William Cockburn

Rapid production of single-chain Fv fragments in plants using a potato virus X episomal vector

We have used a plant virus episomal vector, based on potato virus X (PVX) to transiently express a single-chain Fv (scFv) and its diabody derivative in plants. The scFv was directed against a continuous epitope (cryptotope) on the coat protein of potato virus V. A cloned, full-length PVX vector sequence, containing the scFv gene, was used to direct in vitro transcription and the resulting RNA was used to inoculate Nicotiana clevelandii plants. Within a few days, plants developed characteristic symptoms and immunoblot analysis showed that accumulation of scFv protein coincided with accumulation of PVX. Targeting of the scFv to the apoplast greatly increased protein accumulation compared with cytosolic scFv and produced more severe symptoms on infected plants. ELISA demonstrated that the scFv and diabody extracted from infected plants showed the same antigen-binding specificity as that of the parental monoclonal antibody. The PVX vector is a convenient, rapid, low-cost in planta expression system that can also be used for assessment of scFv production and function prior to stable plant transformation.

Antibody expression in transgenic plants

Antibodies perform an essential role in immunity, where their prime function is to bind target proteins (antigens) in a highly specific manner. This function is exploited in many applications that use isolated antibodies. Increasingly, hosts that would not naturally produce antibodies (including plants) are being used for antibody production. Edible plants offer the potential for both the production and the delivery of antibodies to be used in the mouth or the gut. Antibody specificity is also being exploited for in situ applications, where recombinant antibodies exert their effect in the cells that produce them. Based on this approach, novel forms of plant disease resistance and new types of mutants are being developed.

Selection of phage antibodies to surface epitopes of Phytophthora infestans

Antibodies specific for surface-exposed epitopes on germlings of the plant pathogen, Phytophthora infestans, were isolated from a diverse phage library displaying single-chain Fv (scFv) antibody fragments. The library was subpanned against external soluble components released from mycelia, sporangia and germlings and a discrete population of phage antibodies isolated. Binding of monoclonal phage antibodies was demonstrated by enzyme-linked immunosorbent assay (ELISA) and diversity was established by BstNI restriction enzyme digest patterns. Antibodies were subcloned as fusions at the C-terminus of maltose binding protein (MBP) and expressed as soluble proteins in Escherichia coli. These antibody fusion proteins bound to P. infestans germlings and to mycelial homogenates from various Phytophthora species. The binding activities to mycelial homogenates of fungal species not belonging to the order Peronosporales were substantially lower. Several phage-displayed scFvs were used in conjunction with fluorescently labelled antiphage antibody to visualise the distribution of their cognate epitopes on the surface of the germlings. The combination of procedures developed here with Phytophthora demonstrates the potential of phage antibody technology in isolating antibodies to cell surface and external soluble components of pathogens, some of which may play a role in host/pathogen interactions.

Selection of phage-display peptides that bind to cucumber mosaic virus coat protein

Several discrete peptides that bind specifically to the coat protein of cucumber mosaic virus (CMV) were isolated from a diverse phage library displaying random nonapeptides on the major coat protein VIII. Enrichment was shown by polyclonal phage enzyme linked immunosorbent assay (ELISA) after three rounds of selection. Sequencing of the genes encoding 10 of these peptides revealed an absence of any conserved motifs, although nine of them contained a high proportion of proline residues. Some of the selected peptides were displayed at the N-terminus of thioredoxin and expressed in the cytoplasm of Escherichia coli. Both the phage-displayed and thioredoxin-fusion versions of the peptides could detect purified CMV and CMV present in crude leaf extracts from infected plants. By dot blot analysis, a thioredoxin-peptide fusion could readily detect as little as 5 ng of CMV. The peptides did not bind to other plant viruses. These peptides have been shown to be specific and highly sensitive tools in the detection of CMV and, as well as their diagnostic potential, they could form the basis for a novel disease resistance strategy.

Selection of Rabbit Single-chain Fv Fragments against the Herbicide Atrazine using a New Phage Display System

A convenient new bacteriophage display vector, pSD3, has been constructed and used to generate rabbit monoclonal anti-pesticide antibody fragments. Following amplification of immunoglobulin light chain, and heavy chain variable region gene libraries, restriction enzymes Sfi I and PflM I are used to assemble scFv libraries in pSD3. This allows the number of stages involving the polymerase chain reaction and restriction enzyme digestion to be minimized to optimize maintenance of the original diversity of the variable region genes in the libraries. The vector also incorporates an amber codon, a 6xHis tag and a c-myc epitope to facilitate soluble single-chain Fv production detection and purification. Using the pSD3 system two anti-atrazine single-chain Fvs were isolated from a library derived from the spleen cells of a rabbit immunized with bovine serum albumin-atrazine conjugate. Characterization of single-chain Fvs by competition and equilibrium ELISA indicated good specificity and affinity to atrazine.

Cytoplasmic expression of a soluble synthetic mammalian metallothionein-alpha domain in Escherichia coli. Enhanced tolerance and accumulation of cadmium.

Bacteria are commonly used for bioremediation of heavy metal pollution and strategies to improve their performance in this respect are desirable. In this study, an Escherichia coli strain was engineered to express a common metallothionein-α domain. The metallothionein-α domain was over-expressed in the cytoplasm of E. coli as a fusion to the carboxyl terminal of maltose binding protein. The fusion protein was highly soluble in the cytoplasm of E. coli. When grown in the presence of cadmium, cells expressing the metallothionein-α fusion protein showed increased viability compared with control cells. Cells expressing the metallothionein-α also demonstrated increased accumulation of cadmium.Bacteria are commonly used for bioremediation of heavy metal pollution and strategies to improve their performance in this respect are desirable. In this study, an Escherichia coli strain was engineered to express a common metallothionein-alpha domain. The metallothionein-alpha domain was over-expressed in the cytoplasm of E. coli as a fusion to the carboxyl terminal of maltose binding protein. The fusion protein was highly soluble in the cytoplasm of E. coli. When grown in the presence of cadmium, cells expressing the metallothionein-alpha fusion protein showed increased viability compared with control cells. Cells expressing the metallothionein-alpha also demonstrated increased accumulation of cadmium.

Cytoplasmic expression of a soluble synthetic mammalian metallothionein-α domain in Escherichia coli

Bacteria are commonly used for bioremediation of heavy metal pollution and strategies to improve their performance in this respect are desirable. In this study, an Escherichia coli strain was engineered to express a common metallothionein-α domain. The metallothionein-α domain was over-expressed in the cytoplasm of E. coli as a fusion to the carboxyl terminal of maltose binding protein. The fusion protein was highly soluble in the cytoplasm of E. coli. When grown in the presence of cadmium, cells expressing the metallothionein-α fusion protein showed increased viability compared with control cells. Cells expressing the metallothionein-α also demonstrated increased accumulation of cadmium.Bacteria are commonly used for bioremediation of heavy metal pollution and strategies to improve their performance in this respect are desirable. In this study, an Escherichia coli strain was engineered to express a common metallothionein-alpha domain. The metallothionein-alpha domain was over-expressed in the cytoplasm of E. coli as a fusion to the carboxyl terminal of maltose binding protein. The fusion protein was highly soluble in the cytoplasm of E. coli. When grown in the presence of cadmium, cells expressing the metallothionein-alpha fusion protein showed increased viability compared with control cells. Cells expressing the metallothionein-alpha also demonstrated increased accumulation of cadmium.

Filamentous bacteriophage display of a bifunctional protein A::scFv fusion

Filamentous bacteriophage display is a powerful and widely used technology for the selection of affinity ligands. However, the commonly used phagemid systems result in the production of a population of phage of which those displaying the ligand of interest represent only a small proportion. Through simple dilution and nonspecific binding effects, the presence of large numbers of ligand-free phage reduces the likelihood that weak binders will be successfully selected from a ligand library. To provide a means of avoiding such problems, we have introduced an affinity handle into the phage that permits the purification of ligand-displaying phage. The IgG binding domains ofStaphylococcus ciureus protein A (SpA) were fused to a ligand (single chain Fv[scFv]) which is displayed as a fusion with the phage surface protein ApIII. Phage-displaying SpA were separated by affinity chromatography using immobilized human IgG from non-displaying phage and the purified phage were shown to possess functional scFv. Comparisons of fusion proteins in which either the scFv or the affinity handle occupied the amino terminus of the fusion protein showed that, whereas SpA function was unaffected by position, scFv function was compromised when the scFv did not occupy the amino terminus.