David H.L. Bishop

Identification of conserved and variable regions in the envelope glycoprotein sequences of two feline immunodeficiency viruses isolated in Zurich, Switzerland

The nucleotide sequences of the envelope (env) coding regions of two strains of the feline immunodeficiency virus isolated in Zurich, Switzerland (FIVZ1, FIVZ2) have been analysed. In addition, the complete sequence of the FIVZ1 isolate has been determined. Comparisons have been made with the previously published sequences of three North American isolates (PPR and the Petaluma strains FIV34TF10 and FIV14). The isolate FIVZ1 was very similar to the Petaluma strains of FIV and may represent a clonal derivative acquired by contamination. Overall there are between 2.6% and 15.1% amino acid changes in the env gene products of the five isolates. Of the Zurich isolates, FIVZ2 exhibited the greatest divergence to the other viruses and based on its genotype, phenotype and origins probably represents a new isolate of FIV. Possibly the viruses diverged only recently from a common ancestor. Some 31 of the 33 cysteine residues and 17 of the 21 potential N-linked glycosylation sites of the FIV34TF10 env gene product were conserved among all five isolates. The open reading frame 3 (ORF3, or D) which overlaps the env gene (but is encoded in a different frame) has an ATG codon downstream of a potential splice acceptor site in all five isolates, supporting the view that it encodes a viral gene product. In ORF3 of FIVZ1 a stop codon was located 16 amino acids upstream of the stop codon of ORF3 of the other isolates. The ORF4 (or G) of isolate FIVZ2, thought to be the second coding exon of an FIV rev-like gene, contained a nucleotide deletion in amino acid 45 of ORF4, resulting in a--1 frameshift at this position. Comparison of the LTR sequences of the five isolates identified conserved promoter/enhancer elements. A potential stem-loop structure was identified in the R region of the LTRs of all the isolates, despite the heterogeneity of nucleotide sequences in that region. Such structures (TAR) are present in analogous regions of other lentiviruses and are responsible for tat-mediated trans-activation.

Bunyavirus-vector interactions

Recent advances in the genetics and molecular biology of bunyaviruses have been applied to understanding bunyavirus-vector interactions. Such approaches have revealed which virus gene and gene products are important in establishing infections in vectors and in transmission of viruses. However, much more information is required to understand the molecular mechanisms of persistent infections of vectors which are lifelong but apparently exert no untoward effect. In fact, it seems remarkable that LAC viral antigen can be detected in almost every cell in an ovarian follicle, yet no untoward effect on fecundity and no teratology is seen. Similarly the lifelong infection of the vector would seem to provide ample opportunity for bunyavirus evolution by genetic drift and, under the appropriate circumstances, by segment reassortment. The potential for bunyavirus evolution by segment reassortment in vectors certainly exists. For example the Group C viruses in a small forest in Brazil seem to constitute a gene pool, with the 6 viruses related alternately by HI/NT and CF reactions, which assay respectively M RNA and S RNA gene products (Casals and Whitman, 1960; Shope and Causey, 1962). Direct evidence for naturally occurring reassortant bunyaviruses has also been obtained. Oligonucleotide fingerprint analyses of field isolates of LAC virus and members of the Patois serogroup of bunyaviruses have demonstrated that reassortment does occur in nature (El Said et al., 1979; Klimas et al., 1981; Ushijima et al., 1981). Determination of the genotypic frequencies of viruses selected by the biological interactions of viruses and vectors after dual infection and segment reassortment is an important issue. Should a virus result that efficiently interacts with alternate vector species, the virus could be expressed in different circumstances with serious epidemiologic consequences. Dual infection of vectors with different viruses is not unlikely, because many bunyaviruses are sympatric in nature. For example, the Ae. trivittatus-cottontail rabbit and the Ae. triseriatus-squirrel arbovirus cycles are sympatric in the ecotone between their respective grassland and forest ecosystems (LeDuc, 1979). Should a LaCrosse virus variant or reassortant evolve that was efficiently vectored by Ae. trivittatus mosquitoes, significantly more human infections with La Crosse virus would likely occur. Unlike Ae. triseriatus, Ae. trivittatus mosquitoes are not restricted to forested areas and consequently are more likely to encounter and to feed upon humans.(ABSTRACT TRUNCATED AT 400 WORDS)

BACULOVIRUS MULTIGENE EXPRESSION VECTORS AND THEIR USE FOR UNDERSTANDING THE ASSEMBLY PROCESS OF ARCHITECTURALLY COMPLEX VIRUS PARTICLES

The baculovirus expression vector is a eukaryotic DNA viral vector for the cloning and expression of foreign genes in cultured lepidopteran insect cells and insects. It has become an important tool for the large-scale production of recombinant proteins for a variety of applications including the structure-function analysis of genes and their gene products. We have developed a number of baculovirus multigene expression vectors and utilized these to understand the assembly process of multicomponent capsid structures of large viruses such as bluetongue virus (BTV), a member of the Orbivirus genus within the family Reoviridae. BTV is some 810 A in diameter and comprised of two protein shells containing four major proteins, VP2, VP5, VP7 and VP3, surrounding a genome of ten double-stranded RNA segments and three minor proteins (VP2, VP4 and VP6). BTV is the etiological agent of a sheep disease that is sometimes fatal in certain parts of the world (e.g., Africa, Asia, and the Americas). Using baculovirus multigene vectors, we have co-expressed various combinations of BTV genes in insect cells and produced structures that mimic the various stages of BTV assembly. For example, co-expressed VP3 and VP7 form BTV core-like particles, while co-expressed VP2, VP5, VP7 and VP3 form BTV virus-like particles. Using deletion, point and domain switching analyses of each protein, we have been able to identify certain sequences in the VP7 and VP3 proteins that are essential for the assembly of core-like particles. These expression and biochemical studies have been complemented by collaboration studies using cryo-electron microscopy and image processing analyses to provide the three-dimensional structure of the expressed particles. In addition and with other associates, we have used X-ray crystallography of VP7 to deduce its atomic structure. Extensive studies on the immune responses elicited by these self-assembled particles, and chimeric derivatives involving various foreign antigens, have been carried out. Finally, using as little as 10 microg of the self-assembled virus-like particles, we have shown that they can confer long-lasting protection in sheep against BTV.

Secretion of biologically active leech hirudin from baculovirus-infected insect cells

The thrombin inhibitor, hirudin, from the leech Hirudo Medicinalis, is the most powerful natural anticoagulant known. It has been characterized as a polypeptide of 65 amino acids which exhibits its anticoagulant properties by binding tightly and specifically to alpha-thrombin. The potency and specificity of hirudin have generated interest on its possible use in the treatment or prophylaxis of various thrombotic diseases. We have used the baculovirus expression system to efficiently produce active hirudins in insect cells. The Autographa californica nuclear polyhedrosis virus has proved useful as a helper-independent viral expression vector for high-level production of recombinant proteins in cultured insect cells. Hirudin variants (HV1 and HV2) were produced in infected insect cells as secreted proteins by joining their coding sequences to the leader peptide sequence of the vescicular stomatitis virus G protein. The recombinant products were biologically active and, interestingly, N-terminal sequencing of HV1 revealed that the heterologous leader peptide is correctly removed.

Characterization of baculovirus-expressed Rift Valley fever virus glycoproteins synthesized in insect cells

A cDNA corresponding to the complete coding region of the M RNA of the M12 mutant of Rift Valley fever virus (RVFV) strain ZH548 (K. Takehara, M-K. Min, J.K. Battles, K. Sugiyama, V.C. Emery, J.M. Dalrymple, and D.H.L. Bishop, Virology, 169, 452-457, 1989) has been inserted into the baculovirus transfer vector pAcYM1. By comparison with the parent RVFV, the M RNA of the M12 mutant has a new small open reading frame (ORF1) upstream of the one that initiates the precursor of the viral glycoproteins (ORF2, gene order: NS(M)-G2-G1). A derivative of the M12 cDNA was prepared from which most of the upstream sequences (including a polyT tract and ORF1) were removed. Other cDNA constructs were made from this derivative, constructs in which most of the G1 sequences were also removed, or most of the NS(M) coding sequences, or all of the NS(M) and most of G2 coding sequences. Each RVFV M cDNA construct was inserted into a pAcYM1 transfer vector and recombinant baculoviruses were produced (RVM1-5). The derived viruses were employed to study the expression and properties of the RVFV glycoproteins in Spodoptera frugiperda insect cells. For each recombinant virus evidence was obtained which indicated that the RVFV glycoproteins were produced and processed in the insect cells. Although four of the recombinants gave low expression levels of the RVFV glycoproteins, for the vector that made only the G1 product, the expression level was significantly higher. Immunofluorescence analyses established that the RVFV glycoproteins were present both at intracellular locations and on the surface of the recombinant baculovirus infected insect cells.

Expression of snowshoe hare bunyavirus S RNA coding proteins by recombinant baculoviruses

Recombinant baculoviruses have been constructed that express the two snowshoe hare (SSH) bunyavirus proteins coded in overlapping reading frames of the SSH S viral-complementary RNA species (namely the nucleoprotein, N, and the nonstructural protein, NSS). The 26.5 kDa N protein, which is read from the first AUG of the mRNA containing the SSH S sequence, was expressed at a high level (estimated to be ca 40% of the stained cellular proteins in recombinant baculovirus-infected Spodoptera frugiperda cells). This level of expression was much higher than that of the 10.5 kDa NSS protein made at the same time (estimated to be less than 1% of the stained proteins), presumably due in part to lower levels of translation initiation from the second AUG (19 nucleotides downstream). Bal31 nuclease digestion was used to delete the first ATG of the SSH DNA sequence in the baculovirus transfer vector and BamHI was used to remove downstream N coding sequences. A second recombinant baculovirus was constructed from the products that only expressed the SSH NSS protein. The yield of NSS protein was estimated to be of the order of ca 2% of the stained cellular proteins. A third recombinant transfer vector made from the products of the Bal31 digestion, fortuitously possessed a new ATG 8-10 nucleotides upstream of the NSS ATG. A recombinant virus derived from this vector synthesized essentially similar quantities (ca 2% each) of both the NSS protein and a 16.7 kDa N-related product.