolves quickly due to the alkaline conditions (pH 10 to 11) in the midgut, and the ODV particles are released (reviewed in reference 24). After passage through the peritrophic membrane, ODVs bind and fuse with the microvilli of columnar epithelial cells, resulting in the release of nucleocapsids into the cytosol and subsequent initiation of infection (10, 12, 24). A second type of virus particle, the budded virus (BV), is produced in these cells and infects other cells and tissues in the insect, causing a systemic infection (reviewed in reference 22). While the entry mechanisms of BVs have been studied at least to a certain extent (16, 31, 32), the entry mechanism of ODVs is still rather enigmatic due to its complexity and the lack of proper cell lines supporting ODV entry.ODVs contain more than 10 different envelope proteins (3). Five of these, denoted PIF1, PIF2, PIF3, PIF4, and P74, have been identified to be essential for per os infection of insect larvae (6, 7, 14, 18, 20). These PIF proteins function in the early stage of virus infection, and deletion of any of these pif genes leads to a block in infection prior to viral gene expression in midgut epithelial cells (7, 10, 18). Until now, three of these proteins, PIF1, PIF2, and P74, have been reported to function in virus binding (10, 18). Deletion of any of these three proteins leads to a loss of oral infectivity, while only a 3-fold reduction in binding is measured, and no significant reduction in fusion efficiency is observed (10, 18). This suggests that the three PIF proteins, apart from binding to midgut epithelial cells, may have other unknown functions for which they may have to work together. The functions of PIF3 and PIF4 are rather enigmatic although there has been speculation that PIF3 functions in nucleocapsid translocation along the microvilli as it seemed to be dispensable for ODV binding and fusion (18, 24).All five proteins are highly conserved in Baculoviridae and are encoded by so-called core genes (3, 6, 11, 29). Recent work further revealed that these proteins have homologues in other large invertebrate DNA viruses which replicate in the nucleus, such as salivary gland hypertrophy viruses (SGHVs) (9), nudiviruses (30) and white spot syndrome virus (WSSV) (Nimaviridae) (J. A. Jehle, personal communication). pif genes are also found in polydnaviruses of braconid wasps (2). This high conservation of pif genes in a diverse range of large, circular, double-stranded DNA viruses suggests that the PIF proteins are associated with a conserved and evolutionarily ancient entry mechanism of viruses into invertebrate hosts.The aim of the present study is to follow the ODV entry process by investigating whether the PIF proteins form a complex on the ODV membrane. Based on immunogold labeling, cross-linking, differential temperature SDS-PAGE, and coimmunoprecipitation (CoIP) analysis with a panel of recombinant viruses, we provide strong evidence that PIF1, PIF2, PIF3, and P74 form a complex on the ODV surface. This complex is likely to play an essential role in virus entry into midgut epithelial cells of susceptible insect larvae.     

Autographa californica Nucleopolyhedrovirus Ac76: a Dimeric Type II Integral Membrane Protein That Contains an Inner Nuclear Membrane-Sorting Motif

Our previous study showed that the Autographa californica Nucleopolyhedrovirus (AcMNPV) ac76 gene is essential for both budded virion (BV) and occlusion-derived virion (ODV) development. More importantly, deletion of ac76 affects intranuclear microvesicle formation. However, the exact role by which ac76 affects virion morphogenesis remains unknown. In this report, we characterized the expression, distribution, and topology of Ac76 to further understand the functional role of Ac76 in virion morphogenesis. Ac76 contains an α-helical transmembrane domain, and phase separation showed that it was an integral membrane protein. In AcMNPV-infected cells, Ac76 was detected as a stable dimer that was resistant to SDS and thermal denaturation, and only a trace amount of monomer was detected. A coimmunoprecipitation assay demonstrated the dimerization of Ac76 by high-affinity self-association. Western blot analyses of purified virions and their nucleocapsid and envelope fractions showed that Ac76 was associated with the envelope fractions of both BVs and ODVs. Immunoelectron microscopy revealed that Ac76 was localized to the plasma membrane, endoplasmic reticulum (ER), nuclear membrane, intranuclear microvesicles, and ODV envelope. Amino acids 15 to 48 of Ac76 were identified as an atypical inner nuclear membrane-sorting motif because it was sufficient to target fusion proteins to the ER and nuclear membrane in the absence of viral infection and to the intranuclear microvesicles and ODV envelope during infection. Topology analysis of Ac76 by selective permeabilization showed that Ac76 was a type II integral membrane protein with an N terminus exposed to the cytosol and a C terminus hidden in the ER lumen.     

Early synthesis of budded virus envelope fusion protein GP64 enhances Autographa californica multicapsid nucleopolyhedrovirus virulence in orally infected Heliothis virescens

Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV), the type species of the Nucleopolyhedrovirus genus (Baculoviridae family), has two highly unusual traits shared by several baculovirus species. First, the occlusion-derived virus (ODV) that establishes primary infection in the midgut following its ingestion by host larvae contains multiple nucleocapsids, all of which enter the same midgut cell. Second, GP64, the envelope fusion protein of the budded virus (BV) that spreads infection beyond the midgut, is synthesized both early and late during infection. We tested the hypothesis that, together, these two traits enable parental ODV nucleocapsids to bud from infected midgut cells, essentially as BV, to establish secondary infections prior to completion of viral replication within the midgut. This "pass-through" strategy would enable the virus to counter the host's principal defense, sloughing of infected midgut cells, by accelerating the onset of systemic infections. To test this hypothesis, we created an AcMNPV recombinant, AcLate21/20-64HB, that can express gp64 only during the late phase of infection (coincident with the other structural proteins). We then compared the virulence of this virus to that of a control recombinant virus that expresses gp64 in a wild-type manner. We found that when administered orally, the control virus was far more virulent and established secondary infection earlier than AcLate21/20-64HB, but when administered intrahemocoelically, infectivity and virulence of the two recombinants were identical. Our results demonstrate that early gp64 expression is a key component of a unique and highly adaptive baculovirus infection strategy.     

昆虫包涵体衍生病毒囊膜蛋白的分子生物学

了解杆状病毒的囊膜蛋白对揭示病毒入侵、 囊膜蛋白核定向转运机制以及研究控制昆虫新策略等方面具有重要意义。 目前研究表明,包涵体衍生病毒(occlusion-derived virus, ODV)的囊膜蛋白包括ODV-E25, ODV-E66, ODV-E56, ODV-E18, ODV-E28, P74, PIF1, PIF2, PIF3, GP41, ODV-EC27, ODV-E35, ODV-EC43,BV/ODV-E26,P91和ORF150。 本文结合国内外的研究成果系统的综述了囊膜蛋白的结构和功能,其在经口感染、调节细胞周期和囊膜蛋白的传送等方面起作用。 囊膜蛋白的核定向转运机制,ODV与昆虫中肠之间和包涵体基质之间相互作用以及ODV结构蛋白之间的相互作用等将是今后的研究重点。     

Characterization of two Autographa californica nucleopolyhedrovirus proteins, Ac145 and Ac150, which affect oral infectivity in a host-dependent manner

The genome of the baculovirus Autographa californica nuclear polyhedrosis virus (AcMNPV) contains two homologues, orf145 and orf150, of the Heliothis armigera Entomopoxvirus (HaEPV) 11,000-kDa gene. Polyclonal antibodies raised against the Ac145 or Ac150 protein were utilized to demonstrate that they are expressed from late to very late times of infection and are within the nuclei of infected Sf-21 cells. Transmission electron microscopy coupled with immunogold labeling of Ac145 found this protein within the nucleus in areas of nucleocapsid assembly and maturation, along with some association with the enveloped bundles of virions within the developing occlusion bodies (OBs). Ac150 was found to be mainly associated with enveloped bundles of virions within OBs and also with those not yet occluded. Both Ac145 and Ac150 were found to be present in budded virus as well as OBs. Both orf145 and orf150 were deleted from the AcMNPV genome, singly or together, and these deletion mutants were assessed for oral infectivity both in Trichoplusia ni and Heliothis virescens larvae. Deletion of Ac145 led to a small but significant drop in infectivity (sixfold) compared to wild-type (wt) AcMNPV for T. ni but not for H. virescens. Deletion of Ac150 alone had no effect on infectivity of the virus for either host. However, deletion of both Ac145 and Ac150 gave a recombinant virus with a drastic (39-fold) reduction in infectivity compared to wt virus for H. virescens. Intrahemocoelic injection of budded virus from the double-deletion virus into H. virescens larvae is as infectious to this host as wt budded virus, indicating that Ac145 and Ac150 play a role in primary oral infection of AcMNPV, the extent of which is host dependent.     

Baculovirus per os Infectivity Factors Are Involved in HearNPV ODVs Infection of HzAM1 Cells in vitro

Baculoviruses produce two viral phenotypes, the budded virus (BV) and the occlusion-derived virus (ODV). ODVs are released from occlusion bodies in the midgut where they initiate a primary infection. Due to the lack of an in vitro system, the molecular mechanism of ODV infection is still unclear. Here we present data demonstrating that Helicoverpa armigera nucleopolyhedrovirus (HearNPV) ODV infected cultured Hz-AM1 cells in a pH dependent manner. The optimal pH for ODV infection was 8.5, which is same to that in the microvilli of midgut epithelial cells, the ODV native infection sites. Antibodies neutralization analysis indicated that four HearNPV oral infection essential genes p74, pif-1, pif-2 and pif-3 are also essential for HearNPV ODV infection in vitro. Thus, HearNPV-HzAM1 system can be used to analyze the mechanism of ODV entry.     

Baculovirus per os Infectivity Factors Are Involved in HearNPV ODVs Infection of HzAM1 Cells in vitro

Baculoviruses produce two viral phenotypes, the budded virus （BV） and the occlusion-derived virus （ODV）. ODVs are released from occlusion bodies in the midgut where they initiate a primary infection. Due to the lack of an in vitro system, the molecular mechanism of ODV infection is still unclear. Here we present data demonstrating that Helicoverpa armigera nucleopolyhedrovirus （HearNPV） ODV infected cultured Hz-AM1 cells in a pH dependent manner. The optimal pH for ODV infection was 8.5, which is same to that in the microvilli of midgut epithelial cells, the ODV native infection sites. Antibodies neutralization analysis indicated that four HearNPV oral infection essential genes p74, pif-l, pif-2 and pif-3 are also essential for HearNPV ODV infection in vitro. Thus, HearNPV-HzAM1 system can be used to analyze the mechanism of ODV entry.     

Ac23, an envelope fusion protein homolog in the baculovirus Autographa californica multicapsid nucleopolyhedrovirus,is a viral pathogenicity factor

Viral envelope fusion proteins are important structural proteins that mediate viral entry and may affect or determine the host range of a virus. The acquisition, exchange, and evolution of such envelope proteins may dramatically affect the success and evolutionary divergence of viruses. In the family Baculoviridae, two very different envelope fusion proteins have been identified. Budded virions of group I nucleopolyhedroviruses (NPVs) such as the Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV), contain the essential GP64 envelope fusion protein. In contrast group II NPVs and granuloviruses have no gp64 gene but instead encode a different envelope protein called F. F proteins from group II NPVs can functionally substitute for GP64 in gp64null AcMNPV viruses, indicating that GP64 and these F proteins serve a similar functional role. Interestingly, AcMNPV (and other gp64-containing group I NPVs) also contain an F gene homolog (Ac23) but the AcMNPV F homolog cannot compensate for the loss of gp64. In the present study, we show that Ac23 is expressed and is found in budded virions. To examine the function of F protein homologs from the gp64-containing baculoviruses, we generated an Ac23null AcMNPV genome by homologous recombination in E. coli. We found that Ac23 was not required for viral replication or pathogenesis in cell culture or infected animals. However, Ac23 accelerated the mortality of infected insect hosts by approximately 28% or 26 h. Thus, Ac23 represents an important viral pathogenicity factor in larvae infected with AcMNPV.     

杆状病毒Ac78 C末端保守区域的功能初步分析

杆状病毒模式种苜蓿丫纹夜蛾核多角体病毒(Autographa californica multiple nucleopolyhedrovirus, AcMNPV)的orf78 (即Ac78)是最近被发现的杆状病毒核心基因,在杆状病毒的生活周期中具有重要功能.氨基酸序列分析表明,Ac78的C末端105～108位氨基酸区域在Group I NPVs旁系同源物中高度保守.为研究该保守区域在Ac78功能中的作用,利用Bac-to-Bac杆状病毒表达载体系统成功构建了缺失该保守区域,并且携带绿色荧光蛋白基因和多角体蛋白基因的Ac78截短补回型重组病毒(vAc78:del105-108).荧光显微镜分析和病毒生长曲线测定结果表明,在vAc78:del105-108转染的Sf9细胞中,感染性的芽生型病毒粒子(budded virion,BV)产生量与Ac78全长补回型重组病毒(vAc78:HA)基本一致;电镜观察发现,在vAc78:del105-108转染的细胞中,呈现与vAc78:HA的现象一致的典型的杆状病毒感染特征,多粒包埋型病毒粒子(multiple nucleocapsid enveloped occlusion derived virion,M-ODV)以及包埋有M-ODV的包涵体均能正常形成;免疫荧光实验表明,在vAc78:del105-108感染的Sf9细胞中,从病毒感染细胞24 h时开始,Ac78专一定位于感染细胞的内核膜附近,与vAc78:HA的现象一致.上述结果表明,Ac78的C末端105～108位氨基酸保守区域对于BV和M-ODV的有效产生以及Ac78的亚细胞定位非必需.     

Autographa Californica Multiple Nucleopolyhedrovirus P48 (Ac103) Is Required for the Efficient Formation of Virus-Induced Intranuclear Microvesicles

Our previous study has shown that the Autographa californica multiple nucleopolyhedrovirus(AcMNPV) p48(ac103)gene is essential for the nuclear egress of nucleocapsids and the formation of occlusion-derived virions(ODVs). However,the exact role of p48 in the morphogenesis of ODVs remains unknown. In this study, we demonstrated that p48 was required for the efficient formation of intranuclear microvesicles. To further understand its functional role in intranuclear microvesicle formation, we characterized the distribution of the P48 protein, which was found to be associated with the nucleocapsid and envelope fractions of both budded virions and ODVs. In Ac MNPV-infected cells, P48 was predominantly localized to nucleocapsids in the virogenic stroma and the nucleocapsids enveloped in ODVs, with a limited but discernible distribution in the plasma membrane, nuclear envelope, intranuclear microvesicles, and ODV envelope. Furthermore,coimmunoprecipitation assays showed that among the viral proteins required for intranuclear microvesicle formation, P48 associated with Ac93 in the absence of viral infection.     

Association of Cry1Ac toxin resistance in Helicoverpa zea (Boddie) with increased alkaline phosphatase levels in the midgut lumen

Resistance to Bacillus thuringiensis Cry1Ac toxin was characterized in a population of Helicoverpa zea larvae previously shown not to have an alteration in toxin binding as the primary resistance mechanism to this toxin. Cry1Ac-selected larvae (AR1) were resistant to protoxins and toxins of Cry1Ab, Cry1Ac, and the corresponding modified proteins lacking helix α-1 (Cry1AbMod and Cry1AcMod). When comparing brush border membrane vesicles (BBMVs) prepared from susceptible (LC) and AR1 larval midguts, there were only negligible differences in overall Cry1Ac toxin binding, though AR1 had 18% reversible binding, in contrast to LC, in which all binding was irreversible. However, no differences were detected in Cry1Ac-induced pore formation activity in BBMVs from both strains. Enzymatic activities of two putative Cry1Ac receptors (aminopeptidase N [APN] and alkaline phosphatase [ALP]) were significantly reduced (2-fold and 3-fold, respectively) in BBMVs from AR1 compared to LC larvae. These reductions corresponded to reduced protein levels in midgut luminal contents only in the case of ALP, with an almost 10-fold increase in specific ALP activity in midgut fluids from AR1 compared to LC larvae. Partially purified H. zea ALP bound Cry1Ac toxin in ligand blots and competed with Cry1Ac toxin for BBMV binding. Based on these results, we suggest the existence of at least one mechanism of resistance to Cry1A toxins in H. zea involving binding of Cry1Ac toxin to an ALP receptor in the larval midgut lumen of resistant larvae.     

HearNPV Pseudotyped with PIF1, 2, and 3 from MabrNPV: Infectivity and Complex Stability

Effective oral infection is set off by interaction of a group of conserved per os infectivity factors (PIFs) with larval midgut columnar epithelial cells. We constructed pseudotyped viruses by substituting pif1, pif2 or pif3 genes of Helicoverpa armigera nucleopolyhedrovirus (HearNPV) with their homologs from Mamestra bracissae multiple nucleopolyhedrovirus and tested their infectivity to tissue culture cells and to larvae. Transfection and infection assays revealed that all recombinant viruses generated infectious budded virus in both cell culture and in larvae. Electron microscopy showed synthesized occlusion body and occlusion derived virus (ODV) were morphologically indistinguishable from those of the parental virus. By contrast, feeding assays revealed that pseudotyped viruses could not rescue oral infectivity except for pif3 pseudotyped virus that only partially rescued oral infectivity but at a mortality rate much lower than that of the parental HearNPV. Consistent with the bioassay result, PIF complex was detected in ODVs of pif3 pseudotyped virus only but not in pif1 or pif2 pseudotyped viruses. Our results suggest that PIF complex is essential for oral infectivity, and in the formation of the PIF complex, PIF1, 2 are virus-specific while PIF3 does not appear to be as specific and can function in heterologous environment, albeit to a much more limited extent.     

New Insight to Structure-Function Relationship of GalNAc Mediated Primary Interaction between Insecticidal Cry1Ac Toxin and HaALP Receptor of Helicoverpa armigera

Over the last few decades Cry1Ac toxin has been widely used in controlling the insect attack due to its high specificity towards target insects. The pore-forming toxin undergoes a complex mechanism in the insect midgut involving sequential interaction with specific glycosylated receptors in which terminal GalNAc molecule plays a vital role. Recent studies on Cry toxins interactions with specific receptors revealed the importance of several amino acid residues in domain III of Cry1Ac, namely Q509, N510, R511, Y513 and W545, serve as potential binding sites that surround the putative GalNAc binding pocket and mediate the toxin-receptor interaction. In the present study, alanine substitution mutations were generated in the Cry1Ac domain III region and functional significance of those key residues was monitored by insect bioassay on Helicoverpa armigera larvae. In addition, ligand blot analysis and SPR binding assay was performed to monitor the binding characteristics of Cry1Ac wild type and mutant toxins towards HaALP receptor isolated from Helicoverpa armigera. Mutagenesis data revealed that, alanine substitutions in R511, Y513 and W545 substantially impacted the relative affinity towards HaALP receptor and toxicity toward target insect. Furthermore, in silico study of GalNAc-mediated interaction also confirmed the important roles of these residues. This structural analysis will provide a detail insight for evaluating and engineering new generation Cry toxins to address the problem of change in insect behavioral patterns.     

Cry1A毒素与二化螟中肠刷状缘膜囊泡受体蛋白配基结合分析

分离和鉴定二化螟Chilo suppresalis幼虫中肠刷状缘膜囊泡（BBMV）中Cry1A毒素的受体蛋白,对于阐明Cry1A毒素作用机理和二化螟抗性机理具有十分重要的意义。为此,本文就Cry1A毒素对二化螟杀虫活性及Cry1Ac与二化螟中肠受体的配基结合进行了研究。结果表明: Cry1Ab对二化螟室内品系(CN)的毒力高于Cry1Ac,而Cry1Ac高于Cry1Aa。配基结合分析表明二化螟CN品系幼虫中肠BBMV中有6个Cry1Ac结合蛋白(分子量分别为50,70,90,120,160和180 kDa), 其中180,160和90 kDa结合蛋白的条带颜色明显深于其他结合蛋白的条带,表明这3个受体蛋白具有较高的结合浓度。同源竞争结合研究表明,180和90 kDa结合蛋白为Cry1Ac的低亲合性结合蛋白,其他4个为高亲合性结合蛋白。为了研究Cry1Ac和Cry1Ab受体结合部位的相互作用,进行了异源竞争结合研究。Cry1Ab可以与Cry1Ac所有的6个结合蛋白进行竞争性结合,与180,120,70和50 kDa结合蛋白具有高亲合性,而与160和90 kDa结合蛋白具有低亲合性。结果显示,Cry1Ac与Cry1Ab在二化螟幼虫中肠BBMV上拥有多个共享的结合位点,但对每个结合位点的亲合性有差异。基于毒素结合部位的相似性,Cry1Ac和Cry1Ab不宜同时用于转基因Bt水稻来控制二化螟。     

Cytotoxicity and binding profiles of activated Cry1Ac and Cry2Ab to three insect cell lines

While Cry1Ac has been known to bind with larval midgut proteins cadherin, APN (amino peptidase N), ALP (alkaline phosphatase) and ABCC2 (adenosine triphosphate‐binding cassette transporter subfamily C2), little is known about the receptors of Cry2Ab. To provide a clue to the receptors of Cry2Ab, we tested the baseline cytotoxicity of activated Cry1Ac and Cry2Ab against the midgut and fat body cell lines of Helicoverpa zea and the ovary cell line of Spodoptera frugiperda (SF9). As expected, the descending order of cytotoxicity of Cry1Ac against the three cell lines in terms of 50% lethal concetration (LC₅₀) was midgut (31.0 μg/mL) > fat body (59.0 μg/mL) and SF9 cell (99.6 μg/mL). By contrast, the fat body cell line (LC₅₀ = 7.55 μg/mL) was about twice more susceptible to Cry2Ab than the midgut cell line (16.0 μg/mL), the susceptibility of which was not significantly greater than that of SF9 cells (27.0 μg/mL). Further, ligand blot showed the binding differences between Cry1Ac and Cry2Ab in the three cell lines. These results indicated that the receptors of Cry2Ab were enriched in fat body cells and thus largely different from the receptors of Cry1Ac, which were enriched in midgut cells.     

Mechanism of resistance to Bacillus thuringiensis toxin Cry1Ac in a greenhouse population of the cabbage looper, Trichoplusia ni

The cabbage looper, Trichoplusia ni, is one of only two insect species that have evolved resistance to Bacillus thuringiensis in agricultural situations. The trait of resistance to B. thuringiensis toxin Cry1Ac from a greenhouse-evolved resistant population of T. ni was introgressed into a highly inbred susceptible laboratory strain. The resulting introgression strain, GLEN-Cry1Ac-BCS, and its nearly isogenic susceptible strain were subjected to comparative genetic and biochemical studies to determine the mechanism of resistance. Results showed that midgut proteases, hemolymph melanization activity, and midgut esterase were not altered in the GLEN-Cry1Ac-BCS strain. The pattern of cross-resistance of the GLEN-Cry1Ac-BCS strain to 11 B. thuringiensis Cry toxins showed a correlation of the resistance with the Cry1Ab/Cry1Ac binding site in T. ni. This cross-resistance pattern is different from that found in a previously reported laboratory-selected Cry1Ab-resistant T. ni strain, evidently indicating that the greenhouse-evolved resistance involves a mechanism different from the laboratory-selected resistance. Determination of specific binding of B. thuringiensis toxins Cry1Ab and Cry1Ac to the midgut brush border membranes confirmed the loss of midgut binding to Cry1Ab and Cry1Ac in the resistant larvae. The loss of midgut binding to Cry1Ab/Cry1Ac is inherited as a recessive trait, which is consistent with the recessive inheritance of Cry1Ab/Cry1Ac resistance in this greenhouse-derived T. ni population. Therefore, it is concluded that the mechanism for the greenhouse-evolved Cry1Ac resistance in T. ni is an alteration affecting the binding of Cry1Ab and Cry1Ac to the Cry1Ab/Cry1Ac binding site in the midgut.