Frank Sainsbury

Extremely High-Level and Rapid Transient Protein Production in Plants without the Use of Viral Replication

Plant-based overexpression of heterologous proteins has attracted much interest and development in recent years. To date, the most efficient vectors have been based on RNA virus-derived replicons. A system based on a disabled version of cowpea mosaic virus RNA-2 has been developed, which overcomes limitations on insert size and introduces biocontainment. This system involves positioning a gene of interest between the 5′ leader sequence and 3′ untranslated region (UTR) of RNA-2, thereby emulating a presumably stable mRNA for efficient translation. Thus far, the sequence of the 5′ UTR has been preserved to maintain the ability of the modified RNA-2 to be replicated by RNA-1. However, high-level expression may be achieved in the absence of RNA-1-derived replication functions using Agrobacterium-mediated transient transformation. To investigate those features of the 5′ UTR necessary for efficient expression, we have addressed the role of two AUG codons found within the 5′ leader sequence upstream of the main initiation start site. Deletion of an in-frame start codon upstream of the main translation initiation site led to a massive increase in foreign protein accumulation. By 6 d postinfiltration, a number of unrelated proteins, including a full-size IgG and a self-assembling virus-like particle, were expressed to >10% and 20% of total extractable protein, respectively. Thus, this system provides an ideal vehicle for high-level expression that does not rely on viral replication of transcripts.

Bioengineering virus-like particles as vaccines

Virus‐like particle (VLP) technology seeks to harness the optimally tuned immunostimulatory properties of natural viruses while omitting the infectious trait. VLPs that assemble from a single protein have been shown to be safe and highly efficacious in humans, and highly profitable. VLPs emerging from basic research possess varying levels of complexity and comprise single or multiple proteins, with or without a lipid membrane. Complex VLP assembly is traditionally orchestrated within cells using black‐box approaches, which are appropriate when knowledge and control over assembly are limited. Recovery challenges including those of adherent and intracellular contaminants must then be addressed. Recent commercial VLPs variously incorporate steps that include VLP in vitro assembly to address these problems robustly, but at the expense of process complexity. Increasing research activity and translation opportunity necessitate bioengineering advances and new bioprocessing modalities for efficient and cost‐effective production of VLPs. Emerging approaches are necessarily multi‐scale and multi‐disciplinary, encompassing diverse fields from computational design of molecules to new macro‐scale purification materials. In this review, we highlight historical and emerging VLP vaccine approaches. We overview approaches that seek to specifically engineer a desirable immune response through modular VLP design, and those that seek to improve bioprocess efficiency through inhibition of intracellular assembly to allow optimal use of existing purification technologies prior to cell‐free VLP assembly. Greater understanding of VLP assembly and increased interdisciplinary activity will see enormous progress in VLP technology over the coming decade, driven by clear translational opportunity. Biotechnol. Bioeng. 2014;111: 425–440.

A Serine Carboxypeptidase-Like Acyltransferase Is Required for Synthesis of Antimicrobial Compounds and Disease Resistance in Oats

Serine carboxypeptidase-like (SCPL) proteins have recently emerged as a new group of plant acyltransferases. These enzymes share homology with peptidases but lack protease activity and instead are able to acylate natural products. Several SCPL acyltransferases have been characterized to date from dicots, including an enzyme required for the synthesis of glucose polyesters that may contribute to insect resistance in wild tomato (Solanum pennellii) and enzymes required for the synthesis of sinapate esters associated with UV protection in Arabidopsis thaliana. In our earlier genetic analysis, we identified the Saponin-deficient 7 (Sad7) locus as being required for the synthesis of antimicrobial triterpene glycosides (avenacins) and for broad-spectrum disease resistance in diploid oat (Avena strigosa). Here, we report on the cloning of Sad7 and show that this gene encodes a functional SCPL acyltransferase, SCPL1, that is able to catalyze the synthesis of both N-methyl anthraniloyl- and benzoyl-derivatized forms of avenacin. Sad7 forms part of an operon-like gene cluster for avenacin synthesis. Oat SCPL1 (SAD7) is the founder member of a subfamily of monocot-specific SCPL proteins that includes predicted proteins from rice (Oryza sativa) and other grasses with potential roles in secondary metabolism and plant defense.

Cowpea mosaic Virus: The Plant Virus–Based Biotechnology Workhorse

In the 50 years since it was first described, Cowpea mosaic virus (CPMV) has become one of the most intensely studied plant viruses. Research in the past 15 to 20 years has shifted from studying the underlying genetics and structure of the virus to focusing on ways in which it can be exploited in biotechnology. This work led first to the use of virus particles to present peptides, then to the creation of a variety of replicating virus vectors and finally to the development of a highly efficient protein expression system that does not require viral replication. The circle has been completed by the use of the latter system to create empty particles for peptide presentation and other novel uses. The history of CPMV in biotechnology can be likened to an Ouroborus, an ancient symbol depicting a snake or dragon swallowing its own tail, thus forming a circle.

Efficient generation of cowpea mosaic virus empty virus-like particles by the proteolytic processing of precursors in insect cells and plants.

To elucidate the mechanism of formation of cowpea mosaic virus (CPMV) particles, RNA-2-encoded precursor proteins were expressed in Spodoptera frugiperda cells. Processing of the 105K and 95K polyproteins in trans to give the mature Large (L) and Small (S) coat proteins required both the 32K proteinase cofactor and the 24K proteinase itself, while processing of VP60, consisting of the fused L-S protein, required only the 24K proteinase. Release of the L and S proteins resulted in the formation of virus-like particles (VLPs), showing that VP60 can act as a precursor of virus capsids. Processing of VP60 expressed in plants also led to efficient production of VLPs. Analysis of the VLPs produced by the action of the 24K proteinase on precursors showed that they were empty (RNA-free). This has important implications for the use of CPMV VLPs in biotechnology and nanotechnology as it will permit the use of noninfectious particles.

Biochemical analysis of a multifunctional cytochrome P450 (CYP51) enzyme required for synthesis of antimicrobial triterpenes in plants

Significance We carried out functional analysis of the oat enzyme AsCYP51H10, which is a divergent member of the CYP51 cytochrome P450 family and showed that this enzyme is able to catalyze both hydroxylation and epoxidation of the simple triterpene β-amyrin to give 12,13β-epoxy-3β,16β-dihydroxy-oleanane (12,13β-epoxy-16β-hydroxy-β-amyrin). In contrast, the canonical CYP51 enzymes are highly conserved and catalyze only sterol demethylation. We further show that the C12,13 epoxy group is critical for antifungal activity, a discovery that has important implications for triterpene metabolic engineering for food, health, and industrial biotechnology applications. Members of the cytochromes P450 superfamily (P450s) catalyze a huge variety of oxidation reactions in microbes and higher organisms. Most P450 families are highly divergent, but in contrast the cytochrome P450 14α-sterol demethylase (CYP51) family is one of the most ancient and conserved, catalyzing sterol 14α-demethylase reactions required for essential sterol synthesis across the fungal, animal, and plant kingdoms. Oats (Avena spp.) produce antimicrobial compounds, avenacins, that provide protection against disease. Avenacins are synthesized from the simple triterpene, β-amyrin. Previously we identified a gene encoding a member of the CYP51 family of cytochromes P450, AsCyp51H10 (also known as Saponin-deficient 2, Sad2), that is required for avenacin synthesis in a forward screen for avenacin-deficient oat mutants. sad2 mutants accumulate β-amyrin, suggesting that they are blocked early in the pathway. Here, using a transient plant expression system, we show that AsCYP51H10 is a multifunctional P450 capable of modifying both the C and D rings of the pentacyclic triterpene scaffold to give 12,13β-epoxy-3β,16β-dihydroxy-oleanane (12,13β-epoxy-16β-hydroxy-β-amyrin). Molecular modeling and docking experiments indicate that C16 hydroxylation is likely to precede C12,13 epoxidation. Our computational modeling, in combination with analysis of a suite of sad2 mutants, provides insights into the unusual catalytic behavior of AsCYP51H10 and its active site mutants. Fungal bioassays show that the C12,13 epoxy group is an important determinant of antifungal activity. Accordingly, the oat AsCYP51H10 enzyme has been recruited from primary metabolism and has acquired a different function compared to other characterized members of the plant CYP51 family—as a multifunctional stereo- and regio-specific hydroxylase in plant specialized metabolism.

Rapid Transient Production in Plants by Replicating and Non-Replicating Vectors Yields High Quality Functional Anti-HIV Antibody

Background The capacity of plants and plant cells to produce large amounts of recombinant protein has been well established. Due to advantages in terms of speed and yield, attention has recently turned towards the use of transient expression systems, including viral vectors, to produce proteins of pharmaceutical interest in plants. However, the effects of such high level expression from viral vectors and concomitant effects on host cells may affect the quality of the recombinant product. Methodology/Principal Findings To assess the quality of antibodies transiently expressed to high levels in plants, we have expressed and characterised the human anti-HIV monoclonal antibody, 2G12, using both replicating and non-replicating systems based on deleted versions of Cowpea mosaic virus (CPMV) RNA-2. The highest yield (approximately 100 mg/kg wet weight leaf tissue) of affinity purified 2G12 was obtained when the non-replicating CPMV-HT system was used and the antibody was retained in the endoplasmic reticulum (ER). Glycan analysis by mass-spectrometry showed that the glycosylation pattern was determined exclusively by whether the antibody was retained in the ER and did not depend on whether a replicating or non-replicating system was used. Characterisation of the binding and neutralisation properties of all the purified 2G12 variants from plants showed that these were generally similar to those of the Chinese hamster ovary (CHO) cell-produced 2G12. Conclusions Overall, the results demonstrate that replicating and non-replicating CPMV-based vectors are able to direct the production of a recombinant IgG similar in activity to the CHO-produced control. Thus, a complex recombinant protein was produced with no apparent effect on its biochemical properties using either high-level expression or viral replication. The speed with which a recombinant pharmaceutical with excellent biochemical characteristics can be produced transiently in plants makes CPMV-based expression vectors an attractive option for biopharmaceutical development and production.

Cowpea mosaic virus unmodified empty viruslike particles loaded with metal and metal oxide.

The development of methods for the production of empty Cowpea mosaic virus (CPMV) virus-like particles (VLPs) that are devoid of RNA, eVLPs, has renewed promise in CPMV capsid technologies. The recombinant nature of CPMV eVLP production means that the extent and variety of genetic modifications that may be incorporated into the particles is theoretically much greater than those that can be made to infectious CPMV virions due to restrictions on viral propagation of the latter. Free of the infectious agent, the genomic RNA, these particles are now finding potential uses in vaccine development, in vivo imaging, drug delivery, and other nanotechnology applications that make use of internal loading of the empty particles. Here we describe methods for the genetic modification and production of CPMV eVLPs and describe techniques useful for their characterization.

Transient expressions of synthetic biology in plants

Highlights • Transient expression is an effective method for the co-expression of proteins.• A number of vectors are available to facilitate this use.• They can be used to produce complex macromolecules and analyse metabolic pathways.• Transient expression is likely to become a method of choice for plant synthetic biology.

Developmental reorientation of transverse cortical microtubules to longitudinal directions: a role for actomyosin-based streaming and partial microtubule-membrane detachment

Transversely oriented cortical microtubules in elongating cells typically reorient themselves towards longitudinal directions at the end of cell elongation. We have investigated the reorientation mechanism along the outer epidermal wall in maturing leek (Allium porrum L.) leaves using a GFP-MBD microtubule reporter gene and fluorescence microscopy. Incubating leaf segments for 14-18 h with the anti-actin or anti-actomyosin agents, 20 microm cytochalasin D or 20 mM 2,3-butanedione monoxime, inhibited the normal developmental reorientation of microtubules to the longitudinal direction. Observation of living cells revealed a small subpopulation of microtubules with their free ends swinging into oblique or longitudinal directions, before continuing to assemble in the new direction. Electron microscopy confirmed that longitudinal microtubules are partly detached from the plasma membrane. Incubating leaf segments with 0.2% 1 degree-butanol, an activator of phospholipase D, which has been implicated in plasma membrane-microtubule anchoring, promoted the reorientation, presumably by promoting microtubule detachment from the membrane. Stabilizing microtubules with 10 microm taxol also promoted longitudinal orientation, even in the absence of cytoplasmic streaming. These results were consistent with confocal microscopy of live cells before and after drug treatments, which also revealed that the slow (days) global microtubule reorientation is superimposed over short-term (hours) regional cycling in a clockwise and an anti-clockwise direction. We propose that partial detachment of transverse microtubules from the plasma membrane in maturing cells exposes them to hydrodynamic forces of actomyosin-driven cytoplasmic streaming, which bends or shifts pivoting microtubules into longitudinal directions, and thus provides an impetus to push microtubule dynamics in the new direction.