Strategies for selection and identification of rabbit single-chain Fv antibodies as ligand in affinity chromatography.

We developed affinity chromatographic resins that immobilized rabbit single-chain Fv antibodies (scFvs). By biopanning using antigen-coupled multilamellar vesicles (Ag-MLVs), 152 types of original scFv clones that specifically bind to human IgG were isolated and identified. Apparent dissociation rate constants, appkoff, of six different candidates were less than 10-3 s-1 and their dissociation constants, KDs, were ranged from 5.56 × 10-10 to 4.04 × 10-8 M. Consequently, the clones, R1-27, R2-18, and R3-26 were further investigated for use in affinity purification of human IgG. Both the clones, R1-27 and R3-26 maintained more than 40% of antigen-binding activities on the surface of affinity resins. Especially, R3-26 had a relatively high alkaline resistance. The direct separation of human IgG from 10% FBS-D-MEM by use of the column with R1-27 achieved 97.2% purity, while the column with R3-26 showed almost 100% recovery. The affinity resins at the densities between 4.32 and 15.19 mg-scFv/cm3 exhibited maximum binding amount of human IgG, while the highest ligand utilization was achieved by use of the resin at approximately 9 mg-scFv/cm3. The resin exhibited 7.69 mg/cm3 of equilibrium binding capacity (EBC) in affinity chromatography. It was expected that the EBC of affinity resins was strongly dependent on the specific surface area as well as the pore volume of the base resin. Therefore, the strategies to develop affinity ligands will be beneficial for development of on-demand affinity columns with higher affinity/selectivity, chemical resistance, while optimization of pore size and pore volume for scFv-coupled resins will further improve the EBC.

Dielectricity of a molecularly crowded solution accelerates NTP misincorporation during RNA-dependent RNA polymerization by T7 RNA polymerase.

In biological systems, the synthesis of nucleic acids, such as DNA and RNA, is catalyzed by enzymes in various aqueous solutions. However, substrate specificity is derived from the chemical properties of the residues, which implies that perturbations of the solution environment may cause changes in the fidelity of the reaction. Here, we investigated non-promoter-based synthesis of RNA using T7 RNA polymerase (T7 RNAP) directed by an RNA template in the presence of polyethylene glycol (PEG) of various molecular weights, which can affect polymerization fidelity by altering the solution properties. We found that the mismatch extensions of RNA propagated downstream polymerization. Furthermore, PEG promoted the polymerization of non-complementary ribonucleoside triphosphates, mainly due to the decrease in the dielectric constant of the solution. These results indicate that the mismatch extension of RNA-dependent RNA polymerization by T7 RNAP is driven by the stacking interaction of bases of the primer end and the incorporated nucleotide triphosphates (NTP) rather than base pairing between them. Thus, proteinaceous RNA polymerase may display different substrate specificity with changes in dielectricity caused by molecular crowding conditions, which can result in increased genetic diversity without proteinaceous modification.

Molecular crowding induces primer extension by RNA polymerase through base stacking beyond Watson-Crick rules.

The polymerisation of nucleic acids is essential for copying genetic information correctly to the next generations, whereas mispolymerisation could promote genetic diversity. It is possible that in the prebiotic era, polymerases might have used mispolymerisation to accelerate the diversification of genetic information. Even in the current era, polymerases of RNA viruses frequently cause mutations. In this study, primer extension under different molecular crowding conditions was measured using T7 RNA polymerase as a model for the reaction in the prebiotic world. Interestingly, molecular crowding using 20 wt% poly(ethylene glycol) 2000 preferentially promoted the primer extensions with ATP and GTP by T7 RNA polymerase, regardless of Watson-Crick base-pairing rules. This indicates that molecular crowding decreases the dielectric constants in solution, resulting in enhancement of stacking interactions between the primer and an incorporated nucleotide. These findings suggest that molecular crowding could accelerate genetic diversity in the prebiotic world and may promote transcription error of RNA viruses in the current era.

Bisubstrate Function of RNA Polymerases Triggered by Molecular Crowding Conditions.

Since the origin of life on Earth, the role of carrying genetic information has been presumably transferred from RNA to DNA. At present, cellular environments are extremely dense, packed with cosolutes and macromolecules. Hence, the preference between RNA-dependent RNA and DNA polymerization may be affected by molecular crowding. In this study, we investigated both RNA-dependent RNA and DNA polymerizations by tC9Y polymerase ribozyme, T7 RNA polymerase (T7 RNAP), and Klenow fragment DNA polymerase (KF) under different molecular crowding conditions. Poly(ethylene glycol) (PEG) of various molecular weights was used as a crowding agent and found to promote both RNA and DNA ribozyme-catalyzed polymerizations. In contrast, PEG with an average molecular weight of 200 (PEG200) reduced the level of RNA polymerization by proteinaceous T7 RNAP but simultaneously promoted DNA polymerization, without affecting the activity of KF. Thus, proteinaceous RNA polymerase might potentially display bisubstrate specificity, which can be switched in response to changes in the dielectric constant and excluded volume in crowded environments. Our findings validate the bisubstrate activity of RNA polymerase from an evolutionary perspective for the development of non-natural materials.

Enzymatic Synthesis of Cellulose Oligomer Hydrogels Composed of Crystalline Nanoribbon Networks under Macromolecular Crowding Conditions.

Macromolecular crowding, a solution state with high macromolecular concentrations, was used to promote the crystallization-driven self-assembly of enzymatically synthesized cellulose oligomers. Cellulose oligomers were synthesized via cellodextrin phosphorylase-catalyzed enzymatic reactions in the concentrated solutions of water-soluble polymers, such as dextran, poly(ethylene glycol), and poly(N-vinylpyrrolidone). The reaction mixtures were transformed into cellulose oligomer hydrogels composed of well-grown crystalline nanoribbon networks irrespective of the polymer species. This method was successfully applied in the one-pot preparation of double network hydrogels composed of the nanoribbons and physically cross-linked gelatin molecules through the simple control of reaction temperatures, demonstrating the superior mechanical properties of the composite hydrogels. Our concept that promotes the growth of self-assembled architectures under macromolecular crowding conditions demonstrates a new avenue into developing novel hydrogel materials.

Construction of proteins with molecular recognition capabilities using α3ß3 de novo protein scaffolds.

The molecular recognition ability of proteins is essential in biological systems, and therefore a considerable amount of effort has been devoted to constructing desired target-binding proteins using a variety of naturally occurring proteins as scaffolds. However, since generating a binding site in a native protein can often affect its structural properties, highly stable de novo protein scaffolds may be more amenable than the native proteins. We previously reported the generation of de novo proteins comprising three α-helices and three ß-strands (α3ß3) from a genetic library coding simplified amino acid sets. Two α3ß3 de novo proteins, vTAJ13 and vTAJ36, fold into a native-like stable and molten globule-like structures, respectively, even though the proteins have similar amino acid compositions. Here, we attempted to create binding sites for the vTAJ13 and vTAJ36 proteins to prove the utility of de novo designed artificial proteins as a molecular recognition tool. Randomization of six amino acids at two linker sites of vTAJ13 and vTAJ36 followed by biopanning generated binding proteins that recognize the target molecules, fluorescein and green fluorescent protein, with affinities of 10(-7)-10(-8) M. Of note, the selected proteins from the vTAJ13-based library tended to recognize the target molecules with high specificity, probably due to the native-like stable structure of vTAJ13. Our studies provide an example of the potential of de novo protein scaffolds, which are composed of a simplified amino acid set, to recognize a variety of target compounds.

Hydrolytic activities of crystalline cellulose nanofibers.

Cellulose is commonly believed to be inactive to organic substances; this inertness is an essential requirement for raw materials in industrial products. Here we demonstrate the contradictory but promising properties, which are the hydrolytic activities of crystalline cellulose nanofibers for the ester, monophosphate, and even amide bonds of small organic substrates under extremely mild conditions (neutral pH, moderate temperature, and atmospheric pressure). The hydrolytic activities were significantly extended to decompose the coat proteins of model viruses, followed by a drastic decrease in their infection capabilities to the host cells.

Terminal sequence importance of de novo proteins from binary-patterned library: stable artificial proteins with 11- or 12-amino acid alphabet.

Successful approaches of de novo protein design suggest a great potential to create novel structural folds and to understand natural rules of protein folding. For these purposes, smaller and simpler de novo proteins have been developed. Here, we constructed smaller proteins by removing the terminal sequences from stable de novo vTAJ proteins and compared stabilities between mutant and original proteins. vTAJ proteins were screened from an α3ß3 binary-patterned library which was designed with polar/ nonpolar periodicities of α-helix and ß-sheet. vTAJ proteins have the additional terminal sequences due to the method of constructing the genetically repeated library sequences. By removing the parts of the sequences, we successfully obtained the stable smaller de novo protein mutants with fewer amino acid alphabets than the originals. However, these mutants showed the differences on ANS binding properties and stabilities against denaturant and pH change. The terminal sequences, which were designed just as flexible linkers not as secondary structure units, sufficiently affected these physicochemical details. This study showed implications for adjusting protein stabilities by designing N- and C-terminal sequences.