Effect of protamine in obesity induced by high-fat diets in rats.

OBJECTIVE: Protamine has been shown to have an inhibitory effect on protein lipase in vitro; the objective of this study was to evaluate the antiobesity activity effect of protamine in obese induced rats, and to evaluate the effect of protamine on postprandial hypertriacylglyceridemia in rats by intragastric administration of a lipid emulsion containing corn oil. DESIGN: Two experiments were carried out: (1) In a parallel study in rats, we administered a lipid emulsion containing corn oil plus 0, 200 or 500 mg kg(-1) of protamine intragastrically. (2) In a randomized parallel prospective rats experiment, rats were fed with a high-fat diet and 0, 200 or 500 mg of protamine per kg of animal weight during 5 weeks. SUBJECTS: Male Sprague-Dawley rats. MEASUREMENTS: In experiment 1, plasma triacylglycerol levels after oral administration of lipid emulsion were determined. In experiment 2, weight gain, concentrations of plasma triacylglycerol, plasma total cholesterol and albumin were determined, and the subcutaneous and visceral adipose tissues were weighed. RESULTS: Plasma triacylglycerol concentration in rats administered with 200 or 500 mg kg(-1) of protamine was significantly lower than that in rats in the control group (200 mg kg(-1) of protamine, P<0.05 at 1, 2, 3 and 4 h; 500 mg kg(-1) of protamine P<0.05 at 2, 3 and 4 h). In rats fed with a high-fat diet, and 200 and 500 mg kg(-1) of protamine, there was a decreased body weight gain by 52 and 66 g, respectively, reduced visceral fat by 5 and 8 g, respectively and subcutaneous tissue weights by 12 and 15 g, respectively. Plasma triacylglycerol was 17 and 45 mg per 100 ml lower in rats fed with high-fat diet plus 200 and 500 mg kg(-1) of protamine, respectively. And cholesterol concentrations were 18 and 22 mg per 100 ml lower in both protamine groups, respectively. CONCLUSION: Our study demonstrates that protamine reduce weight gain and body fat accumulation through the inhibition of dietary fat absorption.

A putative peroxidase cDNA from turnip and analysis of the encoded protein sequence.

A putative peroxidase cDNA was isolated from turnip roots (Brassica napus L. var. purple top white globe) by reverse transcriptase-polymerase chain reaction (RT-PCR) and rapid amplification of cDNA ends (RACE). Total RNA extracted from mature turnip roots was used as a template for RT-PCR, using a degenerated primer designed to amplify the highly conserved distal motif of plant peroxidases. The resulting partial sequence was used to design the rest of the specific primers for 5' and 3' RACE. Two cDNA fragments were purified, sequenced, and aligned with the partial sequence from RT-PCR, and a complete overlapping sequence was obtained and labeled as BbPA (Genbank Accession No. AY423440, named as podC). The full length cDNA is 1167bp long and contains a 1077bp open reading frame (ORF) encoding a 358 deduced amino acid peroxidase polypeptide. The putative peroxidase (BnPA) showed a calculated Mr of 34kDa, and isoelectric point (pI) of 4.5, with no significant identity with other reported turnip peroxidases. Sequence alignment showed that only three peroxidases have a significant identity with BnPA namely AtP29a (84%), and AtPA2 (81%) from Arabidopsis thaliana, and HRPA2 (82%) from horseradish (Armoracia rusticana). Work is in progress to clone this gene into an adequate host to study the specific role and possible biotechnological applications of this alternative peroxidase source.

Chemical modification of turnip peroxidase with methoxypolyethylene glycol enhances activity and stability for phenol removal using the immobilized enzyme.

Peroxidase from turnip roots (TP) was isolated followed by modification with methoxypolyethylene glycol (MPEG). The catalytic activity of the modified TP (MTP) on ABTS increased 2.5 times after 80 min of reaction. MTP showed a KM similar value to that of TP, but a significantly greater kcat for ABTS oxidation, in aqueous buffer. Chemical modification produced an enhanced stability in organic solvents and increased thermal stability of about 4 times that of TP, in aqueous buffer at 70 degrees C. Circular dichroism showed that MPEG modification decreased TP alpha-helical structure from 26 to 16% and increased beta-turns from 26 to 34%, resulting in an enhanced conformational stability. The temperature at the midpoint of thermal denaturation (melting temperature) increased from 57 to 63 degrees C after modification. MTP was immobilized in alginate beads (IMTP) and tested for oxidative polymerization of concentrated phenolic synthetic solutions, achieving 17 effective contact cycles removing >65% phenols. IMTP may be useful for the development of an enzymatic process for wastewater effluent treatment.

Polyethylene glycol improves phenol removal by immobilized turnip peroxidase.

Purified peroxidase from turnip (Brassica napus L. var. esculenta D.C.) was immobilized by entrapment in spheres of calcium alginate and by covalent binding to Affi-Gel 10. Both immobilized Turnip peroxidase (TP) preparations were assayed for the detoxification of a synthetic phenolic solution and a real wastewater effluent from a local paints factory. The effectiveness of phenolic compounds (PC's) removal by oxidative polymerization was evaluated using batch and recycling processes, and in the presence and in the absence of polyethylene glycol (PEG). The presence of PEG enhances the operative TP stability. In addition, reaction times were reduced from 3h to 10 min, and more effective phenol removals were achieved when PEG was added. TP was able to perform 15 reaction cycles with a real industrial effluent showing PC's removals >90% PC's during the first 10 reaction cycles. High PC's removal efficiencies (>95%) were obtained using both immobilized preparations at PC's concentrations <1.2mM. Higher PC's concentrations decreased the removal efficiency to 90% with both preparations after the first reaction cycle, probably due to substrate inhibition. On the other hand, immobilized TP showed increased thermal stability when compared with free TP. A large-scale enzymatic process for industrial effluent treatment is expected to be developed with immobilized TP that could be stable enough to make the process economically feasible.

Purification and properties of a neutral peroxidase isozyme from turnip (Brassica napus L. Var. Purple Top White Globe) roots.

A neutral peroxidase isozyme (pI 7.2) from turnip roots (TNP) was purified to homogeneity and partially characterized. TNP is a monomeric glycoprotein with 9.1% carbohydrate content and a molecular weight of 36 kDa. Optimum pH values for activity using 2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonic acid (ABTS) and guaiacol as H donors were 4.5 and 5.5, whereas the K(m) values were 0.7 and 3.7 mM, respectively. The ABTS K(m) was approximately 7 times higher than that reported for basic commercial horseradish peroxidase (HRP-C). TNP retained approximately 70% activity after 11 min of heating at 65 degrees C, whereas the activation energy for inactivation (132 kJ/mol) was higher than or comparable to that of other peroxidases. The low ABTS K(m) and high specific activity (1930 units/mg) gave a high catalytic efficiency (500 M(-1) s(-1)). These properties make TNP an enzyme with a high potential as an alternative to HRP in various applications.

Purification and partial characterization of three turnip (Brassicanapus L. var. esculenta D.C.) peroxidases.

Three turnip peroxidases (fractions C1, C2, and C3) were partially purified and characterized, to permit study of their feasibility for use in clinical and enzyme immunoassays. These fractions represented 20% of the initial activity, and fractions C1 and C2 were purified to homogeneity. The optimum pH was between 5.0 and 5.5, while optimum temperature ranged from 40 to 55 degrees C. The ABTS K(m) values for the two acidic fractions (C2 and C3) were 0.70 and 0.42 mM, respectively; about 5 times lower than that reported for the acidic commercial horseradish peroxidase (HRP). Fraction C3 had 4 times higher K(m) value than commercial cationic HRP. The molecular weights determined by SDS-PAGE ranged from 39.2 to 42.5 kDa. Activation energies for inactivation were 113 (C1), 130 (C2), and 172 kJ/mol (C3) which are higher or comparable to other peroxidase isoenzymes reported. Fractions C1 and C3 represent an alternative source of peroxidase because of their higher purification yield and specific activity, when compared to fraction C2.