Unified dimensionless transformation in enzyme kinetics: Application to mathematical analyses of ten biochemical reaction systems.

A novel general principle was proposed to transform enzyme kinetic equations into unified dimensionless forms. The principle consists of six steps. The principle was applied to ten complex biochemical reaction systems and their characteristics were mathematically analyzed. The approach has six merits.: (i) the number of parameters is reduced, (ii) the rate expressions and their progress curves become much simpler, easily understood and are analyzed globally by the newly defined dimensionless time, T, (iii) the relative magnitude of kinetic constants and of the maximum velocity involved in the rate equations are straightforwardly estimated by three type m values, (iv) mass balance and stoichiometric relationship of the dimensionless rate expressions are exactly the same format as of the actual rate expressions, (v) 2D or 3D plots of the unified dimensionless equations can be depicted without inputs of the actual experimental data of the variables and kinetic constants, and (vi) the newly defined dimensionless inactivation constant, Kiact, is useful to estimate the effect of the enzyme inactivation on the batch reactions. The principle is beneficial for the mathematical analyses of complex biochemical reactions involving two or more kinds of enzymes, for those involving two or more substrates or for those involving both.

Full-time dynamics of batch-wise enzymatic cycling system composed of two kinds of dehydrogenase mediated by NAD(P)H for mass production of chiral hydroxyl compounds.

Enzymatic cycling system (coupled dehydrogenase-catalyzed biosystem being composed of two elementary enzymatic reactions mediated by NAD(P)H + NAD(P)+) is industrially attractive for reducing prochiral carbonyl compounds to the corresponding chiral hydroxyl compounds. The reaction rate equation of the batch-wise biosystem was generally derived by ordered Bi Bi mechanism of two-substrate enzyme reaction on several reasonable assumptions. The rate equations of the batch-wise biosystem was generalized by transforming them into the dimensionless forms. The dimensionless forms were solved numerically. It was revealed that the batch-wise biosystem was generally made up of unique 3 phases, i.e., phases I, II and III. Phase I was very short transient so that the biosystem entered rapidly phase II. In phase II the consumption rate dynamically balanced with its formation rate so that the concentration of NAD(P)H was invariable with time (and hence NAD(P)+ concentration was, too). Phase III was substrate-exhausting phase, and the coenzyme concentration became finally only [NAD(P)+] or only [NAD(P)H] depending on the initial molar ratio of the prochiral carbonyl compound to the substrate of the coenzyme regeneration reaction ( [Formula: see text] ) > or <1.0. In phases I and II the numerically calculated values of state variables were very close to the analytical but approximate ones. Preferable initial conditions of the batch-wise enzymatic cycling system, i.e., the initial coenzyme species = NAD(P)+ and [Formula: see text] , were proposed. As the main assumption irreversibility of the two elemental enzymatic reactions was discussed. Validity of the proposed rate equations was mentioned.

Phosphatidylcholine protects neurons from toxic effects of amyloid ß-protein in culture.

Amyloid ß-protein (Aß) is the major component of extracellular plaques in the brains of patients with Alzheimer's disease. It has been suggested that the interaction of Aß with membrane cholesterol is essential for Aß to exert neurotoxicity; however, the effect of phospholipids, another major membrane lipid component, on Aß-induced neurotoxicity remains unclarified. Here we report the protective effect of phosphatidylcholine (PC) on primary cultured neurons against Aß1-42-induced damage. Aß1-42 caused neuronal death as demonstrated by lactose dehydrogenase (LDH) release, which was completely prevented by a pretreatment with PC in a dose-dependent manner. PC containing unsaturated long-chain acyl groups, 1,2-dioleoyl-PC (DOPC), also prevented neuronal death caused by Aß1-42. The oleic acid ethyl-ester (OAEE) partially prevented Aß1-42-induced neurotoxicity. Neurons that were pretreated with DOPC or OAEE for 24h, washed out, and exposed to Aß1-42 in the absence of either of these reagents, were still resistant to Aß1-42-induced neurotoxicity. In contrast, treatment with phosphotidylserine (PS) or docosahexaenoic acid etyl-ester (DHAEE) had no protective effect on neurons against Aß1-42-induced damage. These results suggest that the control of cellular PC content, not PS content, may prove useful in the prevention or treatment of Alzheimer's disease.

Rapid and direct compositional analysis of poly(3-hydroxybutyrate-co-3-hydroxyvalerate) in whole bacterial cells by thermally assisted hydrolysis and methylation-gas chromatography.

Thermally assisted hydrolysis and methylation-gas chromatography (THM-GC) in the presence of an organic alkali was applied to the direct analysis of copolymer composition for poly(3-hydroxybutyrate-co-3-hydroxyvalerate) [P(3HB-co-3HV)] accumulated in whole bacterial cells. Cupriavidus necator was grown on a liquid medium with different molar ratios of valeric acid (V) to glucose (G) in order to control the compositions of P(3HB-co-3HV) produced in the cells. Trace amounts (0.03 mg) of dried Cupriavidus necator cells were directly subjected to THM-GC in the presence of tetramethylammonium hydroxide (TMAH) at 400°C. The obtained chromatograms clearly showed nine characteristic peaks, attributed to the THM products from 3HB and 3HV units in the polymer chains, without any appreciable interference by the bacterial matrix components. Based on these peak intensities, the copolymer compositions were determined rapidly without using any cumbersome sample pretreatment. Moreover, the compositions thus obtained were in good agreement with those obtained by the conventional technique.

Mass production of spores of lactic acid-producing Rhizopus oryzae NBRC 5384 on agar plate.

Mass production of sporangiospores (spores) of Rhizopus oryzae NBRC 5384 (identical to NRRL 395 and ATCC 9363) on potato-dextrose-agar medium was studied aiming at starting its L(+)-lactic acid fermentation directly from spore inoculation. Various parameters including harvest time, sowed spore density, size of agar plate, height of air space, and incubation mode of plate (agar-on-bottom or agar-on-top) were studied. Ordinarily used shallow Petri dishes were found out to be unsuitable for the full growth of R. oryzae sporangiophores. In a very wide range of the sowed spore density, the smaller it was, the greater the number of the harvested spores was. It was also interesting to find out that R. oryzae grown downward vertically with a deep air space in an agar-on-top mode gave larger amount of spores than in an agar-on-bottom mode at 30°C for 7-day cultivation. Scale-up of the agar plate culture from 26.4 to 292 cm(2) was studied, resulting in the proportional relationship between the number of the harvested spores/plate and the plate area in the deep Petri dishes. The number of plates of 50 cm in diameter needed for 100 m(3) industrial submerged fermentation started directly from 2 × 10(5) spores/mL inoculum size was estimated as about 6, from which it was inferred that such a fermentation would be feasible. Designing a 50 cm plate and a method of spreading and collecting the spores were suggested. Bioprocess technological significance of the "full-scale industrial submerged fermentation started directly from spore inoculation omitting pre-culture" has been discussed.

Highly accumulative production of L(+)-lactate from glucose by crystallization fermentation with immobilized Rhizopus oryzae.

In order to produce microbiologically large amount of l(+)-lactic acid (LA) from glucose, batch and fed-batch (intermittent addition of sterilized glucose powder aseptically) cultures of Rhizopus oryzae NBRC 5384 (identical to NRRL 395 and ATCC 9363) whose mycelia were immobilized in situ within sponge-like cubic particles (3.5 mm edge long) were carried out at 37°C in a three baffled shake flask. Appropriately calculated amount of fine powdery calcium carbonate (CaCO(3)) was added initially or intermittently to control pH of the culture liquids. High accumulations of LA (145 g/L and 231 g/L, in reality 176 g/L and 280 g/L as anhydrous calcium lactate) were achieved by a batch (glucose concentration = 150 g/L) and a fed-batch cultures (the initial glucose concentration = 150 g/L and the intermittent addition of glucose equivalent to 100 g/L). In these cultures the yields and productivities of LA were, 95.0%, 1.42 g/L·h and 92.5%, 1.83 g/L·h, respectively. Existence of considerable amounts of calcium lactate (Ca(LA)(2)) as crystals in the culture broth was experimentally proved by two evidences: (i) heating up (70°C) followed by quick low centrifugal force to remove remaining CaCO(3) solids from culture broth and then cooling down (37°C) followed by incubation of the culture supernatant at 37°C to observe recrystallization of Ca(LA)(2), and (ii) the measurement of solubility of Ca(LA)(2) in the culture media. It was conceptually discussed to be able to avoid the product inhibition by means of crystallization fermentation for the high accumulation of LA by R. oryzae.

High cell-density expression system: a novel method for extracellular production of difficult-to-express proteins.

Yeast's extracellular expression provides a cost-efficient means of producing industrially useful recombinant proteins. However, depending on the protein to be expressed, the production results in a poor yield, which is occasionally accompanied with loss of the expression plasmid and hence hampered growth of the host in the inducing medium. Here we propose an alternative approach, high cell-density expression, to improve the yield of a certain range of so-called difficult-to-express proteins. In this expression system, recombinant yeast cells resting in stationary phase (OD(660)=3-4) are suspended in a small aliquot of inducing medium to form a high cell-density culture (e.g., OD(660)=15). When applied to the yeast strains harboring Lentinula edodes laccase (Lcc1 or Lcc4) expressing plasmids, the high cell-density system allowed the host cells to synthesize elevated amounts of the laccase which resulted in >1000- to 6000-fold higher yield than those synthesized in a classical growth-associated manner. The resting cells required aerobic agitation for the maximum production. The production system also worked for other foreign enzymes but not for beta-galactosidase from Aspergillus oryzae or Escherichia coli, likely suggesting an involvement of chaperons that act on a certain range of secretory proteins.

A method for reverse interactome analysis: High-resolution mapping of interdomain interaction network in Dam1 complex and its specific disorganization based on the interaction domain expression.

An experimental methodology that facilitates functional analysis of numerous protein-protein interactions, which have been found in genome-wide interactome researches, has long been awaited. We propose herein an antagonistic inhibition-based approach. The antagonizing polypeptide is generated in the course of interaction domain mapping based on yeast 2-hybrid (Y2H) screening coupled with in vitro convergence of the Y2H-selected fragments, which is performed in a formatted procedure. Using the coupled methodology, we first performed a high-resolution mapping of an interdomain interaction network within budding yeast's Dam1 complex. Dam1 complex is a kinetochore protein complex composed of 10 essential subunits including Spc34p and Spc19p. The high-resolution mapping revealed the overall network structure within the complex for the first time: Dam1 components form into two separated subnetworks on N-terminal scaffolding domains of Spc34p and Spc19p, and the coiled-coil interaction in their C-terminal domains connects the subnetworks. Secondly, we show that the domain fragments converged in the high-resolution mapping acted as potent inhibitors for the endogenous interactions when episomally overexpressed. The in vivo Dam1 interaction targeting with the fragments conferred a similar phenotype on the host cells; a critical and irreversible damage, which was accompanied with disturbed budding and chromosome mis-segregation as a result of disorganized spindle. These phenotypes were strongly related to the cellular function of the Dam1 complex. The results and approach we demonstrated herein not only shed light on the Dam1 molecular architecture but also pave the road to reverse-interactome analysis and discoveries of novel drugs that target disease-related protein-protein interactions.

SIMPLEX: single-molecule PCR-linked in vitro expression: a novel method for high-throughput construction and screening of protein libraries.

A novel strategy for construction of protein libraries called "SIMPLEX: single-molecule PCR-linked in vitro expression" is described. A pool of genes is prepared and thereafter extensively diluted to give one molecule of DNA per well. Each individual molecule is separately amplified by PCR (single-molecule PCR) yielding a one-well-one-gene PCR library. Subsequently, the PCR library is directly transformed into a protein library by means of in vitro-coupled transcription/translation in an array format. Individual proteins in the library can be screened for target functions directly without further purification. The generated protein library is compatible with various selection methods. The strategy provides high-throughput construction and screening of protein libraries, and suits automation.

Creation of novel enantioselective lipases by SIMPLEX.

The single-molecule PCR-linked in vitro expression (SIMPLEX) technology, which can directly link a single molecule of a gene to its encoding protein, has been used to engineer enantioselectivity of lipase from Burkhorderia cepacia KWI-56. A combinatorial mutation has been introduced only to four residues in the hydrophobic substrate-binding pocket of the enzyme based on a structural model of the substrate-enzyme complex. Such focused mutation library constructed by the SIMPLEX technology has been screened for an enantiomeric substrate. Some combinations of substitutions in the four positions of the lipase have been found as effective for changing the enantio-preference from the (S)-form of p-nitrophenyl-3-phenylbutyrate to the (R)-form. Here, we describe the detail procedure to construct such an exclusively in vitro protein library and a practical screening method based on enzymatic activity.

A novel strategy for generation of monoclonal antibodies from single B cells using rt-PCR technique and in vitro expression.

Monoclonal antibodies (Mabs) are important biomolecules in immunology and have widespread applications in prognosis, diagnosis, and therapeutics. Here, we describe a novel approach called single-cell RT-PCR-linked in vitro expression (SICREX), which enables the high-throughput generation and screening of Mabs. This approach entails the isolation of B cells from immunized mouse spleen or human peripheral blood using magnetic microbeads conjugated with a B-cell-selective marker, anti-CD19. The light chain (Lc) and Fd portion of heavy-chain (Hc) genes of each cell are separately amplified by RT-PCR and then combined with the sequences of a T7 promoter, a ribosome binding site (rbs), and a T7 terminator by an overlapping PCR technique. The paired full-length DNA fragments of Lc and Hc genes from single B cells are simultaneously expressed by an Escherichia coli in vitro transcription and translation system followed by an enzyme-linked immunosorbent assay to find positive fragments possessing the affinity for the antigen. From spleen cells of an immunized mouse with calcium binding protein 40, a Fab fragment with K(d) of 1.6 (+/- 0.3) x 10(-8) against the antigen was obtained. From human peripheral blood, Fab fragments against a blood group B-BSA were obtained in a similar manner. The SICREX approach is simple, rapid and versatile, allowing the high-throughput generation of naturally paired Lc and Hc with antigen-binding activity from various animal sources.

In vitro selection of DNA binding sites for transcription factor, PhaR, from Paracoccus denitrificans using genetic library on microbeads and flow cytometry.

We attempted the selection of a site for DNA binding to a transcription factor, PhaR, from Paracoccus denitrificans expressed by cell-free protein synthesis, from a random oligonucleotide library on microbeads that was constructed by the emulsion PCR technique. PhaR is a repressor protein in P. denitrificans that binds to the phaP promoter region. We acquired three types of PhaR-binding DNA fragment using this system. The selected fragments contained a perfect PhaR binding consensus site (TGC I), a sequence similar to that of TGC I, and another PhaR binding site (TGC II).

PCR amplification from single DNA molecules on magnetic beads in emulsion: application for high-throughput screening of transcription factor targets.

We have developed a novel method of genetic library construction on magnetic microbeads based on solid-phase single-molecule PCR in a fine and robust water-phase compartment formed in water-in-oil (w/o) emulsions. In this method, critically diluted DNA fragments were distributed over the emulsion as templates, where beads crosslinked with multiple primers and other PCR components were encapsulated to form multiple reaction compartments. The delivered DNA was then amplified and covalently immobilized on the beads in parallel, within individual compartments, to construct a genetic library on beads (GLOBE), which was readily applicable to a genomewide global scanning of genetic elements recognized by a defined DNA-binding protein. We constructed a GLOBE of Paracoccus denitrificans and selected gene beads that were bound to the His-tagged transcription factor PhaR by flow cytometry. As a result of flow cytometry screening with an anti-His fluorescent antibody, the PhaR target fragments were enriched 1200-fold from this library with this system. Therefore, this system is a powerful tool for analyzing the transcription network on a genomewide scale.

Improvements in the cell-free production of functional antibodies using cell extract from protease-deficient Escherichia coli mutant.

Expression of a functional antibody fragment (Fab) using an Escherichia coli cell-free expression system has been reported previously [Jiang et al., FEBS Lett., 514, 290-294 (2002)]. The low yield of the synthesized antibody, however, limits the usefulness of the cell-free expression system, partly due to the degradation of product by endogenous proteases from the E. coli extract. To determine which proteases are responsible for the degradation, we compared the expression of a 6D9 Fab fragment under conditions whereby several protease inhibitors were added into the cell-free system. The addition of serine protease inhibitor increased the amount of the Fab fragment, indicating that serine proteases caused the antibody degradation. Therefore, several serine protease-deficient mutants of E. coli BW25113 were constructed by targeted homologous recombination. The use of extract from a double protease-deficient mutant (DeltadegP-ompT) significantly increased the amount and antigen-binding activities of an anti-HSA scFv and a 6D9 Fab fragment. These results suggest that the DegP- and OmpT-deleted mutant is a useful source of S30 extract for the production or screening of antibodies using the cell-free expression system.

Novel strategy for protein exploration: high-throughput screening assisted with fuzzy neural network.

To engineer proteins with desirable characteristics from a naturally occurring protein, high-throughput screening (HTS) combined with directed evolutional approach is the essential technology. However, most HTS techniques are simple positive screenings. The information obtained from the positive candidates is used only as results but rarely as clues for understanding the structural rules, which may explain the protein activity. In here, we have attempted to establish a novel strategy for exploring functional proteins associated with computational analysis. As a model case, we explored lipases with inverted enantioselectivity for a substrate p-nitrophenyl 3-phenylbutyrate from the wild-type lipase of Burkhorderia cepacia KWI-56, which is originally selective for (S)-configuration of the substrate. Data from our previous work on (R)-enantioselective lipase screening were applied to fuzzy neural network (FNN), bioinformatic algorithm, to extract guidelines for screening and engineering processes to be followed. FNN has an advantageous feature of extracting hidden rules that lie between sequences of variants and their enzyme activity to gain high prediction accuracy. Without any prior knowledge, FNN predicted a rule indicating that "size at position L167," among four positions (L17, F119, L167, and L266) in the substrate binding core region, is the most influential factor for obtaining lipase with inverted (R)-enantioselectivity. Based on the guidelines obtained, newly engineered novel variants, which were not found in the actual screening, were experimentally proven to gain high (R)-enantioselectivity by engineering the size at position L167. We also designed and assayed two novel variants, namely FIGV (L17F, F119I, L167G, and L266V) and FFGI (L17F, L167G, and L266I), which were compatible with the guideline obtained from FNN analysis, and confirmed that these designed lipases could acquire high inverted enantioselectivity. The results have shown that with the aid of bioinformatic analysis, high-throughput screening can expand its potential for exploring vast combinatorial sequence spaces of proteins.

Enhanced cell-free protein synthesis using a S30 extract from Escherichia coli grown rapidly at 42 degrees C in an amino acid enriched medium.

Growths of Escherichia coli strain A19 were investigated in a 5-L fermentor at 37 and 42 degrees C either in Pratt's medium (a standard medium for cell-free protein synthesis using its S30 extract) or in a casamino acids supplemented Pratt's medium (aa-enriched medium). Specific growth rates in Pratt's medium at 37 and 42 degrees C were 0.77 and 0.46 h(-1), respectively, whereas those in the aa-enriched medium at 37 and 42 degrees C were 0.87 and 1.49 h(-1), respectively. The extent of cell-free chloramphenicol acetyltransferase (CAT) synthesis was compared at 37 degrees C incubation (from a plasmid pK7-CAT) for S30 extracts prepared from the cells cultured in the aa-enriched medium at 37 or 42 degrees C. A 40% increase in CAT synthesis occurred when the 42 degrees C/S30 extract was used as compared with 37 degrees C/S30 extract. CAT and both the light and heavy chains (Lc and Hc) of the Fab fragment of an antibody 6D9 were synthesized at 37 degrees C in the cell-free synthesis in the presence of [(14)C]Leu. Their reaction mixtures were subjected to SDS-PAGE autoradiographic analysis. It was found that most of the synthesized proteins were in the soluble fraction when 42 degrees C/S30 extract was used, suggesting that the 42 degrees C/S30 extract contained greater amounts of various protein folding factors. A dialysis membrane minibioreactor with a reaction volume ca. 0.5 mL was handmade by the authors. The advantages of the minibioreactor are a simple configuration, a low manufacturing cost, and the capability of the dialysis membrane replacement. Increased CAT synthesis was also observed for continuous exchange cell-free (CECF) protein synthesis at 37 degrees C when the 42 degrees C/S30 extract was used in the minibioreactor. Some plausible reasons to give higher protein synthesis activity of the 42 degrees C/S30 extract are discussed.

Direct separation of regio- and enantiomeric isomers of diacylglycerols by a tandem column high-performance liquid chromatography.

A novel HPLC-based method for direct separation of the three isomers of mono-acid diacylglycerols (DAGs), i.e., 1,2-DAG, 2,3-DAG and 1,3-DAG, has been established. The method employs a tandem column system, in which two different columns (a conventional silica gel column and a chiral stationary phase column) are connected in series. Two isomeric mixtures of DAGs (i.e., dicapryloylglycerol and dioleoylglycerol) and lipase-catalyzed reaction mixtures were successfully resolved on the tandem column HPLC system without any derivatization prior to the analysis. According to the established analytical method, stereoselectivity of two lipases toward mono-acid triacylglycerols in ethanolysis reaction was investigated. The tested enzymes were immobilized Candida antarctica lipase B (CALB) and Rhizomucor miehei lipase (RML). Analyses of the enantiomeric purity of 1,2-DAG and 2,3-DAG, generated as intermediates during the reaction, revealed that CALB and RML have sn-3 and sn-1 stereopreference, respectively.

A picoliter chamber array for cell-free protein synthesis.

The completion of human genome sequencing has shifted the focus of research from genes to proteins. In this regard, a protein library chip has become a useful tool for cell-free protein synthesis. In this study, we attempted to make a highly-integrated protein chip from a DNA library using in vitro protein synthesis on a microchamber array fabricated by using PDMS (polydimethyl siloxane), a hydrophobic surface, and glass, a hydrophilic bottom substrate. These structural properties prevented cross-contamination among the chambers. The minimum volume capacity of the smallest chamber was about 1 pl. The total number of chambers per chip was 10,000 on one chip (capacity 150 pl) and 250,000 on two others (1 and 5 pl). Next, we attempted in vitro protein synthesis using this microchamber array. The fluorescence of Green Fluorescent Protein (GFP) expressed on the chamber was rapidly detected (within just 1 h). GFP expression was also successful using immobilized DNA molecules on polymer beads. DNA immobilized beads were added as the source to each microchamber. Protein was successfully synthesized from DNA immobilized beads, which allowed easy handling of the DNA molecules.

Cell-free protein synthesis systems: increasing their performance and applications.

The Escherichia coli cell-free protein synthesis system can now be used for various proteins that need special requirements, such as disulfide bond formation between intra- and inter-molecules, hetero-dimerization, and specific chaperons. In addition, a novel protein library construction method termed "SIMPLEX" has been developed. Some applications with SIMPLEX are described. A highly efficient eukaryotic cell-free translation system using wheat germ extract has also been developed. An advanced framework for a rapid eukaryotic gene expression and analysis is shown.

Enzymatic synthesis of structured lipids.

Structured lipids (SLs) are defined as lipids that are modified chemically or enzymatically in order to change their structure. This review deals with structured triacylglycerols (STGs) and structured phospholipids (SPLs). The most typical STGs are MLM-type STGs, having medium chain fatty acids (FAs) at the 1- and 3-positions and a long chain fatty acid at the 2- position. MLM-type STGs are synthesized by: 1) 1,3-position-specific lipase-catalyzed acyl exchange of TG with FA or with FA ethylester (FAEt); 2) 1,3-position-specific lipase-catalyzed acylation of glycerol with FA, giving symmetric 1,3-diacyl-sn-glycerol, followed by chemical acylation at the sn-2 position, and; 3) 1,3-position-specific lipase-catalyzed deacylation of TG, giving 2-monoacylglycerol, followed by reacylation at the 1- and 3-positions with FA or with (FAEt). Enzymatic preparation of SPLs requires: 1) acyl group modification, and 2) head group modification of phospholipids. Acyl group modification is performed using lipases or phospholipase A2-mediated transesterification or ester synthesis to introduce arbitrary fatty acid to phospholipids. Head group modification is carried out by phospholipase D-catalyzed transphosphatidylation. A wide range of compounds can be introduced into the polar head of phospholipids, making it possible to prepare various SPLs.