Takao Imaeda

High-throughput, cloning-independent protein library construction by combining single-molecule DNA amplification with in vitro expression.

A novel, cloning-independent strategy for construction of protein libraries has been developed and demonstrated experimentally. A pool of genes is prepared and thereafter extensively diluted to give one molecule of DNA per well. Each individual molecule is amplified separately by polymerase chain reaction (single-molecule PCR) yielding a PCR library. Subsequently, the PCR library is directly transformed into a protein library by means of in vitro coupled transcription/translation. Amounts of DNA produced by the single-molecule PCR were equal and uniformity of amounts of successively in vitro synthesized proteins, which were critical for quantitative comparison among clones in the library, was better than that of the classical in vivo expression system. Here, we describe a library of anti-human serum albumin single-chain antibodies (anti-HSA-scFv) originating from a monoclonal anti-HSA-scFv which was constructed and screened in order to demonstrate its real practicability. Application of the strategy described for high-throughput generation and screening of protein libraries is discussed.

Transgenic sweet potato expressing thionin from barley gives resistance to black rot disease caused by Ceratocystis fimbriata in leaves and storage roots

Black rot of sweet potato caused by pathogenic fungus Ceratocystis fimbriata severely deteriorates both growth of plants and post-harvest storage. Antimicrobial peptides from various organisms have broad range activities of killing bacteria, mycobacteria, and fungi. Plant thionin peptide exhibited anti-fungal activity against C. fimbriata. A gene for barley α-hordothionin (αHT) was placed downstream of a strong constitutive promoter of E12Ω or the promoter of a sweet potato gene for β-amylase of storage roots, and introduced into sweet potato commercial cultivar Kokei No. 14. Transgenic E12Ω:αHT plants showed high-level expression of αHT mRNA in both leaves and storage roots. Transgenic β-Amy:αHT plants showed sucrose-inducible expression of αHT mRNA in leaves, in addition to expression in storage roots. Leaves of E12Ω:αHT plants exhibited reduced yellowing upon infection by C. fimbriata compared to leaves of non-transgenic Kokei No. 14, although the level of resistance was weaker than resistance cultivar Tamayutaka. Storage roots of both E12Ω:αHT and β-Amy:αHT plants exhibited reduced lesion areas around the site inoculated with C. fimbriata spores compared to Kokei No. 14, and some of the transgenic lines showed resistance level similar to Tamayutaka. Growth of plants and production of storage roots of these transgenic plants were not significantly different from non-transgenic plants. These results highlight the usefulness of transgenic sweet potato expressing antimicrobial peptide to reduce damages of sweet potato from the black rot disease and to reduce the use of agricultural chemicals.

Identification of genes that enhance cellulase protein production in yeast.

In order to enhance heterologous cellulase protein production in yeast, a plasmid harboring the endoglucanase gene from Clostridium thermocellum (Ctcel8A) was used to systematically transform a homozygous diploid yeast deletion strain collection. We identified 55 deletion strains that exhibited enhanced endoglucanase activity compared with that of the wild-type strain. Genes disrupted in these strains were classified into the categories of transcription, translation, phospholipid synthesis, endosome/vacuole function, ER/Golgi function, nitrogen starvation response, and cytoskeleton. The vps3Δ and vps16Δ strains, which have deletion in genes encoding components of the class C core vacuole/endosome tethering (CORVET) complex, also exhibited enhanced β-glucosidase activity when Ctcel8A was heterologously expressed. Moreover, multiple gene deletion strains were constructed by using the vps3Δ strain. Endoglucanase activity of the resulting rav1Δvps3Δ double deletion strain was exhibited higher than that of the rav1Δ or vps3Δ strains. Our genome-wide analyses using the yeast deletion strain collection identified useful genes that allow efficient expression of cellulase.

Deglycosylation of cellulosomal enzyme enhances cellulosome assembly in Saccharomyces cerevisiae

We have estimated the effects of hyper-mannosylation of dockerin-type cellulase on cellulosome assembly by using Saccharomyces cerevisiae and 44 protein glycosylation mutants, because the heterologous protein displayed on yeast is assumed to be modified by yeast-specific hyper-mannosylation. First, we constructed the yeast strain CtminiCipA, which displays a heterologous scaffolding protein (miniCipA from Clostridium thermocellum) on its cell surface, and glycosylation mutants secreting a dockerin-type cellulase (Cel8Aenz-Cel48Sdoc: a fusion protein of the catalytic domain of C. thermocellum Cel8A and the dockerin domain of C. thermocellum Cel48S). Next, minicellulosomes were assembled by mixing the CtminiCipA strain and the dockerin-type cellulase secreted by each glycosylation mutant. By using an endoglucanase assay and flow cytometric analysis, we showed that some glycosylation mutants enhanced cellulosome assembly; in particular, disruption of glycosylation genes located in the endoplasmic reticulum showed intense enhancement. These findings suggest that inhibition of the core complex or precursor formation in protein glycosylation enhances cellulosome assembly, meaning that absence of glycosylation is more important for cellulosome assembly than reducing the size of the glycochain.