A simple and rapid method for selecting high producers of recombinant proteins in individual clones of P. pastoris.

The identification of clones expressing high levels of recombinant protein in Pichia pastoris is usually dependant upon SDS-PAGE, Western blotting, or bioactivity-based assays that are labour and time-consuming. We describe a rapid method that images green fluorescence protein (GFP) of individual P. pastoris clones transformed with vectors that express the proteins as GFP C- terminal fusion. In this report we have used the system to monitor expression of three proteins from Venturia inaequalis. Culture plates containing individual colonies were imaged on a Fuji LAS-3000 system and the intensity of fluorescence of GFP [Mean Gray Value (MGV)] of each colony recorded. Two common variables, the time course of expression and induction temperature were also optimised using this method. The results show that colonies with high levels of GFP fluorescence can be successfully used to identify, at an early stage, colonies expressing high levels of recombinant proteins. This correlation can be used to monitor the conditions for optimization of the expression and accumulation of extracellular recombinant protein in medium and to identify fractions containing GFP-tagged recombinant proteins during protein purification.

Heterologous expression, isotopic-labeling and immuno-characterization of Cin1, a novel protein secreted by the phytopathogenic fungus Venturia inaequalis.

The phytopathogenic fungus Venturia inaequalis causes scab of apple. Once this fungus penetrates the plant surface, it forms a specialized body called a stroma between the inner cuticle surface and the epidermal cell wall. A novel V. inaequalis gene, cin1, is strongly up-regulated in the early stages of infection. This gene codes for a 523 residue secreted protein, containing eight imperfect repeats of approximately 60 amino acids. Cin1 was expressed in the methanolytic yeast Pichia pastoris using the pPICZ vector system. A protein of 57 kDa was secreted by these transformants and peptide fingerprinting indicated that it was the Cin1 protein product. Multiple angle laser light scattering confirmed the predicted mass of Cin1, showing it was not glycosylated by Pichia and was monomeric in solution. Through measurements of the hydrodynamic properties of Cin1, the experimental Stokes radius of Cin1 was calculated and corresponded to the theoretical value for a natively folded globular protein of size 57 kDa. The mobility of recombinant Cin1 on native PAGE was also consistent with that of a folded protein. To simplify future structural analyses, a two-domain truncated version, Cin1-2D, consisting of domains one and two, was also expressed using the same vector system. Both proteins were purified to homogeneity. Conditions for maximal (>98%) incorporation of 13C and 15N were determined. A mouse polyclonal antibody and three monoclonal antibodies (MAbs) were raised against the full-length version of Cin1. Analysis of the three MAbs using surface plasmon resonance indicated binding to distinct epitopes on the Cin1 protein. Western blots confirmed the different specificities of each MAb.

An E. coli expression system optimized for DELLA proteins.

The DELLA proteins are involved in regulation of plant growth in response to phytohormonal signals such as GA, ethylene, and auxin. They have become one of most challenging and active area of research due to their fundamental roles in plant biology. Here, we describe the first successful expression of the N-terminal domains of DELLA proteins of Arabidopsis thaliana and Malus domestica in Escherichia coli system which will be used to produce monoclonal antibodies for profiling protein micro-arrays. Optimizations of the cloning, expression, and purification using specific tags have been discussed.

Expression in Escherichia coli and in vitro refolding of the plant transcription factor Arabidopsis thaliana RGL3.

Recombinant Arabidopsis thaliana (At) RGL-3, using two vectors pMAL-c2 and pET 21, was expressed as inclusion bodies in Escherichia coli under a range of temperature conditions. Only low levels (8-12% of total protein) of soluble protein were produced. The "soluble" fraction was shown by native PAGE to exist as soluble aggregates of RGL-3. A method was developed, consisting of induction of expression at various temperatures that yielded high levels of refoldable inclusion bodies using the pET vector. (At) RGL-3, as inclusion bodies, was solubilized in 8M urea and refolding was initiated by 20-fold direct dilution of denaturant. Under optimal conditions, 87% of the denatured protein of inclusion bodies was successfully re-natured. Refolding was monitored by "native" PAGE. Refolded RGL-3 was shown to be present as monomers and dimers. Attempts to further purify His-tagged RGL-3 using Ni/NTA chromatography resulted in the formation of higher polymers.

Transformation of the ryegrass endophyte Neotyphodium lolii can alter its in planta mycelial morphology.

The fungus Neotyphodium lolii grows in the intercellular spaces of perennial ryegrass as a mutualistic endosymbiont. One of the benefits it conveys to the plant is the production of alkaloids toxic to herbivores. We wanted to determine in planta expression patterns of the N. lolii 3-hydroxy-3-methylglutaryl-CoA reductase (HMG CoA reductase) gene, believed to be involved in the synthesis of two of these alkaloid toxins, lolitrem B and ergovaline. We transformed the N. lolii strain Lp19 with plasmids, in which DNA fragments upstream of the open reading frame of the N. lolii HMG CoA reductase gene controlled expression of the GUS (gusA; Escherichia coli beta-glucuronidase) reporter gene. In exponentially growing cultures, the GUS gene was not expressed if the length of upstream sequence was less than 400 bp, and >1100 bp were required for maximum expression. When reintroduced into ryegrass plants, transformants often showed highly increased hyphal branching compared to the wild-type parent strain, although in culture their growth kinetics and morphology were indistinguishable from that of the wild-type. Deterioration of hyphae and the hypha-plant interface occurred and in one transformant reduced tillering (formation of new plants, referred to in agronomy as tillers) and death of infected plants. We found no evidence that these abnormalities were caused by interference of the construct with the function of the native gene, as judged by analysis of the site of integration of the promoter-GUS cassette, expression of the native gene and lolitrem B and ergovaline levels in infected plants. However, there was some correlation between GUS expression and the degree of hyphal branching, suggesting that high levels of beta-glucuronidase may disturb the symbiotic interaction. Levels of another alkaloid, peramine, were also not significantly affected by transformation. In previous studies increased in planta branching of the endophyte has been shown to be associated with a severe reduction of alkaloid production. Our results show that a plant-endophyte association in which increased branching occurs is still able to produce alkaloids.

The trans-acting protein interacting with the DNA motif proximal to the transcriptional start site of plant L-asparaginase is bacterial sarcosine oxidase.

A trans-acting protein interacting with a specific sequence motif proximal to the transcriptional start site of the L-asparaginase promoter has been observed previously (E. Vincze, J. M. Reeves, E. Lamping, K. J. F. Farnden, and P. H. S. Reynolds, Plant Mol. Biol. 26:303-311, 1994). Gel retardation experiments in which protein extracts of Mesorhizobium loti and developing nodules were used suggested a bacterial origin for the repressor binding protein (rep2037). Nodulation tests were performed by using different Fix(-) Tn5 mutants of M. loti. Analyses of these mutants revealed a correlation between the presence of Mesorhizobium in the nodule-like structures and the ability of nodule protein extracts to bind the repressor binding domain (RBD). Through the use of mutated RBD sequences, the RBD sequence was identified as CTAAAAT. The repressor protein was isolated from M. loti NZP2037 by multiple chromatographic procedures and affinity separation by using concatemers of RBD attached to magnetic beads. Sequencing of the recovered protein resulted in identification of the repressor protein as the sarcosine oxidase alpha subunit. This was confirmed by expression of the gene encoding the M. loti alpha subunit of sarcosine oxidase in Escherichia coli. When the expressed peptide was bound to RBD, the gel retardation result was identical to the result obtained with rep2037 from M. loti strain NZP2037.

Peptide inhibitors of appressorium development in Glomerella cingulata.

The phytopathogen Glomerella cingulata (anamorph: Colletotrichum gloeosporioides) infects host tissue by means of a specialised infection structure, the appressorium. The Saccharomyces cerevisiae alpha-mating factor pheromone, the Saccharomyces kluyveri alpha-mating factor pheromone and a hendecapeptide produced by G. cingulata inhibit appressorium development. The amino acid sequence of the G. cingulata peptide, GYFSYPHGNLF, is different from that of the mature pheromone peptides of other filamentous fungi. The peptide has sequence similarity with the Saccharomyces alpha-mating factor pheromones, but is unable to elicit growth arrest in S. cerevisiae.