Evolution of d-Arabinose,l-Xylose and l-Ribose Utilization in Mycobacterium smegmatis: Mutants with a Novel Enzyme “Pentose Reductase”

The full-length cDNA sequence of a new pheromone-binding protein (AscrPBP2) was determined from a geometrid moth, Ascotis selenaria cretacea, which secreted a Type II sex pheromone, and an antiserum against its recombinant protein overexpressed in Escherichia coli was prepared. In addition to this antiserum against AscrPBP2, antibodies against AscrPBP1 and general odorant-binding proteins of Bombyx mori were used in Western blotting experiments to analyze the proteins in the antennae of several lepidopteran species secreting Type II sex pheromone components.     

Expression patterns of odorant-binding proteins in antennae of the moth<Emphasis Type="Italic"> Manduca sexta</Emphasis>

Monoclonal antibodies (MAbs) were generated to six recombinant proteins (odorant-binding proteins; OBPs) of Manduca sexta. The specificity of each MAb was demonstrated by labeling six immunoblots, each of which contained samples of all six recombinant OBPs. The expression patterns of the six OBPs could be grouped into three classes: (1) one (GOBP1) was expressed in sensilla located throughout each annulus; (2) two (ABPX and ABP2) were expressed in the long sensilla trichoidea bordering a zone that was arranged as an arch on the periphery of each annulus; (3) three (PBP2, PBP3, and GOBP2) were expressed in shorter sensilla occupying a wedge-shaped mid-annular zone of each annulus. In female antennae, sensilla expressing these OBPs were intermixed, and the distinct zonation observed in the male antenna was absent. In males, PBP2 was co-expressed in exactly the same cells of the mid-annular zone as those expressing PBP3 and most of the same cells expressing GOBP2, although its expression overlapped with no or only a few sensilla expressing OBPs of class 1 (GOBP1) or class 2 (ABPX, ABP2). This overlap of expression or lack of overlap between PBP2 and the other OBPs for male antennae was mirrored in female antennae. In view of the restricted spatial expression of OBPs within an annulus and the diversity of possible dimeric combinations of OBPs that arises from the co-expression of multiple OBPs in a given sensillum, OBPs could contribute to the specificity of the olfactory responses of insects.This research was supported by grants from the National Science Foundation (IBN-9604095) and the University of Illinois Critical Research Initiatives     

Immunolocalization of pheromone-binding protein and general odorant-binding protein in olfactory sensilla of the silk moths Antheraea and Bombyx

The distribution of odorant-binding proteins among olfactory sensilla of three moth species was studied by immuno-electron microscopy. Two polyclonal antisera were used in a post-embedding labelling protocol on sections of cryo-substituted antennae. The first was directed against the pheromone-binding protein (PBP) of Antheraea polyphemus, the second against the general odorant-binding protein (GOBP) of the same species. Immunoblots showed that these antisera were highly specific; both antisera did, however, cross-react with related proteins in the related species A. pernyi, and in the bombycid moth B. mori. PBP and GOBP were localized only in olfactory sensilla trichodea and sensilla basiconica, the principal site being the sensillum lymph surrounding the sensory dendrites. In the males of all three species, the pheromone-sensitive long sensilla trichodea exclusively contained PBP. the majority of the sensilla basiconica in both sexes in these species contained GOBP; these sensilla are known to respond to plant and other general odours. Some sensilla were not labelled by either antiserum; presumably, these held an odorantbinding protein of a different subfamily. Never were PBP and GOBP co-localized in the same sensillum. Two observations deserve special attention: (1) PBP was also found in a few sensilla in females, and (2) in B. mori, where the long sensilla trichodea have a different functional specificity in males (pheromone) and females (plant odours), the expression of the odorant-binding protein (males: PBP; females: GOBP) is similarly different. The distinct and complex distribution pattern of odorant-binding proteins supports the notion that these proteins participate in stimulus recognition.Dedicated to Professor Ya.A. Vinnikov on the occasion of his 85. birthdayThis work was partly supported by DFG grant ste 501/3-1.     

Odorant-binding proteins and chemosensory proteins in pheromone detection and release in the silkmoth Bombyx mori

The genome of the silkmoth Bombyx mori contains 44 genes encoding odorant-binding proteins (OBPs) and 20 encoding chemosensory proteins (CSPs). In this work, we used a proteomic approach to investigate the expression of proteins of both classes in the antennae of adults and in the female pheromone glands. The most abundant proteins found in the antennae were the 4 OBPs (PBP, GOBP1, GOBP2, and ABP) and the 2 CSPs (CSP1 and CSP2) previously identified and characterized. In addition, we could detect only 3 additional OBPs and 2 CSPs, with clearly different patterns of expression between the sexes. Particularly interesting, on the other hand, is the relatively large number of binding proteins (1 OBP and 7 CSPs) expressed in the female pheromone glands, some of them not present in the antennae. In the glands, these proteins could be likely involved in the solubilization of pheromonal components and their delivery in the environment.     

cDNA cloning and recombinant expression of the general odorant binding protein II from Spodoptera litura

A cDNA encoding the general odorant binding protein II (GOBP II) was isolated from the antennae of Spodoptera litura (SlGOBP II, GenBank Accession No. EU086371) by homologous cloning and rapid amplification of cDNA ends (RACE). Sequencing and structural analyses revealed that the open reading frame (ORF) of SlGOBP II was 489 bp, encoding 162 amino acids with a predicted MW of 18.2 kD and pI of 5.72. SlGOPB II shared typical structural features of odorant binding proteins with other insects, including the six conservative cysteine residues. The deduced amino acid sequence of SlGOPB II shared significant identity with the GOBP II from S. frugiperda and S. exigua. RT-PCR and Northern blot analyses showed that SlGOBP II was specifically expressed in the antennae. cDNA encoding SlGOBP II was constructed into the pET-32a vector and the recombinant protein was highly expressed in Es-cherichia coli BL21 (DE3) after induction with IPTG. SDS electrophoresis and Western blot analysis confirmed the molecular weight of the recombinant SIGOBPII i.e, 32 kD, which has a 6×His tag at the N-terminus. The recombinant SlGOBP II was purified by single-step Ni-NTA affinity chromatography and used to raise antiserum in rabbits. ELISA showed that the titer of antiserum was 1︰12800, while Western blot analysis showed that the recombinant SlGOBP II was recognized as anti-SlGOBP II an-tiserum.     

The Lepidoptera Odorant Binding Protein gene family: Gene gain and loss within the GOBP/PBP complex of moths and butterflies

Butterflies and moths differ significantly in their daily activities: butterflies are diurnal while moths are largely nocturnal or crepuscular. This life history difference is presumably reflected in their sensory biology, and especially the balance between the use of chemical versus visual signals. Odorant Binding Proteins (OBP) are a class of insect proteins, at least some of which are thought to orchestrate the transfer of odor molecules within an olfactory sensillum (olfactory organ), between the air and odor receptor proteins (ORs) on the olfactory neurons. A Lepidoptera specific subclass of OBPs are the GOBPs and PBPs; these were the first OBPs studied and have well documented associations with olfactory sensilla. We have used the available genomes of two moths, Manduca sexta and Bombyx mori, and two butterflies, Danaus plexippus and Heliconius melpomene, to characterize the GOBP/PBP genes, attempting to identify gene orthologs and document specific gene gain and loss. First, we identified the full repertoire of OBPs in the M. sexta genome, and compared these with the full repertoire of OBPs from the other three lepidopteran genomes, the OBPs of Drosophila melanogaster and select OBPs from other Lepidoptera. We also evaluated the tissue specific expression of the M. sexta OBPs using an available RNAseq databases. In the four lepidopteran species, GOBP2 and all PBPs reside in single gene clusters; in two species GOBP1 is documented to be nearby, about 100 kb from the cluster; all GOBP/PBP genes share a common gene structure indicating a common origin. As such, the GOBP/PBP genes form a gene complex. Our findings suggest that (1) the lepidopteran GOBP/PBP complex is a monophyletic lineage with origins deep within Lepidoptera phylogeny, (2) within this lineage PBP gene evolution is much more dynamic than GOBP gene evolution, and (3) butterflies may have lost a PBP gene that plays an important role in moth pheromone detection, correlating with a shift from olfactory (moth) to visual (butterfly) communication, at least regarding long distance mate recognition. These findings will be clarified by additional lepidopteran genomic data, but the observation that moths and butterflies share most of the PBP/GOBP genes suggests that they also share common chemosensory-based behavioral pathways.     

斜纹夜蛾普通气味结合蛋白GOBP1基因的表达定位分析

气味调控斜纹夜蛾Spodoptera litura（鳞翅目,夜蛾科）的交配和产卵行为,而嗅觉气味结合蛋白（OBP）是昆虫与外界环境进行化学信息交流中的一种重要蛋白。本研究基于已报道的斜纹夜蛾普通气味结合蛋白GOBP1基因cDNA序列（GenBank登录号为EF159978）设计引物,通过RT-PCR法分析了GOBP1 mRNA的组织特异性表达情况,并对GOBP1基因条带进行了克隆、测序和Blast比对。此外,再通过RNA原位杂交的方法进一步分析了GOBP1 mRNA在触角中的表达定位。结果表明:GOBP1只在斜纹夜蛾的触角组织中表达,而且GOBP1转录本较多分布于靠近嗅觉感受器即触角边缘部位。这些结果进一步说明GOBP1是斜纹夜蛾嗅觉过程中的重要蛋白,同时为深入研究GOBP1与其他蛋白的相互空间定位关系、GOBP1的功能等奠定了基础。     

Construction and analysis of cDNA libraries from the antennae of male and female cotton bollworms Helicoverpa armigera (Hübner) and expression analysis of putative odorant-binding protein genes

Two high-quality cDNA libraries were constructed from female and male antennae of the cotton bollworm Helicoverpa armigera (Hübner). The titers were approximately 2.0 × 10⁶ pfu/ml for females and 2.3 × 10⁶ pfu/ml for males, and this complies with the test requirement. From the libraries, 1750 male ESTs and 1640 female ESTs were sequenced and further analyzed. We identified 15 olfactory genes (12 are new), and 14 of them have the characteristic six conserved cysteine residues. With the exception of OBP9, all the genes were classified as classical OBP genes. By alignment and cluster analysis, the 14 classical OBPs were divided into pheromone binding protein (PBP) genes, odorant binding protein (OBP) genes, general odorant binding protein 1 (GOBP1) genes, general odorant binding protein 2 (GOBP2) genes and antennae binding protein (ABP) genes. Among these genes, we obtained three PBP genes (PBP1–PBP3) including two new PBP genes, one new ABP gene, nine new OBP genes (OBP1–OBP9), one known GOBP1 gene and one known GOBP2 gene. Furthermore, the expression patterns of these 14 classical OBP genes were investigated in various tissues by real-time quantitative polymerase chain reaction (qPCR). The results indicated that some OBP genes are expressed differently in different sexes and tissues, but most of them are highly expressed in antennae.     

General odorant-binding proteins and sex pheromone guide larvae of Plutella xylostella to better food

Olfaction of Lepidopteran larvae has received little attention, compared to the damage to crops done by insects at this stage. We report that larvae of the diamondback moth Plutella xylostella are attracted to their natural sex pheromone and to their major component (Z)-11-hexadecenal, but only in a food context. For such task they use two general odorant-binding proteins (GOBPs), abundantly expressed in the three major sensilla basiconica of the larval antenna, as shown by whole-mount immunostaining and immunocytochemistry experiments. None of the three genes encoding pheromone-binding proteins (PBPs) are expressed at this stage. Both recombinant GOBPs bind (Z)-11-hexadecenal and the corresponding alcohol, but not the acetate. Binding experiments performed with five mutants of GOBP2, where aromatic residues in the binding pocket were replaced with leucine showed that only one or two amino acid substitutions can completely abolish binding to the pheromone shifting the affinity to plant-derived compounds. We hypothesise that detection of their species-specific pheromone may direct larvae to the sites of foraging chosen by their mother when laying eggs, to find better food, as well as to reduce competition with individuals of the same or other species sharing the same host plant. We also provide evidence that GOBP2 is a narrowly tuned binding protein, whose affinity can be easily switched from linear pheromones to branched plants terpenoids, representing a tool better suited for the simple olfactory system of larvae, as compared to the more sophisticated organ of adults.     

Molecular characterization and phylogenetic analysis of three odorant binding protein gene transcripts in Dendrolimus species (Lepidoptera: Lasiocampidae)

Pine caterpillar moths, Dendrolimus spp. (Lepidoptera: Lasiocampidae), are serious economic pest of pines. Previously, phylogenetic analyses of Dendrolimus using different methods yielded inconsistent results. The chemosensory systems of insects may play fundamental roles in promoting speciation. Odorant‐binding proteins (OBPs) participate in the first step of odor detection. Studying the evolution of OBPs in closely related species may help us to identify their role in speciation. We identified three OBPs – one pheromone‐binding protein and two general odorant‐binding proteins – from male antennae of four Dendrolimus species, D. superans (Butler), D. punctatus (Walker), D. kikuchii Matsumura, and D. houi Lajonquiere, the olfactory recognition systems of which had not been previously investigated. We analyzed their molecular characteristics and compared their sequences to those of OBPs in D. tabulaeformis Tsai et Liu. Ka/Ks ratio analyses among the five Dendrolimus species indicate that PBP1 genes experienced more evolutionary pressure than the GOBPs. Phylogenetic relationships of PBP1 and GOBP1 both indicated that D. houi was the basal species, then branched D. kikuchii, while D. tabulaeformis, D. punctatus, and D. superans evolved more recently. These relationships are consistent with the changes in sex pheromone components of these five species. Dendrolimus tabulaeformis and D. punctatus are closely related sister species. However, the distances among GOBP2 sequences in the five Dendrolimus were very short, and the relationships of D. houi and D. kikuchii could not be resolved. Integrating our results with those of previous studies, we hypothesized that D. kikuchii, D. punctatus and D. superans evolved from the basal ancestor because of sex pheromone mutations and environmental pressure.     

Cloning,expression and immunocytochemical localization of a general odorant-binding protein gene from Helicoverpa armigera (Hübner)

A cDNA clone coding for general odorant-binding protein2 was isolated from the antenna of Helicoverpa armigera by RT-PCR and (5'/3')-RACE technique. Results of sequencing and structural analyses showed that the full-length of GOBP2Harm was 636 bp, possessing 162 amino acid residues and a signal peptide of 21 amino acids. Its predicted molecular weight and isoelectric point were 18.2 kDa and 5.21, respectively. This deduced amino acid sequence shared some common structural features with odorant-binding proteins from several moth species, including the six conserved cysteine motif, typical of insect's OBPs. Northern blot showed that GOBP2Harm is specifically expressed in the antenna of Helicoverpa armigera at similar levels in both sexes. In order to obtain sufficient GOBP2 for further determining its biochemical and physiological properties, a bacterical expression vector of GOBP2 was constructed and successfully expressed. The protein was obtained mainly as insoluble inclusion bodies, that, however, could be solubilized and refolded. The rGOBP2 was purified by affinity chromatography and gel filtration. The rGOBP2 was shown to cross-react with an anti-GOBP antiserum from Antheraea polyphemus. Finally, polyclonal antibodies against GOBP2Harm were used to mark the distribution of the protein in olfactory sensilla and were tested by immuno-electron microscopy. In the male, GOBP2Harm is mainly expressed in sensilla basiconica, while in the female, it is equally expressed in sensilla basiconica and in sensilla trichodea.     

昆虫普通气味结合蛋白研究进展

昆虫气味结合蛋白(OBPs)参与昆虫识别环境中气味信息的第一步反应,在调控昆虫生命活动中起着重要的作用.普通气味结合蛋白(GOBPs)主要参与昆虫对寄主植物挥发物或信息素的识别.本文总结了GOBPs基因的分子特征和生理功能,以及GOBPs基因在不同组织、性别和发育阶段的表达特性;针对GOBPs与性信息素结合蛋白(PBP...     

家蚕信息素结合蛋白BmPBP2和BmPBP3基因的初步鉴定及表达分析

嗅觉对昆虫的生存、繁殖等起着重要的作用。依据家蚕Bombyx mori全基因组序列设计特异引物,扩增得到了两个信息素结合蛋白BmPBP2和BmPBP3基因的cDNA片段。结合已报道的家蚕信息素结合蛋白BmPBP1和两个普通气味结合蛋白BmGOBP的信息,对其基因结构分析表明,这5个基因均由3个外显子组成,具有保守的外显子/内含子边界和典型的6个Cys残基,且3个PBP基因在基因组上串联分布。序列同源性分析表明,BmPBP2和BmPBP3与烟草天蛾的PBP2和PBP3的同源性高达69%和63%。半定量RT-PCR分析结果显示,BmPBP2和BmPBP3基因在成虫触角中特异表达,且雌雄表达水平相当。这些结果表明BmPBP2和BmPBP3可能起着性信息素识别的作用。     

Immunolocalization of odorant-binding proteins in noctuid moths (Insecta, Lepidoptera)

Odorant-binding proteins were studied in the noctuid moths Agrotis segetum, Autographa gamma, Helicoverpa armigera, Heliothis virescens and Spodoptera littoralis using antisera raised against the pheromone-binding protein (PBP) and general odorant-binding protein 2 (GOBP2) of Antheraea polyphemus (Saturniidae). Proteins immunoreacting with these antisera were only found on the antennae and PBP and GOBP2 could be identified on western blots of males and females of all five species. PBPs were predominantly localized in sensilla trichodea and GOBP2 in sensilla basiconica, in good correlation with the stimulus specificity of the receptor cells in these sensilla. In H. armigera and H. virescens the majority of the s. trichodea immunoreacted with the antiserum against PBP of A. polyphemus; in A. segetum, A. gamma and S. littoralis, on the other hand, a high percentage of s. trichodea remained unlabelled. Probably, the PBP expressed in these sensilla is so different that it does not immunoreact with the antiserum used. Such a protein was found by native PAGE of antennal extracts of A. segetum and S. littoralis. These data correlate with the fact that the two heliothine species use pheromones with the same alkyl chain length as A. polyphemus, while the other three species use pheromones with shorter chains. In H. armigera, H. virescens, A. gamma and S. littoralis female antennae were also immunolabelled and a large number of PBP-expressing s. trichodea was consistently found. In S.littoralis this fits with the electrophysiologically recorded high pheromone sensitivity of female s. trichodea, whereas in females of H. armigera and H. virescens no or only weak responses to pheromone stimulation have been reported. Therefore, PBP expression in a sensillum does not necessarily imply pheromone sensitivity of its receptor cells.