A GHF7 cellulase from the protist symbiont community of Reticulitermes flavipes enables more efficient lignocellulose processing by host enzymes.

Termites and their gut microbial symbionts efficiently degrade lignocellulose into fermentable monosaccharides. This study examined three glycosyl hydrolase family 7 (GHF7) cellulases from protist symbionts of the termite Reticulitermes flavipes. We tested the hypotheses that three GHF7 cellulases (GHF7-3, GHF7-5, and GHF7-6) can function synergistically with three host digestive enzymes and a fungal cellulase preparation. Full-length cDNA sequences of the three GHF7s were assembled and their protist origins confirmed through a combination of quantitative PCR and cellobiohydrolase (CBH) activity assays. Recombinant versions of the three GHF7s were generated using a baculovirus-insect expression system and their activity toward several model substrates compared with and without metallic cofactors. GHF7-3 was the most active of the three cellulases; it exhibited a combination of CBH, endoglucanase (EGase), and ß-glucosidase activities that were optimal around pH 7 and 30°C, and enhanced by calcium chloride and zinc sulfate. Lignocellulose saccharification assays were then done using various combinations of the three GHF7s along with a host EGase (Cell-1), beta-glucosidase (ß-glu), and laccase (LacA). GHF7-3 was the only GHF7 to enhance glucose release by Cell-1 and ß-glu. Finally, GHF7-3, Cell-1, and ß-glu were individually tested with a commercial fungal cellulase preparation in lignocellulose saccharification assays, but only ß-glu appreciably enhanced glucose release. Our hypothesis that protist GHF7 cellulases are capable of synergistic interactions with host termite digestive enzymes is supported only in the case of GHF7-3. These findings suggest that not all protist cellulases will enhance saccharification by cocktails of other termite or fungal lignocellulases.

Lignin-associated metagene expression in a lignocellulose-digesting termite.

Lignin is a component of plant biomass that presents a significant obstacle to biofuel production. It is composed of a highly stable phenylpropanoid matrix that upon degradation, releases toxic metabolites. Termites have specialized digestive systems that overcome the lignin barrier in wood lignocellulose to efficiently release fermentable simple sugars; however, how termites specifically degrade lignin and tolerate its toxic byproducts remains unknown. Here, using the termite Reticulitermes flavipes and its symbiotic (protozoan) gut fauna as a model system, we used high throughput Roche 454-titanium pyrosequencing and proteomics approaches to (i) experimentally compare the effects of diets containing varying degrees of lignin complexity on host-symbiont digestome composition, (ii) deeply sample host and symbiont lignocellulase diversity, and (iii) identify promising lignocellulase candidates for functional characterization. In addition to revealing over 9500 differentially expressed transcripts related to a wide range of physiological processes, our findings reveal two detoxification enzyme families not generally considered in connection with lignocellulose digestion: aldo-keto reductases and catalases. Recombinant versions of two host enzymes from these enzyme families, which apparently play no roles in cellulose or hemicellulose digestion, significantly enhance lignocellulose saccharification by cocktails of host and symbiont cellulases. These hypothesis-driven results provide important new insights into (i) dietary lignin as a xenobiotic challenge, (ii) the complex mechanisms used by termites to cope with their lignin-rich diets, and (iii) novel lignin-targeted enzymatic approaches to enhance biofuel and biomaterial production.

A soluble form of P74 can act as a per os infectivity factor to the Autographa californica multiple nucleopolyhedrovirus.

The baculovirus occlusion-derived virion (ODV) is required to spread virus infection among insect hosts via the per os route. The Autographa californica multicapsid nucleopolyhedrovirus P74 protein is an ODV envelope protein that is essential for ODVs to be infectious. P74 is anchored in the ODV envelope by a C-terminal transmembrane anchor domain and is N-terminally exposed on the ODV surface. In the present study, a series of N-terminal and C-terminal truncation mutants of P74 were evaluated for their ability to rescue per os infectivity of the P74-null virus, AcLP4. It was discovered that a P74 truncation mutant lacking the C-terminal transmembrane anchor domain of P74 was able to rescue per os infection. This result shows that a soluble form of P74 retains per os infectivity factor function and suggests that P74 may be complexed with other proteins in the ODV envelope.

Trypsin cleavage of the baculovirus occlusion-derived virus attachment protein P74 is prerequisite in per os infection.

Baculovirus occlusion-derived virions (ODVs) contain a number of infectivity factors essential for the initiation of infection in larval midgut cells. Deletion of any of these factors neutralizes infectivity by the per os route. We have observed that P74 of the group I alphabaculovirus Autographa californica multiple nucleopolyhedrovirus (AcMNPV) is N-terminally cleaved when a soluble form of the protein was incubated with insect midgut tissues under alkaline conditions and that cleavage was prevented by soybean trypsin inhibitor (SBTI). Presently, biological assays were carried out that suggest SBTI inhibits and trypsin enhances baculovirus per os infectivity. We developed a method to rescue per os infectivity of a P74 null virus involving co-transfection of viral DNA with a plasmid that transiently expresses p74. We used this plasmid rescue method to functionally characterize P74. A series of site-directed mutants were generated at the N terminus to evaluate if trypsin cleavage sites were necessary for function. Mutagenesis of R195, R196 and R199 compromised per os infectivity and rendered P74 resistant to midgut trypsin.

The Homingbac baculovirus cloning system: An alternative way to introduce foreign DNA into baculovirus genomes.

An in vitro baculovirus cloning system has been developed for direct cloning of foreign DNA into baculovirus genomes. This system is called the "Homingbac system" because it uses homing endonucleases. The Homingbac system was engineered into the baculoviruses AcMNPV, BmNPV, PxMNPV, RoMNPV, HaSNPV and HzSNPV. All Homingbac viruses were designed to retain the polyhedra phenotype so that they could be inoculated per os to insects. This is the first time a common in vitro baculovirus cloning system has been made for multiple baculovirus species that include both groups I and II nucleopolyhedroviruses (NPVs). In this study, the Homingbac system was demonstrated by directly cloning a PCR-amplified beta-glucuronidase gene cassette into a parent Homingbac virus. This new collection of groups I and II NPV Homingbac viruses are a significant expansion of in vitro cloning technology and are new tools for making recombinant baculoviruses.

Evidence for proteolytic cleavage of the baculovirus occlusion-derived virion envelope protein P74.

Baculovirus occlusion-derived virions (ODVs) are released from occlusion bodies by the alkaline environment of the insect midgut. The ODV envelope protein P74 is required for oral infectivity. A soluble form of the Autographa californica multiple nucleopolyhedrovirus P74 protein, P74sol, was engineered as part of a chimeric protein with jellyfish green fluorescent protein (GFP). P74sol-GFP was overproduced by the baculovirus expression system and purified away from the wild-type P74. Brush border membrane vesicles (BBMVs) were prepared from the midguts of third-instar Helicoverpa zea larvae. When P74sol-GFP was incubated under alkaline conditions with BBMVs, a P74sol-GFP product with a smaller molecular mass was produced. Immunoblots indicated that the smaller product was generated by N-terminal cleavage of P74. This cleavage was prevented by soybean trypsin inhibitor. Analysis of the peptide sequences of P74 homologues identified a conserved trypsin cleavage site that could generate the observed P74sol-GFP BBMV-specific cleavage product.

Anticarsia gemmatalis multicapsid nucleopolyhedrovirus v-trex gene encodes a functional 3' to 5' exonuclease.

The viral three-prime repair exonuclease (v-trex) gene of the Anticarsia gemmatalis multicapsid nucleopolyhedrovirus (AgMNPV) is the first baculovirus gene to be described with significant homology to a 3' exonuclease. v-trex is an early gene that is expressed by AgMNPV from 3 h post-infection. In the present study, the AgMNPV v-trex ORF was cloned into the baculovirus Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) under the control of a polyhedrin promoter. The resulting virus produced an abundant, soluble protein that migrated with an apparent size of 23.7 kDa. The 3' to 5' exonuclease activity associated with this v-trex-expressing recombinant AcMNPV was 2000-fold above that of wild-type AcMNPV. This exonuclease activity was inhibited by EDTA and was activated in the presence of Mg2+ and, to a lesser extent, Mn2+. From these results, the AgMNPV v-trex gene is concluded to encode an independently active 3' to 5' exonuclease.

The gp64 locus of Anticarsia gemmatalis multicapsid nucleopolyhedrovirus contains a 3' repair exonuclease homologue and lacks v-cath and ChiA genes.

Anticarsia gemmatalis multicapsid nucleopolyhedrovirus (AgMNPV) is one of the most successful biological insecticides. In this study, we cloned and sequenced a 12.5 kbp BamHI-D restriction endonuclease fragment of the AgMNPV isolate 2D genome that includes the gp64 gene. We compared this highly conserved region with that of other baculoviruses. AgMNPV contained two genes, p22.2 and v-trex, in common with Choristoneura fumiferana MNPV (CfMNPV) that were not present in other baculoviruses. The v-trex gene has homology to a eukaryotic 3' repair exonuclease and appears to have been acquired from an invertebrate host. The v-trex gene product has the potential to be involved in virus recombination or UV-light tolerance. Multigene phylogenetic analysis suggested that AgMNPV is most closely related to Orgyia pseudotsugata MNPV (OpMNPV). AgMNPV differed from other group I NPVs in that ChiA and v-cath gene homologues were missing from the region downstream of the gp64 gene. Proteinase assays and genetic probes suggest the v-cath gene is absent from AgMNPV.

Epitope tagging: a monoclonal antibody specific for recombinant fusion proteins in plants.

The easy identification of a recombinant protein in plant material becomes increasingly relevant as more transgenic plants are used for research and commercial applications. Tagging recombinant proteins with a small peptide (epitope) can perform such a task. However, available epitope antibodies will also cross-react with endogenous plant proteins at a level that may be unacceptable. Here we describe the new epitope antibody AcV5. Whether it is attached to the carbooxyl terminal end of enhanced green fluorescent protein (EGFP) or the Bacillus thuringiensis endotoxin Cry3A, these proteins remain functional. In addition, using less than 250 pg AcV5-tagged EGFP produces a strong signal on Western blots with no cross-reactivity of proteins from a broad range of plants of agronomic importance.

Purification of DNA for the transfection of a Spodoptera frugiperda cell line.

Spodoptera frugiperda (Sf-9) cells have been widely used in baculovirus expression systems, transient gene expression studies and transgenic cell lines. These applications commonly require the transfection of bacterial plasmid DNA. One of the most reliable methods of preparing transfection-quality plasmid DNA is cesium chloride (CsCl) density gradient centrifugation. However, the traditional CsCl DNA purification is a long and laborious process. We have made a series of modifications to the traditional method that makes it faster, safer and easier. In the current study we demonstrate that DNA prepared by our modified CsCl method was also better for the transfection of Sf-9 cells than DNA prepared by the traditional CsCl method.

A study of the Autographa californica multiple nucleopolyhedrovirus ODV envelope protein p74 using a GFP tag.

The Autographa californica multiple nucleopolyhedrovirus (AcMNPV) protein p74 is associated with the occlusion-derived virus (ODV) envelope. p74 is essential for oral infectivity of ODV and has been proposed to play a role in midgut attachment and/or fusion. In this study, p74 protein was expressed in-frame with green fluorescent protein (GFP) to create a p74-GFP chimera. The C-terminal GFP portion of the chimera facilitated visualization of the trafficking of p74 in baculovirus-infected Spodoptera frugiperda (Sf-9) cells. p74-GFP chimeric proteins localized in the intranuclear ring zone of the nucleus and were found to co-precipitate with the microvesicle fraction of cell lysates. A series of truncations of p74 was expressed as p74-GFP chimeras in recombinant baculoviruses. When C-terminal region S580-F645 was deleted from p74, p74-GFP chimera localization became non-specific and chimeras became soluble. p74 region S580-F645 directed GFP to the intranuclear ring zone in a similar pattern to full-length p74. The hydrophobic C terminus of p74 plays a role in protein localization and possibly in transmembrane anchoring and insertion.

Expression and localization of LEF-11 in Autographa californica nucleopolyhedrovirus-infected Sf9 cells.

The Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) lef-11 gene was found previously to be necessary to support optimal levels of transient expression from an AcMNPV late promoter. The lef-11 gene is unusual in that it overlaps both upstream (orf38) and downstream (pp31) genes. In this study, the expression and cellular localization of LEF-11 were examined. The lef-11 transcripts were detected from 4 to 36 h post-infection (p.i.). The 1.5 kb lef-11 mRNA initiates 196 nt upstream of the lef-11 translation initiation codon, within the upstream orf38 gene. This relatively long 5' upstream region encodes a potential small upstream open reading frame (ORF) of 58 amino acids that overlaps the lef-11 ORF. The 3' end of the lef-11 mRNA was mapped as co-terminal with mRNAs from the downstream pp31 gene. Using affinity purified anti-LEF-11 antibodies, levels of LEF-11 expression were found to be maximal between approximately 8 and 24 h p.i., although LEF-11 could be detected as late as 72 h p.i. Using immunofluorescence microscopy, it was determined that LEF-11 localized to dense regions of infected cell nuclei, consistent with its role as a possible late transcription factor.