Expression and purification of heterologous proteins in plant tissue using a geminivirus vector system.

In the past, plant molecular biologists have relied on Escherichia coli, baculovirus and other expression systems to produce plant proteins to quantities sufficient for biochemical analysis. However, such expression systems often result in the production of proteins which possess improper posttranslational modifications. Here, we present a plant virus-based expression system superior to those currently available. We demonstrate that bean yellow dwarf geminivirus (BeYDV) replicates and expresses foreign proteins at high levels in tobacco, Arabidopsis, and other dicotyledonous plants, making it more universal than plant RNA viruses with restricted host ranges which are currently used as expression systems. The DNA-based nature of the BeYDV genome renders it stable for the incorporation of large plant open reading frames, and gives it an advantage over other plant virus-based expression systems which possess insert size restrictions. Using this expression system, the rapid accumulation of a novel Arabidopsis-derived mitogen-activated protein kinase to levels sufficient for standard biochemical analysis is demonstrated.

Identification of a repressor of late gene expression within the AcMNPV genome.

Viral replication and late gene expression of Autographa californica multiple nucleopolyhedrovirus (AcMNPV) requires a series of late expression factors. We examined the AcMNPV genome for additional factors which affect late gene expression. During these investigations, a segment of the AcMNPV genome located immediately downstream to LEF-7 was found to possess a repressor activity. Elimination of this region resulted in greatly enhanced late gene expression. We were unable to link repressor activity to a single open reading frame, suggesting that a cis-acting element rather than a trans-acting factor is responsible for this phenomenon.

Characterization of HCF-1, a determinant of Autographa californica multiple nucleopolyhedrovirus host specificity.

Autographa californica multiple nucleopolyhedrovirus (AcMNPV) infects a wide variety of insect species. A number of AcMNPV late expression factors that are involved in replication have been identified as playing a role in determining host specificity. Host cell factor-1, or HCF-1, was previously demonstrated to be essential for viral replication in Tn-368 cells. Here we demonstrate that HCF-1 is an early protein and localizes to the cell nucleus. Coprecipitation experiments revealed that HCF-1 interacts with itself but none of the other late expression factors required for replication in Tn-368 cells. HCF-1 mutants were constructed and utilized to search for the domains involved in HCF-1 biological function and oligomerization. Possible roles of HCF-1 in determining host specificity are discussed.

Identification and in vivo expression of a prokaryotic-like ribosome recognition sequence upstream of the coat protein gene of potato virus X.

Conserved prokaryotic sequence motifs, distinct from the classic Shine-Dalgarno sequence, yet possessing homology to 16S rRNA in E. coli have been identified in a number of plant viruses. In this report, a similar Shine-Dalgarno-like motif located immediately upstream to the CP gene of potato virus X (PVX) was demonstrated to enable expression of a reporter gene in E. coli to approximately one third the level of a similar construct containing the classical Shine-Dalgarno sequence. Both PVX-specific CP and RNA transcripts were detected in chloroplasts purified from transgenic potato plants containing the PVX CP gene and corresponding leader sequence. Protoplasts generated from these transgenic plants were used to demonstrate that expression of the PVX CP from chloroplasts is possible. The implications of these results on the PVX infection cycle are discussed.

Host cell receptor binding by baculovirus GP64 and kinetics of virion entry.

GP64 is the major envelope glycoprotein from budded virions of the baculoviruses Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) and Orgyia pseudotsugata multicapsid nucleopolyhedrovirus (OpMNPV). To examine the potential role of GP64 as a viral attachment protein in host cell receptor binding, we generated, overexpressed, and characterized a soluble form of the OpMNPV GP64 protein, GP64solOp. Assays for trimerization, sensitivity to proteinase K, and reduction by dithiothreitol suggested that GP64solOp was indistinguishable from the ectodomain of the wild-type OpMNPV GP64 protein. Virion binding to host cells was analyzed by incubating virions with cells at 4 degrees C in the presence or absence of competitors, using a single-cell infectivity assay to measure virion binding. Purified soluble GP64 (GP64solOp) competed with a recombinant AcMNPV marker virus for binding to host cells, similar to control competition with psoralen-inactivated wild-type AcMNPV and OpMNPV virions. A nonspecific competitor protein did not similarly inhibit virion binding. Thus specific competition by GP64solOp for virion binding suggests that the GP64 protein is a host cell receptor-binding protein. We also examined the kinetics of virion internalization into endosomes and virion release from endosomes by acid-triggered membrane fusion. Using a protease sensitivity assay to measure internalization of bound virions, we found that virions entered Spodoptera frugiperda Sf9 cells between 10 and 20 min after binding, with a half-time of approximately 12.5 min. We used the lysosomotropic reagent ammonium chloride to examine the kinetics of membrane fusion and nucleocapsid release from endosomes after membrane fusion. Ammonium chloride inhibition assays indicated that AcMNPV nucleocapsids were released from endosomes between 15 and 30 min after binding, with a half-time of approximately 25 min.

Effect of N-terminal deletions on the activity of pokeweed antiviral protein expressed in E. coli.

Pokeweed antiviral protein (PAP) from Phytolacca americana is a highly specific N-glycosidase removing adenine residues (A4324 in 28S rRNA and A2660 in 23S rRNA) from intact ribosomes of both eukaryotes and prokaryotes. Due to the ribosome impairing activity the gene coding for mature PAP has not been expressed so far in bacteria whereas the full-length gene (coding for the mature 262 amino acids plus two signal peptides of 22 and 29 amino acids at both N- and C-termini, respectively) has been expressed in Escherichia coli. In order to determine: 1) the size of the N-terminal region of PAP which is required for toxicity to E. coli; and 2) the location of the putative enzymatic active site of PAP, 5'-terminal progressive deletion of the PAP full-length gene was carried out and the truncated forms of the gene were cloned in a vector containing a strong constitutive promoter and a consensus Shine-Dalgarno ribosome binding site. The ribosome inactivation or toxicity of the PAP is used as a phenotype characterized by the absence of E. coli colonies, while the mutation of PAP open reading frames in the small number of survived clones is used as an indicator of the toxicity to E. coli cells. Results showed that the native full-length PAP gene was highly expressed and was not toxic to E. coli cells although in vitro ribosome inactivating activity assay indicated it was active. However, all of the N-terminal truncated forms (removal of seven to 107 codons) of the PAP gene were toxic to E. coli cells and were mutated into either out of frame, early termination codon or inactive form of PAP (i.e., clone PAP delta107). Deletion of more than 123 codons restored the correct gene sequence but resulted in the loss of the antiviral and ribosome inactivating activities and by the formation of a large number of clones. These results suggest that full-length PAP (with N- and C-terminal extensions) might be an inactive form of the enzyme in vivo presumably by inclusion body formation or other unknown mechanisms and is not toxic to E. coli cells. However, it is activated by at least seven codon deletions at the N-terminus. Deletions from seven through to 107 amino acids were lethal to the cells and only mutated forms (inactive) of the gene were obtained. But deletion of more than 123 amino acids resulted in the loss of enzymatic activity and made it possible to express the correct PAP gene in E. coli. Because deletion of Tyr94 and Val95, which are involved in the binding of the target adenine base, did not abolish the activity of PAP, it is concluded that the location previously proposed for PAP enzymatic active site should be reassessed.

Expression of the coat protein of potato virus X from a dicistronic mRNA in transgenic potato plants.

Transgenic potato plants were generated which express a dicistronic mRNA corresponding to the 8 kDa protein and coat protein (CP) genes of potato virus X (PVX). Northern blot analysis of RNA isolated from these plants indicated that both the 8 kDa protein and the CP are translated from this dicistronic mRNA. Expression of both of these proteins in transgenic plants was demonstrated by Western blot analysis, and suggests that translation of CP takes place either by initiation by internal entry of ribosomes or by a termination/reinitiation mechanism. CP was detected in protoplasts electroporated with RNA transcripts of the dicistronic construct in the presence or absence of a stable hairpin structure at the 5' terminus, suggesting that the former model is more likely. Similar results were obtained when a DNA fragment containing the PVX CP leader sequence was placed between two reporter genes in the transient assay system. These results suggest that potexvirus CP expression may take place from the genomic RNA as well as from the subgenomic RNA.

Immunological detection of the 8K protein of potato virus X (PVX) in cell walls of PVX-infected tobacco and transgenic potato.

Open reading frame 4 (ORF4) of the potato virus X (PVX) genome encodes an 8K protein which is a part of the "triple gene block" and is known to play a role in the cell-to-cell movement of the virus in infected plants. To locate the 8K protein and further elucidate the mechanism of cell-to-cell transport of PVX, antibodies were raised against the 8K protein and used to localize this protein in PVX-infected tobacco and in transgenic potato plants expressing the 8K protein both by subcellular fractionation and by immunolabeling with colloidal gold. The results indicated that the 8K protein was localized to the cell wall.

Comparative analysis of species-independent, isozyme-specific amino-acid substitutions in mammalian muscle, brain and liver glycogen phosphorylases.

Mammalian glycogen phosphorylases exist as three isozymes, muscle, brain and liver, that exhibit different responses to activation by phosphorylation and AMP, regardless of species. To identify species-independent, amino-acid substitutions that may be important determinants in differential isozyme control, we have sequenced cDNAs containing the entire protein coding regions of rat muscle and brain phosphorylases. Nucleotide sequence comparisons with rat liver, rabbit muscle, and human muscle, brain and liver phosphorylase genes, indicate that muscle and brain isozymes are more related to each other than to the liver isozyme. Unlike the human isozymes, there is little difference in GC content of codons in the rat isozymes. In relation to the rabbit muscle isozyme three-dimensional structure, amino-acid sequence comparisons indicate that very few nonconservative isozyme-specific substitutions occur in buried and dimer contact residues. There is strict conservation of active site, pyridoxal-phosphate-binding site and nucleoside inhibitor site residues, as well as CAP loop and helix-2 residues that comprise the phosphorylation activation and part of the AMP binding sites. In contrast, five liver isozyme-specific substitutions occur between residues 313-325 and another at residue 78 which may be important determinants in the poor activation of this isozyme by AMP. Substitutions in the brain isozyme at residues 21-23, 405 and 435 may play a role in its poor response to activation by phosphorylation.