The kinetics of pancreatic ribonuclease reaction with alkaline and acidic forms of poly A

Summary The RNase hydrolysis of random-coil (alkaline form) poly A follows biphasic kinetics at low salt concentrations. However, its resistance to RNase increases with the ionic strength. Helical (acidic form) poly A is also susceptible to RNase but its hydrolysis follows first-order kinetics, and its resistance increases as the pH is lowered. These conformation-dependent kinetics of poly A hydrolysis are similar to those obtained in the hydrolysis of cellular RNA and reovirus double-stranded RNA.     

Partial Hydrolysis of Poly(2-ethyl-2-oxazoline) and Potential Implications for Biomedical Applications?

The hydrolysis of PEtOx is studied to evaluate the potential toxicity of partially hydrolyzed polymers that might interfere with its increasing popularity for biomedical applications. The hydrolysis of PEtOx is studied in the presence of digestive enzymes (gastric and intestinal) and at 5.8?M hydrochloric acid as a function of temperature (57, 73, 90, and 100?°C). It is found that PEtOx undergoes negligible hydrolysis at 37?°C and that thermal and solution properties are not altered when up to 10% of the polymer backbone is hydrolyzed. Mucosal irritation and cytotoxicity is also absent up to 10% hydrolysis levels. In conclusion, PEtOx will not decompose at physiological conditions, and partial hydrolysis will not limit its biomedical applications.     

On the structure and biological properties of decarbamoylsaxitoxin

The acid hydrolysis product of saxitoxin is shown to be decarbamoylsaxitoxin by spectral characterization and its reconversion to saxitoxin by carbamoylation. Natural and resynthesized saxitoxin are identical in chromatographic and spectral properties and in their potencies in blocking the sodium channel in squid giant axon. The hydrolysis product, decarbamoylsaxitoxin, exhibits 20% of the potency of saxitoxin in the squid axon system. These results confirm the structure of the hydrolysis product and its biological activity relative to saxitoxin.     

Comparison of Hydrolysis Efficiency and Enzyme Adsorption of Three Different Cellulosic Materials in the Presence of Poly(ethylene Glycol)

The addition of non-ionic surfactants has recently been confirmed to positively affect the enzymatic hydrolysis of cellulosic materials. However, the functional mechanisms of these surfactants remain unclear. This work investigated the influence of poly(ethylene glycol) (PEG) on the enzymatic hydrolysis of three cellulosic materials, namely, acid steam-exploded corn straw, pure microcrystalline cellulose (Avicel PH101), and bagasse sulfite pulp (BSP). The results showed that PEG addition led to varied effects on the enzymatic hydrolysis of different cellulosic materials. Addition of PEG was most effective on the enzymatic hydrolysis of PH101 and weakly effective on the hydrolysis of BSP. We further investigated PEG concentrations and enzymatic activities in the supernatant during hydrolysis and found that the positive effects of PEG treatment might contribute to its influence on enzyme desorption from different substrates. We also found that the efficiency of PEG depended on its capacity to bind to different substrates. PEG exhibited stronger affinity to pure cellulose than to the two other lignocellulosic substrates. These findings are helpful in further revealing the mechanism of surfactants and improving the enzymatic hydrolysis process.     

Fluorometric method for estimating the kinetic parameters of beta-naphthyl triphosphate and ATP hydrolysis by acto-heavy meromyosin

We have established a method to estimate the values of various kinetic parameters of acto-heavy meromyosin (acto-HMM) ATPase, using a fluorescent ATP analog, beta-naphthyl triphosphate (beta-NapP3); from the fluorescence intensity change accompanying beta-NapP3 hydrolysis, the various kinetic parameters of beta-NapP3 hydrolysis, including its product inhibition, were obtained. beta-NapPd3 hydrolysis is inhibited competitively by ATP, resulting in different time courses of fluorescence intensity change in the presence and absence of ATP. From this difference, the values of kinetic parameters of ATP hydrolysis, including its product inhibition, can be estimated. By extending this method to the acto-HMM system, seventeen parameters in a reaction scheme for the concurrent hydrolysis of ATP and beta-NapP3, including association constants between F-actin and substrate-free or substrate-bound HMM, were obtained. The kinetic-parameters estimated for ATP hjydrolsis were in good agreement with those in the literature.     

Lactate inhibits hydrolysis of polysaccharide-rich particulate organic waste

This work reveals that, at pH 5-9, a lactate level of up to 30 g l(-1) retarded hydrolysis rates in polysaccharide-rich potato samples. Lactate substantially limited carbohydrate hydrolysis and enhanced the hydrolysis of proteins. Statistical analysis identified the significance of numerous process factors in substrate hydrolysis. At fixed pH, dissociated lactate affected hydrolysis rates more strongly than its molecular counterpart. At a fixed lactate level, an alkaline environment favors carbohydrate hydrolysis; the effect of pH is secondary. Significant effects of lactate on substrate hydrolysis may be evident in fermenting organic substrates with high carbohydrate content.     

Metabolic stability of the LHRH antagonist antide to cell-surface peptidases

The susceptibility to hydrolysis of LHRH and the decapeptide analogue Antide has been compared. The hydrolysis of LHRH by pig kidney brush border membranes is inhibited by phosphoramidon (I50 = 5.6 nM) implicating endopeptidase-24.11 in the initiation of hydrolysis. Under conditions in which LHRH is fully degraded by brush border membranes, Antide was completely resistant to hydrolysis. Similar results were obtained with purified preparations of both endopeptidase-24.11 and angiotensin converting enzyme. These data confirm that the remarkable duration of action of Antide is due principally to its stability to hydrolysis by cell-surface peptidases.     

Process development of starch hydrolysis using mixing characteristics of Taylor vortices

In food industries, enzymatic starch hydrolysis is an important process that consists of two steps: gelatinization and saccharification. One of the major difficulties in designing the starch hydrolysis process is the sharp change in its rheological properties. In this study, Taylor–Couette flow reactor was applied to continuous starch hydrolysis process. The concentration of reducing sugar produced via enzymatic hydrolysis was evaluated by varying operational variables: rotational speed of the inner cylinder, axial velocity (reaction time), amount of enzyme, and initial starch content in the slurry. When Taylor vortices were formed in the annular space, efficient hydrolysis occurred because Taylor vortices improved the mixing of gelatinized starch with enzyme. Furthermore, a modified inner cylinder was proposed, and its mixing performance was numerically investigated. The modified inner cylinder showed higher potential for enhanced mixing of gelatinized starch and the enzyme than the conventional cylinder.     

Hydrolysis of carnosine and related compounds by mammalian carnosinases

Comparative study of hydrolysis of carnosine and a number of its natural derivatives by human serum and rat kidney carnosinase was carried out. The rate of carnosine hydrolysis was 3–4-fold higher then for anserine and ophidine. The rate of homocarnosine, N-acetylcarnosine and carcinine hydrolysis was negligible by either of the enzymes used. Our data show that methylation, decarboxylation or acetylation of carnosine increases resistance of the molecule toward enzymatic hydrolysis. Thus, metabolic modification of carnosine may increase its half-life in the tissues.     

Manometric and spectrophotometric procedures for measurement of procaine hydrolysis by mouse liver in vitro

A decrease in absorbance at 313 nm was used to determine procaine hydrolysis by mouse liver. Results suggested that procaine hydrolysis was not linearly dependent upon the amount of tissue added to the incubate. This resulted from the fact that p-aminobenzoic acid, one of procaine's hydrolysis products, also absorbed at 313 nm. A dual wavelength analysis procedure is described which permitted accurate measurement of procaine hydrolysis by mouse liver without physical separation of procaine from its hydrolysis products. Measurements by the dual wavelength and manometric methods of inhibition of procaine hydrolysis in livers from mice treated with triorthotolyl phosphate indicated that both methods yielded quantitatively comparable results. The dual wavelength procedure is recommended for future studies of procaine hydrolysis by mammalian tissues.     

Production of xylobiose from the autohydrolysis explosion liquor of corncob using Thermotoga maritima xylanase B (XynB) immobilized on nickel-chelated Eupergit C

In this study, a thermostable recombinant xylanase B (XynB) from Thermotoga maritima MSB8 was immobilized on nickel-chelated Eupergit C 250L. This immobilized XynB was then used to hydrolyze the autohydrolysis explosion liquor of corncob (AELC) in a packed-bed enzyme reactor for continuous production of xylooligosaccharides, especially xylobiose. When tested in batch hydrolysis of AELC, the immobilized XynB still retained its relative activity of 92.5% after 10 cycles of hydrolysis at 90 degrees C. The immobilized XynB retained 83.6% of its initial hydrolysis activity even after 168 h of hydrolysis reaction at 90 degrees C and demonstrated a half-life time of 577.6 h (24 days) for continuous hydrolysis. HPLC showed that xylobiose (49.8%) and xylose (22.6%) were the main hydrolysis products yielded during continuous hydrolysis. Xylobiose was adsorbed on an activated charcoal column and eluted with a linear gradient of 15% (v/v) ethanol to yield xylobiose with 84.7% of recovery. Also, the purity of xylobiose was up to 97.2% as determined by HPLC. Therefore, the immobilized XynB was suitable for the efficient production of xylobiose from AELC. This is the first report on the immobilization of xylanase for xylobiose production.     

微生物酶催化腈水解反应的研究进展

腈的酶法水解不仅反应条件温各,而且高效性、高选择性,在光学活性羧酸及其衍生物的合成中具有巨大的应用潜力。综述了催化腈水解的酶类、反应类型、反应特性、影响反应的因素及其在工业上的应用前景。     

Fungal and other β-d-glucosidases — Their properties and applications

β-d-Glucosidase (β-d-glucoside glucohydrolase, EC 3.2.1.21) has been described in a variety of fungi and bacteria. Its function — to catalyse the hydrolysis of cellobiose, and aryl and alkyl β-d-glucosides — depends upon the nature of its source. Recent interest in this enzyme centres on its role in the enzymatic hydrolysis of cellulose. The rate and extent of cellulose hydrolysis can be increased by supplementing commercial cellulases with immobilized β-d-glucosidase, which has high stability and can be recovered and reused. The current state of β-d-glucosidase biotechnology is described.     

A quantitative assessment of the importance of barley seed alpha-amylase, beta-amylase, debranching enzyme, and alpha-glucosidase in starch degradation.

Extracts of germinated barley (Hordeum vulgare L.) seeds of 41 different genotypes were analyzed for their activities of alpha-amylase, beta-amylase, alpha-glucosidase, and debranching enzyme and for their abilities to hydrolyze boiled soluble starch, nonboiled soluble starch, and starch granules extracted from barley seeds with water. Linear correlation analysis, used to quantitate the interactions between the seven parameters, revealed that boiled soluble starch was not a good substrate for predicting activities of enzymes functioning in in vivo starch hydrolysis as the extracts' abilities to hydrolyze boiled soluble starch was not correlated with their abilities to hydrolyze native starch granules. Activities of alpha-amylase and alpha-glucosidase were positively and significantly correlated with the seed extracts' abilities to hydrolyze all three starches. beta-Amylase was only significantly correlated with hydrolysis of boiled soluble starch. No significant correlations existed between debranching enzyme activity and hydrolysis of any of the three starches. Interactions between the four enzymes as they functioned together to hydrolyze the three types of starch were evaluated by path coefficient analysis. alpha-Amylase contributed to hydrolyses of all three starches primarily by its direct effect (noninteractive component). This direct contribution increased as the substrate progressed from the completely artificial boiled soluble starch, to the most physiologically significant substrate, native starch granules. alpha-Glucosidase contributed to the hydrolysis of boiled soluble starch primarily by its direct effect (noninteractive) yet contributed to starch granule hydrolysis primarily via its interaction with alpha-amylase (indirect effect). The contribution of beta-amylase to hydrolysis of boiled soluble starch was direct and it did not contribute significantly to hydrolysis of native starch granules.     

表面活性剂对木质纤维素酶解产糖的影响研究进展

木质纤维素是生产生物燃料乙醇的主要原料,其含量丰富、绿色环保以及可再生性,因此有效地利用木质纤维素有望解决能源短缺问题。表面活性剂能够有效地促进木质纤维素的酶解反应,通过探讨不同表面活性剂对酶解反应的影响及机理,为实际的酶解过程找到合适表面活性剂提供一定的理论指导。     

Modeling of countercurrent shrinking-bed reactor in dilute-acid total-hydrolysis of lignocellulosic biomass

A mathematical model was developed for a countercurrent shrinking-bed reactor to investigate its performance in dilute-acid pretreatment/hydrolysis of lignocellulosic biomass. The results indicate that bed shrinking provides a positive effect on both hemicellulose and cellulose hydrolysis resulting high yield and product concentration. The effect of bed shrinking is more profound on cellulose hydrolysis than on hemicellulose hydrolysis. With dilute sulfuric acid (0.08 wt%) and with optimal adjustment of other operating parameters, the model predicts that near quantitative recovery of hemicellulose sugars is feasible. It further predicts that 80–90% yield with 2–4 wt% product concentration is attainable from hydrolysis of hardwood cellulose. The model also indicates that acid concentration and temperatures acutely affect the reactor performance in cellulose hydrolysis. In contrast, hemicellulose hydrolysis is less sensitive to acid concentration and temperature allowing broader latitude in operating conditions.     

Role of enzymes and inhibitors in leu-enkephalin metabolism in rabbit and human plasma

The hydrolysis of leucine enkephalin by the proteolytic enzymes present in human and rabbit plasma has been studied by kinetic and chromatographic techniques. Data obtained indicate the existence of noticeable intraspecific differences in the kinetics of leu-enkephalin degradation, and of formation of its hydrolysis by-products. The separation of the enzymes active on the substrate and of the inhibitors active on these enzymes evidences the existence of a species specific distribution of both groups of substances. Yet, the dissimilar kinetics of the substrate hydrolysis and of formation of its hydrolysis by-products appear to arise more from diversities in the competition between the enzymes present in plasma and in the role of inhibitors than from the differences in the enkephalin-degrading enzymes. It is suggested that differences observed may be related to the existence of species specific populations of the information-carrying plasma peptides.     

Formation of oligosaccharides during enzymatic lactose hydrolysis and their importance in a whey hydrolysis process: Part II: Experimental

Enzymatic lactose hydrolysis using two yeast and two fungal lactases that are of current technical interest was studied. The enzymes were compared regarding their oligosaccharide production. Parameters influencing oligosaccharide formation, together with the effect of immobilization were examined and conditions minimizing oligosaccharide content in the hydrolysis product were proposed. Enzymatic whey hydrolysis was also considered. A possibility of enzymatic lactose recombination from its hydrolysis products was shown.     

Lactone-ring-cleaving enzymes of microorganisms: their diversity and applications

Microbial lactonohydrolases (lactone-ring-cleaving enzymes) with unique characteristics were found. The Fusarium oxysporum enzyme catalyzes the reversible and stereospecific hydrolysis of aldonate lactones and D-pantolactone (D-PL), and is useful for the optical resolution of racemic PL. The Agrobacterium tumefaciens enzyme hydrolyzes several aromatic lactones, and catalyzes the stereospecific hydrolysis of PL like the Fusarium enzyme, but its selectivity is opposite. The Acinetobacter calcoaceticus enzyme catalyzing the specific hydrolysis of dihydrocoumarin belongs to serine-enzyme family, and is useful for enantioselective hydrolysis of methyl DL-beta-acetylthioisobutyrate and regioselective hydrolysis of methyl cetraxate. This enzyme also catalyzes the bromination of monochlorodimedon when incubated with H(2)O(2) and dihydrocoumarin.