Comparison of recombinant Culicoides allergens produced in different expression systems for IgE serology of insect bite hypersensitivity in horses of different origins.

Insect bite hypersensitivity (IBH) is an allergic dermatitis of horses, an IgE-mediated reaction to Culicoides midges. Causative Culicoides spp. are not indigenous in Iceland resulting in high prevalence of IBH in horses born in Iceland and exported as compared to Icelandic horses born in a Culicoides rich environment. The aims were (i) to compare IgE levels in sera of IBH-affected horses born in Iceland (n = 47) with horses of the Icelandic breed (n = 23) and of other breeds (n = 27) born in Culicoides infested area; (ii) to investigate if barley could be a useful production system of allergens for IBH immunoassays. IgE binding in sera was tested by ELISA on two recombinant Culicoides allergens, rCul n 3 and rCul n 4, each produced in E. coli, insect cells and barley. Significantly more IgE was detected against all allergens in sera from IBH-affected compared to healthy horses. Icelandic-born Icelandic horses stand out with higher IgE levels against the allergens and higher area under the curve (AUC) on rCul n 4 as compared to the European-born horses. The barley and E.coli produced allergens had very similar performance in distinguishing between IBH-affected and healthy horses.

Barley produced Culicoides allergens are suitable for monitoring the immune response of horses immunized with E. coli expressed allergens.

Insect bite hypersensitivity is an allergic dermatitis of horses caused by bites of Culicoides midges. Sufficient amount of pure, endotoxin-free allergens is a prerequisite for development and monitoring of preventive and therapeutic allergen immunotherapy. Aims of the study were to compare the Culicoides nubeculosus (Cul n) allergens Cul n 3 and Cul n 4, produced in transgenic barley grains with the corresponding E. coli or insect cells expressed proteins for measuring antibody and cytokine responses. Allergen-specific IgG responses were measured by ELISA in sera from twelve horses not exposed to Culicoides, before and after vaccination with E. coli-rCul n 3 and 4. Before vaccination no IgG binding to the barley and insect cell produced proteins was detected and a similar increase in specific IgG was observed after vaccination. While IgG levels to the E.coli expressed proteins were higher in the post-vaccination sera, some background binding was observed pre-vaccination. In vitro re-stimulation of PBMC was performed for measurements of cytokines. E. coli expressed proteins resulted in high background in PBMC from non-vaccinated controls. The barley and insect cell expressed proteins induced similar amount of IFN-γ and IL-4 in PBMC from vaccinated horses. Barley produced allergens are promising tools for use in immunoassays.

A novel quasi-species of glutathione transferase with high activity towards naturally occurring isothiocyanates evolves from promiscuous low-activity variants.

Glutathione transferases (GSTs) are known as promiscuous enzymes capable of catalyzing the conjugation of glutathione with a broad range of electrophilic substrates. A previous study based on recombinant chimeras derived from human GST M1-1 and GST M2-2 demonstrated the formation of a subset of F1 generation GSTs, which had lost high activity with substrates distinguishing parental enzymes. In the present study, the members of this subset were recombined by DNA shuffling to produce an F2 generation of GSTs. Screening of 930 bacterial clones demonstrated that 83% of recombinant enzyme variants were active with at least one of three alternative substrates: phenethyl isothiocyanate (PEITC), 1-chloro-2,4-dinitrobenzene, or p-nitrophenyl acetate. The majority had similar low activity as the parental GSTs in the F1 generation. However, 17 novel enzymes displayed high activity with PEITC. Half of these enzymes were similar to GST M1-1, which also has high activity with the same substrate, and all of these GSTs featured Tyr116/Ser210 in the active site. This group of F2 variants apparently had reverted to the GST M1-1 type. A second group of F2 variants with high PEITC activity was characterized by His116 in the active site. This category represented a new variety of GSTs, which demonstrated higher selectivity for isothiocyanate substrates than the GST M1-1 type. The different groups of GSTs can be considered as distinct molecular quasi-species, each of which comprises variant amino acid sequences. The quasi-species are structurally distinguished by active-site residues that govern their substrate selectivities. Clearly, minimal alterations of the active site can generate enzymes with highly distinctive functional properties.

The quest for molecular quasi-species in ligand-activity space and its application to directed enzyme evolution.

We propose that the proper evolving unit in enzyme evolution is not a single "fittest molecule", but a cluster of related variants denoted a "quasi-species". A distribution of variants provides genetic variability and thereby reduces the risk of inbreeding and evolutionary dead-ends. Different matrices of substrates or activity modulators will lead to different selection criteria and divergent evolutionary trajectories. We provide examples from our directed evolution of glutathione transferases illustrating the interplay between libraries of enzyme variants and ligand matrices in the identification of quasi-species. The ligand matrix is shown to be crucial to the outcome of the search for novel activities. In this sense the experimental system resembles the biological environment in governing the evolution of enzymes.

Multi-substrate-activity space and quasi-species in enzyme evolution: Ohno's dilemma, promiscuity and functional orthogonality.

A functional enzyme displays activity with at least one substrate and can be represented by a vector in substrate-activity space. Many enzymes, including GSTs (glutathione transferases), are promiscuous in the sense that they act on alternative substrates, and the corresponding vectors operate in multidimensional space. The direction of the vector is governed by the relative activities of the diverse substrates. Stochastic mutations of already existing enzymes generate populations of variants, and clusters of functionally similar mutants can serve as parents for subsequent generations of enzymes. The proper evolving unit is a functional quasi-species, which may not be identical with the 'best' variant in its generation. The manifestation of the quasi-species is dependent on the substrate matrix used to explore catalytic activities. Multivariate analysis is an approach to identifying quasi-species and to investigate evolutionary trajectories in the directed evolution of enzymes for novel functions.

Multivariate-activity mining for molecular quasi-species in a glutathione transferase mutant library.

A library of recombinant glutathione transferases (GSTs) generated by shuffling of DNA encoding human GST M1-1 and GST M2-2 was screened with eight alternative substrates, and the activities were subjected to multivariate analysis. Assays were made in lysates of bacteria in which the GST variants had been expressed. The primary data showed clustering of the activities in eight-dimensional substrate-activity space. For an incisive analysis, the rows of the data matrix, corresponding to the different enzyme variants, were individually scaled to unit length, thus accounting for different expression levels of the enzymes. The columns representing the activities with alternative substrates were subsequently individually normalized to unit variance and a zero mean. By this standardization, the data were adjusted to comparable orders of magnitude. Three molecular quasi-species were recognized by multivariate K-means and principal component analyses. Two of them encompassed the parental GST M1-1 and GST M2-2. A third one diverged functionally by displaying enhanced activities with some substrates and suppressed activities with signature substrates for GST M1-1 and GST M2-2. A fourth cluster contained mutants with impaired functions and was not regarded as a quasi-species. Sequence analysis of representatives of the mutant clusters demonstrated that the majority of the variants in the diverging novel quasi-species were structurally similar to the M1-like GSTs, but distinguished themselves from GST M1-1 by a Ser to Thr substitution in the active site. The data show that multivariate analysis of functional profiles can identify small structural changes influencing the evolution of enzymes with novel substrate-activity profiles.

Functionally diverging molecular quasi-species evolve by crossing two enzymes.

Molecular evolution is frequently portrayed by structural relationships, but delineation of separate functional species is more elusive. We have generated enzyme variants by stochastic recombinations of DNA encoding two homologous detoxication enzymes, human glutathione transferases M1-1 and M2-2, and explored their catalytic versatilities. Sampled mutants were screened for activities with eight alternative substrates, and the activity fingerprints were subjected to principal component analysis. This phenotype characterization clearly identified at least three distributions of substrate selectivity, where one was orthogonal to those of the parent-like distributions. This approach to evolutionary data mining serves to identify emerging molecular quasi-species and indicates potential trajectories available for further protein evolution.