Synthesis of human adenovirus type 2 fiber protein in Escherichia coli cells

Fiber knob domain lacking the shaft sequence but fused to a coiled coil is a candidate subunit vaccine against egg-drop syndrome

Egg-drop syndrome (EDS) virus is an avian adenovirus that causes a sudden drop in egg production and in the quality of the eggs when it infects chickens, leading to substantial economic losses in the poultry industry. Inactivated EDS vaccines produced in embryonated duck eggs or cell culture systems are available for the prophylaxis of EDS. However, recombinant subunit vaccines that are efficacious and inexpensive are a desirable alternative. In this study, we engineered chimeric fusion proteins in which the trimeric fiber knob domain lacking the triple β-spiral motif in the fiber shaft region was genetically fused to trimeric coiled coils, such as those of the engineered form of the GCN4 leucine zipper peptide or chicken cartilage matrix protein (CMP). The fusion proteins were expressed predominantly as soluble trimeric proteins in Escherichia coli at levels of 15-80mg/L of bacterial culture. The single immunization of chickens with the purified fusion proteins, at a dose equivalent to 10μg of the knob moiety, elicited serum antibodies with high hemagglutination inhibition (HI) activities, similar to those induced by an inactivated EDS vaccine. A dose-response analysis indicated that a single immunization with as little as 1μg of the knob moiety of the CMP-knob fusion protein was as effective as the inactivated vaccine in inducing antibodies with HI activity. The immunization of laying hens had no apparent adverse effects on egg production and effectively prevented clinical symptoms of EDS when the chickens were challenged with pathogenic EDS virus. This study demonstrates that the knob domain lacking the shaft sequence but fused to a trimeric coiled coil is a promising candidate subunit vaccine for the prophylaxis of EDS in chickens.

Synthesis of a eukaryotic virus protein in a prokaryotic viral-cell system: production of the adenovirus type 2 fiber shaft fragment by a tightly regulated T7POL-M13 expression system

The use of recombinant technology for the production of proteins of interest in biotechnology and medicine has grown immensely during the last decade. A major problem often encountered is the degradation of the recombinant product by host cell proteases. We developed a novel system based on the cloning and expression of an inducible phage T7 RNA polymerase into the main intergenic region of the phage M13-KO7. After infection of permissive bacterial strains with the engineered phage, the polymerase gene is transcribed, subsequently translated and gene fragments cloned under T7 promoter sequences are then transcribed. For the evaluation of this system, the gene encoding the shaft fragment of the adenovirus type 2 fiber was cloned into a pET 3a-based expression vector. Expression was demonstrated in a BL21(DE3) strain (containing one copy of the T7 RNA polymerase gene) and also in several F pili-containing bacterial strains only after infection with the proper bacteriophage. Several important parameters for heterologous gene expression in Escherichia coli were investigated. Different bacterial strains were evaluated for the production of the recombinant protein, following: the expression levels, the growth rates and the stability of the plasmid vector at different time intervals after induction. It was observed that the expression levels as well as division rates and plasmid stability differed between the different bacterial strains. The best expression levels were obtained when using the E. coli Top IOF' strain. Degradation was only observed in BL21(DE3) cells after 6 h of induction, whereas none of the F'-containing cells were shown to degrade the recombinant protein during the time of expression. This system, based on the T7 pol-M13 bacteriophage, was shown to be very tightly regulated for most of the bacterial strains evaluated with no expression before induction of the T7 RNA polymerase.

Amplification of recombinant adenoviral transgene products occurs by inhibition of histone deacetylase

n-Butyrate (butyrate) has been shown to amplify transgene expression in cells infected with E1-defective adenoviruses. The present studies were undertaken in order to better define the actions of butyrate in the context of adenovirus gene expression, and to attempt to elucidate the mechanism by which butyrate mediates the transgene amplification. It was found that butyrate amplified viral transgene expression over a concentration range of 0.5-5 mM, and that the amplification required an exposure of 12-24 hr for maximal effect. Western blot analysis of representative viral proteins showed that butyrate treatment amplified DNA-binding protein, but not fiber protein. A transient adenoviral replication system suggested that butyrate had a modest inhibitory effect on replication of the E1-defective adenovirus. Use of a specific inhibitor of histone deacetylase, trichostatin A (TSA), reproduced the amplification of the viral transgene product achieved with the butyrate. In contrast, adenoviral transgene expression could not be amplified by TSA treatment in a cell line known to have a TSA-resistant histone deacetylase. Butyrate amplified steady-state gene expression of the viral transgene, but had no detectable effects on either DNA-binding protein or fiber steady-state gene expression. Nuclear run-off experiments showed that both butyrate and TSA caused an increase in the viral transgene transcription. It was concluded that inhibitors of histone deacetylase amplify adenoviral transgene expression at the transcriptional level.

Human adenovirus type 41 contains two fibers

DNA sequencing of the subgroup F human adenovirus serotype 41 (TAK, Ad41) fiber gene revealed the presence of two adjacent open reading frames encoding information for proteins with molecular weights of 60.6 kDa and 41.4 kDa (Pieniazek, et al; Nucleic Acids Res. 18: p. 1901, 1990). In this paper, various approaches were used to characterize the two proteins and determine whether both fibers were expressed in infected cells as well as on viral particles. We initially used a reverse transcriptase-polymerase chain reaction with primers for the short and long fiber genes to amplify mRNA from Ad41 infected HEp-2 cells at 48 h post-infection. Two distinct DNA bands; one slightly larger than 1.1 kbp and the other at about 1.7 kbp were identified. Second, we used polyclonal anti-Ad41 virion and monoclonal anti-Ad5 fiber antibodies to demonstrate that at both 24 and 36 h post-infection, Ad41 expressed two fiber proteins of the expected size. Specifically, by SDS-PAGE, one fiber (short) had a molecular weight of 40 kDa, while the other (long) had a molecular weight of 60 kDa. Third, by electron microscopy, two sizes of fibers were released from CsCl purified virions, both having a characteristic adenovirus morphology, with a knob at one end. The long fiber measured 315A in length and the short fiber was 250A long. These measurements are consistent with the two Ad41 fibers being encoded by the above open reading frames. We also performed a computer search to compare fiber sequences from other human adenovirus serotypes with that of the Ad41 short and long fiber proteins. The primary structure of both Ad41 fibers were found to be similar in that they contained tail, shaft and knob regions. Further, the tail region of both fibers (amino acids 1-42) showed a 74% overall homology to each other and contained the Ad conserved sequence NH2-F-N-P-V-Y-P-Y-COOH. An interesting difference, however, was observed in the shaft region where the long fiber (amino acids 43-389) had twenty-two 16-amino acid repeat motifs, while the short fiber (amino acids 43-233) had only twelve. Finally, we noted that the long fiber knob region was about 15% longer than that of the short fiber, and showed little overall homology. In conclusion, human adenovirus subgroup F (type 41) virions appear to differ from those of all other human adenoviruses (subgenera A-E) in that they contain two fiber genes and correspondingly, two different sized fibers.(ABSTRACT TRUNCATED AT 400 WORDS)

Inducible expression of a toxic poliovirus membrane protein in Escherichia coli: comparative studies using different expression systems based on T7 promoters

The poliovirus 3AB gene has been cloned and overproduced in T7 expression vectors using different approaches to allow reduction of basal levels of expression. Expression of the poliovirus 3AB gene is highly toxic for E. coli cells, due to drastic changes induced in membrane permeability of the bacteria that lead to cell lysis when the T7 lysozyme is present. The best production of 3AB was achieved with the T7/lac system in cells lacking T7 lysozyme, where this toxic protein was synthesized to high levels and during several hours in the absence of cell lysis. These results show the efficient synthesis of a highly damaging membrane protein and open the possibility to apply heterologous gene expression in E. coli to other lytic proteins.

The amino terminus of the adenovirus fiber protein encodes the nuclear localization signal

Using a recombinant vaccinia virus vector, the fiber protein from adenovirus serotype 2 has been expressed in human cells; the protein expressed was correctly assembled into trimers, glycosylated, and transported to the nucleus. Deletion of amino acids 2-5 (KRAR) resulted in accumulation of fiber in the cytoplasm; fusion of the sequence TKRVRL, found at the beginning of Ad7 fiber, to the N-terminus of this mutant restored correct targeting. Changing the charge of amino acids 91 and 92 within another potential targeting sequence (LKKTK to LEETK) had little effect on nuclear targeting. When fused to the N-terminus of beta-galactosidase and expressed in recombinant vaccinia virus, neither MKRARP nor MTKRVRL (from Ad2 and Ad7 fibers, respectively), were sufficient for efficient transport of the hybrid protein to the nucleus; on the other hand, fusions of either MKRARPSEDTF (from Ad2 fiber) or of MKRPRP (a known targeting sequence from the C-terminus of Ad2 E1A proteins) to beta-galactosidase were localized to the nucleus. These results suggest that sequences at the N-terminus of Ad2 and Ad7 fiber are required for correct nuclear targeting.

Molecular cloning and expression of the VP1 gene of foot-and-mouth disease virus C1 in E. coli: effect on bacterial cell viability

The VP1 gene of foot-and-mouth disease virus (serotype C1) has been cloned in Escherichia coli Clts cells, under the control of the bacteriophage lambda pL promoter. The expressed VP1 protein was complete and non-fused, and its molecular weight was indistinguishable from that of the VP1 obtained from virions. Cells harbouring the recombinant vectors exhibited symptoms of plasmid instability and toxicity and died in a few weeks even when never exposed to inducing conditions. A new plasmid clone in which a segment of the VP1 gene was fused with contiguous genes of the viral genome was very stable. The expressed partial VP1 protein contains the two major immunogenic domains of the virion. This system can be used as a tool to design an immunogenic VP1, and to explore possible synthetic vaccines against foot-and-mouth disease.

Structure of adenovirus fibre. I. Analysis of crystals of fibre from adenovirus serotypes 2 and 5 by electron microscopy and X-ray crystallography

An analysis by electron microscopy in amorphous ice and X-ray diffraction of four types of three-dimensional crystals of adenovirus fibre is presented. Fibre from adenovirus type 2 (Ad2) crystallizes in two forms depending on whether it is native or cleaved near the N terminus at Tyr17. Fibre from Ad5 also crystallizes in two forms, both of which contained fibre cleaved at Tyr17. Analysis of the packing of the fibres in each of these crystals suggests that the overall length of the fibre may be considerably longer (about 350 to 370 A) than previously reported. Crystals of cleaved Ad2 fibre are of sufficient quality to be characterized by X-ray diffraction. They are of space group C2 and cell dimensions a = 134.4 A, b = 77.6 A, c = 539.4 A, beta = 92.7 degrees. These crystals are remarkable in that, despite being monoclinic, the ab plane forms a perfect hexagonal lattice. This is explained by a trigonal packing of the trimeric fibre heads in the crystal. A similar feature is found for one type of Ad5 crystal, although the hexagonal lattice is 12% smaller. The crystals of cleaved Ad2 show very strong meridional intensity at a Bragg spacing of 4.4 A and weaker diffuse intensity corresponding to layer-lines of spacing 26.4 A. This must reflect the quasiperiodicity of the structure of the fibre shaft, which is apparent in the primary sequence. The occurrence of these features combined with the new determination of the length of the fibre (see also the accompanying paper) require a reappraisal of the cross-beta model of the fibre shaft proposed by Green et al.

Structure of adenovirus fibre. II. Morphology of single fibres

Adenovirus type 2 fibres in crystals appear to be significantly longer than found previously (accompanying paper). We therefore examined isolated fibre by electron microscopy and measured a length of 370 A, consistent with the length found in the crystals. The specific N-terminal structure of the fibre caused a heterogeneity in the length that may at least partially explain the values of 280 to 310 A published previously. Green et al. described a 15 amino acid repeat in the primary structure of the shaft of the fibre thought to be associated with the specific three-dimensional folding of the shaft. We compared the adenovirus type 2 (with 22 repeats) and type 3 (with 6 repeats) fibre lengths and derived a contribution of 13.2 A to the length of the shaft per 15 amino acid repeat. Specific morphological features of the fibre are discussed in relation to its amino acid sequence.